US20230156389A1 - Earplugs, earphones, and eartips - Google Patents
Earplugs, earphones, and eartips Download PDFInfo
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- US20230156389A1 US20230156389A1 US17/895,059 US202217895059A US2023156389A1 US 20230156389 A1 US20230156389 A1 US 20230156389A1 US 202217895059 A US202217895059 A US 202217895059A US 2023156389 A1 US2023156389 A1 US 2023156389A1
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- ear canal
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Images
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R1/00—Details of transducers, loudspeakers or microphones
- H04R1/10—Earpieces; Attachments therefor ; Earphones; Monophonic headphones
- H04R1/1016—Earpieces of the intra-aural type
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F11/00—Methods or devices for treatment of the ears or hearing sense; Non-electric hearing aids; Methods or devices for enabling ear patients to achieve auditory perception through physiological senses other than hearing sense; Protective devices for the ears, carried on the body or in the hand
- A61F11/06—Protective devices for the ears
- A61F11/08—Protective devices for the ears internal, e.g. earplugs
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F11/00—Methods or devices for treatment of the ears or hearing sense; Non-electric hearing aids; Methods or devices for enabling ear patients to achieve auditory perception through physiological senses other than hearing sense; Protective devices for the ears, carried on the body or in the hand
- A61F11/06—Protective devices for the ears
- A61F11/08—Protective devices for the ears internal, e.g. earplugs
- A61F11/10—Protective devices for the ears internal, e.g. earplugs inflatable or expandable
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R25/00—Deaf-aid sets, i.e. electro-acoustic or electro-mechanical hearing aids; Electric tinnitus maskers providing an auditory perception
- H04R25/65—Housing parts, e.g. shells, tips or moulds, or their manufacture
- H04R25/652—Ear tips; Ear moulds
- H04R25/656—Non-customized, universal ear tips, i.e. ear tips which are not specifically adapted to the size or shape of the ear or ear canal
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2460/00—Details of hearing devices, i.e. of ear- or headphones covered by H04R1/10 or H04R5/033 but not provided for in any of their subgroups, or of hearing aids covered by H04R25/00 but not provided for in any of its subgroups
- H04R2460/11—Aspects relating to vents, e.g. shape, orientation, acoustic properties in ear tips of hearing devices to prevent occlusion
Definitions
- the present invention relates to devices that modify acoustic attenuation and reflection, and more particularly, though not exclusively, devices that can be inserted into an ear canal or used as a sound insert or panel.
- Hearing protection can take several forms such as earplugs and muffs.
- Such hearing protection devices attenuate acoustic energy before it reaches the eardrum (tympanum) by creating an insertion loss that is achieved by reflection of the sound waves, dissipation with the device’s structure, impedance of the waves through tortuous paths, closing of acoustical valves, and other means.
- SPL sound pressure level
- dB decibels
- Ferrofluids are composed of nanoscale particles (diameter usually 10 nanometers or less) of magnetite, hematite or some other compound containing iron. This is small enough for thermal agitation to disperse them evenly within a carrier fluid, and for them to contribute to the overall magnetic response of the fluid. This is analogous to the way that the ions in an aqueous paramagnetic salt solution (such as an aqueous solution of copper(II) sulfate or manganese(II) chloride) make the solution paramagnetic.
- an aqueous paramagnetic salt solution such as an aqueous solution of copper(II) sulfate or manganese(II) chloride
- ferrofluids are dispersed in a liquid, often using a surfactant, and thus ferrofluids are colloidal suspensions - materials with properties of more than one state of matter.
- the two states of matter are the solid metal and liquid it is in. This ability to change phases with the application of a magnetic field allows them to be used as seals, lubricants, and may open up further applications in future nanoelectromechanical systems.
- True ferrofluids are stable. This means that the solid particles do not agglomerate or phase separate even in extremely strong magnetic fields. However, the surfactant tends to break down over time (a few years), and eventually the nano-particles will agglomerate, and they will separate out and no longer contribute to the fluid’s magnetic response.
- magnetorheological fluid refers to liquids similar to ferrofluids (FF) that solidify in the presence of a magnetic field. Magnetorheological fluids have micrometre scale magnetic particles that are one to three orders of magnitude larger than those of ferrofluids.
- ferrofluids lose their magnetic properties at sufficiently high temperatures, known as the Curie temperature.
- the specific temperature required varies depending on the specific compounds used for the nano-particles.
- Electrorheological (ER) fluids are suspensions of extremely fine nonconducting particles (up to 50 micrometres diameter) in an electrically insulating fluid.
- the apparent viscosity of these fluids changes reversibly by an order of up to 100,000 in response to an electric field.
- a typical ER fluid can go from the consistency of a liquid to that of a gel, and back, with response times on the order of milliseconds.
- the change in apparent viscosity is dependent on the applied electric field, i.e. the potential divided by the distance between the plates.
- the change is not a simple change in viscosity, hence these fluids are now known as ER fluids, rather than by the older term Electro Viscous fluids.
- an electric field dependent shear yield stress When activated an ER fluid behaves as a Bingham plastic (a type of viscoelastic material), with a yield point which is determined by the electric field strength. After the yield point is reached, the fluid shears as a fluid, i.e. the incremental shear stress is proportional to the rate of shear (in a Newtonian fluid there is no yield point and stress is directly proportional to shear). Hence the resistance to motion of the fluid can be controlled by adjusting the applied electric field.
- FIG. 1 illustrates a cartilaginous region and a bony region of an ear canal
- FIG. 2 illustrates general physiology of an ear
- FIG. 3 illustrates a nonlimiting example of an experiment for determining material properties of inflatable elements
- FIG. 4 illustrates the sound pressure levels (SPL) of the upstream microphone (UM) and the downstream microphone (DM) as a function of medium and pressure;
- FIG. 5 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air at 400 mbar gauge pressure;
- FIG. 6 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air at 600 mbar gauge pressure;
- FIG. 7 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air for 400 mbar and 600 mbar gauge pressures;
- FIG. 8 illustrates the insertion loss (IL) value for Air for gauge pressures of 350 mbar, 450 mbar, 550 mbar, and 650 mbar gauge pressures;
- FIG. 9 illustrates the insertion loss (IL) value for H2O for gauge pressures of 350 mbar, 450 mbar, 550 mbar, and 600 mbar gauge pressures;
- FIG. 10 illustrates the insertion loss (IL) value for two mediums, H2O, and Air for 450 mbar and 550 mbar gauge pressures
- FIG. 11 illustrates a general mathematical model of an earplug using a membrane
- FIG. 12 illustrates an experimental test system that can be used to test attenuation and reflection characteristics both in a subject and for panel design
- FIGS. 13 - 18 illustrate non-limiting examples of earplugs with modifiable attenuation
- FIG. 19 illustrates a detachable earplug pumping system in accordance with at least one exemplary embodiment
- FIG. 20 illustrates a lanyard earplug system in accordance with at least one exemplary embodiment
- FIG. 21 A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 21 B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 22 A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 22 B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 23 A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 23 B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation
- FIG. 24 illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment
- FIGS. 25 A and 25 B are schematic diagrams illustrating cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment
- FIG. 25 C is a schematic diagram illustrating a hearing protection device embodiment of the invention.
- FIG. 26 illustrates an earplug in accordance with at least one exemplary embodiment
- FIG. 27 illustrates an acoustic shaping panel in accordance with at least one exemplary embodiment
- FIG. 28 illustrates a cross section of the panel illustrated in FIG. 27 ;
- FIG. 29 illustrates attachment of the panels of FIG. 27 on a wall in accordance with at least one exemplary embodiment
- FIG. 30 A illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment
- FIG. 30 B illustrates a close-up of the medium illustrated in FIG. 30 A ;
- FIGS. 31 A, 31 B, 31 C, and 31 D illustrate variations of cross sections of acoustic shaping panels in accordance with various exemplary embodiments
- FIGS. 32 A, 32 B, and 32 C illustrate the configuration and operation of at least one exemplary embodiment
- FIG. 33 illustrates an earplug in accordance with one exemplary embodiment
- FIGS. 34 A, 34 B, and 34 C illustrate the configuration and operation of at least one exemplary embodiment
- FIGS. 35 A, 35 B, 35 C, and 36 illustrate the configuration and operation of at least one exemplary embodiment
- FIGS. 37 and 38 illustrate a helmet with a liner in accordance with at least one exemplary embodiment
- FIGS. 39 - 40 illustrate various flexible distal ends developed
- FIG. 41 illustrates a novel distal end spiral feed system which enhances uniform expansion about a stent
- FIG. 42 illustrates a tip in accordance with at least one exemplary embodiment
- FIG. 43 illustrates a novel distal end spiral feed system which enhances uniform expansion about a stent
- FIGS. 44 A, 44 B, 44 C, 44 D, 44 E, 44 F, 44 G, 44 H, 44 I, 44 G, 44 J illustrates various eartips, earplugs in accordance with various exemplary embodiments
- FIG. 45 illustrates a work environment
- FIG. 46 illustrates the computer display that represents the work environment of FIG. 45 ;
- FIG. 47 illustrates an embodiment of an earphone/earplug
- FIG. 48 A illustrates a membrane tip in accordance with an embodiment
- FIG. 48 B illustrates a cross section of the tip of FIG. 48 A ;
- FIG. 49 illustrate an inflatable earphone system in accordance with one exemplary embodiment
- FIGS. 50 - 51 illustrate a lanyard pump inflatable earphone system
- FIGS. 52 - 53 illustrate an actuatable inflatable earphone system
- FIGS. 54 A, 54 B, 55 illustrate pull-release expandable earphone system
- FIG. 56 is an illustration of an ear device prior to insertion into an ear canal of an ear in accordance with an example embodiment
- FIG. 57 is a cutaway view of the ear device in accordance with an example embodiment
- FIG. 58 is an illustration of the ear device inserted in the ear canal in accordance with an example embodiment
- FIG. 59 is a cutaway view of the ear device without a stop flange in accordance with an example embodiment
- FIG. 60 is a cutaway view of an ear device without a stop flange in accordance with an example embodiment
- FIG. 61 is a cutaway view of the ear device with a chamber sealed in accordance with an example embodiment
- FIG. 62 is a block diagram of a method for occluding or partially occluding an ear canal with an ear device in accordance with an example embodiment
- FIG. 63 is a block diagram of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment
- FIG. 64 is a block diagram of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment
- FIGS. 65 A and 65 B illustrate the use of a rotating member to open a valve in an ear device
- FIG. 66 is a cutaway view of a molded ear device without a stop flange in accordance with an example embodiment.
- Exemplary embodiments are directed to or can be operatively used on various passive earplugs for hearing protection or electronic wired or wireless earpiece devices (e.g., hearing aids, ear monitors, earbuds, headphones, ear terminal, behind the ear devices or other acoustic devices as known by one of ordinary skill, and equivalents).
- the earpieces can be without transducers (for a noise attenuation application in a hearing protective earplug) or one or more transducers (e.g. ambient sound microphone (ASM), ear canal microphone (ECM), ear canal receiver (ECR)) for monitoring/providing sound.
- ASM ambient sound microphone
- ECM ear canal microphone
- ECR ear canal receiver
- FIG. 1 illustrates a generic cross section of an ear canal 100 , including a cartilaginous region 140 and a bony region 130 of an ear canal 120 .
- the entrance of the ear canal 120 is referred to as the aperture 150 and defines a first end of the ear canal while the tympanic membrane 110 defines the other end of the ear canal 120 .
- FIG. 2 illustrates general outer physiology of an ear, which includes a, auricle tubercle 210 , the antihelix 220 , the helix 230 , the antitragus 240 , tragus 250 , lobule of ear 260 , crus of helix 270 , anterior notch 280 , and intertragic incisures 290 .
- FIG. 3 illustrates a nonlimiting example of an experiment for determining material properties of inflatable elements.
- a noise source 310 e.g., Phonic PAA6
- acoustic source waves 315 e.g., pink noise, white noise
- an upstream first microphone e.g., M1 or UM, Audix Measurement Microphone
- the test sample 330 (e.g., balloon, isolated chamber) can be filled with various fluids (e.g., air, water, water with agents) and inserted into a portion 320 B of the tunnel such that the acoustic source waves impinge one side of the test sample, travels through the test sample, and exit the opposite or adjacent (not shown) side of the test sample, where a downstream microphone (e.g., M2 or DM) measures the exiting acoustic waves.
- various fluids e.g., air, water, water with agents
- the system is set to have an anechoically terminated end, which is accomplished by length (>75 ft) so as to gradually diminish the energy of the travelling wave 316 via wall interaction, and by having small strands of string near the end to absorb more of the energy in the wave.
- the data from the two microphones M1 and M2 are obtained to extract acoustical spectrum information (e.g., using FFT analyzer software such as 340 Spectra-PLUSTM FFT Analyzer). For example, when measuring insertion loss (IL), measurements are taken with M2 prior to insertion of a test sample, then a test sample inserted and measurements retaken with M2.
- insertion loss For discussion herein with regards to tunnel data IL is approximated when using balloons by a difference in the uninflated M2 measurements (i.e. pressure of 000mbar gauge pressure) and an inflated M2 measurement.
- the pressure of a test sample is varied by use of a pressure pump 350 (e.g., SI Pressure LTP1TM Low Pressure Calibration Pump), and monitored by reading the pressure from a pressure gauge 360 (e.g., ExtechTM Differential Pressure Manometer).
- a pressure pump 350 e.g., SI Pressure LTP1TM Low Pressure Calibration Pump
- a pressure gauge 360 e.g., ExtechTM Differential Pressure Manometer
- FIG. 4 illustrates the sound pressure levels (SPL) of the upstream microphone (UM) and the downstream microphone (DM) as a function of medium and pressure.
- SPL sound pressure levels
- UM upstream microphone
- DM downstream microphone
- the top panel illustrates upstream microphone 400 (UM) measurements under six conditions, water as the medium under three pressures: 000 mbar(blue), 400 mbar(green), and 600 mbar(light blue); and air as the medium under the same three pressures: 000 mbar(light purple), 400 mbar(red), and 600 mbar(orange).
- UM upstream microphone 400
- the pressure conditions separate into two general separate lines, the first with no inflation for example 410 , and a second line where the two non-zero pressure values generally overlap into a single line 420 .
- an increase of about 7 dB is measured upstream of the test sample.
- 7 dB of incident energy is reflected from the interface.
- the bottom panel illustrates downstream microphone 460 (DM) measurements under six conditions, water as the medium under three pressures: 000 mbar(blue), 400 mbar(green), and 600 mbar(light blue); and air as the medium under the same three pressures: 000 mbar(light purple), 400 mbar(red), and 600 mbar(orange).
- DM downstream microphone 460
- FIG. 5 illustrates the insertion loss (IL) values 500 for three mediums, NaCl, H2O, and Air at 400 mbar gauge pressure as measured by the downstream microphone DM. Note that a larger IL value is associated with more energy being removed from the initial acoustic wave by the test sample.
- the three different mediums distilled H 2 O with 1.95 mg/L NaCl (light blue line) 510 , distilled H 2 O (blue) 520 , and Air (red) 530 , are distinguishable. For example air provides less IL after 700 Hz than H 2 O 520 and H 2 O+NaCl mixture 510 .
- H 2 O 520 and H 2 O+NaCl mixture 510 have similar profiles below 700 Hz and above 3 kHz. Between 700 Hz-3 KHz the IL values 510 and 520 differ such that an H 2 O+NaCl mixture provides more IL. Note that although an H 2 O+NaCl mixture is illustrated, other mixtures (e.g., with sucrose, alcohol, mineral oil) can be used to taylor specific increases or decreases in IL as a function of frequency for a given pressure.
- FIG. 6 illustrates the insertion loss (IL) values 600 for three mediums, NaCl, H2O, and Air at 600 mbar gauge pressure as measured by the downstream microphone DM. Note that a larger IL value is associated with more energy being removed from the initial acoustic wave by the test sample.
- the three different mediums distilled H 2 O with 1.95 mg/L NaCl (light blue line) 610 , distilled H 2 O (blue) 620 , and Air (red) 630 are distinguishable. For example air provides less IL after about 1.5 kHz than H 2 O 620 and H 2 O+NaCl mixture 610 . Note that the decrease with air as a medium after 1.5 kHz differs from the 400 mbar value of 700 Hz.
- air 630 provides less IL than H 2 O 620 and H 2 O+NaCl mixture 610 above a higher frequency.
- the IL profiles also vary, facilitating using controllable pressure values to obtain design IL profiles. For example, if an earplug uses air and an IL value above 700 Hz in unimportant for the particular use, then an earplug can be designed to have an internal balloon pressure of about 400 mbar, whereas if the IL value above 1.5 kHz is unimportant then the earplug balloon can be designed to have an internal pressure of 600 m bar.
- H 2 O 620 green
- H 2 O+NaCl mixture 610 red
- the IL values 610 and 620 differ such that an H 2 O+NaCl mixture provides more IL.
- other mixtures e.g., with sucrose, alcohol, mineral oil
- the IL value can be varied at different frequencies by adding agents (e.g., NaCl). If one wishes to increase the IL above 700 Hz one could add a mixture of NaCl and distilled water 620 .
- FIG. 7 illustrates the insertion loss (IL) value 700 for three mediums, NaCl, H2O, and Air for two pressures 400 mbar and 600 mbar gauge pressures as illustrated in FIGS. 5 and 6 for ease of comparison.
- IL insertion loss
- FIG. 8 illustrates the insertion loss (IL) value for Air for gauge pressures of 350 mbar ( 800 ), 450 mbar ( 810 ), 550 mbar ( 820 ), and 650 mbar ( 830 ) gauge pressures.
- IL insertion loss
- pressure can be varied in an earplug device to modify the frequency at which the greatest IL is provided. For example, suppose the frequency of an offending noise source gradually increases in frequency. An air-filled earplug with interactive pressure control could increase the pressure of an earplug balloon to maintain suppression of the noise source as its frequency increased.
- FIG. 9 illustrates the insertion loss (IL) value for H 2 O for gauge pressures of 350 mbar ( 900 ), 450 mbar ( 910 ), 550 mbar ( 920 ), and 600 mbar ( 930 ) gauge pressures.
- IL insertion loss
- the pressure of an H 2 O filled earplug bladder can be set to about 350 mbar and if an increase of IL is needed within this range then the pressure can be increased.
- FIG. 10 illustrates the insertion loss (IL) value for the H 2 O values of FIG. 9 and two air values for comparison Air at 450 mbar ( 1030 ) and 550 mbar ( 1020 ) gauge pressures.
- peak IL values differ from the fluid used (e.g., air or H 2 O).
- air e.g., air or H 2 O
- an earplug device is designed to maximize IL at 500 Hz, then one can use air at 450 mbar, where if one wishes to maximize the IL at about 650 Hz the air pressure can be increased to 550 mbar.
- H 2 O at a pressure of about 550 mbar.
- a flatter IL profile when using H 2 O can be obtain between frequencies about 500 Hz and 1 kHz by setting the H 2 O pressure to about 550 mbar as opposed to 450 mbar.
- the membrane itself can also be considered a region separating region 1 and region 2.
- Reflection (R) coefficient and Transmission (T) coefficient can be derived using interface boundary conditions BC1 (continuity of pressure) and BC2 (continuity of particle velocity).
- A1-B1 Z1/Z2 A2-B2 continuity of particle velocity
- equations (1) and (2) are generally used across any boundary between two regions. If we treat the membrane as the second region we will get the relationships:
- A1-B1 Z1/ZM AM-BM continuity of particle velocity
- At least one exemplary embodiment of the present invention employs a simple stretch membrane (i.e., “balloon”) approach, wherein an inflatable, lightweight balloon is inserted into the ear canal in its deflated state, and then inflated once inside the canal.
- This insertion configuration affords its own additional advantages in the realm of having an in-ear product that is undersize compared to the diameter of the ear canal prior to insertion, and then expands once inside the canal, unlike most other earplug products on the market, including the Ety High FidelityTM earplug, which are sized to be oversize the ear canal prior to insertion, and thus require squeezing or compression upon insertion, making insertion more difficult.
- FIG. 12 illustrates a method for testing various configurations.
- the membrane-based earplug testing system comprises in general a tip configuration and a bladder configuration.
- the bladder configuration includes a filler bladder where the filler bladder is a medical balloon that is pre-shaped but deformable.
- the tip configuration includes a compliant tip that is an expandable elastic medical balloon that conforms to a stent.
- the stent connects the filler bladder to the compliant tip.
- the filler bladder can be deformed forcing filler material to the compliant tip which expands to fill an ear canal.
- the material is kept from flowing back to the filler bladder by a deformable one way valve.
- the deformable one-way valve (made of compliant rubber-like material) can be deformed by a user to allow back flow to the bladder.
- the system additionally includes two way and three way valves for the relief of pressure, filler exchange, and pressure measurement.
- the one way valve, two way valve, and three way valves are valves that can be included in housing, with attached medical luer locks that can then be fitted to the stent.
- the tip configuration includes a safety flange to determine whether inclusion of a safety flange affects localization.
- the bladder configuration includes a medical pre-shaped balloon of about 1 cc volume attached to luer lock connectors at either end.
- Various fillers can be used for example H2O, H2O +NaCl, H2O+Alcohol, Alcohol, MR fluid, and Air, note that this list is a non-limiting example only.
- FIGS. 13 - 18 illustrate non-limiting examples of earplugs with modifiable attenuation.
- FIG. 13 illustrates an earpiece (e.g., earplug, headphone, hearing aid) that includes a first reservoir 1310 (e.g., Urethane balloon, silicon balloon) fed by a channel (tube) 1330 in a stent 1300 .
- the stent 1300 can be fabricated from various materials (e.g., silicon, urethane, rubber) and can include internal channel (tubes), for example tubes 1330 and 1320 .
- the stent can also be a multi-lumen (i.e., multi-passageway) stent where the channels/tubes are various lumens of the multi-lumen stent.
- the first reservoir 1310 can be connected to a second reservoir 1370 via the tube 1330 .
- a fluid 1360 can be transferred between the first reservoir 1310 and the second reservoir 1370 by pressing against the second reservoir 1370 or by pressing against the first reservoir 1310 .
- the reservoirs ( 1370 and 1310 ) can be fabricated from stressed membranes (e.g., silicone) so that when fluid is inserted into the reservoirs a restoring force presses against the fluid 1360 by the membrane.
- FIG. 13 illustrates a non-limiting example of a structure that includes a piston head 1380 , a front surface of the piston head 1390 connected to a stem 1384 .
- the structure can lie within a housing that has optional internal threads 1382 , which optional threads on piston head 1380 can engage so if one rotates the piston head one pushes the piston head front surface against the second reservoir 1370 .
- the restoring force of the first reservoir 1310 can be such that the fluid remains in the second reservoir 1370 unless the volume of the second reservoir 1370 is decreased.
- Such a configuration can be used for an earplug where the portion to be inserted is collapsed into a minimal profile shape and upon insertion a user can move the structure so that the volume of the second reservoir 1370 decreases increasing the fluid in to the first reservoir, such that the first reservoir 1310 expands occluding a channel (e.g., ear canal) into which the earpiece is at least partially placed.
- a channel e.g., ear canal
- other channels can be used to convey acoustical energy across the first reservoir, for example the tube 1320 can be used to measure or emit sound to the left of the first reservoir as illustrated in FIG. 13 .
- FIG. 14 illustrates a non-limiting example of a moveable structure discussed with reference to FIG. 13 , where the stem 1384 is attached to a tab 1400 that a user can move (e.g., push, rotate) to move the structure toward or away from the second reservoir 1370 .
- a user can move (e.g., push, rotate) to move the structure toward or away from the second reservoir 1370 .
- FIG. 15 illustrates an isolated view of the stent discussed with reference to FIG. 13 .
- the stent can be similar to that used in an infant urology Foley catheter, which has an inflation tube 1330 and a flush tube 1320 , where for an earplug the flush tube is sealed, for example by injecting a flexible curing material (e.g., Alumilite Flex 40TM casting rubber).
- a flexible curing material e.g., Alumilite Flex 40TM casting rubber.
- a bladder 1600 ( FIG. 16 ) having a preformed shape (e.g., non-compliant medical balloon) or flexible shape (e.g. compliant medical balloon) can be filled with the desired fluid then attached to the stent or to the housing and sealed ( FIG. 17 ).
- the bladder 1730 can be attached 1740 to housing 1700 that can also include threads 1710 .
- the fluid filled 1830 housing 1810 ( FIG. 18 ) (e.g., fabricated from a plastic, hard rubber) can then be attached 1820 to the stent 1800 , the structure screwed into threads in the housing, and a retainer cap 1395 attached to the housing (e.g., via loctite glue) restricting the movement of the structure.
- the retainer cap 1395 there can be a hole in the retainer cap 1395 , having a hole diameter D H , where in at least one embodiment, D H can be larger than the tab 1400 width D F .
- the bladder 1600 can be of various shape for example semi-spherical, cylindrical, and can be formed by various methods such as dip molding. Note also that an optional stop ring 1350 can be used.
- FIG. 19 illustrates a detachable earplug pumping system in accordance with at least one exemplary embodiment.
- the earpiece 3080 can be operatively attached via a tube 3050 to a finger pump 3090 .
- the entire pump system e.g., 3030 , 3050 , 3070 , 3060 , 3035
- a pump seal valve 3040 in a sealing section 3020 in the earpiece 3080 generally allows one way flow and seals when the pump system is detached.
- the earpiece includes initially a deflated fluid reservoir which is fluid filled when the pump is actuated (e.g., finger pumped).
- the pump insert port 3010 allows general sealing with a detachable pumps insert interface 3030 (e.g., arrow head).
- the pump system can include a feed tube 3050 attached to the insert interface 3030 .
- the feed tube can be attached to a pump body 3070 which includes a finger dimple 3060 , for example fabricated from a restoring flexible material (e.g., rubber) that returns to its original shape after deformation.
- a restoring flexible material e.g., rubber
- a one way valve (e.g., 3040 ) system 3035 feeds fluid (e.g., from the environment) into the pump body 3070 so via another deformation of the finger dimple 3060 fluid is available to be pumped into earpiece 3080 .
- FIG. 20 illustrates a lanyard earplug system 4060 in accordance with at least one exemplary embodiment.
- Earpieces 4000 including optional stop flanges 4010 can be attached to a lanyard finger pump system 4060 .
- the lanyard finger pump system can include two connected tubes 4020 A and 4020 B each feeding a separate earpiece 4000 .
- the tubes 4020 A and 4020 B can be connected via one way valves 4030 to a squeeze release section 4050 , which can be squeezed (A) to deflate the earpieces 4000 .
- the pump section can include a finger dimple 4040 and an inlet one way valve C.
- the inlet one way valve C can include a one way valve 4030 .
- the release section 4050 can include two one way valves, one 4060 A associated with tube 4020 A and the other 4060 B associated with tube 4020 B. As fluid is pushed through each one way valve 4060 A and 4060 B the respective earpieces 4000 inflate.
- An optional one way valve per tube (not shown) can be used to make sure that the maximum pressure in each tube 4020 A and 4020 B does not exceed a maximum value P max.
- FIGS. 21 A and 21 B illustrate the operation of at least one exemplary embodiment.
- the device includes a reservoir 10 , a fluid channel 40 , a valve 20 and expandable element 30 .
- the reservoir 10 includes a medium that can be tailored to vary the acoustic spectrum as a function of frequency.
- the distal end (right end of FIG. 21 A ) is inserted into an ear canal. The user then depresses Y1 the reservoir 10 , which moves fluid from the reservoir 10 through the fluid channel 40 in a single direction as provided by the one way valve 20 .
- the fluid movement into the expandable element 30 expands (Z1) the element 30 to a desired extent.
- the modification of any acoustic spectrum that passes through the earplug can be tailored (acoustically shaped) by varying the medium and pressure.
- various mediums will be discussed below, but in general can include liquids, gases, mixtures, colliodal suspensions, foams, gels, and particle suspensions.
- a colloidal suspension e.g. aphron
- a chemical reaction can occur (e.g., to generate heat to warm an earplug before insertion in cold climates).
- FIGS. 22 A and 22 B illustrate concepts of a membrane based earplug, that should fit the majority of the population (5th percentile - 95th percentile), be easy to clean/maintain, be environmentally durable (e.g. durable silicone), maximize ability to detect/identify/pinpoint sounds, be lightweight, easily donned/doffed, and be compatible with currently fielded military equipment, to include helmets.
- the reservoir 2200 includes a medium specifically chosen, as described herein, to control the reflection and/or the transmitted attenuated acoustical spectrum.
- the valve 2240 allows one way passage of the medium into the distal end expanding the distal end (see operation in FIG. 22 B ).
- a user can press on the stent 2210 , which bends because of the cut 2220 , placing pressure on the valve 2240 opening the valve deflating the distal end.
- a house for a safety flange 2250 can be designed so that a user can squeeze the safety flange toward the stent to deform and open the valve 2240 .
- FIGS. 23 A and 23 B illustrates of an exemplary embodiment, includes an earplug 2300 with no valve, for example employs a manual push dimple/tab 2310 system having a fastener in the reservoir (e.g., VelcroTM) that fastens (e.g., portion 2320 interlocking 223 with portion 2330 ) when pushed holding the fluid (gas, or liquid) in an inflation element until manually released (e.g., tab 2310 pulled to pull apart the VelcroTM).
- the holding force F L of the reservoir internal fastener must exceed the natural restoring force of the expanded inflation element 2370 .
- To release the expanded distal end a user pulls the tab to overcome the internal holding force of the reservoir.
- the earplug 2300 can include a body 2350 having various thickness, encompassing a fluid chamber 2340 , connected to a channel 2360 , terminating at an inflation element 2370 .
- a body 2350 having various thickness, encompassing a fluid chamber 2340 , connected to a channel 2360 , terminating at an inflation element 2370 .
- FIG. 24 illustrates an example of an embodiment 2400 where the membrane and/or medium can be designed to tailor the transmitted attenuated sound profile and/or the reflected sound profile (e.g., for use in concert halls).
- small filaments 2463 can be built into the membrane 2462 to absorb sound frequencies associated with the natural frequency of the filaments.
- the Panel 2400 can be configured such that incident wave 2411 having a spectrum 2412 incident on the panel 2400 results in a reflected wave 2421 having spectrum 2423 , and a transmitted wave 2431 having a spectrum 2433 , where the panel has modified the initial spectrum passing through the panel 2432 into the resultant transmitted spectrum 2433 .
- the Panel 2400 can include several layers including a combination membrane X1 that includes a membrane 2450 under tension an absorptive layer 2452 and a medium 2453 FIG.
- FIG. 25 A illustrates an embodiment 2500 where the membrane 2550 includes cavities 2560 that can be filled with or without (e.g., gas, liquids, suspended solids) mediums to design particular resonant frequencies 2525 associated with the cavities, affecting both the transmitted and reflected acoustical spectrum.
- FIG. 25 B illustrates an embodiment 2600 where the membrane is composed of electroactive polymers, (e.g., NafionTM) where a voltage difference across the membrane can stiffen the membrane affecting the reflected and transmitted acoustical profiles.
- electroactive polymers e.g., NafionTM
- a treated NafionTM membrane for example as done for artificial muscle research, can be used as the membrane 2630 for a panel, where the voltage 2610 across the membrane (‘across’ with respect to exterior and interior) can be low initially (e.g., 0.25 volts). When enhanced reflection is desired the voltage can be increased (e.g., 1.5 Volts).
- the fabrication of artificial muscles as known by one of ordinary skill in the art is described in EP Patent Application 0924033 A2, filed 14 Dec. 1998 incorporated by reference in its entirety.
- FIG. 25 C illustrates an additional embodiment 2690 where a sound panel/insert in accordance with an embodiment has been inserted into an ear muff to tailor the spectrum attenuated.
- An additional embodiment includes the use of the sound panel/insert as an outer soft shell 2692 of the earmuff, focusing on reflecting a portion of the spectrum before attenuation.
- a description of the fabrication of an earmuff is described in EP Patent Application No. EP 1811932 B1, filed 16 Nov. 2005 incorporated by reference in its entirety.
- an example of a sound insert in accordance with at least one embodiment of the present invention can be incorporated into the cup shaped cap and/or as part of or inplace of the pressure-equalizing means in application EP 1811932.
- FIG. 26 illustrates at least one exemplary embodiment of an earplug (e.g., foam, polymer flange) with a hollow chamber 2100 , which has a filler material (e.g., water, aphrons, water with solid particles suspended, oil with particles suspended 2140 ), that can be compressed and inserted 2120 into a compacted form 2130 in the ear canal.
- a filler material e.g., water, aphrons, water with solid particles suspended, oil with particles suspended 2140
- the suspended particles or aphrons 2140 can be tailored with various materials tailored to the specific attenuation properties desired.
- FIG. 27 illustrates an acoustic shaping panel 2700 in accordance with at least one exemplary embodiment and FIG. 28 illustrates a cross section of the panel illustrated in FIG. 27 .
- the panel 2700 can include fastening elements 2871 , or can have attachment elements on at least one side of the panel 2700 (e.g., VelcroTM attachment).
- an incident 2841 acoustic wave 2840 (only one frequency illustrated for clarity) with amplitude 2842 passes through the panel 2700 .
- the panel 2700 will modify different frequencies in various methods, for example reducing the amplitude (measured in Decibels or dB).
- the transmitted 2851 acoustic wave 2850 has a reduced amplitude 2852 .
- the reduction amount of the incident amplitude ( 2852 ) is a function of the properties of the case (e.g. front 2810 , back 2820 , and rim 2830 ) of the panels and the properties of the medium 2880 .
- the medium 2880 can be contained within a medium retainer container 2870 (e.g., a bladder).
- the medium 2880 can be inserted under various pressures to obtain various levels of amplitude reduction (e.g., attenuation).
- FIG. 29 illustrates attachment of the panels of FIG. 27 on a wall 2900 in accordance with at least one exemplary embodiment.
- the acoustic properties of a wall 2900 can be modified by adding multiple panels 2700 which are placed 2910 next to each other.
- FIG. 30 A illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment.
- an incident 3041 acoustic wave 3040 (only one frequency illustrated for clarity) with amplitude 3042 passes through the panel.
- the panel will modify different frequencies in various methods, for example reducing the amplitude (measured in Decibels or dB).
- the transmitted 3051 acoustic wave 3050 has a reduced amplitude 3052 .
- the medium 3080 can be contained within a medium retainer container 3070 (e.g., a bladder).
- FIG. 30 B illustrates a closeup of the medium illustrated in FIG. 30 A .
- FIG. 30 B illustrates a closeup of the medium illustrated in FIG. 30 A .
- FIG. 30 B illustrates a closeup of the medium illustrated in FIG. 30 A .
- the medium 3081 includes a suspension 3084 , for example an aphron including a sheath 3083 and core 3082 .
- the sheath 3083 could be an aqueous solution including a surfactant and a core 3082 including a mixture for example oil, or H2O+NaCl, or other mixtures.
- FIGS. 31 A, 31 B, 31 C, and 31 D illustrate variations of cross sections of acoustic shaping panels in accordance with various exemplary embodiments.
- Panels can include various combinations of mediums to shape the acoustic properties of the panels, or a combination of individual panels.
- FIG. 31 A illustrates two mediums 3110 and 3120 that can be combined to provide an overall panel property
- FIG. 31 B illustrates two panels attached 3113 (e.g. via VelcroTM, glue, screws, nails).
- FIG. 31 C and FIG. 31 D illustrates various combinations of mediums are combined to provide tailored acoustic shaping properties of the panels.
- FIG. 31 C includes mediums 3141 and 3143 and fasteners 3171
- FIG. 31 D includes multiple mediums 3191 , 3192 , and 3193 .
- FIGS. 32 A, 32 B, and 32 C illustrate the configuration and operation of at least one exemplary embodiment of an earplug.
- the earplug 3200 includes a reservoir 3270 , a moveable element 3260 , a safety flange 3250 , a valve 3240 , a fluid channel 3230 , a distal end reservoir 3220 , and a distal end shaft 3210 .
- the shaft 3210 can expand for example including regions of various thicknesses (e.g., a thin region 3245 and a thicker region 3247 ), or the shaft can have a port from the distal end reservoir to a flexible element around the distal end of the shaft 3210 which expands while the shaft remains generally constant.
- FIG. 32 C illustrates operation of the earplug Illustrated in FIG. 32 A , where the moveable element 3260 is depressed (squeezed) for example by a user’s fingers, to constrict the reservoir 3270 .
- the constriction of reservoir 3270 forces the medium in the reservoir through the channel 3230 past the valve into the distal end reservoir 3220 .
- the passing of the medium through the valve 3240 prevents the return of the medium into the reservoir 3270 , thus once depressed the fluid remains in or near the distal end reservoir.
- the shaft is flexible then the thin wall portion 3245 will expand 3280 in response B1 to the reservoir constriction A1.
- a flexible element (not shown) can be encased around the shaft where fluid entering the distal reservoir travels via a port to the flexible element expanding the flexible element, which becomes the expandable element 3280 .
- a modification to the non-limiting example illustrated can include a second return valve that opens when a design pressure is reached, for example if one seeks to remove the earplug, when upon pulling the pressure is greater than a designed level (e.g., 400mbar gauge pressure) then medium will flow from the distal reservoir 3220 to the reservoir 3270 .
- FIG. 32 C illustrates use of the earplug 3200 in an ear.
- FIG. 33 illustrates another non-limiting example of an embodiment.
- the earplug 3300 is a foam plug with a reservoir and a finger tab 3310 to hold.
- a user squeezes C1 the foam to a smaller insertion form, which is inserted D1 into the ear canal 3320 .
- the reservoir can include a fluid foam medium, which can be compressed (for example where the gas bubbles get smaller upon compression), thus increasing the pressure of the inserted reservoir.
- FIGS. 34 A, 34 B, and 34 C illustrate the configuration and operation of at least one exemplary embodiment.
- the earplug 3400 includes a reservoir 3470 , a moveable element 3460 with a distal end 3420 , a safety flange 3450 , a valve 3440 , a fluid channel 3430 , a distal end reservoir 3430 and at least one contact 3245 .
- the safety flange 3450 can additionally include a flange reservoir.
- FIG. 34 B illustrates the operation the earplug 3400 , where the reservoir 3470 is constricted by moving E1 (squeezing) the moveable element 3460 forcing a portion of the medium through the valve 3440 into a distal end reservoir 3431 and optionally a safety flange reservoir.
- FIG. 34 C illustrates use of the earplug 3400 in an ear.
- FIGS. 35 A, 35 B, 35 C, and 36 illustrate the configuration and operation of at least one exemplary embodiment.
- FIG. 35 A illustrates a non-limiting example of an earplug embodiment 3500 , including a deformable casing 3510 (e.g. foam), encircling a reservoir 3520 , a valve 3540 , a flexible distal end 3535 , and optionally a flange 3530 .
- a deformable casing 3510 e.g. foam
- 35 B illustrates the operation of the earplug 3500 , where depression G1 of the deformable casing 3510 constricts the reservoir 3520 forcing a portion of the medium past the valve into the flexible distal end 3535 (e.g., a balloon on a shaft, a flexible shaft with varying thickness) expanding H1 the flexible distal end 3535 .
- the expansion of the flexible distal end 3535 can expand the flange 3531 .
- a release mechanism can be included for a user to squeeze open a flexible valve, allowing passage of the medium from the flexible distal end 3535 back to the reservoir 3520 .
- FIG. 35 C illustrates an incorporated release mechanism that when pressed M1, effectively presses N1 on the flexible valve opening the valve for backflow.
- FIG. 36 illustrates use of the earplug 3500 in an ear.
- FIG. 37 and FIG. 38 illustrates an embodiment used in a helmet 3700 (e.g.
- liners 3710 and 3720 for use on aircraft carriers or other noisy environments
- liners 3710 and 3720 each can include different fluid mediums to shape the acoustic profiles entering the helmet 3700 .
- FIGS. 39 - 40 illustrates various flexible distal ends developed by Innovation Labs and Dr. Keady, while FIG. 41 illustrates a novel distal end spiral feed system which enhances uniform expansion about a stent 3910 .
- the tip 4000 can include an acoustic port or be sealed.
- the expandable membrane 3900 expands and is attached by stent 3910 .
- FIGS. 42 - 44 J illustrates multiple examples of embodiments for earplugs, hearing aids, and earpieces.
- FIG. 42 illustrates an earplug 4200 including a stent 4210 and an inflation element 4220 .
- the inflation element can be formed as a single unit 4230 .
- FIG. 43 illustrates the system of FIG. 40 .
- FIG. 44 A illustrates an earplug/hearing aid 4400 having an ambient microphone 4410 , a body 4420 that serves also as a depth control flange, inflation tubes 4430 (feed tubes) a one way vent 4440 (e.g. valve), receiver/microphone 4460 , and wires 4450 .
- FIG. 44 A illustrates an earplug/hearing aid 4400 having an ambient microphone 4410 , a body 4420 that serves also as a depth control flange, inflation tubes 4430 (feed tubes) a one way vent 4440 (e.g. valve), receiver/microphone 4460 , and wires 4450 .
- FIG. 44 B illustrates an embodiment of an earplug/hearing aid 4500 , including inflation tubes 4530 , depth control flange 4520 , inflation element 4540 , tab 4560 , interlocking mechanism 4570 , batteries 4510 , where a user that presses inward, A to B, forces fluid into the inflation element 4540 expanding teh inflation element 4540 from C to D.
- FIG. 44 C illustrates an embodiment of an earplug/hearing aid 4600 , including an inflation tube 4610 , a button 4680 pressing the batteries 4670 , where a user can press the button 4680 engaging the battery 4670 to supply voltage to electrodes 4640 .
- FIG. 44 D illustrates an earplug 4700 including an interlocking mechanism 4710where when a user moves a tab from position A1 to B1 moves fluid in a reservoir, from A3 to B3, into an inflation element 4720 expanding the inflation element from A2 to B2.
- FIGS. 44 E, 44 F, 44 G and 44 H illustrate ferrofluid and/or electro fluid earplug/hearing aid systems.
- FIGS. 44 E and 44 F include ambient microphones 4860 , 4930 , each having a microphone ports 4870 and 4940 .
- FIGS. 44 E and 44 F additionally include coils 4810 , 4950 , which can be used to change local magnetic fields, ferrofluid 4820 , 4920 , and in the case of earplug/hearing aid 4800 an opposing coil 4840 .
- the ferrofluid can react to the magnetic fields moving into and way from the inflation elements 4830 , expanding them.
- FIG. 44 G illustrates a ferrofluid system 5000 with ferrofluid 5010 in isolated chambers in a flange 5010 where a coil 5030 changes the local magnetic field collapsing or releasing the flange 5010 .
- the earplug system 5100 illustrated in FIG. 44 H includes a restoring membrane 5120 that when expanded 5121 exerts a restoring force attempting to impose the attraction of the ferrofluid responding to an increased magnetic field (e.g., moving from K to L).
- an increased magnetic field e.g., moving from K to L.
- the restoring membrane forces the ferrofluid into the inflation element expanding it from 5151 to 5150 .
- FIGS. 44 I and 44 J illustrate the same system using a push button 5220 to engage the battery 5210 with the magnetic coil 5230 increasing the current and applying a magnetic field which attracts the ferrofluid from the tip to the restoring membrane region expanding the restoring membrane 5240 B.
- Additional exemplary embodiments use a field responsive fluids (e.g., Electric and Magnetic Fluid Technology: Any device portion that includes ferrofluids, magnetorheological fluids, and Electro-rheological fluids/electric field responsive fluids.
- a field responsive fluids e.g., Electric and Magnetic Fluid Technology: Any device portion that includes ferrofluids, magnetorheological fluids, and Electro-rheological fluids/electric field responsive fluids.
- one exemplary embodiment uses a magnetic generator (e.g., coil) to control FerroFluid in an earpiece to move from one point of the earpiece to another, and/or to change the attenuation characteristics of the earpiece.
- At least one exemplary embodiment uses an ER fluid to change the attenuation properties via the application of an electric field. For example for an earpiece if the insertion depth control flange contains an ER fluid the viscosity of the fluid can be changed by applying an electric field across the flange changing the characteristics of the flange.
- At least one exemplary embodiment also use a combination ER and FF fluid by mixing them so that a magnetic field can be used to move the fluid while an electric field can be used to gellify the fluid.
- At least one embodiment is directed to using acoustic (e.g., earphone), haptic, and visual indicators to notify persons of a harmful environment, and is even control vehicles so as to decrease danger to items and persons.
- FIG. 45 illustrates a sample work environment
- FIG. 46 illustrates a sample of the computer display equivalent of the work environment of FIG. 45 .
- Notification can take the form of various devices and methods (acoustic, haptic, visual, thermal, and combinations of such).
- Exemplary embodiments are directed to or can be operatively used on various devices, helmets, safety glasses, watches, belt buckles, passive earplugs for hearing protection or electronic wired or wireless devices (e.g., hearing aids, ear monitors, earbuds, headphones, ear terminal, behind the ear devices or other acoustic devices as known by one of ordinary skill, and equivalents) or any other device attached to the body.
- an ambient microphone can measure the ambient sound pressure levels a user is exposed to and when the exposure level reaches a threshold level (e.g., 90% of daily recommended exposure) a tactile notification device can be activated to notify the user, alone or in combination with another notification device (e.g., visual LEDs).
- a threshold level e.g. 90% of daily recommended exposure
- another notification device e.g., visual LEDs
- the non limiting embodiment discussed below is directed to a personal noise exposure monitoring system, however any notification system where a tactile/acoustic/visual notification can be used is within the scope of the invention.
- the system will not only log noise exposures but also provide immediate warning to the worker about then-current, potentially hazardous noise exposures, as well as secondary relevant information so that the worker will know more details about his exposure level and dose, and can make informed decisions to protect themselves. This is important because noises in workplaces are often not constant nor are the noise sources stationary, so workers need to be aware of changing environments and concomitant exposure levels due to either their moving around or variations in equipment/process emissions or movements.
- the head-mounted system can both warning and informational displays for the worker, the worker who works in an environment where noise exposure levels vary will be able to determine when and where he/she needs to wear hearing protection devices or take other preventative action.
- dosimeters are not designed to provide instantaneous noise information to a user; rather they are designed to prevent tampering of the settings and the data; this feature thus obviates a worker from gaining real-time information about surrounding noise. Even those dosimeters that are designed to display data to the workers directly are designed with on-unit visual displays that require the worker to turn their head and intentionally look for information, which is not always in a readily-understandable form, and is certainly not designed to warn the worker of imminent hazard potential.
- the current dosimeter designs are acceptable to measure noise exposure of a worker in a work-shift and record them for later analysis and comparison to some action or criterion levels, such as those promulgated by OSHA or the military.
- the proposed personal noise exposure monitoring system will be able to provide real-time noise hazard information to the workers via multi-modal displays that will draw the worker’s immediate attention by redundant sensory modalities (visual and tactile senses) to provide the proper levels of information to first warn, and next to inform about the hazard in more detail and offer preventative advice.
- redundant sensory modalities visual and tactile senses
- People tend to respond faster and quickly to multi-modal displays than to a uni-modal display.
- the redundancy of multi-modal displays also provides more resistance to masking or interference effects that may cause one of the modalities to be missed, and provides a backup warning path in the event of one modality’s failure.
- Various thresholds can be set.
- the OSHA regulation (1983) for noise exposure allows a time-weighted average (TWA) exposure of 90 dBA (100% dose) for an 8-hour work shift as the criterion level, but hearing conservation programs are required when the TWA is at 85 dBA (50% dose) and above, which is the action level.
- TWA time-weighted average
- NIOSH (2012) recommends 85 dBA TWA for an 8-hour work shift as the criterion level or 100% dose.
- different agencies and branches of the U.S. military recommend different exchange rates for dosage calculation as well.
- Various displays can be tailored for different work conditions and can the type and form of tactile notificator.
- display formats for the head-up visual display could be colored LED lights with varying colors, using standards of green, yellow, and red, and/or blinking patterns, alphanumeric displays with different languages, or visual icons.
- the tactile displays can be parameterized with varying intensity, pulse rates, and/or vibration patterns. Characteristics of cultural subgroups can aid in designing multi-modal displays rendering them cross-cultural in effectiveness. Identification of such characteristics can be used in notification systems aiding in enhanced user acceptance.
- At least one embodiment includes a quickly-responding scheme for alerting workers of their immediate noise exposure.
- the scheme takes into account workplace noise exposure characteristics so that the alert timing can be beneficial or early enough so that workers can take preventive actions.
- At least one embodiment can use multi-modal displays, where multiple methods of notification can be used, for example a visual display and/or tactile display.
- Visual display can be subdivided into two levels: 1 st level visual display can be colored LED lights that can be used to alert the worker to capture immediate attention to noise hazard; 2 nd level visual display can be an alphanumeric display that can display detailed information such as current sound level, cumulative exposure dosage, and expected time to maximum dose at current sound level or cumulative sound exposure.
- the tactile display transducing small vibrations to the user’s body (e.g., head) via tiny vibrotactors (e.g., mounted on eyeglass temples or in a hardhat headband), can be a complimentary or redundant warning avenue to the 1 st level visual display to command attention.
- Another possibility of tactile display is conveying directionality of noise if the noise requires the worker to localize the sound and react to it in certain way. Localization of a backup alarm could be such an example, because hearing and heeding a backup alarm in noise is a significant safety problem in industry (Alali & Casali, 2011).
- At least one embodiment can consist of multi-modal displays and a selected, modified dosimeter. Additional embodiments can be coupled with safety glasses and other devices such as a safety helmet (hardhat). As most noise hazard information is available from currently available dosimeters, existing, off-the-shelf dosimeter can interact with our multimodal displays of at least one embodiment.
- a first embodiment add multimodal or tactile displays to safety glasses.
- Safety glasses will provide a convenient mounting opportunity on the rim of the eyeglass lense plane, or at the hinge of the temple piece, to display colored LED lights that will alert the workers with varying noise hazard information.
- a small vibration transducer i.e., vibrotactile device
- the worker will be alerted when there are significant changes to his/her noise environment, or present or imminent hazards, via both colored lights and vibration.
- Example of such changes can include a sudden increase of noise level that exceeds the allowable limits of either continuous noise (115 dBA rms) or impulse noise (140 dB peak). Cumulative noise dosage at a preset limit for warning activation can be another reason for alerting the worker.
- a separate alphanumeric display (“head-down” style) can be attached to the dosimeter itself, to display detailed noise hazard information when necessary. Simple pushbuttons can allow the workers to navigate the system and retrieve the necessary information, which can include dBA level and dose data, as well as corresponding preventative measure information which will guide the worker.
- a second can be integrated with safety hardhats instead of safety glasses.
- Hardhats will allow several positions to mount both the visual LED display, such as on the underside of the brim, as well as the vibration transducers, which can be headband-mounted.
- a noise source such as a backup alarm for a vehicle, increasing safety in dynamic workplaces where those alarms may be masked by the noise.
- the safety glasses, goggle, face shield can include several multi modal notification systems, for example visual (e.g., LED, color lights, varying light frequency and/or intensity in time), haptic (e.g., surface pressure variations, vibration motors, varying vibration frequency and/or intensity in time), audio (e.g., alarms, audio frequency and/or intensity variations in time), and temperature (e.g., variations in temperature amplitude in time).
- visual e.g., LED, color lights, varying light frequency and/or intensity in time
- haptic e.g., surface pressure variations, vibration motors, varying vibration frequency and/or intensity in time
- audio e.g., alarms, audio frequency and/or intensity variations in time
- temperature e.g., variations in temperature amplitude in time
- a haptic indicator can also be used in accordance with at least one embodiment.
- a vibrator motor e.g., adafruit’s vibrating mini motor disc product ID 1201, 1.5 V 20 mA Micro Pager Motor
- the haptic indicator can be mounted where a user will most notice.
- the haptic intensity can be varied to provide information on location of danger.
- a helmet with various haptic indicators can vary which haptic indicator is activated depending upon the location of the hazard.
- a non-limiting example of a dosimeter for example 3MTM NoisePro Kit NP-DLX, which can be fitted onto a belt.
- FIGS. 45 - 46 illustrate a vehicle and a worker in a dangerous work environment and a notification system of at least one embodiment.
- Sensors e.g., dosimeter, transducers
- a monitoring system e.g., a computer
- the monitoring system keeps track of the location and movement of hazards in the work environment, predicts future potential hazards (e.g., using Kalman Filters to predict location) and sends notification signals to both vehicle operators and workers.
- the notification signals can activate alarms and can even deactivate vehicles if needed.
- the notification signals can take various forms , for example they can be audio (tones, vocal, acoustic icons such as sounds similar to the hazard or recognized as having a particular meaning) haptic, visual, and/or a combination of these.
- FIG. 46 illustrates a computer monitoring system coupled with personal notification systems in accordance with at least one embodiment.
- the monitoring system for example including a processor, can model the work environment 6200 (e.g., using simulation agents (e.g., 6131-W1, and 6133-W2) to model the workers, C, C++, MatLabTM).
- the montoring system can then send signals wirelessly or wired to any object in the work environment that has a receiver.
- the received signal can be used by a processor to activate an alarm on any object.
- the processor can control the object to minimize the hazard.
- the monitoring system can control vehicles in the work environment, for example slowing them down upon calculation of imminent harm (e.g., a few seconds prior to impact) to a worker. For example if a worker is too close to a vehicle backing up the processor can send a signal to slow the vehicle down.
- FIG. 45 illustrates a work environment and an equivalent model.
- the work environment 6000 can include vehicles ( 6001 , 6003 , 6005 , 6007 ) and workers ( 6011 , 6013 ).
- a computer can model 6200 the environment 6000 , where vehicles are illustrated as symbols ( 6121 , 6123 , 6125 , 6127 ) and workers are also illustrated as symbols ( 6131 , 6133 ), such as flow chart shapes, letters abstract forms.
- Regions around workers can be set ( 6151 , 6161 , 6171 , 6181 ) so that when vehicles enter certain regions signals can be sent, for example signals can be sent to the workers so that audio, visual, and/or haptic warnings are played.
- the radii can vary as the movement various of the various vehicles and movement of the workers.
- Each vehicle and/or worker can contain a transmitter, receiver and a processor (e.g., for a worker their cell phone) attached to a notification device or with the ability to interface with a worker’s headgear (e.g., hearing protector, earphones) or the vehicle itself (e.g., via the vehicles display and/or speakers).
- a message could be send to the display of a vehicle presenting a warning that a worker is close.
- FIG. 47 illustrates an embodiment of an earphone/earplug 7010 .
- the earplug/earphone can include and acoustic channel if sound is to be played through the stent 7400 .
- the membrane 7500 at the distal end can be expanded when tabs 7000 are released (e.g. unpinched).
- the tabs 7000 can be connected by a resilient connector 7100 , which tend to restore the tabs to a position B when released.
- the membrane can be a flexible material, such as a silicon base, or fixed volume such as a urethane, although any material that can be used for inflatables both medical and lower grade can be used.
- FIGS. 48 A and 48 B illustrate a membrane eartip.
- the eartips can be sealed after formation, for example via injection molding with a gap, then sealed afterwards, or 3-D printed as sealed.
- the medium encompassed by the eartip can be injected prior to sealing or after sealing (e.g., hypodermic needle, and subsequent sealing epoxy).
- the eartips can be fabricated with various material varying from 10-120 durometer. Silicone, urethane, rubber, or other flexible polymers and materials can be used in addition to materials currently used in eartips as known by one of ordinary skill in the art. In at least one embodiment of the eartip has various portions with different thicknesses.
- region I the portion of the eartip that enters the ear canal first can be of a different thickness (t1) than region III (t3), for example region III can be thicker, Region II can also be of different thickness (t2).
- the thickness of region I can be thicker than region II, so that when region I is compressed, region II can expand in response (A), while region III can expand less.
- the expansion of region II creates a restoring force creating pressure in region I pressing against the ear canal wall facilitating sealing.
- the thickness can vary between a fraction of a mm to several mms.
- the medium in the eartips and the materials forming the structure ( 7600 , 7700 ) can be the same type of material as in the earphone/earplug of FIG. 47 .
- the various thicknesses can be chosen so that region II expands (Region II-A), providing an opposite restoring force, when region I is compressed (Region I-A).
- the eartip can be fabricated by various means, for example injection molding, then sealed with various filler mediums (e.g. gas, liquid, gell), and inserted upon a stent 7700 , for example the eartip 7600 can have an extension portion that slides over the stent 7700 .
- various filler mediums e.g. gas, liquid, gell
- valve versions are mostly closed, entrapped fluid designs, air or liquid, although the valve versions can accommodate open system designs as well. Although they may be open until compressed, for example upon insertion into an ear canal or other opening, then an enclosed chamber, cavity can be created.
- FIGS. 49 - 53 are three sample versions. That operate on a principle of a first member pressing against a reservoir (states Y, K, L), where the fluid in the reservoir has been pressed into an expandable tip. In the initial state, the first member presses against the reservoir, filling a small expandable tip.
- a second member is engaged, moving the first member away from the reservoir (states X, J), or a method of releasing any pressure, for example pressing on a flexible valve (M).
- the reservoir can be attached to the member so that as the first member (e.g., 8040 , 8130 , 8250 ) is moved (e.g., X, M, J) , the reservoir (e.g., 8011 , 8140 , 8311 ) re-expands, serving to empty the expandable tip (e.g., 8010 , 8110 , 8210 ).
- Another version uses the restoring elastic force from the bladder in the expandable tip (e.g., 8010 , 8110 , 8210 ) to refill the reservoir when the first member is released.
- second member 8040 attached to a first member 8050 , is pinched with respect to rigid member 8030 , moving first member 8050 away from tip 8010 .
- FIG. 49 shows a fingertip-operated pinching mechanism to engage the second member
- FIGS. 50 - 51 utilizes a lanyard control system, wherein the lanyard bladder 8140 is pressed to inflate the expandable tip, while pressing 8130 opens a valve, thereby releasing the fluid and collapsing the expandable tip 8110 .
- Each of these versions is constructed to minimize complicated valving; for example, versions I ( 8000 ) and II ( 8200 , 8300 ) do not contain valves, while version III ( 8100 ) includes a collapsible flexible valve, which inventors have used in many prototypes, the valves of which are readily available.
- the reservoir is attached to the expandable tip via very small channels similar to Microphone-in-Real-Ear (MIRE) probe test tubes.
- MIRE Microphone-in-Real-Ear
- the versions can be fabricated so that the tip is removable, requiring a flexible valve which is opened when a small pen tip-sized tube coupler is pressed into the opening at the base of the removable tip, but closed otherwise so that tip removal is possible.
- members such as 8030 , 8040 , 8050 , 8250 , 8240 can be made of semi rigid plastic or any other type of semi-rigid material that has been used in earphones.
- the resilient members such as 8020 , 8230 providing a restoring force can be made of flexible polymers, rubbers, silicones and similar elastic property materials.
- the expandable tips 8010 , 8110 , 8210 can be made of high elastic materials, for example where the material can be stretched to over 100% of its resting length.
- FIGS. 54 A- 55 An example of a relatively simple semi-pneumatic eartip is shown in FIGS. 54 A- 55 .
- the material for this semi-pneumatic design will be an elastomer, which will be parameter-specified as to Young’s modulus of elasticity, nonlinear stress-strain curve, and other relevant metrics.
- the notes on FIGS. 54 A- 55 generally depict the operation, but a brief explanation may be helpful.
- the earphone nozzle is pushed gently forward to act as a “plunger” to “stretch” the elastic membrane longitudinally, rendering it just slightly larger in diameter than the nozzle for ease of insertion into the ear canal.
- the “plunger” is retracted by the elastic spring’s restoring force inherent in the membrane material (essentially, this occurs coincident with the user’s fingers releasing of the earphone housing).
- the membrane material returns to its at-rest bulged state, thus expanding into a bulge or donut-shape around the earphone’s nozzle, providing a seal against the ear canal walls.
- the design will be comprised of a “shape-memory” elastic polymer (elastomer), and in view of the small longitudinal dimensional change necessary between its at-rest and stretched states, the dimensional operating range can easily be maintained well-within the elastomer’s elastic limit.
- Material with fairly low hardness, on the order of 30-60 Shore A durometer, will likely be used to enable the “bulge” to conform to irregularities of the individual ear canals it may encounter in practice. It is important to note that the air inside the membrane is not sealed within it, but shared with the outside air through the nozzle and the earphone ports.
- FIG. 54 A illustrates the elongation state of a pull ring configuration.
- Housing 5400 FIG. 54 B , e.g. QC-20
- a pre-shaped elastic membrane 5440 can fit around the stent of housing 5400 and elongated (X) during insertion.
- An open ended cup 5430 can be inserted to retain the membrane 5440 .
- Elongation can occur by pulling ring 5410 .
- the elasticity of the membrane 5440 returns the membrane back to the resting state (e.g., FIG. 55 ) and the original shape (Y) prior to elongation.
- the tab stop 5420 prevents the membrane 5440 from moving beyond a certain position.
- FIG. 56 is an illustration of an ear device 9000 prior to insertion into an ear canal 9002 of an ear in accordance with an example embodiment.
- a section of ear device 9000 is cutaway to provide detail of internal features. In one embodiment, the section of ear device 9000 that is cutaway is substantially equal to what is shown and disclosed herein.
- Ear device 9000 can comprise the same materials disclosed herein above for the ear tips, inflatable ear sealing structures, ear plugs, and other orifice devices to seal ear canal 9002 .
- Ear device 9000 is illustrated outside an auricle 9004 of the ear. In general, ear device 9000 is configured to occlude or partially occlude ear canal 9002 .
- Ear device 9000 comprises a stent 9006 , a first folding member 9010 , a second folding member 9012 , and a stop flange 9008 .
- stent 9006 is a tube or conduit having a proximal opening 9014 and a distal opening 9016 .
- Stent 9006 is not limited to a single tube but can comprise a structure having one or more tubes or pathways. Stent 9006 can also made solid or having one or both openings plugged such that no pathway through stent 9006 exists.
- stent 9006 is cylindrical in shape and flexible to conform to a torturous shape of ear canal 9002 .
- Distal opening 9016 is exposed to ear canal 9002 when ear device 9000 is inserted in ear canal 9002 .
- stent 9006 is configured to bend after insertion to maintain an un-impeded path from proximal opening 9014 to distal opening 9016 .
- Proximal opening 9014 as shown is exposed to an external environment outside the ear.
- ear device 9000 is an ear plug for isolating the ear canal from the external environment
- distal opening 9016 , proximal opening 9014 , or both may be closed off.
- ear device 9000 can provide the controlled delivery of acoustic information to ear canal 9002 .
- acoustic information can be provided by a transducer coupled to proximal opening 9014 of stent 9006 .
- a transducer can be coupled to deliver acoustic information through stent 9006 to ear canal 9002 .
- a microphone can be coupled to proximal opening 9014 of stent 9006 to retrieve acoustic information that is within ear canal 9002 for processing or delivery to an electronic device.
- Optional stop flange 9008 limits a distance that ear device 9000 can be inserted into ear canal 9002 .
- stop flange 9008 is formed circumferentially around stent 9006 .
- Stop flange 9008 has a diameter greater than ear canal 9002 .
- the size of stop flange 9008 prevents insertion in ear canal 9002 .
- the size and shape of stop flange 9008 can stabilize and hold ear device 9000 to the ear to prevent ear device 9000 from working itself out of ear canal 9002 due to normal activity.
- Stop flange 9008 blocks sound from the external environment from entering ear canal 9002 . Sound will reflect off stop flange 9008 and return to the external environment.
- stent 9006 extends proximally beyond stop flange 9008 . It should be noted that stent 9006 can couple to or be formed integrally with a housing.
- the housing can include electronic circuitry and one or more sensors to support ear device 9000 .
- the electronic circuitry can be used to process acoustic signals, reduce noise, cancel noise, amplify a signal, moderate the amount of acoustical information the ear canal receives, or perform other functions related to the ear or the user.
- ear canal 9002 is occluded or partially occluded by a chamber 9018 .
- Chamber 9018 is sealed to support attenuation of noise in the external environment from reaching ear canal 9002 .
- Ear device 9000 comprises a first folding member 9010 and a second folding member 9012 .
- First folding member 9010 couples to stent 9006 .
- Second folding member 9012 also couples to stent 9006 .
- first folding member 9010 couples to stent 9006 distal to a location where second folding member 9010 couples to stent 9006 .
- First folding member 9010 and second folding member 9012 form chamber 9018 that isolates stent 9006 from walls of ear canal 9002 .
- chamber 9018 is formed circumferentially around a portion of stent 9006 that is configured to be within ear canal 9002 .
- Chamber 9018 is open to the external environment prior to ear device 9000 being inserted into ear canal 9002 .
- Chamber 9018 has a diameter larger than ear canal 9002 .
- a ring valve 9020 when open couples chamber 9018 to the external environment.
- ring valve 9020 has an opening that extends 360 degrees around stent 9006 .
- Ring valve 9020 is open when ear device 9000 is outside the ear canal. Ring valve 9020 can also open and close during insertion of ear device 9000 in ear canal 9002 . This will be discussed in more detail herein below.
- ring valve 9020 opens, a pressure within chamber 9018 will equalize to be the same as the pressure in the external environment.
- stent 9006 is cylindrical in shape.
- First folding member 9010 couples 360 degrees around stent 9006 and is located in proximity to distal opening 9016 .
- first folding member 9010 can couple to stent 9006 between a distal end of stent 9006 and distal to a location where second folding member 9012 couples to stent 9006 .
- First folding member 9010 extends proximally and overlies a portion of a surface 9022 of stent 9006 .
- first folding member 9010 has a maximum diameter or cross-sectional width that is greater than ear canal 9002 .
- Second folding member 9012 couples to stent 9006 distal to stop flange 9008 .
- Second folding member 9012 extends distally and overlies a portion of surface 9022 of stent 9006 .
- second folding member 9012 can have a maximum diameter or cross-sectional width greater than ear canal 9002 .
- the maximum diameter or the cross-sectional width of second folding member 9012 can have a width less than ear canal 9002 .
- second folding member 9012 can extend proximally and overlie a portion of surface 9022 of stent 9006 . This will be disclosed in further detail herein below.
- First folding member 9010 overlies at least a portion of second folding member 9012 whether second folding member 9012 extends distally or proximally.
- FIG. 57 is a cutaway view of ear device 9000 in accordance with an example embodiment.
- the cutaway view provides detail of features within ear device 9000 that cannot be seen from an external view.
- the structure that is cutaway in ear device 9000 is substantially equal to what is shown.
- Ear device 9000 comprises stent 9006 , chamber 9018 , and stop flange 9008 .
- Ear device 9000 includes stent 9006 having a proximal opening 9014 and a distal opening 9016 .
- Distal opening 9016 couples to an ear canal when ear device 9000 is inserted into the ear canal.
- proximal opening 9014 couples to an external environment outside the ear as shown.
- ear device 9000 can be used as an ear plug to isolate the ear canal from noise in the external environment.
- Chamber 9018 is configured to occlude or partially occlude the ear canal. Maximum attenuation occurs when chamber 9018 is a sealed volume within the ear canal.
- chamber 9018 is formed around stent 9006 such that stent 9006 is centered within the ear canal when ear device 9006 is inserted in the ear canal.
- Proximal opening 9014 , distal opening 9016 or both can be plugged to prevent a path to the ear canal via stent 9006 thereby occluding the ear canal.
- Sealing of stent 9006 can comprise a cover on proximal opening 9014 , distal opening 9016 , or both.
- stent 9006 can include a valve to equalize pressure between the external environment and the ear canal to support comfort of ear device 9000 .
- one or more lumens can be coupled through stent 9006 .
- Proximal opening 9014 can be sealed around the one or more lumens or couple to a sealed structure.
- Stent 9006 acts a conduit for the one or more lumens.
- the one or more lumens can be used to couple one or more devices to the ear canal.
- stent 9006 and the one or more lumens couple to a structure that is outside the ear.
- the structure can house electronic circuitry (e.g., processor, microphones, speakers, infrared sensors, oxygen sensors, bio sensors, pressure sensors, humidity sensors) other sensing devices.
- the structure is sealed and insulated from the external environment such that stent 9006 , chamber 9018 , and the structure prevent or reduce noise from the external environment from entering the ear canal. Sealing the ear canal from the external environment reduces noise levels within the ear canal and allows information to be provided to the ear canal in a controlled manner that can be heard even if the noise level in the external environment is high.
- a first end of a first lumen can be coupled to a transducer.
- a second end of the lumen can couple to the ear canal through distal opening 9016 of ear device 9000 .
- the transducer can deliver acoustic information to the lumen which is then delivered to the ear canal. Examples of the acoustic information could be voice, music, or ambient sounds from the external environment. The delivery of the acoustic information can be provided in conjunction with the noise attenuation provided by ear device 9000 .
- a first end of a second lumen can be coupled to a microphone.
- the second lumen then couples through stent 9006 such that the second end of the second lumen is exposed to the ear canal at the distal opening 9016 of ear device 9000 .
- the second lumen couples sound within the ear canal to the microphone where it is converted to an electronic signal. This is useful for delivering a user’s voice for transmission to a device such as a cell phone. For example, if the user of ear device 9000 is speaking, the sound of his or her voice can be picked in the ear canal.
- the second lumen couples to the ear canal through distal opening 9016 and delivers acoustic information within the ear canal to the microphone.
- the voice received from the ear canal can be more intelligible than a voice picked up with an ambient microphone in a noisy external environment.
- the ambient microphone would pick up the user’s voice but also the noise in the external environment. Noise from the external environment is attenuated in the ear canal by chamber 9018 of ear device 9000 .
- the user’s voice can be transmitted with less background noise thereby increasing the clarity and intelligibility of the voice transmission.
- stent 9006 can be used to deliver acoustic information instead of using lumens.
- more than one stent could be formed where stent 9006 is located thereby providing a plurality of channels from the ear canal to the external environment. In the example above, a first stent would couple to the transducer and a second stent would couple to the microphone.
- Ear device 9000 can be molded, machined, formed, or printed.
- ear device 9000 comprises a flexible material that will conform to the torturous shape of an ear canal.
- ear device 9000 comprises a bio-compatible material configured for insertion in the ear canal.
- ear device 9000 is formed from silicone.
- Stop flange 9008 limits the depth of insertion of ear device 9000 into the ear canal.
- stent 9006 extends proximally beyond stop flange 9008 .
- a chamber 9018 is formed around stent 9006 .
- Chamber 9018 comprises a first folding member 9010 and a second folding member 9012 .
- Chamber 9018 is configured to occlude or partially occlude the ear canal when ear device 9000 is inserted.
- chamber 9018 centers stent 9006 within the ear canal.
- ear device 9000 is made flexible to allow stent 9006 and chamber 9018 to bend with and around curves of the ear canal.
- Chamber 9018 of ear device 9000 comprises a first folding member 9010 and a second folding member 9012 . At least a portion of first folding member 9010 overlies a portion of second folding member 9012 .
- a ring valve 9020 is formed by first folding member 9010 and second folding member 9012 . More specifically, ring valve 9020 is a ring-shaped opening formed by a portion of first folding member 9010 that overlies a portion of second folding member 9012 .
- ring valve 9020 couples the external environment to chamber 9018 .
- ring valve 9020 has an opening formed between first folding member 9010 and second folding member 9012 . More specifically, the opening of ring valve 9020 is in a region where first folding member 9010 overlies second folding member 9012 .
- ring valve 9020 is formed 360 degrees around stent 9006 .
- Chamber 9018 couples to the external environment since ring valve 9020 is normally open when ear device 9000 is outside the ear canal. Chamber 9018 cannot be sealed unless first folding member 9010 couples to second folding member 9012 around the entirety of stent 9006 . Sealing of chamber 9018 can also occur by first folding member 9010 coupling to a combination of second folding member 9012 and a surface of stent 9006 .
- chamber 9018 is filled with gases from an external environment.
- chamber 9018 will be at the same pressure as the external environment due to ring valve 9020 being open prior to insertion to the ear canal.
- a sealed chamber 9018 provides improved noise isolation between the external environment and the ear canal.
- Chamber 9018 can be filled with a material to further improve noise isolation or attenuation.
- chamber 9018 can be filled with a foam, a gel, or a liquid.
- the material within chamber 9018 can be compressible to support a wide range of volumes that can occur due to different ear canal diameters.
- stent 9006 is cylindrical in shape.
- First folding member 9010 has an anchor point 9046 that is distal to an anchor point 9044 of second folding member 9012 .
- anchor point 9046 is located near distal opening 9016 of stent 9006 .
- Anchor point 9046 is anchored 360 degrees around stent 9006 .
- anchor point 9046 is a pivot point.
- a force applied to first folding member 9010 by a wall of the ear canal will move first folding member 9010 towards stent 9006 pivoting at anchor point 9046 .
- the force will move first folding member 9010 to couple to the second folding member 9012 thereby sealing chamber 9018 .
- First folding member 9010 comprises a vertical component and a horizontal component.
- first folding member 9010 suspends first folding member 9010 above second folding member 9012 and stent 9006 .
- the horizontal component of first folding member 9010 extends first folding member 9010 to the first predetermined proximal location.
- First folding member 9010 terminates having a proximal end 9036 that overlies second folding member 9012 or stent 9006 .
- the horizontal and vertical components of first folding member 9010 can be combined such that first folding member 9010 is changing horizontally and vertically towards the first predetermined proximal location.
- first folding member 9010 can have a curved shape. The curved shape supports insertion in the ear canal and minimizes long-term discomfort.
- first folding member 9010 can minimize the surface area of first folding member 9010 coupling to the wall of the ear canal.
- an external surface of first folding member 9010 is configured to conform to the shape of the ear canal as ear device 9000 is inserted in the ear canal. The walls of the ear canal applies a pressure 360 degrees around first folding member 9010 during insertion.
- the curved shape of first folding member 9010 also supports coupling to second folding member 9012 to seal chamber 9018 .
- second folding member 9012 will have a curved shape that corresponds to or is similar to the curved shape of first folding member 9010 to support coupling and sealing of chamber 9018 .
- first folding member 9010 is more than a hemisphere in shape but less than a full sphere. In one embodiment, first folding member 9010 will have a diameter maximum or a distance maximum from stent 9006 that is between anchor point 9046 and the proximal end of first folding member 9010 . In one embodiment, an angle 9030 is formed between stent 9006 and first folding member 9010 . Angle 9030 supports insertion into the ear canal. Angle 9030 is typically less than 90 degrees when ear device 9000 is outside the ear. In one embodiment, angle 9030 is 60 degrees or less when ear device 9000 is outside the ear.
- stent 9006 is cylindrical in shape.
- Second folding member 9012 has an anchor point 9044 that is proximal to an anchor point 9046 of first folding member 9010 .
- anchor point 9044 is located near stop flange 9008 of ear device 9000 .
- Anchor point 9044 is anchored 360 degrees around stent 9006 .
- anchor point 9044 is a pivot point.
- second folding member 9012 extends from anchor point 9044 distally such that second folding member 9012 overlies a portion of stent 9006 between anchor point 9044 of second folding member 9012 and anchor point 9046 of first folding member 9010 .
- second folding member 9012 can extend from anchor point 9044 proximally such that second folding member 9012 overlies a portion of stent 9006 between anchor point 9044 of second folding member 9012 and stop flange 9008 .
- First folding member 9010 overlies a portion of second folding member 9012 whether extending distally or proximally over stent 9006 .
- Second folding member 9012 comprises a vertical component and a horizontal component.
- the vertical component of second folding member 9012 suspends second folding member 9012 above stent 9006 .
- the horizontal component of second folding member 9012 extends second folding member 9012 to a predetermined location distally or alternatively a predetermined location proximally overlying stent 9006 .
- the horizontal and vertical components of second folding member 9012 can be combined such that second folding member 9012 is changing horizontally and vertically towards the predetermined location.
- second folding member 9012 forms an angle 9032 with stent 9006 to suspend second folding member 9012 over stent 9006 .
- angle 9032 can be 30 degrees to 150 degrees. In the example, angle 9032 is less than 90 degrees.
- second folding member 9012 can have a curved shape.
- second folding member 9012 can have a curved shape corresponding to the curved shape of first folding member 9010 that overlies second folding member 9012 .
- a force applied to a surface 9038 of second folding member 9012 will produce movement of second folding member 9012 towards stent 9006 .
- second folding member is configured to flex and conform.
- an interior surface 9040 of first folding member 9010 is configured to couple to surface 9038 of second folding member 9012 during insertion of ear device 9000 into the ear canal.
- surface to surface coupling between first folding member 9010 and second folding member 9012 seals chamber 9018 .
- Second folding member 9012 is configured to move towards stent 9006 as a force is applied by first folding member 9010 .
- Second folding member 9012 pivots at anchor point 9044 as second folding member 9012 folds towards stent 9006 .
- FIG. 58 is an illustration of ear device 9000 inserted in ear canal 9002 in accordance with an example embodiment.
- FIG. 58 is a cutaway view of ear device 9000 to illustrate internal structure of ear device 9000 . More specifically the view shows chamber 9018 being sealed and occluding or partially occluding the ear canal. The section of ear device 9000 that is cutaway is substantially equal to the structure shown in the figure.
- First folding member 9010 has a diameter larger than ear canal 9002 . Inserting ear device 9000 into ear canal 9002 applies a force to first folding member 9010 that motivates first folding member to move towards second folding member 9012 . Referring briefly to FIG.
- first folding member 9010 couples to the walls of the ear canal around it’s entirety such that there is no gap between first folding member 9010 and the walls of the ear canal coupling the external environment to the ear canal.
- First folding member 9010 couples to second folding member 9012 to seal chamber 9018 .
- Ear canal 9002 applies a pressure or force 360 degrees around first folding member 9010 .
- surface 9038 of second folding member 9012 couples to surface 9040 of first folding member 9010 .
- surface 9038 of second folding member 9012 couples to surface 9040 of first folding member 9010 , 360 degrees around stent 9006 such that chamber 9018 is sealed when ear device 9000 is inserted in the ear canal.
- Chamber 9018 is not sealed if any portion of surface 9038 of second folding member 9012 does not couple to a corresponding surface 9040 of first folding member 9010 .
- Sealing chamber 9018 provides maximum noise attenuation or ear canal isolation from an external environment. In the example, noise from the external environment is attenuated by stop flange 9008 and chamber 9018 .
- stent 9006 The only other path for noise to couple to ear canal 9002 is through stent 9006 or between first folding member 9010 and the walls of the ear canal. As mentioned previously, any acoustic information coupling through stent 9006 is controlled.
- stent 9006 can be plugged at distal port 9016 , proximal port 9014 , or both.
- stent 9006 can be made solid or filled to prevent the transfer of acoustic information to ear canal 9002 .
- An alternate embodiment for sealing ring valve 9020 has proximal end 9036 of first folding member 9010 coupling to stent 9006 or surface 9038 of second folding member 9012 . Ring valve 9020 would also seal if proximal end 9036 coupled a complete 360 degrees around stent 9006 .
- FIG. 59 is a cutaway view of ear device 9000 without a stop flange in accordance with an example embodiment.
- ear device 9000 is cutaway to illustrate chamber 9018 and ring valve 9020 .
- the structure that is cutaway is substantially equal to the structure of ear device 9000 that is shown in the figure.
- Stop flange is removed to better view ring valve 9020 .
- Ring valve 9020 has an opening that couples into chamber 9018 .
- the opening in ring valve 9020 is a 360-degree slot around stent 9006 .
- the 360 degree slot around stent 9006 appears as a ring shaped opening.
- Chamber 9018 is a volume that is formed around stent 9006 that is defined by first folding member 9010 and second folding member 9012 .
- ring valve 9020 is in an open state such that the external environment is coupled to chamber 9018 .
- Ring valve 9020 is in the open state when a gap occurs anywhere in the 360-degree slot around stent 9006 . The gap couples the external environment to chamber 9018 .
- ring valve 9020 is closed when first folding member 9010 couples to second folding member 9012 whereby chamber 9018 is isolated from the external environment.
- first folding member 9010 forms a 360-degree seal to second folding member 9012 that decouples the ear canal from the external environment by chamber 9018 .
- a double-sided arrow 9050 illustrates a distance from a center of stent 9006 to second folding member 9012 .
- a double-sided arrow 9052 illustrates a distance from a center of stent 9006 to first folding member 9010 .
- a portion of first folding member 9010 overlies a portion of second folding member 9012 .
- First folding member 9010 will couple to second folding member 9012 when the portion of first folding member 9010 overlying the portion of second folding member 9012 is moved from the distance 9052 to the distance 9050 or less.
- stent 9006 is cylindrical in shape.
- second folding member 9012 has a curved shape extending from anchor point 9044 to a distal end 9054 of second folding member 9012 .
- distal end 9054 is circular in shape having a radius equal to the distance of double-sided arrow 9050 .
- first folding member 9010 has a curved shape extending from anchor point 9046 to proximal end 9036 of first folding member 9010 .
- the portion of first folding member 9010 overlying the portion of second folding member 9012 can have a similar rate of curvature to prevent coupling of the first folding member 9010 to second folding member 9012 when ear device 9000 is in a quiescent state (e.g. outside the ear canal).
- the gap between the portion of first folding member 9010 overlying the portion of the second folding member 9012 is approximately constant around stent 9006 .
- FIG. 60 is a cutaway view of an ear device 9000 without a stop flange in accordance with an example embodiment.
- the cutaway view removes a portion of ear device 9000 to illustrate structure that cannot be seen with an external view.
- the portion that is removed is substantially equal to the structure that is shown in the figure.
- the optional stop flange is removed to view ring valve 9020 .
- ear device 9000 can have a stop flange as shown in FIGS. 56 - 58 to limit insertion in an ear canal.
- Ear device 9000 is configured to occlude or partially occlude an ear canal of an ear.
- Chamber 9018 of ear device 9000 is configured to be inserted in the ear canal.
- stent 9006 is a passageway that can be used to deliver acoustic information or receive acoustic information from the ear canal. Stent 9006 can also be used to equalize pressure between the external environment and the ear canal.
- a proximal end of stent 9006 couples to an enclosure that is outside the ear.
- Proximal opening 9014 of stent 9006 is a pathway of stent 9006 to an interior of the enclosure.
- the enclosure can house electronic circuitry, transducers, sensors, valves, a power supply, and other devices (e.g., earphones, hearing aids).
- the enclosure is sealed and insulated such that the external environment is not coupled to the ear canal through stent 9006 .
- Acoustic information can be transferred through stent 9006 itself or stent 9006 can be a conduit to channel one or more lumens or electronics to the ear canal.
- a first and a second lumen can be placed within stent 9006 .
- the distal end of the first lumen is exposed to the ear canal.
- the second lumen is exposed to the ear canal.
- the distal ends of the first and second lumens would be placed at or near distal opening 9016 of ear device 9000 .
- a microphone can be coupled to a proximal end of the first lumen for receiving acoustic information in the ear canal.
- a transducer can be coupled to the proximal end of a second lumen for delivering acoustic information to the ear canal.
- the microphone and transducer would be coupled to electronic circuitry in the housing (coupled to stent 9006 ) or located somewhere outside the ear.
- Chamber 9018 comprises first folding member 9010 and second folding member 9060 .
- First folding member 9010 and second folding member 9060 form ring valve 9070 .
- the orientation of second folding member 9060 differs from second folding member 9012 as disclosed in FIG. 59 .
- Second folding member 9060 performs the same function as second folding member 9012 . In fact, any feature stated herein for second folding member 9012 also applies to second folding member 9060 and vice versa.
- An anchor point 9062 of second folding member 9060 is between anchor point 9046 of first folding member 9010 and the stop flange (not shown).
- Second folding member 9060 extends from anchor point 9062 proximally such that second folding member 9060 overlies stent 9006 .
- a portion of first folding member 9010 overlies a portion of second folding member 9010 .
- second folding member 9060 can be formed having a portion that extends vertically from anchor point 9062 and horizontally above stent 9006 in a proximal direction.
- second folding member 9060 can be formed as a curved structure that changes vertically and horizontally.
- Second folding member 9060 has a proximal end 9064 that terminates before the stop flange (not shown).
- second folding member 9060 is curved to suspend second folding member 9060 above stent 9006 .
- second folding member 9060 forms an angle 9068 with stent 9006 (e.g., line 9069 B).
- Angle 9068 e.g., between line 9069 A and line 9069 B
- angle 9068 is typically greater than 90 degrees.
- angle 9068 is 120 degrees or greater. If angle 9068 is less than 90 degrees it will be an implementation of second folding member 9012 as disclosed in FIG. 59 .
- An opening of ring valve 9070 comprises a distance between proximal end 9036 of first folding member 9010 and proximal end 9064 of second folding member 9012 .
- stent 9006 is a cylinder that can be an open channel or a filled structure that has no path from the external environment to the ear canal.
- second folding member 9060 has an anchor point 9062 that couples to stent 2006 or is formed part of stent 2006 .
- second folding member 9060 extends proximally forming a curved structure suspended above stent 9006 .
- the curved structure of second folding member 9060 is formed 360 degrees around stent 9006 .
- proximal end 9064 of second folding member 9060 can be seen as circular in shape around stent 9006 .
- Proximal end 9064 forms the circle having a radius indicated by double sided arrow 9072 from the center of stent 9006 .
- First folding member 9010 is a curved structure extending from anchor point 9046 to proximal end 9036 suspended above stent 9006 .
- the curved structure is formed 360 degrees around stent 9006 .
- a portion of first folding member 9010 overlies a portion of second folding member 9060 .
- proximal end 9036 of first folding member 9010 can be seen as circular in shape around stent 9006 .
- Proximal end 9036 forms the circle having a radius indicated by double sided arrow 9076 from the center of stent 9006 .
- a width of an opening of ring valve 9070 is approximately the distance of double-sided arrow 9076 less the distance of double-sided arrow 9072 when ear device 9000 is not inserted in the ear canal.
- first folding member 9010 has a maximum radius as indicated by double sided arrow 9074 . In one embodiment, the maximum radius is located distally from proximal end 9036 . The maximum radius of first folding member 9010 is greater than a radius of the era canal.
- ear device 9000 is outside the ear canal in a quiescent state where ring valve 9070 is open and chamber 9018 is coupled to the external environment. Chamber 9018 can be filled with a compressible material to further attenuate noise from the external environment. In one embodiment, filling chamber 9018 would also improve noise attenuation when chamber 9018 is open to the external environment.
- FIG. 61 is a cutaway view of ear device 9000 with chamber 9018 sealed in accordance with an example embodiment.
- the cutaway view illustrates structure within ear device 9000 that could not be seen with an external view.
- the section of ear device 9000 that is cutaway is substantially equal to what is shown in the illustration.
- Ear device 9000 has an optional stop flange removed to illustrate chamber 9018 being sealed.
- Ring valve 9070 is shown sealed thereby sealing chamber 9018 for occluding or partially occluding the ear canal with ear device 9000 .
- a force will be applied to ear device 9000 when inserted in an ear canal of an ear. More specifically, the wall of the ear canal applies a force to first folding member 9010 . Referring briefly to FIG.
- the ear canal radius will be smaller than the maximum radius indicated by double sided arrow 9074 . Twice the distance of double-sided arrow 9074 is a maximum diameter of ear device 9000 .
- the ear canal having a radius less than double-sided arrow 9074 of FIG. 60 will apply a force 360 degrees around first folding member 9010 that folds first folding member 9010 towards stent 9006 .
- First folding member 9010 is flexible and supports folding when inserted into the ear canal such that little or no discomfort occurs. First folding member 9010 conforms and couples to the wall of the ear canal. No gap will exist between a surface of first folding member 9010 and the wall of the ear canal that couples the external environment to the ear canal.
- Chamber 9018 is sealed when first folding member 9010 couples to second folding member 9060 .
- chamber 9018 is sealed when first folding member 9010 couples to second folding member 9060 a full 360 degrees around stent 9006 such that no gap exists between first folding member 9010 and second folding member 9060 .
- Sealing chamber 9018 isolates the ear canal from the external environment thereby attenuating noise from the external environment from reaching the ear canal.
- Ear device 9000 occludes or partially occludes the ear canal when chamber 9018 is sealed in the ear canal and stent 9006 does not couple to the external environment.
- noise or sound is reflected by the stop flange (not shown) away from the ear canal and back into the external environment.
- ear device 9000 provides excellent noise attenuation from the external environment.
- stent 9006 can be used to deliver acoustic information to the ear canal or receive acoustic information from the ear canal. This can be useful for an application such as two-way communication in a noisy environment or listening to music in a noisy environment.
- a pressure within chamber 9018 is approximately equal to a pressure in the external atmosphere when chamber 9018 is sealed.
- chamber 9018 of ear device 9000 is exposed to the external environment when chamber 9018 is not sealed. The pressure within chamber 9018 would be the same as the pressure within the external environment.
- Upon inserting ear device 9000 into an ear canal a force is applied around first folding member 9010 that moves first folding member towards second folding member 9012 .
- the wall of the ear canal provides a force 360 degrees around first folding member 9010 .
- First folding member 9010 is flexible and provides little resistance in folding to fit the diameter of the ear canal. Chamber 9018 is then sealed when first folding member 9010 couples to second folding member 9060 whereby no gap exists to the external environment through ring valve 9070 .
- Chamber 9018 maintains approximately equal pressure with the external atmosphere by opening ring valve 9070 during an adjustment that changes the ear canal diameter whether the diameter of the ear canal increases or decreases thereby respectively increasing or decreasing the volume of chamber 9018 .
- first folding member 9018 and second folding member 9060 are configured to decouple when a change in volume occurs. For example, chamber 9018 being inserted into a region of the ear canal that has a reduced diameter will reduce volume within chamber 9018 and expel an amount of gas corresponding to a difference in volume from the prior larger volume of chamber 9018 to the smaller volume of chamber 9018 due to the reduced diameter of the ear canal. Thus, although the volume is reduced in chamber 9018 , the pressure within chamber 9018 stays approximately equal to the external environment due to the expelled gas volume.
- Ring valve 9070 seals after adjustment to the change in volume within the ear canal thereby maintaining the noise attenuation properties of ear device 9000 . Comfort is maintained as the pressure applied to the walls of the ear canal stays the same.
- the flexibility of first folding member 9010 and second folding member 9060 is such that second folding member 9060 can fold to couple to stent 9006 .
- first folding member 9010 can fold to couple to second folding member 9060 (while second folding member 9060 couples to stent 9006 ) such that the volume within 9018 is reduced to a minimum and thereby accommodate small diameter ear canals.
- the ring valve 9070 does not open and expel gas during a decrease in volume of chamber 9018 the pressure within chamber 9018 will increase. This may have an effect on comfort due to increase pressure on the walls of the ear canal and also noise attenuation.
- Chamber 9018 also maintains approximately equal pressure with the external atmosphere by opening ring valve 9070 during an adjustment that changes the ear canal diameter from a smaller diameter to a larger diameter thereby increasing the volume of chamber 9018 .
- first folding member 9018 and second folding member 9060 are configured to decouple when the increase in volume occurs. For example, chamber 9018 being inserted into a region of the ear canal that increases in diameter will increase the volume within chamber 9018 and allow an amount of gas into chamber 9018 from the external environment that corresponds to a difference in volume from the prior smaller volume of chamber 9018 and the larger volume of chamber 9018 due to the increased diameter of the ear canal.
- First folding member 9010 and second folding member 9012 fold outward toward the larger diameter wall of the ear canal, decouples, and then seals.
- the pressure within chamber 9018 stays approximately equal to the external environment due ring valve 9070 opening to the external environment.
- Ring valve 9070 seals after adjustment to the change in volume within the ear canal thereby maintaining the noise attenuation properties of ear device 9000 .
- Comfort is maintained as the pressure applied to the walls of the ear canal stays the same.
- the resilience of first folding member 9010 and second folding member 9060 is such that first folding member 9010 will change shape towards the shape disclosed in FIG. 60 when ear device 9000 is not inserted in the ear canal thereby expanding to the increased diameter of the ear canal.
- second folding member 9060 will also change shape towards the shape disclosed in FIG. 60 when ear piece 9000 is not inserted in the ear canal thereby expanding to the increased diameter of the ear canal.
- Ring valve 9070 will open during the transition to an increased ear canal diameter thereby exposing chamber 9018 to the external environment. Ring valve 9070 closes after the adjustment to the increased diameter and the pressure within chamber 9018 is approximately equal to the pressure in the external environment. Comfort is maintained as the pressure applied to the walls of the ear canal by ear device 9000 independent of the diameter of the ear canal.
- the attenuation properties are also maintained as ring valve 9070 is sealed after insertion and adjustment within the ear canal.
- FIG. 62 is a block diagram 9080 of a method for occluding or partially occluding an ear canal with an ear device in accordance with an example embodiment.
- Block diagram 9080 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention.
- a step 9082 an ear device is inserted into an ear canal of an ear.
- the ear device has a chamber configured to occlude or partially occlude the ear canal.
- the ear device comprises at least one stent and the chamber.
- the chamber is formed around the at least one stent.
- a ring valve couples to the chamber for coupling to an external environment.
- the ring valve has an opening 360 degrees around the at least one stent.
- a step 9084 closing the ring valve seals the chamber thereby isolating the ear canal from the external environment.
- the ring valve is configured to close when inserted in the ear canal. Thus, occluding or partially occluding the ear canal.
- a force is applied to the ring valve or the chamber to seal the ring valve. The force applied closes the opening of the ring valve thereby sealing the chamber.
- the opening of the ring valve is 360 degrees around the at least one stent.
- the ring valve seals the opening 360 degrees around the at least one stent.
- the ring valve comprises a first folding member overlying a second folding member.
- the ring valve is open prior to being inserted in the ear canal.
- the ring valve couples the external environment to the chamber.
- the ear canal is configured to apply a force that closes the opening of the ring valve 360 degrees around the at least one stent to seal the chamber thereby closing the ring valve.
- the ring valve opens when the ear device is removed from the ear.
- the ring valve opens as the ear device is being inserted in the ear canal to support adjustment of the chamber volume to a change in diameter of the ear canal.
- the pressure is adjusted within the chamber.
- the chamber is configured to maintain a pressure approximately equal to the external environment as the chamber volume changes.
- the ring valve opens as the volume of the chamber changes thereby coupling the chamber to the external environment through the ring valve. The pressure in the chamber then equalizes to a pressure in the in the external environment.
- the ring valve opens in response to a change in the diameter of the ear canal which results in an adjustment of the chamber volume.
- FIG. 63 is a block diagram 9100 of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment.
- the block diagram 9100 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention.
- a step 9102 an ear device is inserted into an ear canal of an ear.
- a chamber of the ear device is configured to occlude or partially occlude the ear canal of the ear.
- a pressure within the chamber remains approximately equal for different chamber volumes.
- a ring valve of the ear device is open prior to inserting the ear device into the ear canal.
- the ring valve couples the external environment to the chamber.
- the ring valve is configured to close when inserted in the ear canal.
- the ring valve is configured to open in response to a diameter change in the ear canal during insertion that causes the chamber to increase in size or be reduced in size to occlude or partially occlude the ear canal. Opening the ring valve during insertion couples the chamber to the external environment thereby equalizing a pressure within the chamber to the external environment.
- the pressure within the chamber is approximately equal to the pressure in the external environment for any chamber size in the ear device.
- a gap is formed between a first folding member and a second folding member when the ring valve opens.
- the ring valve comprises a portion of the first folding member overlying a portion of the second folding member.
- the first folding member can be formed around a stent.
- the second folding member can be formed around a stent. Under quiescent conditions such as when the ear device is outside the ear a gap will exist between the first and second folding members such that the ring valve is open.
- the first folding member decouples from the second folding member due to a diameter change in the ear canal forming an opening in the ring valve.
- the ear canal is configured to apply a force to the first folding member of the ear device that couples the first folding member to the second folding member.
- the ring valve closes when the first folding member couples to the second folding member such that no gaps exist coupling the chamber to the external environment.
- the chamber is sealed.
- the chamber is coupled to the external environment.
- the ring valve is configured to open when the ear device is removed from the ear canal. The ring valve opens such that a gap in the ring valve couples the chamber to the external environment.
- FIG. 64 is a block diagram 9120 of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment.
- the block diagram 9120 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention.
- a step 9122 an ear canal of an ear is occluded or partially occluded with an ear device.
- the ear canal is occluded or partially occluded by a chamber that is sealed.
- the chamber is normally open to the external environment. In the normally open configuration, the chamber of the ear device is coupled to the external environment. The process of inserting the ear device into the ear canal of the ear seals the chamber thereby isolating the ear canal from the external environment.
- the chamber is coupled to the external environment or decoupled from the external environment by a ring valve.
- Walls of the ear canal are configured to apply a force to the ring valve.
- the force applied by the walls of the ear canal to the ring valve closes the ring valve thereby sealing the chamber that occludes or partially occludes the ear canal.
- pressure within the chamber is equalized to the external environment.
- the ring valve opens in a response to a change in a diameter of the ear canal during insertion of the ear device.
- the ring valve couple the chamber of the ear device to the external environment thereby equalizing a pressure within the chamber to the external environment as the chamber adapts to the diameter of the ear canal.
- the change in the diameter of the ear canal during insertion of the ear device into the ear canal corresponds to a change in the volume of the chamber to occlude or partially occlude the ear canal.
- a force is applied 360 degrees around the ring valve to close the ring valve and thereby seal the chamber.
- the walls of the ear canal of the ear apply a force 360 degrees around the ring valve.
- the force applied 360 degrees on the ring valve by the ear canal closes the ring valve thereby isolating the ear canal from the external environment.
- an ear device comprising a stent 9006 , a first folding member 9010 , and a second folding member 9012 .
- a second folding member can be oriented as disclosed in FIG. 60 as second folding member 9060 .
- First folding member 9010 forms a chamber with either second folding member 9012 or second folding member 9060 .
- First folding member 9010 couples to stent 9006 and extends proximally. A major portion of first folding member 9010 overlies a portion of stent 9006 .
- Second folding member 9012 or second folding member 9060 couples to stent 9006 .
- First folding member 9010 overlies second folding member 9012 or second folding member 9060 .
- a portion of first folding member 9010 overlies a portion of second folding member 9012 or second folding member 9060 .
- the first folding member 9010 couples to the second folding member 9012 or second folding member 9060 when inserted in the ear canal of an ear as indicated in FIGS. 58 and 61 .
- First folding member 9010 and second folding member 9012 form a chamber 9018 as disclosed in FIG. 58 when inserted in the ear canal to occlude or partially occlude the ear canal.
- first folding member and second folding member 9060 form a chamber 9018 as disclosed in FIG. 61 when inserted in the ear canal to occlude or partially occlude the ear canal.
- Chamber 9018 couples to and is formed around stent 9006 .
- first folding member 9010 is shown coupling circumferentially to stent 9006 .
- second folding member 9012 couples circumferentially to stent 9006 .
- first folding member 9010 couples to stent 9006 distal to where second folding member 9012 couples to stent 9006 .
- second folding member 9060 couples circumferentially to stent 9006 .
- a stop flange 9008 couples to stent 9006 . Stop flange 9008 limits how far ear device 9000 can be inserted into the ear canal.
- stop flange 9008 is larger than the diameter of the ear canal.
- Stop flange 9008 is located proximally in relation to first folding member 9010 and second folding member 9012 or second folding member 9060 .
- first folding member 9010 and second folding member 9012 or second folding member 9060 form a valve. In one embodiment, they form a ring valve. The valve couples chamber 9018 to the external environment.
- Ring valve 9020 is normally open.
- ring valve 9020 has a gap that is circular or ring shaped around stent 9006 .
- Ring valve 9020 comprises a portion of first folding member 9010 overlying a portion of second folding member 9012 .
- the gap is the distance between the overlying portions of first folding member 9010 and second folding member 9012 .
- ring valve 9020 can comprise a portion of first folding member 9010 overlying a portion of second folding member 9060 .
- the gap is the distance between the overlying portions of first folding member 9010 and second folding member 9060 .
- first folding member 9010 is configured to fold towards stent 9006 during insertion of the ear device into the ear canal.
- First folding member 9010 is configured to be flexible to bend, fold, conform.
- First folding member 9010 is low friction for easily being inserted into the ear canal.
- First folding member 9010 has a diameter that is greater than a diameter of the ear canal.
- First folding member 9010 has an anchor point 9046 that is a pivot point to support folding, bending, or conforming to a shape of the ear canal.
- at least a portion of the outer surface of first folding member 9010 is configured to couple to and conform to a surface of the ear canal. Note that a force applied by walls of the ear canal to an exterior surface of first folding member 9010 will move first folding member 9010 towards stent 9006 and thereby second folding member 9012 or second folding member 9060 .
- the second folding member 9060 or second folding member 9012 is configured to flex or fold. As shown in FIG. 61 , a force 9080 is applied to first folding member 9010 folding first folding member 9010 to couple to second folding member 9060 .
- the force 9080 corresponds to the walls of an ear canal when ear device 9000 is inserted into the ear canal.
- Second folding member 9060 or second folding member 9012 is configured to flex or fold. More specifically, second folding member 9060 or 9012 is configured to flex, fold, and conform when first folding member couples to second folding member 9060 or second folding member 9012 . Second folding member 9060 or second folding member 9012 conforms to the shape and contour of the ear canal when inserted in the ear canal. As disclosed at least a portion of the outer surface of the second folding member 9060 or second folding member 9012 is configured to couple to at least a portion of an interior surface of first folding member 9010 to seal chamber 9018 .
- chamber 9018 is normally open when ear device 9000 is outside the ear canal. Normally open corresponds to ring valve 9020 being open. Thus, chamber 9018 is coupled to the external environment prior to ear device 9000 being inserted into the ear canal.
- ear device 9000 is inserted in an ear canal 9002 .
- First folding member 9010 couples to second folding member 9012 such that chamber 9018 is sealed. Ring valve 9020 is closed when chamber 9018 is sealed. A gap in ring valve 9020 prior to ring valve 9020 sealing couples chamber 9018 to the external environment. Thus, when chamber 9018 is sealed the pressure within chamber 9018 is approximately equal to a pressure in the external environment.
- first folding member 9010 decouples from second folding member 9012 or second folding member 9060 as chamber 9018 adjusts to a change in diameter of the ear canal to conform to occlude or partially occlude the ear canal.
- Ring valve 9020 closes once the chamber conforms to the diameter of the ear canal sealing chamber 9018 .
- Ear canal 9002 is then isolated from the external environment by chamber 9018 that is sealed. Noise in the external environment is attenuated by stop flange 9008 and chamber 9018 before reaching ear canal 9002 .
- chamber 9018 is configured to seal as ear device 9000 is inserted into ear canal 9002 .
- Chamber 9018 is configured to occlude or partially occlude the ear canal when sealed.
- Chamber 9018 comprises first folding member 9010 and second folding member 9012 or second folding member 9060 .
- First folding member 9010 couples around stent 9006 .
- An outer surface of first folding member 9010 is configured to couple to a surface of ear canal 9002 .
- Second folding member 9012 or second folding member 9060 couples around stent 9006 . At least a portion of first folding member 9010 overlies at least a portion of second folding member 9012 or second folding member 9060 .
- First folding member 9010 is configured to couple to the second folding member 9012 or second folding member 9060 when inserted into ear canal 9002 .
- a gap exists between first folding member 9010 and second folding member 9012 or second folding member 9060 when ear device 9000 is outside ear canal 9002 .
- the gap couples the external environment to chamber 9018 when ear device 9000 is outside ear canal 9002 .
- First folding member 9010 couples to second folding member 9012 or second folding member 9060 to close the gap when ear device 9000 is inserted in ear canal 9002 thereby sealing chamber 9018 .
- the gap opens between first folding member 9010 and second folding member 9012 or second folding member 9060 during insertion into ear canal 9002 to equalize pressure between chamber 9018 and the external environment.
- a pressure within chamber 9018 is approximately constant as a volume of chamber 9018 increases or decreases.
- a volume decrease in chamber 9018 corresponds to a reduction in diameter of ear canal 9002 .
- the reduction in diameter of ear canal 9002 expels gas within chamber 9018 thereby opening ring valve 9020 .
- Displacing the gas to accommodate the smaller volume maintains the pressure within chamber 9018 approximately equal to the external environment.
- a volume increase in chamber 9018 corresponds to an increase in diameter of ear canal 9002 .
- the increase in diameter of ear canal 9002 supports opening of ring valve 9020 .
- Opening ring valve 9020 couples chamber 9018 to the external environment thereby equalizing the pressure within chamber 9018 to the approximately equal to the external environment when ring valve 9020 closes.
- a volume in chamber 9018 can be filled in part by a gas, foam, or liquid.
- FIGS. 65 A and 65 B illustrate an earplug where a first sealed chamber 30 is inflated by moving fluid 40 from a second sealed chamber 10 my pressing Y1 on the second sealed chamber, where a valve 20 prevents backflow.
- a rotatable element 6500 attached to a flexible stent to which the valve 20 is attached can be rotated 6600 , to open the valve releasing the fluid 40 from the first sealed chamber 30 toward the second sealed chamber 10 .
- FIG. 66 is a cutaway view of a molded ear device 6000 without a stop flange in accordance with an example embodiment.
- the front tip portion 6620 is molded as shown, then folded toward ridge 6610 to form a tip. This way a nearly enclosed tip can be molded.
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Abstract
At least one exemplary embodiment is directed to an earphone, ear device, eartip, or earplug configured to inserted in an ear canal of the ear. The earphone, ear device, eartip, or earplug is configured to occlude or partially occlude the ear canal of the ear. The earphone, ear device, eartip, or earplug includes a chamber to occlude or partially occlude the ear canal that is sealed when inserted in the ear canal and open to the external environment when outside the ear.
Description
- This application is a continuation of U.S. Pat App. No. 16/905,655, filed 18 Jun. 2020, which is a continuation in part of and claims priority benefit to U.S. Pat. App. No. 16/590466, filed 2 Oct. 2019, which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/740408, filed 2 Oct. 2018, U.S. Pat. App. No. 16/590466 also claims priority to and is a continuation in part of U.S. Pat. App. No. 15/674239, filed 10 Aug. 2017, which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/437331, filed 21 Dec. 2016, and also which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/373313, filed 10 Aug. 2016, also claims priority to and is a continuation in part of U.S. Pat. App. No. 15/182569, filed 14 Jun. 2016, which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/307486, filed 12 Mar. 2016, and also which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/307484, filed 12 Mar. 2016, and also which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/239337, filed 9 Oct. 2015, and also which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/217663, filed 11 Sept. 2015, and which claims priority to and is a continuation in part of U.S. Pat. App. No. 14/807887, filed 24 Jul. 2015, which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 62/187506, filed 1 Jul. 2015, and which claims priority to and is a continuation in part of U.S. Pat. App. No. 13/859,815, filed 10 Apr. 2013, which claims priority to and is a continuation of U.S. Pat. App. No. 13/154,429, filed 6 Jun. 2011, which claims priority to and is a non provisional conversion of U.S. Pat. App. No. 61/351290, filed 4 Jun. 2010.
- The present invention relates to devices that modify acoustic attenuation and reflection, and more particularly, though not exclusively, devices that can be inserted into an ear canal or used as a sound insert or panel.
- Hearing protection can take several forms such as earplugs and muffs. Such hearing protection devices attenuate acoustic energy before it reaches the eardrum (tympanum) by creating an insertion loss that is achieved by reflection of the sound waves, dissipation with the device’s structure, impedance of the waves through tortuous paths, closing of acoustical valves, and other means. For a hearing protector, the amount of sound pressure level (SPL) reduced, usually measured in decibels (dB), is typically depicted graphically as a function of frequency. Most hearing protection fails to deliver a flat attenuation across frequency spectrum, instead typically providing attenuation which increases in dB as frequency increases; therefore, the attenuation spectrum is typically nonlinear, which affects the perception of sound frequencies across the audible spectrum in different degrees. For this reason, pitch perception and other auditory experiences which rely on frequency-based cues can be compromised by the nonlinear attenuation imparted by conventional hearing protectors. This leads to the need for uniform or “flat” attenuation, which is desirable in many situations, for example, musicians would like to conserve their hearing while hearing an accurate frequency representation of the produced music, or workers who must listen for certain spectral characteristics associated with their machinery or environment. Ferrofluids are composed of nanoscale particles (diameter usually 10 nanometers or less) of magnetite, hematite or some other compound containing iron. This is small enough for thermal agitation to disperse them evenly within a carrier fluid, and for them to contribute to the overall magnetic response of the fluid. This is analogous to the way that the ions in an aqueous paramagnetic salt solution (such as an aqueous solution of copper(II) sulfate or manganese(II) chloride) make the solution paramagnetic.
- Particles in ferrofluids are dispersed in a liquid, often using a surfactant, and thus ferrofluids are colloidal suspensions - materials with properties of more than one state of matter. In this case, the two states of matter are the solid metal and liquid it is in. This ability to change phases with the application of a magnetic field allows them to be used as seals, lubricants, and may open up further applications in future nanoelectromechanical systems.
- True ferrofluids are stable. This means that the solid particles do not agglomerate or phase separate even in extremely strong magnetic fields. However, the surfactant tends to break down over time (a few years), and eventually the nano-particles will agglomerate, and they will separate out and no longer contribute to the fluid’s magnetic response.
- The term magnetorheological fluid (MRF) refers to liquids similar to ferrofluids (FF) that solidify in the presence of a magnetic field. Magnetorheological fluids have micrometre scale magnetic particles that are one to three orders of magnitude larger than those of ferrofluids.
- However, ferrofluids lose their magnetic properties at sufficiently high temperatures, known as the Curie temperature. The specific temperature required varies depending on the specific compounds used for the nano-particles.
- Electrorheological (ER) fluids are suspensions of extremely fine nonconducting particles (up to 50 micrometres diameter) in an electrically insulating fluid. The apparent viscosity of these fluids changes reversibly by an order of up to 100,000 in response to an electric field. For example, a typical ER fluid can go from the consistency of a liquid to that of a gel, and back, with response times on the order of milliseconds. The change in apparent viscosity is dependent on the applied electric field, i.e. the potential divided by the distance between the plates. The change is not a simple change in viscosity, hence these fluids are now known as ER fluids, rather than by the older term Electro Viscous fluids. The effect is better described as an electric field dependent shear yield stress. When activated an ER fluid behaves as a Bingham plastic (a type of viscoelastic material), with a yield point which is determined by the electric field strength. After the yield point is reached, the fluid shears as a fluid, i.e. the incremental shear stress is proportional to the rate of shear (in a Newtonian fluid there is no yield point and stress is directly proportional to shear). Hence the resistance to motion of the fluid can be controlled by adjusting the applied electric field.
- One of the current issues with hearing protection and hearing assistance systems is that the attenuation cannot be tuned for a particular situation.
- Exemplary embodiments of present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
-
FIG. 1 illustrates a cartilaginous region and a bony region of an ear canal; -
FIG. 2 illustrates general physiology of an ear; -
FIG. 3 illustrates a nonlimiting example of an experiment for determining material properties of inflatable elements; -
FIG. 4 illustrates the sound pressure levels (SPL) of the upstream microphone (UM) and the downstream microphone (DM) as a function of medium and pressure; -
FIG. 5 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air at 400 mbar gauge pressure; -
FIG. 6 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air at 600 mbar gauge pressure; -
FIG. 7 illustrates the insertion loss (IL) value for three mediums, NaCl, H2O, and Air for 400 mbar and 600 mbar gauge pressures; -
FIG. 8 illustrates the insertion loss (IL) value for Air for gauge pressures of 350 mbar, 450 mbar, 550 mbar, and 650 mbar gauge pressures; -
FIG. 9 illustrates the insertion loss (IL) value for H2O for gauge pressures of 350 mbar, 450 mbar, 550 mbar, and 600 mbar gauge pressures; -
FIG. 10 illustrates the insertion loss (IL) value for two mediums, H2O, and Air for 450 mbar and 550 mbar gauge pressures; -
FIG. 11 illustrates a general mathematical model of an earplug using a membrane; -
FIG. 12 illustrates an experimental test system that can be used to test attenuation and reflection characteristics both in a subject and for panel design; -
FIGS. 13-18 illustrate non-limiting examples of earplugs with modifiable attenuation; -
FIG. 19 illustrates a detachable earplug pumping system in accordance with at least one exemplary embodiment; -
FIG. 20 illustrates a lanyard earplug system in accordance with at least one exemplary embodiment; -
FIG. 21A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 21B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 22A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 22B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 23A is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 23B is a schematic diagram illustrating non-limiting example of earplugs with modifiable attenuation; -
FIG. 24 illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment; -
FIGS. 25A and 25B are schematic diagrams illustrating cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment; -
FIG. 25C is a schematic diagram illustrating a hearing protection device embodiment of the invention; -
FIG. 26 illustrates an earplug in accordance with at least one exemplary embodiment; -
FIG. 27 illustrates an acoustic shaping panel in accordance with at least one exemplary embodiment; -
FIG. 28 illustrates a cross section of the panel illustrated inFIG. 27 ; -
FIG. 29 illustrates attachment of the panels ofFIG. 27 on a wall in accordance with at least one exemplary embodiment; -
FIG. 30A illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment; -
FIG. 30B illustrates a close-up of the medium illustrated inFIG. 30A ; -
FIGS. 31A, 31B, 31C, and 31D illustrate variations of cross sections of acoustic shaping panels in accordance with various exemplary embodiments; -
FIGS. 32A, 32B, and 32C illustrate the configuration and operation of at least one exemplary embodiment; -
FIG. 33 illustrates an earplug in accordance with one exemplary embodiment; -
FIGS. 34A, 34B, and 34C illustrate the configuration and operation of at least one exemplary embodiment; -
FIGS. 35A, 35B, 35C, and 36 illustrate the configuration and operation of at least one exemplary embodiment; -
FIGS. 37 and 38 illustrate a helmet with a liner in accordance with at least one exemplary embodiment; -
FIGS. 39-40 illustrate various flexible distal ends developed; -
FIG. 41 illustrates a novel distal end spiral feed system which enhances uniform expansion about a stent; -
FIG. 42 illustrates a tip in accordance with at least one exemplary embodiment; -
FIG. 43 illustrates a novel distal end spiral feed system which enhances uniform expansion about a stent; -
FIGS. 44A, 44B, 44C, 44D, 44E, 44F, 44G, 44H, 44I, 44G, 44J illustrates various eartips, earplugs in accordance with various exemplary embodiments; -
FIG. 45 illustrates a work environment; -
FIG. 46 illustrates the computer display that represents the work environment ofFIG. 45 ; -
FIG. 47 illustrates an embodiment of an earphone/earplug; -
FIG. 48A illustrates a membrane tip in accordance with an embodiment; -
FIG. 48B illustrates a cross section of the tip ofFIG. 48A ; -
FIG. 49 illustrate an inflatable earphone system in accordance with one exemplary embodiment; -
FIGS. 50-51 illustrate a lanyard pump inflatable earphone system; -
FIGS. 52-53 illustrate an actuatable inflatable earphone system; -
FIGS. 54A, 54B, 55 illustrate pull-release expandable earphone system; -
FIG. 56 is an illustration of an ear device prior to insertion into an ear canal of an ear in accordance with an example embodiment; -
FIG. 57 is a cutaway view of the ear device in accordance with an example embodiment; -
FIG. 58 is an illustration of the ear device inserted in the ear canal in accordance with an example embodiment; -
FIG. 59 is a cutaway view of the ear device without a stop flange in accordance with an example embodiment; -
FIG. 60 is a cutaway view of an ear device without a stop flange in accordance with an example embodiment; -
FIG. 61 is a cutaway view of the ear device with a chamber sealed in accordance with an example embodiment; -
FIG. 62 is a block diagram of a method for occluding or partially occluding an ear canal with an ear device in accordance with an example embodiment; -
FIG. 63 is a block diagram of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment; -
FIG. 64 is a block diagram of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment; -
FIGS. 65A and 65B illustrate the use of a rotating member to open a valve in an ear device; and -
FIG. 66 is a cutaway view of a molded ear device without a stop flange in accordance with an example embodiment. - The following description of exemplary embodiment(s) is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.
- Exemplary embodiments are directed to or can be operatively used on various passive earplugs for hearing protection or electronic wired or wireless earpiece devices (e.g., hearing aids, ear monitors, earbuds, headphones, ear terminal, behind the ear devices or other acoustic devices as known by one of ordinary skill, and equivalents). For example, the earpieces can be without transducers (for a noise attenuation application in a hearing protective earplug) or one or more transducers (e.g. ambient sound microphone (ASM), ear canal microphone (ECM), ear canal receiver (ECR)) for monitoring/providing sound. In all of the examples illustrated and discussed herein, any specific values should be interpreted to be illustrative only and non-limiting. Thus, other examples of the exemplary embodiments could have different values.
- Processes, techniques, apparatus, and materials as known by one of ordinary skill in the art may not be discussed in detail but are intended to be part of the enabling description where appropriate. For example specific materials may not be listed for achieving each of the targeted properties discussed, however one of ordinary skill would be able, without undo experimentation, to determine the materials needed given the enabling disclosure herein.
- Notice that similar reference numerals and letters refer to similar items in the following figures, and thus once an item is defined in one figure, it may not be discussed or further defined in the following figures. Processes, techniques, apparatus, and materials as known by one of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the enabling description where appropriate.
-
FIG. 1 illustrates a generic cross section of anear canal 100, including acartilaginous region 140 and abony region 130 of anear canal 120. The entrance of theear canal 120 is referred to as theaperture 150 and defines a first end of the ear canal while thetympanic membrane 110 defines the other end of theear canal 120. -
FIG. 2 illustrates general outer physiology of an ear, which includes a,auricle tubercle 210, theantihelix 220, thehelix 230, the antitragus 240, tragus 250, lobule ofear 260, crus of helix 270,anterior notch 280, andintertragic incisures 290. -
FIG. 3 illustrates a nonlimiting example of an experiment for determining material properties of inflatable elements. To isolate the variations in ear canal lengths, ear canal cross sections and insertion depths of earpieces (e.g., earplugs, in-the-canal hearing aids) anexperimental setup 300 was constructed as illustrated inFIG. 3 . A noise source 310 (e.g., Phonic PAA6) generates acoustic source waves 315 (e.g., pink noise, white noise) which travel down anacoustic tube 320A where the incident acoustic signal is measured by an upstream first microphone (e.g., M1 or UM, Audix Measurement Microphone). The test sample 330 (e.g., balloon, isolated chamber) can be filled with various fluids (e.g., air, water, water with agents) and inserted into aportion 320B of the tunnel such that the acoustic source waves impinge one side of the test sample, travels through the test sample, and exit the opposite or adjacent (not shown) side of the test sample, where a downstream microphone (e.g., M2 or DM) measures the exiting acoustic waves. To minimize reflections from the end of the downstream tube the system is set to have an anechoically terminated end, which is accomplished by length (>75 ft) so as to gradually diminish the energy of the travelling wave 316 via wall interaction, and by having small strands of string near the end to absorb more of the energy in the wave. The data from the two microphones M1 and M2 are obtained to extract acoustical spectrum information (e.g., using FFT analyzer software such as 340 Spectra-PLUS™ FFT Analyzer). For example, when measuring insertion loss (IL), measurements are taken with M2 prior to insertion of a test sample, then a test sample inserted and measurements retaken with M2. Using the same sound source in both measurements, the difference in the two measurements is defined as insertion loss (IL). For discussion herein with regards to tunnel data IL is approximated when using balloons by a difference in the uninflated M2 measurements (i.e. pressure of 000mbar gauge pressure) and an inflated M2 measurement. The pressure of a test sample is varied by use of a pressure pump 350 (e.g., SI Pressure LTP1™ Low Pressure Calibration Pump), and monitored by reading the pressure from a pressure gauge 360 (e.g., Extech™ Differential Pressure Manometer). -
FIG. 4 illustrates the sound pressure levels (SPL) of the upstream microphone (UM) and the downstream microphone (DM) as a function of medium and pressure. dB Values rms between water and air at 000 mbar, 400 mbar, and 600 mbar gauge pressure are illustrated. A larger value indicates higher SPL values, thus a value of -10 dB is an increase of 20 dB in SPL value from -30 dB. Note that the values for 000 mbar represent the uninflated value and the insertion loss (IL) can be obtained by subtracting the 000 mbar value from the pressure values for the downstream microphone (DM). IL values are presented on the next plot (FIG. 5 ); note also that the plotting values are 1-octave values and hence have been averaged from the narrowband data, thus details in the narrow band data are lost. However the 1-octave values allow more direct comparison to human subject data (FIGS. 11 and 12 ). - The top panel illustrates upstream microphone 400 (UM) measurements under six conditions, water as the medium under three pressures: 000 mbar(blue), 400 mbar(green), and 600 mbar(light blue); and air as the medium under the same three pressures: 000 mbar(light purple), 400 mbar(red), and 600 mbar(orange). Note that the pressure conditions separate into two general separate lines, the first with no inflation for example 410, and a second line where the two non-zero pressure values generally overlap into a
single line 420. Thus generally independent of pressure in the sample, an increase of about 7 dB is measured upstream of the test sample. One possible interpretation is that 7 dB of incident energy is reflected from the interface. - The bottom panel illustrates downstream microphone 460 (DM) measurements under six conditions, water as the medium under three pressures: 000 mbar(blue), 400 mbar(green), and 600 mbar(light blue); and air as the medium under the same three pressures: 000 mbar(light purple), 400 mbar(red), and 600 mbar(orange). Note that the pressure conditions separate into two general regions, the first region is associated with no
inflation 440 where irrespective of medium, as one might expect, the lines overlap. The other region varies depending upon medium and pressure. For example, a red line marks dB values for air at 440 mbar and the orange line dB values for 600 mbar. In general as the pressure increases the rms dB value decreases in value as measured by DM. Note that between a frequency of 300-700 Hz an increase in pressure is not associated with an decrease measured value at DM. Note that both UM and DM measurements have roughly a frequency independent standard deviation of < 0.2 dB. -
FIG. 5 illustrates the insertion loss (IL) values 500 for three mediums, NaCl, H2O, and Air at 400 mbar gauge pressure as measured by the downstream microphone DM. Note that a larger IL value is associated with more energy being removed from the initial acoustic wave by the test sample. As illustrated the three different mediums, distilled H2O with 1.95 mg/L NaCl (light blue line) 510, distilled H2O (blue) 520, and Air (red) 530, are distinguishable. For example air provides less IL after 700 Hz than H2O 520 and H2O+NaCl mixture 510. Note that H2O 520 and H2O+NaCl mixture 510 have similar profiles below 700 Hz and above 3 kHz. Between 700 Hz-3 KHz the IL values 510 and 520 differ such that an H2O+NaCl mixture provides more IL. Note that although an H2O+NaCl mixture is illustrated, other mixtures (e.g., with sucrose, alcohol, mineral oil) can be used to taylor specific increases or decreases in IL as a function of frequency for a given pressure. -
FIG. 6 illustrates the insertion loss (IL) values 600 for three mediums, NaCl, H2O, and Air at 600 mbar gauge pressure as measured by the downstream microphone DM. Note that a larger IL value is associated with more energy being removed from the initial acoustic wave by the test sample. As illustrated the three different mediums distilled H2O with 1.95 mg/L NaCl (light blue line) 610, distilled H2O (blue) 620, and Air (red) 630 are distinguishable. For example air provides less IL after about 1.5 kHz than H2O 620 and H2O+NaCl mixture 610. Note that the decrease with air as a medium after 1.5 kHz differs from the 400 mbar value of 700 Hz. Thus at increasedpressures air 630 provides less IL than H2O 620 and H2O+NaCl mixture 610 above a higher frequency. Thus generally as the test sample pressure is increased, the IL profiles also vary, facilitating using controllable pressure values to obtain design IL profiles. For example, if an earplug uses air and an IL value above 700 Hz in unimportant for the particular use, then an earplug can be designed to have an internal balloon pressure of about 400 mbar, whereas if the IL value above 1.5 kHz is unimportant then the earplug balloon can be designed to have an internal pressure of 600 m bar. - Note that H2O 620 (green) and H2O+NaCl mixture 610 (red) have similar profiles up to about 700 Hz. Above 700 Hz, the IL values 610 and 620 differ such that an H2O+NaCl mixture provides more IL. Note that although an H2O+NaCl mixture is illustrated, other mixtures (e.g., with sucrose, alcohol, mineral oil) can be used to tailor specific increases or decreases in IL as a function of frequency for a given pressure. Thus, if an earplug is designed for use with distilled water, the IL value can be varied at different frequencies by adding agents (e.g., NaCl). If one wishes to increase the IL above 700 Hz one could add a mixture of NaCl and distilled
water 620. -
FIG. 7 illustrates the insertion loss (IL)value 700 for three mediums, NaCl, H2O, and Air for twopressures 400 mbar and 600 mbar gauge pressures as illustrated inFIGS. 5 and 6 for ease of comparison. -
FIG. 8 illustrates the insertion loss (IL) value for Air for gauge pressures of 350 mbar (800), 450 mbar (810), 550 mbar (820), and 650 mbar (830) gauge pressures. In general as the pressure of a test sample increases the IL value increases for frequencies less than about 300 Hz and greater than about 1 kHz. Between about 300 Hz and 1 kHz the pressure with the larger IL depends upon frequency. For example, a pressure of 450 mbar has a larger IL value than other pressures at about 500 Hz, while a pressure of 550 mbar has the largest IL value at about 650 Hz. Thus pressure can be varied in an earplug device to modify the frequency at which the greatest IL is provided. For example, suppose the frequency of an offending noise source gradually increases in frequency. An air-filled earplug with interactive pressure control could increase the pressure of an earplug balloon to maintain suppression of the noise source as its frequency increased. -
FIG. 9 illustrates the insertion loss (IL) value for H2O for gauge pressures of 350 mbar (900), 450 mbar (910), 550 mbar (920), and 600 mbar (930) gauge pressures. In general as the pressure of a test sample increases the IL value increases for frequencies less than about 300 Hz. Above about 300 Hz the pressure with the larger IL depends upon frequency. For example a pressure of 450 mbar has a larger IL value than other pressures at about 625 Hz, while a pressure of 550 mbar has the largest IL value at about 1.25 kHz. Thus pressure can be varied in an earplug device to modify the frequency at which the greatest IL is provided. For example, suppose a flatter frequency dependent IL is desired between frequencies of about 500 Hz and 800 Hz, then the pressure of an H2O filled earplug bladder can be set to about 350 mbar and if an increase of IL is needed within this range then the pressure can be increased. -
FIG. 10 illustrates the insertion loss (IL) value for the H2O values ofFIG. 9 and two air values for comparison Air at 450 mbar (1030) and 550 mbar (1020) gauge pressures. Note that peak IL values differ from the fluid used (e.g., air or H2O). For example, if an earplug device is designed to maximize IL at 500 Hz, then one can use air at 450 mbar, where if one wishes to maximize the IL at about 650 Hz the air pressure can be increased to 550 mbar. If one wishes to design an earplug to maximize IL at about 1.25 kHz then one can use H2O at a pressure of about 550 mbar. Note that a flatter IL profile when using H2O can be obtain between frequencies about 500 Hz and 1 kHz by setting the H2O pressure to about 550 mbar as opposed to 450 mbar. - The extent of the earplug can be modeled as a region extending from x=0 to x=L with an incident pressure wave A1 (
FIG. 11 ). The reflectance of the pressure wave and transmission of the pressure wave will depend upon the impedance (Z=pc) between two regions. The membrane itself can also be considered aregion separating region 1 and region 2. Between two regions the Reflection (R) coefficient and Transmission (T) coefficient can be derived using interface boundary conditions BC1 (continuity of pressure) and BC2 (continuity of particle velocity). -
-
- Note that equations (1) and (2) are generally used across any boundary between two regions. If we treat the membrane as the second region we will get the relationships:
-
-
- For a membrane the speed of sound in the membrane, (cm), is a function of the tension force per unit length (Ti) and the surface density (m, mass per unit area), and can be expressed as:
-
- Thus ZM can be expressed as
-
- whereas Z1=p1*c1 =(1 Kg/m3)(343 m/sec, in air)=343, and using roughly pm=1100 Kg/m3 (for rubber) and a tension of about Ti= (1.2 atm*101300 N/m2)*(π )*(0.005 m)2/0.01 m≈954 N/m, and m=(1100 Kg/m3)*(0.0001 m)/[(π )*(0.005 m)2 ] ≈1401 Kg/m2 one can obtain about ZM≈907,..so that roughly the ratio Z1/ZM = 0.38. Note that for a membrane earplug the filler pressure can be varied and hence the tension force can be varied. Note that a simple examination of continuity of particle velocity (2) results in:
-
- Thus reflectivity increases at the membrane interface (essentially B1 approaches A1). The unique aspect of membrane earplugs is that the tension can be varied by increasing the pressure in the bladder and the relative speeds of sound can be varied by changing the filler fluid. If one uses a filler fluid of water H2O as a comparison to the aforementioned air, Z2=(1500 m/sec)(1000 Kg/m3)=1500000. In a more general analysis the Reflectivity coefficient (R), examining only the air-filler interface, can be reduced, for when k2L<<1 (a small membrane thickness), as:
-
- This shows a large reflection coefficient, when the filler is H2O. Note that the value of Z2 is determined by the filler fluid medium and can be tailored depending upon desired attenuation performance.
- At least one exemplary embodiment of the present invention employs a simple stretch membrane (i.e., “balloon”) approach, wherein an inflatable, lightweight balloon is inserted into the ear canal in its deflated state, and then inflated once inside the canal. This insertion configuration affords its own additional advantages in the realm of having an in-ear product that is undersize compared to the diameter of the ear canal prior to insertion, and then expands once inside the canal, unlike most other earplug products on the market, including the Ety High Fidelity™ earplug, which are sized to be oversize the ear canal prior to insertion, and thus require squeezing or compression upon insertion, making insertion more difficult.
-
FIG. 12 illustrates a method for testing various configurations. The membrane-based earplug testing system comprises in general a tip configuration and a bladder configuration. The bladder configuration includes a filler bladder where the filler bladder is a medical balloon that is pre-shaped but deformable. The tip configuration includes a compliant tip that is an expandable elastic medical balloon that conforms to a stent. The stent connects the filler bladder to the compliant tip. The filler bladder can be deformed forcing filler material to the compliant tip which expands to fill an ear canal. The material is kept from flowing back to the filler bladder by a deformable one way valve. The deformable one-way valve (made of compliant rubber-like material) can be deformed by a user to allow back flow to the bladder. The system additionally includes two way and three way valves for the relief of pressure, filler exchange, and pressure measurement. The one way valve, two way valve, and three way valves are valves that can be included in housing, with attached medical luer locks that can then be fitted to the stent. In one of the test configurations the tip configuration includes a safety flange to determine whether inclusion of a safety flange affects localization. Likewise the bladder configuration includes a medical pre-shaped balloon of about 1 cc volume attached to luer lock connectors at either end. Various fillers can be used for example H2O, H2O +NaCl, H2O+Alcohol, Alcohol, MR fluid, and Air, note that this list is a non-limiting example only. -
FIGS. 13-18 illustrate non-limiting examples of earplugs with modifiable attenuation.FIG. 13 illustrates an earpiece (e.g., earplug, headphone, hearing aid) that includes a first reservoir 1310 (e.g., Urethane balloon, silicon balloon) fed by a channel (tube) 1330 in astent 1300. Thestent 1300 can be fabricated from various materials (e.g., silicon, urethane, rubber) and can include internal channel (tubes), forexample tubes first reservoir 1310 can be connected to asecond reservoir 1370 via thetube 1330. Thus a fluid 1360 can be transferred between thefirst reservoir 1310 and thesecond reservoir 1370 by pressing against thesecond reservoir 1370 or by pressing against thefirst reservoir 1310. Additionally the reservoirs (1370 and 1310) can be fabricated from stressed membranes (e.g., silicone) so that when fluid is inserted into the reservoirs a restoring force presses against the fluid 1360 by the membrane. For example if the second reservoir was fabricated from a compliant balloon with an initial state of collapse, then filling thesecond reservoir 1370 with fluid 1360 would stretch the membrane such that the membrane would seek to press against thefluid 1360. If the first reservoir restoring force caused by its membrane is less than that of thesecond reservoir 1370 then the fluid 1360 will move viatube 1330 into the first reservoir. Alternatively a structure can press against thesecond reservoir 1370 pushing against the fluid 1360 moving a portion of the fluid in to the first reservoir.FIG. 13 illustrates a non-limiting example of a structure that includes apiston head 1380, a front surface of thepiston head 1390 connected to astem 1384. The structure can lie within a housing that has optionalinternal threads 1382, which optional threads onpiston head 1380 can engage so if one rotates the piston head one pushes the piston head front surface against thesecond reservoir 1370. - Note that in at least one exemplary embodiment the restoring force of the
first reservoir 1310 can be such that the fluid remains in thesecond reservoir 1370 unless the volume of thesecond reservoir 1370 is decreased. Such a configuration can be used for an earplug where the portion to be inserted is collapsed into a minimal profile shape and upon insertion a user can move the structure so that the volume of thesecond reservoir 1370 decreases increasing the fluid in to the first reservoir, such that thefirst reservoir 1310 expands occluding a channel (e.g., ear canal) into which the earpiece is at least partially placed. Note that other channels can be used to convey acoustical energy across the first reservoir, for example thetube 1320 can be used to measure or emit sound to the left of the first reservoir as illustrated inFIG. 13 . -
FIG. 14 illustrates a non-limiting example of a moveable structure discussed with reference toFIG. 13 , where thestem 1384 is attached to atab 1400 that a user can move (e.g., push, rotate) to move the structure toward or away from thesecond reservoir 1370. -
FIG. 15 illustrates an isolated view of the stent discussed with reference toFIG. 13 . Note that for ease of manufacturing the stent can be similar to that used in an infant urology Foley catheter, which has aninflation tube 1330 and aflush tube 1320, where for an earplug the flush tube is sealed, for example by injecting a flexible curing material (e.g.,Alumilite Flex 40™ casting rubber). - A bladder 1600 (
FIG. 16 ) having a preformed shape (e.g., non-compliant medical balloon) or flexible shape (e.g. compliant medical balloon) can be filled with the desired fluid then attached to the stent or to the housing and sealed (FIG. 17 ). Thebladder 1730 can be attached 1740 tohousing 1700 that can also includethreads 1710. The fluid filled 1830 housing 1810 (FIG. 18 ) (e.g., fabricated from a plastic, hard rubber) can then be attached 1820 to thestent 1800, the structure screwed into threads in the housing, and aretainer cap 1395 attached to the housing (e.g., via loctite glue) restricting the movement of the structure. Note that there can be a hole in theretainer cap 1395, having a hole diameter DH, where in at least one embodiment, DH can be larger than thetab 1400 width DF. Note that thebladder 1600 can be of various shape for example semi-spherical, cylindrical, and can be formed by various methods such as dip molding. Note also that anoptional stop ring 1350 can be used. -
FIG. 19 illustrates a detachable earplug pumping system in accordance with at least one exemplary embodiment. Theearpiece 3080 can be operatively attached via atube 3050 to afinger pump 3090. The entire pump system (e.g., 3030, 3050, 3070, 3060, 3035) can be detachable from apump insert port 3010. Apump seal valve 3040 in asealing section 3020 in theearpiece 3080 generally allows one way flow and seals when the pump system is detached. The earpiece includes initially a deflated fluid reservoir which is fluid filled when the pump is actuated (e.g., finger pumped). Thepump insert port 3010 allows general sealing with a detachable pumps insert interface 3030 (e.g., arrow head). The pump system can include afeed tube 3050 attached to theinsert interface 3030. The feed tube can be attached to apump body 3070 which includes afinger dimple 3060, for example fabricated from a restoring flexible material (e.g., rubber) that returns to its original shape after deformation. Thus deformation of thefinger dimple 3060 forces fluid throughfeed tube 3050 and into theearpiece 3080. A one way valve (e.g., 3040)system 3035 feeds fluid (e.g., from the environment) into thepump body 3070 so via another deformation of thefinger dimple 3060 fluid is available to be pumped intoearpiece 3080. -
FIG. 20 illustrates alanyard earplug system 4060 in accordance with at least one exemplary embodiment.Earpieces 4000 includingoptional stop flanges 4010 can be attached to a lanyardfinger pump system 4060. The lanyard finger pump system can include twoconnected tubes separate earpiece 4000. Thetubes way valves 4030 to asqueeze release section 4050, which can be squeezed (A) to deflate theearpieces 4000. The pump section can include afinger dimple 4040 and an inlet one way valve C. The inlet one way valve C can include a oneway valve 4030. Therelease section 4050 can include two one way valves, one 4060A associated withtube 4020A and the other 4060B associated withtube 4020B. As fluid is pushed through each oneway valve respective earpieces 4000 inflate. An optional one way valve per tube (not shown) can be used to make sure that the maximum pressure in eachtube -
FIGS. 21A and 21B illustrate the operation of at least one exemplary embodiment. Note that materials used for construction of earplugs, hearing aids, headphones, balloons and membranes can be used to construct exemplary embodiments used as earplugs. The device includes areservoir 10, afluid channel 40, avalve 20 andexpandable element 30. Thereservoir 10 includes a medium that can be tailored to vary the acoustic spectrum as a function of frequency. The distal end (right end ofFIG. 21A ) is inserted into an ear canal. The user then depresses Y1 thereservoir 10, which moves fluid from thereservoir 10 through thefluid channel 40 in a single direction as provided by the oneway valve 20. The fluid movement into theexpandable element 30 expands (Z1) theelement 30 to a desired extent. The modification of any acoustic spectrum that passes through the earplug can be tailored (acoustically shaped) by varying the medium and pressure. Various non-limiting examples of various mediums will be discussed below, but in general can include liquids, gases, mixtures, colliodal suspensions, foams, gels, and particle suspensions. For example a colloidal suspension (e.g. aphron) can be held in suspension until mixed by a user (e.g.,reservoir 10 squeezed) and a chemical reaction can occur (e.g., to generate heat to warm an earplug before insertion in cold climates). -
FIGS. 22A and 22B illustrate concepts of a membrane based earplug, that should fit the majority of the population (5th percentile - 95th percentile), be easy to clean/maintain, be environmentally durable (e.g. durable silicone), maximize ability to detect/identify/pinpoint sounds, be lightweight, easily donned/doffed, and be compatible with currently fielded military equipment, to include helmets. The reservoir 2200 includes a medium specifically chosen, as described herein, to control the reflection and/or the transmitted attenuated acoustical spectrum. Astent 2210 with a cut 2220 (to facilitate bending), channels the medium into a flexibledistal end 2230. Thevalve 2240 allows one way passage of the medium into the distal end expanding the distal end (see operation inFIG. 22B ). To release the pressure a user can press on thestent 2210, which bends because of thecut 2220, placing pressure on thevalve 2240 opening the valve deflating the distal end. Alternatively, a house for asafety flange 2250 can be designed so that a user can squeeze the safety flange toward the stent to deform and open thevalve 2240. - At least one example,
FIGS. 23A and 23B , illustrates of an exemplary embodiment, includes anearplug 2300 with no valve, for example employs a manual push dimple/tab 2310 system having a fastener in the reservoir (e.g., Velcro™) that fastens (e.g.,portion 2320 interlocking 223 with portion 2330) when pushed holding the fluid (gas, or liquid) in an inflation element until manually released (e.g.,tab 2310 pulled to pull apart the Velcro™). The holding force FL of the reservoir internal fastener must exceed the natural restoring force of the expandedinflation element 2370. To release the expanded distal end a user pulls the tab to overcome the internal holding force of the reservoir. Note that theearplug 2300 can include abody 2350 having various thickness, encompassing afluid chamber 2340, connected to achannel 2360, terminating at aninflation element 2370. When thetab 2310 is pushed Z the fluid moves from thechamber 2370 into and inflating at least a portion of theinflation element 2370. - At least one further exemplary embodiment can be used as a sound panel or insert, described in more detail below with respect to
FIGS. 27-31D .FIG. 24 illustrates an example of anembodiment 2400 where the membrane and/or medium can be designed to tailor the transmitted attenuated sound profile and/or the reflected sound profile (e.g., for use in concert halls). For examplesmall filaments 2463 can be built into themembrane 2462 to absorb sound frequencies associated with the natural frequency of the filaments. ThePanel 2400 can be configured such thatincident wave 2411 having aspectrum 2412 incident on thepanel 2400 results in a reflectedwave 2421 havingspectrum 2423, and a transmittedwave 2431 having aspectrum 2433, where the panel has modified the initial spectrum passing through thepanel 2432 into the resultant transmittedspectrum 2433. ThePanel 2400 can include several layers including a combination membrane X1 that includes amembrane 2450 under tension anabsorptive layer 2452 and a medium 2453FIG. 25A illustrates anembodiment 2500 where themembrane 2550 includescavities 2560 that can be filled with or without (e.g., gas, liquids, suspended solids) mediums to design particularresonant frequencies 2525 associated with the cavities, affecting both the transmitted and reflected acoustical spectrum.FIG. 25B illustrates anembodiment 2600 where the membrane is composed of electroactive polymers, (e.g., Nafion™) where a voltage difference across the membrane can stiffen the membrane affecting the reflected and transmitted acoustical profiles. For example a treated Nafion™ membrane, for example as done for artificial muscle research, can be used as themembrane 2630 for a panel, where thevoltage 2610 across the membrane (‘across’ with respect to exterior and interior) can be low initially (e.g., 0.25 volts). When enhanced reflection is desired the voltage can be increased (e.g., 1.5 Volts). The fabrication of artificial muscles as known by one of ordinary skill in the art is described in EP Patent Application 0924033 A2, filed 14 Dec. 1998 incorporated by reference in its entirety. -
FIG. 25C illustrates anadditional embodiment 2690 where a sound panel/insert in accordance with an embodiment has been inserted into an ear muff to tailor the spectrum attenuated. An additional embodiment includes the use of the sound panel/insert as an outersoft shell 2692 of the earmuff, focusing on reflecting a portion of the spectrum before attenuation. A description of the fabrication of an earmuff is described in EP Patent Application No. EP 1811932 B1, filed 16 Nov. 2005 incorporated by reference in its entirety. For example an example of a sound insert in accordance with at least one embodiment of the present invention can be incorporated into the cup shaped cap and/or as part of or inplace of the pressure-equalizing means in application EP 1811932. the -
FIG. 26 illustrates at least one exemplary embodiment of an earplug (e.g., foam, polymer flange) with ahollow chamber 2100, which has a filler material (e.g., water, aphrons, water with solid particles suspended, oil with particles suspended 2140), that can be compressed and inserted 2120 into a compactedform 2130 in the ear canal. Note that while compacting the earplug the pressure of the interior can increase. The suspended particles oraphrons 2140 can be tailored with various materials tailored to the specific attenuation properties desired. -
FIG. 27 illustrates anacoustic shaping panel 2700 in accordance with at least one exemplary embodiment andFIG. 28 illustrates a cross section of the panel illustrated inFIG. 27 . Thepanel 2700 can includefastening elements 2871, or can have attachment elements on at least one side of the panel 2700 (e.g., Velcro™ attachment). Referring toFIG. 28 , anincident 2841 acoustic wave 2840 (only one frequency illustrated for clarity) withamplitude 2842 passes through thepanel 2700. Depending upon the desired acoustic shaping, thepanel 2700 will modify different frequencies in various methods, for example reducing the amplitude (measured in Decibels or dB). The transmitted 2851acoustic wave 2850 has a reducedamplitude 2852. The reduction amount of the incident amplitude (2852) is a function of the properties of the case (e.g. front 2810, back 2820, and rim 2830) of the panels and the properties of the medium 2880. The medium 2880 can be contained within a medium retainer container 2870 (e.g., a bladder). The medium 2880 can be inserted under various pressures to obtain various levels of amplitude reduction (e.g., attenuation). -
FIG. 29 illustrates attachment of the panels ofFIG. 27 on awall 2900 in accordance with at least one exemplary embodiment. In the non-limiting example illustrated, the acoustic properties of awall 2900 can be modified by addingmultiple panels 2700 which are placed 2910 next to each other. -
FIG. 30A illustrates cross section of an acoustic shaping panel in accordance with at least one exemplary embodiment. Referring toFIG. 30A , anincident 3041 acoustic wave 3040 (only one frequency illustrated for clarity) withamplitude 3042 passes through the panel. Depending upon the desired acoustic shaping, the panel will modify different frequencies in various methods, for example reducing the amplitude (measured in Decibels or dB). The transmitted 3051acoustic wave 3050 has a reducedamplitude 3052. The medium 3080 can be contained within a medium retainer container 3070 (e.g., a bladder).FIG. 30B illustrates a closeup of the medium illustrated inFIG. 30A . In the non-limiting example illustrated inFIG. 30B the medium 3081 includes asuspension 3084, for example an aphron including asheath 3083 andcore 3082. For example thesheath 3083 could be an aqueous solution including a surfactant and acore 3082 including a mixture for example oil, or H2O+NaCl, or other mixtures. -
FIGS. 31A, 31B, 31C, and 31D illustrate variations of cross sections of acoustic shaping panels in accordance with various exemplary embodiments. Panels can include various combinations of mediums to shape the acoustic properties of the panels, or a combination of individual panels. For exampleFIG. 31A illustrates twomediums FIG. 31B illustrates two panels attached 3113 (e.g. via Velcro™, glue, screws, nails). Additional non-limiting examples are illustrated inFIG. 31C andFIG. 31D , where various combinations of mediums are combined to provide tailored acoustic shaping properties of the panels. For exampleFIG. 31C includesmediums fasteners 3171 andFIG. 31D includesmultiple mediums -
FIGS. 32A, 32B, and 32C illustrate the configuration and operation of at least one exemplary embodiment of an earplug. Theearplug 3200 includes areservoir 3270, amoveable element 3260, asafety flange 3250, avalve 3240, afluid channel 3230, adistal end reservoir 3220, and adistal end shaft 3210. Theshaft 3210 can expand for example including regions of various thicknesses (e.g., athin region 3245 and a thicker region 3247), or the shaft can have a port from the distal end reservoir to a flexible element around the distal end of theshaft 3210 which expands while the shaft remains generally constant. -
FIG. 32C illustrates operation of the earplug Illustrated inFIG. 32A , where themoveable element 3260 is depressed (squeezed) for example by a user’s fingers, to constrict thereservoir 3270. The constriction ofreservoir 3270 forces the medium in the reservoir through thechannel 3230 past the valve into thedistal end reservoir 3220. The passing of the medium through thevalve 3240 prevents the return of the medium into thereservoir 3270, thus once depressed the fluid remains in or near the distal end reservoir. If the shaft is flexible then thethin wall portion 3245 will expand 3280 in response B1 to the reservoir constriction A1. Note that a flexible element (not shown) can be encased around the shaft where fluid entering the distal reservoir travels via a port to the flexible element expanding the flexible element, which becomes theexpandable element 3280. Note that a modification to the non-limiting example illustrated can include a second return valve that opens when a design pressure is reached, for example if one seeks to remove the earplug, when upon pulling the pressure is greater than a designed level (e.g., 400mbar gauge pressure) then medium will flow from thedistal reservoir 3220 to thereservoir 3270.FIG. 32C illustrates use of theearplug 3200 in an ear. -
FIG. 33 illustrates another non-limiting example of an embodiment. Theearplug 3300 is a foam plug with a reservoir and afinger tab 3310 to hold. A user squeezes C1 the foam to a smaller insertion form, which is inserted D1 into theear canal 3320. Note that the reservoir can include a fluid foam medium, which can be compressed (for example where the gas bubbles get smaller upon compression), thus increasing the pressure of the inserted reservoir. -
FIGS. 34A, 34B, and 34C illustrate the configuration and operation of at least one exemplary embodiment. Theearplug 3400 includes areservoir 3470, amoveable element 3460 with adistal end 3420, asafety flange 3450, avalve 3440, afluid channel 3430, adistal end reservoir 3430 and at least onecontact 3245. Note thesafety flange 3450 can additionally include a flange reservoir.FIG. 34B illustrates the operation theearplug 3400, where thereservoir 3470 is constricted by moving E1 (squeezing) themoveable element 3460 forcing a portion of the medium through thevalve 3440 into adistal end reservoir 3431 and optionally a safety flange reservoir. The medium moving into thedistal reservoir 3431 allows the reservoir to remain constricted by thevalve 3440 prohibiting backward flow. Thecontacts 3245 move as themoveable element 3460 is moved, where thecontact 3245 press lightly against the walls of the ear canal securing the earplug.FIG. 34C illustrates use of theearplug 3400 in an ear. -
FIGS. 35A, 35B, 35C, and 36 illustrate the configuration and operation of at least one exemplary embodiment.FIG. 35A illustrates a non-limiting example of anearplug embodiment 3500, including a deformable casing 3510 (e.g. foam), encircling areservoir 3520, avalve 3540, a flexibledistal end 3535, and optionally aflange 3530.FIG. 35B illustrates the operation of theearplug 3500, where depression G1 of thedeformable casing 3510 constricts thereservoir 3520 forcing a portion of the medium past the valve into the flexible distal end 3535 (e.g., a balloon on a shaft, a flexible shaft with varying thickness) expanding H1 the flexibledistal end 3535. The expansion of the flexibledistal end 3535 can expand theflange 3531. In at least one embodiment a release mechanism can be included for a user to squeeze open a flexible valve, allowing passage of the medium from the flexibledistal end 3535 back to thereservoir 3520. For exampleFIG. 35C illustrates an incorporated release mechanism that when pressed M1, effectively presses N1 on the flexible valve opening the valve for backflow.FIG. 36 illustrates use of theearplug 3500 in an ear. - Although considerable discussion has been included with respect to use in earplugs, additional embodiments of the invention can be used in other systems and devices that can benefit from controlling the acoustic spectrum passing through the device. For example, helmets, flexible wrap that is wrapped around devices for acoustic isolation, tool handles (e.g., jackhammers), around the hull of ships to mitigate acoustic loss, and other uses one of ordinary skill in the relevant art would know. For example
FIG. 37 andFIG. 38 illustrates an embodiment used in a helmet 3700 (e.g. for use on aircraft carriers or other noisy environments) whereseveral liners 3710 and 3720 (although a single liner can be used), where the liners (3710 and/or 3720) each can include different fluid mediums to shape the acoustic profiles entering thehelmet 3700. -
FIGS. 39-40 illustrates various flexible distal ends developed by Innovation Labs and Dr. Keady, whileFIG. 41 illustrates a novel distal end spiral feed system which enhances uniform expansion about astent 3910. Thetip 4000 can include an acoustic port or be sealed. Theexpandable membrane 3900 expands and is attached bystent 3910.FIGS. 42-44J illustrates multiple examples of embodiments for earplugs, hearing aids, and earpieces.FIG. 42 illustrates anearplug 4200 including astent 4210 and aninflation element 4220. The inflation element can be formed as asingle unit 4230.FIG. 43 illustrates the system ofFIG. 40 . Aninflation tube 4350 can be placed through ahole 4331, then anend 4360 wrapped 4330 around thestent 4310, withholes 4340 in the inflation tube. When the winding in completed the end of theinflation tube 4350 is inserted through asecond hole 4332.FIG. 44A illustrates an earplug/hearing aid 4400 having anambient microphone 4410, abody 4420 that serves also as a depth control flange, inflation tubes 4430 (feed tubes) a one way vent 4440 (e.g. valve), receiver/microphone 4460, andwires 4450.FIG. 44B illustrates an embodiment of an earplug/hearing aid 4500, includinginflation tubes 4530,depth control flange 4520,inflation element 4540,tab 4560,interlocking mechanism 4570,batteries 4510, where a user that presses inward, A to B, forces fluid into theinflation element 4540 expanding tehinflation element 4540 from C to D.FIG. 44C illustrates an embodiment of an earplug/hearing aid 4600, including aninflation tube 4610, abutton 4680 pressing thebatteries 4670, where a user can press thebutton 4680 engaging thebattery 4670 to supply voltage toelectrodes 4640. Where theelectrodes 4640 are embedded in a medium 4660 (e.g., water) to turn the medium into gas (e.g., electrolysis), where the gas and fluid have a increased pressure that expands theinflation element 4630. The earplug/hearing aid 4600 can include anambient microphone 4650, and an internal receiver/microphone 4620.FIG. 44D illustrates anearplug 4700 including an interlocking mechanism 4710where when a user moves a tab from position A1 to B1 moves fluid in a reservoir, from A3 to B3, into aninflation element 4720 expanding the inflation element from A2 to B2.FIGS. 44E, 44F, 44G and 44H illustrate ferrofluid and/or electro fluid earplug/hearing aid systems. For exampleFIGS. 44E and 44F includeambient microphones microphone ports FIGS. 44E and 44F additionally includecoils ferrofluid hearing aid 4800 an opposingcoil 4840. The ferrofluid can react to the magnetic fields moving into and way from theinflation elements 4830, expanding them.FIG. 44G illustrates aferrofluid system 5000 withferrofluid 5010 in isolated chambers in aflange 5010 where acoil 5030 changes the local magnetic field collapsing or releasing theflange 5010. Theearplug system 5100 illustrated inFIG. 44H includes a restoringmembrane 5120 that when expanded 5121 exerts a restoring force attempting to impose the attraction of the ferrofluid responding to an increased magnetic field (e.g., moving from K to L). When the magnetic field is released (current to minimal) the restoring membrane forces the ferrofluid into the inflation element expanding it from 5151 to 5150.FIGS. 44I and 44J illustrate the same system using apush button 5220 to engage thebattery 5210 with themagnetic coil 5230 increasing the current and applying a magnetic field which attracts the ferrofluid from the tip to the restoring membrane region expanding the restoringmembrane 5240B. - Additional exemplary embodiments use a field responsive fluids (e.g., Electric and Magnetic Fluid Technology: Any device portion that includes ferrofluids, magnetorheological fluids, and Electro-rheological fluids/electric field responsive fluids. For example one exemplary embodiment uses a magnetic generator (e.g., coil) to control FerroFluid in an earpiece to move from one point of the earpiece to another, and/or to change the attenuation characteristics of the earpiece. At least one exemplary embodiment uses an ER fluid to change the attenuation properties via the application of an electric field. For example for an earpiece if the insertion depth control flange contains an ER fluid the viscosity of the fluid can be changed by applying an electric field across the flange changing the characteristics of the flange.
- At least one exemplary embodiment also use a combination ER and FF fluid by mixing them so that a magnetic field can be used to move the fluid while an electric field can be used to gellify the fluid.
- At least one embodiment is directed to using acoustic (e.g., earphone), haptic, and visual indicators to notify persons of a harmful environment, and is even control vehicles so as to decrease danger to items and persons.
FIG. 45 illustrates a sample work environment, whileFIG. 46 illustrates a sample of the computer display equivalent of the work environment ofFIG. 45 . - Notification can take the form of various devices and methods (acoustic, haptic, visual, thermal, and combinations of such). Exemplary embodiments are directed to or can be operatively used on various devices, helmets, safety glasses, watches, belt buckles, passive earplugs for hearing protection or electronic wired or wireless devices (e.g., hearing aids, ear monitors, earbuds, headphones, ear terminal, behind the ear devices or other acoustic devices as known by one of ordinary skill, and equivalents) or any other device attached to the body. For example, an ambient microphone can measure the ambient sound pressure levels a user is exposed to and when the exposure level reaches a threshold level (e.g., 90% of daily recommended exposure) a tactile notification device can be activated to notify the user, alone or in combination with another notification device (e.g., visual LEDs). In all of the examples illustrated and discussed herein, any specific values should be interpreted to be illustrative only and non-limiting. Thus, other examples of the exemplary embodiments could have different values.
- The non limiting embodiment discussed below is directed to a personal noise exposure monitoring system, however any notification system where a tactile/acoustic/visual notification can be used is within the scope of the invention. The system will not only log noise exposures but also provide immediate warning to the worker about then-current, potentially hazardous noise exposures, as well as secondary relevant information so that the worker will know more details about his exposure level and dose, and can make informed decisions to protect themselves. This is important because noises in workplaces are often not constant nor are the noise sources stationary, so workers need to be aware of changing environments and concomitant exposure levels due to either their moving around or variations in equipment/process emissions or movements. The head-mounted system, can both warning and informational displays for the worker, the worker who works in an environment where noise exposure levels vary will be able to determine when and where he/she needs to wear hearing protection devices or take other preventative action.
- Most current dosimeters are not designed to provide instantaneous noise information to a user; rather they are designed to prevent tampering of the settings and the data; this feature thus obviates a worker from gaining real-time information about surrounding noise. Even those dosimeters that are designed to display data to the workers directly are designed with on-unit visual displays that require the worker to turn their head and intentionally look for information, which is not always in a readily-understandable form, and is certainly not designed to warn the worker of imminent hazard potential. The current dosimeter designs are acceptable to measure noise exposure of a worker in a work-shift and record them for later analysis and comparison to some action or criterion levels, such as those promulgated by OSHA or the military. In addition to the traditional functionalities of dosimeters, the proposed personal noise exposure monitoring system will be able to provide real-time noise hazard information to the workers via multi-modal displays that will draw the worker’s immediate attention by redundant sensory modalities (visual and tactile senses) to provide the proper levels of information to first warn, and next to inform about the hazard in more detail and offer preventative advice. People tend to respond faster and quickly to multi-modal displays than to a uni-modal display. Furthermore, the redundancy of multi-modal displays also provides more resistance to masking or interference effects that may cause one of the modalities to be missed, and provides a backup warning path in the event of one modality’s failure. Once the worker is aware that he/she is under a present or imminent noise hazard, he/she can then look at the secondary visual display on the device to gain more detailed information about the noise’s level and dose, and receive advisory guidance on possible actions to take to avoid noise-induced hearing loss.
- Various thresholds can be set. For example, the OSHA regulation (1983) for noise exposure allows a time-weighted average (TWA) exposure of 90 dBA (100% dose) for an 8-hour work shift as the criterion level, but hearing conservation programs are required when the TWA is at 85 dBA (50% dose) and above, which is the action level. On the other hand, NIOSH (2012) recommends 85 dBA TWA for an 8-hour work shift as the criterion level or 100% dose. Also, different agencies and branches of the U.S. military recommend different exchange rates for dosage calculation as well. Various displays can be tailored for different work conditions and can the type and form of tactile notificator. For example possible examples of display formats for the head-up visual display could be colored LED lights with varying colors, using standards of green, yellow, and red, and/or blinking patterns, alphanumeric displays with different languages, or visual icons. The tactile displays can be parameterized with varying intensity, pulse rates, and/or vibration patterns. Characteristics of cultural subgroups can aid in designing multi-modal displays rendering them cross-cultural in effectiveness. Identification of such characteristics can be used in notification systems aiding in enhanced user acceptance.
- In view that a noise environment is dynamic in many workplaces, at least one embodiment includes a quickly-responding scheme for alerting workers of their immediate noise exposure. The scheme takes into account workplace noise exposure characteristics so that the alert timing can be beneficial or early enough so that workers can take preventive actions.
- At least one embodiment can use multi-modal displays, where multiple methods of notification can be used, for example a visual display and/or tactile display.
- Visual display can be subdivided into two levels: 1st level visual display can be colored LED lights that can be used to alert the worker to capture immediate attention to noise hazard; 2nd level visual display can be an alphanumeric display that can display detailed information such as current sound level, cumulative exposure dosage, and expected time to maximum dose at current sound level or cumulative sound exposure.
- The tactile display, transducing small vibrations to the user’s body (e.g., head) via tiny vibrotactors (e.g., mounted on eyeglass temples or in a hardhat headband), can be a complimentary or redundant warning avenue to the 1st level visual display to command attention. However, it is also possible to design the tactile display to convey more information than a simple warning via variations in the vibration pattern, such as increasing the vibratory frequency and/or amplitude as noise level rises, or providing a constant pulsating, compressive vibration as maximum dose is imminent. Another possibility of tactile display is conveying directionality of noise if the noise requires the worker to localize the sound and react to it in certain way. Localization of a backup alarm could be such an example, because hearing and heeding a backup alarm in noise is a significant safety problem in industry (Alali & Casali, 2011).
- At least one embodiment can consist of multi-modal displays and a selected, modified dosimeter. Additional embodiments can be coupled with safety glasses and other devices such as a safety helmet (hardhat). As most noise hazard information is available from currently available dosimeters, existing, off-the-shelf dosimeter can interact with our multimodal displays of at least one embodiment.
- A first embodiment add multimodal or tactile displays to safety glasses. Safety glasses will provide a convenient mounting opportunity on the rim of the eyeglass lense plane, or at the hinge of the temple piece, to display colored LED lights that will alert the workers with varying noise hazard information. A small vibration transducer (i.e., vibrotactile device) will be mounted on, or embedded within the temple piece of the safety glasses, and will complement the visual LED signal to draw immediate attention of the worker when needed to convey a conspicuous warning. Thus, the worker will be alerted when there are significant changes to his/her noise environment, or present or imminent hazards, via both colored lights and vibration. Example of such changes can include a sudden increase of noise level that exceeds the allowable limits of either continuous noise (115 dBA rms) or impulse noise (140 dB peak). Cumulative noise dosage at a preset limit for warning activation can be another reason for alerting the worker. A separate alphanumeric display (“head-down” style) can be attached to the dosimeter itself, to display detailed noise hazard information when necessary. Simple pushbuttons can allow the workers to navigate the system and retrieve the necessary information, which can include dBA level and dose data, as well as corresponding preventative measure information which will guide the worker.
- A second can be integrated with safety hardhats instead of safety glasses. Hardhats will allow several positions to mount both the visual LED display, such as on the underside of the brim, as well as the vibration transducers, which can be headband-mounted. As mentioned prior, one can add additional vibration motors to convey the direction of a noise source, such as a backup alarm for a vehicle, increasing safety in dynamic workplaces where those alarms may be masked by the noise.
- The safety glasses, goggle, face shield, can include several multi modal notification systems, for example visual (e.g., LED, color lights, varying light frequency and/or intensity in time), haptic (e.g., surface pressure variations, vibration motors, varying vibration frequency and/or intensity in time), audio (e.g., alarms, audio frequency and/or intensity variations in time), and temperature (e.g., variations in temperature amplitude in time).
- A haptic indicator can also be used in accordance with at least one embodiment. For example a vibrator motor (e.g., adafruit’s vibrating mini motor disc product ID 1201, 1.5
V 20 mA Micro Pager Motor) can be mounted in user safety equipment. The haptic indicator can be mounted where a user will most notice. For example on the bridge of safety glasses or throughout a helmet, where the haptic intensity can be varied to provide information on location of danger. For example a helmet with various haptic indicators can vary which haptic indicator is activated depending upon the location of the hazard. - A non-limiting example of a dosimeter, for example 3M™ NoisePro Kit NP-DLX, which can be fitted onto a belt.
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FIGS. 45-46 illustrate a vehicle and a worker in a dangerous work environment and a notification system of at least one embodiment. Sensors (e.g., dosimeter, transducers) on vehicles and workers can be fed (e.g., via Electromagnetic Waves) into a monitoring system (e.g., a computer). The monitoring system keeps track of the location and movement of hazards in the work environment, predicts future potential hazards (e.g., using Kalman Filters to predict location) and sends notification signals to both vehicle operators and workers. The notification signals can activate alarms and can even deactivate vehicles if needed. The notification signals can take various forms , for example they can be audio (tones, vocal, acoustic icons such as sounds similar to the hazard or recognized as having a particular meaning) haptic, visual, and/or a combination of these. -
FIG. 46 illustrates a computer monitoring system coupled with personal notification systems in accordance with at least one embodiment. The monitoring system, for example including a processor, can model the work environment 6200 (e.g., using simulation agents (e.g., 6131-W1, and 6133-W2) to model the workers, C, C++, MatLab™). The montoring system can then send signals wirelessly or wired to any object in the work environment that has a receiver. The received signal can be used by a processor to activate an alarm on any object. Optionally the processor can control the object to minimize the hazard. For example the monitoring system can control vehicles in the work environment, for example slowing them down upon calculation of imminent harm (e.g., a few seconds prior to impact) to a worker. For example if a worker is too close to a vehicle backing up the processor can send a signal to slow the vehicle down. -
FIG. 45 illustrates a work environment and an equivalent model. For example thework environment 6000 can include vehicles (6001, 6003, 6005, 6007) and workers (6011, 6013). A computer can model 6200 theenvironment 6000, where vehicles are illustrated as symbols (6121, 6123, 6125, 6127) and workers are also illustrated as symbols (6131, 6133), such as flow chart shapes, letters abstract forms. Regions around workers can be set (6151, 6161, 6171, 6181) so that when vehicles enter certain regions signals can be sent, for example signals can be sent to the workers so that audio, visual, and/or haptic warnings are played. Regions (e.g., 6151) can vary in size depending upon possible threats, for example if there is a fast moving vehicle (e.g., speed Vs) and the average notification and response time has been determined to be t-response, then the radius from the worker, for example from 6131, to determine 6151 can be at radius-6151=Vs*t-response*SF, where SF is a safety factor (e.g., 1.01-10.0), while the radius to determine 6161 could be Vs*t-response*SF*SCF, where SCF is scale factor (e.g., 1.1-100.0). The radii can vary as the movement various of the various vehicles and movement of the workers. Each vehicle and/or worker can contain a transmitter, receiver and a processor (e.g., for a worker their cell phone) attached to a notification device or with the ability to interface with a worker’s headgear (e.g., hearing protector, earphones) or the vehicle itself (e.g., via the vehicles display and/or speakers). For example, a message could be send to the display of a vehicle presenting a warning that a worker is close. -
FIG. 47 illustrates an embodiment of an earphone/earplug 7010. The earplug/earphone can include and acoustic channel if sound is to be played through thestent 7400. Themembrane 7500 at the distal end can be expanded whentabs 7000 are released (e.g. unpinched). Thetabs 7000 can be connected by aresilient connector 7100, which tend to restore the tabs to a position B when released. Whentabs 7000 are pinched, position A, themembrane 7500 collapses to thestent 7400. When thetabs 7000 are released then thefirmer portion 7200 pushes against areservoir 7300 which pushed a fluid (air, liquid, low viscous gell, fluid with suspensions, ER MR fluid) through thestent 7400 expanding themembrane 7500. The membrane can be a flexible material, such as a silicon base, or fixed volume such as a urethane, although any material that can be used for inflatables both medical and lower grade can be used. -
FIGS. 48A and 48B illustrate a membrane eartip. The eartips can be sealed after formation, for example via injection molding with a gap, then sealed afterwards, or 3-D printed as sealed. The medium encompassed by the eartip can be injected prior to sealing or after sealing (e.g., hypodermic needle, and subsequent sealing epoxy). The eartips can be fabricated with various material varying from 10-120 durometer. Silicone, urethane, rubber, or other flexible polymers and materials can be used in addition to materials currently used in eartips as known by one of ordinary skill in the art. In at least one embodiment of the eartip has various portions with different thicknesses. For example region I, the portion of the eartip that enters the ear canal first can be of a different thickness (t1) than region III (t3), for example region III can be thicker, Region II can also be of different thickness (t2). For example the thickness of region I can be thicker than region II, so that when region I is compressed, region II can expand in response (A), while region III can expand less. The expansion of region II creates a restoring force creating pressure in region I pressing against the ear canal wall facilitating sealing. The thickness can vary between a fraction of a mm to several mms. The medium in the eartips and the materials forming the structure (7600, 7700) can be the same type of material as in the earphone/earplug ofFIG. 47 . The various thicknesses can be chosen so that region II expands (Region II-A), providing an opposite restoring force, when region I is compressed (Region I-A). - The eartip can be fabricated by various means, for example injection molding, then sealed with various filler mediums (e.g. gas, liquid, gell), and inserted upon a
stent 7700, for example theeartip 7600 can have an extension portion that slides over thestent 7700. - These designs are mostly closed, entrapped fluid designs, air or liquid, although the valve versions can accommodate open system designs as well. Although they may be open until compressed, for example upon insertion into an ear canal or other opening, then an enclosed chamber, cavity can be created.
- Below, as depicted in
FIGS. 49-53 , are three sample versions. That operate on a principle of a first member pressing against a reservoir (states Y, K, L), where the fluid in the reservoir has been pressed into an expandable tip. In the initial state, the first member presses against the reservoir, filling a small expandable tip. When a user wishes to insert the earphone, a second member is engaged, moving the first member away from the reservoir (states X, J), or a method of releasing any pressure, for example pressing on a flexible valve (M). The reservoir can be attached to the member so that as the first member (e.g., 8040, 8130,8250) is moved (e.g., X, M, J) , the reservoir (e.g., 8011, 8140, 8311) re-expands, serving to empty the expandable tip (e.g., 8010, 8110, 8210). Another version uses the restoring elastic force from the bladder in the expandable tip (e.g., 8010, 8110, 8210) to refill the reservoir when the first member is released. For examplesecond member 8040, attached to afirst member 8050, is pinched with respect to rigid member 8030, movingfirst member 8050 away from tip 8010. 8050 is attached toreservoir 8011, so that as it moves away from the tip 8010, fluid moves from tip 8010 intoreservoir 8011. Once theearphone 8000 is inserted, thesecond member 8040 is released (pivots away from 8030), and an elastic force, for example fromresilient member 8020, moves thefirst member 8050 against the reservoir, again refilling the expandable tip 8010 inside the ear canal. When a user wishes to remove the earphone, thesecond member 8040 is engaged again, pivoting it toward 8030, and the expandable tip 8010 is deflated and theearphone 8000 is removed.FIG. 49 shows a fingertip-operated pinching mechanism to engage the second member, whileFIGS. 52-53 show a finger pressing mechanism to engage athird member 8240.FIGS. 50-51 utilizes a lanyard control system, wherein thelanyard bladder 8140 is pressed to inflate the expandable tip, while pressing 8130 opens a valve, thereby releasing the fluid and collapsing theexpandable tip 8110. Each of these versions is constructed to minimize complicated valving; for example, versions I (8000) and II (8200, 8300) do not contain valves, while version III (8100) includes a collapsible flexible valve, which inventors have used in many prototypes, the valves of which are readily available. The reservoir is attached to the expandable tip via very small channels similar to Microphone-in-Real-Ear (MIRE) probe test tubes. The versions can be fabricated so that the tip is removable, requiring a flexible valve which is opened when a small pen tip-sized tube coupler is pressed into the opening at the base of the removable tip, but closed otherwise so that tip removal is possible. Note that members such as 8030, 8040, 8050, 8250, 8240 can be made of semi rigid plastic or any other type of semi-rigid material that has been used in earphones. The resilient members such as 8020, 8230 providing a restoring force can be made of flexible polymers, rubbers, silicones and similar elastic property materials. Theexpandable tips - These designs, while air-filled within the confines of the membrane, have pathways for air that connect with the ambient atmosphere, thus the internal pressure is the same as atmospheric pressure. There is no air or liquid reservoir, and no need for valves or other airtight sealing mechanisms to seal-off the membrane bladder. An example of a relatively simple semi-pneumatic eartip is shown in
FIGS. 54A-55 . The material for this semi-pneumatic design will be an elastomer, which will be parameter-specified as to Young’s modulus of elasticity, nonlinear stress-strain curve, and other relevant metrics. The notes onFIGS. 54A-55 generally depict the operation, but a brief explanation may be helpful. - Basically, the earphone nozzle is pushed gently forward to act as a “plunger” to “stretch” the elastic membrane longitudinally, rendering it just slightly larger in diameter than the nozzle for ease of insertion into the ear canal. Once in the canal, the “plunger” is retracted by the elastic spring’s restoring force inherent in the membrane material (essentially, this occurs coincident with the user’s fingers releasing of the earphone housing). Thus, the membrane material returns to its at-rest bulged state, thus expanding into a bulge or donut-shape around the earphone’s nozzle, providing a seal against the ear canal walls. To actuate in this simple manner, the design will be comprised of a “shape-memory” elastic polymer (elastomer), and in view of the small longitudinal dimensional change necessary between its at-rest and stretched states, the dimensional operating range can easily be maintained well-within the elastomer’s elastic limit. Material with fairly low hardness, on the order of 30-60 Shore A durometer, will likely be used to enable the “bulge” to conform to irregularities of the individual ear canals it may encounter in practice. It is important to note that the air inside the membrane is not sealed within it, but shared with the outside air through the nozzle and the earphone ports. This ensures that when the membrane retracts slightly backward, i.e., away from the eardrum, into its at-rest bulged state, that no suction pressure is pulled against the eardrum which could be painful. This design has many options, including variants of the profile of the at-rest shape of the membrane, which could be pre-formed into two sealing donut shapes rather than the one shown, or even other shapes. Also, in lieu of using the earphone nozzle as the plunger to elongate the membrane for easy insertion, a separate thin stem could be provided to effect the same function.
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FIG. 54A illustrates the elongation state of a pull ring configuration. Housing 5400 (FIG. 54B , e.g. QC-20) A pre-shapedelastic membrane 5440, can fit around the stent ofhousing 5400 and elongated (X) during insertion. An open ended cup 5430 can be inserted to retain themembrane 5440. Elongation can occur by pullingring 5410. Upon release of thering 5410 the elasticity of themembrane 5440 returns the membrane back to the resting state (e.g.,FIG. 55 ) and the original shape (Y) prior to elongation. Thetab stop 5420 prevents themembrane 5440 from moving beyond a certain position. -
FIG. 56 is an illustration of anear device 9000 prior to insertion into anear canal 9002 of an ear in accordance with an example embodiment. A section ofear device 9000 is cutaway to provide detail of internal features. In one embodiment, the section ofear device 9000 that is cutaway is substantially equal to what is shown and disclosed herein.Ear device 9000 can comprise the same materials disclosed herein above for the ear tips, inflatable ear sealing structures, ear plugs, and other orifice devices to sealear canal 9002.Ear device 9000 is illustrated outside anauricle 9004 of the ear. In general,ear device 9000 is configured to occlude or partially occludeear canal 9002.Ear device 9000 comprises astent 9006, afirst folding member 9010, asecond folding member 9012, and astop flange 9008. In the example,stent 9006 is a tube or conduit having aproximal opening 9014 and adistal opening 9016.Stent 9006 is not limited to a single tube but can comprise a structure having one or more tubes or pathways.Stent 9006 can also made solid or having one or both openings plugged such that no pathway throughstent 9006 exists. In one embodiment,stent 9006 is cylindrical in shape and flexible to conform to a torturous shape ofear canal 9002.Distal opening 9016 is exposed toear canal 9002 whenear device 9000 is inserted inear canal 9002. In one embodiment,stent 9006 is configured to bend after insertion to maintain an un-impeded path fromproximal opening 9014 todistal opening 9016.Proximal opening 9014 as shown is exposed to an external environment outside the ear. In an example, whereear device 9000 is an ear plug for isolating the ear canal from the external environment,distal opening 9016,proximal opening 9014, or both may be closed off. Alternatively,ear device 9000 can provide the controlled delivery of acoustic information toear canal 9002. The ear would be occluded byear device 9000 and acoustic information can be provided by a transducer coupled toproximal opening 9014 ofstent 9006. In one embodiment, a transducer can be coupled to deliver acoustic information throughstent 9006 toear canal 9002. In one embodiment, a microphone can be coupled toproximal opening 9014 ofstent 9006 to retrieve acoustic information that is withinear canal 9002 for processing or delivery to an electronic device. -
Optional stop flange 9008 limits a distance thatear device 9000 can be inserted intoear canal 9002. In one embodiment, stopflange 9008 is formed circumferentially aroundstent 9006. Stopflange 9008 has a diameter greater thanear canal 9002. The size ofstop flange 9008 prevents insertion inear canal 9002. The size and shape ofstop flange 9008 can stabilize and holdear device 9000 to the ear to preventear device 9000 from working itself out ofear canal 9002 due to normal activity. Stopflange 9008 blocks sound from the external environment from enteringear canal 9002. Sound will reflect offstop flange 9008 and return to the external environment. In one embodiment,stent 9006 extends proximally beyondstop flange 9008. It should be noted thatstent 9006 can couple to or be formed integrally with a housing. The housing can include electronic circuitry and one or more sensors to supportear device 9000. For example, the electronic circuitry can be used to process acoustic signals, reduce noise, cancel noise, amplify a signal, moderate the amount of acoustical information the ear canal receives, or perform other functions related to the ear or the user. - In general,
ear canal 9002 is occluded or partially occluded by achamber 9018.Chamber 9018 is sealed to support attenuation of noise in the external environment from reachingear canal 9002.Ear device 9000 comprises afirst folding member 9010 and asecond folding member 9012. First foldingmember 9010 couples tostent 9006.Second folding member 9012 also couples tostent 9006. In one embodiment,first folding member 9010 couples tostent 9006 distal to a location wheresecond folding member 9010 couples tostent 9006. First foldingmember 9010 andsecond folding member 9012form chamber 9018 that isolatesstent 9006 from walls ofear canal 9002. In one embodiment,chamber 9018 is formed circumferentially around a portion ofstent 9006 that is configured to be withinear canal 9002.Chamber 9018 is open to the external environment prior toear device 9000 being inserted intoear canal 9002.Chamber 9018 has a diameter larger thanear canal 9002. Aring valve 9020 whenopen couples chamber 9018 to the external environment. In one embodiment,ring valve 9020 has an opening that extends 360 degrees aroundstent 9006.Ring valve 9020 is open whenear device 9000 is outside the ear canal.Ring valve 9020 can also open and close during insertion ofear device 9000 inear canal 9002. This will be discussed in more detail herein below. Thus, whenring valve 9020 opens, a pressure withinchamber 9018 will equalize to be the same as the pressure in the external environment. - In one embodiment,
stent 9006 is cylindrical in shape. First foldingmember 9010couples 360 degrees aroundstent 9006 and is located in proximity todistal opening 9016. Alternatively,first folding member 9010 can couple tostent 9006 between a distal end ofstent 9006 and distal to a location wheresecond folding member 9012 couples tostent 9006. First foldingmember 9010 extends proximally and overlies a portion of asurface 9022 ofstent 9006. In one embodiment,first folding member 9010 has a maximum diameter or cross-sectional width that is greater thanear canal 9002.Second folding member 9012 couples tostent 9006 distal to stopflange 9008.Second folding member 9012 extends distally and overlies a portion ofsurface 9022 ofstent 9006. In one embodiment,second folding member 9012 can have a maximum diameter or cross-sectional width greater thanear canal 9002. In one embodiment, the maximum diameter or the cross-sectional width ofsecond folding member 9012 can have a width less thanear canal 9002. Alternatively,second folding member 9012 can extend proximally and overlie a portion ofsurface 9022 ofstent 9006. This will be disclosed in further detail herein below. First foldingmember 9010 overlies at least a portion ofsecond folding member 9012 whethersecond folding member 9012 extends distally or proximally. -
FIG. 57 is a cutaway view ofear device 9000 in accordance with an example embodiment. The cutaway view provides detail of features withinear device 9000 that cannot be seen from an external view. The structure that is cutaway inear device 9000 is substantially equal to what is shown.Ear device 9000 comprisesstent 9006,chamber 9018, and stopflange 9008.Ear device 9000 includesstent 9006 having aproximal opening 9014 and adistal opening 9016.Distal opening 9016 couples to an ear canal whenear device 9000 is inserted into the ear canal. Conversely, proximal opening 9014 couples to an external environment outside the ear as shown. In one embodiment,ear device 9000 can be used as an ear plug to isolate the ear canal from noise in the external environment.Chamber 9018 is configured to occlude or partially occlude the ear canal. Maximum attenuation occurs whenchamber 9018 is a sealed volume within the ear canal. In oneembodiment chamber 9018 is formed aroundstent 9006 such thatstent 9006 is centered within the ear canal whenear device 9006 is inserted in the ear canal.Proximal opening 9014,distal opening 9016 or both can be plugged to prevent a path to the ear canal viastent 9006 thereby occluding the ear canal. Sealing ofstent 9006 can comprise a cover onproximal opening 9014,distal opening 9016, or both. In a second embodiment,stent 9006 can include a valve to equalize pressure between the external environment and the ear canal to support comfort ofear device 9000. In a third embodiment, one or more lumens can be coupled throughstent 9006.Proximal opening 9014 can be sealed around the one or more lumens or couple to a sealed structure.Stent 9006 acts a conduit for the one or more lumens. The one or more lumens can be used to couple one or more devices to the ear canal. In one embodiment,stent 9006 and the one or more lumens couple to a structure that is outside the ear. The structure can house electronic circuitry (e.g., processor, microphones, speakers, infrared sensors, oxygen sensors, bio sensors, pressure sensors, humidity sensors) other sensing devices. In one embodiment, the structure is sealed and insulated from the external environment such thatstent 9006,chamber 9018, and the structure prevent or reduce noise from the external environment from entering the ear canal. Sealing the ear canal from the external environment reduces noise levels within the ear canal and allows information to be provided to the ear canal in a controlled manner that can be heard even if the noise level in the external environment is high. For example, a first end of a first lumen can be coupled to a transducer. A second end of the lumen can couple to the ear canal throughdistal opening 9016 ofear device 9000. The transducer can deliver acoustic information to the lumen which is then delivered to the ear canal. Examples of the acoustic information could be voice, music, or ambient sounds from the external environment. The delivery of the acoustic information can be provided in conjunction with the noise attenuation provided byear device 9000. - Similarly, a first end of a second lumen can be coupled to a microphone. The second lumen then couples through
stent 9006 such that the second end of the second lumen is exposed to the ear canal at thedistal opening 9016 ofear device 9000. The second lumen couples sound within the ear canal to the microphone where it is converted to an electronic signal. This is useful for delivering a user’s voice for transmission to a device such as a cell phone. For example, if the user ofear device 9000 is speaking, the sound of his or her voice can be picked in the ear canal. The second lumen couples to the ear canal throughdistal opening 9016 and delivers acoustic information within the ear canal to the microphone. The voice received from the ear canal can be more intelligible than a voice picked up with an ambient microphone in a noisy external environment. The ambient microphone would pick up the user’s voice but also the noise in the external environment. Noise from the external environment is attenuated in the ear canal bychamber 9018 ofear device 9000. Thus, the user’s voice can be transmitted with less background noise thereby increasing the clarity and intelligibility of the voice transmission. Alternatively,stent 9006 can be used to deliver acoustic information instead of using lumens. Moreover, more than one stent could be formed wherestent 9006 is located thereby providing a plurality of channels from the ear canal to the external environment. In the example above, a first stent would couple to the transducer and a second stent would couple to the microphone. -
Ear device 9000 can be molded, machined, formed, or printed. In general,ear device 9000 comprises a flexible material that will conform to the torturous shape of an ear canal. In one embodiment,ear device 9000 comprises a bio-compatible material configured for insertion in the ear canal. In the example,ear device 9000 is formed from silicone. Stopflange 9008 limits the depth of insertion ofear device 9000 into the ear canal. Note thatstent 9006 extends proximally beyondstop flange 9008. Thus, a first portion ofstent 9006 is placed within the ear canal and a second portion ofstent 9006 is outside the ear canal. Achamber 9018 is formed aroundstent 9006.Chamber 9018 comprises afirst folding member 9010 and asecond folding member 9012.Chamber 9018 is configured to occlude or partially occlude the ear canal whenear device 9000 is inserted. In one embodiment,chamber 9018centers stent 9006 within the ear canal. As previously mentioned,ear device 9000 is made flexible to allowstent 9006 andchamber 9018 to bend with and around curves of the ear canal. -
Chamber 9018 ofear device 9000 comprises afirst folding member 9010 and asecond folding member 9012. At least a portion offirst folding member 9010 overlies a portion ofsecond folding member 9012. Aring valve 9020 is formed byfirst folding member 9010 andsecond folding member 9012. More specifically,ring valve 9020 is a ring-shaped opening formed by a portion offirst folding member 9010 that overlies a portion ofsecond folding member 9012. In one embodiment,ring valve 9020 couples the external environment tochamber 9018. In one embodiment,ring valve 9020 has an opening formed betweenfirst folding member 9010 andsecond folding member 9012. More specifically, the opening ofring valve 9020 is in a region wherefirst folding member 9010 overliessecond folding member 9012. In one embodiment,ring valve 9020 is formed 360 degrees aroundstent 9006.Chamber 9018 couples to the external environment sincering valve 9020 is normally open whenear device 9000 is outside the ear canal.Chamber 9018 cannot be sealed unlessfirst folding member 9010 couples tosecond folding member 9012 around the entirety ofstent 9006. Sealing ofchamber 9018 can also occur byfirst folding member 9010 coupling to a combination ofsecond folding member 9012 and a surface ofstent 9006. In one embodiment,chamber 9018 is filled with gases from an external environment. In one embodiment,chamber 9018 will be at the same pressure as the external environment due toring valve 9020 being open prior to insertion to the ear canal. A sealedchamber 9018 provides improved noise isolation between the external environment and the ear canal.Chamber 9018 can be filled with a material to further improve noise isolation or attenuation. For example,chamber 9018 can be filled with a foam, a gel, or a liquid. In one embodiment, the material withinchamber 9018 can be compressible to support a wide range of volumes that can occur due to different ear canal diameters. - In one embodiment,
stent 9006 is cylindrical in shape. First foldingmember 9010 has ananchor point 9046 that is distal to ananchor point 9044 ofsecond folding member 9012. In the example,anchor point 9046 is located neardistal opening 9016 ofstent 9006.Anchor point 9046 is anchored 360 degrees aroundstent 9006. In one embodiment,anchor point 9046 is a pivot point. A force applied tofirst folding member 9010 by a wall of the ear canal will move first foldingmember 9010 towardsstent 9006 pivoting atanchor point 9046. The force will move first foldingmember 9010 to couple to thesecond folding member 9012 thereby sealingchamber 9018. First foldingmember 9010 comprises a vertical component and a horizontal component. The vertical component offirst folding member 9010 suspends first foldingmember 9010 abovesecond folding member 9012 andstent 9006. The horizontal component offirst folding member 9010 extends first foldingmember 9010 to the first predetermined proximal location. First foldingmember 9010 terminates having aproximal end 9036 that overliessecond folding member 9012 orstent 9006. The horizontal and vertical components offirst folding member 9010 can be combined such thatfirst folding member 9010 is changing horizontally and vertically towards the first predetermined proximal location. In one embodiment,first folding member 9010 can have a curved shape. The curved shape supports insertion in the ear canal and minimizes long-term discomfort. In one embodiment, the curved shape offirst folding member 9010 can minimize the surface area offirst folding member 9010 coupling to the wall of the ear canal. In one embodiment, an external surface offirst folding member 9010 is configured to conform to the shape of the ear canal asear device 9000 is inserted in the ear canal. The walls of the ear canal applies apressure 360 degrees aroundfirst folding member 9010 during insertion. The curved shape offirst folding member 9010 also supports coupling tosecond folding member 9012 to sealchamber 9018. In one embodiment,second folding member 9012 will have a curved shape that corresponds to or is similar to the curved shape offirst folding member 9010 to support coupling and sealing ofchamber 9018. In one embodiment,first folding member 9010 is more than a hemisphere in shape but less than a full sphere. In one embodiment,first folding member 9010 will have a diameter maximum or a distance maximum fromstent 9006 that is betweenanchor point 9046 and the proximal end offirst folding member 9010. In one embodiment, anangle 9030 is formed betweenstent 9006 andfirst folding member 9010.Angle 9030 supports insertion into the ear canal.Angle 9030 is typically less than 90 degrees whenear device 9000 is outside the ear. In one embodiment,angle 9030 is 60 degrees or less whenear device 9000 is outside the ear. - In the example embodiment,
stent 9006 is cylindrical in shape.Second folding member 9012 has ananchor point 9044 that is proximal to ananchor point 9046 offirst folding member 9010. In the example,anchor point 9044 is located nearstop flange 9008 ofear device 9000.Anchor point 9044 is anchored 360 degrees aroundstent 9006. In one embodiment,anchor point 9044 is a pivot point. As shown,second folding member 9012 extends fromanchor point 9044 distally such thatsecond folding member 9012 overlies a portion ofstent 9006 betweenanchor point 9044 ofsecond folding member 9012 andanchor point 9046 offirst folding member 9010. Alternatively,second folding member 9012 can extend fromanchor point 9044 proximally such thatsecond folding member 9012 overlies a portion ofstent 9006 betweenanchor point 9044 ofsecond folding member 9012 and stopflange 9008. First foldingmember 9010 overlies a portion ofsecond folding member 9012 whether extending distally or proximally overstent 9006. -
Second folding member 9012 comprises a vertical component and a horizontal component. The vertical component ofsecond folding member 9012 suspendssecond folding member 9012 abovestent 9006. The horizontal component ofsecond folding member 9012 extendssecond folding member 9012 to a predetermined location distally or alternatively a predetermined location proximally overlyingstent 9006. The horizontal and vertical components ofsecond folding member 9012 can be combined such thatsecond folding member 9012 is changing horizontally and vertically towards the predetermined location. In one embodiment,second folding member 9012 forms anangle 9032 withstent 9006 to suspendsecond folding member 9012 overstent 9006. In one embodiment,angle 9032 can be 30 degrees to 150 degrees. In the example,angle 9032 is less than 90 degrees. In one embodiment,second folding member 9012 can have a curved shape. In one embodiment,second folding member 9012 can have a curved shape corresponding to the curved shape offirst folding member 9010 that overliessecond folding member 9012. - A force applied to a
surface 9038 ofsecond folding member 9012 will produce movement ofsecond folding member 9012 towardsstent 9006. In one embodiment, second folding member is configured to flex and conform. In general, aninterior surface 9040 offirst folding member 9010 is configured to couple tosurface 9038 ofsecond folding member 9012 during insertion ofear device 9000 into the ear canal. In one embodiment, surface to surface coupling betweenfirst folding member 9010 andsecond folding member 9012seals chamber 9018.Second folding member 9012 is configured to move towardsstent 9006 as a force is applied byfirst folding member 9010.Second folding member 9012 pivots atanchor point 9044 assecond folding member 9012 folds towardsstent 9006. -
FIG. 58 is an illustration ofear device 9000 inserted inear canal 9002 in accordance with an example embodiment.FIG. 58 is a cutaway view ofear device 9000 to illustrate internal structure ofear device 9000. More specifically the view showschamber 9018 being sealed and occluding or partially occluding the ear canal. The section ofear device 9000 that is cutaway is substantially equal to the structure shown in the figure. First foldingmember 9010 has a diameter larger thanear canal 9002. Insertingear device 9000 intoear canal 9002 applies a force tofirst folding member 9010 that motivates first folding member to move towardssecond folding member 9012. Referring briefly toFIG. 57 ,angle 9030 offirst folding member 9010 is reduced upon insertion intoear canal 9002. First foldingmember 9010 also conforms to a shape ofear canal 9002. In one embodiment,first folding member 9010 couples to the walls of the ear canal around it’s entirety such that there is no gap betweenfirst folding member 9010 and the walls of the ear canal coupling the external environment to the ear canal. First foldingmember 9010 couples tosecond folding member 9012 to sealchamber 9018.Ear canal 9002 applies a pressure or force 360 degrees aroundfirst folding member 9010. In the example,surface 9038 ofsecond folding member 9012 couples to surface 9040 offirst folding member 9010. More specifically,surface 9038 ofsecond folding member 9012 couples to surface 9040 offirst folding member stent 9006 such thatchamber 9018 is sealed whenear device 9000 is inserted in the ear canal. This corresponds to ringvalve 9020 being closed.Chamber 9018 is not sealed if any portion ofsurface 9038 ofsecond folding member 9012 does not couple to acorresponding surface 9040 offirst folding member 9010. This corresponds to ringvalve 9020 being open.Sealing chamber 9018 provides maximum noise attenuation or ear canal isolation from an external environment. In the example, noise from the external environment is attenuated bystop flange 9008 andchamber 9018. The only other path for noise to couple toear canal 9002 is throughstent 9006 or betweenfirst folding member 9010 and the walls of the ear canal. As mentioned previously, any acoustic information coupling throughstent 9006 is controlled. In one embodiment,stent 9006 can be plugged atdistal port 9016,proximal port 9014, or both. In one embodiment,stent 9006 can be made solid or filled to prevent the transfer of acoustic information toear canal 9002. An alternate embodiment for sealingring valve 9020 hasproximal end 9036 offirst folding member 9010 coupling tostent 9006 orsurface 9038 ofsecond folding member 9012.Ring valve 9020 would also seal ifproximal end 9036 coupled a complete 360 degrees aroundstent 9006. -
FIG. 59 is a cutaway view ofear device 9000 without a stop flange in accordance with an example embodiment. In the example,ear device 9000 is cutaway to illustratechamber 9018 andring valve 9020. The structure that is cutaway is substantially equal to the structure ofear device 9000 that is shown in the figure. Stop flange is removed to betterview ring valve 9020.Ring valve 9020 has an opening that couples intochamber 9018. In one embodiment, the opening inring valve 9020 is a 360-degree slot aroundstent 9006. Thus, the 360 degree slot aroundstent 9006 appears as a ring shaped opening.Chamber 9018 is a volume that is formed aroundstent 9006 that is defined byfirst folding member 9010 andsecond folding member 9012. As shown,ring valve 9020 is in an open state such that the external environment is coupled tochamber 9018.Ring valve 9020 is in the open state when a gap occurs anywhere in the 360-degree slot aroundstent 9006. The gap couples the external environment tochamber 9018. Conversely,ring valve 9020 is closed whenfirst folding member 9010 couples tosecond folding member 9012 wherebychamber 9018 is isolated from the external environment. In one embodiment,first folding member 9010 forms a 360-degree seal tosecond folding member 9012 that decouples the ear canal from the external environment bychamber 9018. - A double-
sided arrow 9050 illustrates a distance from a center ofstent 9006 tosecond folding member 9012. A double-sided arrow 9052 illustrates a distance from a center ofstent 9006 tofirst folding member 9010. As mentioned previously, a portion offirst folding member 9010 overlies a portion ofsecond folding member 9012. First foldingmember 9010 will couple tosecond folding member 9012 when the portion offirst folding member 9010 overlying the portion ofsecond folding member 9012 is moved from thedistance 9052 to thedistance 9050 or less. In one embodiment,stent 9006 is cylindrical in shape. In one embodiment,second folding member 9012 has a curved shape extending fromanchor point 9044 to adistal end 9054 ofsecond folding member 9012. In one embodiment,distal end 9054 is circular in shape having a radius equal to the distance of double-sided arrow 9050. In one embodiment,first folding member 9010 has a curved shape extending fromanchor point 9046 toproximal end 9036 offirst folding member 9010. In one embodiment, the portion offirst folding member 9010 overlying the portion ofsecond folding member 9012 can have a similar rate of curvature to prevent coupling of thefirst folding member 9010 tosecond folding member 9012 whenear device 9000 is in a quiescent state (e.g. outside the ear canal). In one embodiment, the gap between the portion offirst folding member 9010 overlying the portion of thesecond folding member 9012 is approximately constant aroundstent 9006. -
FIG. 60 is a cutaway view of anear device 9000 without a stop flange in accordance with an example embodiment. The cutaway view removes a portion ofear device 9000 to illustrate structure that cannot be seen with an external view. The portion that is removed is substantially equal to the structure that is shown in the figure. The optional stop flange is removed to viewring valve 9020. In general,ear device 9000 can have a stop flange as shown inFIGS. 56-58 to limit insertion in an ear canal.Ear device 9000 is configured to occlude or partially occlude an ear canal of an ear.Chamber 9018 ofear device 9000 is configured to be inserted in the ear canal. As shown,stent 9006 is a passageway that can be used to deliver acoustic information or receive acoustic information from the ear canal.Stent 9006 can also be used to equalize pressure between the external environment and the ear canal. Typically, a proximal end ofstent 9006 couples to an enclosure that is outside the ear.Proximal opening 9014 ofstent 9006 is a pathway ofstent 9006 to an interior of the enclosure. The enclosure can house electronic circuitry, transducers, sensors, valves, a power supply, and other devices (e.g., earphones, hearing aids). In one embodiment, the enclosure is sealed and insulated such that the external environment is not coupled to the ear canal throughstent 9006. - Acoustic information can be transferred through
stent 9006 itself orstent 9006 can be a conduit to channel one or more lumens or electronics to the ear canal. For example, a first and a second lumen can be placed withinstent 9006. The distal end of the first lumen is exposed to the ear canal. Similarly, the second lumen is exposed to the ear canal. Typically, the distal ends of the first and second lumens would be placed at or neardistal opening 9016 ofear device 9000. A microphone can be coupled to a proximal end of the first lumen for receiving acoustic information in the ear canal. A transducer can be coupled to the proximal end of a second lumen for delivering acoustic information to the ear canal. The microphone and transducer would be coupled to electronic circuitry in the housing (coupled to stent 9006) or located somewhere outside the ear. -
Chamber 9018 comprises first foldingmember 9010 andsecond folding member 9060. First foldingmember 9010 andsecond folding member 9060form ring valve 9070. As mentioned previouslychamber 9018 is configured to occlude or partially occlude the ear canal of the ear. The orientation ofsecond folding member 9060 differs fromsecond folding member 9012 as disclosed inFIG. 59 .Second folding member 9060 performs the same function assecond folding member 9012. In fact, any feature stated herein forsecond folding member 9012 also applies tosecond folding member 9060 and vice versa. Ananchor point 9062 ofsecond folding member 9060 is betweenanchor point 9046 offirst folding member 9010 and the stop flange (not shown).Second folding member 9060 extends fromanchor point 9062 proximally such thatsecond folding member 9060 overliesstent 9006. A portion offirst folding member 9010 overlies a portion ofsecond folding member 9010. In one embodiment,second folding member 9060 can be formed having a portion that extends vertically fromanchor point 9062 and horizontally abovestent 9006 in a proximal direction. In one embodiment,second folding member 9060 can be formed as a curved structure that changes vertically and horizontally.Second folding member 9060 has aproximal end 9064 that terminates before the stop flange (not shown). In one embodiment,second folding member 9060 is curved to suspendsecond folding member 9060 abovestent 9006. In one embodiment,second folding member 9060 forms anangle 9068 with stent 9006 (e.g.,line 9069B). Angle 9068 (e.g., betweenline 9069A andline 9069B) is typically greater than 90 degrees. In one embodiment,angle 9068 is 120 degrees or greater. Ifangle 9068 is less than 90 degrees it will be an implementation ofsecond folding member 9012 as disclosed inFIG. 59 . - An opening of
ring valve 9070 comprises a distance betweenproximal end 9036 offirst folding member 9010 andproximal end 9064 ofsecond folding member 9012. In one embodiment,stent 9006 is a cylinder that can be an open channel or a filled structure that has no path from the external environment to the ear canal. As mentioned previously,second folding member 9060 has ananchor point 9062 that couples to stent 2006 or is formed part of stent 2006. In the example,second folding member 9060 extends proximally forming a curved structure suspended abovestent 9006. The curved structure ofsecond folding member 9060 is formed 360 degrees aroundstent 9006. In the example,proximal end 9064 ofsecond folding member 9060 can be seen as circular in shape aroundstent 9006.Proximal end 9064 forms the circle having a radius indicated by doublesided arrow 9072 from the center ofstent 9006. - First folding
member 9010 is a curved structure extending fromanchor point 9046 toproximal end 9036 suspended abovestent 9006. The curved structure is formed 360 degrees aroundstent 9006. A portion offirst folding member 9010 overlies a portion ofsecond folding member 9060. In the example,proximal end 9036 offirst folding member 9010 can be seen as circular in shape aroundstent 9006.Proximal end 9036 forms the circle having a radius indicated by doublesided arrow 9076 from the center ofstent 9006. In one embodiment, a width of an opening ofring valve 9070 is approximately the distance of double-sided arrow 9076 less the distance of double-sided arrow 9072 whenear device 9000 is not inserted in the ear canal. In one embodiment,first folding member 9010 has a maximum radius as indicated by doublesided arrow 9074. In one embodiment, the maximum radius is located distally fromproximal end 9036. The maximum radius offirst folding member 9010 is greater than a radius of the era canal. As shown,ear device 9000 is outside the ear canal in a quiescent state wherering valve 9070 is open andchamber 9018 is coupled to the external environment.Chamber 9018 can be filled with a compressible material to further attenuate noise from the external environment. In one embodiment, fillingchamber 9018 would also improve noise attenuation whenchamber 9018 is open to the external environment. -
FIG. 61 is a cutaway view ofear device 9000 withchamber 9018 sealed in accordance with an example embodiment. The cutaway view illustrates structure withinear device 9000 that could not be seen with an external view. The section ofear device 9000 that is cutaway is substantially equal to what is shown in the illustration.Ear device 9000 has an optional stop flange removed to illustratechamber 9018 being sealed.Ring valve 9070 is shown sealed thereby sealingchamber 9018 for occluding or partially occluding the ear canal withear device 9000. In general, a force will be applied toear device 9000 when inserted in an ear canal of an ear. More specifically, the wall of the ear canal applies a force tofirst folding member 9010. Referring briefly toFIG. 60 , the ear canal radius will be smaller than the maximum radius indicated by doublesided arrow 9074. Twice the distance of double-sided arrow 9074 is a maximum diameter ofear device 9000. The ear canal having a radius less than double-sided arrow 9074 ofFIG. 60 will apply aforce 360 degrees aroundfirst folding member 9010 that folds first foldingmember 9010 towardsstent 9006. First foldingmember 9010 is flexible and supports folding when inserted into the ear canal such that little or no discomfort occurs. First foldingmember 9010 conforms and couples to the wall of the ear canal. No gap will exist between a surface offirst folding member 9010 and the wall of the ear canal that couples the external environment to the ear canal.Chamber 9018 is sealed whenfirst folding member 9010 couples tosecond folding member 9060. In one embodiment,chamber 9018 is sealed whenfirst folding member 9010 couples to second folding member 9060 a full 360 degrees aroundstent 9006 such that no gap exists betweenfirst folding member 9010 andsecond folding member 9060.Sealing chamber 9018 isolates the ear canal from the external environment thereby attenuating noise from the external environment from reaching the ear canal.Ear device 9000 occludes or partially occludes the ear canal whenchamber 9018 is sealed in the ear canal andstent 9006 does not couple to the external environment. In one embodiment, noise or sound is reflected by the stop flange (not shown) away from the ear canal and back into the external environment. Noise that reaches an entrance to the ear canal is blocked by sealedchamber 9018. Note that any noise would have to couple through one offirst folding member 9010,second folding member 9060, andchamber 9018 to reach the ear canal. Attenuation properties ofear device 9000 can be improved by fillingchamber 9018 with a gas, liquid, or foam that supports sound suppression. In one embodiment,chamber 9018 can be filled with a compressible material that supports noise attenuation. Thus,ear device 9000 provides excellent noise attenuation from the external environment. As disclosed herein above,stent 9006 can be used to deliver acoustic information to the ear canal or receive acoustic information from the ear canal. This can be useful for an application such as two-way communication in a noisy environment or listening to music in a noisy environment. - In one embodiment, a pressure within
chamber 9018 is approximately equal to a pressure in the external atmosphere whenchamber 9018 is sealed. Referring briefly toFIG. 60 ,chamber 9018 ofear device 9000 is exposed to the external environment whenchamber 9018 is not sealed. The pressure withinchamber 9018 would be the same as the pressure within the external environment. Upon insertingear device 9000 into an ear canal a force is applied aroundfirst folding member 9010 that moves first folding member towardssecond folding member 9012. The wall of the ear canal provides aforce 360 degrees aroundfirst folding member 9010. First foldingmember 9010 is flexible and provides little resistance in folding to fit the diameter of the ear canal.Chamber 9018 is then sealed whenfirst folding member 9010 couples tosecond folding member 9060 whereby no gap exists to the external environment throughring valve 9070. -
Chamber 9018 maintains approximately equal pressure with the external atmosphere by openingring valve 9070 during an adjustment that changes the ear canal diameter whether the diameter of the ear canal increases or decreases thereby respectively increasing or decreasing the volume ofchamber 9018. In one embodiment,first folding member 9018 andsecond folding member 9060 are configured to decouple when a change in volume occurs. For example,chamber 9018 being inserted into a region of the ear canal that has a reduced diameter will reduce volume withinchamber 9018 and expel an amount of gas corresponding to a difference in volume from the prior larger volume ofchamber 9018 to the smaller volume ofchamber 9018 due to the reduced diameter of the ear canal. Thus, although the volume is reduced inchamber 9018, the pressure withinchamber 9018 stays approximately equal to the external environment due to the expelled gas volume.Ring valve 9070 seals after adjustment to the change in volume within the ear canal thereby maintaining the noise attenuation properties ofear device 9000. Comfort is maintained as the pressure applied to the walls of the ear canal stays the same. In one embodiment, the flexibility offirst folding member 9010 andsecond folding member 9060 is such thatsecond folding member 9060 can fold to couple tostent 9006. Similarly,first folding member 9010 can fold to couple to second folding member 9060 (whilesecond folding member 9060 couples to stent 9006) such that the volume within 9018 is reduced to a minimum and thereby accommodate small diameter ear canals. Alternatively, if thering valve 9070 does not open and expel gas during a decrease in volume ofchamber 9018 the pressure withinchamber 9018 will increase. This may have an effect on comfort due to increase pressure on the walls of the ear canal and also noise attenuation. -
Chamber 9018 also maintains approximately equal pressure with the external atmosphere by openingring valve 9070 during an adjustment that changes the ear canal diameter from a smaller diameter to a larger diameter thereby increasing the volume ofchamber 9018. In one embodiment,first folding member 9018 andsecond folding member 9060 are configured to decouple when the increase in volume occurs. For example,chamber 9018 being inserted into a region of the ear canal that increases in diameter will increase the volume withinchamber 9018 and allow an amount of gas intochamber 9018 from the external environment that corresponds to a difference in volume from the prior smaller volume ofchamber 9018 and the larger volume ofchamber 9018 due to the increased diameter of the ear canal. First foldingmember 9010 andsecond folding member 9012 fold outward toward the larger diameter wall of the ear canal, decouples, and then seals. Thus, although the volume is increased inchamber 9018, the pressure withinchamber 9018 stays approximately equal to the external environmentdue ring valve 9070 opening to the external environment.Ring valve 9070 seals after adjustment to the change in volume within the ear canal thereby maintaining the noise attenuation properties ofear device 9000. Comfort is maintained as the pressure applied to the walls of the ear canal stays the same. In one embodiment, the resilience offirst folding member 9010 andsecond folding member 9060 is such thatfirst folding member 9010 will change shape towards the shape disclosed inFIG. 60 whenear device 9000 is not inserted in the ear canal thereby expanding to the increased diameter of the ear canal. Similarly,second folding member 9060 will also change shape towards the shape disclosed inFIG. 60 whenear piece 9000 is not inserted in the ear canal thereby expanding to the increased diameter of the ear canal.Ring valve 9070 will open during the transition to an increased ear canal diameter thereby exposingchamber 9018 to the external environment.Ring valve 9070 closes after the adjustment to the increased diameter and the pressure withinchamber 9018 is approximately equal to the pressure in the external environment. Comfort is maintained as the pressure applied to the walls of the ear canal byear device 9000 independent of the diameter of the ear canal. The attenuation properties are also maintained asring valve 9070 is sealed after insertion and adjustment within the ear canal. -
FIG. 62 is a block diagram 9080 of a method for occluding or partially occluding an ear canal with an ear device in accordance with an example embodiment. Block diagram 9080 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention. In astep 9082, an ear device is inserted into an ear canal of an ear. The ear device has a chamber configured to occlude or partially occlude the ear canal. The ear device comprises at least one stent and the chamber. The chamber is formed around the at least one stent. A ring valve couples to the chamber for coupling to an external environment. The ring valve has an opening 360 degrees around the at least one stent. - In a
step 9084, closing the ring valve seals the chamber thereby isolating the ear canal from the external environment. The ring valve is configured to close when inserted in the ear canal. Thus, occluding or partially occluding the ear canal. A force is applied to the ring valve or the chamber to seal the ring valve. The force applied closes the opening of the ring valve thereby sealing the chamber. In one embodiment, the opening of the ring valve is 360 degrees around the at least one stent. Thus, to seal the chamber the ring valve seals the opening 360 degrees around the at least one stent. - In at
step 9086, the ring valve comprises a first folding member overlying a second folding member. The ring valve is open prior to being inserted in the ear canal. Thus, the ring valve couples the external environment to the chamber. The ear canal is configured to apply a force that closes the opening of thering valve 360 degrees around the at least one stent to seal the chamber thereby closing the ring valve. - In a
step 9088, the ring valve opens when the ear device is removed from the ear. In astep 9090, the ring valve opens as the ear device is being inserted in the ear canal to support adjustment of the chamber volume to a change in diameter of the ear canal. In astep 9092, the pressure is adjusted within the chamber. The chamber is configured to maintain a pressure approximately equal to the external environment as the chamber volume changes. In astep 9094, the ring valve opens as the volume of the chamber changes thereby coupling the chamber to the external environment through the ring valve. The pressure in the chamber then equalizes to a pressure in the in the external environment. The ring valve opens in response to a change in the diameter of the ear canal which results in an adjustment of the chamber volume. -
FIG. 63 is a block diagram 9100 of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment. The block diagram 9100 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention. In astep 9102, an ear device is inserted into an ear canal of an ear. A chamber of the ear device is configured to occlude or partially occlude the ear canal of the ear. In one embodiment, a pressure within the chamber remains approximately equal for different chamber volumes. - In a
step 9104, a ring valve of the ear device is open prior to inserting the ear device into the ear canal. The ring valve couples the external environment to the chamber. The ring valve is configured to close when inserted in the ear canal. The ring valve is configured to open in response to a diameter change in the ear canal during insertion that causes the chamber to increase in size or be reduced in size to occlude or partially occlude the ear canal. Opening the ring valve during insertion couples the chamber to the external environment thereby equalizing a pressure within the chamber to the external environment. Thus, the pressure within the chamber is approximately equal to the pressure in the external environment for any chamber size in the ear device. - In a
step 9106, a gap is formed between a first folding member and a second folding member when the ring valve opens. In one embodiment, the ring valve comprises a portion of the first folding member overlying a portion of the second folding member. The first folding member can be formed around a stent. Similarly, the second folding member can be formed around a stent. Under quiescent conditions such as when the ear device is outside the ear a gap will exist between the first and second folding members such that the ring valve is open. In one embodiment, the first folding member decouples from the second folding member due to a diameter change in the ear canal forming an opening in the ring valve. - In a
step 9108, the ear canal is configured to apply a force to the first folding member of the ear device that couples the first folding member to the second folding member. The ring valve closes when the first folding member couples to the second folding member such that no gaps exist coupling the chamber to the external environment. Thus, the chamber is sealed. In astep 9110, the chamber is coupled to the external environment. The ring valve is configured to open when the ear device is removed from the ear canal. The ring valve opens such that a gap in the ring valve couples the chamber to the external environment. -
FIG. 64 is a block diagram 9120 of a method for occluding or partially occluding an ear canal with a chamber of an ear device in accordance with an example embodiment. The block diagram 9120 comprises one or more steps. A step order is not implied, can be practiced in any sequence, and one or more steps can be removed from the sequence to practice the invention. In astep 9122, an ear canal of an ear is occluded or partially occluded with an ear device. The ear canal is occluded or partially occluded by a chamber that is sealed. In one embodiment, the chamber is normally open to the external environment. In the normally open configuration, the chamber of the ear device is coupled to the external environment. The process of inserting the ear device into the ear canal of the ear seals the chamber thereby isolating the ear canal from the external environment. - In a
step 9124, the chamber is coupled to the external environment or decoupled from the external environment by a ring valve. Walls of the ear canal are configured to apply a force to the ring valve. The force applied by the walls of the ear canal to the ring valve closes the ring valve thereby sealing the chamber that occludes or partially occludes the ear canal. In astep 9126, pressure within the chamber is equalized to the external environment. In one embodiment, the ring valve opens in a response to a change in a diameter of the ear canal during insertion of the ear device. The ring valve couple the chamber of the ear device to the external environment thereby equalizing a pressure within the chamber to the external environment as the chamber adapts to the diameter of the ear canal. The change in the diameter of the ear canal during insertion of the ear device into the ear canal corresponds to a change in the volume of the chamber to occlude or partially occlude the ear canal. - In a
step 9128, a force is applied 360 degrees around the ring valve to close the ring valve and thereby seal the chamber. In one embodiment, the walls of the ear canal of the ear apply aforce 360 degrees around the ring valve. The force applied 360 degrees on the ring valve by the ear canal closes the ring valve thereby isolating the ear canal from the external environment. - Referring briefly to
FIG. 56 andFIG. 60 , an ear device is shown comprising astent 9006, afirst folding member 9010, and asecond folding member 9012. Alternatively, a second folding member can be oriented as disclosed inFIG. 60 assecond folding member 9060. First foldingmember 9010 forms a chamber with eithersecond folding member 9012 orsecond folding member 9060. First foldingmember 9010 couples tostent 9006 and extends proximally. A major portion offirst folding member 9010 overlies a portion ofstent 9006. -
Second folding member 9012 orsecond folding member 9060 couples tostent 9006. First foldingmember 9010 overliessecond folding member 9012 orsecond folding member 9060. In one embodiment, a portion offirst folding member 9010 overlies a portion ofsecond folding member 9012 orsecond folding member 9060. Thefirst folding member 9010 couples to thesecond folding member 9012 orsecond folding member 9060 when inserted in the ear canal of an ear as indicated inFIGS. 58 and 61 . First foldingmember 9010 andsecond folding member 9012 form achamber 9018 as disclosed inFIG. 58 when inserted in the ear canal to occlude or partially occlude the ear canal. Similarly, first folding member andsecond folding member 9060 form achamber 9018 as disclosed inFIG. 61 when inserted in the ear canal to occlude or partially occlude the ear canal.Chamber 9018 couples to and is formed aroundstent 9006. - Referring to
FIG. 57 ,first folding member 9010 is shown coupling circumferentially tostent 9006. Similarly,second folding member 9012 couples circumferentially tostent 9006. Note thatfirst folding member 9010 couples tostent 9006 distal to wheresecond folding member 9012 couples tostent 9006. Referring briefly toFIG. 60 ,second folding member 9060 couples circumferentially tostent 9006. In one embodiment, astop flange 9008 couples tostent 9006. Stopflange 9008 limits howfar ear device 9000 can be inserted into the ear canal. In one embodiment, stopflange 9008 is larger than the diameter of the ear canal. Stopflange 9008 is located proximally in relation tofirst folding member 9010 andsecond folding member 9012 orsecond folding member 9060. In one embodiment,first folding member 9010 andsecond folding member 9012 orsecond folding member 9060 form a valve. In one embodiment, they form a ring valve. The valve coupleschamber 9018 to the external environment. - Referring briefly to
FIG. 59 , aring valve 9020 is illustrated.Ring valve 9020 is normally open. In oneembodiment ring valve 9020 has a gap that is circular or ring shaped aroundstent 9006.Ring valve 9020 comprises a portion offirst folding member 9010 overlying a portion ofsecond folding member 9012. The gap is the distance between the overlying portions offirst folding member 9010 andsecond folding member 9012. Similarly,ring valve 9020 can comprise a portion offirst folding member 9010 overlying a portion ofsecond folding member 9060. The gap is the distance between the overlying portions offirst folding member 9010 andsecond folding member 9060. - Referring briefly to
FIG. 57 ,first folding member 9010 is configured to fold towardsstent 9006 during insertion of the ear device into the ear canal. First foldingmember 9010 is configured to be flexible to bend, fold, conform. First foldingmember 9010 is low friction for easily being inserted into the ear canal. First foldingmember 9010 has a diameter that is greater than a diameter of the ear canal. First foldingmember 9010 has ananchor point 9046 that is a pivot point to support folding, bending, or conforming to a shape of the ear canal. In one embodiment, at least a portion of the outer surface offirst folding member 9010 is configured to couple to and conform to a surface of the ear canal. Note that a force applied by walls of the ear canal to an exterior surface offirst folding member 9010 will move first foldingmember 9010 towardsstent 9006 and therebysecond folding member 9012 orsecond folding member 9060. - Referring briefly to
FIG. 61 , thesecond folding member 9060 orsecond folding member 9012 is configured to flex or fold. As shown inFIG. 61 , aforce 9080 is applied tofirst folding member 9010 foldingfirst folding member 9010 to couple tosecond folding member 9060. Theforce 9080 corresponds to the walls of an ear canal whenear device 9000 is inserted into the ear canal.Second folding member 9060 orsecond folding member 9012 is configured to flex or fold. More specifically,second folding member second folding member 9060 orsecond folding member 9012.Second folding member 9060 orsecond folding member 9012 conforms to the shape and contour of the ear canal when inserted in the ear canal. As disclosed at least a portion of the outer surface of thesecond folding member 9060 orsecond folding member 9012 is configured to couple to at least a portion of an interior surface offirst folding member 9010 to sealchamber 9018. - Referring briefly to
FIG. 56 ,chamber 9018 is normally open whenear device 9000 is outside the ear canal. Normally open corresponds to ringvalve 9020 being open. Thus,chamber 9018 is coupled to the external environment prior toear device 9000 being inserted into the ear canal. - Referring briefly to
FIG. 58 ,ear device 9000 is inserted in anear canal 9002. First foldingmember 9010 couples tosecond folding member 9012 such thatchamber 9018 is sealed.Ring valve 9020 is closed whenchamber 9018 is sealed. A gap inring valve 9020 prior toring valve 9020 sealingcouples chamber 9018 to the external environment. Thus, whenchamber 9018 is sealed the pressure withinchamber 9018 is approximately equal to a pressure in the external environment. In one embodiment,first folding member 9010 decouples fromsecond folding member 9012 orsecond folding member 9060 aschamber 9018 adjusts to a change in diameter of the ear canal to conform to occlude or partially occlude the ear canal. This corresponds to a gap opening inring valve 9020 that coupleschamber 9018 to the external environment thereby equalizing the pressure withinchamber 9018 to approximately the pressure of the external environment.Ring valve 9020 closes once the chamber conforms to the diameter of the earcanal sealing chamber 9018.Ear canal 9002 is then isolated from the external environment bychamber 9018 that is sealed. Noise in the external environment is attenuated bystop flange 9008 andchamber 9018 before reachingear canal 9002. - Referring briefly to
FIG. 58 ,chamber 9018 is configured to seal asear device 9000 is inserted intoear canal 9002.Chamber 9018 is configured to occlude or partially occlude the ear canal when sealed.Chamber 9018 comprises first foldingmember 9010 andsecond folding member 9012 orsecond folding member 9060. First foldingmember 9010 couples aroundstent 9006. An outer surface offirst folding member 9010 is configured to couple to a surface ofear canal 9002.Second folding member 9012 orsecond folding member 9060 couples aroundstent 9006. At least a portion offirst folding member 9010 overlies at least a portion ofsecond folding member 9012 orsecond folding member 9060. First foldingmember 9010 is configured to couple to thesecond folding member 9012 orsecond folding member 9060 when inserted intoear canal 9002. In one embodiment, a gap exists betweenfirst folding member 9010 andsecond folding member 9012 orsecond folding member 9060 whenear device 9000 is outsideear canal 9002. The gap couples the external environment tochamber 9018 whenear device 9000 is outsideear canal 9002. First foldingmember 9010 couples tosecond folding member 9012 orsecond folding member 9060 to close the gap whenear device 9000 is inserted inear canal 9002 thereby sealingchamber 9018. The gap opens betweenfirst folding member 9010 andsecond folding member 9012 orsecond folding member 9060 during insertion intoear canal 9002 to equalize pressure betweenchamber 9018 and the external environment. - Referring briefly to
FIG. 58 , a pressure withinchamber 9018 is approximately constant as a volume ofchamber 9018 increases or decreases. In one embodiment, a volume decrease inchamber 9018 corresponds to a reduction in diameter ofear canal 9002. The reduction in diameter ofear canal 9002 expels gas withinchamber 9018 thereby openingring valve 9020. Displacing the gas to accommodate the smaller volume maintains the pressure withinchamber 9018 approximately equal to the external environment. In one embodiment, a volume increase inchamber 9018 corresponds to an increase in diameter ofear canal 9002. The increase in diameter ofear canal 9002 supports opening ofring valve 9020. Openingring valve 9020 coupleschamber 9018 to the external environment thereby equalizing the pressure withinchamber 9018 to the approximately equal to the external environment whenring valve 9020 closes. In one embodiment, a volume inchamber 9018 can be filled in part by a gas, foam, or liquid. -
FIGS. 65A and 65B illustrate an earplug where a first sealedchamber 30 is inflated by movingfluid 40 from a second sealedchamber 10 my pressing Y1 on the second sealed chamber, where avalve 20 prevents backflow. A rotatable element 6500 attached to a flexible stent to which thevalve 20 is attached, can be rotated 6600, to open the valve releasing the fluid 40 from the first sealedchamber 30 toward the second sealedchamber 10. -
FIG. 66 is a cutaway view of a moldedear device 6000 without a stop flange in accordance with an example embodiment. The front tip portion 6620 is molded as shown, then folded toward ridge 6610 to form a tip. This way a nearly enclosed tip can be molded. - Processes, techniques, apparatus, and materials as known by one of ordinary skill in the art may not be discussed in detail but are intended to be part of the enabling description where appropriate. For example, specific materials may not be listed for achieving each of the targeted properties discussed, however one of ordinary skill would be able, without undo experimentation, to determine the materials needed given the enabling disclosure herein.
- While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all modifications, equivalent structures and functions of the relevant exemplary embodiments. For example, if words such as “orthogonal”, “perpendicular” are used, the intended meaning is “substantially orthogonal” and “substantially perpendicular” respectively. Additionally, although specific numbers may be quoted in the claims, it is intended that a number close to the one stated is also within the intended scope, i.e. any stated number (e.g., 20 mils) should be interpreted to be “about” the value of the stated number (e.g., about 20 mils).
- Thus, the description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the exemplary embodiments of the present invention. Such variations are not to be regarded as a departure from the spirit and scope of the present invention.
Claims (3)
1. An ear device comprising:
a stent;
a deformable reservoir;
a deformable membrane, wherein the deformable reservoir is connected to the deformable membrane by a fluid channel;
a speaker;
an ambient sound microphone; and
fixture elements within the deformable reservoir, wherein the deformable reservoir is configured to be deformed manually moving fluid from the reservoir through the channel into the deformable membrane expanding the deformable membrane, wherein the position of the deformed reservoir is secured by the fixture elements.
2. An ear device comprising:
a stent configured for insertion into an ear canal;
a folding member having a resting shape, wherein the folding member is attached to a distal end of the stent with the opposing end free to move along the stent in the anti-distal direction; and
a ring attached to the opposing end, the ring configured to be moved by a finger, where the ring and attached opposing end are configured to move in the direction a finger pulls the ring to decrease the folding member’s resting shape radially.
3. An ear device comprising:
a stent configured for insertion into an ear canal;
a first sealed chamber;
a second sealed chamber;
a valve; and
a rotatable member, wherein the rotatable member is attached to a portion of the stent and is configured so that rotating the rotatable member opens the valve so that fluid can flow between the first sealed chamber and the second sealed chamber.
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US17/895,059 US20230156389A1 (en) | 2015-09-11 | 2022-08-25 | Earplugs, earphones, and eartips |
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US201662307486P | 2016-03-12 | 2016-03-12 | |
US15/182,569 US20160295311A1 (en) | 2010-06-04 | 2016-06-14 | Earplugs, earphones, panels, inserts and safety methods |
US201662373313P | 2016-08-10 | 2016-08-10 | |
US201662437331P | 2016-12-21 | 2016-12-21 | |
US15/674,239 US20180220239A1 (en) | 2010-06-04 | 2017-08-10 | Earplugs, earphones, and eartips |
US201862740408P | 2018-10-02 | 2018-10-02 | |
US201916590466A | 2019-10-02 | 2019-10-02 | |
US16/905,655 US11477560B2 (en) | 2015-09-11 | 2020-06-18 | Earplugs, earphones, and eartips |
US17/895,059 US20230156389A1 (en) | 2015-09-11 | 2022-08-25 | Earplugs, earphones, and eartips |
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Families Citing this family (5)
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---|---|---|---|---|
WO2019208315A1 (en) * | 2018-04-25 | 2019-10-31 | 積水ポリマテック株式会社 | Earpiece |
WO2020121608A1 (en) * | 2018-12-14 | 2020-06-18 | ソニー株式会社 | Acoustic device and acoustic system |
CN114554336A (en) * | 2020-11-25 | 2022-05-27 | 深圳富泰宏精密工业有限公司 | Earphone set |
CN112788462B (en) * | 2021-01-14 | 2022-08-26 | 深圳市弘毅佳科技有限公司 | In-ear earphone capable of avoiding ear ache |
FR3124075B1 (en) * | 2021-06-17 | 2023-07-14 | Myned Corp | Ear plug |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6256396B1 (en) * | 1995-05-26 | 2001-07-03 | William Bradford Cushman | Self-fitting hearing protection earplug with facile insertion mechanism |
US8499886B2 (en) * | 2011-10-14 | 2013-08-06 | Plantronics, Inc. | Expander ear tip |
US20150150728A1 (en) * | 2012-11-30 | 2015-06-04 | Gideon Williams Duvall | Orifice Occluding Inflated Device |
Family Cites Families (96)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2876767A (en) | 1955-11-02 | 1959-03-10 | Wasserman Nathan | Ear plug |
US2850012A (en) | 1957-06-20 | 1958-09-02 | Mine Safety Appliances Co | Ear plug |
US3110356A (en) | 1961-04-14 | 1963-11-12 | Emanuel S Mendelson | Earplug |
US3505999A (en) | 1967-08-25 | 1970-04-14 | Old Westport Medical Ass Inc | Earplug |
US3602654A (en) | 1968-10-04 | 1971-08-31 | John A Victoreen | Hydraulically expandable earpiece |
DE2459259B2 (en) | 1973-12-21 | 1979-04-26 | N.V. Philips' Gloeilampenfabrieken, Eindhoven (Niederlande) | Ear piece with a thin-walled flexible capsule filled with a liquid medium |
US4060080A (en) | 1975-03-17 | 1977-11-29 | Taichiro Akiyama | Plug for living body |
US4029083A (en) | 1975-05-12 | 1977-06-14 | Baylor Carl S | Probe for audiometric apparatus |
US4834211A (en) | 1988-02-02 | 1989-05-30 | Kenneth Bibby | Anchoring element for in-the-ear devices |
US4896679A (en) | 1989-05-22 | 1990-01-30 | St Pierre Carol L | Method and apparatus for the exclusion of sound and water from the auditory canal |
US4913165A (en) | 1989-07-24 | 1990-04-03 | Michael Fishgoyt | Underwater eardrum protector |
US5131411A (en) | 1990-08-20 | 1992-07-21 | Virginia Polytechnic Institute & State University | Custom-fitting earplug formed in situ using foaming action |
US5333622A (en) | 1990-08-20 | 1994-08-02 | The Center For Innovative Technology | Earplug and hearing devices formed in-situ |
US6440102B1 (en) | 1998-07-23 | 2002-08-27 | Durect Corporation | Fluid transfer and diagnostic system for treating the inner ear |
US7171371B2 (en) | 1999-09-03 | 2007-01-30 | Smg Trust | Method and system for providing pre and post operative support and care |
US6368289B2 (en) | 2000-02-14 | 2002-04-09 | Kinderlife Instruments, Inc. | Acoustic coupling device |
US6368288B2 (en) | 2000-02-14 | 2002-04-09 | Kinderlife Instruments, Inc. | Acoustic coupling device |
US6647368B2 (en) | 2001-03-30 | 2003-11-11 | Think-A-Move, Ltd. | Sensor pair for detecting changes within a human ear and producing a signal corresponding to thought, movement, biological function and/or speech |
US7756281B2 (en) | 2006-05-20 | 2010-07-13 | Personics Holdings Inc. | Method of modifying audio content |
WO2007137232A2 (en) | 2006-05-20 | 2007-11-29 | Personics Holdings Inc. | Method of modifying audio content |
US8199919B2 (en) | 2006-06-01 | 2012-06-12 | Personics Holdings Inc. | Earhealth monitoring system and method II |
US8208644B2 (en) | 2006-06-01 | 2012-06-26 | Personics Holdings Inc. | Earhealth monitoring system and method III |
US8194864B2 (en) | 2006-06-01 | 2012-06-05 | Personics Holdings Inc. | Earhealth monitoring system and method I |
EP2041996A2 (en) | 2006-06-01 | 2009-04-01 | Personics Holdings Inc. | Ear input sound pressure level monitoring system |
US8917876B2 (en) | 2006-06-14 | 2014-12-23 | Personics Holdings, LLC. | Earguard monitoring system |
WO2007150033A2 (en) | 2006-06-22 | 2007-12-27 | Personics Holdings Inc. | Methods and devices for hearing damage notification and intervention |
US7629124B2 (en) | 2006-06-30 | 2009-12-08 | Canon U.S. Life Sciences, Inc. | Real-time PCR in micro-channels |
WO2008008730A2 (en) | 2006-07-08 | 2008-01-17 | Personics Holdings Inc. | Personal audio assistant device and method |
US20080178088A1 (en) | 2006-07-27 | 2008-07-24 | Personics Holdings Inc. | Method and device of customizing headphones |
WO2008022271A2 (en) | 2006-08-16 | 2008-02-21 | Personics Holdings Inc. | Method of auditory display of sensor data |
WO2008061260A2 (en) | 2006-11-18 | 2008-05-22 | Personics Holdings Inc. | Method and device for personalized hearing |
WO2008064230A2 (en) | 2006-11-20 | 2008-05-29 | Personics Holdings Inc. | Methods and devices for hearing damage notification and intervention ii |
US7779844B2 (en) | 2006-12-15 | 2010-08-24 | Kimberly-Clark Worldwide, Inc. | Self-fitting device for location in an ear canal |
WO2008083315A2 (en) | 2006-12-31 | 2008-07-10 | Personics Holdings Inc. | Method and device configured for sound signature detection |
US8917894B2 (en) | 2007-01-22 | 2014-12-23 | Personics Holdings, LLC. | Method and device for acute sound detection and reproduction |
WO2008095013A1 (en) | 2007-01-30 | 2008-08-07 | Personics Holdings Inc. | Sound pressure level monitoring and notification system |
US8254591B2 (en) | 2007-02-01 | 2012-08-28 | Personics Holdings Inc. | Method and device for audio recording |
US8213649B2 (en) | 2007-02-02 | 2012-07-03 | Personics Holdings Inc. | Method and device for evaluating auditory health |
WO2008103925A1 (en) | 2007-02-22 | 2008-08-28 | Personics Holdings Inc. | Method and device for sound detection and audio control |
US8625812B2 (en) | 2007-03-07 | 2014-01-07 | Personics Holdings, Inc | Acoustic dampening compensation system |
WO2008124786A2 (en) | 2007-04-09 | 2008-10-16 | Personics Holdings Inc. | Always on headwear recording system |
US8526645B2 (en) | 2007-05-04 | 2013-09-03 | Personics Holdings Inc. | Method and device for in ear canal echo suppression |
WO2008137872A1 (en) | 2007-05-04 | 2008-11-13 | Personics Holdings Inc. | Earguard sealing system i: multi-chamber systems |
US9191740B2 (en) | 2007-05-04 | 2015-11-17 | Personics Holdings, Llc | Method and apparatus for in-ear canal sound suppression |
US8081780B2 (en) | 2007-05-04 | 2011-12-20 | Personics Holdings Inc. | Method and device for acoustic management control of multiple microphones |
WO2008137870A1 (en) | 2007-05-04 | 2008-11-13 | Personics Holdings Inc. | Method and device for acoustic management control of multiple microphones |
WO2008144654A1 (en) | 2007-05-17 | 2008-11-27 | Personics Holdings Inc. | Method and device for quiet call |
WO2008153589A2 (en) | 2007-06-01 | 2008-12-18 | Personics Holdings Inc. | Earhealth monitoring system and method iv |
WO2008157557A1 (en) | 2007-06-17 | 2008-12-24 | Personics Holdings Inc. | Earpiece sealing system |
US7822219B2 (en) | 2007-06-20 | 2010-10-26 | Baker Lawrence K | Cartilage displacing bead, ridge, or key projection |
WO2009009794A1 (en) | 2007-07-12 | 2009-01-15 | Personics Holdings Inc. | Expandable earpiece sealing devices and methods |
WO2009012491A2 (en) | 2007-07-19 | 2009-01-22 | Personics Holdings Inc. | Device and method for remote acoustic porting and magnetic acoustic connection |
CN101785327B (en) | 2007-07-23 | 2013-11-20 | 艾瑟斯技术有限责任公司 | Diaphonic acoustic transduction coupler and ear bud |
US8391534B2 (en) | 2008-07-23 | 2013-03-05 | Asius Technologies, Llc | Inflatable ear device |
WO2009026532A1 (en) | 2007-08-22 | 2009-02-26 | Personics Holdings Inc. | Orifice insertion devices and methods |
US8018328B2 (en) | 2007-09-12 | 2011-09-13 | Personics Holdings Inc. | Adaptive audio content generation system |
WO2009036344A1 (en) | 2007-09-12 | 2009-03-19 | Personics Holdings Inc. | Sealing devices |
US8348010B2 (en) * | 2007-10-19 | 2013-01-08 | Apple Inc. | Invertible ear tips for an ear piece |
US8718313B2 (en) | 2007-11-09 | 2014-05-06 | Personics Holdings, LLC. | Electroactive polymer systems |
US8855343B2 (en) | 2007-11-27 | 2014-10-07 | Personics Holdings, LLC. | Method and device to maintain audio content level reproduction |
US8142870B2 (en) | 2007-12-13 | 2012-03-27 | Personics Holdings Inc. | Energy responsive conformal device |
US8326635B2 (en) | 2007-12-25 | 2012-12-04 | Personics Holdings Inc. | Method and system for message alert and delivery using an earpiece |
US8473081B2 (en) | 2007-12-25 | 2013-06-25 | Personics Holdings, Inc. | Method and system for event reminder using an earpiece |
US8251925B2 (en) | 2007-12-31 | 2012-08-28 | Personics Holdings Inc. | Device and method for radial pressure determination |
US8447031B2 (en) | 2008-01-11 | 2013-05-21 | Personics Holdings Inc. | Method and earpiece for visual operational status indication |
US9757069B2 (en) | 2008-01-11 | 2017-09-12 | Staton Techiya, Llc | SPL dose data logger system |
US8208652B2 (en) | 2008-01-25 | 2012-06-26 | Personics Holdings Inc. | Method and device for acoustic sealing |
WO2009105677A1 (en) | 2008-02-20 | 2009-08-27 | Personics Holdings Inc. | Method and device for acoustic sealing |
US8213629B2 (en) | 2008-02-29 | 2012-07-03 | Personics Holdings Inc. | Method and system for automatic level reduction |
US8319620B2 (en) | 2008-06-19 | 2012-11-27 | Personics Holdings Inc. | Ambient situation awareness system and method for vehicles |
EP2303206A1 (en) | 2008-06-26 | 2011-04-06 | Personics Holdings INC. | Occlusion effect mitigation and sound isolation device for orifice inserted systems |
US7886745B2 (en) | 2008-06-30 | 2011-02-15 | Kimberly-Clark Worldwide, Inc. | Self-fitting device for location in an ear canal |
US7913696B2 (en) | 2008-06-30 | 2011-03-29 | Kimberly-Clark Worldwide Inc. | Self-fitting device for location in an ear canal |
EP2309955A4 (en) | 2008-07-06 | 2014-01-22 | Personics Holdings Inc | Pressure regulating systems for expandable insertion devices |
US8488799B2 (en) | 2008-09-11 | 2013-07-16 | Personics Holdings Inc. | Method and system for sound monitoring over a network |
US9253560B2 (en) | 2008-09-16 | 2016-02-02 | Personics Holdings, Llc | Sound library and method |
US8600067B2 (en) | 2008-09-19 | 2013-12-03 | Personics Holdings Inc. | Acoustic sealing analysis system |
US20100071707A1 (en) | 2008-09-22 | 2010-03-25 | Wohl Daniel L | External middle ear insufflation device |
US9129291B2 (en) | 2008-09-22 | 2015-09-08 | Personics Holdings, Llc | Personalized sound management and method |
US8992710B2 (en) | 2008-10-10 | 2015-03-31 | Personics Holdings, LLC. | Inverted balloon system and inflation management system |
US8554350B2 (en) | 2008-10-15 | 2013-10-08 | Personics Holdings Inc. | Device and method to reduce ear wax clogging of acoustic ports, hearing aid sealing system, and feedback reduction system |
US9138353B2 (en) | 2009-02-13 | 2015-09-22 | Personics Holdings, Llc | Earplug and pumping systems |
WO2010094034A1 (en) | 2009-02-13 | 2010-08-19 | Personics Holdings Inc. | Method and device for acoustic sealing and occulsion effect mitigation |
WO2011041900A1 (en) | 2009-10-05 | 2011-04-14 | Sonomax Technologies Inc. | Pressure regulation mechanism for inflatable in-ear device |
US8437492B2 (en) | 2010-03-18 | 2013-05-07 | Personics Holdings, Inc. | Earpiece and method for forming an earpiece |
US9123323B2 (en) | 2010-06-04 | 2015-09-01 | John P. Keady | Method and structure for inducing acoustic signals and attenuating acoustic signals |
EP2586216A1 (en) | 2010-06-26 | 2013-05-01 | Personics Holdings, Inc. | Method and devices for occluding an ear canal having a predetermined filter characteristic |
US10362381B2 (en) | 2011-06-01 | 2019-07-23 | Staton Techiya, Llc | Methods and devices for radio frequency (RF) mitigation proximate the ear |
US9479859B2 (en) * | 2013-11-18 | 2016-10-25 | 3M Innovative Properties Company | Concha-fit electronic hearing protection device |
US9479878B2 (en) * | 2014-08-25 | 2016-10-25 | Starkey Laboratories, Inc. | Enhanced comfort earbud |
US9485595B2 (en) * | 2014-08-25 | 2016-11-01 | Starkey Laboratories, Inc. | Inverted flange earbud |
US10542341B2 (en) * | 2017-06-29 | 2020-01-21 | Starkey Laboratories, Inc. | Flanged earbud and hearing device including same |
US11014125B2 (en) * | 2017-10-17 | 2021-05-25 | Eargo, Inc. | Hand removable, clip on wax guards |
MX2020009361A (en) * | 2018-03-09 | 2021-06-08 | Earsoft Llc | Eartips and earphone devices, and systems and methods therefore. |
US11206472B2 (en) * | 2018-09-28 | 2021-12-21 | Apple Inc. | Multi-layer porous shielding |
US11012770B2 (en) * | 2019-03-25 | 2021-05-18 | Apple Inc. | Eartips for in-ear listening devices |
-
2020
- 2020-06-18 US US16/905,655 patent/US11477560B2/en active Active
-
2022
- 2022-08-25 US US17/895,059 patent/US20230156389A1/en not_active Abandoned
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6256396B1 (en) * | 1995-05-26 | 2001-07-03 | William Bradford Cushman | Self-fitting hearing protection earplug with facile insertion mechanism |
US8499886B2 (en) * | 2011-10-14 | 2013-08-06 | Plantronics, Inc. | Expander ear tip |
US20150150728A1 (en) * | 2012-11-30 | 2015-06-04 | Gideon Williams Duvall | Orifice Occluding Inflated Device |
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US20200359122A1 (en) | 2020-11-12 |
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