CN111817527A - Toggle type power generation device and method and electronic equipment - Google Patents

Abstract

A toggle type power generation device, a method thereof and an electronic apparatus. This toggle type power generation facility includes: the self-generating body comprises a coil and a magnetic circuit system for generating magnetic induction lines; and a toggle mechanism, wherein the toggle mechanism is drivably connected to the self-generating main body, wherein the toggle mechanism is adapted to be toggled to drive the self-generating main body, so that magnetic flux formed in the coil by the magnetic induction lines generated by the magnetic circuit system is changed to generate electromotive force, thereby converting mechanical energy generated by toggling into electric energy, contributing to reducing the volume and improving the power generation efficiency.

Description

Toggle type power generation device and method and electronic equipment

Technical Field

The invention relates to the technical field of power generation, in particular to a toggle type power generation device, a method thereof and electronic equipment.

Background

With the advent of high technology, the electronics industry has experienced a very significant growth, and wireless controllers are very commonly used in different electronic control devices. For example, for a common household or office appliance to be equipped with a wireless controller, the conventional wireless controller must be driven using a battery as a power source. Therefore, after the life cycle of the battery is over, the user must frequently replace the old battery with a new one.

At present, the small-sized low-power electronic product is generated by using the acting force of hands or external tiny mechanical pressure, and a series of problems of short service life, repeated cost, unreliability, environmental pollution and the like caused by battery power supply can be well solved. Under the circumstance of increasingly severe environmental pollution, it is important to reduce the mass production of industrial wastes. The common mechanical kinetic energy power generation device has larger volume, stronger noise and relatively low power generation efficiency. Although small-sized and low-power-consumption electronic products do not have high requirements for devices for supplying power, conventional mechanical kinetic energy power generation devices are large in size and low in power generation efficiency. In particular, when the existing mechanical kinetic energy power generation device is used to supply power to a wall switch for controlling electrical equipment such as a luminaire, the existing mechanical kinetic energy power generation device has a large volume, so that a user has to reserve a large enough space on a wall to install the wall switch, and the surface appearance of the wall is damaged.

Disclosure of Invention

An advantage of the present invention is to provide a toggle power generation apparatus, a method thereof, and an electronic device, which can convert mechanical energy of a toggle into electric energy, thereby contributing to a reduction in size and an improvement in power generation efficiency.

Another advantage of the present invention is to provide a toggle power generating device, a method thereof and an electronic apparatus, wherein in an embodiment of the present invention, the toggle power generating device is capable of driving a coil or a magnetic circuit system through a toggle mechanism, such that a magnetic flux in the coil is changed to convert a mechanical energy of the toggle into an induced electrical energy.

Another advantage of the present invention is to provide a toggle power generating apparatus, a method thereof and an electronic device, wherein in an embodiment of the present invention, the toggle power generating apparatus can be hidden on a large area of a surface of an object such as a wall surface, and only a toggle end of a toggle element is exposed, so as to prevent the surface of the object such as the wall surface from being damaged in a large area, and effectively protect the beauty of the surface of the object such as the wall surface.

Another advantage of the present invention is to provide a toggle power generating apparatus, a method thereof and an electronic device, wherein, in an embodiment of the present invention, a toggle direction of a toggle element of the toggle power generating apparatus can be substantially perpendicular to a swing direction of a magnetic conductor in the magnetic circuit system, so as to substantially reduce a lateral dimension of the toggle power generating apparatus while ensuring labor saving.

Another advantage of the present invention is to provide a toggle power generating apparatus, a method thereof and an electronic device, wherein in an embodiment of the present invention, a toggle element of the toggle power generating apparatus can store a driving force provided by the toggle element by a power storage element, which helps to increase a power generated by the toggle power generating apparatus.

Another advantage of the present invention is to provide a toggle power generating apparatus, a method thereof and an electronic device, wherein in an embodiment of the present invention, the toggle mechanism of the toggle power generating apparatus can be automatically reset, so that the coil can cut the magnetic induction lines generated by the magnetic circuit system twice when the toggle mechanism is manually toggled once, which helps to improve the power generating efficiency.

Another advantage of the present invention is to provide a toggle type power generating apparatus, a method thereof, and an electronic device, wherein it is not necessary to use expensive materials or complicated structures in order to achieve the above advantages. Therefore, the present invention successfully and effectively provides a solution to not only provide a simple toggle type power generating apparatus and method thereof, and an electronic device, but also increase the practicality and reliability of the toggle type power generating apparatus and method thereof, and the electronic device.

To achieve the above and other advantages and in accordance with the purpose of the present invention, a toggle type power generating apparatus includes:

the self-generating body comprises a coil and a magnetic circuit system for generating magnetic induction lines; and

and the toggle mechanism is connected to the self-generating main body in a driving way, and is suitable for being toggled to drive the self-generating main body, so that magnetic flux formed in the coil through the magnetic induction lines generated by the magnetic circuit system is changed to generate electromotive force, and mechanical energy generated by toggling is converted into electric energy.

In one embodiment, the toggle mechanism includes a toggle element, wherein the toggle element has a toggle end and an actuating end, and the toggle end of the toggle element extends outwardly from the actuating end of the toggle element, wherein the actuating end of the toggle element is drivingly connected to the magnetic circuit for actuating the magnetic circuit to change the direction of the magnetic flux induced by the magnetic circuit such that the direction of the magnetic flux induced through the coil changes.

In one embodiment, the toggle mechanism further comprises a power accumulating element, wherein the power accumulating element is arranged between the driving end of the toggle element and the magnetic circuit system, and is used for accumulating the driving force provided by the driving end of the toggle element to serve as an accumulated force, and the magnetic circuit system is driven quickly under the action of the accumulated force when the accumulated force reaches a preset accumulated force threshold value.

In one embodiment, the power accumulating element is a power accumulating spring, wherein one end of the power accumulating spring is connected to the magnetic circuit system, and the other end of the power accumulating spring is connected to the driving end of the shift lever element.

In one embodiment, said driving end portion of said lever element is provided with an engagement groove, wherein said one end of said power accumulating spring is fixedly connected to said magnetic circuit system, and said other end of said power accumulating spring protrudes into said engagement groove of said driving end portion of said lever element to be detachably connected with said driving end portion of said lever element.

In one embodiment, the toggle end of the toggle element extends outward to extend out of a plane of a bottom surface of the magnetic circuit system, and the predetermined toggle angle of the toggle end of the toggle element is within 90 °.

In one embodiment, the toggle end of the toggle element is perpendicular to the bottom surface of the magnetic circuit system.

In one embodiment, the toggle mechanism comprises a toggle element, wherein the toggle element has a toggle end and two driving ends, wherein the two driving ends of the toggle element oppositely extend from the toggle end of the toggle element, and the two driving ends of the toggle element are respectively connected to the two magnetic circuits in a driving manner, so as to synchronously drive the two magnetic circuits to change the direction of the magnetic induction lines generated by the magnetic circuits, and thus the direction of the magnetic induction lines passing through the coil is changed.

In one embodiment, the magnetic circuit system comprises a magnetic cavity and a permanent magnet, wherein the magnetic cavity comprises a top magnetizer, a bottom magnetizer and a middle magnetizer, and the permanent magnet is jointly disposed between the top magnetizer and the bottom magnetizer, wherein the coil surrounds the middle magnetizer, and the toggle mechanism is drivingly connected to the middle magnetizer through the power accumulating element for driving the middle magnetizer to move so that the end of the middle magnetizer alternately contacts the top magnetizer and the bottom magnetizer.

In one embodiment, the lever element further has a rotation fulcrum portion, wherein the rotation fulcrum portion is located adjacent to the driving end portion of the lever element, and when the toggle end portion of the lever element is toggled, the toggle end portion and the driving end portion of the lever element both rotate with the rotation fulcrum portion in between.

In one embodiment, the driving end of the shifter element integrally extends laterally from the rotation fulcrum portion of the shifter element, and the shifting end of the shifter element integrally extends longitudinally from the driving end of the shifter element to form the shifter element having an L-shaped configuration.

In one embodiment, a ratio between a toggle moment arm provided by the toggle end of the toggle element and a drive force arm provided by the drive end of the toggle element is greater than 2: 1.

According to another aspect of the present invention, there is provided an electronic device comprising:

at least one toggle power generation device, wherein the toggle power generation device comprises:

the self-generating body comprises a coil and a magnetic circuit system for generating magnetic induction lines; and

a toggle mechanism, wherein the toggle mechanism is drivably connected to the self-generating body, wherein the toggle mechanism is adapted to be toggled to drive the self-generating body so that a magnetic flux formed in the coil via a magnetic induction line generated by the magnetic circuit system is changed to generate an electromotive force, thereby converting mechanical energy generated by toggling into electric energy; and

and the signal generator is electrically connected with the toggle type power generation device in a working mode and is used for generating and transmitting a wireless signal when the toggle type power generation device provides electric energy so as to control other electronic equipment to carry out preset operation.

According to another aspect of the present invention, there is provided a method of manufacturing a flip-type power generator, comprising the steps of:

correspondingly arranging at least one coil and at least one magnetic circuit system; and

the coil or the magnetic circuit system can be arranged with a toggle mechanism in a toggle manner, wherein when the toggle mechanism is toggled, the toggle mechanism drives the coil or the magnetic circuit system to change the magnetic flux in the coil to generate electromotive force, thereby converting the mechanical energy generated by the toggle into electric energy.

According to another aspect of the present invention, there is provided a method for generating electricity from a pull-type electricity generating apparatus, comprising the steps of:

a toggle mechanism is toggled to enable the toggle mechanism to rotate; and

the poking mechanism drives at least one self-generating main body, wherein the self-generating main body comprises a coil and a magnetic circuit system, so that magnetic flux formed in the coil by magnetic induction lines generated by the magnetic circuit system is changed to generate electromotive force, and mechanical energy generated by poking is converted into electric energy.

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

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

Drawings

Fig. 1 is a perspective view of a toggle type power generation apparatus according to an embodiment of the present invention.

Fig. 2 is a schematic view illustrating an application of the toggle type power generation device according to the above embodiment of the present invention.

Fig. 3 shows an exploded view of the toggle power generation apparatus according to the above embodiment of the present invention.

Fig. 4 is a schematic partial structural view of the toggle type power generation device according to the above embodiment of the present invention.

Fig. 5 shows a schematic cross-sectional view of the toggle type power generation device according to the above embodiment of the present invention.

Fig. 6A and 6B are schematic diagrams illustrating a toggle state of the toggle type power generation device according to the above embodiment of the present invention.

Fig. 7A and 7B show a first modified embodiment of the toggle power generation device according to the above embodiment of the present invention.

Fig. 8A and 8B show a second modified embodiment of the toggle power generation device according to the above embodiment of the present invention.

Fig. 9A and 9B show a third modified embodiment of the toggle power generation device according to the above embodiment of the present invention.

Fig. 10A and 10B show a fourth modified embodiment of the toggle power generation device according to the above embodiment of the present invention.

FIG. 11 is a cross-sectional schematic view of an electronic device according to an embodiment of the invention.

Fig. 12 is a flow chart illustrating a method for manufacturing a toggle type generator according to an embodiment of the present invention.

Fig. 13 is a flow chart illustrating a self-generating method of the toggle power generator according to an embodiment of the invention.

Detailed Description

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

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be constructed and operated in a particular orientation and thus are not to be considered limiting.

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

The toggle type power generation device can comprise at least one coil, at least one magnetic circuit system and a toggle mechanism, wherein the magnetic circuit system is used for generating magnetic induction lines, and the toggle mechanism is suitable for being toggled to drive the coil or the magnetic circuit system, so that magnetic flux in the coil is changed to generate electromotive force, mechanical energy generated by toggling is converted into electric energy, and the effect of power generation is achieved.

As shown in fig. 1 to 5, a dial type power generating apparatus 1 according to an embodiment of the present invention is illustrated, wherein the dial type power generating apparatus 1 includes at least a self-generating body and a dial mechanism 30, wherein the self-generating body includes a coil 10 for generating an electromotive force and a magnetic circuit system 20 for generating magnetic induction lines, wherein the dial mechanism 30 is drivably connected to the self-generating body for driving the self-generating body so that a magnetic flux formed in the coil by the magnetic induction lines generated by the magnetic circuit system 20 is changed to generate an electromotive force, thereby converting mechanical energy generated by the dial into electric energy.

Specifically, in this embodiment of the present invention, the toggle mechanism 30 is drivably connected to the magnetic circuit system 20, and the magnetic circuit system 20 is used to generate magnetic induction lines, wherein when the toggle mechanism 30 is toggled, the magnetic circuit system 20 is driven by the toggle mechanism 30 to change the direction of the magnetic induction lines generated through the magnetic circuit system 20, so that the direction of the magnetic induction lines passing through the coil 10 is changed, and further the magnetic flux in the coil 10 is changed to generate induced electromotive force, thereby the toggle type power generation apparatus 1 achieves the effect of generating power.

It is noted that, since the toggle mechanism 30 is toggled to drive the magnetic circuit system 20 to change the direction of the generated magnetic induction line, so that the magnetic flux in the coil 10 changes, the coil 10 will generate an induced electromotive force. At this time, if the coil 10 forms a closed loop with a load such as a signal generator, an induced current will be generated in the closed loop formed by the coil 10 and the load, so that the toggle type power generation device 1 converts the mechanical energy of the toggle into electric energy, and then provides working electric energy for the corresponding load. Of course, in other examples of the present invention, the self-generating body may also be implemented as a piezoelectric power generating device.

In particular, the self-generating wireless switch requires a large driving force because it needs to drive a power generation device to generate electric power. Compared with the key-type self-generating wireless switch in the prior art, the toggle type power generation device 1 has the remarkable advantages that: firstly, the driving force required by the toggle mechanism 30 is smaller than that required by a key type, so that the toggle type power generation device 1 of the invention has a much lighter hand feeling in operation; meanwhile, compared with a key-type operation mode, the mechanical vibration area is obviously reduced due to the design of the shifting rod type, so that the shifting rod type power generation device 1 is quieter during power generation operation, and the problem of high noise during operation of a self-generating wireless switch in the prior art is solved; secondly, the design of the toggle type power generation device 1 belongs to a retro style, and the toggle type power generation device can be widely applied to star hotels and high-end places, so that the strong artistic interest and different operation experiences are brought to users; finally, the volume of the toggle type power generation device 1 can be very small and thin, so that a plurality of independent toggle type self-power generation wireless switches can be arranged on one panel, and multi-channel control is facilitated. In addition, in the invention, the toggle type power generation device 1 can intuitively perform adjustment operation of terminals such as lamps, for example, when the toggle lever is toggled upwards, the lamps are turned on; when the shifting lever is shifted downwards, the lamp is dimmed, so that the lamp is more visual and concise in operation.

More specifically, as shown in fig. 3 and fig. 5, the magnetic circuit system 20 of the toggle generator 1 may include a magnetic cavity 21 and a permanent magnet 22, wherein the magnetic cavity 21 may include a top magnetizer 211, a bottom magnetizer 212 and a middle magnetizer 213, and the permanent magnet 22 is jointly disposed between the top magnetizer 211 and the bottom magnetizer 212 to form a magnetic cavity 210 between the top magnetizer 211 and the bottom magnetizer 212. The coil 10 surrounds the middle magnetizer 213, and both the coil 10 and the middle magnetizer 213 are disposed in the magnetic conductive cavity 210. The end of the middle magnetizer 213 extends out of the magnetism guiding cavity 210, and the toggle mechanism 30 is connected to the middle magnetizer 213 in a driving manner, and is used for driving the middle magnetizer 213 to move so that the end of the middle magnetizer 213 contacts the top magnetizer 211 and the bottom magnetizer 212 alternately, so that the direction of the magnetic induction line passing through the coil 10 is changed to change the magnetic flux in the coil 10, thereby generating the induced electromotive force. It is understood that the permanent magnet 22 of the present invention may be made of permanent magnet materials, such as magnets, alnico permanent magnet alloys, ferrochrome permanent magnet alloys, permanent magnetic ferrites, rare earth permanent magnet materials, composite permanent magnet materials, etc.; the magnetic cavity 21 may be made of magnetic material or material containing magnetic material, such as iron, carbon steel, iron-silicon alloy, iron-aluminum alloy, iron-silicon-aluminum alloy, nickel-iron alloy, iron-cobalt alloy, etc.

Illustratively, as shown in fig. 6A and 6B, the N pole of the permanent magnet 22 contacts the top magnetic conductor 211 to make the top magnetic conductor 211 the N pole; the S-pole of the permanent magnet 22 contacts the bottom magnetizer 212 to make the bottom magnetizer 212 an S-pole. Thus, when the toggle mechanism 30 is toggled to drive the first end 2131 of the middle magnetizer 213 to contact the top magnetizer 211 and the second end 2132 of the middle magnetizer 213 to contact the bottom magnetizer 212, the first end 2131 and the second end 2132 of the middle magnetizer 213 are respectively N-pole and S-pole, so that the magnetic induction line passing through the coil 10 is directed from the first end 2131 of the middle magnetizer 213 to the second end 2132 of the middle magnetizer 213; when the toggle mechanism 30 is toggled to drive the first end 2131 of the middle magnetizer 213 to contact the bottom magnetizer 212 and the second end 2132 of the middle magnetizer 213 to contact the top magnetizer 211, the first end 2131 and the second end 2132 of the middle magnetizer 213 are respectively an S pole and an N pole, so that the magnetic induction line passing through the coil 10 is directed to the first end 2131 of the middle magnetizer 213 from the second end 2132 of the middle magnetizer 213. That is, during the process of dialing the toggle mechanism 30 to drive the middle magnetizer 213, the direction of the magnetic induction line passing through the coil 10 will be changed, so that the magnetic flux in the coil 10 will be changed accordingly, thereby generating the induced electromotive force.

It should be noted that although in the above embodiment of the present invention, the middle magnetizer 213 is driven by the toggle mechanism 30 to make the two end portions of the middle magnetizer 213 alternately contact the top magnetizer 211 and the bottom magnetizer 212, respectively, to change the direction of the magnetic induction line passing through the coil 10, so as to generate the induced electromotive force, in other examples of the present invention, there are other implementations to change the direction of the magnetic induction line passing through the coil 10, for example, the middle magnetizer 213 is driven by the toggle mechanism 30 to make only one end portion of the middle magnetizer 213 alternately contact the top magnetizer 211 and the bottom magnetizer 212, and the other end portion of the middle magnetizer 213 does not contact the top magnetizer 211 and the bottom magnetizer 212, so as to still change the direction of the magnetic induction line passing through the coil 10.

Preferably, in the above embodiment of the present invention, as shown in fig. 6A, before the toggle mechanism 30 is toggled to drive the middle magnetizer 213, the first end 2131 and the second end 2132 of the middle magnetizer 213 contact the bottom magnetizer 212 and the top magnetizer 211 of the magnetic cavity 21, respectively; as shown in fig. 6B, after the toggle mechanism 30 is toggled to drive the middle magnetizer 213, the first end 2131 and the second end 2132 of the middle magnetizer 213 contact the top magnetizer 211 and the bottom magnetizer 212 of the magnetic cavity 21, respectively, so that the directions of the magnetic induction lines passing through the coil 10 are completely opposite before and after the toggle mechanism 30 is toggled to increase the degree of the magnetic flux change in the coil 10, thereby generating a large induced electromotive force.

Illustratively, as shown in fig. 5, the magnetic circuit system 20 includes a coil support 23 having a pair of swing fulcrum portions 231, wherein the coil 10 is wound on an outer periphery of the coil support 23, wherein the middle magnetic conductor 213 is disposed on the coil support 23 and located between the pair of swing fulcrum portions 231, such that the middle magnetic conductor 213 can swing in the magnetic conducting cavity 21 of the magnetic conducting cavity 21 with the pair of swing fulcrum portions 231 as swing fulcrums under the driving of the toggle mechanism 30 to alternately contact with edges of the top magnetic conductor 211 and the bottom magnetic conductor 212, thereby changing a direction of a magnetic induction line passing through the coil 10, and further generating an induced electromotive force.

Of course, in other examples of the present invention, before the toggle mechanism 30 is toggled to drive the middle magnet 213, neither the first end 2131 nor the second end 2132 of the middle magnet 213 contacts the magnet-conductive cavity 21, so that the magnetic flux in the coil 10 is zero; after the toggle mechanism 30 is toggled to drive the middle magnetizer 213, the first end 2131 or the second end 2132 of the middle magnetizer 213 respectively contacts with the top magnetizer 211 or the bottom magnetizer 212 of the magnetic cavity 21, so that the magnetic flux in the coil 10 is not zero, and the magnetic flux in the coil 10 changes before and after the toggle mechanism 30 is toggled to generate an induced electromotive force.

It should be noted that, according to the above-mentioned embodiment of the present invention, as shown in fig. 3 and fig. 5, the toggle mechanism 30 of the toggle power generating apparatus 1 includes a toggle element 31, wherein the toggle element 31 has a toggle end 311 and a driving end 312, wherein the driving end 312 of the toggle element 31 is drivingly connected to the middle magnetizer 213 of the magnetic cavity 21 of the magnetic circuit system 20, and the toggle end 311 of the toggle element 31 extends outwards from the driving end 312 of the toggle element 31 to deviate from the plane of the middle magnetizer 213, so that a user can toggle the toggle end 311 of the toggle element 31 out of the plane of the middle magnetizer 213 to drive the driving end 312 of the toggle element 31 to move and further drive the middle magnetizer 213 to swing, so that the two ends of the middle magnetizer 213 alternately contact the top magnetizer 211 and the bottom magnetizer 212 of the magnetic cavity 21, thereby generating an induced electromotive force for the coil 10.

It is noted that, since the toggle end 311 of the toggle element 31 is deviated from the plane of the middle magnetizer 213, the cross-sectional area of the toggle generator 1 at the plane of the middle magnetizer 213 is reduced. At the same time, this arrangement of the present invention also enables the toggle direction of the toggle end 311 of the toggle element 31 to be different from the swing direction of the middle magnetizer 213, so as to provide a user with enough operating space to perform a toggle operation.

Preferably, as shown in fig. 2 and 5, the toggle end 311 of the toggle element 31 extends outward to protrude out of the plane of the bottom surface of the magnetic circuit system 20, so that when the magnetic circuit system 20 and the coil 10 of the toggle generator 1 can be buried in the surface of an attached object such as a wall surface W, the toggle end 311 of the toggle element 31 of the toggle generator 1 is still outside the surface of the attached object such as the wall surface W, so as to ensure the overall aesthetic appearance of the surface of the attached object such as the wall surface W, and facilitate a user to toggle the toggle end 311 of the toggle element 31 to enable the toggle generator 1 to generate electricity.

More preferably, as shown in fig. 6A, the toggle end 311 of the toggle element 31 is substantially perpendicular to the middle magnetizer 213, so that the toggle direction of the toggle element 31 is substantially perpendicular to the swinging direction of the middle magnetizer 213, so as to increase the toggle arm provided by the toggle end 311 of the toggle element 31 to the maximum extent while further reducing the cross-sectional area of the toggle generator 1 at the plane where the middle magnetizer 213 is located, so as to apply a smaller toggle force to the toggle end 311 of the toggle element 31, thereby enabling the toggle generator 1 to generate power. In other words, the predetermined included angle between the toggle end 311 of the toggle element 31 and the middle magnetic conductor 213 is about 90 °, i.e., the toggle end 311 of the toggle element 31 is substantially perpendicular to the bottom surface of the magnetic circuit system 20, so as to increase the toggle arm provided by the toggle end 311 of the toggle element 31 to the maximum. Of course, in other examples of the present invention, the predetermined angle between the toggle end 311 and the middle magnetic conductor 213 of the toggle element 31 may be implemented as other angles, such as 60 ° to 120 ° or other non-zero and non-180 ° angles.

It is noted that when the toggle end 311 of the toggle element 31 is toggled, the predetermined angle between the toggle end 311 of the toggle element 31 and the middle magnetic conductor 213 will be changed accordingly. Illustratively, as shown in fig. 6B, when the toggle end 311 of the toggle element 31 is toggled by a predetermined toggle angle, the predetermined included angle between the toggle end 311 of the toggle element 31 and the middle magnetic conductor 213 will also change, wherein the predetermined toggle angle θ may be, but is not limited to, less than 90 ° (i.e., within 90 °). Preferably, the predetermined dial angle is implemented as an angle between 15 ° and 60 °. More preferably, the predetermined dial angle is implemented as an angle between 30 ° and 45 °. Of course, in other examples of the invention, the predetermined dial angle may also be embodied as any angle between 0 ° and 180 °.

Further, as shown in fig. 3 and 5, the shift lever element 31 further has a rotation fulcrum portion 313, wherein the rotation fulcrum portion 313 is located adjacent to the driving end portion 312 of the shift lever element 31, and when the shift end portion 311 of the shift lever element 31 is shifted, the shift end portion 311 and the driving end portion 312 of the shift lever element 31 rotate with the rotation fulcrum portion 313 as a rotation fulcrum, and the middle magnetic conductor 213 is driven to swing by the driving end portion 312 of the shift lever element 31, so that the coil 10 generates an induced electromotive force.

It should be noted that, just because the rotation fulcrum portion 313 of the lever element 31 is adjacent to the driving end 312 of the lever element 31, so that the lever arm provided by the lever end 311 of the lever element 31 is larger than the driving force arm provided by the driving end 312 of the lever element 31, when a user applies a smaller lever force to the lever end 311 of the lever element 31, the driving end 312 of the lever element 31 can provide a larger driving force to drive the middle magnetic conductor 213 to swing. In particular, the ratio between the toggle arm provided by the toggle end 311 of the toggle element 31 and the driving arm provided by the driving end 312 of the toggle element 31 is preferably greater than 2:1, which helps to save labor when the toggle end 311 of the toggle element 31 is toggled.

Preferably, as shown in fig. 5 and 6A, the driving end 312 of the lever element 31 integrally extends transversely from the rotation fulcrum portion 313 of the lever element 31, and the toggle end 311 of the lever element 31 integrally extends longitudinally from the driving end 312 of the lever element 31 to form the lever element 31 having an L-shaped configuration. In this way, when the driving end 312 of the toggle element 31 is close to the end of the middle magnetic conductor 213, the toggle end 311 of the toggle element 31 is also close to the end of the middle magnetic conductor 213, so as to increase the compactness of the toggle power generation device 1 and help to reduce the volume of the toggle power generation device 1.

More preferably, as shown in fig. 5 and 6A, the toggle end 311 of the toggle lever element 31 is provided with a notch 3110 at a position adjacent to the driving end 312 of the toggle lever element 31, so as to prevent the toggle end 311 of the toggle lever element 31 from structurally interfering with the magnetic circuit system 20 when the toggle end 311 of the toggle lever element 31 is toggled, so as to ensure that the toggle end 311 of the toggle lever element 31 can be toggled in a wide range.

It should be noted that, in other examples of the present invention, the rotation fulcrum portion 313 of the shift lever element 31 may also be disposed between the driving end 312 and the toggle end 311 of the shift lever element 31, that is, both the driving end 312 and the toggle end 311 of the shift lever element 31 can extend outward from the rotation fulcrum portion 313 of the shift lever element 31 at an angle to form the shift lever element 31 with an L-like structure, so as to effectively avoid the structural interference between the driving end 312 of the shift lever element 31 and the magnetic circuit system 20.

According to the above embodiment of the present invention, as shown in fig. 3 and fig. 6A, the toggle mechanism 30 further includes a power accumulating element 32, wherein the power accumulating element 32 is disposed between the driving end 312 of the toggle element 31 and the middle magnetic conductor 213 of the magnetic circuit system 20, and is used for accumulating the driving force provided by the driving end 312 of the toggle element 31 as an accumulated force, and when the accumulated force reaches a predetermined accumulated force threshold, the middle magnetic conductor 213 is rapidly swung under the action of the accumulated force, so as to shorten the time for one swing of the middle magnetic conductor 213, which helps to increase the speed of magnetic flux change in the coil 10, and further increase the induced electromotive force, so as to improve the power generation performance of the toggle power generation apparatus 1.

For example, as shown in fig. 6A and 6B, the power accumulating element 32 of the toggle mechanism 30 can be, but is not limited to be, implemented as a power accumulating spring 321, wherein one end of the power accumulating spring 321 is fixedly connected to the first end of the middle magnetic conductor 213, and the other end of the power accumulating spring 321 is connected to the driving end 312 of the toggle lever element 31. Before the toggle end 311 of the toggle element 31 is toggled, the first end 2131 and the second end 2132 of the middle magnetizer 213 are respectively contacted and attracted to the top magnetizer 211 and the bottom magnetizer 212, and when the toggle end 311 of the toggle element 31 is toggled, the driving force provided by the driving end 312 of the toggle element 31 will continuously deform the energy accumulation shrapnel 321 to accumulate an increasingly large energy accumulation until the energy accumulation accumulated in the energy accumulation shrapnel 321 reaches the predetermined energy accumulation threshold, the first end 2131 and the second end 2132 of the middle magnetizer 213 will swing to be separated from the top magnetizer 211 and the bottom magnetizer 212, respectively, and further the first end 2131 and the second end 2132 of the middle magnetizer 213 will swing rapidly to be respectively contacted and attracted to the bottom magnetizer 212 and the top magnetizer 211, so that the magnetic induction line passing through the coil 10 rapidly changes direction, thereby enhancing the power generation performance of the dial type power generation device 1.

It should be noted that, in the above embodiment of the present invention, the energy storage element 32 of the toggle mechanism 30 can make the first end 2131 and the second end 2132 of the middle magnetizer 213 alternately and rapidly contact with the top magnetizer 211 and the bottom magnetizer 212 to achieve rapid switching of magnetic poles, and the time of each switching is controlled within 5ms, which is helpful to improve the power generation efficiency of the toggle-type power generation apparatus 1.

It can be understood that, when the storage force stored in the storage spring 321 reaches the predetermined storage force threshold, the driving torque applied by the storage spring 321 to the middle magnetizer 213 is just equal to the magnetic attraction torque applied by the top magnetizer 211 and the bottom magnetizer 212 to the middle magnetizer 213, so that the middle magnetizer 213 can just separate from the attraction between the top magnetizer 211 and the bottom magnetizer 212 to swing. Of course, in other examples of the invention, the energy storage element 32 can also be embodied as another type of elastic element, such as an elastic rod or a spring.

Preferably, as shown in fig. 5 and 6A, the driving end 312 of the lever element 31 of the toggle mechanism 30 is provided with an engaging groove 3120, wherein one end of the power accumulating elastic piece 321 is fixedly connected to the first end 2131 of the middle magnetizer 213, and the other end of the power accumulating elastic piece 321 extends into the engaging groove 3120 of the driving end 312 of the lever element 31 to be detachably connected with the driving end 312 of the lever element 31, which helps to reduce the difficulty of assembling the toggle generator 1 and facilitate replacement of the lever element 31.

Of course, in other examples of the present invention, the other end of the power accumulating elastic piece 321 can also be connected to the driving end 213 of the lever element 31 by means of a method such as screwing, gluing, fitting, and snapping, which will not be described in detail herein.

It should be noted that, according to the above-mentioned embodiment of the present invention, as shown in fig. 1 and fig. 5, the toggle generating device 1 further comprises a housing 40, wherein the housing 40 has a receiving cavity 401 and an opening 402, wherein the coil 10 and the magnetic circuit system 20 are both accommodated in the receiving cavity 401 of the housing 40, wherein the toggle element 31 of the toggle mechanism 30 is disposed in the housing 40 in a toggle manner, and the driving end 312 of the toggle element 31 is located in the receiving cavity 401 of the housing 40, and the toggle end 311 of the toggle element 31 extends out of the receiving cavity 401 of the housing 40 via the opening 402 of the housing 40 to be located outside the housing 40 for being toggled by a user.

Illustratively, as shown in fig. 5, the rotation fulcrum portion 313 of the lever member 31 is pivotably provided to the housing 40, and is located at one side of the opening 402 of the housing 40; the magnetic circuit system 20 is disposed on the housing 40 and located on the other side of the opening 402 of the housing 40; thus, when the driving end 312 of the lever element 31 extends toward the magnetic circuit system 20 to drive the middle magnetizer 213 of the magnetic circuit system 20 to swing, the toggle end 311 of the lever element 31 just can pass through the opening 402 of the housing 40 to protrude out of the housing 40, so as to be conveniently toggled by a user. It will be appreciated that the size of the opening 402 of the housing 40 is slightly larger than the cross-sectional size of the dial end 311 of the dial element 31 in order to reserve sufficient dial space for the dial end 311. Further, in this example of the present invention, the rotation fulcrum portion 313 of the lever element 31 may be implemented as a pivot shaft so as to pivotally mount the lever element 31 to the housing 40. Of course, in other examples of the present invention, the rotation fulcrum portion 313 of the shift lever element 31 may be implemented as a rotatable component such as a spherical ball or a cylindrical roller, etc., as long as the shift lever element 31 can be rotatably disposed on the housing 40, which is not described in detail herein.

It should be noted that, since the cross section of the toggle end 311 of the toggle element 31 is much smaller than the cross section of the housing 40, so that the size of the opening 402 of the housing 40 is much smaller than the size of the housing 40, as shown in fig. 2, when the housing 40 of the toggle generator 1 is buried under a wall W, only an opening with the same size and corresponding position as the opening 402 of the housing 40 needs to be reserved on the wall W, and the wall W does not need to be damaged in a large area, so as to prevent the overall beauty of the wall W from being affected.

In particular, as shown in fig. 3 and 5, the housing 40 of the toggle generator 1 of the present invention may include a base 41 and a cover 42, wherein the magnetic circuit system 20 and the toggle mechanism 30 are both disposed on the base 41, and the cover 42 is detachably mounted on the base 41 to cover the magnetic circuit system 20 and the toggle mechanism 30, so as to facilitate maintenance and replacement of internal structures or components of the toggle generator 1.

In the above embodiment of the present invention, as shown in fig. 3 and 4, the toggle type power generating device 1 may further include a reset mechanism 50, wherein the reset mechanism 50 is configured to restore the toggle mechanism 30 to the state before being toggled when the toggle force applied to the toggle mechanism 30 is removed, so as to perform next toggle power generation.

It should be noted that, since the reset mechanism 50 can restore the toggle mechanism 30 to the position before being toggled, so that the direction of the magnetic induction line generated by the magnetic circuit system 20 will also be restored to the initial state, in the process of applying and removing the toggle force, the direction of the magnetic induction line generated by the magnetic circuit system 20 will change twice, that is, the user only needs to toggle the toggle mechanism 30 once, and the direction of the magnetic induction line passing through the coil 10 will change twice, so that the magnetic flux in the coil 10 changes twice, and further, two induced electromotive forces are generated, which is beneficial to improving the power generation efficiency of the toggle power generation apparatus 1.

Preferably, as shown in fig. 3, the reset mechanism 50 may be implemented as a reset spring 51, wherein the reset spring 51 is arranged between the housing 40 and the toggle mechanism 30 for restoring the toggle mechanism 30 to the state before being toggled. Illustratively, the return spring 51 is disposed in the accommodating cavity 401 of the housing 40, and one end of the return spring 51 is biased against the toggle end 311 of the toggle lever element 31, so that during the toggle end 311 of the toggle lever element 31 is toggled, the return spring 51 accumulates elastic potential energy along with the toggle end 311 of the toggle lever element 31, and once the toggle force applied to the toggle end 311 of the toggle lever element 31 is removed, the return spring 51 drives the toggle end 311 of the toggle lever element 31 to return to the original position before being toggled.

Of course, in other examples of the present invention, the return spring 51 may also be disposed between the casing 40 and the middle magnetizer 213 of the magnetic conductive cavity 21 of the magnetic circuit system 20, so that when the toggle force applied to the toggle element 31 is removed, the return spring 51 will drive the middle magnetizer 213 to swing to the initial position, and thus drive the toggle end 311 of the toggle element 31 to return to the original position before being toggled. It is understood that the reset mechanism 50 of the present invention can be implemented as other types of reset elements such as magnetic attraction component or rubber, besides the reset spring 51, and the present invention will not be described in detail herein.

It should be noted that fig. 7A and 7B show a first modified embodiment of the toggle power generating device 1 according to the above-described embodiment of the present invention. The dial type power generation device 1 according to this modified embodiment of the present invention is different from the above-described embodiment of the present invention in that: the toggle type power generation device 1 comprises two coils 10 and two magnetic systems 20, wherein the two coils 10 are respectively arranged on the two magnetic systems 20, and the two magnetic systems 20 are arranged on the left side and the right side of the toggle mechanism 30; the toggle element 31 of the toggle mechanism 30 has one toggle end 311 and two drive ends 312, wherein the two drive ends 312 extend oppositely from the toggle end 311, and the two drive ends 312 of the toggle element 31 are respectively connected to the middle magnetizers 213 of the magnetic conductive cavities 21 of the two magnetic circuits 20 in a driving manner, so that when the toggle end 311 of the toggle element 31 is toggled, the two drive ends 312 of the toggle element 31 synchronously drive the middle magnetizers 213 of the two magnetic circuits 20 to swing, so that induced electromotive forces are generated in the two coils 10 simultaneously, thereby increasing the power generated by the toggle power generating device 1.

Fig. 8A and 8B show a second modified embodiment of the dial type power generation device 1 according to the above-described embodiment of the present invention. The dial type power generation device 1 according to this modified embodiment of the present invention is different from the above-described embodiment of the present invention in that: the middle magnetic conductor 213 of the magnetic cavity 21 of the magnetic circuit system 20 is fixedly disposed on the housing 40, and the coil 213 surrounds the middle magnetic conductor 213 to maintain a constant position; the permanent magnet 22 in the magnetic circuit system 20 and the top magnetizer 211 and the bottom magnetizer 212 of the magnetic conductive cavity 21 are movably disposed to form a magnetic set 20A capable of being driven, wherein the driving end 311 of the lever element 31 of the toggle mechanism 30 is drivably connected to the magnetic set 20 ', so that when the toggling end 311 of the lever element 31 is toggled, the driving end 312 of the lever element 31 drives the magnetic set 20A of the magnetic circuit system 20 to move, so that the top magnetizer 211 and the bottom magnetizer 212 of the magnetic set 20' alternately contact the middle magnetizer 213 to change the magnetic induction line direction passing through the coil 10, thereby generating an induced electromotive force.

More specifically, as shown in fig. 8A and 8B, the permanent magnet 22 of the magnet group 20 ' is disposed between the top magnetizer 211 and the bottom magnetizer 212, and the top magnetizer 211 and the bottom magnetizer 212 each have a portion that protrudes with respect to the permanent magnet 22 to form a magnetic gap 200 ' between the protruding portions, wherein an end of the middle magnetizer 213 extends into the magnetic gap 200 ', and a thickness of the middle magnetizer 213 is smaller than a distance between the top magnetizer 211 and the bottom magnetizer 212. Thus, when the toggle end 311 of the toggle element 31 is toggled, the top magnetizer 211 and the bottom magnetizer 212 alternately collide with the end of the middle magnetizer 213, so that the direction of the magnetic induction line passing through the coil 10 is changed, thereby generating an induced electromotive force in the coil 10.

Fig. 9A and 9B show a third modified embodiment of the toggle power generation apparatus according to the embodiment of the present invention. The toggle generator according to this variant embodiment of the invention differs from the above-described embodiment according to the invention in that: the magnetic circuit system 20A has a magnetic gap 200A, wherein the toggle mechanism 30A is connected to the coil 10 in a driving manner, and when the toggle mechanism 30A is toggled, the coil 10 can be driven by the toggle mechanism 30A to be displaced relative to the magnetic gap 200A of the magnetic circuit system 20A, so that the coil 10 cuts magnetic induction lines generated by the magnetic circuit system 20A to change magnetic flux in the coil 10, thereby generating electromotive force, and the toggle type power generation apparatus 1A achieves the effect of power generation.

More specifically, the magnetic gap 200A of the magnetic circuit system 20A of the toggle type power generation device 1A has an annular shape, and the coil 10 can be driven by the toggle mechanism 30A to be relatively moved with respect to the magnetic gap 200A of the magnetic circuit system 20A, so that the coil 10 cuts magnetic induction lines to generate a dynamic electromotive force.

For example, as shown in fig. 9A, the magnetic circuit system 20A includes a top magnetic conductive plate 21A, a permanent magnet 22A, and a bottom magnetic conductive plate 23A, wherein the bottom magnetic conductive plate 23A has a groove 231A, and the permanent magnet 22A is disposed in the groove 231A of the bottom magnetic conductive plate 23A and has a gap with a peripheral sidewall of the bottom magnetic conductive plate 23A, wherein the top magnetic conductive plate 21A is attached to a top surface of the permanent magnet 22A, so that the top magnetic conductive plate 21A and the permanent magnet 22A form the ring-shaped magnetic gap 200A with closely-distributed magnetic induction lines in the bottom magnetic conductive plate 23A. The magnetic circuit system 20A is fixedly disposed on the housing 40, and the coil 10 is fixedly connected to the driving end 312A of the lever element 31A of the toggle mechanism 30A, and the coil 10 is correspondingly located in the magnetic gap 200A of the magnetic circuit system 20A before the toggle end 311A of the lever element 31A is toggled; when the toggle end 311A of the toggle element 31A is toggled, the driving end 312A of the toggle element 31A drives the coil 10 to leave the magnetic gap 200A of the magnetic circuit system 20A, so that the coil 10 cuts the magnetic induction lines generated by the magnetic circuit system 20A, thereby generating electromotive force. It will be appreciated that the toggle end 311A of the toggle element 31A extends obliquely outwardly from the drive end 312A of the toggle element 31 to form the toggle element 31 having an L-like configuration.

Preferably, the driving end 312A of the lever element 31A extends outward from the rotation fulcrum portion 313A of the lever element 31A to provide a sufficiently large mounting surface for fixedly mounting the coil 10. For example, as shown in fig. 8, the driving end 312A of the lever element 31A has a circular plate-shaped structure so that the coil 10 of an O-type is fixedly provided to the bottom surface of the driving end 312A.

More preferably, the driving end 312A of the shifter element 31A is made of a magnetic material or a material containing a magnetic material, so that a magnetic attraction force is generated between the driving end 312A of the shifter element 31A and the permanent magnet 22A of the magnetic circuit system 20A. Thus, when the toggle force applied to the toggle end 311A of the toggle element 31A is removed, the driving end 312A of the toggle element 31A is attracted only to the top surface of the top magnetic conductive plate 21A by the magnetic attraction of the permanent magnet 22A, so that the coil 10 is automatically inserted into the magnetic gap 200A of the magnetic circuit system 20A to cut the magnetic induction lines again to generate a secondary electromotive force. In other words, in this example of the present invention, the toggle power generating device 1A does not need to additionally provide a reset mechanism, and the driving end 312A and the toggle end 311A of the toggle element 31A can be restored to the initial positions only by the magnetic attraction force between the driving end 312A of the toggle element 31A and the permanent magnet 22A, so as to simplify the structure of the toggle power generating device 1A.

It is noted that in other examples of the present invention, before the toggle end 311A of the toggle element 31A is toggled, the coil 10 may be correspondingly located outside the magnetic gap 200A of the magnetic circuit system 20A; when the toggle end 311A of the toggle element 31A is toggled, the driving end 312A of the toggle element 31A drives the coil 10 to be inserted into the magnetic gap 200A of the magnetic circuit system 20A, so that the coil 10 cuts the magnetic induction lines generated by the magnetic circuit system 20A, thereby generating electromotive force.

It should be noted that fig. 10A and 10B show a fourth modified embodiment of the toggle power generating device according to the above embodiment of the present invention. Compared to the third variant embodiment of the invention described above, the toggle generator according to this variant embodiment of the invention differs in that: the toggle mechanism 30A is drivably connected to the magnetic circuit system 20A, and when the toggle mechanism 30A is toggled, the magnetic circuit system 20A can be driven by the toggle mechanism 30A to cause the coil 10 and the magnetic gap 200A of the magnetic circuit system 20A to generate relative displacement, so that the coil 10 cuts the magnetic induction lines generated by the magnetic circuit system 20A to change the magnetic flux in the coil 10, thereby generating electromotive force, and still enabling the toggle type power generation apparatus 1A to achieve the power generation effect.

Illustratively, the coil 10 is fixedly disposed on the housing 40, and the magnetic circuit system 20A is fixedly connected to the driving end 312A of the lever element 31A of the toggle mechanism 30A, and the coil 10 is correspondingly located in the magnetic gap 200A of the magnetic circuit system 20A before the toggle end 311A of the lever element 31A is toggled; when the toggle end 311A of the toggle element 31A is toggled, the driving end 312A of the toggle element 31A drives the magnetic circuit system 20A away from the coil 10, so that the coil 10 is away from the magnetic gap 200A of the magnetic circuit system 20A, and the coil 10 cuts the magnetic induction lines generated by the magnetic circuit system 20A, thereby generating a dynamic electromotive force.

According to another aspect of the present invention, as shown in fig. 11, an embodiment of the present invention further provides an electronic device, wherein the electronic device may include any one of the above-mentioned toggle generating devices 1 and a signal generator 2, wherein the signal generator 2 is operatively and electrically connected to the toggle generating device 1, and is configured to generate and transmit a wireless signal when the toggle generating device 1 is supplied with power, so as to control other electronic devices such as a lighting system or a sound system, etc. to perform a predetermined operation through the wireless signal.

Illustratively, as shown in fig. 11, the signal generator 2 may be, but is not limited to be, implemented as a circuit board integrating a series of electronic components, wherein the circuit board is correspondingly disposed in the housing 40 of the dial type electric power generating device 1, and the circuit board is electrically connected to the coil 10 of the dial type electric power generating device 1. Thus, when the toggle mechanism 30 of the toggle type power generation device 1 is toggled, an electromotive force is generated in the coil 10 to provide working power for the circuit board, so that the circuit board can generate and transmit a wireless signal to control a device such as a lighting system or a sound system to perform a preset operation (such as turning on or off).

According to another aspect of the present invention, as shown in fig. 12, an embodiment of the present invention further provides a method for manufacturing a toggle type power generator, including the steps of:

s100: correspondingly arranging at least one coil 10 and at least one magnetic circuit system 20; and

s200: a toggle mechanism 30 is disposed on the coil 10 or the magnetic circuit system 20 in a toggle manner, wherein when the toggle mechanism 30 is toggled, the toggle mechanism 30 drives the coil 10 or the magnetic circuit system 20 to change the magnetic flux in the coil 10 to generate an electromotive force, so as to convert the mechanical energy generated by the toggle into electrical energy.

According to another aspect of the present invention, as shown in fig. 13, an embodiment of the present invention further provides a self-generating method of a toggle type power generator, including the steps of:

(A) a toggle mechanism 30 is toggled to enable the toggle mechanism 30 to rotate; and

(B) at least one self-generating body is driven by the toggle mechanism 30, wherein the self-generating body comprises a coil 10 and a magnetic circuit system 20, so that magnetic flux formed in the coil 10 by magnetic induction lines generated by the magnetic circuit system 20 is changed to generate electromotive force, thereby converting mechanical energy generated by toggling into electric energy.

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

Claims (15)

1. A toggle type power generation device, comprising:

the self-generating body comprises a coil and a magnetic circuit system for generating magnetic induction lines; and

and the toggle mechanism is connected to the self-generating main body in a driving way, and is suitable for being toggled to drive the self-generating main body, so that magnetic flux formed in the coil through the magnetic induction lines generated by the magnetic circuit system is changed to generate electromotive force, and mechanical energy generated by toggling is converted into electric energy.

2. The toggle generator of claim 1, wherein the toggle mechanism includes a toggle element, wherein the toggle element has a toggle end and a drive end, and wherein the toggle end of the toggle element extends outwardly from the drive end of the toggle element, wherein the drive end of the toggle element is drivingly connected to the magnetic circuit for driving the magnetic circuit to change the direction of the magnetic flux induced by the magnetic circuit such that the direction of the magnetic flux induced through the coil changes.

3. A toggle type power generating device as recited in claim 2, wherein the toggle mechanism further comprises a power accumulating element, wherein the power accumulating element is disposed between the actuating end of the toggle element and the magnetic circuit system, for accumulating the actuating force provided via the actuating end of the toggle element as an accumulated force, and the magnetic circuit system is driven rapidly by the accumulated force when the accumulated force reaches a predetermined accumulated force threshold.

4. A toggle type power generating device as recited in claim 3, wherein the power accumulating element is a power accumulating leaf spring, wherein one end of the power accumulating leaf spring is connected to the magnetic circuit system, and the other end of the power accumulating leaf spring is connected to the driving end of the toggle element.

5. The toggle type power generating apparatus according to claim 4, wherein the driving end portion of the toggle element is provided with an engaging groove, wherein the one end of the power accumulating spring is fixedly connected to the magnetic circuit system, and the other end of the power accumulating spring protrudes into the engaging groove of the driving end portion of the toggle element to be detachably connected with the driving end portion of the toggle element.

6. The toggle generator of claim 2, wherein the toggle end of the toggle element extends outwardly to extend out of a plane of a bottom surface of the magnetic circuit system, and the predetermined toggle angle of the toggle end of the toggle element is within 90 °.

7. The toggle generator of claim 6, wherein the toggle end of the toggle element is perpendicular to the bottom surface of the magnetic circuit system.

8. The toggle generator of claim 2, wherein the toggle mechanism includes a toggle element, wherein the toggle element has a toggle end and two actuating ends, wherein the two actuating ends of the toggle element extend oppositely from the toggle end of the toggle element, and the two actuating ends of the toggle element are respectively drivingly connected to the two magnetic circuits for synchronously actuating the two magnetic circuits to change the direction of the magnetic induction lines generated by the magnetic circuits, such that the direction of the magnetic induction lines passing through the coil changes.

9. The toggle power generating device according to claim 3, wherein the magnetic circuit system comprises a magnetic conducting cavity and a permanent magnet, wherein the magnetic conducting cavity comprises a top magnetic conductor, a bottom magnetic conductor and a middle magnetic conductor, and the permanent magnet is jointly disposed between the top magnetic conductor and the bottom magnetic conductor, wherein the coil surrounds the middle magnetic conductor, and the toggle mechanism is drivingly connected to the middle magnetic conductor through the power accumulating element for driving the middle magnetic conductor to move so that the end of the middle magnetic conductor alternately contacts the top magnetic conductor and the bottom magnetic conductor.

10. The toggle generator according to any one of claims 2 to 9, wherein the toggle element further has a rotation fulcrum portion, wherein the rotation fulcrum portion is located adjacent to the driving end portion of the toggle element, and when the toggle end portion of the toggle element is toggled, the toggle end portion and the driving end portion of the toggle element both rotate between the rotation of the rotation fulcrum portion.

11. The toggle generator of claim 10, wherein the driving end of the toggle element integrally extends laterally from the rotation fulcrum portion of the toggle element, and the toggle end of the toggle element integrally extends longitudinally from the driving end of the toggle element to form the toggle element having an L-shaped configuration.

12. A toggle generator according to claim 11, wherein the ratio of the toggle arm provided by the toggle end of the toggle element to the driving arm provided by the driving end of the toggle element is greater than 2: 1.

13. An electronic device, comprising:

at least one toggle power generation device, wherein the toggle power generation device comprises:

the self-generating body comprises a coil and a magnetic circuit system for generating magnetic induction lines; and

a toggle mechanism, wherein the toggle mechanism is drivably connected to the self-generating body, wherein the toggle mechanism is adapted to be toggled to drive the self-generating body so that a magnetic flux formed in the coil via a magnetic induction line generated by the magnetic circuit system is changed to generate an electromotive force, thereby converting mechanical energy generated by toggling into electric energy; and

and the signal generator is electrically connected with the toggle type power generation device in a working mode and is used for generating and transmitting a wireless signal when the toggle type power generation device provides electric energy so as to control other electronic equipment to carry out preset operation.

14. A method for manufacturing a toggle type power generation device is characterized by comprising the following steps:

correspondingly arranging at least one coil and at least one magnetic circuit system; and

the coil or the magnetic circuit system can be arranged with a toggle mechanism in a toggle manner, wherein when the toggle mechanism is toggled, the toggle mechanism drives the coil or the magnetic circuit system to change the magnetic flux in the coil to generate electromotive force, thereby converting the mechanical energy generated by the toggle into electric energy.

15. The self-generating method of the toggle type generating set is characterized by comprising the following steps:

a toggle mechanism is toggled to enable the toggle mechanism to rotate; and

the poking mechanism drives at least one self-generating main body, wherein the self-generating main body comprises a coil and a magnetic circuit system, so that magnetic flux formed in the coil by magnetic induction lines generated by the magnetic circuit system is changed to generate electromotive force, and mechanical energy generated by poking is converted into electric energy.

Images