CN104656479B - Touch and produce instruction and self-powered controller - Google Patents
Touch and produce instruction and self-powered controller Download PDFInfo
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- CN104656479B CN104656479B CN201410856037.4A CN201410856037A CN104656479B CN 104656479 B CN104656479 B CN 104656479B CN 201410856037 A CN201410856037 A CN 201410856037A CN 104656479 B CN104656479 B CN 104656479B
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/04—Programme control other than numerical control, i.e. in sequence controllers or logic controllers
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0487—Interaction techniques based on graphical user interfaces [GUI] using specific features provided by the input device, e.g. functions controlled by the rotation of a mouse with dual sensing arrangements, or of the nature of the input device, e.g. tap gestures based on pressure sensed by a digitiser
- G06F3/0488—Interaction techniques based on graphical user interfaces [GUI] using specific features provided by the input device, e.g. functions controlled by the rotation of a mouse with dual sensing arrangements, or of the nature of the input device, e.g. tap gestures based on pressure sensed by a digitiser using a touch-screen or digitiser, e.g. input of commands through traced gestures
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0484—Interaction techniques based on graphical user interfaces [GUI] for the control of specific functions or operations, e.g. selecting or manipulating an object, an image or a displayed text element, setting a parameter value or selecting a range
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K35/00—Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit
- H02K35/04—Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit with moving coil systems and stationary magnets
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- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Theoretical Computer Science (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Human Computer Interaction (AREA)
- Power Engineering (AREA)
- Automation & Control Theory (AREA)
- Position Input By Displaying (AREA)
- Toys (AREA)
Abstract
The present invention relates to the technical field of touch controller, disclose touch and produce instruction and self-powered controller, including panel, induction electrode and electrification structure;Electrification structure includes coil, magnet, upper conduction magnetic board and lower magnetic conductive board, and upper conduction magnetic board and lower magnetic conductive board are respectively arranged on the upper end and lower end of magnet, and coil is set in group of magnets;The lower section of panel for driving coil provided with being moved up and down so that the driving structure of coil cutting magnetic induction line, the drive end of driving structure is connected with coil, and the abutment end of driving structure is connected on the inner surface of panel;The electric wire of coil, which is electrically connected with, to carry out the Shaping Module of shaping to the electric current that coil is produced and is powered to send the control module of instruction.By, to the corresponding position of induction electrode, realizing controller self-powered on user's manual palpation panel and sending the effect of instruction, it is not necessary to be used as power supply using battery etc., the problem of avoiding existing using battery, the use of controller is highly reliable, reduces customer using cost, uses environmental protection.
Description
Technical field
The present invention relates to the technical field of touch controller, more particularly to touch generation instruction and self-powered control
Device.
Background technology
Electronic product is widely used in life, and low power dissipation electron product would generally use battery as the electricity of work
Source, such as touch controller, remote control.There is limitation using battery as power supply, it is limited that it has service life, and
Need repeat buying battery and the problem of periodic replacement battery is used, these problems can dramatically increase the use cost of user;Separately
Outside, so, can be significantly using battery for the electronic product that some security protections are acted on because battery easily gets rusty and leakage
Reduce electronic product reliability, and can not meet it is round-the-clock it is permanent offer the energy the need for, when meet with illegal invasion when, electronics
Product is likely to not work because of battery failure, and loss is brought to user.
In addition, most of battery is disposable product, its usage cycles is shorter, such as needs to be used for a long time, then must constantly purchase
Battery is bought, increases the financial burden of user;Furthermore, manufacture battery not only needs to consume resource, and substantial amounts of old and useless battery quilt
Abandon, detrimental effect can be brought to environment, not environmentally.
The content of the invention
It is an object of the invention to provide touch to produce instruction and self-powered controller, it is intended to solves in the prior art,
The electronic products such as touch controller, as power supply, are existed using poor reliability, increase customer using cost and not using battery
Environmentally friendly the problem of.
The present invention be achieved in that touch produce instruction and self-powered controller, including panel, induction electrode and
Electrification structure;The induction electrode is located at the inner surface of the panel;The electrification structure includes coil and group of magnets, the magnetic
Iron group includes magnet, upper conduction magnetic board and lower magnetic conductive board, and the upper conduction magnetic board is located at the upper end of the magnet, the lower magnetic conductive board
It is arranged on the lower end of magnet;The coil is set in the group of magnets;The lower section of the panel, which is provided with, to be used to drive the line
Circle is moved up and down so that the driving structure of coil cutting magnetic induction line, the driving structure has abutment end and connected with the coil
The drive end connect, the abutment end of the driving structure is connected to the inner surface of the panel;The electric wire of the coil is electrically connected with
There is the electric current for being produced to the coil to carry out the Shaping Module of shaping and be powered to send the control module of instruction.
Further, the driving structure includes lever and linkage structure, and the middle part hinge arrangement of the lever is described
The front end of lever forms the abutment end, and the linkage structure is connected with the coil, and the lever rear end pass through it is described
Linkage structure driving coil is moved up and down.
Further, the middle part of the lever has a pin joint of hinge arrangement, and the lever is in bending, and the thick stick
The bending place of bar forms the pin joint.
Further, the touch produces instruction and self-powered controller includes for driving the linkage structure to add
The mobile accelerating structure of speed, the accelerating structure is connected between the rear end of the lever and linkage structure.
Further, the accelerating structure includes flexure strip, magnetic inductive block and two magnet pieces of stress deformation, the bullet
Property piece middle part hinge arrangement, the front end of the flexure strip is connected to the rear end of the lever, the rear end connection of the flexure strip
In the magnetic inductive block, two magnet pieces are separately positioned opposite, and the magnetic inductive block is placed between two magnet pieces, and adhesive
In one of magnet piece.
Further, fulcrum, the fixed pivot arrangement of the flexure strip, and the bullet are formed with the middle part of the flexure strip
Property piece fulcrum centre position of the position higher than two magnet pieces.
Further, the touch, which produces instruction and self-powered controller, includes back-moving spring, the back-moving spring
Lower end fixed and arranged, the upper end of the back-moving spring is disposed to extend upward, is connected to the abutment end of the lever.
Further, the linkage structure includes linkage support, and one end of the linkage support is connected with coil, forms institute
State drive end, the other end of the linkage support extends outwardly arrangement.
Further, one end of the linkage support, which extends outwardly, two clamping strips, and two clamping strips are separately
Arrangement, forms the clamping interval for clamping the coil between the two.
Further, the inner surface of the panel is provided with multiple induction electrodes;The control module is electrically connected with multichannel
Touch signal gathers module, and the Multi-way touch signal acquisition module is electrically connected at multiple induction electrodes respectively, described
In Multi-way touch signal acquisition module have oscillator and according to the frequency of oscillation of the oscillator change send with it is each described
The corresponding logic controller encoded to control module of induction electrode.
Further, the touch produces instruction and self-powered controller includes two driving structures, two
The driving structure is arranged symmetrically in the both sides of the electrification structure.
Further, the periphery of the lower magnetic conductive board is extended to outside the magnet, and the periphery projection of the lower magnetic conductive board
There is the peripheral board extended upward, magnetic gap is formed between the peripheral board and the upper conduction magnetic board, the coil is plugged in described
In magnetic gap.
Further, the upper surface of the peripheral board is at least above the upper surface of the upper conduction magnetic board.
The controller that the present invention is provided, user by manual palpation panel to the corresponding position of induction electrode, meanwhile, profit
The electric wire in the coil cutting magnetic induction line of electrification structure, coil is driven to produce electric current with driving structure, the electric current passes through sizing die
The shaping of block, is that control module is powered, and realizes and touches self-powered effect, and control module power and it is in running order after,
It can then correspond to and send out instruction, the effect for touching and producing instruction is realized in the outside corresponding electric equipment action of driving;Touch
Produce in instruction and self-powered controller need not using battery etc. as power supply, can avoid existed using battery one be
Row problem so that the use of controller is highly reliable, substantially reduces customer using cost, and environment etc. will not be impacted,
Using more environmentally friendly;Furthermore, the controller of touch manner, for traditional silica gel keyboard, mechanical switch keyboard, it has
There is longer service life, arrangement can also more instruct buttons in same big area, using effect is more preferable
Brief description of the drawings
Fig. 1 is that provided in an embodiment of the present invention touch produces instruction and self-powered controller principle structural representation;
Fig. 2 is that the theory structure of driving structure provided in an embodiment of the present invention with electrification structure in a state of nature is illustrated
Figure;
Fig. 3 is that the theory structure that driving structure provided in an embodiment of the present invention is in operating state with electrification structure is illustrated
Figure;
Fig. 4 is that driving structure provided in an embodiment of the present invention is in the theory structure schematic diagram after action with electrification structure;
Fig. 5 is the schematic front view provided in an embodiment of the present invention for touching and producing instruction and self-powered controller;
Fig. 6 is the schematic front view of accelerating structure provided in an embodiment of the present invention;
Fig. 7 is that touch generation instruction provided in an embodiment of the present invention and self-powered controller have multiple induction electrodes
Elevational schematic view;
Fig. 8 is the main view exploded perspective view of electrification structure provided in an embodiment of the present invention;
Fig. 9 is the schematic front view that coil provided in an embodiment of the present invention is in above group of magnets;
Figure 10 be shown in Fig. 8 in coil move down after schematic front view;
Figure 11 is the schematic top plan view of linkage structure provided in an embodiment of the present invention and fitting coils.
Embodiment
In order to make the purpose , technical scheme and advantage of the present invention be clearer, it is right below in conjunction with drawings and Examples
The present invention is further elaborated.It should be appreciated that the specific embodiments described herein are merely illustrative of the present invention, and
It is not used in the restriction present invention.
The realization of the present invention is described in detail below in conjunction with specific embodiment.
As shown in Fig. 1~11, the preferred embodiment provided for the present invention.
Shown in reference picture 1~11, the touch that the present embodiment is provided produces instruction and self-powered controller, and it can be used for
Various electric equipments are controlled, can be controlled by various wireless modes, can also be with smart home product receiving terminal
It is used in combination, and user is during touch controller, controller can produce electric energy, realize self-powered effect.
The touch that the present embodiment is provided produces instruction and confession electric controller, including panel 100, induction electrode 101, driving
Structure and electrification structure 103.Wherein, the shape of panel 100 can be diversified, such as tabular, or arc tabular etc., specifically may be used
Depending on being needed with actual design;Induction electrode 101 is sticked on the inner surface of panel 100.
Electrification structure 103 include coil and group of magnets, wherein, group of magnets include magnet 1033, upper conduction magnetic board 1036 with
And lower magnetic conductive board 1034, upper conduction magnetic board 1036 is arranged on the upper surface of magnet 1033, and lower magnetic conductive board 1034 is arranged on magnet
On 1033 lower surface, so, because the two ends magnetic of magnet 1033 is different, and due to upper conduction magnetic board 1036 and lower magnetic conductive board
1034 are separately positioned on the upper surface of magnet 1033 and lower surface, so that, in the periphery of upper conduction magnetic board 1036 and lower magnetic conductive board
Magnetic induction line is then produced between 1034 periphery.
Coil includes bobbin 1031 and is wrapped in the electric wire 1032 of the periphery of bobbin 1031, the bobbin 1031
Provided be disposed to extend along the short transverse of bobbin 1031 and lower ending opening hole position, and group of magnets inserted by the lower ending opening of hole position
In the hole position for being located at the bobbin 1031, so, when coil extended height direction is moved up and down, the electricity of the periphery of bobbin 1031
Line 1032 then can to the magnetic induction line between the periphery of upper conduction magnetic board 1036 and the lower periphery of magnetic conductive board 1034 produce cutting, that is, on lead
Magnetic induction line in the magnetic gap that magnetic sheet 1036 is constituted with lower magnetic conductive board 1034 is cut, and in cutting process, the electric wire of coil
Electric current can be then produced in 1032.
Driving structure is arranged on the lower section of panel 100, and it has abutment end 1021 and drive end, and the abutment end 1021 is set
In the lower section of panel 100, and it is connected on the inner surface of panel 100, the drive end of driving structure and the coil of electrification structure 103
Connection, so, when on user's touch panel 100 with 101 corresponding position of induction electrode, and presses panel 100, passes through face down
The drive end that the inner surface of plate 100 bear against driving structure is moved down, at the same the drive end of driving structure then move down or
It is moved upwardly by, certainly, drive end is moved or is moved upwardly by down, depending on the specific setting of visual driving structure, now, due to driving
The drive end of dynamic structure is connected with coil, under the driving effect of drive end, coil then can opposed magnet group move down or court
Upper movement, coil then produces cutting movement to the magnetic induction line between upper conduction magnetic board 1036 and lower magnetic conductive board 1034, and then, in coil
The two ends of electric wire 1032 then output current.
In the present embodiment, the electric wire 1032 of coil is electrically connected with Shaping Module 106 and control module 107, the electricity of coil
Produce electric current in line 1032, the shaping that the electric current of generation passes through Shaping Module 106, it is possible to achieve power, enter for control module 107
And control module 107 is initially located in working condition, and program according to its inner setting etc., send wireless instructions driving external electrical
Device equipment works.
In actual use, the two ends of electric wire 1032 of coil produce the arteries and veins that magnitude of voltage is higher, the time is shorter
Punching, voltage peak is in more than 10V, and hold time only 1.5mS, so, by the shaping of Shaping Module 106, by shaping pulse
For square wave, voltage is 2V, and the duration is more than 6mS, so as to be embodied as control module 107 and other circuit elements are powered so that
Control module 107 and other circuit elements are in running order.
The present embodiment, control module 107 is wirelessly driven in outside electric equipment work, the control module 107
Provided with RF communication elements, the instruction that control module 107 is sent is sent, outside electric equipment by the RF communication elements
In be provided with corresponding terminal receiver, terminal receiver correspondingly performs action according to the instruction that RF communication elements are sent is received.
Wireless telecommunications between the terminal receiver of RF communication elements and outside electric equipment can be proprietary protocol or opening
Agreement, such as ZigBee, Z-WAVE etc..
Or, as other embodiments, it can also be entered between control module 107 and outside electric equipment by wired mode
Row is electrically connected with, so that control module 107 sends instructions to the terminal receiver of the electric equipment of outside by wired mode
In, electric equipment then corresponds to and performs action.
The controller of above-mentioned offer, user by manual palpation and pressing panel 100 to the corresponding portion of induction electrode 101
Position, the coil cutting magnetic induction line of electrification structure 103 is driven using driving structure, so that the electric wire 1032 in coil produces electric current,
The electric current can be powered by the shaping of Shaping Module 106 for control module 107, realized and touched self-powered effect, and control
Module 107 power and it is in running order after, then can correspond to and send out instruction, the outside corresponding electric equipment of driving is dynamic
Make, realize the effect for touching and producing control instruction.
In above-mentioned touch produces instruction and self-powered controller, it need not be using battery etc. as power supply, can
To avoid a series of problems existed using battery so that the use of controller is highly reliable, substantially reduces customer using cost,
And environment etc. will not be impacted, use is more environmentally friendly;Furthermore, the controller of touch manner, relative to traditional silica gel keyboard,
For mechanical switch keyboard, it has longer service life.
In the present embodiment, driving structure includes lever 102 and linkage structure 105, and the middle part of the lever 102 is hinged cloth
Put, the middle part of lever 102 forms pin joint, is connected by pin joint with hinged seat, so that the front end and rear end of lever 102
With respect to tilting above and below pin joint.
The front end of lever 102 forms above-mentioned abutment end 1021, and it is in the lower section of panel 100, and is connected to panel 100
Inner surface on, there is the drive end that is connected with coil, and the rear end of lever 102 passes through linkage structure 105 in linkage structure 105
Driving coil is moved up and down, thus by user touch and by lower panel 100 with the corresponding position of induction electrode 101, realize
The collection that coil cutting magnetic induction line is generated electricity and finger induced signal is instructed.
Specifically, the front end of lever 102 is arranged in spherical shape or triangular shape, it is, abutment end 1021 in spherical shape or
Triangular shape arrangement, so so that when abutment end 1021 is compressed by the inner surface of panel 100, frictional force is reduced as far as possible.
Lever 102 is in bending, and its bending place forms above-mentioned pin joint, that is, the bending place of lever 102 is hinged
Arrangement, so, using pin joint as boundary, the two ends bending arrangement of lever 102, the arrangement for being easy to the two ends of lever 102 to move up and down.
In the present embodiment, accelerating structure 104, the accelerating structure are provided between the rear end of lever 102 and linkage structure 105
104 are connected with the rear end of lever 102 and linkage structure 105 respectively, and it is used to drive the acceleration of linkage structure 105 to move, so that
Realize that driving coil accelerates to move up and down, fly-cutting magnetic induction line.
Specifically, accelerating structure 104 is included in the flexure strip 1043 and magnetic inductive block 1042 of stress deformation, flexure strip 1043
Portion's hinge arrangement, its front end is connected to the rear end of lever 102, and its rear end is connected with magnetic inductive block 1042, and magnetic inductive block 1042 and connection
Dynamic structure 105 is connected, and is respectively equipped with magnet piece 1041 over and under in magnetic inductive block 1042, two magnet pieces 1041 are alternate
Every positioned opposite, form interval region between the two, magnetic inductive block 1042 is then arranged in the interval region, and magnetic inductive block 1042 with
The wherein adhesive of a magnet piece 1041.
The operating process of the driving structure of above-mentioned offer is as follows:
As shown in Fig. 2 in an initial condition, magnetic inductive block 1042 is pull-in on N poles magnet piece 1041, and now, coil is in
Extreme position above group of magnets;
As shown in figure 3, now, with the corresponding position of induction electrode 101 on user's finger touch panel 100, and finger after
Continuous to press downwards, under the compressing of panel 100, the abutment end 1021 of lever 102 is moved down, lever 102 around pin joint tilting, this
When, the rear end of lever 102 is moved upwardly by, also, the rear end driving flexure strip 1043 of lever 102 is deformed, and flexure strip 1043 occurs
Deformation, but be due to that magnetic inductive block 1042 is held by N poles magnet piece 1041, therefore, do not have in the deforming force of flexure strip 1043
When reaching sufficiently large active force, magnetic inductive block 1042 can't be moved down;As finger continues down to press panel 100, elasticity
The deforming force of piece 1043 is increasing, until the deforming force is more than between magnetic inductive block 1042 and N poles magnet piece 1041
The suction-combining force when, shown in reference picture 4, in the presence of flexure strip 1043, magnetic inductive block 1042 can then accelerate to move down, and by S
Pole magnet piece 1041 is held, because linkage structure 105 is connected with magnetic inductive block 1042, so that the drive end of linkage structure 105 then drives
Moving winding high-speed mobile down, coil then high-speed cutting magnetic induction line, so that, in the two ends output current of coil wire 1032.
Flexure strip 1043 is in bending, and its middle part is formed with fulcrum, and the fulcrum is articulated and connected with pillar so that flexure strip
1043 middle part hinge arrangement, so, when flexure strip 1043 is during powered, the tilting of flexure strip 1043 is deformed, in order to
Realize that flexure strip 1043 can restPose automatically after the distress resolves down pressed on panel 100 are applied.
In the present embodiment, driving structure also includes back-moving spring 113, the lower end fixed and arranged of the back-moving spring 113, multiple
The upper end of position spring 113 is connected to the abutment end 1021 of driving structure, that is, lever 102 front end.So, when panel 100
Down along behind the front end of lever 102, back-moving spring 113 is by compression, after the distress resolves of the panel 100 of application,
Recover in the presence of the restoring force of spring 113, the front end of lever 102 is then swung upward, recover reset condition, certainly, in lever 102
Front end move up and down during, accelerating structure 104 and the grade of linkage structure 105 are also with corresponding action.
Or, magnetic conduction, higher than the middle part of two magnet pieces 1041, so, is worked as in the position of the fulcrum of flexure strip 1043
Block 1042 is by after the adhesive of S poles magnet piece 1041, and the deformation power of flexure strip 1043 is greater than magnetic inductive block 1042 and S poles magnet piece 1041
Between the suction-combining force so that, after the distress resolves down pressed on panel 100 are applied, flexure strip 1043 then restores to the original state,
It is exactly that magnetic inductive block 1042 is moved upwardly by, is pull-in on N poles magnet piece 1041, so that, set when needing to control the electrical equipment of outside again
When standby, user then touch again and down by panel 100 with the corresponding position of induction electrode 101, repeat the above-mentioned behaviour referred to
Make.
In the present embodiment, linkage structure 105 includes linkage support 107, and one end of linkage support 107 forms above-mentioned driving
End, the drive end is fixedly connected with coil, and the other end of linkage support 107 extends outwardly arrangement, the other end of linkage support 107
It is connected with magnetic inductive block 1042, so, when being moved up and down between magnetic inductive block 1042 is fast in two magnet 1033, magnetic inductive block 1042 is then
Driving linkage support 107 is moved up and down, and then is moved up and down using the driving coil of linkage support 107, realizes coil cutting magnetic induction
The effect of line.
One end for the ease of linkage support 107 is fixedly connected with coil, the present embodiment, one end court of linkage support 107
Two clamping strips 1071 are extended with outside, the alternate arrangement of two clamping strip 1071 is formed for clamping bobbin 1031 between the two
Clamping interval, so, the periphery of coil is clamped in using two clamping strips 1071, then can cause linkage support 107
One end is fixedly connected with coil, also, using the elastic deformability of clamping strip 1071, can greatly increase its chucking power.
Clamping strip 1071 is in the arc shape of outer gibbosity, so, and the clamping between two clamping strips 1071 is spaced to form approximate
Toroidal, is easy to the cooperation at the clamping interval and coil periphery.In the present embodiment, two clamping strips 1071 of linkage support 107
Form above-mentioned drive end.
Certainly, as other embodiments, one end of linkage support 107 can also be matched somebody with somebody using other various structures with coil
Close, be welded to connect as used, or other manner can.
As further optimum choice, linkage support 107 is the elastic linkage support 107 arranged in bending, this
Sample, when magnetic inductive block 1042 is driving linkage support 107, linkage support 107 deforms, so that linkage support 107 is more
Quick driving coil is moved up and down.Certainly, the setting for linkage support 107 can be diversified, such as spring-piece type, or other
Can flexible deformation structure etc..
In the group of magnets that the present embodiment is provided, the periphery of lower magnetic conductive board 1034 is extended to outside magnet 1033, and lower magnetic conductive board
1034 periphery is convexly equipped with peripheral board 1035, and projection is disposed to extend the peripheral board 1035 upward, formed magnet 1033 and on lead
The periphery of magnetic sheet 1036, that is to say, that lower magnetic conductive board 1034 formation caviton shape, so, peripheral board 1035 and magnet 1033 it
Between then form magnetic gap;After magnet 1033 and upper conduction magnetic board 1036 are located in the hole position of bobbin 1031, coil is then plugged
In the magnetic gap stated, it is possible to moved up and down in the magnetic gap.
So, due to the setting of peripheral board 1035 so that the magnetic induction line between upper conduction magnetic board 1036 and lower magnetic conductive board 1034
Coverage is wider, and the intensity of magnetic induction line is bigger, increase coil during moving up and down, cutting upper conduction magnetic board 1036 with
The density of magnetic induction line between lower magnetic conductive board 1034, during also greatly enhancing coil cutting magnetic induction line, the current strength of generation.
Specifically, the profile of upper conduction magnetic board 1036, magnet 1033, lower magnetic conductive board 1034 and peripheral board 1035 is all rounded
Shape, certainly, depending on concrete structure setting is visually actually needed.
In the present embodiment, the upper end of peripheral board 1035 and the upper end flush arrangement of upper conduction magnetic board 1036, that is, both etc.
High arrangement;Or, according to actual needs, the upper surface of peripheral board 1035 can also be higher than the upper surface of upper conduction magnetic board 1036.
That is, the upper surface of peripheral board 1035, which is tried one's best, is not less than the upper surface of upper conduction magnetic board 1036.
In addition, the hole position of bobbin 1031 is through hole, line so, is easy in the upper end and lower end of its thorough coil frame 1031
Enclose the scope moved up and down.Also, hole position is circular port, so, accordingly, magnet 1033 and upper conduction magnetic board 1036 also Cheng Yuan
Arrangements;Or, as other embodiments, hole position, upper conduction magnetic board 1036 and magnet 1033 can also be in other shapes cloth
Put, such as square shape.
The touch that the present embodiment is provided produces instruction and self-powered controller, and it can be exactly only with singly-bound touch manner
Single induction electrode 101, or multikey touch manner are set, the induction electrode 101 of multiple difference in functionalitys is exactly set.
Controller for realizing multikey touch manner, controller includes multiple senses for being arranged on the inner surface of panel 100
Electrode 101 is answered, now, the lower section of panel 100 is then correspondingly provided with two driving structures, and two driving structures are arranged symmetrically
The both sides of electrification structure 103;Or, can also individually or a driving structure, depending on being specifically visually actually needed.
In the present embodiment, touch generation instruction and self-powered controller include Multi-way touch signal acquisition module 108,
The Multi-way touch signal acquisition module 108 is electrically connected at control module 107 and multiple induction electrodes 101, the Multi-way touch
There is oscillator and logic controller in signal acquisition module 108.
So, when driving structure driving coil is moved up and down, the output current of electric wire 1032 in coil, electric current passes through shaping
After the shaping of module 106, powered to control module 107 and Multi-way touch signal acquisition module 108, also, in control module 107
And Multi-way touch signal acquisition module 108 is when being in firm start-up operation state, the finger of user still stop on panel 100 with
On the corresponding position of induction electrode 101, therefore, about 5pF electric capacity is formed between finger and induction electrode 101, by this
The frequency of oscillation of oscillator in the influence of electric capacity, Multi-way touch signal acquisition module 108 can then change, the frequency of oscillator
Rate changes, and causes logic controller to export corresponding coding, and then, the coding of logic controller output is sent to control mould
In block 107, and because each induction electrode 101 has different codings, so, control module 107 is according to the volume received
Code, then can be used for distinguishing different induction electrodes 101, and wirelessly send instruction using RF communication elements, or controller passes through
Wired mode sends instruction, the outside corresponding electric equipment action of control.
In the present embodiment, touch and produce instruction and self-powered controller also including bottom plate 106, the bottom plate 106 and face-piece
Coordinate, and enclose to form receiving space between bottom plate 106 and face-piece, above-mentioned electrification structure 103, driving structure etc. are placed on this
In receiving space.Certainly, the structure setting of bottom plate 106 can be variation, depending on being specifically visually actually needed.
The foregoing is merely illustrative of the preferred embodiments of the present invention, is not intended to limit the invention, all essences in the present invention
Any modifications, equivalent substitutions and improvements made within refreshing and principle etc., should be included in the scope of the protection.
Claims (10)
- Instruction and self-powered controller are produced 1. touching, it is characterised in that including panel, induction electrode and electrification structure; The induction electrode is located at the inner surface of the panel;The electrification structure includes coil and group of magnets, and the group of magnets includes Magnet, upper conduction magnetic board and lower magnetic conductive board, the upper conduction magnetic board are located at the upper end of the magnet, and the lower magnetic conductive board is arranged on magnetic The lower end of iron;The coil is set in the group of magnets;The lower section of the panel, which is provided with, to be used to drive to move down on the coil Move so that the driving structure of coil cutting magnetic induction line, the driving structure has abutment end and the driving being connected with the coil End, the abutment end of the driving structure is connected to the inner surface of the panel;The electric wire of the coil be electrically connected with for pair The electric current that the coil is produced carries out the Shaping Module of shaping and is powered to send the control module of instruction, and the driving structure includes Lever and linkage structure, the middle part hinge arrangement of the lever, the front end of the lever form the abutment end, the linkage Structure is connected with the coil, and the rear end of the lever is moved up and down by the linkage structure driving coil, described to touch Produce instruction and self-powered controller includes for driving the linkage structure to accelerate mobile accelerating structure, the acceleration Structure is connected between the rear end of the lever and linkage structure, and the accelerating structure includes flexure strip, the magnetic conduction of stress deformation Block and two magnet pieces, the middle part hinge arrangement of the flexure strip, the front end of the flexure strip is connected to after the lever End, the rear end of the flexure strip is connected to the magnetic inductive block, and two magnet pieces are separately positioned opposite, and the magnetic inductive block is put Between two magnet pieces, and it is pulled on one of magnet.
- 2. as claimed in claim 1 touch produces instruction and self-powered controller, it is characterised in that the middle part of the lever Pin joint with hinge arrangement, the lever is in bending, and the bending place of the lever forms the pin joint.
- 3. as claimed in claim 1 touch produces instruction and self-powered controller, it is characterised in that in the flexure strip Portion is formed with the magnetic of position higher than two of fulcrum, the fixed pivot arrangement of the flexure strip, and the fulcrum of the flexure strip The centre position of iron block.
- 4. as claimed in claim 1 or 2 touch produces instruction and self-powered controller, it is characterised in that the touch production Raw instruction and self-powered controller include back-moving spring, the lower end fixed and arranged of the back-moving spring, the back-moving spring Upper end is disposed to extend upward, is connected to the abutment end of the lever.
- 5. as claimed in claim 1 or 2 touch produces instruction and self-powered controller, it is characterised in that the linkage knot Structure includes linkage support, and one end of the linkage support is connected with coil, the formation drive end, the linkage support it is another Hold the arrangement that extends outwardly.
- 6. as claimed in claim 4 touch produces instruction and self-powered controller, it is characterised in that the linkage support One end, which extends outwardly, two clamping strips, and two clamping strips are separately arranged, is formed between the two for clamping the line The clamping interval of circle.
- 7. as claimed in claim 1 or 2 touch produces instruction and self-powered controller, it is characterised in that the panel Inner surface is provided with multiple induction electrodes;The control module is electrically connected with Multi-way touch signal acquisition module, and the multichannel is touched Touch signal acquisition module and be electrically connected to have in multiple induction electrodes, the Multi-way touch signal acquisition module respectively and shake Swing device and encode to control module corresponding with each induction electrode is sent according to the change of the frequency of oscillation of the oscillator Logic controller.
- 8. as claimed in claim 7 touch produces instruction and self-powered controller, it is characterised in that the touch, which is produced, to be referred to Order and self-powered controller include two driving structures, and two driving structures are arranged symmetrically to generate electricity described The both sides of structure.
- 9. as claimed in claim 1 or 2 touch produces instruction and self-powered controller, it is characterised in that the lower magnetic conduction The periphery of plate is extended to outside the magnet, and the periphery of the lower magnetic conductive board is convexly equipped with the peripheral board extended upward, the periphery Magnetic gap is formed between plate and the upper conduction magnetic board, the coil is plugged in the magnetic gap.
- 10. as claimed in claim 9 touch produces instruction and self-powered controller, it is characterised in that the peripheral board Upper surface is at least above the upper surface of the upper conduction magnetic board.
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CN201710735287.6A CN107357518B (en) | 2014-12-31 | 2014-12-31 | Touch generation instruction and self-powered controller |
CN201410856037.4A CN104656479B (en) | 2014-12-31 | 2014-12-31 | Touch and produce instruction and self-powered controller |
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CN201410856037.4A CN104656479B (en) | 2014-12-31 | 2014-12-31 | Touch and produce instruction and self-powered controller |
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CN201710735287.6A Division CN107357518B (en) | 2014-12-31 | 2014-12-31 | Touch generation instruction and self-powered controller |
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CN104656479B true CN104656479B (en) | 2017-08-22 |
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CN201410856037.4A Active CN104656479B (en) | 2014-12-31 | 2014-12-31 | Touch and produce instruction and self-powered controller |
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CN107357518B (en) * | 2014-12-31 | 2024-02-13 | 刘远芳 | Touch generation instruction and self-powered controller |
CN110703657B (en) * | 2015-05-29 | 2023-07-25 | 广东易百珑智能科技有限公司 | Self-generating wireless switch and application thereof |
CN105048599B (en) * | 2015-08-28 | 2019-07-09 | 武汉领普科技有限公司 | Spontaneous controller for electric consumption |
CN106464116B (en) * | 2015-11-26 | 2020-04-03 | 广东易百珑智能科技有限公司 | Kinetic energy power generation device, wireless transmitter, manufacturing method and application of wireless transmitter |
KR102073651B1 (en) | 2015-11-26 | 2020-02-05 | 김기삼 | Kinetic energy generator, radio transmitter, manufacturing method and application |
CN108595032B (en) * | 2018-05-10 | 2021-06-25 | 东南大学 | Self-generating energy-saving wireless mouse capable of generating electricity by pressing |
CN110071617A (en) * | 2019-01-11 | 2019-07-30 | 深圳市易百珑科技有限公司 | Balance drive power generator and its multikey reversed return type passive transmitter and launching technique |
CN110718134A (en) * | 2019-10-21 | 2020-01-21 | 黄静勤 | Education robot is built to multi-functional intention |
CN112614326A (en) * | 2020-12-09 | 2021-04-06 | 无锡迪富智能电子股份有限公司 | Self-generating remote controller for intelligent closestool |
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CN104656479A (en) | 2015-05-27 |
CN107357518A (en) | 2017-11-17 |
CN107357518B (en) | 2024-02-13 |
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