KR20180044307A - Kinetic Energy Generation Device and Radio Transmitter, Method of Manufacturing and Application - Google Patents

Abstract

The present invention relates to a kinetic energy generator, a radio transmitter, and a manufacturing method and application thereof. The kinetic energy generator includes an annular magnetic gap (14) and a coil (30). The coil reciprocates in the magnetic gap Electricity can be generated by generating a current. The kinetic energy generating method includes driving the coil to reciprocate in the magnetic gap. The radio transmitter includes a kinetic energy generating device and a high frequency radio transmitting circuit board (22), wherein the high frequency radio transmitting circuit board includes a frequency module, the high frequency radio transmitting circuit board is electrically connected to the coil of the kinetic energy generating device, Induced currents generated in the coils can provide electrical energy to small electronic devices.

Description

Kinetic Energy Generation Device and Radio Transmitter, Method of Manufacturing and Application

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device field, and more particularly, to a kinetic energy generating device, a kinetic energy generating method, and a radio transmitter using the kinetic energy generating device.

Wireless controllers are already widely used in various electronic control devices. For example, commonly used household or office electrical appliances can often be deployed with a wireless controller, which is typically powered by using the battery as a power source. Therefore, after the end of the life cycle of the battery, the user must frequently replace the old battery with a new battery.

Most home or office appliances also use wired switches, which are inconvenient for wiring and are still battery powered even when using a wireless switch, so you must replace the battery frequently after the end of the battery life cycle. In particular, the user must remove the wireless switch from the wall, remove the housing of the wireless switch, and clean and replace the battery. Otherwise, the electrolyte in the battery will leak and pollute the environment and shorten the life of the battery have. Therefore, a cleaner and more reliable power source is needed for both wireless switches and other small electronic devices.

It is an object of the present invention to provide a kinetic energy generator and a radio transmitter capable of realizing self-power supply, and a manufacturing method and an application thereof.

It is another object of the present invention to provide a kinetic energy generator and a radio transmitter capable of converting mechanical energy into electric energy to realize self-power supply, and a manufacturing method and application thereof.

It is still another object of the present invention to provide a kinetic energy generating device having a coil and a magnetic gap and allowing the kinetic energy generating device to generate electricity by making the coil reciprocate in the magnetic gap, And to provide a manufacturing method and an application.

It is still another object of the present invention to provide a method of driving a coil or a magnetic system for driving the coil so that the coil can generate a relative movement with the magnetic gap, And a radio transmitter for generating electricity by reciprocating motion in the magnetic gap under the driving of the motor, and a manufacturing method and an application thereof.

It is still another object of the present invention to provide a kinetic energy generating device and a radio transmitter for generating electric power by causing the coil to reciprocate in the magnetic gap through up-and-down movement, and a manufacturing method and application thereof.

It is still another object of the present invention to provide a kinetic energy generator and a radio transmitter for generating electric power by causing the coil to reciprocate in the magnetic gap through circumferential motion, and a manufacturing method and application thereof.

It is still another object of the present invention to provide a kinetic energy generating device and a radio transmitter capable of generating electricity by generating induction currents by alternately driving a plurality of coils by the driving device, and a manufacturing method and application thereof have.

It is still another object of the present invention to provide a kinetic energy generating device and a radio transmitter for driving a circuit board with an induction current generated by the kinetic energy generating device to perform a corresponding transmitting operation of the radio transmitter, .

It is still another object of the present invention to provide a radio transmitter and a radio frequency transmission circuit board which are provided with a high frequency wireless transmission circuit board to drive the high frequency wireless transmission circuit board with an induction current generated in the kinetic energy generation device, An energy generating device, a wireless transmitter, and a manufacturing method and an application thereof.

It is still another object of the present invention to provide a kinetic energy generator and a radio transmitter having a simple operation and a high power generation efficiency and a manufacturing method and application thereof.

In order to achieve the above object, the present invention mainly provides a kinetic energy generating device,

At least one coil;

At least one magnet system with an annular magnetic gap; And

And at least one driving device, under which, under the action of the driving device, the coil generates a displacement relative to the magnetic gap, causing the coil to be cut by the magnetic induction wire of the magnet system, thereby generating an induced current .

In one embodiment, the drive apparatus is for driving the magnetic path system so that the coils generate the induced current by causing a repetitive relative displacement in the magnetic gap and the coil of the magnet system.

In one embodiment, the drive includes a driver for driving the coil to cause the coil to generate the induced current by causing a repetitive relative displacement in the magnetic gap of the coil and the magnetic path system.

In one embodiment, the magnet system includes a lower magnetic induction plate whose longitudinal section is U-shaped, a permanent magnet body and an upper magnetic induction plate, wherein the permanent magnet body and the upper magnetic induction plate are installed in the lower magnetic induction plate Thereby forming the annular magnetic gap.

In one embodiment, the actuator includes a ceramic body, wherein the coil is fixed to the ceramic body, and the ceramic body is automatically returned through magnetic attracting force with the magnet system to automatically return the coil .

In one embodiment, the actuator includes an elastic plate, of which the coil is fixed to the elastic plate, and the elastic plate is capable of automatically returning the coil by automatically returning through its elastic recovery performance .

In one embodiment, it further comprises a base sheet and one or more elastic plate fixing sheets, wherein the lower magnetic induction plate and the elastic plate fixing sheet are fixed to the base sheet, and one end of the elastic plate is fixed to the coil And the other end is fixed to the elastic plate fixing sheet.

In one embodiment, the driver includes an upper cam and a lower cam that can be engaged and disengaged through protrusions, wherein the lower cam is fixed to the magnet system, The coil can be driven to reciprocate in the magnetic gap by rotating the cam in the circumferential direction.

In one embodiment, in the embodiment using the cam, the actuator further comprises a ceramic body, wherein the ceramic body is arranged to separate the upper cam and the lower cam from the separated state through magnetic attraction force with the magnet system It is possible to automatically return to the engaged state.

In one embodiment, the kinetic energy generating apparatus includes two kinetic energy generating units including two coils and two magnetic path systems, wherein the driving apparatus includes a seesaw plate and a supporting point for supporting the seesaw plate Wherein two coils are fixed to both ends of the seesaw plate, and two coils are located on both sides of the fulcrum, respectively, one of the coils being corresponding to the one of the magnetic poles of the system When inserted into the gap, the other coil is separated from the magnetic gap of the corresponding one of the magnetic-field systems, so that the two coils are cut by the magnetic-induction lines of the two corresponding magnetic- Thereby generating a current.

In one embodiment, the two coils are connected in series or in parallel, and both ends of the seesheet are arranged so that they can also be adsorbed and coupled with the two corresponding magnet systems via magnetic forces.

In one embodiment, the apparatus further includes a circuit board, wherein the coil is electrically connected to the circuit board, and the induced current generated in the coil is supplied to the circuit board.

In one embodiment, in an example of automatically returning using the magnetic attraction of the ceramic body and the magnet system, the coil further comprises a circuit board, wherein the coil is electrically connected to the circuit board, A current is supplied to the circuit board, wherein the circuit board is fixed on the upper side of the ceramic body, and the coil is fixed to the bottom side of the ceramic body.

In one example, in an example of automatically returning using the elastic recovery performance of an elastic plate, the circuit further includes a circuit board, wherein the coil is electrically connected to the circuit board, And the circuit board is fixed to the upper side of the elastic plate, and the coil is fixed to the bottom side of the elastic plate.

In an example of returning using rotation of the cam, in one embodiment, the apparatus further includes a circuit board, wherein the coil is electrically connected to the circuit board, and the induced current generated in the coil is supplied to the circuit board Wherein the coil is fixed to the bottom side of the circuit board, and the circuit board is interconnected with the cam so that the cam drives the circuit board and further drives the coil in motion. Preferably, the ceramic body is provided on the upper side and the bottom side of the circuit board, or is molded integrally with the circuit board.

In one example, in the example of returning using the seesaw plate, the coil further includes a circuit board, the coil being electrically connected to the circuit board, the induced current generated in the coil being supplied to the circuit board, Wherein the circuit board is fixed on the upper side of the seesaw plate.

In one example, in an example of returning using rotation of the cam, a circuit board is further included, wherein the width of the magnetic gap is between 0.5 mm and 10 mm, and the winding of the coil is between 50-800 wheels , And the wire diameter of the coil is between 0.06 mm and 0.5 mm. It will be understood that the foregoing specific values are by way of example only and are not intended to limit the present invention in any way.

According to another aspect of the present invention there is provided a wireless transmitter further comprising a kinetic energy generator and a high frequency wireless transmission circuit board, wherein the high frequency wireless transmission circuit board comprises a frequency module, The radio transmission circuit board is electrically connected to the coil in the kinetic energy generation device.

According to another aspect of the present invention, the present invention further provides a method of generating kinetic energy,

Generating an induced current by causing a displacement relative to the annular magnetic gap of the coil and the magnet system to occur under the action of the drive so that the coil is cut by the magnetic induction wire of the magnet system.

In one embodiment, the method of generating kinetic energy further comprises:

And driving the coil to reciprocate with respect to the magnetic gap so that the coil is cut by the magnetic induction wire of the magnet system to generate the induction current.

In one embodiment,

Driving the ceramic body to move the coil away from the magnetic gap in response to an external force acting on the ceramic body of the driving device; And

And in response to the sudden loss of the external force, magnetic attraction of the ceramics and the magnet system causes the ceramics to automatically return so that the coils enter the magnetic gap.

In one embodiment,

In response to an external force acting on the elastic plate of the driving device, driving the elastic plate to disengage the coil from the magnetic gap and accumulating elastic potential energy; And

And in response to the sudden loss of the external force, an elastic recovery performance of the elastic plate causes the elastic plate to automatically return so that the coil enters the magnetic gap.

In one embodiment,

Responsive to an external force acting on the elastic plate of the drive, actuating the elastic plate to cause the coil to enter the magnetic gap and accumulating elastic potential energy; And

And in response to the sudden loss of the external force, an elastic recovery performance of the elastic plate causes the elastic plate to automatically return so that the coil is disengaged from the magnetic gap.

In one embodiment,

In response to an external force acting on the upper cam of the drive, the upper cam and the lower cam are separated and the coil is disengaged from the magnetic gap due to movement of the upper cam; And

When the upper cam continues to rotate, the upper cam and the lower cam are engaged again to allow the coil to enter the magnetic gap.

In one embodiment,

When the upper cam continues to rotate, the upper cam and the lower cam are engaged again under the action of magnetic attraction of the ceramics and the magnet system to allow the coil to enter the magnetic gap.

In one embodiment, the upper cam is connected to a circuit board, and the lower cam is fixed to the lower magnetic induction plate of the magnet system, and the ceramic body is installed on the circuit board.

In one embodiment,

In response to the first end of the seesaw supported by the fulcrum of the drive device being pressed, the first coil enters the corresponding first magnetic gap and the second coil leaves the corresponding second magnetic gap step; And

In response to the second end opposite to the seesaw plate being pressed, the second coil enters the corresponding second magnetic gap, and at the same time, the first coil departs from the corresponding first magnetic gap .

In one embodiment,

So that the corresponding end of the seesaw plate is adsorbed and coupled with the corresponding magnet system via the magnetic attraction force correspondingly to the coil entering the magnetic gap.

In one embodiment, the magnetic gap < RTI ID = 0.0 >

Providing a columnar lower magnetic induction plate having a U-shaped longitudinal section;

Providing a permanent magnet body and an upper magnetic induction plate having an outer diameter smaller than an inner diameter of the lower magnetic induction plate; And

And the step of forming the magnetic gap by sequentially providing the permanent magnet body and the upper magnetic induction plate in the lower magnetic induction plate.

In view of the above, the kinetic energy generating device of the present invention is simple in structure, low in cost, safe and reliable in its power generation process, and does not cause pollution to the environment, . The kinetic energy generating method of the present invention is very advantageous for realizing the current demand of the electronic device, because the operation process is simple and convenient. The radio transmitter of the present invention is simple in structure, safe in performance, and inexpensive.

1 is a front structural view of a first embodiment of the kinetic energy generating device and the radio transmitter of the present invention.
2 is a three-dimensional structure diagram of the magnet system in the first embodiment of the kinetic energy generating device of the present invention.
FIG. 3 is an exploded view of the magnet system of FIG. 2. FIG.
4 to 6 are flowcharts of the kinetic energy generator of the present invention.
7 is an exploded view of a second embodiment of the kinetic energy generating device and the wireless transmitter of the present invention.
8 to 10 are explanatory views of the principle of operation of the kinetic energy generating device and the radio transmitter of the second embodiment of the present invention.
11 is a front structural view of the kinetic energy generating device of the present invention and the third embodiment of the radio transmitter.
12 is a three-dimensional structure diagram of the kinetic energy generating device of the present invention and the third embodiment of the radio transmitter.
13 is an exploded view of the kinetic energy generating device and the radio transmitter of the third embodiment of the present invention.
FIGS. 14 to 16 are explanatory views of the operation principle of the third embodiment of the kinetic energy generating device and the radio transmitter of the present invention.
17 is a three-dimensional structure diagram of the kinetic energy generating device of the present invention and the fourth embodiment of the radio transmitter.
18 is an exploded view of the kinetic energy generating device of the present invention and the fourth embodiment of the radio transmitter.
Fig. 19 is a view for explaining a moving direction of the driving device in the radio transmitter shown in Fig. 17; Fig.
20 to 21 are explanatory views of the principle of operation of the kinetic energy generator of the present invention and the fourth embodiment of the radio transmitter.

The following description is intended to enable a person skilled in the art to implement the present invention by disclosing the present invention. The preferred embodiments of the following description are by way of example only and those skilled in the art may conceive of other obvious variations. The basic principles of the invention as defined in the following description may be applied to other implementations, modifications, improvements, equivalent implementations, and other techniques that do not depart from the spirit and scope of the invention.

It will be apparent to those skilled in the art that the terms "longitudinal", "transverse", "upper", "lower", "before", "after", "left", "right" , "Horizontal", "upper", "lower", "inner", "outer" refer to the orientation or positional relationship shown in the attached drawings, It is to be understood that the term " device " or " device " is for the purpose of convenience and simplicity of description of the present invention only and does not necessarily imply or imply that the indicated device or element must have a particular orientation, It should not be understood as doing.

The present invention mainly provides a kinetic energy generator, wherein the kinetic energy generator provides a magnetic gap and a coil to drive the coil to reciprocate in the magnetic gap to generate an induction current, The kinetic energy generating device obtains the effect of generating electricity.

1 to 6, in the first embodiment of the kinetic energy generating device of the present invention, the kinetic energy generating device includes a magnet system 10, a driving device 20, and a coil 30 The magnetic gap 14 is formed in the magnet system 10 and the coil 30 is fixed to the driving device 20 so that the magnetic gap 14 14 generates an induction current, thereby obtaining the effect that the kinetic energy generating device of the present invention generates electricity.

As shown, the magnet system 10 forms an annular magnetic gap 14, which generates an induced current in the coil by generating a relative displacement with respect to the magnetic gap 14, The power generation operation can be performed. The position of the magnetic gap 14 is fixed and the manner in which the coil 30 is moved or the position of the coil 30 is fixed and the position of the magnetic gap 14 is changed. So that a relative displacement occurs between the coil 30 and the magnetic gap 14. More specifically, the magnet system 10 is fixed, the driving device 20 drives the coil 30 to move, or the coil 30 is fixed, and the driving device 20 The coil 30 and the magnetic path system 10 are displaced relative to each other so that the coil 30 moves in the magnetic gap 14 in a high speed reciprocating motion, The coil 30 is cut at a high speed by the magnetic induction line of the magnet system 10, and thus, an induction current is generated in the coil 30 based on the electromagnetic induction principle. In the preferred embodiment of the present invention, the driving unit 20 drives the coil 30 to generate an induced current.

2 and 3, in the first embodiment of the present invention, the magnet system 10 includes an upper magnetic induction plate 13, a permanent magnet body 12, and a lower magnetic induction plate (not shown) Wherein the lower magnetic induction plate 11 has a concave groove 111 and the permanent magnet body 12 is provided in the concave groove 111 of the lower magnetic induction plate 11 And the upper magnetic induction plate 13 is bonded to the upper surface of the permanent magnet body 12 so that the upper magnetic induction plate 13 and the lower magnetic induction plate 13 are separated from each other. The permanent magnet body 12 forms the annular magnetic gap 14 in which the magnetic induction line is densely distributed in the lower magnetic induction plate 11. [

In addition, in the first embodiment of the present invention, the lower magnetic induction plate 11 is a cylindrical magnetic induction plate whose longitudinal section is U-shaped, so that the concave groove 111 is also a columnar shape, Wherein an outer diameter of the permanent magnet body (12) located in the concave groove (111) of the cylindrical lower magnetic induction plate (11) is smaller than a diameter of the concave groove (111) Since the plate 13 is also cylindrical and has an outer diameter equal to the outer diameter of the permanent magnet body 12, a magnetic induction line is tightly formed between the upper magnetic induction plate 13 and the lower magnetic induction plate 11 So that the magnetic gap 14 distributed can be formed.

As a modification of the first embodiment of the present invention, the upper magnetic induction plate 13 and the lower magnetic induction plate 11 may adopt other shapes or structural forms. For example, the lower magnetic induction plate 11 may be a U-shaped hollow rectangular box or the like, and the upper magnetic induction plate 13 and the permanent magnet body 12 may be formed in the lower magnetic induction plate 11 It suffices to form the magnetic gap 14 in which the magnetic induction line is densely distributed. The present invention is not limited thereto and all of the technical features which are the same as or similar to the present invention can be obtained by using the same or similar technical means as the present invention.

The person skilled in the art may determine the manner of forming the magnetic gap 14 according to the actual situation and if they can generate the magnetic gap 14 they are all within the protection range of the kinetic energy generating device of the present invention The specific embodiments of the present invention are not limited thereto.

1 and 4, in the first embodiment of the kinetic energy generating apparatus of the present invention, the driving apparatus 20 includes a driving unit, which in the present embodiment is a ceramic body 21, It is made of a magnetic ceramic material. It will be appreciated that the actuator may be formed by coating a non-magnetic material surface with a ceramic material, and the present invention is not limited in this respect. In the presently preferred embodiment, the actuator is specifically implemented with a steel plate. The cross section of the coil 30 is O-shaped and is fixed to the bottom surface of the ceramic body 21. When the ceramic body 21 is provided on the upper surface of the upper magnetic induction plate 13, May be inserted into the magnetic gap 14. When the ceramics body 21 is installed on the surface of the upper magnetic induction plate 13 due to the porosity of the ceramics body 21, the attractive force of the permanent magnet body 12 below the upper magnetic induction plate 13 The upper magnetic induction plate 13 is firmly attracted to the upper surface of the upper magnetic induction plate 13 and the coil 30 is correspondingly positioned in the magnetic gap 14. [ When the coil 30 is separated from the magnetic gap 14 but is still located within the magnetic attraction field range of the magnetic path system 10, the coil 30 is in contact with the magnetic attraction force of the magnetic path system 10 The upper magnetic induction plate 13 can be quickly moved back to a position where the upper magnetic induction plate 13 and the upper magnetic induction plate 13 are attracted to each other.

4 to 6 are explanatory views of the operation of the first embodiment of the kinetic energy generator of the present invention.

4, when the ceramics body 21 is attracted together with the upper surface of the upper magnetic induction plate 13 by the attraction force of the permanent magnet body 12, Is located in the magnetic gap (14), and the kinetic energy generating device is in a stationary state.

5, when the ceramic body 21 is moved upward by the external force F, the coil 30 moves upward along the ceramics body 21, By a predetermined distance. At the same time, since the ceramics body 21 can receive a force pulling down the permanent magnet body 12, the external force F is directed upward from the upper magnetic induction plate 13 The potential of the coil 30 is necessarily maintained by the strong magnetic attracting force of the permanent magnet body 12, so that the coil 30 has potential energy.

6, when the external force F suddenly disappears, the ceramics body 21 quickly moves downward and returns by the action of the magnetic force of the permanent magnet body 12, And is again attached to the surface of the guide plate 13. At the same time, the coil 30 fixed to the ceramics body 21 is also moved downward at high speed by the ceramics body 21 and is inserted into the magnetic gap 14. The high speed movement of the coil 30 in the magnetic gap 14 causes the coil 30 to be quickly cut by the magnetic induction line densely distributed in the magnetic gap, An electric current is generated, and the induced current can be used to drive the corresponding device.

Specifically, in the first embodiment of the present invention, the ceramics body 21 is a steel plate, and, alternatively, a person skilled in the art can change the type of the ceramics body 21 according to the actual situation. For example, cobalt, nickel, alloys thereof, and the like can be selected and used. In addition, those skilled in the art can change specific technical solutions according to the teachings of the present invention, for example, the coil 30 does not move and the magnet system 10 is set to move, The coil may be cut through a magnetic induction wire in the magnet system 10 to generate a current. In other words, a current can be generated immediately by cutting the coil 30 through the magnetic induction line in the magnet system 10, so that the same or similar technology as the present invention can be adopted, All of which are within the scope of protection of the present invention and are not limited to the specific embodiments of the present invention.

In the first embodiment of the kinetic energy generating device of the present invention, the width of the magnetic gap 14 is between 0.5 mm and 10 mm, the winding of the coil 30 is between 50 and 800 wheels, 30) is 0.06 mm-0.5 mm. Those skilled in the art will be able to determine the width of the magnetic gap 14 and the winding diameter of the coil 30 and the diameter of the coil 30 according to the electrical energy size demand, All of which are within the scope of protection of the present invention and are not limited to the specific embodiments of the present invention.

Those skilled in the art can adopt any method for generating the induced current by driving the coil 30 to reciprocate in the magnetic gap 14, for example, electric power drive, mechanical power drive, The same kinetic energy generating device of the present invention can be applied to the kinetic energy generating device of the present invention by adopting the same or similar technical solution as the kinetic energy generating device of the present invention to solve the same or similar technical problem, It is within the scope of protection.

In addition, when the driving device 20 drives the coil 30 to reciprocate in the magnetic gap 14, the return motion of the coil 30 in the magnetic gap 14 is performed through the suction force Or a reciprocating motion of the coil 30 in the magnetic gap 14 through an elastic force or a reciprocating motion of the coil 30 in the magnetic gap 14 through an inertial force or an external force And the person skilled in the art can decide according to the specific situation. The concrete embodiment of the kinetic energy generating device of the present invention is not limited thereto.

It should be emphasized that the circuit board 22 is electrically connected to the kinetic energy generating device of the present invention to drive the circuit board 22 through an induction current generated by the kinetic energy generating device to perform a corresponding operation At the start, the kinetic energy generator with the circuit board 22 becomes a radio transmitter.

Specifically, the coil 30 is electrically connected to the circuit board 22, and the circuit board 22 can be integrated with a series of circuit elements 221, Can be fixed to the upper side of the ceramics body 21 to be implemented. That is, as shown in FIG. 4, a compact structure can be formed on the upper side of the magnet system 10, and a person skilled in the art can also be located on the circumference side of the magnet system 10 And can only be electrically connected to the coil 30.

The induction current generated by the coil 30 is converted to the power used by the voltage converter in the circuit board 22 to provide power to the main control module of the circuit board. At the same time, when the high frequency radio frequency circuit is integrally integrated on the circuit board 22, the main control module can also generate a control command, which is transmitted to the various electronic devices through the high frequency radio frequency circuit And controls the electronic device. For example, when the control command is transmitted to an electronic control system and the electronic control system can be used as a smart home control system, it is operatively connected via a central control unit to a different electronic element, , A curtain control unit, an air conditioning control unit, and a smart indicating unit.

For example, in typical applications, the kinetic energy generating device of the present invention can be applied to a self-generating wireless switch, of which the self-generating wireless switch is applied to connect any electronic device. The self-generating wireless switch in which the kinetic energy generating device of the present invention is disposed controls the self-generating device of the electronic device in a switch manner. For example, the self-generating wireless switch of the preferred embodiment is used to control the illuminator in a switched manner. It should be understood that the self-generating wireless switch may switch on or off other electronic devices, for example, home or office electronic devices such as TVs, refrigerators, and electric fans.

In the above embodiment of the present invention, a kinetic energy generating method applied to power a small electronic device is provided, and a typical example is applied to a wireless switch to form a wireless self-generating switch, the method including the following steps do. Driving the ceramic body (21) to move under the action of external force such that the coil (30) connected to it moves away from the annular magnetic gap (14) of the magnet system (10) by a predetermined distance; And

When the action of the external force is lost, the ceramics body 21 is again attracted to the magnet system 10 under the action of the magnetic absorption force of the magnet system 10, and at the same time, (14), and causing the coil (30) to be cut by the magnetic induction wire of the magnet system (10), thereby generating an induction current to generate electricity.

In this method, as shown in the drawing, when the ceramics 21, which is made of an external plate, is lifted up and the coil 30 is separated from the magnetic gap 14 by a predetermined distance, And the iron plate is normally attracted by the magnet when the iron plate is attracted by the magnet. Therefore, when the external force is to be separated upward from the magnet, it is inevitable that the strong attraction force of the magnet Thereby maintaining the potential energy. When the external force suddenly disappears, the iron plate moves downward rapidly by the action of the attracting force of the magnet and is attracted to the magnet again. At the same time, the coil coupled with the magnet is also inserted into the magnetic gap 14 at a high speed downwardly, and the high speed movement of the coil causes the coil 30 to be quickly cut by the magnetic induction line, An induced current is generated in the coil 30.

For example, specifically, in application to a wireless switch or other small electronic device, the ceramic body 21 as the actuator moves under the external force of operation such as pushing, turning, pushing, When the external force applied by the user suddenly disappears, the ceramic body 21 is automatically returned to the initial attraction position by the action of the magnetic attraction force of the magnet system 10 , The coil 30 enters the magnetic gap 14 again. As described above, the high-speed reciprocating motion for leaving and entering the magnetic gap 14 causes the coil to be cut at a high speed by the magnetic induction line of the magnet system 10, thereby generating an induced current.

It will be appreciated that, in this manner, this structure is simpler since the ceramics 21 automatically return under the magnetic action of the magnet system 10. In another embodiment, the ceramics body 21 may be automatically returned through other methods, for example, to return the ceramics body 21 through elastic deformation recovery performance. For example, when the ceramic body 21 is connected to a spring so that when the coil 30 is released from the magnetic gap 14, the spring is pulled or compressed and an external force is lost, The coil 30 is returned to the magnetic gap 14 by recovering the initial state and returning the ceramics body 21 to complete a rapid reciprocating movement.

According to the above inventive concept, in the initial state, the coil (30) is located in the magnetic gap (14), and in the primary power generation operation, the coil (30) After leaving the magnetic gap 14, the magnetic gap 14 is returned. The coil 30 is positioned outside the magnetic gap 14 and the coil 30 is positioned outside the magnetic gap 14 during the first power generation operation, And then enters the magnetic gap 14 and then deviates from the magnetic gap 14 again. Consequently, an induction current can be generated in the coil 30 by allowing the coil 30 to enter and leave the magnetic gap 14 at a high speed.

7 to 10 show a specific application example of the second embodiment as the radio transmitter of the present invention. In this embodiment, similarly, the radio transmitter includes a magnet system 10A, a driving device 20A and a coil 30A , And the magnet system 10A includes an upper magnetic induction plate 13A, a permanent magnet body 12A, and a lower magnetic induction plate 11A. The permanent magnet body 12A is provided on the concave groove of the lower magnetic induction plate 11A and has a space between the four side walls of the lower magnetic induction plate 11A, The upper magnetic induction plate 13A and the permanent magnet body 12A are attached to the upper surface of the permanent magnet body 12A and the lower magnetic induction plate 11A is formed in a ring- Thereby forming the magnetic gap 14A. In this embodiment, the radio transmitter generates the induction current by reciprocating the coil 30A in the magnetic gap 14A using the elastic plate 21A, and also generates the induction current through the circuit board 22A ) To perform transmission.

7 is an exploded view of the first embodiment of the present invention. 7, in this embodiment, the circuit board 22A is electrically connected to the coil 30 of the kinetic energy generating device, and among the kinetic energy generating devices, the driving device 20A Wherein the coil 30A is fixed to the lower surface of the elastic plate 21A and the upper surface of the elastic plate 21A is fixed to the circuit board 22A The circuit board 22A is electrically connected to the coil 30A and the coil 30A reciprocates in the magnetic gap 14A by the elastic force of the elastic plate 21A , The power generation effect of the kinetic energy generation device is realized. It will be appreciated that the circuit board 22A may be fixed at other locations in the overall power generation system, without having to be secured to the upper surface of the elastic plate 21A.

The elastic plate 21A has a first end 211A and a second end 212A and the first end 211A has a first fixing hole 2111A and a second fixing hole 2111A, 2112A. The kinetic energy generating device of the present invention further includes a base sheet 40 on which a first fixing sheet 41 and a second fixing sheet 42 are fixedly installed . The first fixing sheet 41 and the second fixing sheet 42 have the same height and the elastic plate 21A is fixed to the first fixing hole 2111A and the second fixing hole 2112A through the first fixing hole 2111A and the second fixing hole 2112A, And is fixed to the first fixing sheet 41 and the second fixing sheet 42, thereby realizing fixing to the base sheet 40. [ In other words, under the support of the first fixing sheet 41 and the second fixing sheet 42, the elastic plate 21A can realize relative fixing with respect to the base sheet 40, The second end 212A of the elastic plate 21A is relatively positioned with respect to the first end 211A of the elastic plate 21A so that the elastic plate 21A can be held in the horizontal position .

In other words, the proximal end of the elastic plate 21A is fixed in position via one or a plurality of fixing sheets 41, 42, and the bottom surface of the distal end is fixed to the coil 30A. The distal end of the elastic plate can be automatically returned by rotating the first end 211A, which is a near end thereof as the second end 212A, as a fulcrum. That is, in the embodiment of the present invention, the coil 30A is automatically returned through the elastic recovery performance of the elastic plate 21A, unlike the above-described embodiment, which returns the coil 30 through the magnetic attraction force.

The first fixing sheet 41 and the second fixing sheet 42 are located below the second end 212A of the elastic plate 21A and the height of the elastic plate 21A The coil 30A is driven to accurately position the coil 30A in the magnetic gap 14A formed by the magnetic path system 10A. In other words, when the elastic plate 21A is stopped in the state where there is no external force, the height thereof is substantially equal to the height of the magnet system 10A, and when the external force on the elastic plate 21A is lost, The coil 30A can be positioned in the magnetic gap 14A formed in the magnet system 10A, so that the kinetic energy generation device of the present invention can have a power generation function.

In addition, the shape of the second end 212A of the elastic plate 21A ensures that the O-coil 30 can be fixed to the lower surface thereof. Preferably, the second end 212A of the elastic plate 21A is circular, and the second end 212A of the circular shape is an enlarged portion, the outer diameter of which is larger than the outer diameter of the coil 30A , The coil 30A can be stably fixed to the lower surface of the second end 212A of the elastic plate 21A. The second end 212A of the elastic plate 21A further includes a protrusion 2121A which protrudes from the second end 212A of the elastic plate 21A, As shown in FIG. It will be appreciated by those skilled in the art that the shape is exemplary only and is not intended to limit the invention.

8 to 10 are explanatory diagrams of a power generation process of the radio transmitter according to the embodiment of the present invention.

8, when no external force is applied to the elastic plate 21A, the second end 212A of the elastic plate 21A and the coil 30A are connected to the magnet system (not shown) 10A. At the same time, the coil 30A is located in the magnetic gap 14A formed in the magnet system 10A. At this time, the entire kinetic energy generator is in a stopped state.

9, when the external force F1 acts upward on the protrusion 2121A on the second end 212A of the elastic plate 21A, the coil 30A contacts the elastic plate 21A ) Of the magnetic gap 14A along the second end 212A of the magnetic gap 14A. At this time, the first end 211A of the elastic plate 21A is fixed to the first fixing sheet 41 and / or the second fixing sheet 42 on the base sheet 10, The second end 212A of the plate 21A is upwardly acted by the external force F1 and the second end 212A of the elastic plate 21A is deformed upwardly, .

10, when the external force F1 is lost, the force applied to the protrusion 2121A on the second end 212A of the elastic plate 21A is released, 21A are moved downward at high speed by the action of the elastic force. The coil 30A also quickly returns to the magnetic gap 14A along with the high-speed downward movement of the second end 212A of the elastic plate 21A, and the coil 30A returns to the inside of the magnetic gap 14A The magnetic flux is quickly cut off by the magnetic induction line that is densely distributed in the magnetic gap 14A and finally the induction current is generated and transmitted to the circuit board 22A, 22A to perform a corresponding radio transmission operation.

As a modification of the present embodiment, a person skilled in the art can appropriately change the structure and shape of the elastic plate 21A and the material of the elastic plate 21A according to actual situation or specific needs, All of which are within the scope of protection of the present invention, by adopting the same or similar technical means as the transmitter and solving the same or similar technical problems as the present invention and achieving the same or similar technical effect as the present invention, But the present invention is not limited thereto.

In the radio transmitter of the present invention, the circuit board 22A is a high frequency wireless transmission circuit board, and the high frequency wireless transmission circuit board is provided with a series of circuit board elements 221A and a transmission module (RF frequency module) The same) is integrated. That is, the coil 30A of the kinetic energy generation device is electrically connected to the high frequency wireless transmission circuit board. When the coil 30A of the kinetic energy generating device is cut by the magnetic induction wire densely distributed in the magnetic gap 14A to generate the induction current, the induction current flows to the circuit board element 221A And controls the operation of the electronic device by driving the high frequency wireless transmission circuit board having the RF transmission module to transmit the high frequency radio wave.

The elastic plate 21A as the actuator in the embodiment of the present invention generates an induction current in the coil 30 by moving the coil 30A in a manner similar to a lever to generate a high reciprocating movement. The coil 30A is located in the magnetic gap 14A and the protrusion 2121A is lifted up so that the second end 212A of the elastic plate 21A is moved upward The coil 30A is separated from the magnetic gap 14A and the potential energy is accumulated in the elastic plate 21A when the first stage 211A is rotated upwardly and the external force is lost, It can be understood that the induction current is generated by causing the coil 30A to enter the magnetic gap 14A again and to be cut at a high speed by the magnetic induction line of the magnetic path system 10A There will be. In another embodiment, the height of the fixing sheets 41 and 42 is higher than that of the magnet system 10A. In an initial state, the coil 30A is positioned outside the magnetic gap 14A, When the protrusion 2121A is pressed downward and the second end 212A of the elastic plate 21A is rotated downward toward the support point of the first end 211A, The elastic plate 21A automatically rotates upwards to return to the position where the coil 30A is in contact with the magnetic gap 21A when the elastic plate 21A returns to the position of the gap 14A and the potential energy accumulates in the elastic plate 21A, The coil 30A is allowed to enter and leave the magnetic gap 14A at a high speed so that the mall 30A is cut at a high speed by the magnetic induction wire of the magnetic path system 10A Understand that an induction current is generated Will.

Correspondingly, embodiments of the present invention provide kinetic energy generation methods that are applied in providing power to small electronic devices. For example, a typical application to a wireless switch is to form a wireless self-generating switch,

The elastic plate 21A is elastically deformed by the action of the external force and the second end 212A performs the lever movement with the first end 211A as a fulcrum and drives the coil 30 connected to the elastic plate 21A, Leaving a predetermined distance from the annular magnetic gap (14A) of the annular magnetic gap (14A); And

When the external force is lost, the elastic plate 21A is automatically returned to automatically return the coil 30A. The coil 30A is cut by the magnetic induction wire of the magnet system 10A, And generating an induced current for generating the induced current.

Alternatively,

The second stage 212A of the elastic plate 21A undergoes a lever movement with the first stage 211A as a fulcrum under the action of an external force to cause elastic deformation and drives the coil 30 connected thereto to drive the jigger system 10A, Into an annular magnetic gap (14A); And

And driving the coil (30A) to be separated from the magnetic gap (14A) by automatically returning the elastic plate (21A) when the external force action disappears, wherein the coil (30A) And is excited by the magnetic induction line of the system 10A to generate an induction current for generating electricity.

It should be noted that the action of the external force received by the elastic plate 21A may be a direct action from the user or other indirect action and may cause a positional shift to the distal end of the elastic plate 21A It is only necessary to accumulate the elastic potential energy.

When the coil 30A is fixed and the actuator of the driving device is used to drive the magnet system 10A, the distal end of the elastic plate 21A can be fixed to the magnet system 10A So that, under the action of an external force, when the distal end of the elastic plate 21A is pivoted relative to the end near the end, the coil 30A is unchanged in position and the magnetic system 10A is driven to move When the external force suddenly disappears, the elastic plate 21A is automatically returned by the elastic recovery performance, thereby automatically returning the magnet system 10A. Thus, A high-speed reciprocating movement opposite to the gap 14A and the coil 30A is generated, so that the coil 30A can generate an induced current. Similarly, when the elastic plate 21A is used to drive the magnet system 10A, in the initial state, the coil 30A may be located in the magnetic gap 14A, And the repetitive cycling process may be such that the movement of the magnetic path system 10A causes the magnetic gap 14A to be firstly disengaged from the coil 30A and then quickly returned, May be such that the magnetic gap 14A is first applied to the periphery of the coil 30A and then quickly released from the coil 30A again.

11-16 illustrate a third embodiment of the radio transmitter of the present invention. Similarly, the radio transmitter includes a magnet system 10B, a drive device 20B and a coil 30B, 10B includes an upper magnetic induction plate 13B, a permanent magnet body 12B and a lower magnetic induction plate 11B and the permanent magnet body 12B is mounted on a concave groove of the lower magnetic induction plate 11B And the upper magnetic induction plate 13B is attached to the upper surface of the permanent magnet body 12B so that the upper magnetic induction plate 13B is attached to the lower magnetic induction plate 11B, And the permanent magnet body 12B form the annular magnetic gap 14B in which the magnetic induction line is densely distributed in the lower magnetic induction plate 11B.

The difference between the third embodiment and the first embodiment of the radio transmitter is that, in the third embodiment, the coil 30B reciprocates up and down in the magnetic gap 14B by using the relative circumferential rotational movement of the cam And generates the induction current and drives the circuit board 22B through the induction current to perform a corresponding transmission operation.

In detail, in the third embodiment of the radio transmitter according to the present invention, the driving device 20B includes a driver having a cam, and the cam has a cylindrical shape in which the upper cam 201B and the lower cam 202B, The upper cam 201B has a first space 2011B and the lower cam 202B has a second space 2021B. A plurality of continuous first protrusions 2012B are provided at the edge of the upper cam 201B and each of the first protrusions 2012B has a first upper end 20121B and a first lower end 20122B . Likewise, a plurality of second projecting teeth 2022B are provided at the edges of the lower cam 202B so as to be mutually engaged with the first projecting teeth 2012B, 2 upper end 20221B and a second lower end 20222B. The first upper end 20121B of the first projecting teeth 2012B is connected to the second projection 2022B of the second projecting teeth 2022B when the respective first projecting teeth 2012B are engaged with the second projecting teeth 2022B, 2 upper end 20221B and the first lower end 20122B of the first protrusion 2012B is located at the second lower end 20222B of the second protrusion 2022B; When the upper cam 201B circumferentially rotates with respect to the lower cam 202B, the first upper end 20121B and the lower first end 20122B of the first projecting teeth 2012B on the upper cam 201B, The upper cam 201B slides along the second upper end 20221B and the second lower end 20222B of the second protrusion 2022B on the lower cam 202B, Thereby performing a reciprocating up and down movement.

As shown in FIGS. 12 and 13, the radio transmitter further includes a circuit board 22B, and the circuit board 22B is fixed to the upper cam 201B. Concretely, at least one fastening member 2013B is provided at the edge of the upper cam 201B, and a fastening hole 222B having the same number as the fastening member is provided at the edge of the circuit board 22B It is convenient to fix the circuit board 22B to the upper cam 201B through the engagement of the fastening member 2013B and the fastening hole 22B. In the above embodiment of the radio transmitter of the present invention, three coupling members 2013B are provided at the edge of the upper cam 201B, and the coupling members 2013B , And the circuit board 22B can be fixed together with the upper cam 201B. It will be understood that the fastening member 2013B may be provided on the circuit board 22B and the fastening hole 222B may be provided on the upper cam 201B. Of course, the circuit board 22B and the upper cam 201B may be fixedly connected to each other through other connection methods, and the present invention is not limited in this respect.

The coil 30B is fixed to the lower surface of the circuit board 22B and is located in the first space 2011B of the upper cam 201B and the upper surface of the circuit board 22B is made of ceramics 21B ). The ceramics body 21B is fixed to the upper surface of the circuit board 22B and may be made of a porcelain material such as an iron plate or may be formed by coating a porcelain material with a non-magnetic material. At the same time, in the modified embodiment of the radio transmitter of the present invention, the magnet system 10B is the same as the magnet system 10 in the first embodiment of the kinetic energy generator, and the magnet system 10B Is located in the second space 2021B of the lower cam. When the upper cam 201B and the lower cam 202B are engaged, the coil 30B is positioned in the magnetic gap 14B formed in the magnetic path system 10B.

The ceramic body 21B may be positioned on the lower surface of the circuit board 22B or may be integrated with the circuit board 22B so as to generate magnetic attracting force with the magnet system 10, It can be understood that it is only necessary to automatically return to the engagement state. The ceramic body 21B may be fixed to the upper cam 201 and the circuit board 22B may be fixedly connected to the ceramics body 21B.

14 to 16 are explanatory views of the operating principle of the third embodiment of the radio transmitter of the present invention.

14, at the initial position, the ceramics body 21B receives the downward attractive force of the permanent magnet body 12B in the magnet system 10B, and at the same time, The cam 201B is fixed together and the circuit board 22B is fixed to the ceramics body 22B so that the upper cam 201B is magnetized with the magnetic force of the ceramics body 21B and the permanent magnet body 12B And is completely engaged with the lower cam 202B by the action of suction force. At this time, the coil 30B is positioned in the magnetic gap 14B of the magnetic path system 10B and is in a stationary state.

As shown in Fig. 15, when the lower cam 202B is kept fixed and the circumferential action of the external force F2 is applied to the upper cam 201B, the first projection 201B on the upper cam 201B, The teeth 2012B begin to separate along the second protrusion 2022B on the lower cam 202B; The first upper end 20121B of the first projecting teeth 2012B on the upper cam 201B corresponds to the second lower end 20222B of the second projecting teeth 2022B on the lower cam 202B The coil 30B is separated from the magnetic gap 14B and the distance between the upper cam 201B and the lower cam 202B reaches a maximum value.

16, the ceramic body 21B is affected by the magnetic force of the magnet system 10B, and when the upper cam 201B is continuously rotated at a high speed, The first protruding teeth 2012B on the cam 201B and the second protruding teeth 2022B on the lower cam 202B are meshed again and the coil 30B is rotated in the downward direction of the upper cam 201B Enters the magnetic gap 14B again along the movement, and is cut at a high speed by the magnetic induction line densely distributed in the magnetic gap 14B. According to the electromagnetic induction principle, when the upper cam 201B moves downward rapidly and the coil 30B is cut at a high speed by the magnetic induction line which is densely distributed in the magnetic gap 14B, the coil 30B An induced current may be generated. The induced current can be driven to perform the corresponding operation of the circuit board 22B.

It should be noted that in the third embodiment of the radio transmitter of the present invention, the direction of rotation of the upper cam 201B and the lower cam 202B is adjustable according to the actual situation, And the lower cam 202B perform a circumferential movement along the first protruding teeth 2012B and the second protruding teeth 2022B so that the coil 30B can reciprocate in the magnetic gap 14B An induced current can be generated immediately.

In addition, in the third embodiment of the radio transmitter according to the present invention, the ceramics body 21B is specifically made of a steel plate, and a person skilled in the art can determine specific materials of the ceramics body 21B It is possible. For example, the magnetic material may be a magnetic material opposite to the magnetic pole of the magnet system 10B, and all of the magnetic materials having the porcelain performance are within the protection scope of the present invention, and the specific embodiment of the present invention is not limited thereto.

The technician in the field can also adjust the motion relationship between the upper cam 201B and the lower cam 202B according to the needs or actual conditions of the customer. In other words, a person skilled in the art fixes the upper cam 201B, and the lower cam 202B allows the second protrusion 2022B to move along the first protrusion 201B, As shown in FIG. In other words, a person skilled in the art can generate the induction current by installing the coil 30B as fixed, and by installing the magnet system 10B to reciprocate with respect to the coil 30B. However, the present invention is not limited to the above-described embodiments, and the same or similar technical effects of the present invention may be adopted to achieve the same or similar technical effects as the present invention. .

In the third embodiment of the radio transmitter of the present invention, the circuit board 22B is a high frequency wireless transmission circuit board, and the circuit board element 221B and the frequency module (RF frequency module) The same applies hereinafter) are electrically connected. That is, the coil 30B of the kinetic energy generation device is electrically connected to the high frequency wireless transmission circuit board. When the induction current is generated by cutting the coil 30B in the kinetic energy generation device by the magnetic induction line densely distributed in the magnetic gap 14B, the induction current flows to the circuit board element 221B and the RF Frequency radio transmission circuit board provided with the frequency module to control the operation of the electronic device by emitting radio-frequency radio waves.

In the third embodiment of the radio transmitter according to the present invention, the shape and structure of the cam can be changed to, for example, an elliptical shape or a ring shape according to the actual situation, 30B may be driven to reciprocate in the magnetic gap 14B to generate the induced current, all of which are within the scope of protection of the present invention, and the embodiment of the present invention is not limited thereto.

Correspondingly, in the above embodiment of the present invention, there is provided a kinetic energy generating method for application to powering a small electronic device, such as is typically applied to a wireless switch to form a wireless self-generating switch , The method

The upper cam 201B starts to separate from the lower cam 202B by the action of an external force and drives the circuit board 22B connected to the upper cam 201B to rotate the coil 30B ) By a predetermined distance from the annular magnetic gap (14B) of the magnet system (10B); And

The magnetic attractive force between the ceramics body 21B and the magnetic path system 10B automatically returns the upper cam 201B and the circuit board 22B and the coil 30B is automatically Of which the coil 30B is cut by the magnetic induction wire of the magnet system 10B to generate an induction current for generating electricity.

Alternatively,

The lower cam 202B starts to be separated from the upper cam 201B by the action of an external force and is driven so that the system 10B is moved to the arm connected thereto and the coil 30B assembled to the circuit board 22B Leaving a predetermined distance from the annular magnetic gap (14B) of the magnet system (10B); And

When the external force is lost, the lower cam 202B is automatically returned to engage with the upper cam 201B, and the magnet system 10B is automatically driven to return, And enters the magnetic gap 14B of the system 10B wherein the coil 30A is cut by a magnetic induction wire of the magnet system 10B to generate an induction current for generating electricity do.

17 to 21 show a fourth embodiment of the radio transmitter according to the present invention. The difference between this embodiment and the first embodiment is that, in this embodiment, the radio transmitter uses the up / (30C) reciprocates in the magnetic gap (14C) formed in the magnet system (10C) to generate an induced current and drives the circuit board (22C) to perform a corresponding transmitting operation through the induced current There is.

17 and 18, the radio transmitter includes a base plate 50, a kinetic energy generating device and a circuit board 22C, and the kinetic energy generating device is fixed to the base plate And the circuit board 22C may be electrically connected to the kinetic energy generating device to perform a corresponding transmission operation by driving the induction current.

In detail, in the fourth embodiment of the radio transmitter of the present invention, the driving apparatus includes a driver which is specifically implemented as a seesaw plate in this embodiment, and the seesaw plate includes a first stage 21C and a second stage A supporting point 503 is fixed to the base plate 50 and two mounting seats are provided on both sides of the supporting point 503 so as to form a first concave groove 501, And the second concave groove 502 are formed. It will be understood that the concave groove 501 and the concave groove 502 may be concave in the base plate 50, and the present invention is not limited in this respect. In this preferred embodiment, the kinetic energy generating device of the radio transmitter includes a first kinetic energy generating unit and a second kinetic energy generating unit, wherein the first kinetic energy generating unit and the second kinetic energy generating unit are Are fixedly installed in the first concave groove (501) and the second concave groove (502) on both sides of the support point (503).

The first kinetic energy generating unit includes a first magnetic system 10C, a first coil 30C and a first driving device 20C. The first magnetic system 10C includes a first magnetic gap 14C, , And the second kinetic energy generation unit includes a second magnetic system (10C '), a second coil (30C') and a second driving device (20C '), and the second magnetic system And a second magnetic gap 14C '. The first driving device 20C drives the first coil 30C to reciprocate in the first magnetic gap 14C formed in the first magnetic induction system 10C, And the second driving device 20C 'is driven such that the second coil 30C' reciprocates in the second magnetic gap 14C 'formed in the system 10C' So that a second induced current can be generated. The circuit board 22C is electrically connected to the first coil 30C and the second coil 30C 'and receives a corresponding control command transmission operation through driving of the first induction current and the second induction current Can be performed. In the present embodiment, it is to be understood that the two drive units 20C form one overall drive structure, and more specifically, a seesaw plate that moves with the fulcrum portion 503 as a fulcrum. The two kinetic energy generating units may be symmetrically located on both sides of the fulcrum portion 503, and the positions thereof may be rationally divided according to actual conditions so as to be parallel to each other. For example, when the circuit board 22C is fixed on the left side of the seesaw plate, the fulcrum portion 503 may be located close to the first kinetic energy generating unit on the left side. The coil winding amount and the wire diameter of the two coils 30C and 30C 'may be the same or different.

18, the first magnetic induction system 10C includes a cylindrical first lower magnetic induction plate 11C whose longitudinal section is U-shaped, a first permanent magnet body 12C and a first upper magnetic induction plate 13C , Wherein the first lower magnetic induction plate 11C is fixedly installed in the first concave groove 501 and the first permanent magnet body 12C and the second upper magnetic induction plate 13C And the first upper magnetic induction plate 13C is disposed inside the first lower magnetic induction plate 11C and the first upper magnetic induction plate 13C is disposed inside the first lower magnetic induction plate 11C, Is bonded to the upper surface of the first magnetic gap (12C) to form the first magnetic gap (14C) in which the magnetic induction line is densely distributed in the first magnetic induction system (10C). Correspondingly, the second magnetic induction system 10C 'has a cylindrical second lower magnetic induction plate 11C', a second permanent magnet body 12C 'and a second upper magnetic induction plate 13C' Wherein the second lower magnetic induction plate 11C 'is fixedly installed in the second concave groove 502 and the second permanent magnet body 12C' and the second upper magnetic induction plate And the second upper magnetic induction plate 13C 'is disposed in the second lower magnetic induction plate 11C', and the second upper magnetic induction plate 13C ' Is bonded to the upper surface of the second permanent magnet body 12C 'to form the second magnetic gap 14C' in which the magnetic induction line is densely distributed in the second magnetic induction system 10C '. It will be understood that the magnetic gap 14C and the magnetic gap 14C 'are annular and the shape of the magnetic induction plate is not limited to the cylindrical shape.

The first coil 30C is of an O type and is fixed to the lower surface of the first driving device 20C and the first driving device 20C is arranged such that the first coil 30C is connected to the first magnetic system 10C of the first magnetic gap 14C. Correspondingly, the second coil 30C 'is O-shaped and fixedly mounted on the lower surface of the second driving device 20C', and the second driving device 20C 'is fixed to the lower surface of the second coil 30C' Can be driven to enter the second magnetic gap 14C 'formed in the system 10C'.

In other words, in the fourth embodiment of the radio transmitter according to the present invention, the first driving device 20C controls the first coil 30C via the first end 21C of the seesaw plate, And the second driving device 20C 'drives the second coil 21C' through the second end 21C 'of the seesaw plate so as to reciprocate in the first magnetic gap 14C formed in the system 10C, 30C 'are reciprocated in the second magnetic gap 14C' formed in the system 10C '.

17 to 21, in the fourth embodiment of the radio transmitter of the present invention, the circuit board 22C is fixedly mounted on the upper surface of the first driving device 20C. The circuit board 22C may be located on the upper surface of the second driving device 20C ', or may be located in the middle of the seesaw plate, or may be fixed to the base plate 50. [ The first drive device 20C and the second drive device 20C 'are connected to each other to form the seesaw plate 503. The fulcrum portion 503 is located at an intermediate portion of the lower surface of the seesaw plate, The first projections 211C and the second projections 211C are symmetrically provided at both ends of the plate and the first projections 211C are located on the left side of the first driving device 20C, The projection 211C 'is located on the right side of the second driving device 20C', and when one end of the seesaw plate uses the same force, the other end can be lifted. It is to be understood that the installation of the protrusions 211C and the protrusions 211C 'is simple in operation, and that the user can also simply press or lift both ends of the seesaw plate. The present invention is not limited in this respect Do not.

19, when the first projection 211C in the seesaw plate is pressed by an external force, the first driving device 20C is moved downward by the driving of the external force F3, The driving device 20C 'is lifted by the reaction of the fulcrum portion 503 and the external force F3. In other words, the first driving device 20C and the second driving device 20C 'swing up and down about the fulcrum portion 503 along the direction of the arrow shown by the action of the external force F3 . The output terminals of the two coils 30C and 30C 'are all connected to the circuit board 22C and the two coils 30C and 30C' may be connected in series or in parallel.

20 and 21 are explanatory diagrams of the operating principle of the fourth embodiment of the radio transmitter of the present invention. Arrows in the figure indicate that when the coil 30C on the left side moves downward, the coil 30C 'on the right side moves upward; When the coil 30C 'on the right side moves downward, the coil 30C on the left side moves upward.

20, at the beginning, one side of the seesaw plate is low and one side is high, that is, either one of the first driving device 20C or the second driving device 20C ' System 10C or the second magnetic system 10C 'to drive the first coil 30C to enter the first magnetic gap 14C formed in the first magnetic field system 10C, And the second coil 30C 'is driven to enter the second magnetic gap 14C' formed in the system 10C '. In the illustration of the operating principle of the present invention, the initial position is such that the first driving device 20C allows the first coil 30C to enter the first magnetic gap 14C formed in the first magnetic field system 10C It is a situation to drive.

When the downward external force F3 'is applied to the second projection 211C', the second driving device 20C 'of the second kinetic energy generation unit is driven by the external force F3' The second driving device 20C 'moves the second coil 30C' downward at a high speed to move the second magnetic gap (not shown) formed in the second magnetic-field system 10C ' 14C ', and is rapidly cut by a magnetic induction line densely distributed in the second magnetic gap 14C', thereby generating a second induced current.

21, at the same time, the first driving device 20C is moved in a direction opposite to the direction of the second driving device 20C 'by the joint action of the external force F3' and the fulcrum portion 503 The first driving unit 20C moves up and the first coil 30C is driven by the first driving unit 20C to move the first magnetic unit 20C formed in the first magnetic path 10C, The first magnetic gap 14C is separated from the gap 14C so that when the first coil 30C leaves the first magnetic gap 14C of the system 10C with the first magnetic element, Is cut by a densely distributed magnetic induction line, and thus a first induced current is generated.

At this time, in a state in which the first coil 30C is separated from the magnetic gap 14C, that is, in the state where the left side of the drawing is lifted, an external force F3 directed downward to the first projection 211C The first driving device 20C rapidly moves downward by the driving of the external force F3 and simultaneously moves the first coil 30C to the first magnetic body 10C of the first magnetic system 10C, So that the first coil 30C is cut at a high speed by the magnetic induction line densely distributed in the first magnetic gap 14C and the first induced current .

The second driving device 20C 'quickly moves upward due to the joint action of the external force F3 and the fulcrum portion 503 and the second coil 30C' The second induced current is generated again by being driven so as to be cut off at a high speed by a magnetic induction line which is separated from the second magnetic gap 14C 'in the first magnetic gap 14C' and is densely distributed in the second magnetic gap 14C ' .

As described above, every time one of the seesaw plates is pressed once, all of the electric energy is generated. Thereafter, when the opposite side of the seesaw plate is pressed again, one electric energy is further applied to the two coils Lt; / RTI > That is, every time the seesaw is pressed, the radio transmitter of the present invention can generate electric energy each time, and the first driving device 20C and the second driving device 20C ' So that the first induction current and the second induction current can be constantly generated. The circuit board 22C is electrically connected to the first coil 30C and the second coil 30C 'so that the first induced current and the second induced current are applied to the circuit board 22C And can be driven to perform a radio transmission operation. Correspondingly, a person skilled in the art can design the circuit module of the circuit board 22C to designate the induced current generated in the first and second coils 30C, 30C 'connected in series or in parallel, . ≪ / RTI >

Note that in the fourth embodiment of the present invention, the circuit board 22C is provided on the upper surface of the first driving device 20C, and the first coil 30C and the second coil 30C 'are all electrically connected to the circuit board 22C to provide a driving current to the circuit board 22C. The technician of the present invention may connect a different circuit board 22C to the first coil 30C and the second coil 30C 'in accordance with the actual situation so that the induction current generated by the first kinetic energy generator The induction current generated by the second kinetic energy generator may be separately output and the different circuit boards may be driven to perform the corresponding radio transmission operation. It is to be understood that within the scope of the present invention, the same or similar technical solution to the present invention may be employed to solve the same or similar technical problems as the present invention, But the present invention is not limited thereto.

In the fourth embodiment of the radio transmitter according to the present invention, the circuit board 22C is a high frequency wireless transmission circuit board, and the circuit board element 221C and the frequency module (RF frequency module) The same applies hereinafter) are electrically connected. That is, the first coil 30C and the second coil 30C 'of the kinetic energy generator are electrically connected to the high frequency wireless transmission circuit board, respectively. The first coil 30C and the second coil 30C 'of the kinetic energy generator are connected to a magnetic induction line densely distributed in the first magnetic gap 14C and the second magnetic gap 14C' The induction current controls the operation of the electronic device by driving the high frequency wireless transmission circuit board including the circuit board element 221C and the RF frequency module to radiate radio frequency radio waves .

In another embodiment, the two coils 30C, 30C 'are fixed and by moving the two system 10C, 10C' through a seesaw plate, the two coils 30C, It will be understood that an induction current may be generated in the first coil 30C '.

Also, in the embodiment of the present invention, both ends of the seesaw plate are made of a porcelain material, or a ceramic body such as an iron plate is separately added. In the process of moving the coils 30C and 30C ' Each of the systems 10C and 10C 'has a magnetic attracting force at both ends of the seesaw plate so as to maintain balance and accelerate downward movement of both ends of the seesaw plate.

Correspondingly, in the above embodiment of the present invention, there is provided a kinetic energy generating method for application to powering a small electronic device, which is applied to a wireless switch as a typical example to form a wireless self-generating switch,

In the initial state, the first coil 30C located at one side of the seesaw plate is inserted into the first magnetic gap 14C of the first magnetic induction system 10C, and the first coil 30C located at the opposite side of the seesaw plate The second coil 30C 'being located outside the second magnetic gap 14C' of the system 10C ';

When the other side of the seesaw plate is pressed, the second coil 30C 'is inserted into the second magnetic gap 14C' of the second magnetic induction system 10C ' The coil 30C is separated from the first magnetic gap 14C of the system 10C so that the first and second coils 30C and 30C ' step; And

When one side of the seesaw is joined, the first coil (30C) is inserted again into the first magnetic gap (14C) of the first magnetic induction system (10C), and the second coil The first and second coils 30C and 30C 'are separated from the second magnetic gap 14C' of the system 10C 'by the second magnetic field so that the first and second coils 30C and 30C' .

In addition, in the fourth embodiment of the radio transmitter according to the present invention, the induced electromotive force is different between the first coil 30C and the winding of the second coil 30C ', the first magnetic gap 14C, 2 magnetic field strength of the magnetic gap 14C ', and the pressing speed on both the left and right sides of the seesaw plate, and their calculation formulas are as follows.

E = -n * ?? /? T

Where:

E: Induced electromotive force

n: coil winding

ΔΦ / Δt: rate of change of magnetic flux

The person skilled in the art can modify the concrete embodiment of the radio transmitter according to the present invention as necessary and has a mechanism capable of driving the coil to reciprocate the coil in the magnetic gap Or a mechanism for generating a current by cutting the coil through a magnetic induction line in the magnetic gap, all belong to the protection scope of the present invention, and the specific embodiment of the present invention is not limited thereto.

As an application of the kinetic energy generating device of the present invention, a person skilled in the art can apply the kinetic energy generating device to different cases depending on the actual situation. For example, the kinetic energy generating device may be applied to a power- When the switch plate is pressed, the movement of the switch plate drives the kinetic energy generating device to convert the mechanical energy into electrical energy, thereby driving the controller to perform the operation, The device can be controlled.

In addition, the technician of the present invention may also develop the application of the kinetic energy generator according to actual needs. For example, when the user presses the button of the remote controller, such as the application of the kinetic energy generator and the remote controller, The pressing operation can operate the remote control by driving the kinetic energy generating device to convert mechanical energy into electrical energy. It is to be understood that the present invention is not limited to the above-described embodiments, provided that the same or similar technical solutions as those of the kinetic energy generation device of the present invention are adopted, It does not.

According to this preferred embodiment described above, it will be understood that the present invention further includes a kinetic energy generating method,

And causing the coil to reciprocate in the annular magnetic gap such that cutting of the magnetic induction line causes the coil to generate an induced current for power generation.

Preferably, in the step, the coil can reciprocate in the magnetic gap through a combination of a magnetic attractive force and an external force.

[0302] Optionally, in the step, the coil reciprocates in the magnetic gap through the combination of an elastic force and an external force.

The speed of motion of the coil in the magnetic gap may be determined according to the magnitude of the demanded amount of electric energy of the user, and the concrete implementation method of the kinetic energy generating method of the present invention is not limited thereto. Or similar technical solution to solve the same or similar technical problems as the present invention and to obtain the same or similar technical effect as the present invention are all within the scope of the present invention.

Preferably, in a first embodiment of the kinetic energy generating method of the present invention, the coil reciprocates in the magnetic gap through a drive device. The drive device may generate electric current by driving the coil to reciprocate in the magnetic gap through an arbitrary method, for example, a manual drive, a mechanical external drive, or the like. And may determine how the drive drives the coil according to actual circumstances. The method of generating the kinetic energy of the present invention is not limited to this embodiment, and if the same or similar technical effect as that of the present invention can be obtained by employing the same or similar technology, .

As a further disclosed embodiment of the present invention, the driving device may drive the coil to reciprocate in the magnetic gap through a method such as up-down motion or circumferential motion, for example, an elastic plate drive, a seesaw- The coil can be driven to reciprocate in the magnetic gap.

Specifically, in the method of reciprocating the coil through the elastic plate in the magnetic gap, the coil is fixed to the elastic plate, and then the coil is reciprocated in the magnetic gap using the elastic force of the elastic plate It implements the purpose of generating electricity.

Wherein the seesaw moves in both directions under the action of the fulcrum through a method of providing a support point at an intermediate portion of the seesaw plate in a method of reciprocating the coil through the seesaw plate through the seesaw plate, When the seesaw plate is fixed together with the seesaw plate, when the seesaw plate is moved up and down under the action of external force, the coil also achieves the object of generating electricity by reciprocating in the magnetic gap by the operation of the seesaw plate.

It should be noted that as long as external force acts on either side of the seesaw plate due to the specificity of the seesaw plate, both sides of the seesaw plate perform corresponding movements, only the opposite direction of motion. Therefore, when the coil is moved in the magnetic gap by using a seesaw plate, the coil and the magnetic gap can be provided on both sides of the seesaw plate, and the reciprocating motion of the seesaw plate causes currents . In other words, in the power generation method in which the coil is caused to reciprocate in the magnetic gap by using the seesaw plate to generate an induction current, the seesaw plate generates an induction current twice as much as the power generation efficiency of the kinetic energy generation method Can be improved.

Wherein the cam is provided with a pair of upper cams and lower cams which mesh with each other, and the cams are provided with successive protrusions respectively in the upper cam and the lower cam And the upper cam and the lower cam are engaged through the protrusion, and the upper cam and the lower cam are relatively rotatable along the protrusion. The coil and the magnetic gap are fixed to the upper cam and the lower cam respectively so that the coil is moved up and down along the circumferential rotation of the protrusion along the relative circumferential movement between the upper cam and the lower cam And realizes the purpose of generating electricity by implementing the reciprocating motion of the coil in the magnetic gap.

It will be appreciated by those skilled in the art that other driving methods may be employed depending on the needs of the customer or the actual situation, and that the method can reciprocate the coil in the magnetic gap, and that the method has the same or similar technical effect It is within the protection range of the kinetic energy generating method of the present invention, and the concrete embodiment of the kinetic energy generating method of the present invention is not limited thereto.

In addition, in the kinetic energy generating method of the present invention, the magnetic gap is obtained through a method of installing a magnetic path system, and the magnetic gap is a circular shape. As a modification of the kinetic energy generating method of the present invention, a person skilled in the art can set the magnetic gap through other methods, and the shape and parameters of the magnetic gap can also be determined according to actual needs. Or similar technical measures are adopted to implement the same or similar technical effect as the present invention, all fall within the scope of the kinetic energy generating method of the present invention.

Note that, in the kinetic energy generating method of the present invention, the method in which the coil reciprocates in the magnetic gap includes not only the method in which the coil is not moved but the magnetic gap is set to move, , The magnetic gap also includes a non-moving method, and it is only necessary for the coil to generate an induced current by making a relative reciprocating motion in the magnetic gap. It will be apparent to those skilled in the art that the relative position of the coil and the magnetic gap It is within the scope of protection of the kinetic energy generating method of the present invention that the same or similar technical effect as that of the present invention can be adopted to implement the same or similar technical effect as the present invention, But the present invention is not limited thereto.

The present invention further relates to a method of manufacturing a kinetic energy generating device,

Providing a self-contained system having an annular magnetic gap;

And installing a coil that can be driven to reciprocate in the magnetic gap.

Further, as a kind of improvement of the present invention, the method of manufacturing the kinetic energy generating device of the present invention

And installing a driving device for driving the coil to reciprocate in the magnetic gap.

Preferably, in the method of manufacturing the kinetic energy generating device of the present invention, the driving device is installed to reciprocate the coil in the magnetic gap through up-and-down movement.

Further, in the method of manufacturing the kinetic energy generating device of the present invention, the driving device is provided with an elastic plate, and the coil is driven to reciprocate in the magnetic gap through the elastic plate. Specifically, in the method for manufacturing a kinetic energy generating device of the present invention, since the coil is fixedly connected to the elastic plate, the coil can move up and down according to the elastic force of the elastic plate, The induced current can be generated.

Alternatively, in the method of manufacturing the kinetic energy generating device of the present invention, a seesaw plate is installed in the drive device, and the coil is driven to reciprocate in the magnetic gap through the seesaw plate. Specifically, a support point portion is provided at an intermediate portion of the seesaw plate, and both side portions of the seesaw plate can be moved up and down under the action of external force through the fulcrum portion. Since the coil is fixed together with the seesaw plate, Can induce an induced current by reciprocating the magnetic gap along the up and down movements of both ends of the seesaw plate.

Note that both ends of the seesaw plate are bi-directionally moved at the same time under the action of the fulcrum portion, so that only the direction of motion of both ends of the seesaw plate is opposite. In other words, when the external force acts once, both ends of the seesaw plate simultaneously move in opposite directions. The artisan of this field is provided with the coil and the magnetic gap at both ends of the seesaw plate, So that when the external force acts on the seesaw plate once, the coils at both ends of the seesaw plate can simultaneously move in the magnetic gap. When the same external force is repeatedly applied, the coils at both ends of the seesaw plate can reciprocate in the magnetic gap, respectively, thereby realizing induction current generation. In other words, in the method of manufacturing the kinetic energy generating device of the present invention, the seesaw plate is installed as a driving device and the coil is driven to reciprocate in the magnetic gap. In this case, under the assumption that the same acting force and other conditions are the same , Twice the induced current can be generated, and the power generation efficiency of the kinetic energy generation device can be improved.

Optionally, the drive may drive the coil to reciprocate in the magnetic gap through a rotational motion.

In the method of manufacturing a kinetic energy generating device of the present invention, a cam is provided in the driving device, and the coil is driven to reciprocate in the magnetic gap through a circumferential movement of the cam. Specifically, the cams are each provided with a pair of upper cams and lower cams to be meshed with each other, and protrusions successive to the upper cam and the lower cam are provided, respectively, and through the engagement of the protrusions, Cam engagement, and the upper cam and the lower cam can perform relative circumferential movement along the protrusion. When the upper cam and the lower cam perform a relative circumferential movement along the protrusion, the upper cam and the lower cam also move up and down relative to each other due to the shape of the protrusion.

In a first embodiment of the method for manufacturing the kinetic energy generation device of the present invention, the coil is installed to be fixedly connected to the upper cam, and the magnetic gap is installed to be fixedly connected to the lower cam. Accordingly, when the upper cam and the lower cam perform a circumferential movement along the protrusion, the coil also moves upward and downward along the protruding tooth shape together with the upper cam to thereby realize a reciprocating motion in the magnetic gap, .

It should be noted that in the method of manufacturing the kinetic energy generating device of the present invention, it is sufficient that the coil and the magnetic gap are provided, and the coil can reciprocate in the magnetic gap. The relative movement relationship between the coil and the magnetic gap, for example the magnetic gap, does not move and the coil is reciprocated in the magnetic gap according to a request or actual situation, or the coil is not moved The magnetic gap can be installed in such a manner that the magnetic gap reciprocates relative to the coil and if the same or similar technical effect as the present invention is adopted to achieve the same or similar technical effect as the present invention, But the present invention is not limited thereto.

In the method of manufacturing the kinetic energy generating device of the present invention, the magnetic gap is formed through the following steps.

Providing a hollow columnar lower magnetic induction plate having a U-shaped longitudinal section;

Providing a circular magnet and an upper circular magnetic induction plate having an inner diameter smaller than the outer diameter of the lower magnetic induction plate;

Providing the magnet and the upper magnetic induction plate in the lower magnetic induction plate to form the magnetic gap in which the magnetic induction line is densely distributed.

In addition, a person skilled in the art can install the magnetic gap using other methods according to the actual situation, and the method of manufacturing the kinetic energy generating device of the present invention is not limited to this. Accordingly, the kinetic energy generating device and the radio transmitter of the present invention are simple in structure, low in cost, safe and reliable in their power generation process, and capable of realizing power generation requirements and environmentally friendly demands without polluting the environment have. The kinetic energy generating method of the present invention is extremely advantageous for realizing the current demand of a general electronic device because the operation process is simple and convenient. The radio transmitter of the present invention is simple in structure, reliable in performance, and inexpensive.

It will be appreciated by those skilled in the art that the embodiments of the invention illustrated in the above description and accompanying drawings are illustrative only and are not restrictive of the present invention. The object of the present invention has already been fully and effectively implemented. It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

Claims (31)

In a kinetic energy generator,
At least one coil;
At least one magnet system with an annular magnetic gap; And
Generating at least one drive, wherein under the action of the drive, the coil generates a displacement relative to the magnetic gap such that the coil is cut by the magnetic induction wire of the magnet system, Wherein the kinetic energy generating device comprises: The method according to claim 1,
Wherein the driving device drives the magnet system to cause the magnetic gap and the coil of the magnet system to generate repeated relative displacements so that the coils generate the induced current. . The method according to claim 1,
Characterized in that the drive comprises a driver for driving the coil to cause the coils to generate the induced current by causing repeated relative displacement in the magnetic gap of the coil and the magnetic path system, Generator. The method of claim 3,
Wherein the magnet system comprises a lower magnetic induction plate whose longitudinal section is U-shaped, a permanent magnet body and an upper magnetic induction plate, wherein the permanent magnet body and the upper magnetic induction plate are installed in the lower magnetic induction plate, Thereby forming a magnetic gap. 5. The method of claim 4,
Characterized in that the actuator comprises a ceramic body and the coil is fixed to the ceramic body and the ceramic body is automatically returned through the magnetic attraction force with the magnet system to thereby automatically return the coil Energy generation device. 5. The method of claim 4,
Wherein the actuator comprises an elastic plate, wherein the coil is fixed to the elastic plate, and the elastic plate is capable of automatically returning the coil by automatically returning through its elastic recovery performance Energy generation device. The method according to claim 6,
Wherein the lower magnetic induction plate and the elastic plate fixing sheet are fixed to the base sheet, one end of the elastic plate is connected to the coil, and the other end Is fixed to the elastic plate fixing sheet. 5. The method of claim 4,
The driver includes an upper cam and a lower cam that can be engaged and disengaged through protrusions, wherein the lower cam is fixed to the magnet system, and the upper cam is movable in a circumferential direction Wherein the coil can be driven to reciprocate in the magnetic gap by performing rotational motion of the coil. 9. The method of claim 8,
Wherein the driver further comprises a ceramic body, wherein the ceramic body is capable of automatically returning the upper cam and the lower cam from the separated state to the engaged state through the magnetic attraction force with the magnet system Kinetic energy generator. The method according to claim 1,
Wherein said kinetic energy generating device includes two kinetic energy generating units including two said coils and two said magnet system, wherein said driving device includes a seesaw plate and a fulcrum for supporting said seesaw plate, Wherein two coils are fixed at both ends of the seesaw plate and two coils are located on both sides of the fulcrum portion and one of the coils is inserted into the magnetic gap of the corresponding one of the coils, And the other one of the coils is separated from the magnetic gap of the corresponding one of the magnetic poles so that the two coils are cut by the magnetic induction lines of the two corresponding magnetic poles to generate the induced current A kinetic energy generating device characterized by. 11. The method of claim 10,
Wherein each of the magnet system includes a lower magnetic induction plate whose longitudinal section is U-shaped, a permanent magnet body, and an upper magnetic induction plate, wherein the permanent magnet body and the upper magnetic induction plate are installed in the lower magnetic induction plate, Wherein the magnetic gap of the magnetic field generating member is formed in the magnetic gap. 12. The method of claim 11,
Wherein the two coils are connected in series or in parallel, and both ends of the seesaw plate are disposed so as to be capable of being adsorbed and coupled with two corresponding magnet systems through magnetic forces. 13. The method according to any one of claims 1 to 12,
Further comprising a circuit board, wherein the coil is electrically connected to the circuit board, and the induced current generated in the coil is supplied to the circuit board. 6. The method of claim 5,
Wherein the coil is electrically connected to the circuit board, and the induced current generated in the coil is supplied to the circuit board, wherein the circuit board is fixed on the upper side of the ceramic body, Wherein the coil is fixed to the bottom side of the ceramic body. 8. The method according to claim 6 or 7,
Wherein the coil is electrically connected to the circuit board, and the induced current generated in the coil is supplied to the circuit board, wherein the circuit board is fixed to the upper side of the elastic plate, And the coil is fixed to a bottom side of the elastic plate. 10. The method of claim 9,
Wherein the coil is electrically connected to the circuit board so that the induced current generated in the coil is supplied to the circuit board and the coil is fixed to the bottom side of the circuit board, Wherein the circuit board is interconnected with the cam such that the cam drives the circuit board and further drives the coil in motion. The method according to claim 6,
Wherein the ceramic body is provided on the upper side and the bottom side of the circuit board or is molded integrally with the circuit board. 13. The method according to any one of claims 10 to 12,
Wherein the coil is electrically connected to the circuit board so that the induced current generated in the coil is supplied to the circuit board and the circuit board is fixed to the upper side of the seesaw board A kinetic energy generator. 13. The method according to any one of claims 1 to 12,
Wherein a width of the magnetic gap is between 0.5 mm and 10 mm, a turn of the coil is between 50-800 wheels, and a diameter of the coil is between 0.06 mm and 0.5 mm. In a wireless transmitter,
The radio transmitter includes the kinetic energy generating device according to any one of claims 1 to 19 and a high frequency wireless transmission circuit board, wherein the high frequency wireless transmission circuit board includes a frequency module, Wherein the substrate is electrically connected to the coil in the kinetic energy generation device. In kinetic energy generation methods,
A displacement relative to the annular magnetic gap of the coil and the magnet system is generated under the action of the driving device to cause the coil to be cut by the magnetic induction wire of the magnet system to thereby generate an induced current, Wherein the step of generating the kinetic energy comprises: 22. The method of claim 21,
The kinetic energy generation method also includes
Further comprising the step of causing the drive to reciprocate the coil relative to the magnetic gap such that the coil is cut by the magnetic induction wire of the magnet system to generate the induced current. Way. 23. The method of claim 22,
Driving the ceramic body to move the coil away from the magnetic gap in response to an external force acting on the ceramic body of the driving device; And
In response to sudden disappearance of the external force, magnetic attraction of the ceramics and the magnet system to automatically return the ceramics to drive the coils to enter the magnetic gap Development method. 23. The method of claim 22,
In response to an external force acting on the elastic plate of the driving device, driving the elastic plate to disengage the coil from the magnetic gap and accumulating elastic potential energy; And
And in response to the sudden loss of the external force, resilient recovery performance of the elastic plate drives the coil to enter the magnetic gap by automatically returning the elastic plate. 23. The method of claim 22,
Responsive to an external force acting on the elastic plate of the drive, actuating the elastic plate to cause the coil to enter the magnetic gap and accumulating elastic potential energy; And
And in response to the sudden loss of the external force, resilient recovery performance of the elastic plate causes the coil to move away from the magnetic gap by automatically returning the elastic plate. 23. The method of claim 22,
In response to an external force acting on the upper cam of the drive, the upper cam and the lower cam are separated and the coil is disengaged from the magnetic gap due to movement of the upper cam; And
And when the upper cam continues to rotate, the upper cam and the lower cam are engaged again so that the coil enters the magnetic gap. 27. The method of claim 26,
When the upper cam continues to rotate, bringing the upper cam and the lower cam back into engagement with the magnetic gap, under the action of the magnetic attractive force of the ceramic body and the magnetic path system, thereby bringing the coil into the magnetic gap Kinetic energy generation method. 28. The method of claim 27,
Wherein the upper cam is connected to a circuit board, the lower cam is fixed to a lower magnetic induction plate of the magnet system, and the ceramics body is installed on the circuit board. 22. The method of claim 21,
In response to the first end of the seesaw supported by the fulcrum of the drive device being pressed, the first coil enters the corresponding first magnetic gap and the second coil leaves the corresponding second magnetic gap step; And
In response to the second end opposite to the seesaw plate being pressed, the second coil enters the corresponding second magnetic gap, and at the same time, the first coil departs from the corresponding first magnetic gap Wherein the kinetic energy generating step comprises: 30. The method of claim 29,
Wherein the corresponding end of the seesaw plate is disposed to be adsorbed and coupled to the corresponding magnet system through a magnetic attraction force corresponding to the coil entering the magnetic gap. 31. The method according to any one of claims 21 to 30,
The magnetic gap
Providing a columnar lower magnetic induction plate having a U-shaped longitudinal section;
Providing a permanent magnet body and an upper magnetic induction plate having an outer diameter smaller than an inner diameter of the lower magnetic induction plate; And
And forming the magnetic gap by sequentially providing the permanent magnet body and the upper magnetic induction plate in the lower magnetic induction plate.

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