CN210428800U - Self-powered wireless control system and self-powered transmitter thereof - Google Patents

Abstract

The utility model provides a self-power wireless control system and self-power transmitter thereof, wherein self-power transmitter includes a casing, an at least fine motion generator, an at least communication device, an at least drive key and an at least trigger device. The micro-motion generator is arranged in the shell and is driven to convert kinetic energy into electric energy, the communication device is electrically connected with the micro-motion generator, the communication device is provided with working electric energy by the micro-motion generator, the driving key is pivotally arranged in the shell, the triggering device is arranged on the driving key and the communication device in a transmission way, the triggering device is pressed by the driving key to buffer the driving acting force of the driving key, and the driving acting force is transmitted to the communication device to trigger the communication device.

Description

Self-powered wireless control system and self-powered transmitter thereof

Technical Field

The utility model relates to a self-power field especially relates to a self-power wireless control system and self-power transmitter thereof.

Background

The switch is the most basic electronic component for controlling electrical equipment in the field of electrical control, wherein the switch types comprise a wired control switch and a wireless control switch, and a wiring switch is widely adopted, and the method of pre-embedding wires is generally adopted in buildings.

The passive wireless switch is different from a switch of a pre-buried wire, does not need to use a battery or connect a power line, converts mechanical energy into electric energy through pressing or other modes, and then drives the wireless signal generating device to generate a wireless control signal so as to control the working state of electrical equipment in a circuit.

The existing self-powered wireless switch with a plurality of keys works in the following modes: in the method of directly pressing a sensor with a key, a user's pressing of the key directly applies a pressing force to the sensor, wherein the key presses the sensor based on the force applied by the user. In the use process of the self-powered wireless switch in the prior art, the pressing force is controlled by an operator, so that the acting force on the sensor when the key is pressed is controlled. The method has the defect that the sensor is easy to damage, and the reliability and the service life of the product are influenced. Because the user is difficult to control the pressing pressure when pressing the switch key, two adverse effects are usually caused due to the difference of the pressing pressure, and the sensor is damaged due to the overlarge pressing pressure; too little pressure tends to cause the key to fail to trigger the sensor and not generate a wireless signal.

Fig. 1 shows a passive wireless transmitting component in the prior art, wherein the passive wireless transmitting component is a mechanical key detection sensor. The passive wireless transmitting assembly comprises at least one self-generating electric device 10P, at least one key 20P, a housing assembly 30P, at least one micro switch 40P, and at least one communication circuit board 50P, wherein the micro switch 40P, the self-generating electric device 10P, and the communication circuit board 50P are disposed on the housing assembly 30P, and the key 20P is pivotally connected to the housing assembly 30P. At least one end of the case 20P is provided with a key bump 21P, when the key is pressed by force, the key drives the self-generating device 10P to move, and mechanical energy is converted into electric energy by the self-generating device 10P so as to enable the communication circuit board 50P to work. When the key 20P is driven, the key bump 21P presses the micro switch 40P to trigger the micro switch to operate, wherein the micro switch 40P generates a wireless control signal through the communication circuit board 50P.

In the wireless control switch of the prior art, when the button 20P is pressed, it is difficult to accurately control the on/off of the sensor due to the difference between the force and the speed, which results in a button information detection error. On the other hand, the key bump 21P frequently collides with the micro switch 40P for a long time, so that the micro switch 40P is easily damaged mechanically, thereby causing a control failure.

In summary, the obvious disadvantage of this way of operating the sensor is that it is easy to make the key detection information wrong, which easily results in the sensor being damaged. On the other hand, the structure in the prior art has extremely high requirements on the manufacturing precision, so that the yield of products is low.

SUMMERY OF THE UTILITY MODEL

One of the primary advantages of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the self-powered transmitter includes at least one command lever, wherein works as when the self-powered transmitter is pressed, the command lever buffers the acting force that the self-powered transmitter received, avoids the command button atress of the self-powered transmitter is too big.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the one end atress interference of command lever takes place the deformation bending, the other end of command lever triggers the instruction button, thereby by command lever buffering transmission extremely the effort of instruction button avoids self-powered transmitter triggers rigidly when the atress the instruction button is favorable to the protection the instruction button.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the command lever is a lever element, wherein when being close to the one end of the fulcrum to receive force, the command lever is bent, so that the other end of the command lever is bent around the fulcrum to trigger the command button, so as to buffer the command lever the driving force received by the self-powered transmitter.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the command lever is used as a lever element to drive the movement amount of one end of the command lever is smaller than the command lever touches the displacement amount of the command button, i.e. only needs to drive the command lever is displaced a bit, just accessible the leverage of the command lever triggers the command button, thereby improving the reliability of triggering the command button.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the self-powered transmitter is by when the command lever is forced to drive the interference, the command lever produces bending deformation, and pressure can not direct action promptly the instruction button of self-powered transmitter, by the command lever buffering the pressure that the instruction button bore has improved the reliability that the instruction button switches on, and avoid the self-powered transmitter pressure is too big and damages the instruction button.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the driving key and the command lever of the self-powered transmitter do not require special structure and expensive manufacturing equipment, which is beneficial for improving the manufacturing yield of the self-powered transmitter.

Another advantage of the present invention is to provide a self-powered wireless control system and self-powered transmitter thereof, wherein the self-powered transmitter the command lever is an elastic device, wherein when the command lever is pressed, the command lever supports under the elastic action the driving key of the self-powered transmitter, reducing the pressure borne by the command button.

The other advantages and features of the invention will be fully apparent from the following detailed description and realized by means of the instruments and combinations particularly pointed out in the appended claims.

According to the utility model discloses an aspect, can realize aforementioned purpose and other purposes and advantage the utility model discloses a self-power transmitter, include:

a housing;

at least one micro-motion generator, wherein the micro-motion generator is disposed in the housing, the micro-motion generator being driven to convert kinetic energy into electrical energy;

at least one communication device, wherein the communication device is electrically connected to the micro-motion generator, and the micro-motion generator provides working electric energy for the communication device; and

the trigger device can be stressed to be transmitted to the communication device, and the trigger device is pressed to buffer the driving acting force and transmit the driving acting force to the communication device to trigger the communication device in a buffering mode.

According to an embodiment of the present invention, the triggering device includes at least one triggering bracket and at least one command lever, wherein the command lever can be drivingly disposed on the triggering bracket, and thereby the command lever is supported by the triggering bracket, and the command lever is forced to bend and elastically deform, and the command lever conducts to the driving force of the communication device.

According to an embodiment of the present invention, the command lever is integrally formed on the trigger bracket, the command lever is driven to make a lever motion based on the trigger bracket, wherein the command lever is pressed to be bent and deformed to trigger the communication device.

According to an embodiment of the present invention, the command lever is pivotally disposed on the trigger bracket, the command lever is driven to make a lever motion based on the trigger bracket, wherein the command lever is triggered to trigger the communication device by being pressed to be bent.

According to an embodiment of the present invention, the command lever is movably disposed on the trigger bracket, the command lever is driven to move downward based on the trigger bracket, wherein the command lever pressed to be bent and deformed is touched to trigger the communication device.

According to the utility model discloses an embodiment, the command lever includes a drive end, certainly a transmission end and a command lever fulcrum that the drive end extends, the transmission end is located the distal end of command lever fulcrum, wherein the command lever fulcrum set up in trigger the support, wherein the command lever the drive end atress and drive the transmission end removes.

According to an embodiment of the present invention, the trigger device further includes a command lever driving block, the command lever driving block is disposed above the driving end of the driving lever.

According to an embodiment of the present invention, the trigger device further includes at least one instruction pressing projection, wherein the instruction pressing projection is disposed below the transmission end of the instruction lever, the instruction lever passes through the instruction pressing projection triggers the communication device, so as to pass through the instruction pressing projection increases the triggering distance of the instruction lever.

According to the utility model discloses an embodiment, the command lever is resilient means, the command lever is selected from: elastic device group composed of thin film metal and plastic.

According to an embodiment of the present invention, the self-powered transmitter further comprises a driving key, wherein the driving key is drivably pressed against the command lever of the triggering device, whereby the command lever is pressed by the driving key.

According to an embodiment of the present invention, the driving key is pivotably provided to the housing, whereby the housing supports the driving key to drive the command lever in a rotational manner.

According to the utility model discloses an embodiment, the drive key include a drive main part, set up in an at least information lug of drive main part, the information lug support press in trigger device's top, drive main part atress is pressed and is driven the information lug moves down, by the oppression of information lug trigger device.

According to an embodiment of the present invention, the driving key further comprises at least one power transmission rod, wherein the power transmission rod is driveably disposed in the driving body, and the driving body passes through the power transmission rod for driving the micro-motion generator to work.

According to an embodiment of the present invention, the driving key includes a driving portion and a pivoting portion extending integrally from the driving portion, the pivoting portion is connected to the housing, wherein the driving portion is pressed by a force and performs a one-way seesaw movement based on the pivoting portion.

According to an embodiment of the present invention, the driving key includes a pivot portion and two driving portions extending integrally from two ends of the driving portion, the pivot portion is connected to the housing, wherein the driving portion is pressed by a force and performs a bidirectional seesaw movement based on the pivot portion.

According to the utility model discloses an embodiment, the micro-gap generator includes a generator host computer and a generator drive arrangement, wherein the generator host computer is fixed in the casing, generator drive arrangement by driveably set up in the generator host computer, the drive of power transmission pole the generator drive arrangement motion, the generator host computer will generator drive arrangement's kinetic energy turns into the electric energy.

According to an embodiment of the present invention, the micro-motion generator further comprises a generator fixing unit and at least one reset device, wherein the generator fixing unit is fixed to the generator main body in the housing, wherein the reset device is disposed below the generator driving device to provide the force for resetting the generator driving device.

According to an embodiment of the present invention, the communication device includes a circuit board and at least one command button, wherein the command button is electrically connected to the circuit board, the command button is triggered and the circuit board transmits at least one wireless control signal, wherein the wireless control signal contains encoded information.

According to the utility model discloses an embodiment, communication device's instruction button is mechanical micro-gap switch, the instruction button is selected from: a conductive film switch, a light touch switch, a detection switch, a microswitch, a conductive rubber switch, a metal contact switch and a switch made of semiconductor materials.

According to the utility model discloses a further aspect, the utility model discloses a self-power wireless control system is further provided, include:

the self-powered transmitter as recited in any of the above, wherein the self-powered transmitter transmits at least one wireless control signal in a self-generating manner; and

at least one wireless receiving device, wherein the wireless receiving device receives the wireless control signal, so that the wireless receiving device controls the working state of the electric equipment based on the wireless control signal.

According to another aspect of the present invention, the present invention further provides a wireless transmission method of a self-powered transmitter, wherein the wireless transmission method comprises the following steps:

(a) the force is applied to drive a micro-motion generator so that the micro-motion generator can convert kinetic energy into electric energy; and

(b) the method comprises the steps of pressing an instruction rod of a trigger device, buffering driving acting force by the instruction rod, and triggering an instruction button of a communication device so that the communication device can transmit at least one wireless control signal, wherein the wireless control signal comprises coded information.

According to an embodiment of the present invention, in the above wireless transmitting method, a driving key of the self-powered transmitter is pressed, and the driving key transmits a driving force to the micro-motion generator and the triggering device, so as to drive the micro-motion generator to generate electricity and buffer the driving force of the driving key by the triggering device, so as to trigger the command button of the communication device.

According to an embodiment of the present invention, in the step (b) of the wireless transmission method, an information bump of the driving key presses the command lever to be bent and deformed, so that the command lever buffers the driving force transmitted from the driving key to the command button.

According to an embodiment of the present invention, in the step (b) of the wireless transmission method, the driving end of the command lever is pressed by the driving key to make lever motion based on a command lever fulcrum of the command lever, and the command button is triggered by the driving end of the command lever.

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

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the appended claims.

Drawings

Figure 1 is a schematic diagram of a self-powered wireless switch of the prior art.

Fig. 2 is an overall schematic diagram of a self-powered wireless control system according to a first preferred embodiment of the present invention.

Fig. 3 is an overall schematic diagram of a self-powered transmitter of the self-powered wireless control system according to the above preferred embodiment of the present invention.

Fig. 4 is an exploded view of the self-powered transmitter of the self-powered wireless control system according to the above preferred embodiment of the present invention.

Figure 5 is a cross-sectional view of the self-powered transmitter of the self-powered wireless control system according to the above preferred embodiment of the present invention.

Fig. 6 is a schematic diagram of the operation of the self-powered transmitter of the self-powered wireless control system according to the above preferred embodiment of the present invention.

Fig. 7 is a schematic diagram of a portion of the self-powered transmitter of the self-powered wireless control system according to the above preferred embodiment of the present invention.

Figure 8A is another alternative implementation of the self-powered transmitter of the self-powered wireless control system in accordance with the above-described preferred embodiment of the present invention.

Figure 8B is another alternative implementation of the self-powered transmitter of the self-powered wireless control system in accordance with the above-described preferred embodiment of the present invention.

Figure 9 is an overall exploded view of a self-powered transmitter in accordance with a second preferred embodiment of the present invention.

Figure 10 is a cross-sectional view of the self-powered transmitter according to the above preferred embodiment of the present invention.

Fig. 11 is a schematic diagram of the operation of the self-powered transmitter according to the above preferred embodiment of the present invention.

Figure 12 is an overall exploded view of a self-powered transmitter in accordance with a third preferred embodiment of the present invention.

Figure 13 is a cross-sectional view of the self-powered transmitter according to the above preferred embodiment of the present invention.

Fig. 14 is a schematic diagram of the operation of the self-powered transmitter 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 "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purpose of limitation.

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.

Referring to fig. 2-7 of the drawings, a self-powered wireless control system and self-powered transmitter thereof according to a first preferred embodiment of the present invention will be explained in the following description. The self-powered wireless control system comprises a self-powered transmitter 100 and at least one wireless receiving device 200, wherein the self-powered transmitter 100 transmits at least one wireless control signal in a self-powered manner, and the wireless receiving device 200 receives the wireless control signal transmitted by the self-powered transmitter 100 and executes a control command corresponding to the wireless control signal. It is worth mentioning that the radio control signal contains encoded information, i.e. the communication device transmits the radio control signal with the encoded information. The wireless receiving apparatus 200 is communicatively connected to at least one electrical device, or the wireless receiving apparatus 200 is connected to the electrical device, such as a lamp, a sound, a motor, a remote control switch, and the like. The wireless receiving device 200 controls the operating state of the electrical equipment, such as the on/off of a lamp, the adjustment of brightness, or the adjustment of motor power, based on the received wireless control signal.

As shown in fig. 3 to 7, the self-powered transmitter 100 comprises a housing 10, at least one driving key 20, at least one triggering device 30, at least one micro-motion generator 40, and at least one communication device 50, wherein the triggering device 30, the micro-motion generator 40, and the communication device 50 are disposed on the housing 10. The driving key 20 is arranged in the housing 10 in a driving manner, the driving key 20 is supported by the housing 10, and the micro-motion generator 40 is driven by the driving key 20 to generate electricity. The driving key 20 triggers the communication device 50 through the triggering device 30 to generate and transmit the wireless control signal. The triggering device 30 is driven by the driving key 20, buffers the driving force of the driving key 20, and transmits the driving force to the communication device 50 to trigger the communication device 50. The driving key 20 is disposed to abut against one end of the triggering device 30, and when the driving key 20 is driven by a force, the driving key 20 presses or drives the triggering device 30 to generate elastic deformation. The other end of the triggering device 30 is movably disposed on the communication device 50, and when the driving key 20 drives the triggering device 30, the triggering device 30 triggers the communication device 50 under the action of elastic deformation.

The micro-motion generator 40 is driven to convert mechanical energy into electrical energy, wherein the communication device 50 is electrically connected to the micro-motion generator 40, and the communication device 50 is supplied with operating electrical energy by the micro-motion generator 40. Preferably, in the preferred embodiment of the present invention, the driving key 20 drives the triggering device 30 during the process of driving the micro-motion generator 40 to generate power, and the triggering device 30 triggers the communication device 50 under the action of elastic deformation, so that the communication device 50 is supported by the electric energy generated by the micro-motion generator 40 to send the wireless control signal.

The communication device 50 includes at least one circuit board 51 and at least one command button 52, wherein the circuit board 51 is electrically connected to the micro-motion generator 40, and the micro-motion generator 40 provides operating power for the circuit board 51. The command button 52 of the communication device 50 is electrically connected to the circuit board 51, wherein the command button 52 is triggered to transmit the wireless control signal based on the circuit board 51.

It should be noted that in the preferred embodiment of the present invention, the driving force of the driving key 20 of the self-powered transmitter does not directly act on the command button 52 of the communication device 50, when the driving key 20 is pressed, the driving key 20 acts on the triggering device 30, the driving force of the driving key 20 is buffered by the triggering device 30, and the command button 52 of the communication device 50 is triggered, so as to avoid the damage of the communication device 50 caused by the excessive stress of the driving key 20.

Specifically, the triggering device 30 includes a triggering bracket 31 and at least one command lever 32 disposed on the triggering bracket 31, wherein the triggering bracket 31 supports the command lever 32 to be stressed to buffer the driving force of the driving key 20. The driving key 20 drives the command rod 32 of the triggering device 30 to deform, so as to trigger the command key 52 of the communication device 50. The command lever 32 is driven by the driving key 20 to make a lever motion based on the triggering bracket 31, wherein the command lever 32 triggers the command button 52 after being bent and deformed. It should be noted that the bending deformation of the command lever 32 caused by the force applied thereto is a slight deformation, so as to buffer the driving force transmitted from the command lever 32 to the communication device 50.

Preferably, in the preferred embodiment of the present invention, the command button 52 is a mechanical micro-motion switch, and the command button 52 may be, but not limited to, a conductive membrane switch, a tact switch, a detection switch, a micro-motion switch, a conductive rubber switch, a metal contact switch, a switch made of semiconductor material, and the like.

Preferably, in the preferred embodiment of the present invention, the triggering bracket 31 and the command rod 32 of the triggering device 30 are an integral structure, wherein the command rod 32 is driven by the driving key 20 to perform a lever motion in the supporting function of the triggering bracket 31. The command lever 32 includes a driving end 321, a transmission end 322 extending outward from the driving end 321, and a command lever fulcrum 323, wherein the command lever fulcrum 323 is integrally formed on the trigger bracket 31 of the trigger device 30, and the driving end 321 and the transmission end 322 of the command lever 32 perform a lever motion based on the command lever fulcrum 323.

It should be noted that the driving end 321 of the command lever 32 is located at the proximal end of the command lever fulcrum 323, and the transmission end 322 is located at the distal end of the command lever fulcrum 323. When the driving key 20 is driven by force, the driving force of the driving key 20 acts on the driving end 321 of the command lever 32. The command rod 32 is driven by the driving key 20 to make a lever motion, wherein the driving force F applied to the driving end 321 of the command rod 32 is greater than the force F transmitted from the driving end 322 of the command rod 32 to the command button 52, and the moving stroke L of the driving end 322 of the command rod 32 is less than the moving stroke L of the driving end 322 of the command rod 32. Therefore, it can be understood by those skilled in the art that when a user presses the driving key 20 of the self-powered transmitter 100, the user can press the driving key 20 with a smaller driving stroke, wherein the driving key 20 applies a driving force to the command lever 32 of the triggering device 30, the driving force of the driving key 20 is buffered by the command lever 32, and the buffered force is applied to the command button 52 of the communication device 50 to trigger the command button 52.

In the preferred embodiment of the present invention, the driving key 20 applies a driving force to the driving end 321 of the command lever 32, wherein the driving end 321 of the command lever 32 is driven by the driving key 20 to move based on the command lever fulcrum 323, wherein the driving end 321 of the command lever 32 buffers the driving force of the driving key 20 in a manner of forced deformation, and the command button 52 of the communication device 50 is triggered through the driving end 322.

Preferably, in the preferred embodiment of the present invention, the command lever 32 of the triggering device 30 is made of thin metal or thin plastic, wherein the command lever 32 is an elastic device, and when the driving force of the driving key 20 is eliminated, the command lever 32 can be restored to the initial state under the elastic action. It is to be understood that the structure and material of the trigger device 30 in the preferred embodiment of the present invention are provided as examples and not limitations. The triggering device 30 can therefore also be embodied as other specifically spring-acting devices, such as rubber materials, metal alloys, plastics, etc. In other optional embodiments of the present invention, the command rod 32 of the triggering device 30 may be pivotally connected to the triggering bracket 31, and when the driving key 20 drives the command rod 32, the command rod 32 makes a lever motion based on the position of connecting the triggering bracket 31.

As shown in fig. 4 and 5, the triggering device 30 further includes at least one command lever driving block 33, wherein the command lever driving block 33 is disposed at the driving end 321 of the command lever 32, and the driving key 20 is pressed against the upper end of the command lever driving block 33. When the driving key 20 drives the triggering device 30, the driving key 20 drives the driving end 321 of the command lever 32 to deform through the command lever driving block 33, so as to buffer the driving acting force of the driving key 20. When the driving key 20 is driven by force, the driving key 20 drives the command lever 32 through the command lever driving block 33, so that the command lever 32 generates elastic deformation for buffering the driving force. It can be understood that the command lever driving block 33 is disposed at the upper end of the command lever 32, and the command lever driving block 33 protrudes from the command lever 32, which is beneficial to reduce the moving stroke of the driving key 20 for driving the command lever 32.

Preferably, in the preferred embodiment of the present invention, the command lever driving block 33 and the command lever 32 are of an integral structure, that is, the command lever driving block 33 is integrally formed above the driving end 321 of the command lever 32. It is understood that the command lever driving block 33 may also be disposed above the driving end 321 of the command lever 32 by means of adhesion or other connection.

The triggering device 30 further includes at least one command pressing protrusion 34, wherein the command pressing protrusion 34 is disposed at the transmission end 322 of the command lever 32, and when the driving key 20 drives the command lever 32, the transmission end 322 of the command lever 32 triggers the command button 52 through the command pressing protrusion 34. The command pressing projection 34 is provided at the lower end of the command lever 32, wherein the command pressing projection 34 faces the command key 52 of the communication device 50. It is understood that the command pressing protrusion 34 can reduce the moving stroke of the command lever 32 of the triggering device 30, which facilitates the triggering of the command button 52 of the communication device 50 by the triggering device 30. Preferably, in the preferred embodiment of the present invention, the command pressing protrusion 34 is integrally formed at the lower end of the driving end 322 of the command lever 32, and the moving stroke of the command lever 32 is increased by the command pressing protrusion 34, so that the triggering device 30 triggers the communication device 50.

It should be noted that when the driving key 20 drives the command lever 32 of the triggering device 30, the command lever 32 is elastically deformed and acts on the driving key 20 in a reverse direction, that is, when the user presses the driving key 20, the command lever 32 of the triggering device 30 generates a supporting elastic force in a reverse direction to the driving acting force under the elastic action, so as to reduce the driving acting force of the command lever 32 of the triggering device 30 driving the command button 52. It can be understood that, in the preferred embodiment of the present invention, the driving key 20 drives the command rod 32 to bend and deform, so that the command rod 32 generates a reverse elastic force opposite to the driving force of the driving key 20, and the command rod 32 of the triggering device 30 buffers the driving force of the driving key 20, thereby preventing the command button 52 from being damaged due to an excessive pressing force when the user presses the driving key 20.

As shown in fig. 3 to 7, the driving key 20 includes a driving body 21, at least one information protrusion 22 disposed on the driving body 21, and at least one power transmission rod 23, wherein the driving body 21 is pivotally disposed on the housing 10, and when the driving key 20 is subjected to a driving force, the driving body 21 drives the information protrusion 22 and the power transmission rod 23 to move. The information protrusion 22 of the driving key 20 is disposed to press against the instruction pressing protrusion 34 of the triggering device 30, when the driving body 21 is pressed by a force, the driving body 21 applies a driving force to the instruction pressing protrusion 34 through the information protrusion 22, wherein the instruction pressing protrusion 34 transmits the driving force of the driving body 21 to the instruction lever 32 of the triggering device 30, the driving force of the driving body 21 is buffered by the instruction lever 32, and the instruction key 52 is triggered. The driving body 21 of the driving key 20 drives the information bump 22 and simultaneously drives the power transmission rod 23 to move, and the power transmission rod 23 drives the micro-motion generator 40, so that the micro-motion generator 40 converts the kinetic energy of the power transmission rod 23 into electric energy.

The triggering device 30 is further provided with a transmission hole 301, wherein the power transmission rod 23 passes through the transmission hole 301 and presses against the upper end of the micro-motor generator 40, and the transmission hole 301 is formed in the command rod 32 of the triggering device 30. That is, the power transmission rod 23 of the driving key 20 presses and drives the micro-motion generator 40 through the transmission hole 301. It should be noted that in the preferred embodiment of the present invention, the driving key 20 is forced to directly or indirectly transmit the driving force to the micro-motion generator 40 to drive the micro-motion generator 40 to generate electricity. Illustratively, in the preferred embodiment of the present invention, the driving key 20 transmits the driving force to the micro-motion generator 40 by direct transmission, that is, the driving key 20 directly presses the micro-motion generator 40 to drive the micro-motion generator 40 to generate electricity. It will be immediately apparent to those skilled in the art that the manner in which the drive key 20 drives the operation of the micro-motion generator 40 in the preferred embodiment of the present invention is provided herein by way of example only and not by way of limitation.

It should be noted that, in the present invention, the manner in which the micro-motion generator 40 is driven is only used as an example, and not a limitation, that is, the micro-motion generator 40 can also be driven to trigger through a direct or indirect transmission manner, and is not limited to the driving key 20 passing through the transmission hole 301 to drive the micro-motion generator to generate electricity.

In the preferred embodiment of the present invention, one end of the power transmission rod 23 of the driving key 20 is pressed against the micro-motion generator 40. Preferably, the information protrusion 22 and the power transmission rod 23 of the driving key 20 are integrally formed under the driving body 21, when a user presses the driving body 21 of the driving key 20, the driving body 21 drives the micro-motor 40 through the power transmission rod 23, the micro-motor 40 provides operating power for the communication device 50, and the driving body 21 synchronously drives the triggering device 30 through the information protrusion 22, and the triggering device 30 buffers the driving force of the driving key 20 to trigger the instruction button 52, so that the communication device 50 generates and transmits the wireless control signal.

As shown in fig. 4 and 5, the driving body 21 of the driving key 20 includes a driving portion 211 and at least one pivoting portion 212 integrally extending from the driving portion 211, wherein the pivoting portion 212 is pivotally connected to the housing 10, and the driving portion 211 of the driving body 21 is forced to drive the driving body 21 to rotate based on the pivoting portion 212. Preferably, in the preferred embodiment of the present invention, the driving key 20 is provided to the housing 10 in a snap-fit manner. It will be appreciated by those skilled in the art that in the preferred embodiment of the present invention, the drive key 20 may also be pivotally connected to the housing 10 by other connection means.

Accordingly, the housing 10 serves to fix and support the driving key 20, and to protect the micro-motion generator 40 and the communication device 50 provided to the housing 10. The housing 10 includes a housing body 11 and at least two driving brackets 12 disposed on the housing body 11 and further has at least one receiving cavity 13, wherein the receiving cavity 13 is formed inside the housing body 11, and the micro-motion generator 40 and the communication device 50 are fixedly held in the receiving cavity 13 by the housing body 11. The driving bracket 12 is disposed at both sides of the housing body 11, wherein the driving bracket 12 is supported by the housing body 11 in the accommodating chamber 13. The driving body 21 of the driving key 20 is pivotally disposed on the driving bracket 12 of the housing 10, and the driving key 20 is supported by the driving bracket 12 to rotate above the accommodating cavity 13. Preferably, in the preferred embodiment of the present invention, the driving brackets 12 on both sides of the housing body 11 form a pivot axis, wherein the driving body 21 of the driving key 20 rotates based on the pivot axis when the driving key 20 is pressed with force. More preferably, in the preferred embodiment of the present invention, the driving bracket 12 of the housing 10 is integrally formed with the housing main body 11.

As shown in fig. 4 and 5, the micro-motion generator 40 is fixed in the accommodating cavity 13 by the driving bracket 12, wherein the housing 10 includes at least one generator fixing bracket 14 and is further provided with at least one generator mounting groove 15, wherein the generator mounting groove 15 is formed in the generator fixing bracket 14. The micro-motion generator 40 is fixed to the generator mounting groove 15 by the generator fixing frame 14. The circuit board 51 of the communication device 50 is fixed to the accommodating chamber 13 by the housing body 11. Preferably, in the preferred embodiment of the present invention, the circuit board 51 of the communication device 50 is attached to the upper surface of the housing main body 11, and the command button 52 is disposed above the circuit board 51.

Each of the micro-motion generators 40 includes a generator main body 41, a generator driving device 42, at least one generator fixing unit 43, and at least one resetting device 44, wherein the generator driving device 42 is drivably installed on the generator main body 41, and the generator main body 41 converts the kinetic energy provided by the generator driving device 42 into electric energy. The generator main body 41 of the micro-motion generator 40 is electrically connected to the circuit board 51 of the communication device 50. The power transmission rod 23 of the driving key 20 is disposed to abut against the generator driving device 42 of the micro-motion generator 40, and when the driving key 20 is pressed by a force, the power transmission rod 23 of the driving key 20 drives the generator driving device 42 to move, so that the generator main machine 41 can convert the kinetic energy of the generator driving device 42 into electric energy. The generator fixing unit 43 fixes the generator main body 41 to the generator mounting groove 15 through the generator fixing frame 14, and prevents the micro-motion generator 40 from moving in the housing 10. When the driving key 20 is pressed, the reset device 44 drives the generator driving device 42 to return to the initial position. The reset means 44 is disposed at a lower end of the generator driving means 42, wherein the reset means 44 is implemented as an elastic member, and the reset means 44 has a supporting force that supports the generator driving means 42 upward when the driving key 20 is pressed downward. Preferably, in the preferred embodiment of the present invention, the reset device 44 can be, but is not limited to, a reset spring or a torsion spring device.

In the preferred embodiment of the present invention, when the driving key 20 is pressed, the power transmission rod 23 of the driving key 20 directly or indirectly transmits the driving force to the generator driving device 42 of the micro-motion generator 40. Therefore, it should be understood that, in the above preferred embodiment of the present invention, the manner in which the driving key 20 drives the micro-motion generator 40 to generate electricity is only used as an example and not a limitation. That is, the driving key 20 can also indirectly transmit power to the generator driving device 42 of the micro-motion generator 40 through other transmission devices, so that the generator main machine 41 of the micro-motion generator 40 can generate induction power.

As shown in fig. 6 and 7, the process of transmitting the wireless control signal when the self-powered transmitter 100 is pressed with a force is shown. When the user presses the driving body 21 of the driving key 20, the driving body 21 transmits the driving force from the information bump 22 to the triggering device 30, and the triggering device 30 buffers the driving force of the driving key 20. The information cam 22 presses the command lever 32 of the triggering device 30, so that the command lever 32 is subjected to bending deformation, wherein the transmission end 322 of the command lever 32 makes a lever movement based on the command lever fulcrum 323, and the command lever 32 triggers the command button 52 through the command pressing cam 34. When the driving key 20 triggers the communication device 50 through the triggering device 30, the driving body 21 of the driving key 20 transmits the driving force to the generator driving device 42 of the micromotion motor 40 through the power transmission rod 23, i.e. the power transmission rod 23 drives the generator driving device 42 to move. The generator main machine 41 of the micro-motion generator 40 converts the kinetic energy of the generator drive unit 42 into electrical energy.

It should be noted that in the preferred embodiment of the present invention, when the driving key 20 is pressed by force, the power transmission rod 23 continues to indirectly or directly press the generator driving device 42 of the micro-motion generator 40 to move until the generator main body 41 of the micro-motion generator 40 generates electric energy. When the driving key 20 is released, the reset device 44 drives the generator driving device 42 of the micro-motion generator 40 to move upwards under the elastic action, i.e. the reset device 44 restores the micro-motion generator 40 and the driving key 20 to the initial position.

It will be appreciated by those skilled in the art that in other embodiments of the present invention, the self-powered transmitter 100 for transmitting the wireless control signal in the self-powered wireless control system may comprise a plurality of communication devices 50, wherein each of the communication devices 50 sends different key command information based on the circuit board 51 of the communication device 50 when being triggered.

Referring to fig. 8A or 8B of the drawings accompanying the present application, two alternative embodiments of a self-powered transmitter 100 according to the above preferred embodiment of the present invention are illustrated in the following description. In the preferred embodiment of the present invention, the self-powered transmitter 100 comprises a housing 10, at least one driving key 20, at least one triggering device 30, at least two micro-motion generators 40, and at least two communication devices 50, wherein the triggering device 30, the micro-motion generators 40, and the communication devices 50 are disposed on the housing 10. The driving key 20 is arranged in the housing 10 in a driving manner, the driving key 20 is supported by the housing 10, and the micro-motion generator 40 is driven by the driving key 20 to generate electricity.

It should be noted that in the preferred embodiment of the present invention, the structure and operation principle of the micro-motion generator 40 and the communication device 50 are the same as those of the first preferred embodiment. Unlike the first preferred embodiment described above, in this preferred embodiment of the present invention, the self-powered transmitter 100 is arranged with at least two different communication devices 50 (communication device 50a and communication device 50b) and two different micro-motion generators 40 (micro-motion generator 40a and micro-motion generator 40b), wherein the communication device 50a and the communication device 50b are triggered to send out wireless control contents of different control information. Therefore, self-power transmitter 100 is applicable to the wireless transmitting device that generates electricity certainly of many buttons, for example from the wireless switch that generates electricity, from the wireless control module that generates electricity, from the wireless direct controller that selects etc. of generating electricity remote controller, the intelligent scene switch that generates electricity certainly, many buttons.

As shown in fig. 8A, the driving key 20 of the self-powered transmitter 100 is pivotally disposed on the housing 10, wherein the driving key 20 performs a bi-directional seesaw motion based on the housing 10, that is, two ends of the driving key 20 can be driven to move up and down. The micro-motion generator 40a and the micro-motion generator 40b are oppositely disposed to the housing 10, and the communication device 50a and the communication device 50b are symmetrically disposed to both ends of the housing 10.

Illustratively, when one end of the driving key 20 is pressed, the driving key 20 drives the micro-motion generator 40a on the same side to generate power and trigger the communication device 50a, so that the micro-motion generator 40a on the same side provides working power for the communication device 50 a.

Correspondingly, the driving key 20 includes a driving body 21, two information bumps 22 disposed on the driving body 21, and two power transmission rods 23, wherein the driving body 21 is pivotally disposed on the housing 10, and when the driving key 20 is subjected to a driving force, the driving body 21 drives the information bumps 22 and the power transmission rods 23 to move. The two ends of the driving body 21 are respectively provided with one information projection 22 and one power transmission rod 23, wherein when the driving body 21 rotates based on the housing 10, the information projection 22 and the power transmission rod 23 arranged at one end of the driving body 21 transmit power to the triggering device 30 and the micro-motion generator 40 at the corresponding side to drive the micro-motion generator 40a (or 40b) at the corresponding side to generate power, and the triggering device 30 triggers the communication device 50a (or 50b) at the corresponding side.

The triggering device 30 includes a triggering bracket 31 and at least two command levers 32 disposed on the triggering bracket 31, wherein the triggering bracket 31 supports the command levers 32 to be stressed to buffer the driving force of the driving key 20. The driving key 20 drives the command rod 32 of the triggering device 30 to deform, so as to trigger the command key 52 of the communication device 50. The command lever 32 is driven by the driving key 20 to make a lever motion based on the triggering bracket 31, wherein the command lever 32 triggers the command button 52 after being bent and deformed. In the preferred embodiment of the present invention, the command lever 32 is symmetrically disposed on the trigger bracket 31, and when one end of the driving key 20 is driven by a force, the trigger bracket 31 supports the command lever 32 to buffer the driving force of the driving key 20, and triggers the command button 52 of the communication device 50a (or 50b) on the corresponding side through the command lever 32.

As shown in fig. 8B, the driving key 20 of the self-powered transmitter 100 is pivotally disposed on the housing 10, wherein the driving key 20 makes a one-way seesaw motion based on the housing 10, i.e., one end of the driving key 20 can be driven to move up and down. The micro-motion generator 40a and the micro-motion generator 40b are provided in parallel to the housing 10, and the communication device 50a and the communication device 50b are symmetrically provided on the same side of the housing 10.

Illustratively, when the driving key 20 is pressed, the driving key 20 drives the micro-motion generator 40a at the corresponding position to generate power and trigger the communication device 50a, so that the micro-motion generator 40a provides working power for the communication device 50 a. The driving key 20 includes a driving body 21, an information protrusion 22 disposed on the driving body 21, and a power transmission rod 23, wherein the driving body 21 is pivotally disposed on the housing 10, and when the driving key 20 receives a driving force, the driving body 21 drives the information protrusion 22 and the power transmission rod 23 to move.

Referring to fig. 9-11 of the drawings accompanying the present application, a self-powered transmitter 100A in accordance with a second preferred embodiment of the present invention is illustrated in the following description. The self-powered transmitter 100A includes a housing 10A, at least one driving key 20A, at least one triggering device 30A, at least one micro-motion generator 40A, and at least one communication device 50A, wherein the triggering device 30A, the micro-motion generator 40A, and the communication device 50A are disposed in the housing 10A. The driving key 20A is arranged in the housing 10A in a driving manner, the driving key 20A is supported by the housing 10A, and the micro-motion generator 40A is driven by the driving key 20A to generate electricity. The driving key 20A triggers the communication device 50A through the triggering device 30A to generate and transmit the wireless control signal. The triggering device 30A is driven by the driving key 20A, buffers the driving force of the driving key 20A, and transmits the driving force to the communication device 50A to trigger the communication device 50A. The driving key 20A is disposed to abut against one end of the triggering device 30A, and when the driving key 20A is forced to be driven, the driving key 20A presses or drives the triggering device 30A to generate elastic deformation. The other end of the triggering device 30A is movably disposed on the communication device 50A, and when the driving key 20A drives the triggering device 30A, the triggering device 30A triggers the communication device 50A under the action of elastic deformation.

In the preferred embodiment of the present invention, the structure and function of the housing 10A, the driving key 20A, the micro-motion generator 40A, and the communication device 50A are the same as those of the self-powered transmitter 100 of the above preferred embodiment, and the trigger device 30A of the self-powered transmitter 100A is different from the self-powered transmitter 100 of the above preferred embodiment. Specifically, the triggering device 30A includes at least one triggering bracket 31A and at least one command lever 32A disposed on the triggering bracket 31A, wherein the triggering bracket 31A supports the command lever 32A to be stressed so as to buffer the driving force of the driving key 20A. The driving key 20A drives the command rod 32A of the triggering device 30A to deform, so as to trigger the command key 52A of the communication device 50A. The command lever 32A is driven by the driving key 20A to make a lever motion based on the triggering bracket 31A, wherein the command lever 32A triggers the command button 52A after being bent and deformed.

In the preferred embodiment of the present invention, the command rod 32A of the triggering device 30A is pivotally connected to the triggering bracket 31A, wherein the command rod 32A is driven by the driving key 20A to make a lever motion at the supporting function of the triggering bracket 31A. The command lever 32A includes a driving end 321A, a transmission end 322A extending outward from the driving end 321A, and a command lever fulcrum 323A, wherein the command lever fulcrum 323A is pivotally disposed on the triggering bracket 31A of the triggering device 30A, and the driving end 321A and the transmission end 322A of the command lever 32A perform lever motion based on the command lever fulcrum 323A.

The trigger bracket 31A of the triggering device 30A further includes at least two bracket units 311A and at least one elastic element 312A supporting the command lever 32A, wherein the command lever fulcrum 323A of the command lever 32A is pivotably disposed on the bracket unit 311A of the trigger bracket 31A, and the driving end 321A and the driving end 322A of the command lever 32A are supported by the bracket unit 311A to rotate based on the command lever fulcrum 323A. The elastic element 312A supports the command lever 32A of the triggering device 30A, and when the driving key 20A drives and presses the command lever 32A of the triggering device 30A, the command lever 32A presses the elastic element 312A. The information projection 22A of the driving key 20A is pressed against the upper side of the command lever 32A, and when the driving key 20A is pressed by a force, the information projection 22A presses the command lever 32A to be bent and deformed. The command lever 32A damps the driving force to the communication device 50A by the supporting action of the holder unit 311A and the elastic member 312A. It should be noted that, in the preferred embodiment of the present invention, the driving key 20A drives the command rod 32A of the triggering device 30A to perform a lever motion, wherein the driving key 20A drives the command rod 32A to move with a smaller moving stroke and a larger driving stroke, so as to improve the reliability of the triggering of the command button 52A of the communication device 50A. Since the driving key 20A drives the command rod 32A to make a lever motion, the command rod 32A is pressed by the information bump 22A of the driving key 20A to generate an elastic deformation, so as to reduce the driving force of the command rod 32A pressing the command key 52A, which is beneficial to protecting the command key 52A of the communication device 50A.

It is understood that when the actuating key 20A directly or indirectly presses the command lever 32A of the triggering device 30A, the elastic element 312A provides a force of the command lever 32A against the actuating key 20A to buffer the actuating force of the actuating key 20A transmitted to the communication device 50A. When the driving key 20A is released, the elastic element 312A elastically drives the command lever 32A of the triggering device 30A to return to the initial position, and the command lever 32A drives the driving key 20A to move upward to the initial state.

Preferably, in the preferred embodiment of the present invention, the elastic member 312A is implemented as a torsion spring device, wherein the torsion spring device is provided to the holder unit 311A of the trigger holder 31A, and the elastic member 312A supports the command lever 32A based on the holder unit 311A. Alternatively, the elastic element 312A may also be implemented as a spring element, wherein the spring element is disposed below the command lever 32A, and when the driving key 20A drives the command lever 32A of the triggering device 30A, the command lever 32A presses the elastic element 312A to buffer the driving force of the command lever 32A. It is worth mentioning that in this preferred embodiment of the present invention, the specific type of the elastic element 312A is only used as an example and not as a limitation.

As shown in fig. 12-14, a self-powered transmitter 100B in accordance with a third preferred embodiment of the present invention is illustrated in the following description. The self-powered transmitter 100B comprises a housing 10B, at least one driving key 20B, at least one triggering device 30B, at least one micro-motion generator 40B, and at least one communication device 50B, wherein the triggering device 30B, the micro-motion generator 40B, and the communication device 50B are disposed in the housing 10B. The driving key 20B is drivably provided to the housing 10B, the driving key 20B is supported by the housing 10B, and the micro-motion generator 40B is driven by the driving key 20B to generate power. The driving key 20B triggers the communication device 50B through the triggering device 30B to generate and transmit the wireless control signal. The triggering device 30B is driven by the driving key 20B, buffers the driving force of the driving key 20B, and transmits the driving force to the communication device 50B to trigger the communication device 50B. The driving key 20B is disposed to abut against one end of the triggering device 30B, and when the driving key 20B is driven by a force, the driving key 20B presses or drives the triggering device 30B to generate elastic deformation. The other end of the triggering device 30B is movably disposed on the communication device 50B, and when the driving key 20B drives the triggering device 30B, the triggering device 30B triggers the communication device 50B under the action of elastic deformation.

In the preferred embodiment of the present invention, the structure and function of the housing 10B, the driving key 20B, the micro-motion generator 40B, and the communication device 50B are the same as those of the self-powered transmitter 100 of the above preferred embodiment, and the trigger device 30B of the self-powered transmitter 100B is different from the self-powered transmitter 100 of the above preferred embodiment. Specifically, the triggering device 30B includes at least one triggering bracket 31B and at least one command lever 32B movably disposed on the triggering bracket 31B, wherein the triggering bracket 31B supports the command lever 32B to be stressed to buffer the driving force of the driving key 20B. The driving key 20B drives the command rod 32B of the triggering device 30B to deform, so as to trigger the command key 52B of the communication device 50B. The command lever 32B is driven by the drive key 20B to move up and down based on the trigger bracket 31B, wherein the command lever 32B is bent and deformed to trigger the command button 52B.

In the preferred embodiment of the present invention, the command rod 32B of the triggering device 30B is movably disposed on the triggering bracket 31B, wherein the command rod 32B is driven by the driving key 20B to move up and down under the supporting action of the triggering bracket 31B. The command lever 32B includes a driving end 321B, a transmission end 322B extending outward from the driving end 321B, and a command lever fulcrum 323B, wherein the command lever fulcrum 323B is movably disposed on the triggering bracket 31B of the triggering device 30B. When the driving key 20B is pressed with force, the driving key 20B drives the command lever 32 to move down along the trigger bracket 31B.

Accordingly, the triggering bracket 31B of the triggering device 30B further includes at least two bracket units 311B, at least one elastic element 312B, and at least two moving chutes 313B, wherein the command lever fulcrum 323B of the command lever 32B is movably disposed on the moving chute 313B of the triggering bracket 31B, and the command lever 32B is supported by the elastic element 312B to move up and down along the vertical direction of the moving chute 313B. When the driving key 20B drives the command lever 32B, the command lever 32B is pressed by the driving key 20B to move downward, and the command lever 32B triggers the command key 52B of the communication device 50B. The elastic element 312B is disposed below the command lever 32B, and the elastic element 312B provides a force of the command lever 32B opposite to the driving key 20B, so as to buffer the driving force transmitted from the driving key 20B to the communication device 50B. When the driving key 20B is released, the elastic element 312B elastically drives the command lever 32B of the triggering device 30B to return to the initial position, and the command lever 32B drives the driving key 20B to move upward to the initial state.

The information projection 22B of the driving key 20B is pressed against the upper side of the command lever 32B, and when the driving key 20B is pressed by a force, the information projection 22B presses the command lever 32B, wherein the command lever 32B is bent and deformed by the driving force of the driving key 20B and the supporting force of the elastic element 312B. The command lever 32B damps the driving force to the communication device 50B by the supporting action of the elastic member 312B. It is worth mentioning that, unlike the above preferred embodiment, in the preferred embodiment of the present invention, the driving key 20B drives the command lever 32B of the triggering device 30B to move up and down in the vertical direction. It can be understood that, since the command rod 32B of the triggering device 30B is subjected to bending deformation, the driving key 20B is enabled to drive the other end of the command rod 32B with a smaller moving stroke and have a larger moving stroke, so as to improve the reliability of the triggering of the command key 52B of the communication device 50B. Since the command lever 32B is pressed by the information protrusion 22B of the driving key 20B to be elastically deformed, the driving force of the command lever 32B pressing the command key 52B is reduced, which is beneficial to protecting the command key 52B of the communication device 50B.

Referring to another aspect of the present invention, the present invention further provides a wireless transmission method of a self-powered transmitter 100, wherein the wireless transmission method comprises the following steps:

(a) the force is applied to drive a micro-motion generator 40, so that the micro-motion generator 40 can convert kinetic energy into electric energy; and

(b) the method comprises the steps of pressing a command lever 32 of a trigger device 30, buffering the driving force by the command lever 32, and triggering a command button 52 of a communication device 50, so that the communication device 50 can transmit at least one wireless control signal.

In the above wireless transmission method of the present invention, a driving key 20 of the self-powered transmitter 100 is pressed, wherein the driving key 20 transmits a driving force to the micro-motion generator 40 and the triggering device 30 for driving the micro-motion generator 40 to generate power and buffering the driving force of the driving key 20 by the triggering device 30 to trigger the command button 52 of the communication device 50. In the step (a) of the above wireless transmission method of the present invention, further, a power transmission rod 23 of the driving key 20 drives the micro-motion generator 40, and drives the micro-motion generator 40 to generate power.

In the step (b) of the above wireless transmission method of the present invention, an information bump 22 of the driving key 20 presses the command lever 32 to be bent and deformed, so that the command lever 32 buffers the driving force transmitted from the driving key 20 to the command button 52. In the step (b) of the above-mentioned wireless transmission method of the present invention, the driving end 321 of the command lever 32 is pressed by the driving key 20 to make lever motion based on a command lever fulcrum 323 of the command lever 32, and the command button 52 is triggered by a driving end 322 of the command lever 32.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The objects of the present invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (28)

1. A self-powered transmitter, comprising:

a housing;

at least one micro-motion generator, wherein the micro-motion generator is disposed in the housing, the micro-motion generator being driven to convert kinetic energy into electrical energy;

at least one communication device, wherein the communication device is electrically connected to the micro-motion generator, and the micro-motion generator provides working electric energy for the communication device; and

the trigger device can be stressed to be transmitted to the communication device, and the trigger device is pressed to buffer the driving acting force and transmit the driving acting force to the communication device to trigger the communication device in a buffering mode.

2. The self-powered transmitter of claim 1, wherein the triggering device comprises at least one triggering bracket and at least one command lever, wherein the command lever is drivingly disposed on the triggering bracket, the command lever is supported by the triggering bracket, the command lever is forced to elastically deform in a bending manner, and the command lever transmits the driving force to the communication device.

3. The self-powered transmitter of claim 2, wherein the command lever is integrally formed with the trigger bracket, the command lever being actuated to lever based on the trigger bracket, wherein the command lever forced to flex is activated to trigger the communication device.

4. The self-powered transmitter of claim 2, wherein the command lever is pivotally disposed on the trigger bracket, the command lever being actuated to lever based on the trigger bracket, wherein the command lever forced to flex is activated to trigger the communication device.

5. The self-powered transmitter of claim 2, wherein the command lever is movably disposed to the trigger bracket, the command lever being actuated to move downward based on the trigger bracket, wherein the command lever forced to flex is activated to trigger the communication device.

6. The self-powered transmitter of claim 3, wherein the command lever comprises a drive end, a transmission end extending from the drive end, and a command lever fulcrum, the transmission end being distal to the command lever fulcrum, wherein the command lever fulcrum is disposed on the trigger bracket, wherein the drive end of the command lever is forced to move the transmission end.

7. The self-powered transmitter of claim 4, wherein the command lever comprises a drive end, a transmission end extending from the drive end, and a command lever fulcrum, the transmission end being distal to the command lever fulcrum, wherein the command lever fulcrum is disposed on the trigger bracket, wherein the drive end of the command lever is forced to move the transmission end.

8. The self-powered transmitter of claim 5, wherein the command lever comprises a drive end, a transmission end extending from the drive end, and a command lever fulcrum, the transmission end being distal to the command lever fulcrum, wherein the command lever fulcrum is disposed on the trigger bracket, wherein the drive end of the command lever is forced to move the transmission end.

9. The self-powered transmitter of claim 6, wherein the triggering device further comprises a command lever drive block disposed above the drive end of the drive lever.

10. The self-powered transmitter of claim 7, wherein the triggering device further comprises a command lever drive block disposed above the drive end of the drive lever.

11. The self-powered transmitter of claim 8, wherein the triggering device further comprises a command lever drive block disposed above the drive end of the drive lever.

12. The self-powered transmitter of claim 6, wherein the triggering device further comprises at least one command press tab, wherein the command press tab is disposed below the actuation end of the command lever, the command lever triggering the communication device via the command press tab to increase a triggering distance of the command lever via the command press tab.

13. The self-powered transmitter of claim 7, wherein the triggering device further comprises at least one command press tab, wherein the command press tab is disposed below the actuation end of the command lever, the command lever triggering the communication device via the command press tab to increase a triggering distance of the command lever via the command press tab.

14. The self-powered transmitter of claim 8, wherein the triggering device further comprises at least one command press tab, wherein the command press tab is disposed below the actuation end of the command lever, the command lever triggering the communication device via the command press tab to increase a triggering distance of the command lever via the command press tab.

15. The self-powered transmitter of claim 6, wherein the command lever is a resilient device, the command lever selected from the group consisting of: elastic device group composed of thin film metal and plastic.

16. The self-powered transmitter of claim 7, wherein the command lever is a resilient device, the command lever selected from the group consisting of: elastic device group composed of thin film metal and plastic.

17. The self-powered transmitter of claim 8, wherein the command lever is a resilient device, the command lever selected from the group consisting of: elastic device group composed of thin film metal and plastic.

18. A self-powered transmitter as claimed in any one of claims 2 to 17, wherein the self-powered transmitter further comprises an actuation key, wherein the actuation key is drivingly pressed against the command lever of the triggering device, whereby the command lever is pressed by the actuation key.

19. The self-powered transmitter of claim 18, wherein the drive key is pivotably disposed on the housing, whereby the housing supports the drive key for rotationally driving the command lever.

20. A self-powered transmitter as recited in claim 19, wherein the driving key comprises a driving body, at least one information bump disposed on the driving body, the information bump abutting against the triggering device, the driving body being pressed to drive the information bump to move downward, the information bump pressing against the triggering device.

21. A self-powered transmitter as in claim 20, wherein the drive key further comprises at least one power transmission rod, wherein the power transmission rod is drivingly disposed to the drive body, and wherein the drive body drives the micro-motion generator through the power transmission rod.

22. A self-powered transmitter as recited in claim 20, wherein the actuation key comprises an actuation portion and a pivot portion integrally extending from the actuation portion, the pivot portion being coupled to the housing, wherein the actuation portion is forced to be depressed in a unidirectional paddle motion based on the pivot portion.

23. A self-powered transmitter as recited in claim 20, wherein the actuator key comprises a pivot portion and two actuator portions integrally extending from opposite ends of the actuator portion, the pivot portion being coupled to the housing, wherein the actuator portions are forced to move in a bi-directional tilting motion based on the pivot portion.

24. The self-powered transmitter of claim 21, wherein the micro-motion generator comprises a generator main body and a generator driving device, wherein the generator main body is fixed to the housing, the generator driving device is drivably disposed on the generator main body, the power transmission rod drives the generator driving device to move, and the generator main body converts kinetic energy of the generator driving device into electrical energy.

25. The self-powered transmitter of claim 24, wherein the micro-motion generator further comprises a generator mounting unit and at least one reset device, wherein the generator mounting unit mounts the generator body to the housing, and wherein the reset device is disposed below the generator drive device to provide a force to reset the generator drive device.

26. The self-powered transmitter of claim 24, wherein the communication device comprises a circuit board and at least one command button, wherein the command button is electrically connected to the circuit board, the command button being activated to transmit at least one wireless control signal from the circuit board, wherein the wireless control signal comprises encoded information.

27. The self-powered transmitter of claim 26, wherein the instruction button of the communication device is a mechanical microswitch selected from the group consisting of: a conductive film switch, a light touch switch, a detection switch, a microswitch, a conductive rubber switch, a metal contact switch and a switch made of semiconductor materials.

28. A self-powered wireless control system, comprising:

the self-powered transmitter of any one of claims 1 to 27, wherein the self-powered transmitter is configured to transmit at least one wireless control signal in a self-generating manner; and

at least one wireless receiving device, wherein the wireless receiving device receives the wireless control signal, so that the wireless receiving device controls the working state of the electric equipment based on the wireless control signal.

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