DE202011110400U1 - Measuring device for a bone conduction hearing aid - Google Patents

Abstract

Measuring device (20) for a bone conduction hearing device (2), wherein the measuring device (20) comprises: a first interface (44a), which is provided for connection to a measuring interface (44) of the bone conduction hearing device (2), a signal source ( 21) for outputting at least one test signal (U1) to the first interface (44a), and a measuring circuit (26) for measuring an electrical characteristic of a coil (12) of the bone conduction hearing device (2).

Description

The invention relates to a measuring device for a bone conduction hearing aid, such a bone conduction hearing aid, the entire arrangement of such a bone conduction hearing aid and the measuring device.

Bone conduction hearing aids generally include a vibration transducer which, by vibration, inputs sound waves directly into the user's skull. For this purpose, the bone conduction hearing is placed on the user's head, z. B. in the region of the ear or laterally next to the ear. The vibration conduct arrives with its contact surface, the Konduktorkopf, z. B. to the mastoid or maxillary bone. The Konduktorkopf is z. B. connected to an electromagnet, which is excited by an applied with the low-frequency electrical induction coil.

In this case, a contact pressure or contact pressure of the vibration is set, which in adults z. B. at 100 g (grams) and in a child is 90 g.

Too low a contact force causes the vibration introduction is not ensured. Excessive contact pressure can cause user pain.

A bone conduction hearing aid may generally be attached directly to the ear in adults, or to spectacle wearers as part of a hearing aid. The contact force can be z. B. be adjusted by bending a wire. Thus, the bending wire can be adjusted until the user hears for a good, but the investment power is not uncomfortably high.

In infants also attaching often done not on the ear, but by serving as Anpresseendes headband. The contact pressure can thus be adjusted by tensioning the headband.

Also, an adjustment of the contact pressure on the pressing device is not without problems in children or disabled people. In infants and toddlers under the age of four years, a suitable response, whether the sound is easy to understand and still free of pain, may not be available. Even with some disabled people or people with reduced or increased sensation of pain, this can be problematic.

Measuring devices for measuring the contact pressure are generally not sufficient to adjust a bone conduction hearing aid. So z. B. by a spring balance a tensile force to the headband or the hearing aid are applied until it lifts off the head. However, such a measured value is inaccurate.

The invention has for its object to provide a measuring device for a hearing aid and such a hearing aid, with which a review and adjustability of the investment force is possible.

This object is achieved by a measuring device according to claim 1 and a hearing aid according to claim 12. The dependent claims describe preferred developments. Furthermore, an overall arrangement of the measuring device and the hearing aid is provided.

The invention is based on the idea to measure the contact force in situ when wearing a hearing aid by an electrical reference signal is applied to the vibration or its coil and electrical properties of the coil are measured.

This is based on the knowledge that the electrical properties of the coil change as a function of the contact pressure. By the contact force, the position of the Konduktorkopfes and thus also the position of the electromagnet in the coil is changed. This adjustment causes the electromagnet is accommodated differently in the coil, for. B. immersed at different depths.

Accordingly, the electrical properties of the coil acted upon by electrical signals change. These electrical properties can be measured when exposed to a reference signal. In this case, however, the application of an acoustic signal via air to the microphone of the hearing device would be relatively imprecise in order to measure the changes in the electrical properties due to the contact pressure. It turns out, however, that the direct application of an electrical signal via a suitable interface makes it possible to measure the electrical properties of the coil with sufficient accuracy.

As an electrical property, in particular the reactance of the coil changes, thus also the phase shift between current and voltage as well as the total impedance and the current.

A measurement of the electrical properties can, for. B. by tapping the falling on the vibration or its coil and resistor AC voltage. Depending on Reactive resistance changes this alternating voltage, which is caused by z. B. rectification and subsequent comparison with reference voltages can be evaluated.

Furthermore, z. Example, the phase shift of the current relative to the voltage and / or the current flowing through the coil can be evaluated.

The measuring device according to the invention thus has an electrical signal source for an AC signal in the acoustic frequency range, d. H. between 17 Hz and 17 kHz. It turns out that measurements are particularly suitable between 1 and 2 kHz. The signal generator is in this case connected to a suitable measurement interface of the hearing aid. The measuring device further has a measuring circuit for measuring the relevant electrical variable, wherein the measuring circuit is preferably connected to the same connection point at which the coupling of the alternating voltage signal takes place.

The hearing aid according to the invention accordingly has a suitable interface for connecting the measuring device. This interface is thus connected to the connection point of the vibration, for. B. directly or via an impedance converter.

The measuring device can display the measurement result via an output device. In this case, in particular an optical display is advantageous. So z. B. a suitable contact force by lighting a green light, in particular a green LED, and too high or too low contact force accordingly by a red light, z. As a red LED can be displayed. Furthermore, acoustic announcements or visual displays with more detailed information are possible.

The measuring device according to the invention is advantageously portable, provided separately from the hearing aid and connected to this.

In principle, however, the measuring device can also be combined with or integrated into the bone conduction hearing aid. In this case, the interface of the measuring device with the measuring interface of the bone conduction hearing aid z. B. via a switch such. B. be connected to a transistor to activate the measurement mode.

Before carrying out the measurement in the applied state, a measurement without pressing can be carried out beforehand for the purpose of calibration or reference measurement, thus indicating that no contact force is yet present. Advantageously, the measuring device before attachment of the clamping device, for. B. the headband and already turned on so that it takes measurements in the relaxed state. Then the clamping device is tensioned until the display device indicates the correct value of the contact pressure, z. B. by the green light.

The measurement is preferably carried out in the switched-off state of the hearing device or its microphone in order not to measure an overlay of the measurement signal with acoustic signals of the microphone.

The invention will be explained below with reference to the accompanying drawings of some embodiments. Show it:

1 the attachment of a hearing aid according to the invention on the head of a user;

2 the hearing aid off 1 .

3 a block diagram of the arrangement of the hearing aid and the measuring device;

4 the vibration conductor off 2 in another illustration; and

5 a circuit diagram of a measuring device according to the invention.

On a head 1 a user is a hearing aid 2 by means of a pressing device 3 , here a headband 3 , pressed or pressed. The contact pressure of the pressing device 3 can with a headband z. B. can be adjusted by tightening the band, this can, for. B. a Velcro 3a be provided. Instead of a headband z. B. a headband may be provided.

In 2 is the structure of the hearing aid 2 shown. The hearing aid 2 has a housing 4 , a control panel 5 and a vibration conductor 6 on. The in the case 4 lying components 7 . 8th . 9 . 10 are shown here schematized and possibly incomplete. In the case 4 are a control device 7 that z. B. is designed as a microprocessor of the microcomputer, an amplifier 8th and Z. B. a microphone 9 intended. operating devices 10 can on the control panel 5 and also on the housing 4 be provided. The vibration conductor 6 essentially has a conductor housing 6a and a coil 12 (Exciter coil, induction coil) in which a ferromagnetic rod (core) 14 is performed with a serving as a contact surface Conductor head 15 connected is.

By applying the coil 12 over the amplifier device 8th with low frequency voltage or signal currents is thus the rod 14 deflected and generates the vibrations of the Konduktorkopfes 15 who's on the head 1 the user, for. B. the mastoid, a jawbone or other bone of the skull. The Conductor Head 15 is with the case 6a via a flexible sealing ring 16 , z. B. of rubber, silicone or a plastic material connected. The sealing ring 16 thus seals the vibration conductor 6 and allows the vibrational movement of the Konduktorkopfes 15 opposite the conductor housing 6a , Due to its elasticity, the sealing ring acts 16 thus also as a spring device; If necessary, a guide of the staff can be added 14 and a further return spring may be provided.

When pressing the hearing aid 2 to the head 1 the user thus gets in particular also the Konduktorkopf 15 to the head 1 ; the conductor housing 6a and the other parts of the hearing aid 2 be through the pressing device 3 against the head 1 pressed. Thus, the Konduktorkopf adjusted 15 together with the core 14 depending on the contact force against the conductor housing 6a , So z. B. the ferromagnetic core 14 with larger contact force further into the coil 12 pressed.

According to the invention, this exploits the fact that the electrical properties of the coil 12 depending on the position of the core 14 change, so that the contact pressure and the resulting deformation or distortion of the sealing ring 16 can be measured electrically.

3 shows an embodiment of such a measuring arrangement. In this block diagram is the vibration coupler 6 with his spool 12 and a resistor 18 from Z. B. R = 40 ohms drawn. The vibration conductor 6 is thus by the controller 7 over the amplifier 8th driven. According to the invention, a measuring device 20 provided with their interface (plug) 44a to an interface 44 of the hearing aid 2 connected.

The measuring device 20 is in 3 with their main components and in 5 shown in more detail with a possible block diagram: it has a signal source 21 uaf, z. B. a sine wave generator (AC voltage source) for outputting an AC voltage of frequency 1.4 kHz, to which a downstream impedance converter 22 connected to an interface connection point 24 of the vibration conductor 6 connected. To the connection point 24 is still via an amplifier 31 a voltage measuring circuit 26 for measuring at the connection point 24 connected voltage U1 and / or the current I1 connected to either the green LED 40 or the red LED 41 serves.

5 shows a realization; the voltage measuring circuit 26 has z. B. a peak rectifier circuit 32 for rectifying the amplified AC signal, and a comparator means 34 on. It is provided with resistors R1 to R24, capacitors or coupling capacitors C1 to C6, transistors T1 to T5, diodes D1 to D3, trimmers Tr1, Tr2 for setting reference voltages of the comparator circuit 34 , and operational amplifiers OP1 to OP4 realized.

The measuring device 20 becomes with its interface (plug) 44a to the measuring interface (connector receptacle) 44 of the hearing aid 2 connected. The measurement interface 44 is thus complementary to a common interface 42 that z. B. as a programming interface or signal interface 42 serves, provided. Basically, the interfaces 42 and 44 but also be combined.

By connecting the interface 44a (Plug) of the measuring device 20 to the measuring interface 44 becomes the measuring device 20 thus to the connection point 24 connected. The signal source 21 gives about the impedance converter 22 the 1.4 kHz signal on the connection point 24 , Depending on reactance of the coil 12 accordingly sets an AC voltage at the connection point 24 a, wherein via the coupling capacitor C5 only the AC voltage component is tapped. This alternating voltage signal can thus subsequently be amplified and rectified by the comparator device 34 be compared with a reference value. If the of reactance of the coil 12 dependent voltage is within a permissible range, the green LED becomes 40 controlled so that at the measuring device 20 for the user recognizably the green light comes on. If the contact pressure is too high or too low, the comparator device controls 34 the red LED 41 at.

Hereinafter, the operation of measuring the pressing force will be described.

The measuring device 20 comes with its serving as an interface connector 44a into the measurement interface (connector receptacle) 44 the turned off and not yet upside down 1 pressed hearing aid 2 plugged in. Thus the red LED lights up 41 , as there is no contact force. Subsequently, then the pressing device 3 put on and the hearing aid 2 at the head 1 positioned, and subsequently the pressing device 3 over the clasp 3a looking forward to the green LED 40 shines. During pressing, the sealing ring deforms and stretches 16 so that's the rod 14 in its position in the coil 12 changed and change the electrical properties to be measured.

After reaching the correct contact force, ie when the green LED lights up 40 , the measuring device can 20 by pulling her plug 44a be removed without the hearing aid 2 or the pressing device 3 to change.

Instead of in 5 shown embodiment, in which the measuring device 20 at the connection point 24 voltage is measured and thus the reactance of the coil 12 can also be measured, the phase shift of the through the connection point 24 flowing measuring current I1 relative to that of the signal source 21 output AC voltage are determined, so that instead of the measuring circuit 26 according to the phase shift is determined. This can be z. Example, by an intermediate shunt resistor, at which the falling shunt voltage is taken and their phase is compared with the phase of the signal voltage Ug. Corresponding circuits for this are known; z. B. the signal voltage Ug and the shunt voltage can be converted via appropriate functional devices in rectangular voltages whose phase shift then z. B. can be determined, in which both voltages are input to an AND gate whose output signal reproduces the phase shift with its pulse width.

Other measuring devices for measuring the electrical properties of the coil 12 are possible, for. B. the height of the current I1 or measuring circuits for measuring the reactance and / or the inductance of the coil 12 ,

Furthermore, it is also possible to successively input two different signal frequencies in succession, d. H. to carry out two measurements.

The sealing ring 16 can also be omitted if the vibration directly on the conductor housing 6a is entered.

Claims (13)

Measuring device ( 20 ) for a bone conduction hearing aid ( 2 ), the measuring device ( 20 ): a first interface ( 44a ) for connection to a measuring interface ( 44 ) of the bone conduction hearing aid ( 2 ) or connected to it, a signal source ( 21 ) for outputting at least one test signal (U1) to the first interface ( 44a ), and a measuring circuit ( 26 ) for measuring an electrical property of a coil ( 12 ) of the bone conduction hearing aid ( 2 ). Measuring device ( 20 ) according to claim 1, characterized in that the signal source ( 21 ) An alternating voltage signal of constant frequency in the acoustic frequency range of 17 Hz to 17 kHz, preferably between 1 kHz and 2 kHz z. B. about 1.4 kHz, outputs. Measuring device ( 20 ) according to claim 1 or 2, characterized in that it comprises an output device ( 40 . 41 ) for outputting an output signal. Measuring device ( 20 ) according to one of the preceding claims, characterized in that the output device ( 40 . 41 ) in response to the measurement outputs a first signal for indicating a proper contact force or at least a second signal for indicating an improper, in particular too high or too low, contact force. Measuring device ( 20 ) according to one of the preceding claims, characterized in that the output device ( 42 ) optical display means ( 40 . 41 ), z. B. differently colored LEDs ( 40 . 41 ) for displaying different functional states of the bone conduction hearing aid ( 2 ) or to display a value of the contact pressure. Measuring device ( 20 ) according to one of the preceding claims, characterized in that the measuring circuit ( 26 ) is designed to measure at least one of the following measured variables: one at its first interface ( 44a ) voltage (U1), one at the bone conduction hearing aid ( 2 ) falling voltage (U1), the reactance of the bone conduction hearing aid ( 2 ) or the coil ( 12 ) of the bone conduction hearing aid ( 2 ), through the first interface and measuring interface ( 44a ) into the bone conduction hearing aid ( 2 ) flowing measuring current (I1), and / or a phase shift of the measuring current (I1) relative to the signal source (I1) 21 ) or on the bone conduction hearing aid ( 2 ) decreasing voltage, an inductance of the coil ( 12 ) of the bone conduction hearing aid ( 2 ). Measuring device ( 20 ) according to one of the preceding claims, characterized in that the measuring circuit ( 26 ) a rectifier circuit ( 32 ) for rectifying a measuring voltage and outputting a rectified measuring voltage to a comparator device ( 34 ) having. Measuring device ( 20 ) according to one of the preceding claims, characterized in that it has setting means (Tr1, Tr2) for setting reference variables, in particular reference voltages, for calibrating the measuring device ( 20 ) in a depressurized state of the bone conduction hearing aid ( 2 ) having. Measuring device ( 20 ) according to one of the preceding claims, characterized in that it is provided by the bone conduction hearing aid ( 2 ) and with their first interface ( 44a ) to the measuring interface ( 44 ) of the bone conduction hearing aid ( 2 ) is connectable. Measuring device ( 20 ) according to claim 9, characterized in that it is designed to be portable. Measuring device ( 20 ) according to one of claims 1 to 8, characterized in that it is connected to the bone conduction hearing aid ( 2 ) is combined or integrated, and its first interface ( 44a ) with the measuring interface ( 44 ) of the bone conduction hearing aid ( 2 ), z. B. via a switch. Bone conduction hearing aid ( 2 ), comprising: a housing ( 4 ), a control panel ( 5 ), a vibration transducer ( 6 ) with a Konduktorkopf ( 15 ) for attachment to the head ( 1 ) of a user, wherein the bone conduction hearing aid ( 2 ) by means of a pressing device ( 3 ) is pressable on the head of the user, characterized in that the bone conduction hearing aid ( 2 ) a measuring interface ( 44 ) for connecting a measuring device ( 20 ) is provided according to one of the preceding claims or connected to this, wherein the measuring interface ( 44 ) with the vibration conductor ( 6 ) is connected to input a measurement signal (U1) to the vibration conductor ( 6 ). Arrangement of a measuring device ( 20 ) according to one of claims 1 to 11 and the bone conduction hearing aid ( 2 ) according to claim 12.

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