CN104656479A - Touching type command generation and self power supply controller - Google Patents

Abstract

The invention relates to the technical field of touching type controller, and discloses a touching type command generation and self power supply controller. The touching type command generation and self power supply controller comprises a panel, an induction electrode and a power generation structure, wherein the power generation structure comprises a coil, a magnet, an upper concentrating flux plate and a lower concentrating flux plate; the upper concentrating flux plate and the lower concentrating flux plate are respectively arranged at the upper end and the lower end of the magnet, and the coil is arranged on a magnet set in sleeving manner; a driving structure which is used for driving the coil to move up and down to enable the coil to cut a magnetic induction line is arranged below the panel, the driving end of the driving structure is connected with the coil, and the propping end of the driving structure is propped against the inner surface of the panel; a wire of the coil is electrically connected a shaping module for shaping current generated by the coil and a control module which is electrified to send a command. A user manually touches the part, corresponding to the induction electrode, on the panel, so that the effects of self power supply and command sending of the controller are realized. A battery is not needed to be used as a power supply, and the existence problem of the used battery is avoided. The using reliability of the controller is strong, the using cost of users is reduced, and the controller is environment-friendly.

Description

Touch and produce instruction and self-powered controller

Technical field

The present invention relates to the technical field of touch-type controller, particularly relate to and touch generation instruction and self-powered controller.

Background technology

Electronic product is widely used in life, and low power dissipation electron product can use battery as the power supply of work usually, as touch controller, telepilot etc.Use battery to have limitation as power supply, it is limited to there is serviceable life in it, and needs repeat buying battery and the problem that uses of periodic replacement battery, and these problems can the use cost of remarkable adding users; In addition, because battery easily gets rusty and leakage, like this, for the electronic product of some security protection effects, use battery greatly can reduce the reliability of electronic product, and the round-the-clock needs that the energy is provided for a long time cannot be met, when meeting with illegal invasion, electronic product is inoperative because of battery failure possibly, brings loss to user.

In addition, battery great majority are disposable products, and its life cycle is shorter, as needed Long-Time Service, then constantly must buy battery, the financial burden of adding users; Moreover manufacturing battery not only needs consumption of natural resource, and a large amount of old and useless batterys is dropped, and can bring adverse influence, not environmentally to environment.

Summary of the invention

The object of the present invention is to provide to touch and produce instruction and self-powered controller, be intended to solve in prior art, the electronic products such as touch controller adopt battery as power supply, there is dependability difference, adding users use cost and problem not environmentally.

The present invention is achieved in that to touch and produces instruction and self-powered controller, comprises panel, induction electrode and electrification structure; Described induction electrode is located at the inside surface of described panel; Described electrification structure comprises coil and group of magnets, and described group of magnets comprises magnet, upper conduction magnetic board and lower magnetic conductive board, and described upper conduction magnetic board is located at the upper end of described magnet, and described lower magnetic conductive board is arranged on the lower end of magnet; Described coil is set in described group of magnets; The below of described panel is provided with the drives structure making coil cutting magnetic induction line for driving described coil to move up and down, the drive end that described drives structure has abutment end and is connected with described coil, the abutment end of described drives structure is connected to the inside surface of described panel; The electric wire electric current be electrically connected with for producing described coil of described coil carries out the Shaping Module of shaping and the control module of energising transmission instruction.

Further, described drives structure comprises lever and linkage structure, the middle part hinge arrangement of described lever, and the front end of described lever forms described abutment end, described linkage structure is connected with described coil, and the rear end of described lever is moved up and down by described linkage structure drive coil.

Further, the middle part of described lever has the pin joint of hinge arrangement, and described lever is bending, and the bending place of described lever forms described pin joint.

Further, described touch produces instruction and self-powered controller and includes accelerating structure for driving described linkage structure to accelerate movement, between the rear end that described accelerating structure is connected to described lever and linkage structure.

Further, described accelerating structure comprises the flexure strip of stress deformation, magnetic inductive block and two magnet pieces, the middle part hinge arrangement of described flexure strip, the front end of described flexure strip is connected to the rear end of described lever, the rear end of described flexure strip is connected to described magnetic inductive block, two described magnet pieces are positioned opposite separately, and described magnetic inductive block is placed between two magnet pieces, and is pulled on one of them magnet piece.

Further, the middle part of described flexure strip is formed with fulcrum, the fulcrum fixed and arranged of described flexure strip, and the position of the fulcrum of described flexure strip is higher than the centre position of two described magnet pieces.

Further, described touch produces instruction and self-powered controller comprises back-moving spring, the lower end fixed and arranged of described back-moving spring, and the upper end of described back-moving spring extends layout upward, is connected to the abutment end of described lever.

Further, described linkage structure comprises linkage support, and one end of described linkage support is connected with coil, forms described drive end, and the other end of described linkage support extends outwardly layout.

Further, one end of described linkage support has extended outwardly two clamping strips, and two described clamping strips are arranged separately, form the clamping interval for clamping described coil between the two.

Further, the inside surface of described panel is provided with multiple induction electrode; Described control module is electrically connected with Multi-way touch signals collecting module, and this Multi-way touch signals collecting module is electrically connected at multiple described induction electrode respectively, there is in described Multi-way touch signals collecting module oscillator and send the coding corresponding with each described induction electrode to the logic controller of control module according to the oscillation frequency change of described oscillator.

Further, described touch produces instruction and self-powered controller includes two described drives structure, and two described drives structure are arranged symmetrically in the both sides of described electrification structure.

Further, the periphery of described lower magnetic conductive board extends to outside described magnet, and the periphery of described lower magnetic conductive board is convexly equipped with the peripheral board extended upward, is formed with magnetic gap between described peripheral board and described upper conduction magnetic board, and described coil is plugged in described magnetic gap.

Further, the upper surface of described peripheral board is at least higher than the upper surface of described upper conduction magnetic board.

Controller provided by the invention, the position that user is manually corresponding to induction electrode on touch panel, meanwhile, utilizes drives structure to drive the coil cutting magnetic induction line of electrification structure, electric wire generation current in coil, this electric current, by the shaping of Shaping Module, for control module is powered, realizes touching self-powered effect, and control module power and in running order after, then correspondence outwards can send instruction, drive outside corresponding electric equipment action, realize touching the effect producing instruction; Touching to produce in instruction and self-powered controller does not need to adopt battery etc. as power supply, the series of problems using battery to exist can be avoided, make the dependability of controller strong, greatly reduce customer using cost, and can not impact environment etc., use comparatively environmental protection; Moreover the controller of touch manner, for traditional silica gel keyboard, mechanical switch keyboard, it has longer serviceable life, and can also arrange more instruction button in area large equally, result of use is better

Accompanying drawing explanation

Fig. 1 is that the touch that the embodiment of the present invention provides produces instruction and self-powered controller principle structural representation;

Fig. 2 is the drives structure that provides of the embodiment of the present invention and electrification structure theory structure schematic diagram in a state of nature;

Fig. 3 is the theory structure schematic diagram that the drives structure that provides of the embodiment of the present invention and electrification structure are in operating state;

Fig. 4 is the theory structure schematic diagram after the drives structure that provides of the embodiment of the present invention and electrification structure are in action;

Fig. 5 is the schematic front view that the touch that provides of the embodiment of the present invention produces instruction and self-powered controller;

Fig. 6 is the schematic front view of the accelerating structure that the embodiment of the present invention provides;

Fig. 7 is the elevational schematic view that the touch that provides of the embodiment of the present invention produces that instruction and self-powered controller have multiple induction electrode;

Fig. 8 is that the master of the electrification structure that the embodiment of the present invention provides looks exploded perspective view;

Fig. 9 is the schematic front view that coil that the embodiment of the present invention provides is in above group of magnets;

Figure 10 be shown in Fig. 8 in coil mobile down after schematic front view;

Figure 11 is the schematic top plan view of the linkage structure that provides of the embodiment of the present invention and fitting coils.

Embodiment

In order to make object of the present invention, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the present invention is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the present invention, be not intended to limit the present invention.

Below in conjunction with specific embodiment, realization of the present invention is described in detail.

As shown in Fig. 1 ~ 11, it is preferred embodiment provided by the invention.

With reference to shown in Fig. 1 ~ 11, the touch that the present embodiment provides produces instruction and self-powered controller, it may be used for controlling various electric equipment, can be controlled by various wireless mode, can also be used in combination with Smart Home product receiving terminal, and user is in the process of touch controller, controller can produce electric energy, realizes self-powered effect.

The touch that the present embodiment provides produces instruction and self-powered controller, comprises panel 100, induction electrode 101, drives structure and electrification structure 103.Wherein, the shape of panel 100 can be diversified, as tabular, or arc tabular etc., specifically actual design can need and determine; Induction electrode 101 is sticked on the inside surface of panel 100.

Electrification structure 103 comprises coil and group of magnets, wherein, group of magnets comprises magnet 1033, upper conduction magnetic board 1036 and lower magnetic conductive board 1034, upper conduction magnetic board 1036 is arranged on the upper surface of magnet 1033, lower magnetic conductive board 1034 is arranged on the lower surface of magnet 1033, like this, because the two ends magnetic of magnet 1033 is different, and on the upper surface being separately positioned on magnet 1033 due to upper conduction magnetic board 1036 and lower magnetic conductive board 1034 and lower surface, thus, between the periphery of upper conduction magnetic board 1036 and the periphery of lower magnetic conductive board 1034, then produce magnetic induction line.

Coil comprises coil former 1031 and is wrapped in the electric wire 1032 of this coil former 1031 periphery, be provided with in this coil former 1031 and extend layout and the position, hole of lower ending opening along coil former 1031 short transverse, and the lower ending opening of group of magnets passing hole position is plugged in the Kong Weizhong of this coil former 1031, like this, when coil extended height direction moves up and down, 1032, the electric wire of coil former 1031 periphery can produce the magnetic induction line between upper conduction magnetic board 1036 periphery and lower magnetic conductive board 1034 periphery and cut, magnetic induction line namely in the magnetic gap that forms of upper conduction magnetic board 1036 and lower magnetic conductive board 1034 cuts, and in cutting process, then can generation current in the electric wire 1032 of coil.

Drives structure is arranged on the below of panel 100, it has abutment end 1021 and drive end, this abutment end 1021 is arranged on the below of panel 100, and be connected on the inside surface of panel 100, the drive end of drives structure is connected with the coil of electrification structure 103, like this, when position corresponding with induction electrode 101 on user's touch panel 100, and press panel 100 down, the drive end that be bear against drives structure by the inside surface of panel 100 is moved down, the drive end of drives structure then moves down or moves upward simultaneously, certainly, drive end moves down or moves upward, determined by the concrete setting of drives structure, now, because the drive end of drives structure is connected with coil, under the driving effect of drive end, coil then opposed magnet group can move or moves upward down, coil then produces cutting movement to the magnetic induction line between upper conduction magnetic board 1036 and lower magnetic conductive board 1034, and then, the two ends of electric wire 1032 then output current in coil.

In the present embodiment, the electric wire 1032 of coil is electrically connected with Shaping Module 106 and control module 107, generation current in the electric wire 1032 of coil, the electric current produced is by the shaping of Shaping Module 106, can be implemented as control module 107 to power, and then control module 107 is initially located in duty, and according to the program etc. of its inner setting, sends wireless instructions and drive outside electric equipment work.

In actual use, electric wire 1032 two ends of coil produce the pulse that magnitude of voltage is higher, the time is shorter, voltage peak, at more than 10V, is held time and is only 1.5mS, like this, by the shaping of Shaping Module 106, be square wave by shaping pulse, voltage is 2V, and the duration is greater than 6mS, thus be embodied as control module 107 and other circuit component is powered, make control module 107 and other circuit component in running order.

The present embodiment, control module 107 wirelessly drives outside electric equipment work, RF communication element is provided with in this control module 107, the instruction that control module 107 sends, sent by this RF communication element, be provided with corresponding terminal receiver in outside electric equipment, terminal receiver is according to the instruction receiving RF communication element and send, and correspondence performs an action.Wireless telecommunications between the terminal receiver of RF communication element and outside electric equipment can be proprietary protocols, also can be open protocol, such as ZigBee, Z-WAVE etc.

Or, as other embodiment, also can be electrically connected by wired mode between control module 107 and outside electric equipment, thus instruction is sent in the terminal receiver of outside electric equipment by wired mode by control module 107, electric equipment then correspondence performs an action.

The above-mentioned controller provided, user manually touches and presses the position to induction electrode 101 correspondence on panel 100, drives structure is utilized to drive the coil cutting magnetic induction line of electrification structure 103, thus electric wire 1032 generation current in coil, this electric current is by the shaping of Shaping Module 106, can power for control module 107, realize touching self-powered effect, and control module 107 power and in running order after, then correspondence outwards can send instruction, drive outside corresponding electric equipment action, realize touching the effect producing steering order.

Produce in instruction and self-powered controller in above-mentioned touch, it does not need to adopt battery etc. as power supply, the series of problems using battery to exist can be avoided, make the dependability of controller strong, greatly reduce customer using cost, and can not impact environment etc., use comparatively environmental protection; Moreover the controller of touch manner, for traditional silica gel keyboard, mechanical switch keyboard, it has longer serviceable life.

In the present embodiment, drives structure comprises lever 102 and linkage structure 105, the middle part hinge arrangement of this lever 102, and the middle part of lever 102 forms pin joint, be connected with hinged seat by pin joint, thus make the front end of lever 102 and rear end relative to the upper and lower tilting of pin joint.

The front end of lever 102 forms above-mentioned abutment end 1021, it is in the below of panel 100, and be connected on the inside surface of panel 100, there is in linkage structure 105 drive end be connected with coil, and the rear end of lever 102 is moved up and down by linkage structure 105 drive coil, thus touched by user and by position corresponding with induction electrode 101 on lower panel 100, realize the collection of the generating of coil cutting magnetic induction line and the instruction of finger induced signal.

Particularly, the front end of lever 102 is that spherical shape or triangular shape are arranged, namely, abutment end 1021 is that spherical shape or triangular shape are arranged, like this, when abutment end 1021 is compressed by the inside surface of panel 100, reduces friction force as far as possible.

Lever 102 is in bending, and its bending place forms above-mentioned pin joint, the namely bending place hinge arrangement of lever 102, like this, take pin joint as boundary, and the two ends bending of lever 102 is arranged, is convenient to the layout that lever 102 two ends move up and down.

In the present embodiment, accelerating structure 104 is provided with between the rear end of lever 102 and linkage structure 105, this accelerating structure 104 is connected with the rear end of lever 102 and linkage structure 105 respectively, it moves for driving the acceleration of linkage structure 105, thus realize drive coil accelerate move up and down, fly-cutting magnetic induction line.

Particularly, accelerating structure 104 comprises flexure strip 1043 and the magnetic inductive block 1042 of stress deformation, the middle part hinge arrangement of flexure strip 1043, its front end is connected to the rear end of lever 102, its rear end is connected with magnetic inductive block 1042, and magnetic inductive block 1042 is connected with linkage structure 105, above magnetic inductive block 1042 and below be respectively equipped with magnet piece 1041, these two magnet pieces 1041 are positioned opposite separately, form interval region between the two, magnetic inductive block 1042 is arranged in this interval region, and magnetic inductive block 1042 and wherein magnet piece 1041 adhesive.

The operating process of the above-mentioned drives structure provided is as follows:

As shown in Figure 2, in an initial condition, magnetic inductive block 1042 is pull-in on N pole magnet piece 1041, and now, coil is in the extreme position above group of magnets;

As shown in Figure 3, now, position corresponding with induction electrode 101 on user's finger touch panel 100, and finger continues to press downwards, under the compressing of panel 100, the abutment end 1021 of lever 102 moves down, lever 102 is around pin joint tilting, now, the rear end of lever 102 is moved upward, and, the rear end of lever 102 drives flexure strip 1043 to be out of shape, there is deformation in flexure strip 1043, but because magnetic inductive block 1042 is held by N pole magnet piece 1041, therefore, when the deforming force of flexure strip 1043 does not reach enough large acting force, magnetic inductive block 1042 can't move down, along with finger continues down to press panel 100, the deforming force of flexure strip 1043 is increasing, until when this deforming force is greater than the suction-combining force between magnetic inductive block 1042 and N pole magnet piece 1041, with reference to shown in Fig. 4, under the effect of flexure strip 1043, magnetic inductive block 1042 can accelerate to move down, and held by S pole magnet piece 1041, because linkage structure 105 is connected with magnetic inductive block 1042, thus the drive end of linkage structure 105 then drive coil high-speed mobile down, coil is high-speed cutting magnetic induction line then, thus, at the two ends output current of coil wire 1032.

Flexure strip 1043 in bending, fulcrum is formed in the middle part of it, this fulcrum and pillar are articulated and connected, make the middle part hinge arrangement of flexure strip 1043, like this, when flexure strip 1043 is in driven process, flexure strip 1043 tilting is out of shape, in order to realize after applying the distress resolves down pressed on panel 100, flexure strip 1043 can restPose automatically.

In the present embodiment, drives structure also includes back-moving spring 113, the lower end fixed and arranged of this back-moving spring 113, and the upper end of back-moving spring 113 is connected to the abutment end 1021 of drives structure, the namely front end of lever 102.Like this, when panel 100 is down behind the front end of lever 102, back-moving spring 113 is by compression deformation, after the distress resolves of the panel 100 applied, under the effect recovering spring 113 restoring force, the front end of lever 102 then swings upward, recover virgin state, certainly, in the process that the front end of lever 102 moves up and down, accelerating structure 104 and linkage structure 105 etc. are also along with corresponding action.

Or, the position of the fulcrum of flexure strip 1043, higher than the middle part of two magnet pieces 1041, like this, after magnetic inductive block 1042 is by magnet piece 1041 adhesive of S pole, the deformation power of flexure strip 1043 is greater than the suction-combining force between magnetic inductive block 1042 and S pole magnet piece 1041, thus, after applying the distress resolves down pressed on panel 100, flexure strip 1043 reinstatement, namely magnetic inductive block 1042 moves upward, be pull-in on N pole magnet piece 1041, thus, when needing again to control outside electric equipment, user then again touches and down presses position corresponding with induction electrode 101 on panel 100, repeat the above-mentioned operation mentioned.

In the present embodiment, linkage structure 105 comprises linkage support 107, one end of linkage support 107 forms above-mentioned drive end, this drive end is fixedly connected with coil, the other end of linkage support 107 extends outwardly layout, the other end of linkage support 107 is connected with magnetic inductive block 1042, like this, when magnetic inductive block 1042 moves up and down between two magnet 1033 are fast, magnetic inductive block 1042 drives linkage support 107 to move up and down, and then utilize linkage support 107 drive coil to move up and down, realize the effect of coil cutting magnetic induction line.

One end for the ease of linkage support 107 is fixedly connected with coil, the present embodiment, one end of linkage support 107 has extended outwardly two clamping strips 1071, and the alternate layout of this two clamping strip 1071, forms the clamping interval for clamping coil former 1031 between the two, like this, utilize these two clamping strips 1071 to be clamped in the periphery of coil, then one end of linkage support 107 can be made to be fixedly connected with coil, and, utilize the elastic deformability of clamping strip 1071, can greatly increase its holding force.

Clamping strip 1071 arc shape in outer gibbosity, like this, the clamping gap-forming approximate circle shape between two clamping strips 1071, is convenient to coordinating of this clamping interval and coil periphery.In the present embodiment, two clamping strips 1071 of linkage support 107 define above-mentioned drive end.

Certainly, as other embodiment, one end of linkage support 107 also can adopt other various structures and fitting coils, be welded to connect, or alternate manner can as adopted.

As further optimum choice, linkage support 107 is the elasticity linkage support 107 of arranging in bending, like this, when magnetic inductive block 1042 is when driving linkage support 107, linkage support 107 deforms, thus make linkage support 107 faster drive coil move up and down.Certainly, can variation for arranging of linkage support 107, as spring-piece type, or other can the structure with elastic deformation etc.

In the group of magnets that the present embodiment provides, the periphery of lower magnetic conductive board 1034 extends to outside magnet 1033, and the periphery of lower magnetic conductive board 1034 is convexly equipped with peripheral board 1035, this peripheral board 1035 is put towards projection extension cloth, be formed in the periphery of magnet 1033 and upper conduction magnetic board 1036, that is, lower magnetic conductive board 1034 forms caviton shape, like this, then magnetic gap is formed between peripheral board 1035 and magnet 1033; After magnet 1033 and upper conduction magnetic board 1036 are located in the Kong Weizhong of coil former 1031, coil then plugs in above-mentioned magnetic gap, and can move up and down in this magnetic gap.

Like this, due to the setting of peripheral board 1035, make the magnetic induction line coverage between upper conduction magnetic board 1036 and lower magnetic conductive board 1034 wider, and the intensity of magnetic induction line is larger, increase coil in the process moved up and down, the density of magnetic induction line between cutting upper conduction magnetic board 1036 and lower magnetic conductive board 1034, also greatly in intensifier coil cutting magnetic induction line process, the strength of current of generation.

Particularly, all rounded shape of profile of upper conduction magnetic board 1036, magnet 1033, lower magnetic conductive board 1034 and peripheral board 1035, certainly, concrete structure is arranged to be determined by actual needs.

In the present embodiment, the upper end of peripheral board 1035 and the upper end flush arrangement of upper conduction magnetic board 1036, namely both contour layouts; Or according to actual needs, the upper surface of peripheral board 1035 also can higher than the upper surface of upper conduction magnetic board 1036.That is, the upper surface of peripheral board 1035 is not less than the upper surface of upper conduction magnetic board 1036 as far as possible.

In addition, the Kong Weiwei through hole of coil former 1031, the upper end of its thorough coil frame 1031 and lower end, like this, be convenient to the scope that coil moves up and down.Further, Kong Weiwei circular port, like this, accordingly, magnet 1033 and upper conduction magnetic board 1036 also circular shape are arranged; Or as other embodiment, Kong Wei, upper conduction magnetic board 1036 and magnet 1033 can be also other arrangements, as square shape etc.

Touch that the present embodiment provides produces instruction and self-powered controller, and it can singly-bound touch manner, is exactly only arrange single induction electrode 101, or multikey touch manner, arranges the induction electrode 101 of multiple difference in functionality exactly.

For the controller realizing multikey touch manner, controller includes multiple induction electrode 101 being arranged on panel 100 inside surface, now, the below of panel 100 then correspondence is provided with two drives structure, and these two drives structure are arranged symmetrically in the both sides of electrification structure 103; Or, also can separately or a drives structure, specifically be determined by actual needs.

In the present embodiment, touch produces instruction and self-powered controller includes Multi-way touch signals collecting module 108, this Multi-way touch signals collecting module 108 is electrically connected at control module 107 and multiple induction electrode 101, has oscillator and logic controller in this Multi-way touch signals collecting module 108.

Like this, when drives structure drive coil moves up and down, electric wire 1032 output current in coil, electric current is by after the shaping of Shaping Module 106, power to control module 107 and Multi-way touch signals collecting module 108, and, control module 107 and Multi-way touch signals collecting module 108 be in just start working state time, the finger of user still stops on position corresponding with induction electrode 101 on panel 100, therefore, the electric capacity of nearly 5pF is formed between finger and induction electrode 101, be subject to the impact of this electric capacity, the oscillation frequency of the oscillator in Multi-way touch signals collecting module 108 then can change, the frequency change of oscillator, logic controller is caused to export corresponding coding, and then, the coding that logic controller exports is sent in control module 107, and have different codings due to each induction electrode 101, like this, control module 107 is according to the coding received, then may be used for distinguishing different induction electrodes 101, and utilize that RF communication element is wireless sends instruction, or controller sends instruction by wired mode, control outside corresponding electric equipment action.

In the present embodiment, touch produces instruction and self-powered controller also comprises base plate 106, and this base plate 106 coordinates with face-piece, and encloses formation spatial accommodation between base plate 106 and face-piece, and above-mentioned electrification structure 103, drives structure etc. are placed in this spatial accommodation.Certainly, the vibrational power flow of base plate 106 can be variation, is specifically determined by actual needs.

The foregoing is only preferred embodiment of the present invention, not in order to limit the present invention, all any amendments done within the spirit and principles in the present invention, equivalent replacement and improvement etc., all should be included within protection scope of the present invention.

Claims (13)

1. touch and produce instruction and self-powered controller, it is characterized in that, comprise panel, induction electrode and electrification structure; Described induction electrode is located at the inside surface of described panel; Described electrification structure comprises coil and group of magnets, and described group of magnets comprises magnet, upper conduction magnetic board and lower magnetic conductive board, and described upper conduction magnetic board is located at the upper end of described magnet, and described lower magnetic conductive board is arranged on the lower end of magnet; Described coil is set in described group of magnets; The below of described panel is provided with the drives structure making coil cutting magnetic induction line for driving described coil to move up and down, the drive end that described drives structure has abutment end and is connected with described coil, the abutment end of described drives structure is connected to the inside surface of described panel; The electric wire electric current be electrically connected with for producing described coil of described coil carries out the Shaping Module of shaping and the control module of energising transmission instruction.

2. as claimed in claim 1 touch produces instruction and self-powered controller, it is characterized in that, described drives structure comprises lever and linkage structure, the middle part hinge arrangement of described lever, the front end of described lever forms described abutment end, described linkage structure is connected with described coil, and the rear end of described lever is moved up and down by described linkage structure drive coil.

3. as claimed in claim 2 touch produces instruction and self-powered controller, and it is characterized in that, the middle part of described lever has the pin joint of hinge arrangement, and described lever is bending, and the bending place of described lever forms described pin joint.

4. touch as claimed in claim 2 or claim 3 and produce instruction and self-powered controller, it is characterized in that, described touch produces instruction and self-powered controller and includes accelerating structure for driving described linkage structure to accelerate movement, between the rear end that described accelerating structure is connected to described lever and linkage structure.

5. as claimed in claim 4 touch produces instruction and self-powered controller, it is characterized in that, described accelerating structure comprises the flexure strip of stress deformation, magnetic inductive block and two magnet pieces, the middle part hinge arrangement of described flexure strip, the front end of described flexure strip is connected to the rear end of described lever, and the rear end of described flexure strip is connected to described magnetic inductive block, and two described magnet pieces are positioned opposite separately, described magnetic inductive block is placed between two magnet pieces, and is pulled on one of them magnet piece.

6. as claimed in claim 5 touch produces instruction and self-powered controller, it is characterized in that, the middle part of described flexure strip is formed with fulcrum, the fulcrum fixed and arranged of described flexure strip, and the position of the fulcrum of described flexure strip is higher than the centre position of two described magnet pieces.

7. touch as claimed in claim 2 or claim 3 and produce instruction and self-powered controller, it is characterized in that, described touch produces instruction and self-powered controller comprises back-moving spring, the lower end fixed and arranged of described back-moving spring, the upper end of described back-moving spring extends layout upward, is connected to the abutment end of described lever.

8. touch as claimed in claim 2 or claim 3 and produce instruction and self-powered controller, it is characterized in that, described linkage structure comprises linkage support, and one end of described linkage support is connected with coil, form described drive end, the other end of described linkage support extends outwardly layout.

9. as claimed in claim 7 touch produces instruction and self-powered controller, it is characterized in that, one end of described linkage support has extended outwardly two clamping strips, and two described clamping strips are arranged separately, form the clamping interval for clamping described coil between the two.

10. the touch as described in claim 1 or 2 or 3 produces instruction and self-powered controller, and it is characterized in that, the inside surface of described panel is provided with multiple induction electrode; Described control module is electrically connected with Multi-way touch signals collecting module, and this Multi-way touch signals collecting module is electrically connected at multiple described induction electrode respectively, there is in described Multi-way touch signals collecting module oscillator and send the coding corresponding with each described induction electrode to the logic controller of control module according to the oscillation frequency change of described oscillator.

11. touch generation instruction and self-powered controller as claimed in claim 10, it is characterized in that, described touch produces instruction and self-powered controller includes two described drives structure, and two described drives structure are arranged symmetrically in the both sides of described electrification structure.

12. touches as described in claim 1 or 2 or 3 produce instruction and self-powered controller, it is characterized in that, the periphery of described lower magnetic conductive board extends to outside described magnet, and the periphery of described lower magnetic conductive board is convexly equipped with the peripheral board extended upward, be formed with magnetic gap between described peripheral board and described upper conduction magnetic board, described coil is plugged in described magnetic gap.

13. touch generation instruction and self-powered controller as claimed in claim 12, and it is characterized in that, the upper surface of described peripheral board is at least higher than the upper surface of described upper conduction magnetic board.