CN109113942B - Carbon nano tube fiber composite shape memory alloy type driver - Google Patents
Carbon nano tube fiber composite shape memory alloy type driver Download PDFInfo
- Publication number
- CN109113942B CN109113942B CN201811190544.3A CN201811190544A CN109113942B CN 109113942 B CN109113942 B CN 109113942B CN 201811190544 A CN201811190544 A CN 201811190544A CN 109113942 B CN109113942 B CN 109113942B
- Authority
- CN
- China
- Prior art keywords
- fiber yarn
- shape memory
- memory alloy
- carbon nanotube
- nano tube
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03G—SPRING, WEIGHT, INERTIA OR LIKE MOTORS; MECHANICAL-POWER PRODUCING DEVICES OR MECHANISMS, NOT OTHERWISE PROVIDED FOR OR USING ENERGY SOURCES NOT OTHERWISE PROVIDED FOR
- F03G7/00—Mechanical-power-producing mechanisms, not otherwise provided for or using energy sources not otherwise provided for
- F03G7/06—Mechanical-power-producing mechanisms, not otherwise provided for or using energy sources not otherwise provided for using expansion or contraction of bodies due to heating, cooling, moistening, drying or the like
- F03G7/065—Mechanical-power-producing mechanisms, not otherwise provided for or using energy sources not otherwise provided for using expansion or contraction of bodies due to heating, cooling, moistening, drying or the like using a shape memory element
Landscapes
- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Yarns And Mechanical Finishing Of Yarns Or Ropes (AREA)
- Springs (AREA)
- Resistance Heating (AREA)
Abstract
The invention discloses a carbon nano tube fiber composite shape memory alloy type driver, which comprises: a carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy type electric heating driver; the carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver comprises: a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy barrel type laser photo-thermal driver; the carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver comprises: nanoparticle composite carbon nanotube fiber yarn, shape memory alloy wire, laser receiver and laser; under the action of laser and photo-heat, the nanoparticle composite carbon nanotube fiber yarn and the shape memory alloy wire generate telescopic and rotary superposition enhancement cooperative driving effect.
Description
Technical Field
The invention belongs to the technical field of artificial intelligence, optical mechanical and electrical integration and robot driving, relates to driver technology in the field of optical mechanical and electrical integration and robot driving, and particularly relates to a carbon nanotube fiber composite shape memory alloy type driver.
Background
With the rapid development of artificial intelligence technology, opto-mechanical and mechanical integration and robot technology, the driving technology is more and more important. The robot driving joint is required to have higher flexibility, flexibility and compact structure, and the performance of the joint driving system determines various performance indexes of the robot, such as bearing capacity, appearance structure and the like, so that the selection of the driving system is very important for the design of the robot joint. The joint driver of the robot commonly used at present comprises a motor, pneumatic, hydraulic, human muscle made of new materials such as shape memory alloy, piezoelectric ceramics and the like. The traditional motor has low power/weight ratio, and a speed reducing mechanism is usually required to reduce the speed and increase the torque output, so that a transmission system is complex and the layout is difficult. Pneumatic muscle is a main driving mode of a pneumatic system for robot joint driving, and has simple and compact structure and low installation accuracy requirement, but an air supply pipeline is not separated, so that the moving range of a robot is limited, the resistance loss is increased, the control accuracy is reduced due to the overlong air supply pipeline, and accurate position and speed control is difficult to realize. The traditional hydraulic pressure has great advantages in the industrial robot joint driving, but the control system is huge, and meanwhile, the traditional hydraulic pressure is difficult to apply in the fields of mobile robots and the like due to the arrangement problem of oil (or gas) sources like pneumatic transmission of pneumatic muscles and the like. The artificial muscle made of new materials such as shape memory alloy, electrostriction, piezoelectricity and the like has the advantages of small volume, high output power, simple structure and the like, and has development prospect.
How to further develop the execution efficiency of the shape memory alloy in the driver, how to combine the shape memory alloy with the new nano material to further improve the driving efficiency, how to realize remote non-contact control driving in the fields of artificial intelligence technology, opto-mechanical integration and robotics, etc., and the technical problems are to be solved.
Disclosure of Invention
Aiming at the problems of driver technology development in the fields of artificial intelligence technology, optical-mechanical-electrical integration and robot technology at present, the invention provides a carbon nanotube fiber composite shape memory alloy type driver so as to achieve the aim of optimizing and improving various performance indexes of the driver.
The implementation specific technical scheme of the carbon nano tube fiber composite shape memory alloy type driver comprises the following steps: comprising the following steps: a carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy type electric heating driver; the carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver comprises: a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy barrel type laser photo-thermal driver; the carbon nanotube fiber composite shape memory alloy type electrothermal driver comprises: nanoparticle composite carbon nanotube fiber yarn bundle spring-type electric heating driver or nanoparticle composite carbon nanotube fiber yarn bundle core-type electric heating driver; the carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver comprises: nanoparticle composite carbon nanotube fiber yarn, shape memory alloy wire, driver output device, laser receiver and laser; a nanoparticle composite carbon nanotube fiber yarn comprising: assembling or compounding the nano particles and carbon nano tube fiber yarns; the carbon nanotube fiber yarn comprises: multiple strand fiber formed by a plurality of single carbon nano tubes or carbon nano tube gathering beam fiber through a strand doubling process is formed into continuous yarn with a spiral structure through a twisting process; the nanoparticle comprises: charged nanoparticles, nanoelectrolytes or nanoelectrolytes; the nano particle composite carbon nano tube fiber yarn and the shape memory alloy wire are in mutual interval close contact, a spiral stranded structure is formed through a secondary twisting process, one end of the nano particle composite carbon nano tube fiber yarn is provided with a laser receiver, the other end of the nano particle composite carbon nano tube fiber yarn is provided with a driver output device, and an integrated carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver is formed; under the irradiation of laser, the laser receiver of the carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver rapidly transmits laser photo-heat to the nano particle composite carbon nano tube fiber yarn, charged nano particles in the nano particle composite carbon nano tube fiber yarn rapidly enter holes of the carbon nano tube fiber yarn or gaps of a carbon nano tube fiber yarn bundle, so that the volume or the shape of the nano particle composite carbon nano tube fiber yarn is promoted to be changed, and a telescopic and rotary driving effect is generated; simultaneously, the laser receiver also transmits laser light and heat to the shape memory alloy wire, so that the temperature of the shape memory alloy wire is increased; the shape memory alloy wire and the nanoparticle composite carbon nanotube fiber yarn are in close contact with each other at intervals and are in a twisted spiral stranded structure, and the nanoparticle composite carbon nanotube fiber yarn also transmits laser light and heat to the shape memory alloy wire to generate a heat conduction superposition effect, so that the temperature of the shape memory alloy wire is accelerated, the driving response speed of the shape memory alloy wire is improved, and the shape memory alloy wire shape change generates an enhanced driving effect; under the action of laser light and heat, the nano particle composite carbon nano tube fiber yarn in the carbon nano tube fiber composite shape memory alloy wire type laser light and heat driver is combined with the shape memory alloy wire, so that the telescopic and rotary superposition enhancement cooperative driving effect can be generated jointly.
In the above scheme, the carbon nanotube fiber composite shape memory alloy barrel-type laser photothermal driver comprises: a nanoparticle composite carbon nanotube fiber yarn spring, a shape memory alloy cylinder, a nanoparticle composite carbon nanotube fiber yarn spiral winding layer, a laser receiver and a laser; the nano particle composite carbon nano tube fiber yarn spring layer is assembled in the middle of the carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver; the shape memory alloy cylinder is assembled outside the nanoparticle composite carbon nanotube fiber yarn spring layer and is in close contact with the nanoparticle composite carbon nanotube fiber yarn spring layer; the nano particle composite carbon nano tube fiber yarn is spirally wound outside the shape memory alloy cylinder according to a certain angle direction to form a nano particle composite carbon nano tube fiber yarn spiral winding layer, and the laser receiver is assembled at one end of the nano particle composite carbon nano tube fiber yarn spiral winding layer; the laser receiver is closely contacted with one end of the nanoparticle composite carbon nanotube fiber yarn spring, one end of the shape memory alloy cylinder and one end of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer; the nano particle composite carbon nano tube fiber yarn spring layer, the shape memory alloy cylinder, the nano particle composite carbon nano tube fiber yarn spiral winding layer and the laser receiver form an integrated carbon nano tube fiber composite shape memory alloy cylinder type laser photo-thermal driver with a sandwich structure together; under the irradiation of laser, the laser receiver of the carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver rapidly transmits laser photo-heat to the nano particle composite carbon nano tube fiber yarn spring layer, charged nano particles in the nano particle composite carbon nano tube fiber yarn spring layer rapidly enter holes of carbon nano tube fiber yarns or gaps of carbon nano tube fiber yarn bundles, and the volume or the shape of the nano particle composite carbon nano tube fiber yarn spring is promoted to change, so that a telescopic and rotary driving effect is generated; the laser receiver rapidly transmits laser light and heat to the nanoparticle composite carbon nanotube fiber yarn spiral winding layer, charged nanoparticles in the nanoparticle composite carbon nanotube fiber yarn spiral winding layer rapidly enter multiple holes of the carbon nanotube fiber yarn or gaps of carbon nanotube fiber yarn bundles, and the volume or the shape of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer is promoted to change, so that a telescopic and rotary driving effect is generated; the laser receiver rapidly transmits laser light and heat to the shape memory alloy cylinder, and the temperature of the shape memory alloy cylinder is increased; due to the integrated structure, the nanoparticle composite carbon nanotube fiber yarn spring and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer also transmit partial light and heat to the shape memory alloy cylinder to generate a laser light and heat superposition effect, so that the temperature rise of the shape memory alloy cylinder is accelerated, the driving response speed of the shape memory alloy cylinder is improved, and the shape memory alloy cylinder can generate a larger light and heat driving effect; under the action of laser light and heat, a nanometer particle composite carbon nanotube fiber yarn spring layer, a shape memory alloy cylinder and a nanometer particle composite carbon nanotube fiber yarn spiral winding layer in the carbon nanotube fiber composite shape memory alloy cylinder type laser light and heat driver generate telescopic and rotary superposition enhancement cooperative driving effects.
In the above-mentioned scheme, nanoparticle composite type carbon nanotube fiber yarn bundle spring-type electrothermal driver includes: a nanoparticle composite carbon nanotube fiber yarn spring layer, a shape memory alloy cylinder layer, and a nanoparticle composite carbon nanotube fiber yarn spiral winding layer; the nanoparticle composite carbon nanotube fiber yarn spring layer is processed by adopting nanoparticle composite carbon nanotube fiber yarn bundles, and an engineering resin reinforcing process is introduced, so that a spring manufactured by a double-spiral structure is formed through a secondary twisting process; the nanoparticle composite type carbon nano tube fiber yarn spring is assembled in the middle of the nanoparticle composite type carbon nano tube fiber yarn bundle spring type electric heating driver; the shape memory alloy cylinder layer is assembled outside the nanoparticle composite carbon nanotube fiber yarn spring layer and is in close contact with the nanoparticle composite carbon nanotube fiber yarn spring layer; the nano particle composite carbon nano tube fiber yarn is wound outside the shape memory alloy cylinder layer according to a certain angle and is in close contact with the shape memory alloy cylinder layer to form a nano particle composite carbon nano tube fiber yarn spiral winding layer; the two ends of the nanoparticle composite carbon nanotube fiber yarn spring layer are connected with controllable low voltage, and when the low voltage is connected, charged nanoparticles enter into the porous holes of the carbon nanotube fiber yarn spring layer or gaps of the carbon nanotube fiber yarn bundles, so that the morphology or volume of the nanoparticle composite carbon nanotube fiber yarn spring layer changes, and a driving effect of stretching and rotating is generated; the two ends of the shape memory alloy cylinder are connected with controllable medium voltage, and when the medium voltage is connected, the temperature of the shape memory alloy cylinder rises, so that the shape change generates a driving effect; the two ends of the nanoparticle composite type carbon nanotube fiber yarn spiral winding layer are connected with controllable high voltage, and when the high voltage is connected, charged nanoparticles enter the multi-holes of the carbon nanotube fiber yarn or gaps of the carbon nanotube fiber yarn bundles, so that the shape or volume of the nanoparticle composite type carbon nanotube fiber yarn spiral winding layer changes, and a driving effect of stretching and rotating is generated; the nanoparticle composite carbon nanotube fiber yarn spring layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer form an integrated structure; the nano particle composite carbon nano tube fiber yarn spring layer forms one electrode with low voltage characteristic, the nano particle composite carbon nano tube fiber yarn spiral winding layer forms the other electrode with high voltage characteristic, the middle shape memory alloy tube forms a potential difference, and forms an unbalanced electric field synergistic effect with middle voltage provided by two ends of the shape memory alloy tube, so as to generate controllable telescopic driving effect; the nanoparticle composite carbon nanotube fiber yarn spring layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer cooperatively form a telescopic and rotary superposition enhanced driving effect.
In the above-mentioned scheme, nanoparticle composite carbon nanotube fiber yarn bundle core type electric heat driver includes: the nano particle composite carbon nano tube fiber yarn bundle core layer, the shape memory alloy tube layer and the nano particle composite carbon nano tube fiber yarn spiral winding layer; the nanoparticle composite carbon nanotube fiber yarn bundle core layer is assembled in the middle of the nanoparticle composite carbon nanotube fiber yarn bundle core type electric heating driver; the shape memory alloy cylinder layer is assembled outside the nanoparticle composite carbon nano tube fiber yarn bundle core layer and is in close contact with the nanoparticle composite carbon nano tube fiber yarn bundle core layer; the nano particle composite carbon nano tube fiber yarn is wound outside the shape memory alloy cylinder layer according to a certain angle direction to form a nano particle composite carbon nano tube fiber yarn spiral winding layer; the two ends of the nano particle composite carbon nano tube fiber yarn bundle core layer are connected with controllable low voltage, when the low voltage is connected, charged nano particles enter holes of the carbon nano tube fiber yarn or gaps of the carbon nano tube fiber yarn bundle, so that the form or volume of the nano particle composite carbon nano tube fiber yarn bundle core layer is changed, and a driving effect of stretching and rotating is generated; the two ends of the nanoparticle composite type carbon nanotube fiber yarn spiral winding layer are connected with controllable high voltage, and when the high voltage is connected, charged nanoparticles enter the multi-holes of the carbon nanotube fiber yarn or gaps of the carbon nanotube fiber yarn bundles, so that the shape or volume of the nanoparticle composite type carbon nanotube fiber yarn spiral winding layer changes, and a driving effect of stretching and rotating is generated; the nanoparticle composite carbon nanotube fiber yarn bundle core layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer form an integrated structure; the nanoparticle composite carbon nanotube fiber yarn bundle core layer forms one electrode with low potential of the nanoparticle composite carbon nanotube fiber yarn bundle core type electric heating driver, the nanoparticle composite carbon nanotube fiber yarn spiral winding layer forms the other electrode with high potential and forms an unbalanced electric field gradient structural characteristic, an unbalanced potential difference is formed on the shape memory alloy cylinder layer, and the shape memory alloy cylinder is caused to generate a telescopic driving effect; the nanoparticle composite carbon nanotube fiber yarn bundle core layer, the shape memory alloy tube layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer cooperatively form a telescopic and rotary superposition enhanced driving effect.
In the above scheme, the preparation method of the carbon nanotube fiber yarn in the nanoparticle composite carbon nanotube fiber yarn comprises the following steps: electrostatic spinning, chemical vapor growth (CVD), wet spinning, dry spinning, array spinning, double crimping, high temperature high speed melt blowing, laser drawing or Xano Shear; the carbon nanotube fiber includes: single-walled carbon nanotube fibers or multi-walled carbon nanotube fibers; the method for assembling the nano particles on the carbon nano tube fiber yarn comprises the following steps: a blend melting method (BFM), a solution penetration method (infiration), a blend extrusion method (MLM), a clad implantation method (ICM), a blend wrap method (MWM), a Coating Film Method (CFM), or a robust grafting method (KBT).
In the above scheme, the laser receiver includes: adopting a three-dimensional graphene material and a composite material, a carbon nano tube composite material, a heat storage material, a carbon fiber composite material, a heat storage and heat conduction composite material, an inorganic heat conduction material or an organic heat conduction material; the three-dimensional graphene material includes: three-dimensional graphene material, three-dimensional graphene composite material, three-dimensional graphene oxide composite material or three-dimensional porous graphene composite material; the three-dimensional porous graphene composite material comprises: a three-dimensional porous graphene sponge composite, a three-dimensional porous graphene hydrogel composite, a three-dimensional porous graphene aerogel composite, a three-dimensional porous graphene foam composite, or a three-dimensional porous graphene oxide assembly composite; the three-dimensional porous graphene composite material comprises: the three-dimensional porous graphene composite material formed by assembling or adding graphene nano sheets, nano carbon tubes or heat conduction nano materials has the heat storage and heat conduction enhancement effects.
The carbon nano tube fiber composite shape memory alloy type driver has the following beneficial effects:
a. the invention relates to a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver, which adopts the steps that nano particle composite carbon nano tube fiber yarns and shape memory alloy wires are in mutual interval close contact, and a spiral stranded structure is formed through a twisting process; because the carbon nano tube fiber yarn has excellent heat conducting performance, the carbon nano tube fiber yarn is tightly contacted with the shape memory alloy wire and twisted to form a spiral stranded state, the carbon nano tube fiber yarn can quickly transmit laser light and heat to the shape memory alloy wire, so that the temperature rise of the shape memory alloy wire is promoted to be increased, and the driving response speed of the shape memory alloy wire is improved; under the action of laser light and heat, the nano particle composite carbon nano tube fiber yarn in the carbon nano tube fiber composite shape memory alloy wire type laser light and heat driver is combined with the shape memory alloy wire, so that the telescopic and rotary superposition enhancement cooperative driving effect can be generated jointly.
b. The carbon nano tube fiber composite shape memory alloy barrel type laser photo-thermal driver adopts a nano particle composite carbon nano tube fiber yarn spring layer, a shape memory alloy barrel, a nano particle composite carbon nano tube fiber yarn spiral winding layer and a laser receiver to jointly form the carbon nano tube fiber composite shape memory alloy barrel type laser photo-thermal driver with a sandwich structure; when laser light and heat are rapidly transmitted to the nanoparticle composite carbon nanotube fiber yarn spring layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer, charged nanoparticles rapidly enter the holes of the carbon nanotube fiber yarn or the gaps of the carbon nanotube fiber yarn bundles, so that the volume or the shape of the nanoparticle composite carbon nanotube fiber yarn spring layer and the volume or the shape of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer are simultaneously changed, and a telescopic and rotary cooperative driving effect is generated; the laser receiver also rapidly transmits laser light and heat to the shape memory alloy cylinder, and the temperature of the shape memory alloy cylinder is increased; due to the integrated structure, the nanoparticle composite carbon nanotube fiber yarn spring layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer also transmit part of photo-thermal energy to the shape memory alloy cylinder to generate a laser photo-thermal superposition effect, so that the temperature rise of the shape memory alloy cylinder is accelerated, and the photo-thermal driving response speed of the shape memory alloy cylinder is improved; under the action of laser light and heat, a nanometer particle composite carbon nanotube fiber yarn spring layer, a shape memory alloy cylinder and a nanometer particle composite carbon nanotube fiber yarn spiral winding layer in the carbon nanotube fiber composite shape memory alloy cylinder type laser light and heat driver generate telescopic and rotary superposition enhancement cooperative driving effects.
c. The invention relates to a nanoparticle composite carbon nanotube fiber yarn bundle spring type electric heating driver, which adopts a nanoparticle composite carbon nanotube fiber yarn spring layer, a shape memory alloy cylinder layer and a nanoparticle composite carbon nanotube fiber yarn spiral winding layer; the nanometer particle composite carbon nanotube fiber yarn spring layer forms one electrode with low voltage characteristic, the nanometer particle composite carbon nanotube fiber yarn spiral winding layer forms the other electrode with high voltage characteristic, the shape memory alloy tube in the middle layer forms a potential difference, and forms an unbalanced electric field synergistic effect with the middle voltage provided by the two ends of the shape memory alloy tube, so as to generate controllable telescopic driving effect; the nanoparticle composite carbon nanotube fiber yarn spring layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer cooperatively form a telescopic and rotary superposition enhanced driving effect.
Drawings
The invention will be further described with reference to the accompanying drawings and examples, in which:
FIG. 1 is a schematic illustration of a nanoparticle composite carbon nanotube fiber yarn structure;
FIG. 2 is a schematic diagram of a carbon nanotube fiber composite shape memory alloy wire type laser photothermal driver;
FIG. 3 is a schematic diagram of a carbon nanotube fiber composite shape memory alloy cartridge laser photothermal driver;
FIG. 4 is a schematic illustration of a nanoparticle composite carbon nanotube fiber yarn spring structure;
FIG. 5 is a schematic diagram of a nanoparticle composite carbon nanotube fiber yarn bundle spring-type electrothermal driver;
fig. 6 is a schematic structural diagram of a nanoparticle composite carbon nanotube fiber yarn bundle core type electrothermal driver.
The device comprises a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver 1, a nano particle composite carbon nano tube fiber yarn 2, a shape memory alloy wire 3, a first laser receiver 4, nano particles 5, a carbon nano tube fiber yarn 6, a driver output device 7, a carbon nano tube fiber composite shape memory alloy tube type laser photo-thermal driver 8, a first nano particle composite carbon nano tube fiber yarn spring layer 9, a shape memory alloy tube 10, a first nano particle composite carbon nano tube fiber yarn spiral winding layer 11, a second laser receiver 12, a nano particle composite carbon nano tube fiber yarn bundle spring type electric heating driver 13, a second nano particle composite carbon nano tube fiber yarn spring layer 14, a first shape memory alloy tube layer 15, a second nano particle composite carbon nano tube fiber yarn spiral winding layer 16, a nano particle composite carbon nano tube fiber yarn core type electric heating driver 17, a nano particle composite carbon nano tube fiber yarn bundle core layer 18, a second shape memory alloy tube layer 19 and a third nano tube composite carbon nano tube fiber yarn spiral winding layer 20.
Detailed Description
For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be further described with reference to the accompanying drawings.
Example 1.
Carbon nanotube fiber composite shape memory alloy wire type laser photothermal driver 1
The carbon nanotube fiber composite shape memory alloy wire type laser photothermal driver 1 of the embodiment 1 of the invention is a schematic structural diagram (see fig. 2); schematic structural diagram of nanoparticle composite carbon nanotube fiber yarn (see fig. 1).
The embodiment 1 of the invention discloses a realization specific technical scheme of a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver 1, which comprises the following steps: comprising the following steps: the device comprises a nanoparticle composite carbon nanotube fiber yarn 2, a shape memory alloy wire 3, a driver output device 7, a first laser receiver 4 and a laser; nanoparticle composite carbon nanotube fiber yarn 2 comprising: assembling or compounding the nano particles 5 and the carbon nano tube fiber yarns 6; a carbon nanotube fiber yarn 6 comprising: multiple strand fiber formed by a plurality of single carbon nano tubes or carbon nano tube gathering beam fiber through a strand doubling process is formed into continuous yarn with a spiral structure through a twisting process; the nano particles 5 adopt nano electrolyte substances; the nano particle composite carbon nano tube fiber yarn 2 and the shape memory alloy wire 3 are in mutual interval close contact, a spiral stranded structure is formed through a secondary twisting process, a first laser receiver 4 is assembled at one end of the nano particle composite carbon nano tube fiber yarn, a driver output device 7 is assembled at the other end of the nano particle composite carbon nano tube fiber yarn, and an integrated carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver 1 is formed; the first laser receiver 4 adopts a three-dimensional porous graphene composite material, namely nano heat-conducting particles are assembled in the three-dimensional porous graphene.
Under the irradiation of laser, the first laser receiver 4 transmits laser light and heat to the nano particle composite carbon nano tube fiber yarn 2, and charged ions of nano electrolyte substances in the nano particle composite carbon nano tube fiber yarn 2 rapidly enter into the holes of the carbon nano tube fiber yarn 6 or gaps of the carbon nano tube fiber yarn bundles, so that the volume or the shape of the nano particle composite carbon nano tube fiber yarn 2 is promoted to change, and a telescopic and rotary driving effect is generated; simultaneously, the first laser receiver 4 also transmits laser light and heat to the shape memory alloy wire 3, so that the temperature of the shape memory alloy wire 3 is increased; the shape memory alloy wire 3 and the nano particle composite carbon nano tube fiber yarn 2 are in close contact with each other at intervals and are in a twisted spiral stranded structure, and the nano particle composite carbon nano tube fiber yarn 2 bundles also transmit laser light and heat to the shape memory alloy wire 3 to generate a heat conduction superposition effect, so that the temperature rise speed of the shape memory alloy wire 3 is accelerated, the driving response speed of the shape memory alloy wire 3 is improved, and the shape memory alloy wire 3 generates a shape change to generate an enhanced driving effect; under the action of laser light and heat, the nano particle composite carbon nano tube fiber yarn 2 in the carbon nano tube fiber composite shape memory alloy wire type laser light and heat driver 1 is combined with the shape memory alloy wire 3, so that the telescopic and rotary superposition enhancement cooperative driving effect can be generated jointly.
Example 2.
Carbon nanotube fiber composite shape memory alloy barrel-type laser photo-thermal driver 8
The carbon nanotube fiber composite shape memory alloy barrel-type laser photothermal driver 8 of embodiment 2 of the present invention is schematically shown (see fig. 3); the nanoparticle composite carbon nanotube fiber yarn 2 is structurally schematic (see fig. 1); the first nanoparticle composite carbon nanotube fiber yarn spring layer 9 is schematically shown (see fig. 4).
The embodiment 2 of the invention relates to a concrete technical scheme for realizing a carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver 8, which comprises the following steps: the device comprises a first nanoparticle composite type carbon nano tube fiber yarn spring layer 9, a shape memory alloy cylinder 10, a first nanoparticle composite type carbon nano tube fiber yarn spiral winding layer 11, a second laser receiver 12 and a laser; the first nano particle composite carbon nano tube fiber yarn spring layer 9 is assembled in the middle of the carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver 8; the shape memory alloy cylinder 10 is assembled outside the first nano particle composite carbon nano tube fiber yarn spring layer 9 and is in close contact with the first nano particle composite carbon nano tube fiber yarn spring layer; the nano particle composite carbon nano tube fiber yarn 2 is spirally wound outside the shape memory alloy cylinder 10 according to a certain angle direction to form a first nano particle composite carbon nano tube fiber yarn spiral winding layer 11, and a second laser receiver 12 is assembled at one end of the first nano particle composite carbon nano tube fiber yarn spiral winding layer; the second laser receiver 12 is closely contacted with one end of the first nano particle composite carbon nano tube fiber yarn spring layer 9, one end of the shape memory alloy cylinder 10 and one end of the first nano particle composite carbon nano tube fiber yarn spiral winding layer 11; the first nano particle composite carbon nano tube fiber yarn spring layer 9, the shape memory alloy cylinder 10, the first nano particle composite carbon nano tube fiber yarn spiral winding layer 11 and the second laser receiver 12 together form the integrated carbon nano tube fiber composite shape memory alloy cylinder type laser photo-thermal driver 8 with a sandwich structure. The second laser receiver 12 is a three-dimensional graphene composite. The first nanoparticle composite carbon nanotube fiber yarn spring layer 9 is processed by adopting the nanoparticle composite carbon nanotube fiber yarn 2, and is introduced into an engineering resin reinforcing process, and a spring manufactured by a double-spiral structure is formed through a secondary twisting process.
Under the irradiation of laser, the second laser receiver 12 of the carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver 8 rapidly transmits laser photo-thermal to the first nano particle composite carbon nano tube fiber yarn spring layer 9, and charged nano particles 5 in the first nano particle composite carbon nano tube fiber yarn spring layer 9 rapidly enter holes of carbon nano tube fiber yarns or gaps of carbon nano tube fiber yarn bundles, so that the volume or shape of the first nano particle composite carbon nano tube fiber yarn spring layer 9 is changed, and a telescopic and rotary driving effect is generated; the second laser receiver 12 rapidly transmits laser light and heat to the first nanoparticle composite carbon nanotube fiber yarn spiral winding layer 11, and charged nanoparticles 5 in the first nanoparticle composite carbon nanotube fiber yarn spiral winding layer 11 rapidly enter multiple holes of carbon nanotube fiber yarns or gaps of carbon nanotube fiber yarn bundles to promote volume or form changes of the first nanoparticle composite carbon nanotube fiber yarn spiral winding layer 11, so that a telescopic and rotary driving effect is generated; the second laser receiver 12 rapidly transmits the laser light and heat to the shape memory alloy tube 10, and the temperature of the shape memory alloy tube 10 is increased; due to the integrated structure, the first nano particle composite carbon nano tube fiber yarn spring layer 9 and the first nano particle composite carbon nano tube fiber yarn spiral winding layer 11 also transmit part of light and heat to the shape memory alloy barrel 10, so that a laser light and heat superposition effect is generated, the temperature of the shape memory alloy barrel 10 is accelerated, the driving response speed of the shape memory alloy barrel 10 is improved, and the shape memory alloy barrel 10 can generate a larger light and heat driving effect; under the action of laser light and heat, a first nano particle composite carbon nano tube fiber yarn spring layer 9, a shape memory alloy cylinder 10 and a first nano particle composite carbon nano tube fiber yarn spiral winding layer 11 in the carbon nano tube fiber composite shape memory alloy cylinder type laser light and heat driver 8 generate telescopic and rotary superposition enhancement cooperative driving effects.
Example 3.
Nanoparticle composite carbon nanotube fiber yarn bundle spring type electrothermal driver 13
The nanoparticle composite carbon nanotube fiber yarn bundle spring-type electrothermal driver 13 of embodiment 3 of the present invention is schematically shown (see fig. 5); nanoparticle composite carbon nanotube fiber yarn structural schematic (see fig. 1); the second nanoparticle composite carbon nanotube fiber yarn spring layer 14 is schematically shown (see FIG. 4).
The nanoparticle composite carbon nanotube fiber yarn bundle spring-loaded electrothermal driver 13 of embodiment 3 of the present invention comprises: a second nanoparticle composite carbon nanotube fiber yarn spring layer 14, a first shape memory alloy cylinder layer 15, a second nanoparticle composite carbon nanotube fiber yarn spiral winding layer 16; the second nanoparticle composite carbon nanotube fiber yarn spring layer 14 is processed by adopting the nanoparticle composite carbon nanotube fiber yarn 2, and an engineering resin reinforcing process is introduced, so that a spring manufactured by a double-spiral structure is formed through a secondary twisting process; the second nanoparticle composite carbon nanotube fiber yarn spring layer 14 is assembled in the middle of the nanoparticle composite carbon nanotube fiber yarn bundle spring type electrothermal driver 13; the first shape memory alloy cylinder layer 15 is assembled outside the nanoparticle composite carbon nanotube fiber yarn spring layer 14 and is in close contact with the outer surface of the nanoparticle composite carbon nanotube fiber yarn spring layer; the nanoparticle composite carbon nanotube fiber yarn 2 is wound outside the first shape memory alloy cylinder layer 15 according to a certain angle and is in close contact with the first shape memory alloy cylinder layer to form a second nanoparticle composite carbon nanotube fiber yarn spiral winding layer 16.
The nanoparticle composite carbon nanotube fiber yarn 2 is processed and manufactured to be connected with controllable low voltage at two ends of a spring, and when the low voltage is connected, charged nanoparticles 5 enter into the porous holes or gaps of the carbon nanotube fiber yarn spring layer 14 of the second carbon nanotube fiber yarn, so that the shape or volume of the spring layer 14 of the second nanoparticle composite carbon nanotube fiber yarn is changed, and a driving effect of stretching and rotating is generated; the two ends of the shape memory alloy cylinder 15 are connected with controllable medium voltage, when the medium voltage is connected, the temperature of the shape memory alloy cylinder 15 is increased, and then the shape is changed to generate a driving effect; the two ends of the second nano particle composite carbon nano tube fiber yarn spiral winding layer 16 are connected with controllable high voltage, when the high voltage is connected, charged nano particles 5 enter into the multi-holes of the carbon nano tube fiber yarn or gaps of the carbon nano tube fiber yarn bundles, so that the shape or volume of the second nano particle composite carbon nano tube fiber yarn spiral winding layer 16 is changed, and a telescopic and rotary driving effect is generated; the second nano particle composite carbon nano tube fiber yarn spring layer 14, the first shape memory alloy cylinder layer 15 and the second nano particle composite carbon nano tube fiber yarn spiral winding layer 16 form an integrated structure; the second nano particle composite carbon nano tube fiber yarn spring layer 14 forms one electrode with low voltage characteristic, the second nano particle composite carbon nano tube fiber yarn spiral winding layer 16 forms the other electrode with high voltage characteristic, the shape memory alloy tube 15 of the middle layer forms a potential difference, and forms an unbalanced electric field synergistic effect with the middle voltage provided by the two ends of the shape memory alloy tube 15, so as to generate controllable telescopic driving effect; the second nanoparticle composite carbon nanotube fiber yarn spring layer 14, the first shape memory alloy cylinder layer 15 and the second nanoparticle composite carbon nanotube fiber yarn spiral winding layer 16 cooperatively form a telescopic and rotary superposition enhanced driving effect.
Example 4.
Nanoparticle composite carbon nanotube fiber yarn bundle core type electric heating driver 17
The nanoparticle composite carbon nanotube fiber yarn bundle core type electrothermal driver 17 of embodiment 4 of the present invention is schematically shown in fig. 6; the nanoparticle composite carbon nanotube fiber yarn 2 is structurally schematic (see fig. 1).
The nanoparticle composite carbon nanotube fiber yarn bundle core type electrothermal driver 17 of embodiment 4 of the present invention comprises: comprising the following steps: the nano-particle composite carbon nano-tube fiber yarn bundle core layer 18, the second shape memory alloy tube layer 19 and the third nano-particle composite carbon nano-tube fiber yarn spiral winding layer 20; the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18 is manufactured by processing nanoparticle composite carbon nanotube fiber yarns 2; the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18 is assembled in the middle; the second shape memory alloy tube layer 19 is assembled outside the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18 and is in close contact with the nanoparticle composite carbon nanotube fiber yarn bundle core layer; the nanoparticle composite carbon nanotube fiber yarn 2 is wound outside the second shape memory alloy tube layer 19 according to a certain angle direction to form a third nanoparticle composite carbon nanotube fiber yarn spiral winding layer 20.
The two ends of the nano particle composite carbon nano tube fiber yarn bundle core layer 18 are connected with controllable low voltage, when the low voltage is connected, charged nano particles 5 enter into the multi-holes of the carbon nano tube fiber yarns or gaps of the carbon nano tube fiber yarn bundles, so that the form or volume of the nano particle composite carbon nano tube fiber yarn bundle core layer 18 is changed, and a driving effect of stretching and rotating is generated; the two ends of the third nano particle composite carbon nano tube fiber yarn spiral winding layer 20 are connected with controllable high voltage, when the high voltage is connected, charged nano particles 5 enter into the multi-holes of the carbon nano tube fiber yarn or gaps of the carbon nano tube fiber yarn bundles, so that the shape or volume of the third nano particle composite carbon nano tube fiber yarn spiral winding layer 20 is changed, and a telescopic and rotary driving effect is generated; the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18, the second shape memory alloy tube layer 19 and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer 20 form an integrated structure; the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18 forms one electrode of the nanoparticle composite carbon nanotube fiber yarn bundle core type electric heat driver 17 with low potential, the third nanoparticle composite carbon nanotube fiber yarn spiral winding layer 20 forms the other electrode with high potential and forms the unbalanced electric field gradient structural characteristic, and forms the unbalanced potential difference for the second shape memory alloy barrel layer 19, so that the shape memory alloy barrel 19 generates the telescopic superposition driving effect; the nanoparticle composite carbon nanotube fiber yarn bundle core layer 18, the second shape memory alloy tube layer 19 and the third nanoparticle composite carbon nanotube fiber yarn spiral winding layer 20 cooperatively form a telescopic and rotary superposition enhanced driving effect.
In this document, terms such as front, rear, upper, lower, etc. are defined with respect to the positions of the components in the drawings and with respect to each other, for clarity and convenience in expressing the technical solution. It should be understood that the use of such orientation terms should not limit the scope of the claimed application.
The embodiments described above and features of the embodiments herein may be combined with each other without conflict.
The foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the application are intended to be included within the scope of the application.
Claims (1)
1. A carbon nanotube fiber composite shape memory alloy actuator, comprising: a carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy type electric heating driver; the carbon nano tube fiber composite shape memory alloy type laser photo-thermal driver comprises: a carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver or a carbon nano tube fiber composite shape memory alloy barrel type laser photo-thermal driver; the carbon nanotube fiber composite shape memory alloy type electrothermal driver comprises: nanoparticle composite carbon nanotube fiber yarn bundle spring-type electric heating driver or nanoparticle composite carbon nanotube fiber yarn bundle core-type electric heating driver; the carbon nano tube fiber composite shape memory alloy wire type laser photo-thermal driver comprises: nanoparticle composite carbon nanotube fiber yarn, shape memory alloy wire, driver output device, laser receiver and laser; the nanoparticle composite carbon nanotube fiber yarn is formed by assembling or compositing nanoparticles and carbon nanotube fiber yarn; the carbon nano tube fiber yarn is a multi-ply fiber formed by single carbon nano tube or carbon nano tube aggregation bundle fiber through a ply-bonding process, and a continuous yarn with a spiral structure is formed through a twisting process; the nanoparticle comprises: charged nanoparticles, nanoelectrolytes or nanoelectrolytes; the nanoparticle composite carbon nanotube fiber yarn and the shape memory alloy wire are in mutual interval close contact, a spiral stranded structure is formed by secondary twisting, one end of the spiral stranded structure is provided with a laser receiver, and the other end of the spiral stranded structure is provided with a driver output device, so that an integrated carbon nanotube fiber composite shape memory alloy wire type laser photo-thermal driver is formed;
The carbon nano tube fiber composite shape memory alloy barrel-type laser photo-thermal driver comprises: a nanoparticle composite carbon nanotube fiber yarn spring, a shape memory alloy cylinder, a nanoparticle composite carbon nanotube fiber yarn spiral winding layer, a laser receiver and a laser; the nanoparticle composite type carbon nanotube fiber yarn spring is assembled in the middle of the carbon nanotube fiber composite shape memory alloy barrel-type laser photo-thermal driver; the shape memory alloy cylinder is assembled outside the nanoparticle composite carbon nanotube fiber yarn spring and is in close contact with the nanoparticle composite carbon nanotube fiber yarn spring; the nano particle composite carbon nano tube fiber yarn is spirally wound outside the shape memory alloy cylinder according to a certain angle direction to form a nano particle composite carbon nano tube fiber yarn spiral winding layer, and the laser receiver is assembled at one end of the nano particle composite carbon nano tube fiber yarn spiral winding layer; the laser receiver is closely contacted with one end of the nanoparticle composite carbon nanotube fiber yarn spring, one end of the shape memory alloy cylinder and one end of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer; the nano particle composite carbon nano tube fiber yarn spring, the shape memory alloy cylinder, the nano particle composite carbon nano tube fiber yarn spiral winding layer and the laser receiver form an integrated carbon nano tube fiber composite shape memory alloy cylinder type laser photo-thermal driver;
The nanoparticle composite carbon nanotube fiber yarn bundle spring-type electrothermal driver comprises: a nanoparticle composite carbon nanotube fiber yarn spring layer, a shape memory alloy cylinder layer, and a nanoparticle composite carbon nanotube fiber yarn spiral winding layer; the nanoparticle composite type carbon nano tube fiber yarn spring adopts a nanoparticle composite type carbon nano tube fiber yarn bundle and engineering resin, and a double-spiral structure is formed through a secondary twisting process to manufacture the spring of the nanoparticle composite type carbon nano tube fiber yarn spring layer; the nanoparticle composite type carbon nano tube fiber yarn spring layer is assembled in the middle of the nanoparticle composite type carbon nano tube fiber yarn bundle spring type electric heating driver; the shape memory alloy cylinder layer is assembled outside the nanoparticle composite carbon nanotube fiber yarn spring layer and is in close contact with the nanoparticle composite carbon nanotube fiber yarn spring layer; the nano particle composite carbon nano tube fiber yarn is wound outside the shape memory alloy cylinder layer according to a certain angle and is in close contact with the shape memory alloy cylinder layer to form a nano particle composite carbon nano tube fiber yarn spiral winding layer; the two ends of the nanoparticle composite carbon nanotube fiber yarn spring layer are connected with controllable low voltage, and the nanoparticle composite carbon nanotube fiber yarn spring layer can stretch and rotate under the action of the low voltage; the two ends of the shape memory alloy cylinder are connected with controllable medium voltage, and when the medium voltage is connected, the temperature of the shape memory alloy cylinder rises, so that the shape changes; the two ends of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer are connected with controllable high voltage, and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer can stretch and rotate under the action of the high voltage; the nanoparticle composite carbon nanotube fiber yarn spring layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer form an integrated structure; the nanoparticle composite carbon nanotube fiber yarn spring layer forms one electrode with low voltage characteristics, and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer forms the other electrode with high voltage characteristics;
The nanoparticle composite carbon nanotube fiber yarn bundle core type electric heating driver comprises: the nano particle composite carbon nano tube fiber yarn bundle core layer, the shape memory alloy tube layer and the nano particle composite carbon nano tube fiber yarn spiral winding layer; the nanoparticle composite carbon nanotube fiber yarn bundle core layer is assembled in the middle of the nanoparticle composite carbon nanotube fiber yarn bundle core type electric heating driver; the shape memory alloy cylinder layer is assembled outside the nanoparticle composite carbon nano tube fiber yarn bundle core layer and is in close contact with the nanoparticle composite carbon nano tube fiber yarn bundle core layer; the nano particle composite carbon nano tube fiber yarn is wound outside the shape memory alloy cylinder layer according to a certain angle direction to form a nano particle composite carbon nano tube fiber yarn spiral winding layer; the two ends of the nanoparticle composite carbon nano tube fiber yarn bundle core layer are connected with controllable low voltage, and the nanoparticle composite carbon nano tube fiber yarn bundle core layer can stretch and rotate under the action of the low voltage; the two ends of the nanoparticle composite carbon nanotube fiber yarn spiral winding layer are connected with controllable high voltage, and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer can stretch and rotate under the action of the high voltage; the nanoparticle composite carbon nanotube fiber yarn bundle core layer, the shape memory alloy cylinder layer and the nanoparticle composite carbon nanotube fiber yarn spiral winding layer form an integrated structure; the nanoparticle composite carbon nano tube fiber yarn bundle core layer forms one electrode with low potential of the nanoparticle composite carbon nano tube fiber yarn bundle core type electrothermal driver, and the nanoparticle composite carbon nano tube fiber yarn spiral winding layer forms the other electrode with high potential;
The preparation method of the carbon nano tube fiber yarn in the nano particle composite carbon nano tube fiber yarn comprises the following steps: electrostatic spinning, chemical vapor growth, wet spinning, dry spinning, array spinning, double crimping, high temperature high speed melt blowing, laser drawing or Xano Shear; the carbon nanotube fiber includes: single-walled carbon nanotube fibers or multi-walled carbon nanotube fibers; the method for assembling the nano particles on the carbon nano tube fiber yarn comprises the following steps: a blending fusion method, a solution permeation method, a blending extrusion rolling method, a coating implantation method, a blending winding method, a coating film method or a strong grafting method;
the laser receiver is made of a three-dimensional graphene material, a composite material, a carbon nanotube composite material, a heat storage material, a carbon fiber composite material, a heat storage and heat conduction composite material, an inorganic heat conduction material or an organic heat conduction material; the three-dimensional graphene material includes: three-dimensional graphene material, three-dimensional graphene composite material, three-dimensional graphene oxide composite material or three-dimensional porous graphene composite material; the three-dimensional porous graphene composite material comprises: a three-dimensional porous graphene sponge composite, a three-dimensional porous graphene hydrogel composite, a three-dimensional porous graphene aerogel composite, a three-dimensional porous graphene foam composite, or a three-dimensional porous graphene oxide assembly composite; the three-dimensional porous graphene composite material comprises: and assembling or adding a three-dimensional porous graphene composite material formed by graphene nano sheets, nano carbon tubes or heat-conducting nano materials.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201811190544.3A CN109113942B (en) | 2018-10-12 | 2018-10-12 | Carbon nano tube fiber composite shape memory alloy type driver |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201811190544.3A CN109113942B (en) | 2018-10-12 | 2018-10-12 | Carbon nano tube fiber composite shape memory alloy type driver |
Publications (2)
Publication Number | Publication Date |
---|---|
CN109113942A CN109113942A (en) | 2019-01-01 |
CN109113942B true CN109113942B (en) | 2023-08-29 |
Family
ID=64858049
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201811190544.3A Active CN109113942B (en) | 2018-10-12 | 2018-10-12 | Carbon nano tube fiber composite shape memory alloy type driver |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN109113942B (en) |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109571458B (en) * | 2019-01-08 | 2023-09-22 | 中国地质大学(武汉) | Carbon nanocomposite working medium driver |
CN112376143B (en) * | 2020-10-23 | 2022-05-20 | 复旦大学 | Implantable ligament substitute material based on oriented carbon nanotube fibers and preparation method thereof |
CN112864597B (en) * | 2021-01-11 | 2023-03-31 | 北京碳垣新材料科技有限公司 | Carbon nanotube-shape memory alloy radio frequency antenna |
CN117267075B (en) * | 2023-11-17 | 2024-01-19 | 兰州西脉科立新材料有限公司 | Linear motor |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1614865A (en) * | 2004-12-02 | 2005-05-11 | 上海交通大学 | Permanent magnetic bistable electrothermal microdrivers |
CN104769834A (en) * | 2012-08-01 | 2015-07-08 | 德克萨斯州大学系统董事会 | Coiled and non-coiled twisted nanofiber yarn and polymer fiber torsional and tensile actuators |
WO2015143601A1 (en) * | 2014-03-24 | 2015-10-01 | 国家纳米科学中心 | Electrically-heated flexible driver, applications thereof, and locking unit driven by driver |
CN106905546A (en) * | 2017-02-20 | 2017-06-30 | 西北工业大学 | A kind of high strength and high conductivity composite fibre strengthens the preparation method of composite |
CN209800177U (en) * | 2018-10-12 | 2019-12-17 | 中国地质大学(武汉) | Carbon nano tube fiber composite shape memory alloy type driver |
Family Cites Families (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP5679733B2 (en) * | 2010-08-06 | 2015-03-04 | キヤノン株式会社 | Actuator |
-
2018
- 2018-10-12 CN CN201811190544.3A patent/CN109113942B/en active Active
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1614865A (en) * | 2004-12-02 | 2005-05-11 | 上海交通大学 | Permanent magnetic bistable electrothermal microdrivers |
CN104769834A (en) * | 2012-08-01 | 2015-07-08 | 德克萨斯州大学系统董事会 | Coiled and non-coiled twisted nanofiber yarn and polymer fiber torsional and tensile actuators |
WO2015143601A1 (en) * | 2014-03-24 | 2015-10-01 | 国家纳米科学中心 | Electrically-heated flexible driver, applications thereof, and locking unit driven by driver |
CN106905546A (en) * | 2017-02-20 | 2017-06-30 | 西北工业大学 | A kind of high strength and high conductivity composite fibre strengthens the preparation method of composite |
CN209800177U (en) * | 2018-10-12 | 2019-12-17 | 中国地质大学(武汉) | Carbon nano tube fiber composite shape memory alloy type driver |
Non-Patent Citations (1)
Title |
---|
纳米碳复合材料的结构设计和功能仿生;余雪平;兰竹瑶;姜春阳;张骁骅;李清文;;科学通报(第23期);全文 * |
Also Published As
Publication number | Publication date |
---|---|
CN109113942A (en) | 2019-01-01 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN109113942B (en) | Carbon nano tube fiber composite shape memory alloy type driver | |
CN209800177U (en) | Carbon nano tube fiber composite shape memory alloy type driver | |
Haines et al. | New twist on artificial muscles | |
Kosidlo et al. | Nanocarbon based ionic actuators—a review | |
Jang et al. | Carbon nanotube yarn for fiber‐shaped electrical sensors, actuators, and energy storage for smart systems | |
Leng et al. | Recent advances in twisted‐fiber artificial muscles | |
JP5959807B2 (en) | Actuator and actuator structure | |
JP5679733B2 (en) | Actuator | |
US12006598B2 (en) | Sheath-run artificial muscles and methods of use thereof | |
Xu et al. | High-performance flexible asymmetric fiber-shaped supercapacitor based on CF/PPy and CNT/MnO2 composite electrodes | |
JP5733938B2 (en) | Actuator | |
JP5734064B2 (en) | Actuator | |
CN209278065U (en) | Carbon nano-tube fibre yarn Composite thermal expansion material type photothermal laser driver | |
CN112721230B (en) | Microfiber high-energy implantation equipment for manufacturing three-dimensional reinforced carbon fiber composite material | |
Chang et al. | Soft actuators based on carbon nanomaterials | |
Deng et al. | Progress and prospective of electrochemical actuator materials | |
CN109372710B (en) | Carbon nano tube fiber yarn composite thermal expansion material type laser photo-thermal driver | |
Liu et al. | CNT-intertwined polymer electrode toward the practical application of wearable devices | |
Li et al. | Spirally deformable soft actuators and their designable helical actuations based on a highly oriented carbon nanotube film | |
JP2008500189A (en) | Actuators based on geometrically anisotropic nanoparticles | |
Hayashi et al. | A review of dry spun carbon nanotube yarns and their potential applications in energy and mechanical devices | |
JP2010158103A (en) | Actuator | |
CN101881465B (en) | Electronic ignition device | |
Lang et al. | Emerging innovations in electrically powered artificial muscle fibers | |
Hu et al. | Fast and Strong Carbon Nanotube Yarn Artificial Muscles by Electro-osmotic Pump |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |