CN107852080A

CN107852080A - Self-generating remote controller and its application

Info

Publication number: CN107852080A
Application number: CN201680000666.4A
Authority: CN
Inventors: 廖淑辉; 刘远芳; 廖旺宏
Original assignee: Individual
Current assignee: SHENZHEN WUDIANTONG TECHNOLOGY Co.,Ltd.
Priority date: 2016-02-04
Filing date: 2016-08-09
Publication date: 2018-03-27
Also published as: CN206378979U; CN112767675A; WO2017133211A1; CN112863163A

Abstract

One Self-generating remote controller and its application, the Self-generating remote controller include：Key device (20), cloth key lid (11), driving lid (12), kinetic-energy power generator (40) and controller (30), an at least button (21) for wherein described key device (20) is pressed and the driving lid (12) drive the kinetic-energy power generator (40) by mechanical kinetic energy switch to for electric energy when, an at least wireless control signal that the button (21) that the controller (30) is launched and is pressed in the case where the electric energy that the kinetic-energy power generator (40) provides is supplied matches.

Description

Self-generating remote controller and its application

Technical field

The present invention relates to a remote controler more particularly to an electric appliance remote controllers with a self-generating function, while providing a self-power generation method, a method for transmitting signal and the continuous variable signal control method of a Self-generating remote controller.

Background technique

Remote controler using very extensive, becomes indispensable controlling equipment in field of household appliances.But electric appliance remote controller on the market will use battery to need to be replaced frequently as power supply it is known that battery is easily-consumed products, this can bring some expenses and inconvenience to user；According to statistics, the battery that the whole world consumes on the electronic product of household appliance technical field every year is up to over ten billion piece, this is a huge expense, moreover, a large amount of waste battery will be damaged to environment, it is therefore necessary to research and develop a remote controler that just can control household electrical appliance without battery.

In recent years, with the development of science and technology, it has begun and appears on the market without the wireless switching of battery, due to the limitation of technology, the key of the existing switch that bursts at the seams without using battery will realize that pressing movement is used to generate electricity and complete key information acquisition again, the number of keys of this wireless switching has biggish limitation, it is typically only capable to arrange several a limited number of keys, and be typically only capable to realize the control of simple electric switch switched on and off, it is unable to satisfy the demand of up to tens keys of remote controler of the electric appliances such as television set, sound equipment.Moreover, for remote controler, comfortably feel and sensitive control are highly important, if the technology of existing passive and wireless switch is used to manufacture the electric appliance multikey remote controler meet disadvantage that journey is big, feel is poor, noise is big before leaving, can not be applied in actual products.Still further aspect, existing self-generating device generating efficiency is lower, and the signal transmitting operation that discomfort is combined into a variety of key commands of remote controler provides enough electric energy supplies.

Summary of the invention

It is an object of the present invention to provide a Self-generating remote controllers, wherein the Self-generating remote controller includes kinetic-energy power generator, do not need additional battery or external power supply.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the Self-generating remote controller is passive self-power generation type, and can arrange numerous keys.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the Self-generating remote controller is using top Lid synthesizes entirety with bottom cover, and top cover is inactive, and bottom cover can move, and any more key can be arranged on motionless top cover.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the Self-generating remote controller is self-power generation type, the part that relative displacement power generation occurs and key part are provided separately, are difficult to arrange together to solve the problems, such as should to act while generating relative displacement power generation placing key-press part again and stir.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the Self-generating remote controller includes the driving lid of multi-direction swing, and are driven by it kinetic-energy power generator and produce electricl energy, thus convenient to use.

Another object of the present invention is to provide a Self-generating remote controller, wherein the Self-generating remote controller by cloth key lid come placing key-press, and lid is driven to be used to drive power generation, so that power generation and key are provided independently from, to facilitate the arrangement of multiple keys.

Another object of the present invention is to provide a Self-generating remote controllers, when wherein user uses the Self-generating remote controller, button operation and the operation collocation for pressing the driving lid, in a manner of realizing remote signal, to provide a kind of mode of operation of completely new remote controler.

Another object of the present invention is to provide a Self-generating remote controllers can start kinetic-energy power generator wherein the driving lid can be arranged to press any position of its bottom surface, thus convenient to use.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the driving is covered when being pressed and discharging, the kinetic-energy power generator can be driven to generate an electric energy, that is, generate electric energy twice, send one or many control signals as needed for the Self-generating remote controller.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the kinetic-energy power generator of the Self-generating remote controller has magnetic conduction cavity, coil is located in the magnetic conduction cavity, to reduce leakage field, improve generating efficiency.

Another object of the present invention is to provide a Self-generating remote controllers, wherein the magnetic conduction cavity of the kinetic-energy power generator of the Self-generating remote controller uses magnetic conduction cavity configuration, induction coil is placed on the center pillar of the inside of magnetic conduction chamber, the one side of magnetic conduction chamber has magnetic group, in this way, entire coil is completely covered by magnetic induction line, to reduce leakage field, thus during the movement of magnetic group, coil obtains the flux change amount increased, thus high-power electric energy of inducting is generated in coil.

Another object of the present invention is to provide a Self-generating remote controllers, high-power electric energy can be provided while wherein the common kinetic-energy power generator of the kinetic-energy power generator volume ratio equal-wattage of the Self-generating remote controller is small, and magnetoelectricity conversion ratio significantly improves, to which industrial applicibility greatly enhances, application range is more extensive.

Another object of the present invention is to provide a Self-generating remote controller, the Self-generating remote controller includes unilateral pendulum A dynamic driving lid, is suitable for being installed on environmental surfaces such as wall.Another object of the present invention is to provide the self-power generation methods of a Self-generating remote controller can convert electric energy for the pressing kinetic energy suffered by remote controler and provide electric power source for the Self-generating remote controller for the remote control device of machinery power generation.

Another object of the present invention is to provide a continuous variable signal control methods, are used for passive and wireless device, such as Self-generating remote controller, can realize critical function, such as stepless-adjustment volume, brightness continuous variable by emitting signal twice.

In order to realize that at least one above-mentioned purpose, the present invention provide a Self-generating remote controller comprising:

An at least key device comprising one or more keys；

An at least cloth key lid, for arranging the key；

At least one driving lid；

An at least kinetic-energy power generator；And

An at least controller, when wherein at least one key is pressed and the kinetic-energy power generator is driven to switch to mechanical kinetic energy for electric energy for driving lid, an at least wireless control signal that the key that the controller is launched and is pressed in the case where the electric energy that the kinetic-energy power generator provides is supplied matches.

In one embodiment, the cloth key lid is movably engaged with driving lid.

In one embodiment, the cloth key lid and driving lid form an accommodating chamber, and the controller and the kinetic-energy power generator are located in the accommodating chamber.

In one embodiment, the cloth key lid and the driving are covered respectively as a top cover and a bottom cover.

In one embodiment, the cloth key lid and the driving are covered respectively as a top cover and a side cover.

In one embodiment, the driving lid is configured to the medial movement along the cloth key lid.

In one embodiment, the driving lid is configured to move on the outside of the cloth key lid.

In one embodiment, the cloth key lid and the driving are covered through an at least hook and at least a sliding slot slidably engages.

In one embodiment, the cloth key lid and the driving are covered is cooperated by the corresponding sliding slot of four hooks and four that are located at four sides, and the driving covers and is configured to move along front and rear, left and right and up and down direction.

In one embodiment, the cloth key lid and the driving are covered respectively as a top cover and a bottom cover, and are connected in such a way that unilateral side is swung.

In one embodiment, the driving lid is suitable for being fixed on an environmental surfaces, and the driving lid described in this way is motionless, and the cloth key lid can be covered relative to the driving and be moved.

In one embodiment, the cloth key lid and described driving lid one end pass through an at least hook respectively and an at least sliding slot cooperates, and the other end is cooperated by an at least card slot and an axis.

In one embodiment, the kinetic-energy power generator is piezoelectric effect generator, is produced electricl energy when the pressure by the driving lid is driven.

In one embodiment, the kinetic-energy power generator includes an at least magnetic group, an at least coil, an and at least center pillar, wherein the coil is arranged around the center pillar, the magnetic group includes an at least permanent magnet and pushes up magnetizer and an at least bottom magnetizer positioned at opposite polarity at least the one of the permanent magnet two opposite sides, wherein when driving lid and the cloth key lid generate relative displacement, the center pillar can alternately contact the top magnetizer and the bottom magnetizer, it changes to pass through the magnetic induction line direction of the coil, make to generate an at least induced current in the coil.

In one embodiment, there is a magnetic gap, one end of the center pillar extends into the magnetic gap, with the inside for alternately contacting the top magnetizer and the bottom magnetizer between the top magnetizer and the bottom magnetizer.

In one embodiment, the magnetic group is fixed, and the center pillar is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer by driving.

In one embodiment, the center pillar is fixed, and the magnetic group is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer by driving.

In one embodiment, the self-generating device further includes a magnetic conduction cavity, wherein the center pillar and the coil are located in the magnetic conduction cavity.

In one embodiment, the magnetic conduction cavity has an opening, and the magnetic group sealing is in the opening.

In one embodiment, the center pillar is installed on the magnetic conduction cavity.

In one embodiment, the center pillar and the magnetic conduction cavity are integrally formed.

In one embodiment, the kinetic-energy power generator further includes an at least driving arm, and the driving arm has a magnetic group fixing groove, and with the fixation magnetic group, the driving arm and the magnetic conduction cavity are pivotably connected.

In one embodiment, the kinetic-energy power generator further includes an at least driving element, it is connected to the driving arm, the driving lid includes at least one touch element, it can act on the driving element, pivot the driving arm, so that the magnetic group and the center pillar generate relative displacement.

In one embodiment, the driving element is an elastic slice.

In one embodiment, the driving element and the driving arm are integrally formed.

In one embodiment, the kinetic-energy power generator further includes an at least reset element, is connected to the driving element, and after the driving drowning is pressed, under the reset response of the reset element, the driving arm and the magnetic group can automatically reset.

In one embodiment, the reset element is selected from one of elastic slice, compressed spring and torsional spring.

In one embodiment, described reset element one end is connected to the driving element, and the other end is connected to the controller.

In one embodiment, described reset element one end is connected to the driving element, and the other end is connected to the cloth key lid.

In one embodiment, the magnetic conduction cavity is additionally provided with two pins, and the both ends of the coil are respectively positioned in the pin.

In one embodiment, the magnetic conduction cavity is fixed on the controller to root.

In one embodiment, the magnetic conduction cavity is fixed on the cloth key lid.

In one embodiment, described Driving armIncluding an at least rest body, an at least magnetic group fixed arm group and an at least swing arm group, the magnet fixed arm group respectively extends internally from the both ends of the rest body and forms the magnetic group fixing groove with the rest body, and the swing arm group extends out to the two sides of the magnetic conduction cavity from the magnetic group fixed arm group.

In one embodiment, the magnetic group fixing groove has an aperture towards the intracorporal center pillar of the magnetic conduction chamber, extends into the magnetic group for described center pillar one end.

In one embodiment, each magnetic group fixed arm group is additionally provided with an at least abutment end dowel, for consolidating the top magnetizer and the bottom magnetizer.

In one embodiment, the top magnetizer also has a top magnetizer abutment end, and the bottom magnetizer also has a bottom magnetizer abutment end, and the abutment end dowel is for positioning the top magnetizer abutment end and the bottom magnetizer abutment end.

In one embodiment, the swing arm group and the magnetic conduction cavity are pivotably connected by an at least rotary axis groove and a rotation axis.

In one embodiment, the top magnetizer also has a top magnetizer abutment end, the bottom magnetizer also has a bottom magnetizer abutment end, the magnetic conduction cavity has a top edge and a bottom edge, the top magnetizer abutment end and the bottom magnetizer abutment end extend into the magnetic conduction cavity, when wherein the center pillar alternately contacts the top magnetizer abutment end and the bottom magnetizer abutment end, the bottom magnetizer abutment end and the top magnetizer abutment end are correspondingly contacted with the bottom edge of the magnetic conduction cavity and the top edge respectively, are made across the coil The direction of magnetic induction line changes, to generate the induced current in the coil.

In one embodiment, the cloth key lid has one or more key slots, wherein each key is arranged in the corresponding key slot.

In one embodiment, the convex top surface in the cloth key lid of each key it is arranged.

In one embodiment, the key of the key device is integrally formed, to form a key board.

In one embodiment, the key press is less than driving lid with pressing force required for the corresponding connection corresponding key circuit of controller to be pressed to start the pressing force of the kinetic energy electric generating devcie.

In one embodiment, the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates supplies the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches after the power supply shaping operation of the shaping circuit.

In one embodiment, the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.

According to a further aspect of the invention, the present invention provides a Self-generating remote controller comprising:

An at least key device comprising one or more keys；

An at least controller；

An at least shell has an accommodating chamber, and including at least one driving lid；And

An at least kinetic-energy power generator, the kinetic-energy power generator and the controller are located in the accommodating chamber, and the kinetic-energy power generator includes: an at least magnetic conduction cavity, an at least magnetic group, an at least center pillar and at least a coil, wherein the coil is arranged around the center pillar, the magnetic group includes an at least permanent magnet and opposite polarity two magnetizer for being located at the permanent magnet two opposite sides, wherein a magnetic gap is formed between two magnetizers, described center pillar one end extends into the magnetic gap, the coil and the center pillar are arranged in the magnetic conduction cavity to reduce leakage field；

The kinetic-energy power generator can be driven when wherein the driving lid is configured as being pressed, the center pillar is set alternately to contact two magnetizers, to generate an at least induced current in the coil, and at least wireless control signal that the controller key launching and be pressed under the electric energy supply of the induced current matches.

According to a further aspect of the invention, the present invention provides an infrared Self-generating remote controller comprising:

An at least shell has an accommodating chamber；

An at least key device comprising one or more keys；

An at least infrared controller is configured with an at least infrared-emitting diode；And

An at least kinetic-energy power generator, the infrared controller and the kinetic-energy power generator are located in the accommodating chamber, and the kinetic-energy power generator is configured to convert electric energy for mechanical kinetic energy, the infrared controller launches the wireless control signal to match with the key being pressed via the infrared-emitting diode under the electric energy supply that the kinetic-energy power generator provides.

According to a further aspect of the invention, the present invention provides the method for transmitting signal of a Self-generating remote controller, it includes the following steps: in response to an at least button operation and in addition independent at least one power generation pressing operation, the Self-generating remote controller self power generation simultaneously launch an at least wireless control signal corresponding to the button operation.

In one embodiment, the method further includes:

(A) in the button operation: when an at least key for an at least key device is pressed, the control instruction circuit that an at least controller corresponds to the key is switched on；

(B) in the power generation pressing operation: when at least one mobilizable driving lid is pressed, at least a kinetic-energy power generator, which is driven, converts electric energy for mechanical energy；And

(C) controller emits the wireless control signal of the corresponding key being pressed under the electric energy supply that the kinetic-energy power generator provides.

In one embodiment, wherein in the step (B), the touch element of the driving lid is further comprised the steps of: when compressing the driving element, an at least reset element generates elastic deformation, and the method also includes step (D): when the pressing force for being applied to the driving lid disappears, the reset element is restored from elastic deformation state to original state, the driving element drives the driving arm and the magnetic group to automatically reset, the center pillar is set alternately to contact two magnetizers of the magnetic group again, to generate another secondary induced current.

In one embodiment, the method further includes:

(b) in the power generation pressing operation: when at least a cloth key lid is pressed, the cloth key lid generates relative displacement at least one driving lid, and at least a kinetic-energy power generator, which is driven, converts electric energy for mechanical energy；

And

(c) controller emits what correspondence was pressed under the electric energy supply that the kinetic-energy power generator provides The wireless control signal of the key.

In one embodiment, wherein in the step (b), the touch element of the driving lid is further comprised the steps of: when compressing the driving element, an at least reset element generates elastic deformation, and the method also includes steps (d): when the pressing force for being applied to the cloth key lid disappears, the reset element is restored from elastic deformation state to original state, the driving element drives the driving arm and the magnetic group to automatically reset, the center pillar is set alternately to contact two magnetizers of the magnetic group again, to generate another secondary induced current.

According to a further aspect of the invention, the present invention provides the continuous variable signal control method of a Self-generating remote controller comprising:

(I) an at least kinetic-energy power generator is driven so that an at least center pillar is alternately contacted an at least magnetic group to push up magnetizer and a bottom magnetizer positioned at the one of an at least permanent magnet two opposite sides, an at least coil around the center pillar is set and generates first time induced current, the controller the first time induced current electric energy supply under launch first time wireless control signal；

(II) under at least reset response of a reset element, the center pillar alternately contacts the bottom magnetizer and the top magnetizer of the magnetic group, an at least coil around the center pillar is set and generates second of induced current, the controller second of the induced current electric energy supply under launch second of wireless control signal；

(III) when determining that the time difference for the wireless control signal twice that the step (I) and the step (II) issue is located in preset time, at least electric appliance being remotely controlled is programmed to the button operation of the Self-generating remote controller doing single keys presses processing；And

(IV) when the wireless control signal twice for determining that the step (I) and the step (II) issue is located at other than preset time, the electric appliance is programmed to the button operation of the Self-generating remote controller doing continuous key-press processing, and the electric appliance is made to execute the control operation of continuous variable signal.

According to a further aspect of the invention, the present invention provides the self-power generation method of a Self-generating remote controller, it includes the following steps: when at least one driving lid is pressed, the driving lid makes an at least magnetic group for an at least kinetic-energy power generator and is located at the intracorporal at least center pillar of an at least magnetic conduction chamber and magnetic group generation relative displacement, the center pillar is set alternately to contact a top magnetizer and a bottom magnetizer that the magnetic group is located at a permanent magnet two opposite sides, make to generate induced current at least once in the coil being arranged in around the center pillar, wherein the coil and the center pillar are located in the magnetic conduction cavity, the coil is completely covered by magnetic induction line, reduce leakage field, improve the generating efficiency of the kinetic-energy power generator.

In one embodiment, the method also includes steps: when driving lid is no longer pressed, under at least reset response of a reset element, the center pillar is set alternately to contact the bottom magnetizer and the top magnetizer of the magnetic group, to make to generate another secondary induced current in the coil being arranged in around the center pillar.

According to a further aspect of the invention, the present invention provides the self-power generation method of a Self-generating remote controller, it includes the following steps: when at least a cloth key lid is pressed, at least one driving lid being pivotably connected with the cloth key lid makes an at least magnetic group for an at least kinetic-energy power generator and is located at the intracorporal at least center pillar of an at least magnetic conduction chamber and magnetic group generation relative displacement, the center pillar is set alternately to contact an opposite polarity top magnetizer and a bottom magnetizer that the magnetic group is located at a permanent magnet two opposite sides, make to generate induced current at least once in the coil being arranged in around the center pillar, wherein the coil and the center pillar are located in the magnetic conduction cavity, the coil is completely covered by magnetic induction line, reduce leakage field, improve the generating efficiency of the kinetic-energy power generator.

In one embodiment, the method also includes steps: when the cloth key lid is no longer pressed, under at least reset response of a reset element, the center pillar is set alternately to contact the bottom magnetizer and the top magnetizer of the magnetic group, to make to generate another secondary induced current in the coil being arranged in around the center pillar.

Detailed description of the invention

Figure 1A is the stereoscopic schematic diagram of a Self-generating remote controller according to a preferred embodiment of the invention.

Figure 1B is the stereoscopic schematic diagram of the Self-generating remote controller of above preferred embodiment according to the present invention.

Fig. 2 is the explosive decomposition schematic diagram of the Self-generating remote controller of above preferred embodiment according to the present invention.

Fig. 3 is the stereoscopic schematic diagram of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 4 is the explosive decomposition schematic diagram of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 5 is the stereoscopic schematic diagram of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 6 is the stereoscopic schematic diagram of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 7 is the schematic cross-sectional view of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 8 is the schematic cross-sectional view of kinetic-energy power generator in above preferred embodiment according to the present invention.

Fig. 9 is the schematic cross-section of kinetic-energy power generator in above preferred embodiment according to the present invention.

Figure 10 A and Figure 10 B are the electricity generating principle schematic diagrames of a kinetic-energy power generator in above preferred embodiment according to the present invention.

Figure 11 is the side schematic view of the Self-generating remote controller of above preferred embodiment according to the present invention.

Figure 12 is the operation chart of the Self-generating remote controller of above preferred embodiment according to the present invention.

Key is disclosed in Figure 13 to be pressed and produce during being released electric energy twice.

Figure 14 A is the structural schematic diagram of the controller of the Self-generating remote controller of above preferred embodiment according to the present invention.

Figure 14 B is the logical flow chart in the Self-generating remote controller of above preferred embodiment according to the present invention.

Figure 15 show radio transmitter system composition figure in the Self-generating remote controller of above preferred embodiment of the invention.

Figure 16 is the explosive decomposition schematic diagram of a Self-generating remote controller according to another embodiment of the present invention.

Figure 17 is the side schematic view of Self-generating remote controller according to the abovementioned embodiments of the present invention.

Figure 18 is the operation chart of Self-generating remote controller according to the abovementioned embodiments of the present invention.

Specific embodiment

It is described below for disclosing the present invention so that those skilled in the art can be realized the present invention.Preferred embodiment in being described below is only used as illustrating, it may occur to persons skilled in the art that other obvious modifications.The basic principle of the invention defined in the following description can be applied to other embodiments, deformation scheme, improvement project, equivalent program and the other technologies scheme without departing from the spirit and scope of the present invention.

It will be understood by those skilled in the art that, in exposure of the invention, term " longitudinal direction ", " transverse direction ", "upper", "lower", " preceding ", " rear ", " left side ", " right side ", "vertical", "horizontal", "top", "bottom" "inner", the orientation or positional relationship of the instructions such as "outside" is to be based on the orientation or positional relationship shown in the drawings, it is merely for convenience of description of the present invention and simplification of the description, rather than the device or element of indication or suggestion meaning must have a particular orientation, it is constructed and operated in a specific orientation, therefore above-mentioned term is not considered as limiting the invention.

It is worth mentioning that, term " one " should be understood " at least one " or " one or more ", i.e. in one embodiment, the quantity of one element can be one, and in a further embodiment, the quantity of the element can be to be multiple, and therefore, term " one " should not be understood as the limitation to quantity.

As Figure 1A to Figure 15 show a preferred embodiment of a Self-generating remote controller of the invention.Specifically, the Self-generating remote controller includes a shell 10, a key device 20, a controller 30 and a kinetic-energy power generator 40.The shell 10 includes a cloth key lid 11 and a driving lid 12.The cloth key lid 11 and the driving lid 12 can be arranged in the opposite sides of the shell 10, such as upper cover and lower cover respectively as the shell 10；Or the driving lid 12 is located at the side of the cloth key lid 11, the upside that such as cloth key lid 11 is located at the shell 10, and the driving lid 12 is located at a certain side of the shell 10.

In this embodiment in accordance with the invention, the driving lid 12 can be used as the lower cover of the Self-generating remote controller, and an accommodating chamber 13 is collectively formed in the cloth key lid 11 as upper cover, and the key device 20 includes One or more keys 21, it can cooperate to complete command information acquisition with the controller 30, the kinetic-energy power generator 40 can generate an at least induced current under the driving effect of the driving lid 12, to supply the controller 30 to which the controller 30 can launch an at least remote signal under electric energy supply.In this embodiment, the controller 30 and the kinetic-energy power generator 40 are all set in the accommodating chamber 13.

More specifically, the controller 30 is the circuit board arrangement for integrating multiple circuit modules comprising one or more key electrodes 31, a coding module 32, a wireless signal emission source 33 and a shaping circuit 34.The ammonium key instruction for corresponding to a certain key electrode 31 is sent to the electric appliance for needing to be remotely controlled via the wireless signal emission source 33 for the coding module 32 after the shaping circuit 34 by the induced current that wherein kinetic-energy power generator 40 generates.

Multiple keys 21 that the key device 20 includes can be independent of each other multiple keys 21, or in this embodiment in accordance with the invention, the key device 20 further includes a finger-board 22, it is integrally formed with multiple keys 21, so that the key device 20 of the invention can form the key board of an entirety.Each key 21 includes a press section and the conductive part for being set to the press section, as described in interior be embedded in press section or coated on the press section surface.The press section can be made with flexible material, if silica gel material is made, to guarantee the comfort level of operator's pressing.The conductive part is used to be connected the battery plate 31 of the corresponding controller 30, so as to be suitable conductive material such as conductive rubber material.The cloth key lid 11 has multiple key slots 111 to match with each key 21 press section in top surface.

The key device 20 fits in the cloth key lid 11, it is protruded from the corresponding key slot 11 press section of each key 21, push action is carried out convenient for operator, it is also possible to multiple keys 21 to protrude from the same key slot 11, certain each key 21 can not also be from 11 convexity of key slot, the cloth key lid 11 as described in flushing substantially with the surface of the cloth key lid 11 and be embedded in.The contact point of the conductive part of each key 21 is set to the back side of the press section, and matches relatively with the corresponding key electrode 31 on the controller 30, convenient for conduction.That is, when operator presses the press section of each key 21, the key of the conductive part and the controller 30 corresponds to the matching of key electrode 31 contact and is connected, when operator unclamps the silica gel portion 211, the key 21 being pressed restores initial position, that is, the conductive part is not in contact with the correspondence key electrode 31 when just beginning and end pressing.When the key 21 is pressed, corresponding key electrode 31 contacts conduction on the conductive part and the controller 30 of the key 21, the coding module 32 issues and the corresponding control instruction of the key 21, and the wireless signal emission source 33 receives the corresponding control that the coding module 32 issues System instruction, issues remote signal, to control a remote appliance.It is understood that the structure of above-mentioned key device 20 is only used as citing without limiting the present invention, as long as being constructed to be permeable to be pressed and cooperate the acquisition function of completing command information with the controller 30.

It can be understood that, the wireless signal emission source 33 can be the various radio transmitters or device that can be realized wireless signal transmitting, such as the high frequencies radio transmitter such as amplitude shift keying circuit (ASK), FS keying circuit (FSK), phase-shift keying (PSK) circuit (PSK), it can be RFID radio-frequency module, it can be mobile communication module, it can be the wireless communication modules such as bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module, or can be infrared transmission module such as infrared-emitting diode.As long as the i.e. described wireless signal emission source 33 can be realized the emission function of wireless remote control signals, the present invention is not so limited in this respect.

It is noted that in this embodiment in accordance with the invention, as an example with infrared ray radiation pattern.It is i.e. of the invention to propose a kind of passive and wireless remote controler of infrared remote control initiatively, the structure of the remote controler of the invention can adapt to the multikey arrangement of IR remote controller, such as the remote control applications of the invention to television set control when, these keys 21 are corresponding, and connect is to complete power switch, channel increase and decrease selection, the selection of volume plus-minus, numeral input, the circuit for showing the control instructions such as menu.Such as the remote control applications of the invention to air-conditioning control when, these keys 21 are corresponding, and connect is the circuit for completing the control instructions such as power switch, model selection, air force selection, temperature selection.The remote control applications of the invention to intelligent electric appliance system such as smart home system control when, what these keys 21 of the remote controler of the invention can correspond to connection is to complete the power supplys of the household electrical appliances such as different electric appliances such as television set, air-conditioning, sound equipment, intelligent curtain, headlamp to connect and the circuit of control.

The shell 10 is additionally provided with window 14, the window 14 that such as right edge of certain a side of the cloth key lid 11 as shown in figure 1 also has the corresponding wireless signal emission source 33 for being embodied as infrared-emitting diode, the infrared-emitting diode position is corresponding with the window 14, for emitting infrared remote-controlled signal to remote appliance.

In this embodiment in accordance with the invention, the cloth key lid 11 is used for the arrangement of the key 21, i.e., the press section of each key 21 protrudes from the top surface of the cloth key lid 11, facilitates the pressing key 21 for operator.And the driving lid 12 is used to start the kinetic-energy power generator 40, i.e., the described driving lid 12 can drive the kinetic-energy power generator 40 that mechanical energy is converted to electric energy in depressed operation, to provide electric energy to the controller 30.To, in this embodiment of the invention, the acquisition of key command information and the generation of electric energy are independently carried out, so as to facilitate the remote controler of the invention multiple keys cloth It sets.I.e. in the prior art, while pressing keys, it needs that power generator is driven to generate electricity, to be not easily accomplished mostly strong arrangement, it can only be implemented as arranging the passive and wireless switch of simple switch key in this way, play the function of opening and closing electric appliance, and cannot be as remote controler of the invention, switching function not only may be implemented in it, can also realize above-mentioned diversified distant control function.

As shown in Figures 3 to 12 it is an embodiment of the kinetic-energy power generator 40, discloses one of structure of the kinetic-energy power generator 40, electric energy can be converted by mechanical energy when being driven, to provide electric energy to the controller 30.Such as can be piezoelectric effect generator, induction generator etc..In this implementation, as an example, the kinetic-energy power generator 40 includes a magnetic group 42, a coil 43 and a center pillar 44.The magnetic group 42 includes a permanent magnet 421 and forms two magnetizers 422 and 423 of opposite magnetic pole positioned at 421 two opposite sides of permanent magnet, push up magnetizer 422 and bottom magnetizer 423, and magnetic gap 424 is formed between two magnetizers, one end of the center pillar 44 extends into the magnetic gap 424.The coil 43 is arranged in around the center pillar 44, and the coil 43 is electrically connected to the controller 30, the wherein center pillar 44, it may be embodied to magnetizer such as iron core, and it can alternately contact two magnetizers 422 and 423, to make the magnetic induction line direction across the coil 43 change, so as to generate induced current in the coil 43, to which the kinetic-energy power generator 40 can provide electric energy for the controller 30, and the coding module 32 and the wireless signal emission source 33 is supplied to carry out the operation of signal transmitting under the power supply shaping operation of the shaping circuit 34 through the controller 30.

It is understood that the magnetic group 42 is fixed, and the center pillar 44 can be driven and go alternately to contact two magnetizers 422 and 423.Or the center pillar 44 is fixed, the magnetic group 42 is mobile by driving and contacts two magnetizers 422 and 423 with the center pillar 44 respectively, to make to generate the induced current in the coil 43 being arranged in around the center pillar 44.The coil 43 can be directly sleeved on the center pillar 44, be also possible to the coil 43 and be sheathed on a coil rack, the coil rack is sheathed on the center pillar 44 again.

In this preferred embodiment of the invention, the kinetic-energy power generator further includes a magnetic conduction cavity 41.The coil 43 is set in the magnetic conduction chamber 410 that the magnetic conduction cavity 41 is formed, and the magnetic group 42 carries out shift reciprocately in the one side of the magnetic conduction cavity 41, to convert electric energy for mechanical kinetic energy.More specifically, the magnetic conduction cavity 41 may be embodied as a magnetic conductive shell, the center pillar 44 is located in the magnetic conductive shell, the center pillar 12 includes permeability magnetic material with the magnetic conductive shell and mutually assembles or be integrally formed, to improve magnetic conduction efficiency, the coil 43 is set to the inside of the magnetic conductive shell, i.e., in the described magnetic conduction chamber 410, and is surrounded on the center pillar 44.The magnetic conductive shell in addition to have one side have one opening 411 other than, other sides such as other Four sides or five sides can shield for permeability magnetic material.That is, the magnetic conduction cavity 41 forms the magnetic conduction container of relative closure, the coil 43 is accommodated in the magnetic conduction container, and the opening 411 is embodied as magnetic group sealing.In this way, the coil 30 is completely covered by magnetic induction line, to reduce the leakage field of entire magnetic circuit system when the magnetic group 20 is used to seal the opening 411.In other words, in this embodiment, the magnetic conduction cavity 41 forms the closed magnetic conduction cavity of relative closure, to reduce leakage field.

The magnetic group 42 includes the permanent magnet 421, the top magnetizer 422 and the bottom magnetizer 423, and the permanent magnet 421 is set between the top magnetizer 422 and the bottom magnetizer 423.The inside that the magnetic conduction chamber 410 is respectively placed in one end of the top magnetizer 422 and the bottom magnetizer 423, and the top magnetizer 422 and the bottom magnetizer 423 respectively have the part protruded relative to the permanent magnet 421, and the magnetic gap 424 is formed between the part of protrusion, the outboard end of the center pillar 44 extends into the magnetic gap 424.Width between the top magnetizer 422 and the bottom magnetizer 423 is magnetic gap width.It is understood that the top magnetizer 422 and each own permeability magnetic material of the bottom magnetizer 423 is made or surface is coated with permeability magnetic material.The permanent magnet 421 is made of permanent-magnet materials, such as magnet, Al-Ni-Co series permanent-magnet alloy, siderochrome cobalt system permanent-magnet alloy, permanent-magnet ferrite, rare earth permanent-magnetic material and composite permanent-magnetic material.It is worth mentioning that, in the operation that the kinetic-energy power generator 40 produces electricl energy, when the center pillar alternately contacts the top magnetizer 422 and the bottom magnetizer 423, the top magnetizer 422 and the bottom magnetizer 423 can also be alternately with the top edge of the magnetic conductive shell 411 and bottom along conflicts, the direction of the magnetic induction line across the coil 43 is set to change, to generate induced current in the coil 43.Of course, it should be understood that in a further embodiment, the top magnetizer 422 and the bottom magnetizer 423 can also respectively be not positioned in the end of the inside of the magnetic conduction chamber 410, i.e., do not extend into the inside of the magnetic conduction chamber 410.

It is understood that the kinetic-energy power generator of the invention can be the various devices that can convert mechanical energy to kinetic energy.In this preferred embodiment that the present invention enumerates, the coil 43 is placed in the inside of the magnetic conduction chamber 411, side has the magnetic group 42 to close, the coil 43 is able to be covered by magnetic induction line, leakage field is minimum in this way, therefore the energy generated is much higher compared to common kinetic-energy power generator, so the embodiment of the present invention kinetic-energy power generator has higher generating efficiency.

More specifically, the magnetic conduction cavity 41 may include a top shell 412, two flanks 413 and a bottom case 414, can mutually assemble or integrally formed.Two flanks 413 respectively extend from the two sides of the top shell 412, the bottom case 414 is connected to two flanks 413, and 414 one end of the bottom case of the magnetic conduction cavity 41 extends outward to form a bottom along 4141, and the other end extends to form the center pillar 44 upwardly and outwardly, that is The center pillar 44 extends one end of the bottom case 414, and parallel with the bottom case 414 opposite, and there are gaps between two flanks 413 of the magnetic conduction cavity 41, so that the coil 43 is sheathed on the center pillar 44.Of course, it should be understood that the center pillar 44 can be assembled in the magnetic conduction cavity 41, can also otherwise be integrally formed in the magnetic conduction cavity 41, the present invention is not so limited in this respect.

In this embodiment in accordance with the invention, the magnetic conduction cavity 41 can the magnetic group 42 so that the center pillar 44 in the magnetic conduction cavity 41 and the magnetic group 42 is generated relative displacement by driving.The magnetic conduction cavity 41 can be fixedly connected with 30 phase of controller, or be fixedly connected with the shell 10, the cloth key lid 11 as described in being fixed on.

One end of the top magnetizer 422 extends outward to form a top magnetizer abutment end 4221, one end of the bottom magnetizer 423 extends outward to form a bottom magnetizer abutment end 4231, and the top magnetizer abutment end 4221 and the bottom magnetizer abutment end 4231 can be placed in the inside of the magnetic conduction chamber 410.Width between the top magnetizer abutment end 4221 and the bottom magnetizer abutment end 4231 is magnetic gap width.Under the effect of external force, the top magnetizer abutment end 4221 and the bottom magnetizer abutment end 4231 are alternately contacted with the top edge 4121 of the magnetic conduction cavity 41 and the bottom along 4141, the center pillar 44 is alternately contacted with the bottom magnetizer abutment end 4231 and the top magnetizer abutment end 4221, the direction of the magnetic induction line across the coil 43 is set to change, to generate induced current in the coil 43.

It is understood that the magnetic conduction cavity 41 and the magnetic group 42 generate relative displacement, so that the kinetic-energy power generator 40 be made to generate the induced current.Those skilled in the art it is expected that, it is fixed to can be the magnetic conduction cavity 41, the magnetic group 42 generates relative displacement by driving, or the magnetic group 42 is fixed, the magnetic conduction cavity 41 is driven and the center pillar 44 is driven to generate relative displacement, to make the center pillar 44 alternately contact the bottom magnetizer abutment end 4231 and the top magnetizer abutment end 4221, so that the coil 43 be made to generate the induced current.

Further, in order to make the kinetic-energy power generator 40 be easier to realize the displacement of the relatively described magnetic conduction cavity 41 of the magnetic group 42 by applying external force, the kinetic-energy power generator 40 further includes a driving arm 45, and the magnetic group 42 is set in the driving arm 45.In example shown in the figure, the magnetic group 42 can be swung up and down, and stroke is determined (such as may be embodied as 0.5mm, but the present invention is not limited thereto) by magnetic gap width.That is, the fixed magnetic group 42 of the driving arm 45, makes the magnetic group 42 replace abutting along 4141 with the top edge 4121, the center pillar 44, the bottom respectively within the scope of magnetic gap.In addition, the driving arm 45 is also used to hold and consolidate the magnetic group 42.The driving arm 45 pivotly cooperates with the magnetic conduction cavity 41, so that the driving arm 45 can be driven and drive the magnetic group 42 opposite Displacement is generated in the center pillar 44 in the magnetic conduction cavity 41.Certainly in other embodiments, it is also possible to the driving arm 45 and is fixed, and the magnetic conduction cavity 41 is generated displacement by driving.

More specifically, the kinetic-energy power generator 40 further includes a driving element 46, it is connected to the driving arm 45, when external force is when the driving element 46, the driving arm 45 can be driven.The driving arm 45 includes a rest body 451, a magnetic group fixed arm group 452 and a swing arm group 453.The driving element 46 is connected to the rest body 451 of the driving arm 45, it is preferable that the driving element 46 can be integral with 45 integrated injection molding of driving arm.Specifically, the driving element 46 may be embodied as elastic slice in this embodiment, and elastic construction can rapidly make the driving arm generate displacement.That is, the elastic slice is connected to the rest body 451 in the present embodiment.The elastic slice 41 is also used to increase potential energy, accelerates the movement velocity of the magnetic group 42 of the kinetic-energy power generator 40.

The both ends of the rest body 451 of the magnetic group fixed arm group 452 from U-shaped respectively extend internally and and the rest body 451 one magnetic group fixing groove 454 of formation.The top magnetizer 422, the bottom magnetizer 423 of the magnetic group 42 are set in the magnetic group fixing groove 454 after mutually assembling with the permanent magnet 421, and the magnetic group fixing groove 454 has aperture 455 towards the center pillar 44 in the magnetic conduction cavity 41, is extended into the magnetic gap 44 of the magnetic group 42 for the center pillar 44.It is worth mentioning that, each magnetic group fixed arm group 452 is further convexly equipped with an abutment end dowel 4521, for consolidating the top magnetic conduction abutment end 4221 of the top magnetizer 422 and the bottom magnetic conduction abutment end 4231 of the bottom magnetizer 423 respectively, the magnetic group 42 is enable more securely to be set in the magnetic group fixing groove 454.It is understood that the driving arm 45 can have other to be capable of forming fixing groove to fix the structure of the magnetic group 42.

The swing arm group 453 further extends outwardly from each rest body 451 and has a rotation axis 4531 on the inside of each comfortable end, and correspondingly, the flank 413 of two of the magnetic conduction cavity 41 is respectively provided with a rotary axis groove 4131.Each rotation axis 4531 is positioned in corresponding each rotary axis groove 4131, to make the driving arm 45 swing around the rotation axis 4531, so that the driving arm 45 drives the magnetic group 42 to replace abutting along 4141 and the center pillar 44 with the top edge 4121 of the magnetic conduction cavity 41, the bottom.It is understood that the rotation axis 4531 and the rotary axis groove 4131 can also be separately positioned on the flank 413 of the magnetic conduction cavity 41 and the swing arm group 453 of the driving arm 45.It will be appreciated by persons skilled in the art that the structure that driving arm 45 described above and the magnetic conduction cavity 41 are pivotly cooperatively connected also is only used as illustrating and being not intended to limit the present invention.

In this embodiment in accordance with the invention, the coil 43 is set in the magnetic conduction chamber 410 of the magnetic conduction cavity 41 and is sleeved on the center pillar 512, and the magnetic group 42 is set to described by the driving arm 45 In magnetic group fixing groove 454, the driving element 46 is connected to the driving arm 45, the change in displacement that the magnetic group 42 can be made to be swung to the swing of the driving element, to generate induced current in the coil 43, and then the kinetic-energy power generator 40 provides the power source of electric power for the Self-generating remote controller.

The kinetic-energy power generator 40 further includes a reset element 47, when the driving element 46 drives the driving arm 45 and the magnetic group 42 is driven to be displaced, the reset element 47 puts aside potential energy, and when the external force for being applied to the driving element 46 disappears or is reduced to predefined size, the reset element 47 can make the driving element 46 be back to initial position, to which the magnetic group 42 returns to initial position, the center pillar 44 alternately contacts the top magnetizer 422 and the bottom magnetizer 423 again, so as to generate another secondary induced current again.In this embodiment i.e. of the invention, a circulate operation can produce induced current twice.

In this embodiment, it is described from generating apparatus 40 between the driving lid 12 and the controller 30, described 47 one end of reset element is connected to the driving element 46, the other end is fixed on the controller 30, or the other end is fixed on the shell 10, the inner surface of cloth key lid 11 as described in being fixed on.The reset element 47 may be embodied as it is various can put aside potential energy in stress, the element that stress revocation or while reducing automatically reset, such as elastic slice, compressed spring, torsional spring.

41 top side of magnetic conduction cavity can also further include two pins 415, the both ends of the coil 43 can be respectively positioned in the pin 415, and it further reconnects in the shaping circuit 34 of the controller 30, the electric energy that the kinetic-energy power generator 40 described in this way generates is able to be supplied to the controller 30.

In this embodiment of the invention, the driving lid 12 is Multidirectional motion, can be swung slightly with top to bottom, left and right, front and rear, stroke about 1.5mm or more fractional value.Specifically, the driving lid 12 includes a driving lid main body 121, and one touch element 122, its inner surface for being set to the driving lid main body 121 raisedly, for compressing the driving element 46 to drive the magnetic group 42, the driving lid 12 further includes multiple hooks 123, such as four hooks 123 of four sides, it is slideably engaged with the cloth key lid 11, for fixed and position-limiting action.Sliding slot 112 as being formed with corresponding number on the inside of the cloth key lid 11, the hook 123 are slidably disposed in the sliding slot 112.It is understood that the hook 123 also can be set in the cloth key lid 11, and the sliding slot 112 is set to the driving lid 12.The sliding slot 112 also can be set in the outer surface of the cloth key lid 11, it is different from the inside that driving lid 12 shown in Figure 11 and 12 is located at the cloth key lid 11, the driving lid 12 can also be located at the outside of the cloth key lid 11, so that the driving lid 12 is in the activity of the outside of the cloth key lid 11.

In addition, it is noted that as shown in figure 11, the driving is withstood on the vertex of the reset element 47 Element 46, makes the magnetic group 42 be in the initialized location in Figure 10 A, and the reset element 47 makes four hooks 123 of the driving lid 12 catch on four sliding slots 112 of the cloth key lid 10 simultaneously, the driving lid 12 is made to be located at original state.That is, the sliding slot 112 correspondingly limits the hook 123, so that the driving lid 12 will not fall off with the cloth key lid 10, and relative displacement can flexibly occur.

The activation member of the generating operation of the Self-generating remote controller, that is, driving element 46 (implementable is an elastic slice) is pushed by being arranged in the driving lid (implementable is a lower cover) of the bottom surface of the Self-generating remote controller.Passive and wireless switch in the prior art, key should press movement, also go to contradict conductive rubber, movement is complicated, cannot arrange more key.And the Self-generating remote controller of the invention separates two parts, that is to say, that motion parts, that is, driving lid 12 is separated with the two-part function of key information collecting part, that is, key device 20, is not interfere with each other, and is worked independently, while being operated coherent.It is noted that the driving lid 12 can also be set as a part of lower cover, such as only corresponding key area size.

It is as shown in figs. 10 a and 10b the electricity generating principle schematic diagram of the kinetic-energy power generator 40.Wherein the dotted line with arrow in figure is expressed as the direction of magnetic induction line.Original state to assume as shown in Figure 10 A, in the initial state, the bottom magnetizer abutment end 4231 for the bottom magnetizer 423 that the top magnetizer abutment end 4221 of the top magnetizer 422 of the pole the N connection of the permanent magnet 421 is abutted against with the center pillar 44, while being connect with the pole S of the permanent magnet 421 is abutted against with the bottom along 4141.Magnetic induction line is stable state at this time, without generating induced current in the coil 43.As shown in Figure 10 B, if the driving element 45 is driven by the driving lid 12 and makes to move up the magnetic group 42, make to abut against with the top magnetizer abutment end 4221 with the top edge 4121.The bottom magnetizer abutment end 4231 connecting simultaneously with the pole S of the permanent magnet 421 is abutted against with the center pillar 44.It will be appreciated by persons skilled in the art that the orientation of the above-mentioned pole N and the pole S arrangement is also only used as illustrating and being not intended to limit the present invention.In mobile process, direction across the magnetic induction line of the coil 43 is changed, quickly variation makes the coil 43 generate induced current for this, and the size of electric current and the speed that the magnetic group 42 is displaced, the parameters such as circle number, the magnetic permeability of permeability magnetic material, leakage field rate, magnetic saturation intensity of the coil 43 are directly related.

The calculation formula of induced electromotive force is as follows:

E=-n* ΔΦ/Δ t

In formula: E is induced electromotive force, and n is the number of turns of coil, and ΔΦ/Δ t is the change rate of magnetic flux.

In turn, the kinetic-energy power generator 40 provides the power source of electric power for the Self-generating remote controller.In addition, under the reset response of the reset element 47, the magnetic group 42 is back to the position of Figure 10 A from the position of Figure 10 B, to pass through the line when the external force for being applied to the driving lid 12 disappears or is decreased to predefined size The direction of the magnetic induction line of circle 43 is changed again, and quickly variation makes the coil 43 generate induced current again for this.

Disclose the process that an operator operates the Self-generating remote controller as shown in figure 12:

The key 21 is pressed, makes the conductive part (being embodied as conductive rubber) that the corresponding key electrode 31 of the controller 30 is connected, that the pressing force f that the key 21 needs is numerically about F1=0.2N.

The touch element 122 of the driving lid 12 is supported by the reset element 47, and when pressing needs the power of F2=2-3N, wherein F1 < F2.

Operator begins to use remote controler, and due to holding the effect of power, the thumb of operator presses the key 21 in Figure 12, pushes the driving lid 12 in remaining four direction centre of the palm；When certain practical operation, other modes can also be taken according to the habit of operator, the key 21 as described in index finger pressing, other fingers are used to push the driving lid 12.

When f is greater than 0.2N, the stroke of the key 21 reaches terminal, the key electrode 31 on the controller 30 is connected in advance, but at this time, the controller 30 is electric not yet, and it is to carry out corresponding instruction preparation for the transmitting after will being powered that the key electrode 31 is connected in advance；Each key 21 has different instructions, this instruction is generated by the encoder in the coding module 32.

When being applied to the power of touch element 122 of the driving lid 12 greater than 3N, driving 12 distalmost end of lid can sink into about 1.5mm, and (this embodiment of the invention is by taking 1.5mm as an example, but it is not limited thereto), the touch element 122 withstands 46 stroke of driving element and reaches 0.75mm.

The driving element 46 drives the magnetic group 42 mobile, and the displacement of the magnetic group 42 causes the center pillar 44 alternately to contact the top magnetizer 422 and the bottom magnetizer 423 of the magnetic group 42, to generate induced current in the coil 43.

It is about 2V, the direct current energy that the duration is about 10ms that the electric current that the coil 43 generates can provide voltage after the shaping circuit 34 of the controller 30 for coding circuit.

At this point, circuit part obtains electric energy, start to work, the encoder of the coding module 32 can be by the instruction issue remote signal of the key electrode 31 corresponding at the key 21 pressed in advance.

Within the time of 10ms, wireless signal battery has fired, at this time, the Overstroke that the driving lid 12 inwardly moves, the hand of operator still keeps grip, thus the state of the magnetic group 42 keeps temporarily static, the electric energy of inducting previously generated is also exhausted, and circuit is in power failure state again.

If under the thrust of the reset element 47, the driving lid 12 starts to reset towards the outside of the Self-generating remote controller, and the touch element 122 is with described at this point, the hand for holding the Self-generating remote controller is unclamped Lid 12 is driven to retreat.

The reset element 47 pushes the driving element 45 and the element 122 that touches to reset towards the outside of the Self-generating remote controller, the magnetic group 42 is caused to be returned to original initial position (Figure 10 A), therefore, an induced current can be generated again in the coil 43.

The induced current generated again can make circuit work on power 10ms again, and launch corresponding signal (such as unclamping signal) instruction.

It presses signal of transmitting, unclamp signal of transmitting, signal twice can be emitted in total by one-touch.Remote controlled electric appliance can be designed as a reception first time signal and be carried out corresponding control operation, or only receives second of signal and control operation to execute to correspond to, or signal is all received to execute corresponding control and operate twice.

It is worth mentioning that, the F1 and F2 are defined as characteristic value, F1 is the smallest force value needed for making conductive rubber that controller key electrode be connected, F2 is then that the touch element 122 presses the driving element 46 the magnetic group 42 is made to abut required minimum force value, and F2 > F1 with the center pillar 44 in the magnetic conduction cavity 41.Therefore, in unclamping step, because of characteristic value F2 > F1, when f is decreased under F2 but is greater than F1 in release process, the driving lid 12 is retreated but key does not unclamp, and corresponding key electrode still can be at pre-on state.In addition, it is necessary to, it is noted that aforesaid operations during occur design parameter numerical value be all only used as illustrate and be not intended to limit the present invention, can according to need and designed, designed in practical applications.

In addition, being directed to the button operation of the key 21 of the key device 20 and being independent two kinds of operations for the pressing operation of the driving lid 12, can carry out simultaneously；It is also possible to the button operation for the key 21 of the key device 20 preceding, and then carries out the pressing operation for the driving lid 12；It is also possible to, for the driving lid 12 pressing operation preceding, then carry out the button operation of the key 21 for the key device 20, then unclamp again the driving lid 12, second of induced current can be generated when unclamping the driving lid 12, to emit wireless control signal.

In this preferred embodiment of the invention, the any position of the outer surface of the driving lid 12 can be pressed, as long as hand is by any position of driving 12 outer surface of lid, the touch element 122 can be made to contradict the driving element 46 to be subjected to displacement, the displacement of the driving element 46 will drive the magnetic group 42 and be subjected to displacement, and then the polarity for passing through the magnetic induction line of the coil 43 changes, to generate induced current in the coil 43.

It is noted that as shown in figure 13, signal can be realized critical function, such as stepless-adjustment volume, brightness continuous variable twice for transmitting.

More specifically, transmitting is once just much of that for general demand for control, and it is primary by primary hair, it is complete It is complete to be not necessarily to send out again when bouncing reset once.But, there is such situation in the remote control operation of daily electric appliance, such as to projects such as the adjustment of adjustment, brightness of tv volume, if for traditional remote controler with battery, it does not loose one's grip as long as pressing & hold, just ceaselessly firing order, volume will gradually change remote controler, this is a lasting variable quantity；The remote controler of self power generation can only just have in a flash electric energy what is pressed, by an once signal of hair, if little by little by primary key volume change, if the range of adjustment is relatively more, ceaselessly key, hand can be relatively more tired.Therefore the continuous key-press transmitting of traditional remote controller is simulated, by the time difference of twice emitting to realize stepless changing volume and brightness.

That is, it is noted that the time difference in such as Figure 13 using twice emitting, stepless changing volume may be implemented and brightness needs continuously adjustable variable to operate.

Further, in general button operation, it presses the button and does not exceed 1s clock with the time for unclamping key, as TV remote controller is in channel selection operation, it is usually all to press just to unclamp, process is usually in 0.2-0.5s, if pressing the button the time is more than not loose one's grip still for 1 second, it is to operate continuously that the MCU of so receiving end, which is considered as user, carry out the program of continuous variable adjustment, such as: when adjustment volume becomes larger, if pinning the volume button time is more than 1s, at this time, receiving end has received instruction when pressing, still the instruction of release is not received after waiting one second, in this way, MCU (Microcontroller Unit, micro-control unit) continuously volume will be increased, this location of instruction is unclamped until receiving key, thereby realize passive wireless technologies Under continuous variable adjustment control.Wherein, logic chart is as shown in Figure 14B.

It is as shown in figure 15 radio transmitter system composition figure.When the key 21 is pressed, the key 21 is contacted in corresponding key electrode 31, the electric current that the coil 43 of the kinetic-energy power generator 40 generates can provide direct current energy after power supply shaping circuit for coding circuit, to which the circuit part of the controller 30 obtains electric energy, the coding module 32 issues wireless control directives corresponding with the key 21 and emits corresponding remote signal such as infrared radio signal by the wireless signal emission source 33, to control a remote appliance.

Therefore, by taking infrared signal emits as an example, the infrared radio signal emission process of Self-generating remote controller of the invention is as follows: the corresponding key electrode 31 of a controller is connected by a pressing, a conductive part of the key 21 in an at least key 21 for the Self-generating remote controller；A salient point (the touch element 122) for one driving lid 12 of the Self-generating remote controller is depressed；The reset spring (reset element 47) of the salient point is supported to drive an elastic slice (driving element 46), the elastic slice drives the magnetic group 42 of the kinetic-energy power generator mobile, and the displacement of the magnetic group 42 causes to generate induced current in the coil 43；The electric current that the coil 43 generates is that the coding module 32 provides direct current energy after the shaping circuit 34 of the controller； The encoder of the coding module 32 can will issue corresponding instruction according to the corresponding key electrode being switched on；One infrared-emitting diode (the wireless signal emission source 33) receives instruction and emits the remote signal of infrared waves；The state of the magnetic group 42 keeps temporarily static, and the power consumption of inducting previously generated finishes, and circuit is in power failure state again；When the driving lid 12 is released, the reset spring pushes the elastic slice and the salient point to reset；The magnetic group 42 is driven by the elastic slice occurs relative displacement, generates induced current again in the coil 43；The electric current that the coil 43 generates is supplied to the controller；The coding module of the controller emits the remote signal of infrared waves via the infrared-emitting diode again.

Furthermore, continuous variable signal control method of the invention, it has the one of the Self-generating remote controller and a remote control electrical appliance of a remote controler part, that is, of the invention to receive processor part, and the continuous variable signal control process is as follows: an at least key 21 for the remote controler is depressed；The circuit of the key command of the corresponding key 21 of the coding module 32 of the controller 30 of the remote controler is in an ON state；The driving lid 12 of the remote controler is depressed and triggers the kinetic-energy power generator 40 and produces electricl energy；The controller 30 of the remote controler carries out coded excitation infrared signal according to corresponding key command under power supply；The reception processor part receives decoding；The reception processor part judges whether to receive within the set time to instruct twice, and if receiving instruction twice, continuous key-press processing is done in the reception processor part, to realize the control of continuous variable signal.It is understood that the reception processor part can instruct twice according to not receiving in above-mentioned setting time and judge to do single keys presses processing.

It is worth mentioning that, in this preferred embodiment of the invention, signal emitting-source in the Self-generating remote controller is for convenience of description, it is to illustrate using for infrared emission mode, but it will be appreciated by those skilled in the art that be, the signal emitting-source in the present invention is not limited to infrared emission mode, can also be that other reasonable embodiments such as bluetooth, WIFI, the present invention are not limited thereto.

Correspondingly, the present invention provides a kind of wireless signal transmitting methods of Self-generating remote controller, it includes the following steps: that, in response to a button operation and other independent power generation pressing operation, a wireless control signal of the corresponding button operation is simultaneously launched in the Self-generating remote controller self power generation.

More specifically, for example in the present invention, the wireless signal transmitting method further includes following steps:

In the button operation: when an at least key 21 for the key device 20 is pressed, the control instruction circuit of the corresponding key 21 of the controller 30 is switched on；

In the power generation pressing operation: when the driving lid 12 is pressed, the kinetic-energy power generator 40, which is driven, converts electric energy for mechanical energy；And

The controller 30 emits the corresponding key 21 under the electric energy supply that the kinetic-energy power generator provides Wireless control signal.

It is understood that the button operation refers to the various operations for completing key command information collection by key.The power generation pressing operation can be drives the kinetic-energy power generator 40 that the kinetic-energy power generator 40 is made to execute the operation of spontaneous electrical function independently of other any can be realized except the button operation, is not limited solely to the embodiment enumerated of the invention.

Correspondingly, in the button operation, the key 21 being pressed connects the correspondence key electrode 31 of the controller 30 into circuit, and the coding module 32 of the controller 30 is preset with the coded command of the corresponding key electrode 31.

In the power generation pressing operation, under the driving effect of the driving lid 12, the center pillar 44 of the kinetic-energy power generator 40 is caused alternately to contact the top magnetizer 422 and the bottom magnetizer 423 of the magnetic group 42, the coil 42 being arranged in around the center pillar 44 generates an induced current.Correspondingly, when the driving lid 12 is pressed, it will lead to the magnetic group 42 and moved by driving, the center pillar 44 can also be caused mobile.

More specifically, in this specific example of the invention, the touch element 122 of the driving lid 12 compresses the driving element 46, the driving element 46 drives the driving arm 45 mobile, the magnetic group 42 correspondingly moves, and the center pillar 44 described so alternately contacts the bottom magnetizer 423 and the top magnetizer 422 of the magnetic group 42.

In addition, when the touch element 122 of the driving lid 12 compresses the driving element 46, the reset element 47 generates elastic deformation, and during subsequent driving lid 12 unclamped and be pressed, when i.e. pressing force reduces, the reset element 47 is restored from elastic deformation state to original state, to make the center pillar 44 alternately contact the top magnetizer 422 and the bottom magnetizer 423 of the magnetic group 42 again, to generate second of induced current.

In wireless signal step of transmitting, the induced current that the kinetic-energy power generator 40 generates supplies the coding module 32 after the power supply shaping operation of the shaping circuit 34 of the controller 30, and the wireless signal emission source 33 for being connected to the coding module 32 issues the wireless control signal.

It is noted that, if the key 21 being pressed still maintains when being pressed, and when the driving lid 12 is released, the Self-generating remote controller can issue the wireless control signal twice when the kinetic-energy power generator 40 is in reset process.So as to realize that the continuous variable control operation of the Self-generating remote controller, or the electric appliance for being remotely controlled can be programmed to selection and receive any wireless control signal and execute corresponding operation.Certainly, some key 21 of long-pressing is kept, and is issued described twice wireless When controlling signal, the electric appliance being remotely controlled can be programmed to it is corresponding execute certain specific operations, such as the key that long-pressing corresponding power switchs, into the operation etc. of parameter setting.When the kinetic-energy power generator 40 is in reset process, when the key 21 being pressed is fully released, the Self-generating remote controller can not have to issue the wireless control signal again, and the electric appliance being remotely controlled can be programmed to selection and receive the wireless control signal issued when first time generating operation and execute corresponding operation.

In addition, the present invention provides a kind of self-power generation methods of Self-generating remote controller comprising following steps:

When the driving lid 12 is pressed, the driving lid 12 makes the magnetic group 42 and the center pillar 44 and the magnetic group 42 generation relative displacement in the magnetic conduction cavity 41, the center pillar 44 is set alternately to contact the top magnetizer 422 and the bottom magnetizer 423 of the magnetic group 42, to make to generate induced current in the coil 43 being arranged in around the center pillar 44.Wherein in this embodiment in accordance with the invention, the coil 43 and the center pillar 44 are located in the magnetic conduction cavity 41, the coil 30 is completely covered by magnetic induction line, to reduce the leakage field of entire magnetic circuit system, the generating efficiency of the kinetic-energy power generator 40 of the entire Self-generating remote controller is improved.

When the driving lid 12 is no longer pressed, the reset response of the reset element 47, the center pillar 44 is set alternately to contact the bottom magnetizer 423 and the top magnetizer 422 of the magnetic group 42, to make to generate another secondary induced current in the coil 43 being arranged in around the center pillar 44.

It can be understood that, in example shown in the present invention, the spontaneous electrical remote control device is configured with a kinetic-energy power generator 40, in practical applications, multiple kinetic-energy power generators 40 can also be configured with, and it is driven and produces electricl energy by the corresponding touch element 122 respectively, and the electric energy generated can be integrated into utilization, to be supplied to the controller 30 for emitting wireless control signal.

As Figure 16 to Figure 18 show another variant embodiment of the Self-generating remote controller of the invention.In this variant embodiment, the Self-generating remote controller can be installed in environmental surfaces.Such as this remote controler of the invention may be mounted at the form on wall, be widely used in the remote control operation of the electric appliances such as air-conditioning, heater, intelligent control panel.

Specifically, as shown in figure 16, the Self-generating remote controller includes a shell 10 ', a key device 20 ', a controller 30 ' and a kinetic-energy power generator 40 '.The shell 10 ' includes pivotly engage each other a cloth key lid 11 ' and a driving lid 12 '.Bottom cover of the driving lid 12 ' as the Self-generating remote controller, an accommodating chamber is collectively formed to accommodate the kinetic-energy power generator 40 ' with the cloth key lid 11 ' as top cover, the key device 20 ' realizes the acquisition of control instruction information with the controller 30 ' cooperation, and the controller 30 ' issues wireless control signal under the supply that the kinetic-energy power generator 40 ' produces electricl energy.

More specifically, the key device 20 ' includes one or more keys 21 ', the cloth key lid 11 ' has multiple key slots 111 ' to match with each key 21 '.When the key device 20 ', which fits in the cloth key lid, 11 ' to be arranged, each key 21 ' protrusion from the corresponding key slot 111 ' protrudes from the top surface of the cloth key lid 11 ', carries out button operation convenient for operator.Similarly, the controller 30 ' further includes one or more key electrodes 31 ', is electrically connected to the coding module 32 ' and above-mentioned wireless signal emission source 33 and above-mentioned shaping circuit 34 of the key electrode 31 '.

Preferably, in this embodiment in accordance with the invention, when the Self-generating remote controller is installed on wall, it is implemented as a high frequency radio transmitter.In this embodiment in accordance with the invention, similarly, the silica gel push-button 21 ' can play the role of turning circuit.That is, the key 21 ' of the key device 20 ' is set to the corresponding position of corresponding with the controller 30 ' the key electrode 31 ', when the top end part stress of the key 21 ', the bottom end of the key 21 ' is in contact with the key electrode 31 ', to which the key electrode 31 ' is short-circuited, the controller 30 ' correspondingly issues radio frequency signal, and then controls a remote appliance with wireless radio frequency mode.

Further, the kinetic-energy power generator 40 ' includes a magnetic group 42 ', a coil 43 ' and a center pillar 44 '.The magnetic group 42 ' includes a permanent magnet 421 ' and two magnetizers 422 ' and 423 ' for being located at the 421 ' two opposite sides of permanent magnet formation opposite magnetic pole, and magnetic gap 424 ' is formed between two magnetizers, one end of the center pillar 44 ' extends into the magnetic gap 424 '.The coil 43 ' is arranged around the center pillar 44 ', and the coil 43 ' is electrically connected to the controller 30 ', wherein the center pillar 44 ' can alternately contact two magnetizers 422 ' and 423 ', to make the magnetic induction line direction across the coil 43 ' change, so as to generate induced current in the coil 43 ', to which the kinetic-energy power generator 40 ' can provide electric energy for the controller 30 ', and the coding module 32 ' and the wireless signal emission source 33 ' is supplied to carry out the operation of signal transmitting under the power supply shaping operation of the shaping circuit 34 ' through the controller 30 '.

In this preferred embodiment of the invention, the kinetic-energy power generator further includes a magnetic conduction cavity 41 '.The coil 43 ' is set in the magnetic conduction chamber 410 ' that the magnetic conduction cavity 41 ' is formed, and the magnetic group 42 ' carries out shift reciprocately in the one side of the magnetic conduction cavity 41 ', to convert electric energy for mechanical kinetic energy.The magnetic conduction cavity 41 ' may be embodied as a magnetic conductive shell, the center pillar 44 ' is located in the magnetic conductive shell, the center pillar 12 ' includes permeability magnetic material with the magnetic conductive shell and mutually assembles or be integrally formed, to improve magnetic conduction efficiency, the coil 43 ' is set to the inside of the magnetic conductive shell, in the i.e. described magnetic conduction chamber 410 ', and it is surrounded on the center pillar 44 '.The coil 30 is completely covered by magnetic induction line, to reduce the leakage field of entire magnetic circuit system.In other words, in this embodiment, the magnetic conduction cavity 41 ' forms the closed magnetic conduction cavity of relative closure, thus Reduce leakage field.

Similarly, the magnetic conduction cavity 41 ' can the magnetic group 42 ' so that the center pillar 44 ' in the magnetic conduction cavity 41 ' and the magnetic group 42 ' is generated relative displacement by driving.The magnetic conduction cavity 41 ' can be mutually fixedly connected with the controller 30 ', or be fixedly connected with the shell 10 ', the cloth key lid 11 ' as described in being fixed on.

Similarly, one end of the top magnetizer 422 ' extends outward to form a top magnetizer abutment end 4221 ', one end of the bottom magnetizer 423 ' extends outward to form a bottom magnetizer abutment end 4231 ', and the top magnetizer abutment end 4221 ' and the bottom magnetizer abutment end 4231 ' can be placed in the inside of the magnetic conduction chamber 410 '.Width between the top magnetizer abutment end 4221 ' and the bottom magnetizer abutment end 4231 ' is magnetic gap width.Under the effect of external force, the top magnetizer abutment end 4221 ' and the bottom magnetizer abutment end 4231 ' are alternately contacted with the top edge of the magnetic conduction cavity 41 ' and bottom edge, the center pillar 44 ' is alternately contacted with the bottom magnetizer abutment end 4231 ' and the top magnetizer abutment end 4221 ', the direction of the magnetic induction line across the coil 43 ' is set to change, to generate induced current in the coil 43 '.

The kinetic-energy power generator 40 ' further includes a driving arm 45 ', and the magnetic group 42 ' is set in the driving arm 45 ', and the driving arm 45 ' is for holding and consolidating the magnetic group 42 '.The driving arm 45 ' pivotly cooperates with the magnetic conduction cavity 41 ', so that the driving arm 45 ' can be driven and the magnetic group 42 ' is driven to generate displacement relative to the center pillar 44 ' in the magnetic conduction cavity 41 '.Certainly in other embodiments, it is also possible to the driving arm 45 ' and is fixed, and the magnetic conduction cavity 41 ' is generated displacement by driving.

The kinetic-energy power generator 40 ' further includes a driving element 46 ', is connected to the driving arm 45 ', and when external force is when the driving element 46 ', the driving arm 45 ' can be driven.Preferably, the driving element 46 ' can be integral with the 45 ' integrated injection molding of driving arm.Specifically, the driving element 46 ' may be embodied as elastic slice in this embodiment, and the elastic slice is also used to increase potential energy, accelerate the movement velocity of the magnetic group 42 ' of the kinetic-energy power generator 40 '.

The kinetic-energy power generator 40 ' further includes a reset element 47 ', when the driving element 46 ' drives the driving arm 45 ' and the magnetic group 42 ' is driven to be displaced, the reset element 47 ' puts aside potential energy, and when the external force for being applied to the driving element 46 ' disappears or is decreased to predefined size, the reset element 47 ' can make the driving element 46 ' be back to initial position, to which the magnetic group 42 ' returns to initial position, the center pillar 44 ' alternately contacts the top magnetizer 422 ' and the bottom magnetizer 423 ' again, so as to generate another secondary induced current again.

In this embodiment of the invention, the driving lid 12 ' is mutually pivotly arranged with the cloth key lid 11 ', to realize unilateral swing.Specifically, as shown in figure 16, it include a driving lid main body 121 ' before the driving lid 12 ', and raised ground is set to the one of the driving 121 ' inner surface of lid main body and touches element 122 ', to be used to compress the driving element 46 ' to drive the magnetic group 42 '.12 ' front and rear sides of the driving lid setting is respectively arranged with card slot 124 ', and the position of the correspondence card slot 124 ' of the cloth key lid 11 ' is provided with axis 113 ', in this way by the cooperation of the card slot 124 ' and the axis 113 ', engage the cloth key lid 11 ' pivotly with the driving lid 12 '.It is understood that the driving lid main body 121 ' in the driving lid 12 ' also can be set in the axis 113 ', and the card slot 124 ' is set to the cloth key lid 11 '.

As shown in the figure, the 12 ' left side of driving lid further includes a hook 123 ', slideably engages with the cloth key lid 11 ', realizes fixed and position-limiting action.If the 11 ' inside of cloth key lid is formed with corresponding one sliding slot 112 ', the hook 123 ' is slidably disposed in the sliding slot 112 '.It is understood that the hook 123 ' also can be set in the cloth key lid 11 ', and the sliding slot 112 ' is set to the driving lid 12 '.The sliding slot 112 ' also can be set in the outer surface of the cloth key lid 11 ', that is, be different from the inside that driving lid 12 ' shown in Figure 17 is located at the cloth key lid 11 ', and the driving lid 12 ' can also be located at the outside of the cloth key lid 11 '.

It is noted that in this embodiment in accordance with the invention, as shown in Figure 17 and Figure 18, the driving lid 12 ' and the cloth key lid 11 ' are unilateral swing form.That is, the Self-generating remote controller takes one end card slot type to be connected and fixed, the other end is swingable.Connection type can analogy stapler, one end being capable of unilateral movement up and down.To the Self-generating remote controller stabilized structure, and it is adapted to mount to surface of wall and is operated for operator.In this preferred embodiment, pivot connector structure, that is, axis 113 ' and the card slot 124 ' can be arranged on the other side of the spontaneous electrical remote control device, the cloth key lid 11 ' is suitable for being pressed far from that one end of the pivot connector structure, to be pivotally displaced relative to the axis 113 '.

Further, when the Self-generating remote controller is installed in a metope W, when the cloth key lid 11 ' receives pressing, by the driving lid 12 ' by the wall and W support without be displaced, and due to the pressing that is subject to relative displacement occurs for the cloth key lid 11 ', pivoted around the axis 113 ', to the driving lid 12 ' be equivalent in sink into the cloth key lid 11 ' (certain, in the cloth key lid 11 ' setting at the 12 ' inside of driving lid, it is also possible to the cloth key lid 11 ' to invaginate towards the inside of the driving lid 12 '), the i.e. described driving lid 12 ' and the cloth key lid 11 ' generate opposite, the touch element 122 ' withstands the driving element 46 ' and the kinetic-energy power generator 40 ' is made to convert electric energy for mechanical kinetic energy and generate electricity.When pressing force is applied to the key 21 ', since the driving lid 12 ' is supported by the metope W without relative displacement, And the driving lid 12 ' and the cloth key lid 11 ' can generate relatively, cause the touch element 122 ' that the driving element 46 ' is caused to be subjected to displacement, to equally realize the power generation of the kinetic-energy power generator 40 '.Moreover, similarly, under the reset response of the reset element 47 ', the kinetic-energy power generator 40 ' can generate electricity again, so as to send second of wireless control signal.

It is noted that in this embodiment in accordance with the invention, compared with the above-mentioned preferred embodiment using infrared-emitting diode of the invention, the Self-generating remote controller can not also use infrared-emitting diode by the way of infrared emission wireless signal.Because not having directive limitation for the Self-generating remote controller for being fixed on metope using wireless radio frequency mode remote control, being more convenient.Certainly exist

Correspondingly, this preferred embodiment of the invention provides the wireless signal transmitting method of a Self-generating remote controller comprising following steps:

When an at least key 21 ' for the key device 20 ' is pressed, the control instruction circuit of the corresponding key 21 ' of the controller 30 ' is switched on；

When the cloth key lid 11 ' is pressed, the cloth key lid 11 ' generates relative displacement with the driving lid 12 ', and the kinetic-energy power generator 40 ', which is driven, converts electric energy for mechanical energy；And

The controller 30 ' emits the wireless control signal of the corresponding key 21 ' under the electric energy supply that the kinetic-energy power generator 40 ' provides.

I.e. in the present invention, two lids generate relative displacement, so that the kinetic-energy power generator be driven to produce electricl energy.In this preferred embodiment, the kinetic-energy power generator 40 ' engaged with the driving lid 12 ' is driven and is produced electricl energy.

Correspondingly, when the pressing force for being applied to the cloth key lid 11 ' disappears, the reset element 47 ' is restored from elastic deformation, to which its reset response causes the magnetic group 42 ' being arranged in the driving arm 45 ' to return to initial position, to which the center pillar 44 ' alternately contacts the bottom magnetizer 423 ' and the top magnetizer 422 ' of the magnetic group 42 ' again, to which the kinetic energy electric generating devcie 40 ' produces electricl energy again, if the key 21 ' is still pressed, the controller 30 ' can issue another secondary wireless control signal again.

When the cloth key lid 11 ' is pressed, the driving lid 12 ' and the cloth key lid 11 ' generate relative displacement, the magnetic group 42 ' and the center pillar 44 ' being located in the magnetic conduction cavity 41 ' and the magnetic group 42 ' is set to generate relative displacement, the center pillar 44 ' is set alternately to contact the top magnetizer 422 ' and the bottom magnetizer 423 ' of the magnetic group 42 ', to make to generate an induced current in the coil 43 ' being arranged around the center pillar 44 '.Correspondingly, the coil 43 ' and the center pillar 44 ' are located in the magnetic conduction cavity 41 ', the coil 30 ' It is completely covered by magnetic induction line, to reduce the leakage field of entire magnetic circuit system, improves the generating efficiency of the kinetic-energy power generator 40 ' of the entire Self-generating remote controller.

When the cloth key lid 11 ' is no longer pressed, the reset response of the reset element 47 ', the center pillar 44 ' is set alternately to contact the bottom magnetizer 423 ' and the top magnetizer 422 ' of the magnetic group 42 ', to make to generate another secondary induced current in the coil 43 ' being arranged around the center pillar 44 '.

It should be understood by those skilled in the art that foregoing description and the embodiment of the present invention shown in the drawings are only used as illustrating and being not intended to limit the present invention.The purpose of the present invention has been fully and effectively achieved.Function and structural principle of the invention has been shown in embodiment and explanation, and under without departing from the principle, embodiments of the present invention can have any deformation or modification.

Claims

One Self-generating remote controller characterized by comprising

An at least key device comprising one or more keys；

An at least cloth key lid, for arranging the key；

At least one driving lid；

An at least kinetic-energy power generator；And

An at least controller, when wherein at least one key is pressed and the kinetic-energy power generator is driven to switch to mechanical kinetic energy for electric energy for driving lid, an at least wireless control signal that the key that the controller is launched and is pressed in the case where the electric energy that the kinetic-energy power generator provides is supplied matches.
Self-generating remote controller according to claim 1, wherein the cloth key lid is movably engaged with driving lid.
Self-generating remote controller according to claim 2, wherein the cloth key lid and driving lid form an accommodating chamber, the controller and the kinetic-energy power generator are located in the accommodating chamber.
Self-generating remote controller according to claim 3, wherein the cloth key lid and the driving are covered respectively as a top cover and a bottom cover.
Self-generating remote controller according to claim 3, wherein the cloth key lid and the driving are covered respectively as a top cover and a side cover.
Self-generating remote controller according to claim 4, wherein driving lid is configured to the medial movement along the cloth key lid.
Self-generating remote controller according to claim 4, wherein driving lid is configured to move on the outside of the cloth key lid.
Self-generating remote controller according to claim 6, wherein the cloth key lid and the driving are covered through an at least hook and at least a sliding slot slidably engages.
Self-generating remote controller according to claim 7, wherein the cloth key lid and the driving are covered through an at least hook and at least a sliding slot slidably engages.
Self-generating remote controller according to claim 8, wherein the cloth key lid and the driving are covered is cooperated by the corresponding sliding slot of four hooks and four that are located at four sides, and the driving covers and is configured to move along front and rear, left and right and up and down direction.
Self-generating remote controller according to claim 9, wherein the cloth key lid passes through with driving lid Four hooks and four corresponding sliding slots for being located at four sides cooperate, and driving lid is configured to move along front and rear, left and right and up and down direction.
Self-generating remote controller according to claim 1 wherein the cloth key lid and the driving are covered respectively as a top cover and a bottom cover, and is connected in such a way that unilateral side is swung.
Self-generating remote controller according to claim 12, wherein driving lid is suitable for being fixed on an environmental surfaces, the driving lid described in this way is motionless, and the cloth key lid can be covered relative to the driving and be moved.
Self-generating remote controller according to claim 13, wherein the cloth key lid is configured to the interior side oscillation along the driving lid.
Self-generating remote controller according to claim 13, wherein the cloth key lid is configured to the outer side oscillation along the driving lid.
Self-generating remote controller according to claim 14, wherein the cloth key lid and described driving lid one end pass through an at least hook respectively and an at least sliding slot cooperates, the other end is cooperated by an at least card slot and an axis.
It is produced electricl energy according to claim 1 to any Self-generating remote controller in 16 wherein the kinetic-energy power generator is piezoelectric effect generator when the pressure by the driving lid is driven.
According to claim 1 to any Self-generating remote controller in 16, wherein the kinetic-energy power generator includes an at least magnetic group, an at least coil, an and at least center pillar, wherein the coil is arranged around the center pillar, the magnetic group includes an at least permanent magnet and pushes up magnetizer and an at least bottom magnetizer positioned at opposite polarity at least the one of the permanent magnet two opposite sides, wherein when driving lid and the cloth key lid generate relative displacement, the center pillar can alternately contact the top magnetizer and the bottom magnetizer, it changes to pass through the magnetic induction line direction of the coil, make to generate an at least induced current in the coil.
Self-generating remote controller according to claim 18, wherein there is between the top magnetizer and the bottom magnetizer magnetic gap, one end of the center pillar extends into the magnetic gap, with the inside for alternately contacting the top magnetizer and the bottom magnetizer.
Self-generating remote controller according to claim 19, wherein the magnetic group is fixed, the center pillar is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer by driving.
Self-generating remote controller according to claim 19, wherein the center pillar is fixed, the magnetic group is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer by driving.
Self-generating remote controller according to claim 21, wherein the self-generating device further includes a magnetic conduction cavity, wherein the center pillar and the coil are located in the magnetic conduction cavity.
Self-generating remote controller according to claim 22, wherein the magnetic conduction cavity has an opening, institute The sealing of magnetic group is stated in the opening.
Self-generating remote controller according to claim 23, wherein the center pillar is installed on the magnetic conduction cavity.
Self-generating remote controller according to claim 23, wherein the center pillar and the magnetic conduction cavity are integrally formed.
Self-generating remote controller according to claim 25, wherein the kinetic-energy power generator further includes an at least driving arm, the driving arm has a magnetic group fixing groove, and with the fixation magnetic group, the driving arm and the magnetic conduction cavity are pivotably connected.
Self-generating remote controller according to claim 26, wherein the kinetic-energy power generator further includes an at least driving element, it is connected to the driving arm, the driving lid includes at least one touch element, it can act on the driving element, pivot the driving arm, so that the magnetic group and the center pillar generate relative displacement.
Self-generating remote controller according to claim 27, wherein the driving element is an elastic slice.
Self-generating remote controller according to claim 27, wherein the driving element and the driving arm are integrally formed.
Self-generating remote controller according to claim 27, wherein the kinetic-energy power generator further includes an at least reset element, it is connected to the driving element, after the driving drowning is pressed, under the reset response of the reset element, the driving arm and the magnetic group can automatically reset.
Self-generating remote controller according to claim 30, wherein the reset element is selected from one of elastic slice, compressed spring and torsional spring.
Self-generating remote controller according to claim 30, wherein described reset element one end is connected to the driving element, the other end is connected to the controller.
Self-generating remote controller according to claim 30, wherein described reset element one end is connected to the driving element, the other end is connected to the cloth key lid.
Self-generating remote controller according to claim 22, wherein the magnetic conduction cavity is additionally provided with two pins, the both ends of the coil are respectively positioned in the pin.
Self-generating remote controller according to claim 22, wherein the magnetic conduction cavity is fixed on the controller.
Self-generating remote controller according to claim 22, wherein the magnetic conduction cavity is fixed on the cloth key lid.
Self-generating remote controller according to claim 26, wherein the driving arm includes an at least bracket Matrix, at least a magnetic group fixed arm group and an at least swing arm group, the magnet fixed arm group respectively extends internally from the both ends of the rest body and forms the magnetic group fixing groove with the rest body, and the swing arm group extends out to the two sides of the magnetic conduction cavity from the magnetic group fixed arm group.
The Self-generating remote controller according to claim 37, the magnetic group fixing groove have an aperture towards the intracorporal center pillar of the magnetic conduction chamber, extend into the magnetic group for described center pillar one end.
The Self-generating remote controller according to claim 38, wherein each magnetic group fixed arm group is additionally provided with an at least abutment end dowel, for consolidating the top magnetizer and the bottom magnetizer.
Self-generating remote controller according to claim 39, wherein the top magnetizer also has a top magnetizer abutment end, the bottom magnetizer also has a bottom magnetizer abutment end, and the abutment end dowel is for positioning the top magnetizer abutment end and the bottom magnetizer abutment end.
The Self-generating remote controller according to claim 37, wherein the swing arm group and the magnetic conduction cavity are pivotably connected by an at least rotary axis groove and a rotation axis.
Self-generating remote controller according to claim 18, wherein the top magnetizer also has a top magnetizer abutment end, the bottom magnetizer also has a bottom magnetizer abutment end, wherein the center pillar alternately contacts the top magnetizer abutment end and the bottom magnetizer abutment end.
Self-generating remote controller according to claim 22, wherein the top magnetizer also has a top magnetizer abutment end, the bottom magnetizer also has a bottom magnetizer abutment end, the magnetic conduction cavity has a top edge and a bottom edge, the top magnetizer abutment end and the bottom magnetizer abutment end extend into the magnetic conduction cavity, when wherein the center pillar alternately contacts the top magnetizer abutment end and the bottom magnetizer abutment end, the bottom magnetizer abutment end and the top magnetizer abutment end are correspondingly contacted with the bottom edge of the magnetic conduction cavity and the top edge respectively, the direction of the magnetic induction line across the coil is set to change, to generate the induced current in the coil.
According to claim 1 to any Self-generating remote controller in 16, wherein the cloth key lid has one or more key slots, wherein each key is arranged in the corresponding key slot.
Self-generating remote controller according to claim 18, wherein the cloth key lid has one or more key slots, wherein each key is arranged in the corresponding key slot.
According to claim 1 to any Self-generating remote controller in 16, wherein the key of the key device is integrally formed, to form a key board.
According to claim 1 to the Self-generating remote controller any in 16, wherein by the key press with it is corresponding connect pressing force required for the corresponding key circuit of controller be less than the driving cover be pressed with Start the pressing force of the kinetic energy electric generating devcie.
According to claim 1 to any Self-generating remote controller in 16, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 18, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 22, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 26, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 27, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates supplies the coding module and launches and the key phase that is pressed via the wireless signal emission source after the power supply shaping operation of the shaping circuit The matched wireless control signal.
Self-generating remote controller according to claim 30, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 46, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
Self-generating remote controller according to claim 48, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
Self-generating remote controller according to claim 49, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
Self-generating remote controller according to claim 50, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
Self-generating remote controller according to claim 51, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module
Self-generating remote controller according to claim 52, wherein the wireless signal of the controller is sent out It penetrates source and is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
Self-generating remote controller according to claim 53, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
Self-generating remote controller according to claim 54, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module.
One Self-generating remote controller characterized by comprising

An at least key device comprising one or more keys；

An at least controller；

An at least shell has an accommodating chamber, and including at least one driving lid；And

An at least kinetic-energy power generator, the kinetic-energy power generator and the controller are located in the accommodating chamber, and the kinetic-energy power generator includes: an at least magnetic conduction cavity, an at least magnetic group, an at least center pillar and at least a coil, wherein the coil is arranged around the center pillar, the magnetic group includes an at least permanent magnet and opposite polarity two magnetizer for being located at the permanent magnet two opposite sides, wherein a magnetic gap is formed between two magnetizers, described center pillar one end extends into the magnetic gap, the coil and the center pillar are arranged in the magnetic conduction cavity to reduce leakage field；

The kinetic-energy power generator can be driven when wherein the driving lid is configured as being pressed, the center pillar is set alternately to contact two magnetizers, to generate an at least induced current in the coil, and at least wireless control signal that the controller key launching and be pressed under the electric energy supply of the induced current matches.
Self-generating remote controller according to claim 62, wherein the center pillar is connected to the magnetic conduction cavity.
Self-generating remote controller according to claim 63, wherein the kinetic-energy power generator further includes an at least driving arm, the driving arm has a magnetic group fixing groove, and with the fixation magnetic group, the driving arm and the magnetic conduction cavity are pivotably connected.
Self-generating remote controller according to claim 64, wherein the driving arm is fixed, the magnetic conduction Cavity is mobile so that the center pillar alternately contacts two magnetizers by driving.
Self-generating remote controller according to claim 64, wherein the magnetic conduction cavity is fixed, the driving arm is mobile so that the center pillar alternately contacts two magnetizers by driving.
Self-generating remote controller according to claim 65, wherein the magnetic conduction cavity has an opening, the magnetic group sealing is in the opening.
Self-generating remote controller according to claim 67, wherein the center pillar and the magnetic conduction cavity are integrally formed.
According to the Self-generating remote controller any in claim 62 to 68, wherein the kinetic-energy power generator further includes an at least driving element, it is connected to the driving arm, the driving lid includes at least one touch element, it is connected to the driving element, pivot the driving arm, so that the magnetic group and the center pillar generate relative displacement.
Self-generating remote controller according to claim 69, wherein the driving element is an elastic slice.
Self-generating remote controller according to claim 69, wherein the driving element and the driving arm are integrally formed.
Self-generating remote controller according to claim 69, wherein the kinetic-energy power generator further includes an at least reset element, it is connected to the driving element, after the driving drowning is pressed, under the reset response of the reset element, the driving arm and the magnetic group can automatically reset.
The Self-generating remote controller according to claim 72, wherein the reset element is selected from one of elastic slice, compressed spring and torsional spring.
The Self-generating remote controller according to claim 72, wherein described reset element one end is connected to the driving element, the other end is connected to the controller.
According to the Self-generating remote controller any in claim 62 to 68, wherein the magnetic conduction cavity is additionally provided with two pins, the both ends of the coil are respectively positioned in the pin.
According to the Self-generating remote controller any in claim 62 to 68, wherein the magnetic conduction cavity is fixed on the controller.
According to the Self-generating remote controller any in claim 64 to 68, wherein the driving arm includes an at least rest body, at least a magnetic group fixed arm group and an at least swing arm group, the magnet fixed arm group respectively extends internally from the both ends of the rest body and forms the magnetic group fixing groove with the rest body, and the swing arm group extends out to the two sides of the magnetic conduction cavity from the magnetic group fixed arm group.
The Self-generating remote controller according to claim 77, the magnetic group fixing groove is towards the magnetic conduction cavity The interior center pillar has an aperture, extends into the magnetic group for described center pillar one end.
The Self-generating remote controller according to claim 77, wherein each magnetic group fixed arm group is additionally provided with an at least abutment end dowel, for consolidating two magnetizers.
Self-generating remote controller according to claim 39, wherein two magnetizers are respectively provided with a magnetizer abutment end, the abutment end dowel is for positioning the magnetizer abutment end.
The Self-generating remote controller according to claim 77, wherein the swing arm group and the magnetic conduction cavity are pivotably connected by an at least rotary axis groove and a rotation axis.
According to the Self-generating remote controller any in claim 62 to 68, wherein two magnetizers are respectively provided with a magnetizer abutment end, the magnetic conduction cavity has a top edge and a bottom edge, the two magnetizer abutment ends extend into the magnetic conduction cavity, when wherein the center pillar alternately contacts the two magnetizer abutment ends, the two magnetizer abutment ends are correspondingly contacted with the bottom edge of the magnetic conduction cavity and the top edge respectively, the direction of the magnetic induction line across the coil is set to change, to generate the induced current in the coil.
According to the Self-generating remote controller any in claim 62 to 68, wherein the controller includes at least one set of key electrode, an at least coding module, an at least wireless signal emission source, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the wireless signal emission source matches.
The Self-generating remote controller according to claim 83, wherein the wireless signal emission source of the controller is selected from one of amplitude shift keying circuit, FS keying circuit, phase-shift keying (PSK) circuit, RFID radio-frequency module, mobile communication module, bluetooth communication module, WIFI communication module, Z-Wave communication module, ZigBee communication module and infrared transmission module
One infrared Self-generating remote controller characterized by comprising

An at least shell has an accommodating chamber；

An at least key device comprising one or more keys；

An at least infrared controller is configured with an at least infrared-emitting diode；And

An at least kinetic-energy power generator, the infrared controller and the kinetic-energy power generator are located in the accommodating chamber, and the kinetic-energy power generator is configured to convert electric energy for mechanical kinetic energy, the infrared controller launches the wireless control signal to match with the key being pressed via the infrared-emitting diode under the electric energy supply that the kinetic-energy power generator provides.
The infrared Self-generating remote controller according to claim 85, wherein the shell includes that a mobilizable driving lid can drive the kinetic-energy power generator to carry out spontaneous electrically operated when the driving lid is pressed.
The infrared Self-generating remote controller according to claim 86, wherein the kinetic-energy power generator includes: an at least magnetic group, at least a center pillar and an at least coil, wherein the coil is arranged around the center pillar, the magnetic group includes an at least permanent magnet and opposite polarity two magnetizer for being located at the permanent magnet two opposite sides, a magnetic gap is wherein formed between two magnetizers, described center pillar one end extends into the magnetic gap.
The infrared Self-generating remote controller according to claim 87, wherein the kinetic-energy power generator further includes an at least magnetic conduction cavity, the coil and the center pillar are arranged in the magnetic conduction cavity to reduce leakage field.
The infrared Self-generating remote controller according to claim 88, wherein two magnetizers are respectively provided with a magnetizer abutment end, the magnetic conduction cavity has a top edge and a bottom edge, the two magnetizer abutment ends extend into the magnetic conduction cavity, when wherein the center pillar alternately contacts the two magnetizer abutment ends, the two magnetizer abutment ends are correspondingly contacted with the bottom edge of the magnetic conduction cavity and the top edge respectively, the direction of the magnetic induction line across the coil is set to change, to generate an at least induced current in the coil.
The infrared Self-generating remote controller according to claim 88, wherein the center pillar is connected to the magnetic conduction cavity.
The infrared Self-generating remote controller according to claim 88, wherein the kinetic-energy power generator further includes an at least driving arm, the driving arm has a magnetic group fixing groove, and with the fixation magnetic group, the driving arm and the magnetic conduction cavity are pivotably connected.
The infrared Self-generating remote controller according to claim 91, wherein the driving arm is fixed, the magnetic conduction cavity is mobile so that the center pillar alternately contacts two magnetizers by driving.
The infrared Self-generating remote controller according to claim 91, wherein the magnetic conduction cavity is fixed, the driving arm is mobile so that the center pillar alternately contacts two magnetizers by driving.
The infrared Self-generating remote controller according to claim 88, wherein the magnetic conduction cavity has an opening, the magnetic group sealing is in the opening.
According to the infrared Self-generating remote controller any in claim 91 to 93, wherein the kinetic-energy power generator further includes an at least driving element, it is connected to the driving arm, the driving lid includes at least one electric shock element, it is connected to the driving element, pivot the driving arm, so that the magnetic group and the center pillar generate relative displacement.
The infrared Self-generating remote controller according to claim 95, wherein the driving element is an elastic slice.
The infrared Self-generating remote controller according to claim 95, wherein the kinetic-energy power generator further includes An at least reset element is connected to the driving element, and after the driving drowning is pressed, under the reset response of the reset element, the driving arm and the magnetic group can automatically reset.
The infrared Self-generating remote controller according to claim 97, wherein the reset element is selected from one of elastic slice, compressed spring and torsional spring.
The infrared Self-generating remote controller according to claim 97, wherein described reset element one end is connected to the driving element, the other end is connected to the controller.
The infrared Self-generating remote controller according to claim 93, wherein the magnetic conduction cavity is fixed on the controller.
The infrared Self-generating remote controller according to claim 93, wherein the driving arm and the magnetic conduction cavity are pivotably connected by an at least rotary axis groove and a rotation axis.
According to the infrared Self-generating remote controller any in claim 95 to 94, wherein the controller further includes at least one set of key electrode, an at least coding module, an and at least shaping circuit, wherein each key electrode is corresponding with each key, and after the key is pressed, the key electrode is short-circuited, the induced current that wherein kinetic-energy power generator generates is after the power supply shaping operation of the shaping circuit, supply the coding module and the wireless control signal that the key launching and be pressed via the infrared-emitting diode matches.
According to the infrared Self-generating remote controller any in claim 86 to 94, wherein pressing the mutually indepedent to start the operation of the kinetic-energy power generator with the operation of the corresponding key command circuit of pre-on and the pressing driving lid of the key.
The method for transmitting signal of one Self-generating remote controller, it is characterized in that, include the following steps: in response to an at least button operation and in addition independent at least one power generation pressing operation, the Self-generating remote controller self power generation simultaneously launch an at least wireless control signal corresponding to the button operation.
Method described in 04 according to claim 1, wherein further comprising:

(A) in the button operation: when an at least key for an at least key device is pressed, the control instruction circuit that an at least controller corresponds to the key is switched on；

(B) in the power generation pressing operation: when at least one mobilizable driving lid is pressed, at least a kinetic-energy power generator, which is driven, converts electric energy for mechanical energy；And

(C) controller emits the wireless control signal of the corresponding key being pressed under the electric energy supply that the kinetic-energy power generator provides.
Method described in 05 according to claim 1, wherein being further comprised the steps of: in the step (A) The key being pressed makes the controller transfer the coded command for corresponding to the key.
Method described in 06 according to claim 1, wherein in the step (B), under the driving effect for further comprising the steps of: the driving lid, an at least center pillar for the kinetic-energy power generator is caused alternately to contact opposite polarity two magnetizer positioned at an at least permanent magnet two opposite sides of an at least magnetic group, at least coil being arranged in around the center pillar generates an induced current.
According to claim 1, method described in 07 when further comprising the steps of: the driving lid and being pressed, cause the magnetic group to be moved by driving, so that the center pillar alternately contacts two magnetizers wherein in the step (B).
According to claim 1, method described in 07 when further comprising the steps of: the driving lid and being pressed, cause the center pillar to be moved by driving, so that the center pillar alternately contacts two magnetizers wherein in the step (B).
According to claim 1, method described in 07 reduce leakage field wherein the center pillar and the coil are arranged in a magnetic conduction cavity.
Method described in 10 according to claim 1, wherein in the step (B), when further comprising the steps of: driving lid and being pressed, the magnetic group is caused to be moved by driving, so that the center pillar alternately contacts two magnetizers, and when the center pillar contacts one of them described magnetizer, another described magnetizer contacts magnetic conduction chamber intracorporal bottom edge, when the center pillar contacts another described magnetizer, one of them described described magnetizer contacts the intracorporal top edge of magnetic conduction chamber.
Method described in 07 according to claim 1, wherein in the step (B), when further comprising the steps of: driving lid and being pressed, at least one touch element of the driving lid compresses an at least driving element, a driving element driving at least driving arm is mobile, the magnetic group for being installed on the driving arm correspondingly moves, and the center pillar alternately contacts two magnetizers of the magnetic group.
Method described in 10 according to claim 1, wherein in the step (B), when further comprising the steps of: driving lid and being pressed, at least one touch element of the driving lid compresses an at least driving element, a driving element driving at least driving arm is mobile, the driving arm is pivoted relative to the magnetic conduction cavity, and the magnetic group for being installed on the driving arm correspondingly moves, and the center pillar alternately contacts two magnetizers of the magnetic group.
Method described in 07 according to claim 1, wherein in the step (B), the touch element of the driving lid is further comprised the steps of: when compressing the driving element, an at least reset element generates elastic deformation, and the method also includes step (D): when the pressing force for being applied to the driving lid disappears, institute It states reset element to restore from elastic deformation state to original state, the driving element drives the driving arm and the magnetic group to automatically reset, and makes the center pillar alternately contact two magnetizers of the magnetic group again, to generate another secondary induced current.
Method described in 14 according to claim 1, wherein in the step (D), when the key is still kept pressing and driving lid is released, the controller launches another secondary wireless control signal in the case where the kinetic-energy power generator provides another secondary electric energy supply.
Method described in 15 according to claim 1, wherein by the reception processor part for at least electric appliance that the Self-generating remote controller is remotely controlled is programmed to receive any wireless control signal and executes corresponding single keys presses operation, or when the time interval between the wireless control signal twice within a preset time when, the operation for receiving processor part and receiving the wherein primary wireless control signal and executing corresponding single keys presses.
Method described in 15 according to claim 1, wherein it is programmed to by the reception processor part for at least electric appliance that the Self-generating remote controller is remotely controlled: when the time interval between the wireless control signal twice is more than preset time, the operation for receiving processor part and receiving wherein the wireless control signal twice and executing corresponding continuous key-press.
Any method in 05 to 117 according to claim 1, in the step (C), the electric energy that the self-generating device generates supplies an at least coding module after the power supply shaping operation of the shaping circuit of the controller, and at least wireless signal emission source for being connected to the coding module issues the wireless control signal.
According to claim 1, any method in 05 to 117, in the step (B), the pressing operation of any position of the bottom surface of the driving lid can start the kinetic-energy power generator.
Method described in 04 according to claim 1, wherein further including:

(a) in the button operation: when an at least key for an at least key device is pressed, the control instruction circuit that an at least controller corresponds to the key is switched on；

(b) in the power generation pressing operation: when at least a cloth key lid is pressed, the cloth key lid generates relative displacement at least one driving lid, and at least a kinetic-energy power generator, which is driven, converts electric energy for mechanical energy；And

(c) controller emits the wireless control signal of the corresponding key being pressed under the electric energy supply that the kinetic-energy power generator provides.
According to claim 1, method described in 20, wherein driving lid is fixed, the cloth key lid is pivotally displaced relative to driving lid, and the kinetic-energy power generator engaged with the cloth key lid is caused to be activated.
Method described in 21 according to claim 1, wherein driving lid is fixed in an environmental surfaces.
Method described in 22 according to claim 1, wherein a card slot is pivotably connected by an at least axis and at least for the cloth key lid and described driving lid one end, wherein the method also includes steps: when the cloth key lid is pressed far from the other end of the axis and the card slot, the driving lid and the cloth key lid generate relative displacement, and the driving lid is caused to start the kinetic-energy power generator to convert electric energy for mechanical kinetic energy.
Method described in 21 according to claim 1, wherein in the step (a), it further comprises the steps of: the key being pressed to connect a corresponding at least key electrode for the controller into circuit, wherein the controller is preset with the coded command of the corresponding key electrode.
Method described in 21 according to claim 1, wherein in the step (b), under the driving effect for further comprising the steps of: the driving lid, an at least center pillar for the kinetic-energy power generator is caused alternately to contact two magnetizers positioned at an at least permanent magnet two opposite sides of an at least magnetic group, at least coil being arranged in around the center pillar generates an induced current.
According to claim 1, method described in 25 when further comprising the steps of: the driving lid and being pressed, cause the magnetic group to be moved by driving, so that the center pillar alternately contacts two magnetizers wherein in the step (b).
According to claim 1, method described in 25 reducing leakage field wherein the center pillar and the coil are arranged in a magnetic conduction cavity.
Method described in 26 according to claim 1, wherein in the step (b), when further comprising the steps of: driving lid and being pressed, the magnetic group is caused to be moved by driving, so that the center pillar alternately contacts two magnetizers, and two magnetizers respectively correspondingly contact the intracorporal top edge of the magnetic conduction and a bottom edge.
Method described in 25 according to claim 1, wherein in the step (b), the at least one touch element for further comprising the steps of: the driving lid compresses an at least driving element, a driving element driving at least driving arm is mobile, the magnetic group for being installed on the driving arm correspondingly moves, and the center pillar alternately contacts two magnetizers of the magnetic group.
Method described in 29 according to claim 1, wherein in the step (b), the at least one touch element for further comprising the steps of: the driving lid compresses an at least driving element, a driving element driving at least driving arm is mobile, the driving arm is pivoted relative to the magnetic conduction cavity, the magnetic group for being installed on the driving arm correspondingly moves, and the center pillar alternately contacts two magnetizers of the magnetic group.
According to claim 1, method described in 30, wherein in the step (b), when further comprising the steps of: the touch element of the driving lid and compressing the driving element, an at least reset element generates elastic shape Become, and the method also includes steps (d): when the pressing force for being applied to the cloth key lid disappears, the reset element is restored from elastic deformation state to original state, the driving element drives the driving arm and the magnetic group to automatically reset, the center pillar is set alternately to contact two magnetizers of the magnetic group again, to generate another secondary induced current.
Method described in 31 according to claim 1, wherein when the key is still kept pressing, the controller launches another secondary wireless control signal in the case where the kinetic-energy power generator provides another secondary electric energy supply in the step (d).
Method described in 32 according to claim 1, wherein by the operation that the reception processor part for at least electric appliance that the Self-generating remote controller is remotely controlled is programmed to receive any wireless control signal and executes corresponding single keys presses.
Method described in 32 according to claim 1, wherein it is programmed to by the reception processor part for at least electric appliance that the Self-generating remote controller is remotely controlled: when the time interval between the wireless control signal twice is more than preset time, the operation for receiving processor part and receiving wherein the wireless control signal twice and executing corresponding continuous key-press.
Any method in 20 to 134 according to claim 1, in the step (c), the electric energy that the self-generating device generates supplies an at least coding module after the power supply shaping operation of the shaping circuit of the controller, and at least wireless signal emission source for being connected to the coding module issues the wireless control signal.
The continuous variable signal control method of one Self-generating remote controller characterized by comprising

(I) an at least kinetic-energy power generator is driven so that an at least center pillar is alternately contacted an at least magnetic group to push up magnetizer and a bottom magnetizer positioned at the one of an at least permanent magnet two opposite sides, the at least coil being arranged in around the center pillar generates first time induced current, and the controller launches first time wireless control signal under the electric energy supply of the first time induced current；

(II) under at least reset response of a reset element, the center pillar alternately contacts the bottom magnetizer and the top magnetizer of the magnetic group, an at least coil around the center pillar is set and generates second of induced current, the controller second of the induced current electric energy supply under launch second of wireless control signal；

(III) when determining that the time difference for the wireless control signal twice that the step (I) and the step (II) issue is located in preset time, at least electric appliance being remotely controlled is programmed to the button operation of the Self-generating remote controller doing single keys presses processing；And

(IV) when determining that the time difference for the wireless control signal twice that the step (I) and the step (II) issue is located at other than preset time, the electric appliance is programmed to the button operation of the Self-generating remote controller doing continuous key-press processing, and the electric appliance is made to execute the control operation of continuous variable signal.
Method described in 36 according to claim 1, wherein at least one driving lid is pressed to start the kinetic-energy power generator in the step (I).
Method described in 36 according to claim 1, wherein an at least cloth key lid, which is pressed, makes at least one driving lid generate relative displacement with the cloth key lid in the step (I), so that driving lid starts the kinetic-energy power generator.
Method described in 37 or 138 according to claim 1, wherein in the step (I), at least one touch element of the driving lid compresses an at least driving element, a driving element driving at least driving arm is mobile, the magnetic group for being installed on the driving arm correspondingly moves, and the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group.
Method described in 39 according to claim 1, wherein in the step (I), the driving arm is further comprised the steps of: to pivot relative to an at least magnetic conduction cavity, the magnetic group for being installed on the driving arm correspondingly moves, the center pillar alternately contacts the top magnetizer and the bottom magnetizer, wherein the center pillar and the coil are set in the magnetic conduction cavity.
Method described in 40 according to claim 1, wherein the driving element is an elastic slice.
Method described in 37 according to claim 1, wherein when being applied to the pressing force disappearance of the driving lid, the reset response of the reset element causes the magnetic group to automatically reset in the step (II).
Method described in 38 according to claim 1, wherein when being applied to the pressing force disappearance of the cloth key lid, the reset response of the reset element causes the magnetic group to automatically reset in the step (II).
Method described in 42 or 143 according to claim 1, wherein the reset element is selected from one of elastic slice, compressed spring and torsional spring.
Any method in 36 to 138 and 142 to 143 according to claim 1, wherein the button operation of the Self-generating remote controller and starting the mutual independence of pressing operation of the kinetic-energy power generator and cooperating with each other and complete the control operation of the Self-generating remote controller.
The self-power generation method of one Self-generating remote controller, it is characterized in that, include the following steps: when at least one driving lid is pressed, the driving lid makes an at least magnetic group for an at least kinetic-energy power generator and is located at the intracorporal at least center pillar of an at least magnetic conduction chamber and magnetic group generation relative displacement, so that the center pillar is alternately contacted an opposite polarity top magnetizer and a bottom magnetizer that the magnetic group is located at a permanent magnet two opposite sides, makes to be arranged described Induced current at least once is generated in the coil around center pillar, wherein the coil and the center pillar are located in the magnetic conduction cavity, the coil is completely covered by magnetic induction line, reduces leakage field, improves the generating efficiency of the kinetic-energy power generator.
According to claim 1, method described in 46, wherein the magnetic conduction cavity is fixed, the magnetic group is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group by driving.
According to claim 1, method described in 46, wherein the magnetic group is fixed, the magnetic conduction cavity is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group by driving.
Method described in 46 according to claim 1, wherein the center pillar and the magnetic conduction cavity are integrally formed.
Method described in 46 according to claim 1, the at least driving element for further comprising the steps of: the driving lid driving elasticity is mobile, a driving element driving at least driving arm is mobile, keep the magnetic group for being installed on the driving arm mobile, so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group.
According to claim 1, method described in 50 further comprise the steps of: the driving arm and pivoted relative to the magnetic conduction cavity so that the magnetic group for being installed on the driving arm is mobile.
Any method in 46 to 151 according to claim 1, it further comprises the steps of: when driving lid is no longer pressed, under at least reset response of a reset element, the center pillar is set alternately to contact the bottom magnetizer and the top magnetizer of the magnetic group, to make to generate another secondary induced current in the coil being arranged in around the center pillar.
The self-power generation method of one Self-generating remote controller, it is characterized in that, include the following steps: when at least a cloth key lid is pressed, at least one driving lid being pivotably connected with the cloth key lid makes an at least magnetic group for an at least kinetic-energy power generator and is located at the intracorporal at least center pillar of an at least magnetic conduction chamber and magnetic group generation relative displacement, the center pillar is set alternately to contact a top magnetizer and a bottom magnetizer that the magnetic group is located at a permanent magnet two opposite sides, make to generate induced current at least once in the coil being arranged in around the center pillar, wherein the coil and the center pillar are located in the magnetic conduction cavity, the coil is completely covered by magnetic induction line, reduce leakage field, improve the generating efficiency of the kinetic-energy power generator.
According to claim 1, method described in 53, wherein the magnetic conduction cavity is fixed, the magnetic group is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group by driving.
According to claim 1, method described in 53, wherein the magnetic group is fixed, the magnetic conduction cavity is mobile so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group by driving.
Method described in 53 according to claim 1, wherein the center pillar and the magnetic conduction cavity are integrally formed.
Method described in 53 according to claim 1, the at least driving element for further comprising the steps of: the driving lid driving elasticity is mobile, a driving element driving at least driving arm is mobile, keep the magnetic group for being installed on the driving arm mobile, so that the center pillar alternately contacts the top magnetizer and the bottom magnetizer of the magnetic group.
According to claim 1, method described in 57 further comprise the steps of: the driving arm and pivoted relative to the magnetic conduction cavity so that the magnetic group for being installed on the driving arm is mobile.
Any method in 53 to 158 according to claim 1, it further comprises the steps of: when the cloth key lid is no longer pressed, under at least reset response of a reset element, the center pillar is set alternately to contact the bottom magnetizer and the top magnetizer of the magnetic group, to make to generate another secondary induced current in the coil being arranged in around the center pillar.
According to claim 1, any method in 53 to 158, wherein a card slot is pivotably connected by an at least card slot and at least for the cloth key lid and described driving lid one end, by an at least hook and at least, a sliding slot is slidably connected the other end.
Any method in 53 to 158 according to claim 1, wherein the driving, which is covered, is fixed in an environmental surfaces.
Method described in 61 according to claim 1, wherein driving lid is fixed in a metope.