阅读说明：本技术 自发电无线开关及其联动方法 (Self-generating wireless switch and linkage method thereof ) 是由 刘远芳 于 2019-12-09 设计创作，主要内容包括：本发明提供了一自发电无线开关及其联动方法,其中所述自发电无线开关包括至少一开关板、所述联动装置、一自发电内核以及一信号发射单元,其中所述联动装置被耦合于所述开关板之下以能够在所述开关板被按压时被联动而发生移动,其中所述自发电内核被耦合于所述联动装置以能够在所述开关板被按压时被所述联动装置联动驱动而产生电能,其中藉由所述自发电内核的电能供应,所述信号发射单元被所述开关板触发而被控制发射对应的一无线控制信号。(The invention provides a self-generating wireless switch and a linkage method thereof, wherein the self-generating wireless switch comprises at least one switch board, a linkage device, a self-generating core and a signal transmitting unit, wherein the linkage device is coupled below the switch board and can be linked to move when the switch board is pressed, the self-generating core is coupled to the linkage device and can be driven by the linkage device to generate electric energy when the switch board is pressed, and the signal transmitting unit is triggered by the switch board to be controlled to transmit a corresponding wireless control signal through the supply of the electric energy of the self-generating core.)

1. A self-generating wireless switch, comprising:

at least one switch board;

a linkage, wherein the linkage is coupled under the switch plate to be capable of being moved in linkage when the switch plate is pressed;

a self-generating core, wherein the self-generating core is coupled to the linkage device to be driven by the linkage device to generate electric energy when the switch board is pressed; and

the signal transmitting unit comprises at least one touch control piece and a signal transmitting plate, wherein the touch control piece is arranged corresponding to the switch board, the signal transmitting plate is electrically connected to the self-generating core, when the switch board is pressed, the linkage device can be driven by the switch board in a linkage mode to drive the self-generating core to generate electric energy, the touch control piece is pressed by the switch board to be triggered, and the signal transmitting plate is controlled to transmit a wireless control signal corresponding to the triggered touch control piece through the electric energy supply of the self-generating core.

2. The self-generating wireless switch according to claim 1, further comprising a bottom case, wherein the self-generating core is disposed at the bottom case, wherein the linkage device comprises two driving plates pivotally disposed at the bottom case at both sides of the self-generating core, respectively, wherein when the switching plate is pressed, the driving plate corresponding to the switching plate is pushed to move downward toward the self-generating core, thereby linkage-driving the self-generating core to generate electric energy.

3. The self-generating wireless switch according to claim 2, wherein the bottom case is provided with a plurality of supporting members, each of the supporting members is provided with a pivot hole, wherein a pivot shaft extends from both sides of the driving plate, respectively, wherein each of the pivot shafts is provided in the corresponding pivot hole, thereby forming a state in which the driving plate is pivotably provided in the bottom case.

4. The self-generating wireless switch according to claim 2, wherein the bottom case is provided with a plurality of supporting pieces, each of which extends with a pivot shaft, wherein both sides of the driving plate are respectively provided with a pivot hole, wherein each of the pivot shafts is provided in the corresponding pivot hole, thereby forming a state in which the driving plate is pivotably provided in the bottom case.

5. The self-generating wireless switch according to claim 2, wherein the self-generating core comprises a linkage bracket and a generating device coupled to the linkage bracket, wherein the two driving plates are respectively disposed on the linkage bracket, so that when the driving plates are pushed by the switch plate to move, the driving plates can push the linkage bracket to move downwards towards the generating device, and the linkage bracket drives the generating device to generate electric energy in linkage.

6. The self-generating wireless switch according to claim 5, wherein a groove is formed at a bottom of each of the driving plates, wherein the linkage bracket includes two linkage arms which are linked to each other and are respectively disposed below the corresponding grooves, wherein when any one of the driving plates is pushed to move downward, the linkage arm corresponding to the driving plate is driven to link with the other linkage arm, so that the two linkage arms drive the power generating device to generate electric energy in a balanced manner.

7. The self-generating wireless switch according to claim 6, wherein each of the driving plates has a driving portion and a pivot portion extending from the driving portion, wherein the recess is provided at a bottom of the driving portion, wherein when the driving plate is pushed, the pivot portion of the driving plate pivots so that the driving portion can drive the linkage arm downward.

8. The self-generating wireless switch according to claim 7, wherein the pivoting portion of the driving plate has a slope, whereby the driving plate is a wing plate.

9. The self-generating wireless switch according to claim 8, wherein the linkage further comprises two buffering reset members, wherein each of the buffering reset members is disposed between the driving plate and the bottom case to elastically support the driving plate, wherein when the switch plate is pressed, the corresponding buffering reset member is pressed to store potential energy, and when the switch plate is released, the buffering reset member releases the potential energy to drive the corresponding driving plate and the switch plate to return to the original positions.

10. The self-generating wireless switch according to claim 9, wherein the bottom case is provided with two stoppers, wherein each stopper is provided corresponding to a position of the buffer reset member, respectively, for fixing the position of the buffer reset member.

11. The self-generating wireless switch according to claim 10, wherein a supporting groove is formed at a bottom of each of the driving plates, and wherein the buffering reset pieces are respectively formed at the corresponding supporting grooves to elastically support the driving plates.

12. The self-generating wireless switch according to claim 10, wherein a supporting post extends from a bottom of each of the driving plates, wherein the supporting posts are respectively disposed at the corresponding buffer reset members so that the buffer reset members can elastically support the driving plates.

13. The self-generating wireless switch according to any one of claims 10 to 12, wherein the buffering return member is provided as a spring.

14. The self-generating wireless switch according to any one of claims 2 to 12, wherein the switch plate is extended with at least one push ridge corresponding to a position of the driving plate, whereby the push ridge of the switch plate pushes the driving plate to move when the switch plate is pressed.

15. The self-generating wireless switch according to any one of claims 2 to 12, wherein the bottom case is further extended with a plurality of stoppers, each of the stoppers having an extended end extending from the bottom case and a blocking end extending from the extended end to a pivot path of the driving plate, so that the blocking end can limit a pivot angle of the driving plate by abutting the pivot path of the driving plate against the driving plate, and the angle by which the driving plate is pivoted is limited by abutting the pivot path of the blocking end against the driving plate is less than 30 °.

16. The self-generating wireless switch according to claim 15, further comprising a touch-control member protecting cover, wherein the touch-control member protecting cover is covered on the signal transmitting unit for protecting the touch-control member.

17. The self-generating wireless switch according to claim 16, wherein the touch-control member protection cover is provided with a plurality of operation slots and a shielding member extends from each of the operation slots, each of the shielding members is provided at a position corresponding to the touch-control member and is made of an elastic material, wherein when the switch board is pressed, the shielding member is pressed to downwardly trigger the corresponding touch-control member.

18. The self-generating wireless switch according to claim 17, wherein the touch member protecting cover is provided with an installation shaft, and both sides of the switch plate are respectively provided with an installation groove, and the switch plate is engaged with the installation shaft of the touch member protecting cover through the installation grooves, whereby the switch plate can be tilted along the installation shaft, so that the link gear can be driven when any one end of the switch plate is pressed.

19. The self-generating wireless switch according to any one of claims 6 to 12, wherein the self-generating core further comprises a supporting base, wherein the supporting base has a plurality of positioning members, an installation chamber is provided between the plurality of positioning members, and wherein the linking bracket and the power generating device are provided in the installation chamber.

20. The self-generating wireless switch according to claim 19, wherein a rotating shaft is disposed on each of two sides of each of the linkage arms of the linkage bracket, wherein each of the positioning members of the supporting base is disposed with a rotating groove, and wherein the rotating shaft is disposed in the corresponding rotating groove so as to be capable of rotating in the rotating groove when the linkage arms are linked.

21. The self-generating wireless switch according to claim 20, wherein the self-generating core further comprises a reset member disposed under both the linkage arms to store potential energy when the linkage arms are pushed to move downward and to release potential energy when the linkage arms are released so that the linkage arms are returned to their original positions.

22. The self-generating wireless switch according to claim 21, wherein the reset member is provided as a torsion spring.

23. The self-generating wireless switch according to claim 21, wherein the power generating device comprises an energy storage member coupled to the linkage bracket, a magnetic member connected to the energy storage member, and a coil member, wherein when the linkage bracket is driven, the energy storage member is linked to store potential energy and drive the magnetic member to move, so that the magnetic member and the coil member generate relative motion to generate electric energy in the coil member.

24. The self-generating wireless switch according to claim 23, wherein the power generating apparatus further comprises a swing arm, wherein one end of the swing arm is rotatably disposed to the coil block and the other end is connected to the magnet block, such that when the magnet blocks are interlocked, the swing arm rotates along the coil block to facilitate relative movement between the magnet block and the coil block.

25. The self-generating wireless switch according to claim 24, wherein the coil assembly comprises an iron core and a coil disposed around the iron core, wherein the magnetic assembly comprises two magnetic conductive members and a permanent magnetic member disposed between the two magnetic conductive members, the two magnetic conductive members having a length greater than that of the permanent magnetic member to form a magnetic gap therebetween, wherein one end of the iron core is disposed in the magnetic gap, so that when the magnetic assembly is moved in a linked manner, the iron core alternately contacts each of the magnetic conductive members in the magnetic gap, thereby generating an induced current in the coil.

26. A linkage method of a self-generating wireless switch is characterized by comprising the following steps:

(a) pressing a switch plate;

(b) pushing a driving plate to move by pressing the switch plate;

(c) a linkage support for driving a self-generating core in a linkage manner by the movement of the driving plate;

(d) the linkage of the linkage bracket drives a power generation device to generate electric energy; and

(e) by means of pressing the switch board and supplying electric energy to the power generation device, a touch control piece is triggered and a signal transmitting board is controlled to transmit a wireless control signal corresponding to the touch control piece.

27. The method of claim 26 wherein in said step (b) said drive plate is moved to compress a cushioned reset such that said cushioned reset stores potential energy.

28. The method of claim 27, wherein when the switch plate is released, the buffer return releases potential energy to urge the drive plate and the switch plate to return to a home position.

Technical Field

The invention relates to a self-generating wireless switch, in particular to a self-generating wireless switch with a linkage device, wherein a switch board of the self-generating wireless switch can be in linkage driving with a self-generating kernel of self-generating to generate electric energy through linkage of the linkage device.

Background

Conventional switches are primarily wired directly or powered by batteries. As electrical equipment is widely used, the electrical equipment has higher requirements on the range of use and functionality of the switch. However, the wired power supply narrows the range of use of the switch and reduces the flexibility of use of the switch. And rely on the traditional switch of battery, must lead to the fact a large amount of discarded batteries correspondingly when using a large amount of batteries, this undoubtedly can aggravate environmental pollution, is unfavorable for green.

At present, a plurality of self-generating switches exist in the market, because the conventional multi-switch plate type self-generating switch cannot utilize one power generation core to supply a plurality of switch plates to work, most of the multi-switch plate type self-generating switches can configure the number of the power generation cores according to the number of the switch plates, so that the power generation cores are suitable for being driven by the switch plates with corresponding sizes to generate electric energy. That is to say, because the size of the self-generating kernel can not be adapted to the switch boards with various sizes, the multi-switch-board self-generating switch can not utilize one generating kernel to supply power. In other words, the generating core of the current self-generating switch has low universality and cannot be adapted to self-generating switches with various sizes. Specifically, the power generation core of the self-power generation switch is generally provided with a fixed size, and when the self-power generation switch is assembled in self-power generation switches of different sizes, since the size of the switch board of the self-power generation switch is not matched with the size of the power generation core, a situation that the switch board cannot drive the power generation core to generate electric energy in a linkage mode may occur, and therefore the self-power generation switch is in a failure mode. However, in the field of the self-generating switch, if different power generation cores are configured according to different sizes of the switch boards, various power generation cores need to be arranged, which increases the manufacturing difficulty of the power generation cores and also greatly increases the manufacturing cost of the self-generating switch. And various power generation cores can not be used alternately, so that the use of the cores of the self-generating switch is limited and the waste of resources is caused.

Disclosure of Invention

An object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the self-generating wireless switch includes a linkage device, wherein a switch board of the self-generating wireless switch can be linked to drive a self-generating core of the self-generating wireless switch to generate electric energy by linkage of the linkage device, so as to provide electric energy output for the self-generating wireless switch, thereby facilitating the self-generating wireless switch to operate in a battery-free manner.

Another object of the present invention is to provide a self-generating wireless switch and a method for operating the same, in which the self-generating wireless switch operates without a battery, thereby providing an environment-friendly self-generating wireless switch.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein linkage of the self-generating core by the switch board is not limited by the size of the switch board by linkage of the linkage device, so that the self-generating core is suitable for the self-generating wireless switches of various sizes.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the linkage is disposed under the switch board and has a size adapted to the size of the switch board, so that the linkage can be moved by the switch board when any position of the switch board is pressed, that is, the self-generating core can be driven to generate electric energy by linkage when any position of the switch board is pressed.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein a plurality of switch boards can drive the same self-generating core to generate electric energy by linkage of the linkage device, that is, the self-generating wireless switch can supply the plurality of switch boards with one self-generating core, thereby avoiding complexity of layout of the plurality of self-generating cores and reducing cost of the self-generating wireless switch, and thus providing the self-generating wireless switch with convenient installation and low cost.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the linkage device includes two driving plates, and the size of each driving plate is adapted to the size of the corresponding switching plate, so that when the switching plate is pressed, the corresponding driving plate can be pushed to move, thereby facilitating the linkage driving of the self-generating core by the switching plate.

Another object of the present invention is to provide a self-generating wireless switch and a method for operating the same, wherein the self-generating core includes a linkage bracket and a power generating device coupled to the linkage bracket, and two driving plates are linked to the linkage bracket, so that when any one of the driving plates is pressed, the driving plates move downward to push the linkage bracket to move downward, and the linkage bracket drives the power generating device to generate electric energy in a balanced manner.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the linkage bracket of the self-generating core includes two linkage arms, the two linkage arms are connected in linkage with each other and are respectively disposed corresponding to positions of the driving plates, so that when any one of the driving plates is pressed, the corresponding linkage arm is driven in linkage to link the other linkage arm, and thus the two linkage arms drive the power generation device to generate electric energy in a balanced manner.

Another object of the present invention is to provide a self-generating wireless switch and a method for operating the same, wherein each driving plate is provided with a recess to provide an operating space for the driving plate to drive each linkage arm.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein each of the driving plates is configured as a wing plate and has a driving portion and a pivoting portion, wherein when the switching plate is pressed, the pivoting portion is pivoted so that the driving portion can drive the linkage arm downward.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the self-generating wireless switch includes a bottom case, wherein the driving plate is pivotally disposed at both sides of the linkage bracket to the bottom case, and when the switching plate is pressed, the driving plate corresponding to the switching plate is pushed to move downward toward the self-generating core, thereby linkage-driving the self-generating core to generate electric energy.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the linkage device further includes two buffering reset members, each of the buffering reset members is disposed under each of the driving plates to elastically support the driving plate, and a user can have a good pressing feeling when pressing the switching plate by a buffering action of an elastic supporting force of the buffering reset member on the switching plate.

Another object of the present invention is to provide a self-generating wireless switch and a method for operating the same, wherein a supporting groove is formed at a bottom of each of the driving plates, and each of the supporting grooves is adapted to each of the buffer restoring members so that each of the buffer restoring members elastically supports each of the driving plates in each of the supporting grooves.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the switch board is integrally balanced by the balanced support of the two buffering reset pieces to the switch board, so that the switch board can be driven by the linkage device to generate electric energy by the self-generating core in a balanced manner when the switch board is pressed.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein when the switch board is pressed, the two buffer resetting members are pressed by the two driving boards to store potential energy, and when the switch board is released, the two buffer resetting members can release the potential energy to drive the two driving boards to return to the original positions, and then drive the switch board to return to the original positions, thereby providing the self-generating wireless switch with the automatic resetting switch board.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, in which the linkage device has a simple structure and is easy to manufacture, so that the self-generating core can be economically adapted to the self-generating wireless switches of various sizes.

Another object of the present invention is to provide a self-generating wireless switch and a method of interlocking the same, in which the operation of generating electric power by being pressed conforms to the conventional operation habit of a user.

Another object of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the bottom case further extends with a plurality of stoppers, the stoppers can limit a pivoting angle of the driving plate by abutting a pivoting path of the driving plate against the driving plate, and the driving plate is limited by abutting the driving plate against the pivoting path of the driving plate by the stoppers to have an angle smaller than 30 ° for better pressing feeling while satisfying a power supply amount of the self-generating wireless switch.

Another object of the present invention is to provide a self-generating wireless switch and a method for operating the same, wherein the self-generating wireless switch is configured as a self-generating wireless switch, and the self-generating wireless switch can be driven to transmit different wireless control signals corresponding to different pressing of the switch board by the power supply of the self-generating core.

Another objective of the present invention is to provide a self-generating wireless switch and a linkage method thereof, wherein the self-generating wireless switch further includes a signal transmitting unit, wherein the signal transmitting unit includes a plurality of touch control members corresponding to the switch boards, and when any one of the switch boards is pressed to drive the self-generating core to generate electric energy, the touch control member corresponding to the switch board is touched to drive the signal transmitting unit to transmit a corresponding wireless control signal.

To achieve at least one of the above objects, the present invention provides a self-generating wireless switch, including:

at least one switch board;

a linkage, wherein the linkage is coupled under the switch plate to be capable of being moved in linkage when the switch plate is pressed;

a self-generating core, wherein the self-generating core is coupled to the linkage device to be driven by the linkage device to generate electric energy when the switch board is pressed; and

the signal transmitting unit comprises at least one touch control piece and a signal transmitting plate, wherein the touch control piece is arranged corresponding to the switch board, the signal transmitting plate is electrically connected to the self-generating core, when the switch board is pressed, the linkage device can be driven by the switch board in a linkage mode to drive the self-generating core to generate electric energy, the touch control piece is pressed by the switch board to be triggered, and the signal transmitting plate is controlled to transmit a wireless control signal corresponding to the triggered touch control piece through the electric energy supply of the self-generating core.

In an embodiment of the present invention, the self-generating wireless switch further includes a bottom case, wherein the self-generating core is disposed on the bottom case, wherein the linkage device includes two driving plates, which are pivotally disposed on the bottom case at two sides of the self-generating core, respectively, wherein when the switching plate is pressed, the driving plate corresponding to the switching plate is pushed to move downward toward the self-generating core, thereby cooperatively driving the self-generating core to generate electric energy.

In an embodiment of the present invention, the switch board has at least one pushing ridge extending from a position corresponding to the driving board, so that when the switch board is pressed, the pushing ridge of the switch board pushes the driving board to move.

In an embodiment of the present invention, the bottom case is provided with a plurality of supporting members, each of the supporting members is provided with a pivot hole, wherein a pivot shaft extends from each of two sides of the driving plate, and each of the pivot shafts is provided in the corresponding pivot hole, so that the driving plate is pivotably provided in the bottom case.

In an embodiment of the present invention, the bottom case is provided with a plurality of supporting members, each of the supporting members extends to form a pivot shaft, wherein two sides of the driving plate are respectively provided with a pivot hole, and each of the pivot shafts is disposed in the corresponding pivot hole, so as to form a state that the driving plate is pivotably disposed in the bottom case.

In an embodiment of the present invention, the self-generating core includes a linkage bracket and a power generating device coupled to the linkage bracket, wherein the two driving plates are respectively disposed on the linkage bracket, so that when the driving plates are driven by the switch plate to move downwards, the driving plates can push the linkage bracket to move downwards towards the power generating device, and the linkage bracket drives the power generating device to generate electric energy in a linkage manner.

In an embodiment of the present invention, a groove is disposed at a bottom of each of the driving plates, wherein the linkage bracket includes two linkage arms, the two linkage arms are connected in a linkage manner and disposed below the corresponding grooves, respectively, and when any one of the driving plates is pushed to move downward, the linkage arm corresponding to the driving plate is driven to drive the other linkage arm in a linkage manner, so that the two linkage arms drive the power generation device to generate electric energy in a balanced manner.

In an embodiment of the present invention, each of the driving plates has a driving portion and a pivoting portion extending from the driving portion, wherein the recess is disposed at a bottom of the driving portion, wherein when the driving plate is pushed, the pivoting portion of the driving plate pivots so that the driving portion can drive the linkage arm downward.

In an embodiment of the present invention, the pivot portion of the driving plate has an inclined surface, so that the driving plate is an airfoil plate.

In an embodiment of the present invention, each of the two buffering reset members is disposed between the driving plate and the bottom casing to elastically support the driving plate, wherein when the switch plate is pressed, the corresponding buffering reset member is pressed to store potential energy, and when the switch plate is released, the buffering reset member releases the potential energy to drive the corresponding driving plate and the corresponding switch plate to return to the original positions.

In an embodiment of the invention, the bottom casing is provided with two limiting members, wherein each limiting member is respectively arranged corresponding to a position of the buffer reset member so as to fix the position of the buffer reset member.

In an embodiment of the present invention, a supporting groove is disposed at a bottom of each of the driving plates, and the buffer reset members are disposed in the corresponding supporting grooves to elastically support the driving plates.

In an embodiment of the present invention, a supporting column extends from a bottom of each of the driving plates, wherein the supporting columns are respectively disposed on the corresponding buffering reset pieces so that the buffering reset pieces can elastically support the driving plates.

In an embodiment of the present invention, the buffer restoring member is configured as a spring.

In an embodiment of the present invention, the bottom casing further extends with a plurality of stoppers, each stopper has an extending end extending from the bottom casing and a stopping end extending from the extending end to a pivot path of the driving plate, so that the stopping end can abut against the driving plate in the pivot path of the driving plate to limit a pivot angle of the driving plate, and the abutting of the pivot path of the driving plate against the driving plate by the stopping end limits the pivoting angle of the driving plate to be less than 30 °.

In an embodiment of the invention, the self-generating wireless switch further includes a touch-control piece protection cover, wherein the touch-control piece protection cover is covered on the signal transmitting unit and used for protecting the touch-control piece.

In an embodiment of the invention, the touch member protection cover is provided with a plurality of operation slots and a shielding member extends from each operation slot, each shielding member is disposed at a position corresponding to the touch member and is made of an elastic material, wherein when the switch board is pressed, the shielding member is pressed to trigger the corresponding touch member downwards.

In an embodiment of the invention, the touch control member protection cover is provided with an installation shaft, two sides of the switch board are respectively provided with an installation groove, and the switch board is clamped on the installation shaft of the touch control member protection cover through the installation grooves, so that the switch board can tilt along the installation shaft, and the linkage device can be driven when any end of the switch board is pressed.

In an embodiment of the invention, the self-generating core further includes a supporting seat, wherein the supporting seat has a plurality of positioning members, an installation chamber is disposed between the plurality of positioning members, and the linkage bracket and the power generating device are disposed in the installation chamber.

In an embodiment of the invention, two sides of each linkage arm of the linkage bracket are respectively provided with a rotating shaft, wherein each positioning element of the supporting seat is respectively provided with a rotating groove, and each rotating shaft is arranged in the rotating groove so as to rotate in the rotating groove when the linkage arms are linked.

In an embodiment of the present invention, the self-generating core further includes a reset element, and the reset element is disposed below the two linkage arms to store potential energy when the linkage arms are pushed to move downward and release the potential energy when the linkage arms are released, so that the linkage arms return to the original position.

In an embodiment of the present invention, the reset member is configured as a torsion spring.

In an embodiment of the present invention, the power generation device includes an energy storage member coupled to the linkage bracket, a magnetic assembly connected to the energy storage member, and a coil assembly, wherein when the linkage bracket is driven, the energy storage member is linked to store potential energy and drive the magnetic assembly to move, so that the magnetic assembly and the coil assembly generate relative motion to generate electric energy in the coil assembly.

In an embodiment of the present invention, the power generation device further includes a swing arm, wherein one end of the swing arm is rotatably disposed on the coil assembly and the other end is connected to the magnet assembly, so that when the magnet assembly is linked, the swing arm rotates along the coil assembly to facilitate the relative movement between the magnet assembly and the coil assembly.

In an embodiment of the present invention, the coil assembly includes an iron core and a coil disposed around the iron core, wherein the magnetic assembly includes two magnetic conductive members and a permanent magnetic member disposed between the two magnetic conductive members, a length of the two magnetic conductive members is greater than a length of the permanent magnetic member to form a magnetic gap between the two magnetic conductive members, and one end of the iron core is disposed in the magnetic gap, so that when the magnetic assembly is moved in a linkage manner, the iron core alternately contacts each of the magnetic conductive members in the magnetic gap, thereby generating an induced current in the coil.

The invention also provides a linkage method of the linkage device of the self-generating wireless switch, which comprises the following steps:

(a) pressing a switch plate;

(b) pushing a driving plate to move by pressing the switch plate;

(c) a linkage support for driving a self-generating core in a linkage manner by the movement of the driving plate;

(d) the linkage of the linkage bracket drives a power generation device to generate electric energy; and

(e) by means of pressing the switch board and supplying electric energy to the power generation device, a touch control piece is triggered and a signal transmitting board is controlled to transmit a wireless control signal corresponding to the touch control piece.

In an embodiment of the present invention, in the step (b), when the driving plate moves, a buffer reset member is pressed to store potential energy in the buffer reset member.

In an embodiment of the present invention, when the switch board is released, the buffer resetting member releases potential energy to push the driving board and the switch board to return to the original positions.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

Drawings

Fig. 1 is a perspective view of the self-generating wireless switch according to a preferred embodiment of the present invention.

Fig. 2 is a partial exploded view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 3 is a partial exploded view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 4 is a partial exploded view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 5A is a schematic half-sectional structure view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 5B is a schematic half-sectional structure view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 6A is a schematic cross-sectional view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 6B is a schematic cross-sectional view of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 7 is a partial exploded view of a self-generating core of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 8A is an enlarged side view of the self-generating core of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 8B is an enlarged side view of the self-generating core of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 9 is a partial exploded view of a power generation device of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Fig. 10 is a schematic half-sectional view of the power generation device of the self-generating wireless switch according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "vertical," "lateral," "up," "down," "front," "back," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, the above terms should not be construed as limiting the present invention.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1 to 4 of the drawings, the self-generating wireless switch according to a preferred embodiment of the present invention is illustrated, as shown in fig. 1 to 4, and includes at least one switch board 10, a linkage 20, a self-generating core 30, and a signal transmitting unit 40, wherein the linkage 20 is coupled below the switch board 10 to be capable of being interlocked and moved when the switch board 10 is pressed, wherein the self-generating core 30 is coupled to the linkage 20 to be capable of being interlocked and driven by the linkage 20 to generate electric power when the switch board 10 is pressed, wherein the signal transmitting unit 40 includes at least one touch control 41 provided corresponding to the switch board 10 and a signal transmitting board 42 electrically connected to the self-generating core 30, wherein when the switch board 10 is pressed, the linkage device 20 can be moved by the switch board 10 to drive the self-generating core 30 to generate electric energy, the touch control part 41 is pressed by the switch board 10 to be triggered, and the signal transmitting board 42 is controlled to transmit a wireless control signal corresponding to the triggered touch control part by the supply of the electric energy of the self-generating core 30.

It should be noted that, in the preferred embodiment of the present invention, the self-generating wireless switch includes two switch boards 10, wherein when any one of the switch boards 10 is pressed, the linkage 20 can be driven by the switch board 10 in linkage. In some embodiments of the present invention, the self-generating wireless switch may also include one or more switch boards 10, that is, the self-generating wireless switch may be a single-control, double-control, four-control or multi-control self-generating wireless switch, and the number of switch boards 10 is not to be construed as a limitation to the present invention.

It should be noted that, the touch control members 41 of the signal transmitting unit 40 are correspondingly disposed below the switch board 10 and the number thereof may be set to one, two, four or more, when one switch board 10 is pressed, the touch control members 41 corresponding to the switch board 10 are pressed by the switch board 10 to be triggered, so as to control the signal transmitting board 42 to transmit the corresponding wireless control signals, and therefore, the number of the touch control members 41 is not to be construed as a limitation to the present invention.

It is worth mentioning that the signal transmitting board 42 may be implemented as a single chip, wherein the touch control component 41 may be, but not limited to, a conductive film switch, a light touch switch, a detection switch, a micro switch, a conductive rubber switch, a metal contact switch, a switch made of semiconductor material, and the like.

Specifically, as shown in fig. 2 and 3, in this preferred embodiment of the present invention, the switch board 10 is configured as a rocker switch board 10, and correspondingly, each rocker switch board 10 is configured with two touch control components 41, specifically, two touch control components 41 are respectively configured below two ends of the rocker switch board 10, and the self-generating wireless switch can be controlled to transmit different wireless control signals by triggering different touch control components 41, so that two ends of the rocker switch board 10 can respectively correspond to different control modes, in other words, pressing any end of the rocker switch board 10 can drive the signal transmitting unit 40 to transmit different wireless control signals.

In some embodiments of the present invention, the switch board 10 may correspond to only one touch control 41, that is, one switch board 10 may correspond to one control mode, which is not limited in the present invention.

It should be noted that, as shown in fig. 2 and fig. 3, the self-generating wireless switch further includes a touch-control protection cover 50, wherein the touch-control protection cover 50 is covered on the signal transmitting unit 40 for protecting the touch-control 41.

It can be understood that, in the case where the touch control 40 is repeatedly pressed when the switch board 10 is repeatedly pressed, there is a possibility that the touch control 40 is damaged when the switch board is repeatedly pressed, and therefore, in order to prevent the touch control 40 from being damaged and to extend the service life of the self-generating wireless switch, the self-generating wireless switch of the present invention is provided with the touch control protection cover 50 for protecting the touch control 41.

Specifically, the touch control protection cover 50 is provided with a plurality of operation slots 52 and a shielding member 51 extending from each operation slot, each shielding member 51 is disposed at a position corresponding to the touch control member 41 and is made of an elastic material, wherein when the switch board 10 is pressed, the shielding member 51 is pressed to trigger the corresponding touch control member 41 downward, and when the switch board 10 is released, the shielding member 51 returns to the original position to facilitate the return of the touch control member 41.

More specifically, when the switch board 10 is pressed, the shielding member 51 is pressed to be elastically deformed, so as to move downwards to trigger the touch control member 41, and when the switch board 10 is released, the restoring force of the shielding member 51 enables the shielding member 51 to restore to the original state, so that the acting force on the touch control member 41 disappears, so that the touch control member 41 automatically restores to the original state, and thus, the touch control member 41 is prevented from being repeatedly pressed for many times to cause a failure condition. It can be understood that the shielding member 51 can prevent the acting force of the switch board 10 from directly acting on the touch control member 41, that is, the shielding member 51 can play a role of buffering when the switch board 10 triggers the touch control member 41, so as to prevent the touch control member 41 from being damaged, and can also enable a user to have a better pressing feeling.

It should be noted that the touch-control member protection cover 50 is provided with a mounting shaft 53, the switch board 10 is provided with a mounting groove 101 at each of both sides thereof, and the switch board 10 is engaged with the mounting shaft 53 of the touch-control member protection cover 50 through the mounting groove 101, so that the switch board 10 can be tilted along the mounting shaft 53, and thus the linkage 20 can be driven when any one end of the switch board 10 is pressed, thereby forming the rocker switch board 10.

It should be understood that, in some embodiments of the present invention, the mounting shaft 53 and the mounting groove 101 may also be disposed in opposite directions, that is, the touch control protection cover 50 may also be disposed with two mounting grooves 101, and the switch plate 10 is disposed with the mounting shaft 53, so that the switch plate 10 is disposed in the touch control protection cover 50 in a manner of being tiltable by the mutual engagement of the mounting groove 101 and the mounting shaft 53, which is not limited by the present invention.

Alternatively, the touch piece protection cover 50 may be made of, but not limited to, plastic, rubber, etc.

Further, the linkage device 20 includes two driving plates 21, wherein the two driving plates 21 are disposed below the switch board 10 and the two driving plates 21 are disposed on two sides of the self-generating core 30, respectively, so that when any end of the switch board 10 is pressed, the driving plate 21 corresponding to the switch board 10 can be pushed to move to drive the self-generating core 30 to generate electric energy in linkage.

It can be understood that both ends of the switch board 10 may correspond to one of the driving boards 21, respectively, so that when any one end of the switch board 10 is pressed, the driving board 21 corresponding to the one end of the switch board 10 can be pushed to move downward toward the self-generating core 30, whereby the multi-controlled self-generating switch can supply electric energy to the signal transmitting unit 40 by one self-generating core 30 to transmit different wireless control signals, and thus the self-generating switch of the present invention avoids the complexity of the layout of the plurality of self-generating cores 30 and the plurality of switch boards 10 and can accordingly reduce the production cost of the self-generating wireless switch.

It should be understood that, in the preferred embodiment of the present invention, the self-generating wireless switch is configured as a four-control self-generating wireless switch, specifically, the four touch control members 41 are configured as four, and two of the four touch control members 41 are respectively configured corresponding to two ends of the switch board 10, so that when any one end of the switch board 10 is pressed, the signal transmitting unit 40 can be correspondingly controlled to transmit the corresponding wireless control signal.

It is worth mentioning that, at least one pushing ridge 102 extends from the switch board 10 corresponding to the position of the driving board 21, so that when the switch board 10 is pressed, the pushing ridge 102 of the switch board 10 pushes the driving board 21 to move.

Furthermore, the self-generating wireless switch further includes a bottom case 11, and a receiving cavity 110 is disposed between the bottom case 11 and the switch board 10 for receiving the linkage 20, the self-generating core 30 and the signal transmitting unit 40.

Specifically, the self-generating core 30 is disposed on the bottom case 11, wherein the two driving plates 21 are pivotally disposed on the bottom case 11 at two sides of the self-generating core 30, respectively, and when the switch board 10 is pressed, the driving plate 21 corresponding to the switch board 10 is pushed to move downward toward the self-generating core 30, so that the self-generating core 30 is driven to generate electric energy in a linkage manner.

It should be noted that, the bottom shell 11 is provided with a plurality of supporting members 113, each supporting member 113 is provided with a pivot hole 112, wherein a pivot shaft 2122 extends from both sides of the driving plate 21, and each pivot shaft 2122 is disposed in the corresponding pivot hole 112, so as to form a state that the driving plate 21 is pivotably disposed on the bottom shell 11.

It should be noted that, in some embodiments of the present invention, the pivot shaft 2122 may be disposed on the support 113, wherein both sides of the driving plate 21 may be respectively disposed with the pivot holes 112, and each pivot shaft 2122 is disposed on the corresponding pivot hole 112, so as to form a state that the driving plate 21 is pivotably disposed on the bottom case 11, which is not limited in the present invention.

Further, the self-generating core 30 comprises a linkage bracket 31 and a generating device 32 coupled to the linkage bracket 31, wherein the two driving plates 21 are respectively disposed on the linkage bracket 31, so that when the driving plates 21 are pushed by the switch board 10 to move, the driving plates 21 can push the linkage bracket 31 to move downwards towards the generating device 32, and the linkage bracket 31 is linked to drive the generating device 32 to generate electric energy.

It should be noted that a groove 210 is disposed at the bottom of each driving plate 21, wherein the linking bracket 31 includes two linking arms 311, the two linking arms 311 are connected in a linking manner and disposed below the corresponding groove 210, respectively, when any one of the driving plates 21 is pushed to move downward, the linking arm 311 corresponding to the driving plate 21 is driven to drive the other linking arm 311 in a linking manner, so that the two linking arms 311 drive the power generation device 32 to generate electric energy in a balanced manner.

It can be understood that when any driving plate 21 is driven, the corresponding linkage arm 311 is driven to move downwards in a linkage manner, so as to link the other linkage arm 311 to move, and therefore, when any one of the two linkage arms 311 is driven, the other linkage arm 311 moves in a linkage manner, so that any driving plate 21 can balance and drive the two linkage arms 311 to move downwards, and thus balance and drive the power generation device 32 to generate electric energy. In other words, pressing either end of the switch board 10 balances the ability to drive the generator 32 to generate electricity.

In addition, it is worth mentioning that each driving plate 21 has a driving portion 211 and a pivot portion 212 extending from the driving portion, wherein the groove 210 is disposed at the bottom of the driving portion 211, and when the driving plate 21 is pushed, the pivot portion 212 of the driving plate 21 pivots so that the driving portion 211 can drive the linkage arm 311 downward.

Specifically, the pivot shaft 2122 of the drive plate 21 is disposed on two sides of the drive portion 212, so that the pivot portion 212 of the drive plate 21 is pivotably disposed on the bottom case 11 via the pivot shaft 2122 and the pivot hole 112. The driving portion 212 of the driving plate 21 has an inclined surface 2121, so that the driving plate 21 is an airfoil-shaped plate, that is, the driving portion 211 of the driving plate 21 is higher than the pivoting portion 212 of the driving plate 21, so that when the switch board 10 is pressed, the pivoting portion 212 of the driving plate 21 pivots on the bottom case 11, thereby facilitating the driving portion 211 of the driving plate 21 to move downward to push the linkage 20.

Further, the linkage 20 further includes two buffering reset members 22, wherein each buffering reset member 22 is disposed between the driving plate 21 and the bottom case 11 to elastically support the driving plate 21, wherein when the switch board 10 is pressed, the corresponding buffering reset member 22 is pressed to store potential energy, and when the switch board 10 is released, the buffering reset member 22 releases the potential energy to drive the corresponding driving plate 21 and the switch board 10 to return to the original positions, so that the present invention provides the self-generating wireless switch having the switch board 10 in the automatic reset mode.

Specifically, in the preferred embodiment of the present invention, as shown in fig. 6A and 6B, a supporting groove 213 is respectively formed at the bottom of each of the driving plates 21, wherein each of the supporting grooves 213 is adapted to each of the reset cushioning members 22 so that each of the reset cushioning members 22 elastically supports each of the driving plates 21 in each of the supporting grooves 213. It can be understood that, in addition to the buffer reset member 22 for elastically supporting the driving plate 21 and restoring the driving plate 21 and the switch plate 10 to the original positions by the restoring force of the buffer reset member 22, the buffer reset member 22 is also used for balancing the movement of the driving plate 21 when the driving plate 21 is driven, so that a user can have a good pressing feeling.

In some embodiments of the present invention, a supporting column may also extend from a bottom of each of the driving plates 21, wherein the supporting columns are respectively disposed on the corresponding buffering reset pieces 22 so that the buffering reset pieces 22 can elastically support the driving plates 21, which is not limited in this respect.

It should be mentioned that, the bottom shell 11 is provided with two limiting members 111, wherein each limiting member 111 is respectively arranged corresponding to the position of the buffering reset member 22 for fixing the position of each buffering reset member 22.

Specifically, the limiting member 111 is a cross member extending from the bottom case 11, wherein the buffering restoring member 22 is configured as a spring, and the spring is sleeved on the limiting member 111 to be limited by the limiting member 111 along the radial direction.

In addition, it should be noted that the buffering reset element 22 may also be configured as an elastic sheet, and the limiting element 111 may also be in other shapes and structures, which is not limited in the present invention.

In particular, a plurality of stoppers 114 further extend from the bottom case 11, each stopper 114 has an extending end 1141 extending from the bottom case 11 and a stopping end 1142 extending from the extending end 1141 to the pivot path of the driving plate 21, so that the stopping end 1142 can abut against the driving plate 21 in the pivot path of the driving plate 21 to limit the pivot angle of the driving plate 21, and the abutting of the stopping end 1142 against the driving plate 21 in the pivot path of the driving plate 21 limits the pivot angle of the driving plate 21 to be less than 30 °.

It can be understood that, when the driving plate 21 is pushed to move downwards, the driving plate 21 pivots on the supporting member 113 of the bottom case 11, wherein when the driving plate 21 pivots by an angle less than 30 °, the power generated by the power generation device 32 is driven in a linkage manner to generate enough power for the self-generating wireless switch to transmit the wireless control signal at least once, and when the driving plate 21 pivots by an angle less than 30 °, a user can have a better pressing hand feeling. That is, the blocking member 114 is used to limit the pivoting angle of the driving plate 21 to less than 30 °, so as to satisfy the power supply amount, facilitate the user to have a better pressing feeling, and conform to the conventional pressing habit.

Further, wherein the power generating device 32 is electrically connected to the signal transmitting board 42 of the signal transmitting unit 40 to provide power to the signal transmitting board 42, wherein when the switch board 10 is pressed once, the power generating device 32 is driven to generate power at least for the signal transmitting board 42 to transmit the wireless control signal at least once.

In particular, wherein the dimensions of each of said driving plates 21 are adapted to the dimensions of said switching plate 10 so as to be pushed by said switching plate 10. Specifically, in this preferred embodiment of the present invention, the length of the driving plate 21 is set according to the entire width of the switch board 10 of the self-generating wireless switch, whereby the driving plate 21 can be pushed to move downward when any one of the switch boards 10 is driven.

Therefore, it can be understood that, in practical applications, the size of the driving plate 21 of the linkage device 20 may be set according to the size of the switch board 10, so that it can be satisfied that the switch board 10 drives the self-generating core 30 to generate electric energy by the linkage device 20 in a linkage manner, and thus, electric energy required by the signal transmitting unit 40 to transmit different wireless control signals can be provided by one self-generating core 30 when a plurality of switch boards 10 are pressed, thereby solving the problem that the self-generating core 30 is not common in practical applications, and simplifying the installation process of the self-generating wireless switch.

As shown in fig. 5A and fig. 6A, which are schematic diagrams of an initial state of the self-generating wireless switch, it can be seen that in this state, the two driving plates 21 of the linkage device 20 are elastically supported by the buffer reset member 22 and are blocked and limited by the blocking member 114 of the bottom case 11 to be maintained within 30 ° from the bottom case 11, wherein there is a certain angle between the two linkage arms 311 of the linkage bracket 31 and the bottom case 11, respectively, wherein when any end of the switch board 10 is pressed to drive the corresponding driving plate 21 to move downwards, the linkage arm 311 corresponding to the driving plate 21 is pushed to move downwards and is linked with the other linkage arm 311 to move downwards, so that the two linkage arms 311 of the self-generating core 30 move downwards towards the bottom case 11 to drive the generating device 32 to generate electric energy in a balanced manner, as shown in fig. 5B and 6B.

It should be noted that, as shown in fig. 5B and fig. 6B, in the pressed state of the self-generating wireless switch, the buffering reset piece 22 of the linkage 20 corresponding to the driving plate 21 is pressed to store potential energy. When the switch board 10 is released, the buffer reset piece 22 can release potential energy to return the driving board 21 and the switch board 10 to the original positions, i.e., return the self-generating wireless switch to the initial state.

In addition, when the switch board 10 is pressed to move downwards, the power generation device 32 generates power and supplies the power to the signal transmitting board 42 of the communication unit, and the touch control 41 is triggered by the switch board 10 and transmits the corresponding wireless control signal with the power supplied by the power generation device 32.

As shown in fig. 7, the self-generating core 30 of the self-generating wireless switch according to the above preferred embodiment of the present invention is illustrated, wherein the self-generating core 30 further includes a supporting base 33, wherein the supporting base 33 has a plurality of positioning members 331, an installation chamber 330 is disposed between the plurality of positioning members 331, and wherein the linking bracket 31 and the power generating device 32 are disposed in the installation chamber 330.

Further, two sides of each linkage arm 311 of the linkage bracket 31 are respectively provided with a rotating shaft 312, wherein each positioning member 331 of the supporting seat 33 is respectively provided with a rotating groove 332, wherein the rotating shaft 312 is arranged in the corresponding rotating groove 332 so as to be capable of rotating in the rotating groove 332 when the linkage arms 311 are linked, thereby facilitating the two linkage arms 311 to be driven in a balanced manner.

Furthermore, the self-generating core 30 further comprises a reset element 34, wherein the reset element 34 is arranged below the two linkage arms 311 to store potential energy when the linkage arms 311 are pushed to move downwards and release potential energy when the linkage arms 311 are released, so that the linkage arms 311 return to the original position.

Specifically, the reset part 34 elastically supports the two linkage arms 311 in the initial state of the self-generating wireless switch, and stores potential energy in the pressed state of the self-generating wireless switch, and further when the switch board 10 is released, the reset part 34 releases the potential energy to return the two linkage arms 311 to the original position.

It should be noted that the restoring member 34 can be, but not limited to, a torsion spring or a spring plate.

In addition, it should be noted that each of the linkage arms 311 has a driving arm 3111 and two transmission arms 3112 respectively extending from two ends of the driving arm 3111, so that each of the linkage arms 311 is a "U" shaped arm, wherein the transmission arms 3112 of the two linkage arms 311 are mutually connected in a transmission manner to form a state that the two linkage arms 311 are mutually linked.

Alternatively, the two linking arms 311 may be connected to each other, engaged with each other, or engaged with each other, but the invention is not limited thereto.

As shown in fig. 8A, in the initial state of the self-generating wireless switch, the two linkage arms 311 of the self-generating core 30 and the supporting base 33 form a certain angle, when the switch board 10 is pressed, the two linkage arms 311 rotate in the rotating groove 332 through the rotating shaft 312 and are driven in a balanced manner, so as to drive the power generation device 32 in a linkage manner to generate electric energy, and at this time, the angle between the two linkage arms 311 and the supporting base 33 changes, as shown in fig. 8B.

It is worth mentioning that, as shown in fig. 8B, in the pressed state of the self-generating wireless switch, the reset piece 34 of the self-generating core 30 is pressed by the two linkage arms 311 to store potential energy. When the two linkage arms 311 are released, the reset piece 34 releases potential energy to enable the two linkage arms 311 to return to the original positions, so that the power generation device 32 is linked by the linkage bracket 31 again to generate electric energy.

Further, as shown in fig. 9 and 10, the power generation device 32 includes an energy storage member 321 coupled to the linking bracket 31, a magnetic assembly 322 connected to the energy storage member 321, and a coil assembly 323, wherein when the linking bracket 31 is driven, the energy storage member 321 is linked to store potential energy and drive the magnetic assembly 322 to move, so that the magnetic assembly 322 and the coil assembly 323 generate relative motion to generate electric energy in the coil assembly 323.

In particular, the power generation device 32 further comprises a swing arm 324, wherein one end of the swing arm 324 is rotatably disposed on the coil assembly 323 and the other end is connected to the magnet assembly 322, so that when the magnet assembly 322 is coupled, the swing arm 324 rotates along the coil assembly 323 to facilitate the relative movement between the magnet assembly 322 and the coil assembly 323.

Further, the coil assembly 323 includes an iron core 3231 and a coil 3232 disposed around the iron core 3231, wherein the magnetic assembly 322 includes two magnetic conductive members 3221 and a permanent magnetic member 3222 disposed between the two magnetic conductive members 3221, a length of the two magnetic conductive members 3221 is greater than a length of the permanent magnetic member 3222 to form a magnetic gap 3223 between the two magnetic conductive members 3221, and an end of the iron core 3231 is disposed in the magnetic gap 3223, so that when the magnetic assembly 322 is moved in an interlocking manner, the iron core 3231 alternately contacts each of the magnetic conductive members 3221 in the magnetic gap 3223, thereby generating an induced current in the coil 3232.

It should be noted that the power generation device 32 further includes two mounting members 325, and the two mounting members 325 are disposed on two sides of the magnetic assembly 322 for fixing the two magnetic conductive members 3221 of the magnetic assembly 322.

In summary, the linkage device 20 of the present invention has a simple structure, which facilitates the actual manufacturing and installation of the self-generating wireless switch, and facilitates the self-generating core to be adapted to the self-generating wireless switches of various sizes in an economical and simple manner.

The present invention also provides a linkage method of a linkage device 20 of a self-generating wireless switch, comprising the following steps:

(a) pressing a switch plate 10;

(b) pushing a driving plate 21 to move by pressing the switch plate 10;

(c) a linkage bracket 31 for driving a self-generating core 30 in linkage by the movement of the driving plate 21;

(d) the linkage of the linkage bracket 31 drives a power generation device 32 to generate electric energy; and

(e) by pressing the switch board 10 and supplying power to the power generating device 32, a touch control part 41 is triggered and a signal emitting board 42 is controlled to emit a wireless control signal corresponding to the touch control part 41.

It is worth mentioning that, when the switch board 10 is pressed, the touch control 41 is triggered and turns on the operating circuit of the signal transmitting board 42, and the signal transmitting board 42 transmits the wireless control signal corresponding to the triggered touch control by the electric energy generated by the power generation device 32 being driven, so it can be understood that the signal transmitting board 42 can transmit the wireless control signal when the power generation device 32 is driven to generate the electric energy, that is, the signal transmitting board 42 is powered on.

It is also worth mentioning that in the step (d), the electric energy generated by the power generation device 32 is enough for the signal transmitting board 42 to transmit the wireless control signal at least once, that is, the electric energy generated by driving the power generation device 32 once is enough for the signal transmitting board 42 to transmit the wireless control signal once.

Specifically, in the step (b), when the driving plate 21 moves, a buffering reset piece 22 is pressed, so that the buffering reset piece 22 stores potential energy. Moreover, when the switch board 10 is released, the buffering reset piece 22 releases potential energy to push the driving board 21 and the switch board 10 to return to the original position.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.