CN203352580U - Self-driven wireless signal transmit-receive apparatus - Google Patents

Self-driven wireless signal transmit-receive apparatus Download PDF

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Publication number
CN203352580U
CN203352580U CN2013204340107U CN201320434010U CN203352580U CN 203352580 U CN203352580 U CN 203352580U CN 2013204340107 U CN2013204340107 U CN 2013204340107U CN 201320434010 U CN201320434010 U CN 201320434010U CN 203352580 U CN203352580 U CN 203352580U
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China
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wireless signal
self
conducting layer
metal conducting
signal
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CN2013204340107U
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周军
代俊杰
胡彬
钟俊文
钟其泽
胡琦旖
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Huazhong University of Science and Technology
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Huazhong University of Science and Technology
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Abstract

The utility model discloses a self-driven wireless signal transmit-receive apparatus, comprising a power supply and signal source integrated unit and a wireless signal transmitting terminal. The power supply and signal source integrated unit is a flexible power generation component and comprises a first assembly and a second assembly, a current signal is generated by pressing and loosening the first and second assemblies, and the current signal performs as a signal source for controlling wireless signal emission; the wireless signal transmitting terminal is connected with the power supply and signal source integrated unit in a circuit to receive the signal source from the power supply and signal source integrated unit, a wireless signal transmitting tube is correspondingly driven according to the current signal, and wireless signal emission is achieved. The utility model also discloses a corresponding self-driven wireless signal reception apparatus. According to the self-driven wireless signal transmit-receive apparatus, a self-driven wireless signal transmit-receive function is realized without a cell, in addition, the self-driven wireless signal transmit-receive apparatus is characterized in that the structure is compact, control is convenient, the performance is stable, the applicability is strong, etc.

Description

A kind of self-driven wireless signal transceiver
Technical field
The utility model belongs to wireless transmission and reception technique field, more specifically, relates to a kind of self-driven wireless signal transceiver.
Background technology
The energy is All Around The World development and the most basic actuating force of economic growth, is the basis that the mankind depend on for existence, closely bound up with our daily life.Along with the problems such as global warming, environmental pollution increase the weight of day by day, the fossil fuel of take faces a crisis as basic conventional energy resource, and finding clean and reproducible green energy resource becomes one that current social development and human civilization progress face and urgently challenge.Electric energy be in energy source use the most effectively, the most direct a kind of form, a lot of energy forms finally all are converted to electric energy and are used by people.The application of electric energy divides both macro and micro two aspects, and aspect macroscopical, the normal operation of society and daily life all depend on conventional energy resource or new forms of energy and produce and carry and next electric energy; Aspect microcosmic, personal electric product, implantating biological sensors, microelectromechanical systems, environmental monitoring transducer, even little to nanometer robot all need independent, persistent power supply device provides power, how for these microdevices provide suitable power supply, to be a major issue.
For example, for the electronic product of wireless signal transceiver and so on, in general its power consumption is lower, this class of electronic devices is generally passed through powered battery at present, yet research shows, at least there is following drawback in this battery-powered mode: at first, power supply and the signal source of existing wireless signal transceiver are two systems of separating independently of one another, that is to say that battery is only as the energy supply parts, and the signal source that switch transmits as control and by the touching switch transmit, in the case, depend on the life-span of battery the useful life of wireless signal transceiver, once meet the situation of battery failure, may be due to quantity problem loss signal, even cause the paralysis of system, secondly, due to power supply and separately independent setting of signal source, corresponding meeting causes the circuit structure of wireless signal transceiver inside complicated, and is difficult to make wireless signal transceiver further microminiaturized, finally, discarded battery also can cause and have a strong impact on environment, and has the problems such as the replacement inconvenience of battery and cost increase.
The utility model content
Above defect or Improvement requirement for prior art, the utility model provides a kind of self-driven wireless signal transmitting device and receiving system thereof, its purpose is by its energy supply parts are improved and integrate mutually with signal source, mutually should be able to possess compact conformation in the situation that can realize self-driven wireless signal transmission-receiving function without battery simultaneously, be convenient to control, stable performance and the characteristics such as applicability is strong.
For achieving the above object, according to the utility model, provide a kind of self-driven wireless signal transmitting device, this device comprises power supply and signal source integral unit and wireless signal transmission end, it is characterized in that:
Described power supply and signal source integral unit are the form of flexible generating element and comprise the first assembly and the second assembly, wherein the first assembly consists of jointly high molecular polymer insulating barrier and the first metal conducting layer that is deposited on this high molecular polymer insulating barrier upper surface, and is formed with the first electrode at the edge of this first metal conducting layer; The second assembly consists of jointly flexible substrates and the second metal conducting layer that is deposited on this flexible substrates upper surface, and is formed with the second electrode at the edge of this second metal conducting layer; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier and described the second metal conducting layer is mutually opposed and possess certain interval, can produce ac current signal by the operation of pressing and unclamp first, second assembly in this way, simultaneously using it as the signal source of controlling wireless signal transmission;
Described wireless signal transmission end is connected with signal source integral unit circuit with described power supply, for receiving the ac current signal from power supply and signal source integral unit, then carry out respective drive wireless signal transmission pipe according to this ac current signal, realize thus the firing operation of wireless signal.
As further preferably, the material of described high molecular polymer insulating barrier is selected from PETG, polytetrafluoroethylene, polystyrene, polyimides, polyethylene, dimethyl silicone polymer, FEP fluorinated ethylene propylene copolymer, polytrifluorochloroethylene, polyvinylidene fluoride, ethylene tetrafluoroethylene copolymer or polymethyl methacrylate; The material of described the first metal conducting layer is selected from copper, aluminium or tin indium oxide, and the material of described the second metal conducting layer is selected from gold, silver, copper or aluminium.
As further preferably, the lower surface of described high molecular polymer insulating barrier also is processed to form a plurality of micro-nano concaveconvex structures, and the average-size of these concaveconvex structures is 50 nanometers~200 nanometers.
As further preferably, described power supply and signal source integral unit consist of jointly single flexible generating element or a plurality of flexible generating element that is connected in parallel to each other.
As further preferably, described wireless signal transmission end comprises connected voltage stabilizing chip, transmitting chip and the infrared LED transmitting tube of circuit each other, wherein the voltage stabilizing chip, for being converted to DC current signal from the ac current signal of described power supply and signal source integral unit, giving voltage stabilizing simultaneously and processes; Transmitting chip is modulated for the DC current signal to after conversion; The infrared LED transmitting tube is converted to light signal by the signal of telecommunication after modulation, outwards launches infrared signal simultaneously.
As further preferably, described self-driven wireless signal transmitting device integral body is the flexible structure of collapsible processing.
According on the other hand of the present utility model, corresponding self-driven wireless signal receiver also is provided, this device comprises power subsystem and reception of wireless signals end, it is characterized in that:
Described power subsystem is the form of flexible generating element and comprises the first assembly and the second assembly, wherein the first assembly consists of jointly high molecular polymer insulating barrier and the first metal conducting layer that is deposited on this high molecular polymer insulating barrier upper surface, and is formed with the first electrode at the edge of this first metal conducting layer; The second assembly consists of jointly flexible substrates and the second metal conducting layer that is deposited on this flexible substrates upper surface, and is formed with the second electrode at the edge of this second metal conducting layer; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier and described the second metal conducting layer is mutually opposed and possess certain interval, can produce the electric energy for the work of reception of wireless signals end by the operation of pressing and unclamp first, second assembly in this way;
Described reception of wireless signals end is connected with supporting wireless signal transmission end signal, and the electric energy that utilizes described power subsystem to provide receives from the wireless signal of wireless signal transmission end and it is judged to processing, realizes thus the reception of wireless signals process.
As further preferably, the material of described high molecular polymer insulating barrier is selected from PETG, polytetrafluoroethylene, polystyrene, polyimides, polyethylene, dimethyl silicone polymer, FEP fluorinated ethylene propylene copolymer, polytrifluorochloroethylene, polyvinylidene fluoride, ethylene tetrafluoroethylene copolymer or polymethyl methacrylate; The material of described the first metal conducting layer is selected from copper, aluminium or tin indium oxide, and the material of described the second metal conducting layer is selected from gold, silver, copper or aluminium.
As further preferably, described reception of wireless signals end comprises rectification unit, energy-storage units and the receiving chip that circuit connects each other, and wherein rectification unit will be for being converted to direct current from the alternating current of described power subsystem; Energy-storage units is collected storage for the direct current that conversion is obtained; Receiving chip receives from the wireless signal of wireless signal transmission end and it is judged to processing for the electric energy that utilizes described energy-storage units to store.
As further preferably, described self-driven wireless signal receiver integral body is the flexible structure of collapsible processing.
In general, the above technical scheme of conceiving by the utility model compared with prior art, mainly possesses following technological merit:
1, by adopting flexible generating element substitute the battery in all kinds of wireless signal transceivers and its total system is carried out to structure optimization, can utilize fully, easily the energy of human body self, can guarantee the required work energy of wireless signal transmitting-receiving operation by simple operations, effectively avoid the various inconvenience that cause due to running down of battery simultaneously;
2, by the power supply by wireless signal transmitting device and signal source module, integrated, can when produce the energy be enough to drive transmitting terminal within a short period of time, also realize smoothly self-driven function, thereby make overall structure more simple compact, contribute to improve working life, and be applicable to all kinds of severe applied environments;
3, according to self-driven wireless signal transceiver integral body of the present utility model, be flexible, can processing also just be arranged bending fold, therefore compare and possess greater flexibility with traditional hard device in application, and possess stable performance, cost is low and is convenient to the characteristics such as manufacture in enormous quantities.
The accompanying drawing explanation
Fig. 1 is the unitary construction schematic diagram according to power supply and signal source integral unit in self-driven wireless signal transmitting device of the present utility model;
Fig. 2 a is to after giving single depression according to flexible generating element of the present utility model, the electric current time history plot produced;
Fig. 2 b carries out the time dependent schematic diagram of the resulting integral charge of integration to the current peak in Fig. 5 a.
In institute's drawings attached, identical Reference numeral is used for meaning identical element or structure, wherein:
11-first assembly 12-second assembly 111-high molecular polymer insulating barrier 112-first metal conducting layer 113-first electrode 121-flexible substrates 122-second metal conducting layer 123-the second electrode
Embodiment
In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain the utility model, and be not used in restriction the utility model.In addition, below in each execution mode of described the utility model involved technical characterictic as long as form each other conflict, just can mutually not combine.
Fig. 1 is the unitary construction schematic diagram according to power supply and signal source integral unit in self-driven wireless signal transmitting device of the present utility model.As shown in fig. 1, this power supply and signal source integral unit 1 are the form of flexible generating element, it can consist of the single flexible generating element, or a plurality of flexible generating element be connected in parallel to each other forms jointly, and except as doing the work power supply, also have both the function as the signal source of controlling wireless signal transmission in whole wireless signal transmitting device.
Particularly, each flexible generating element (or being referred to as flexible generator) comprises the first assembly 11 and the second assembly 12, wherein the first assembly 11 consists of jointly high molecular polymer insulating barrier 111 and the first metal conducting layer 112 that is deposited on these high molecular polymer insulating barrier 111 upper surfaces, and is formed with the first electrode 113 at the edge of this first metal conducting layer 112; The second assembly 12 consists of jointly flexible substrates 121 and the second metal conducting layer 122 that is deposited on these flexible substrates 121 upper surfaces, and is formed with the second electrode 123 at the edge of this second metal conducting layer 122; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier 111 and described the second metal conducting layer 122 is mutually opposed and possess certain interval, thus can be by pressing and unclamp the physical operations of first, second assembly, can produce the alternating current that possesses some strength, this alternating current is fed to the connected wireless signal transmission end of circuit with it as the signal source of controlling wireless signal transmission simultaneously, and corresponding triggering wireless signal transmission is brought in the firing operation of carrying out wireless signal thus.
As another functional unit in self-driven wireless signal transmitting device of the present utility model, the wireless signal transmission end is connected with signal source integral unit circuit with above-mentioned power supply, and specifically comprise connected voltage stabilizing chip, transmitting chip and the infrared LED transmitting tube of circuit each other according to a preferred implementation of the present utility model, wherein the voltage stabilizing chip will be for being converted to DC current signal from the ac current signal of described power supply and signal source integral unit, give voltage stabilizing simultaneously and process, for example can adopt the ASM1117-1.8 chip; Transmitting chip is modulated for the DC current signal to after conversion, for example can adopt the NAND gate chip of 74HC00N as core parts; The infrared LED transmitting tube is converted to light signal by the signal of telecommunication after modulation, outwards launches infrared signal simultaneously.
According to another preferred implementation of the present utility model, the material of described high molecular polymer insulating barrier is selected from PETG, polytetrafluoroethylene, polystyrene, polyimides, polyethylene, dimethyl silicone polymer, FEP fluorinated ethylene propylene copolymer, polytrifluorochloroethylene, polyvinylidene fluoride, ethylene tetrafluoroethylene copolymer or polymethyl methacrylate; The material of described the first metal conducting layer is selected from copper, aluminium or tin indium oxide, and the material of described the second metal conducting layer is selected from gold, silver, copper or aluminium.According to another preferred implementation of the present utility model, the lower surface of described high molecular polymer insulating barrier also is processed to form a plurality of micro-nano concaveconvex structures, and its average-size is 50 nanometers~200 nanometers.
Below select take the high molecular polymer insulating barrier as PETG material, the first metal conducting layer by copper form, flexible substrates is the papery material, the second metal conducting layer by aluminium form to process the flexible generating element obtained be example, will be after its single depression and the time dependent curve of electric current that produces of record.As shown in Fig. 2 a and 2b, the electric current peak width produced when single triggers flexible generating element is about 5 milliseconds, and the integration electric weight that this process produces is 4 microcoulombs, is enough to drive whole signal transmitting system.
Ground matches with above-mentioned wireless signal transmitting device, corresponding wireless signal receiver is also disclosed in the utility model, the power subsystem of this wireless signal receiver is the form of flexible generating element equally, and comprise the first assembly and the second assembly, wherein the first assembly consists of jointly high molecular polymer insulating barrier and the first metal conducting layer that is deposited on this high molecular polymer insulating barrier upper surface, and is formed with the first electrode at the edge of this first metal conducting layer; The second assembly consists of jointly flexible substrates and the second metal conducting layer that is deposited on this flexible substrates upper surface, and is formed with the second electrode at the edge of this second metal conducting layer; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier and described the second metal conducting layer is mutually opposed and possess certain interval, can produce the electric energy for the work of reception of wireless signals end by the operation of pressing and unclamp first, second assembly in this way.Similar in its concrete structure and Fig. 1, therefore do not repeat them here.
As another functional unit in self-driven wireless signal receiver of the present utility model, the reception of wireless signals end connects with above-mentioned power unit circuit, and specifically comprise according to a preferred implementation of the present utility model rectification unit, energy-storage units and the receiving chip that circuit connects each other, wherein rectification unit will be for being converted to direct current from the alternating current of described power subsystem; Energy-storage units is collected storage for the direct current that conversion is obtained; Receiving chip receives from the wireless signal of wireless signal transmission end and it is judged to processing for the electric energy that utilizes described energy-storage units to store.In this way, can pass through the simple operations of human body self, for example repeatedly press flexible generating element and can obtain the electric energy that is enough to drive signal receiving end work pre-stored standby in energy-storage units, but thus compact conformation, realize the self-driven process of reception of wireless signals with being convenient to control.
In sum, can be in the situation that do not rely on the self-driven function that battery-powered can realize wireless receiving and dispatching by self-driven wireless signal transceiver of the present utility model, in this device, power supply is also signal source simultaneously, realized the integration of power supply and signal source, corresponding and existing wireless transmitter is compared, overall structure is more simple compact, contributes to improve working life, and is applicable to all kinds of severe applied environments.In addition, this device is flexible can also being convenient to process by bending fold on the whole, in application, compares with the conventional apparatus of hard and has greater flexibility simultaneously; Finally, the energy that the flexible nano generator produces is larger, can effectively utilize the kinetic energy that human body produces, can produce in the short period of time the energy of enough driving transmitting terminals, possess stable performance, long working life, low cost simultaneously, be convenient to the characteristics such as processing and manufacturing in enormous quantities.
Those skilled in the art will readily understand; the foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all any modifications of doing within spirit of the present utility model and principle, be equal to and replace and improvement etc., within all should being included in protection range of the present utility model.

Claims (10)

1. a self-driven wireless signal transmitting device, this device comprises power supply and signal source integral unit and wireless signal transmission end, it is characterized in that:
Described power supply and signal source integral unit are the form of flexible generating element and comprise the first assembly and the second assembly, wherein the first assembly consists of jointly high molecular polymer insulating barrier and the first metal conducting layer that is deposited on this high molecular polymer insulating barrier upper surface, and is formed with the first electrode at the edge of this first metal conducting layer; The second assembly consists of jointly flexible substrates and the second metal conducting layer that is deposited on this flexible substrates upper surface, and is formed with the second electrode at the edge of this second metal conducting layer; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier and described the second metal conducting layer is mutually opposed and possess certain interval, can produce ac current signal by the operation of pressing and unclamp first, second assembly in this way, simultaneously using it as the signal source of controlling wireless signal transmission;
Described wireless signal transmission end is connected with signal source integral unit circuit with described power supply, for receiving the ac current signal from power supply and signal source integral unit, then carry out respective drive wireless signal transmission pipe according to this ac current signal, realize thus the firing operation of wireless signal.
2. self-driven wireless signal transmitting device as claimed in claim 1, it is characterized in that, the material of described high molecular polymer insulating barrier is selected from PETG, polytetrafluoroethylene, polystyrene, polyimides, polyethylene, dimethyl silicone polymer, FEP fluorinated ethylene propylene copolymer, polytrifluorochloroethylene, polyvinylidene fluoride, ethylene tetrafluoroethylene copolymer or polymethyl methacrylate; The material of described the first metal conducting layer is selected from copper, aluminium or tin indium oxide, and the material of described the second metal conducting layer is selected from gold, silver, copper or aluminium.
3. self-driven wireless signal transmitting device as claimed in claim 1 or 2, is characterized in that, the lower surface of described high molecular polymer insulating barrier also has been processed to form a plurality of concaveconvex structures, and the average-size of these concaveconvex structures is 50 nanometers~200 nanometers.
4. self-driven wireless signal transmitting device as claimed in claim 3, is characterized in that, described power supply and signal source integral unit consist of jointly single flexible generating element or a plurality of flexible generating element that is connected in parallel to each other.
5. self-driven wireless signal transmitting device as claimed in claim 4, it is characterized in that, described wireless signal transmission end comprises connected voltage stabilizing chip, transmitting chip and the infrared LED transmitting tube of circuit each other, wherein the voltage stabilizing chip, for being converted to DC current signal from the ac current signal of described power supply and signal source integral unit, giving voltage stabilizing simultaneously and processes; Transmitting chip is modulated for the DC current signal to after conversion; The infrared LED transmitting tube is converted to light signal by the signal of telecommunication after modulation, outwards launches infrared signal simultaneously.
6. self-driven wireless signal transmitting device as claimed in claim 5, is characterized in that, described self-driven wireless signal transmitting device integral body is the flexible structure of collapsible processing.
7. a self-driven wireless signal receiver, this device comprises power subsystem and reception of wireless signals end, it is characterized in that:
Described power subsystem is the form of flexible generating element and comprises the first assembly and the second assembly, wherein the first assembly consists of jointly high molecular polymer insulating barrier and the first metal conducting layer that is deposited on this high molecular polymer insulating barrier upper surface, and is formed with the first electrode at the edge of this first metal conducting layer; The second assembly consists of jointly flexible substrates and the second metal conducting layer that is deposited on this flexible substrates upper surface, and is formed with the second electrode at the edge of this second metal conducting layer; First, second assembly links at its outer ledge, and the upper surface of the lower surface of described high molecular polymer insulating barrier and described the second metal conducting layer is mutually opposed and possess certain interval, can produce the electric energy for the work of reception of wireless signals end by the operation of pressing and unclamp first, second assembly in this way;
Described reception of wireless signals end is connected with supporting wireless signal transmission end signal, and the electric energy that utilizes described power subsystem to provide receives from the wireless signal of wireless signal transmission end and it is judged to processing, realizes thus the reception of wireless signals process.
8. self-driven wireless signal receiver as claimed in claim 7, it is characterized in that, the material of described high molecular polymer insulating barrier is selected from PETG, polytetrafluoroethylene, polystyrene, polyimides, polyethylene, dimethyl silicone polymer, FEP fluorinated ethylene propylene copolymer, polytrifluorochloroethylene, polyvinylidene fluoride, ethylene tetrafluoroethylene copolymer or polymethyl methacrylate; The material of described the first metal conducting layer is selected from copper, aluminium or tin indium oxide, and the material of described the second metal conducting layer is selected from gold, silver, copper or aluminium.
9. self-driven wireless signal receiver as claimed in claim 7 or 8, it is characterized in that, described reception of wireless signals end comprises rectification unit, energy-storage units and the receiving chip that circuit connects each other, and wherein rectification unit will be for being converted to direct current from the alternating current of described power subsystem; Energy-storage units is collected storage for the direct current that conversion is obtained; Receiving chip receives from the wireless signal of wireless signal transmission end and it is judged to processing for the electric energy that utilizes described energy-storage units to store.
10. self-driven wireless signal receiver as claimed in claim 9, is characterized in that, described self-driven wireless signal receiver integral body is the flexible structure of collapsible processing.
CN2013204340107U 2013-07-19 2013-07-19 Self-driven wireless signal transmit-receive apparatus Expired - Lifetime CN203352580U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103441775A (en) * 2013-07-19 2013-12-11 华中科技大学 Self-driven wireless signal receiving-transmitting device

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103441775A (en) * 2013-07-19 2013-12-11 华中科技大学 Self-driven wireless signal receiving-transmitting device
WO2015007160A1 (en) * 2013-07-19 2015-01-22 华中科技大学 Self-driven wireless signal transmitting and receiving devices
CN103441775B (en) * 2013-07-19 2015-04-15 华中科技大学 Self-driven wireless signal receiving-transmitting device

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Granted publication date: 20131218