CN111049352B - Circulation decomposition device, circulation power generation device and circulation decomposition method - Google Patents

Abstract

The invention discloses a cycle decomposition device, a cycle power generation device and a cycle decomposition method, wherein the cycle power generation device comprises a power generation unit and the cycle decomposition device, wherein the power generation unit is set to be capable of being actuated once to generate pulse power once so as to provide primary power output for the cycle power generation device, the cycle decomposition device is operably coupled with the power generation unit and is set to be actuated once by once cycle operation so as to decompose the once cycle actuation of the power generation unit into multiple cycle operations of the cycle decomposition device, thereby reducing the mechanical energy requirement on the single cycle operation of the cycle decomposition device, being beneficial to improving the operation experience of the cycle power generation device, and simultaneously avoiding the integration of multiple pulses and being beneficial to simplifying the circuit structure of the cycle power generation device.

Description

Circulation decomposition device, circulation power generation device and circulation decomposition method

Technical Field

The present invention relates to the field of cyclic power generation, and more particularly, to a cyclic decomposition device, a cyclic power generation device, and a cyclic decomposition method, in which one cyclic operation of the cyclic power generation device can be decomposed into a plurality of cyclic operations for the cyclic decomposition device.

Background

The present power generation device mainly realizes the periodic change of the magnetic flux of a coil through reciprocating periodic motion or rotary periodic motion, and generates periodically changed electric energy on the coil, wherein, for a manually operated small micro power generation device, particularly a reset power generation device, the reset structural design enables the power generation device to complete the periodic motion of the power generation device through a simple pressing action, so even if the repeatability of the manual operation is poor, the consistency of the electric energy generated by the power generation device in each motion period can be still maintained stably through the simple pressing operation, and the reset power generation device is widely applied to the field of passive wireless switches, such as a passive wireless doorbell switch.

Fig. 1A and 1B are schematic diagrams illustrating an operation principle of a conventional reset power generation device, wherein the reset power generation device includes a driving arm 100P and a reset spring 200P, wherein the driving arm 100P has a first driving position 101P and a second driving position 102P, and wherein the reset spring 200P is configured to be compressed when the driving arm 100P is driven from the first driving position 101P to the second driving position 102P by an external force, so that the driving arm 100P can be driven by the reset spring 200P to return to the first driving position 101P after the external force is released. In this way, the one-cycle movement of the reset power generator is completed by one pressing operation of the driving arm 100P. It can be understood that when the return spring 200P is not disposed, that is, when the driving arm 100P performs a one-cycle reciprocating motion between the first driving position 101P and the second driving position 102P by two times of poking in opposite directions of the driving arm 100P by an external force, wherein minimum values of the external force required by the two times of poking in opposite directions of the driving arm 100P are the same and are both set to be F, for the reset type power generation apparatus provided with the return spring 200P, only when the external force for one-time pressing of the driving arm 100P is greater than 2F, the one-cycle motion of the reset type power generation apparatus can be completed by one-time pressing of the driving arm 100P.

That is to say, the current reset type power generation device completes the reciprocating motion of one cycle of the reset type power generation device through one-time pressing action, which is more laborious for dialing the driving arm 100P without the reset spring 200P, and is difficult to obtain good pressing hand feeling, and when the reciprocating motion of one cycle of the reset type power generation device is completed through one-time pressing action, the conversion rate of mechanical energy into electric energy is lower than that of mechanical energy into electric energy when the driving arm 100P is dialed twice without the reset spring 200P. In addition, it can be understood that, a cycle of the reciprocating motion of the reset type power generation apparatus can generate a positive pulse and a negative pulse in opposite directions, and therefore, in order to improve the utilization rate of the electric energy generated by the reset type power generation apparatus, the existing reset type power generation apparatus is often further provided with an electric energy storage unit, so as to be able to temporarily store a first pulse and then integrate two pulses to provide an electric energy output, wherein a transition point of the positive and negative pulses corresponds to a state that the driving arm 100P of the reset type power generation apparatus is in the second driving position 102P, however, a duration of the state that the driving arm 100P of the reset type power generation apparatus is in the second driving position 102P is limited by the repeatability of manual operation and cannot be maintained stably, so that the reset type power generation apparatus has a large electric energy loss before providing the electric energy output.

In summary, the current reset power generation device completes the reciprocating motion of one cycle of the reset power generation device through one-time pressing motion, the pressing motion is laborious and difficult to obtain good pressing hand feeling, and the integration of two pulses generated by the reciprocating motion is complex in circuit structure requirement of the reset power generation device and has large electric energy loss, so that the conversion rate of converting mechanical energy into electric energy of the current reset power generation device is still to be improved.

Disclosure of Invention

An object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device, and a cyclic decomposition method, wherein the cyclic power generation device includes a power generation unit, and the cyclic decomposition device is capable of decomposing one cyclic operation of the power generation unit into a plurality of cyclic operations of the cyclic decomposition device.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device, and a cyclic decomposition method, wherein the cyclic decomposition device is provided in the cyclic power generation device, and one cyclic operation of the cyclic decomposition device can generate one pulse power in the power generation unit corresponding to one actuation of the power generation unit.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic power generation device is configured to provide a single pulse power for outputting a single power, so as to avoid the integration of multiple pulses and facilitate the simplification of the circuit structure of the cyclic power generation device.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic power generation device is configured to provide a primary power output with a single pulse power, so as to avoid the storage and integration of multiple pulses, thereby facilitating the reduction of the circuit loss of the cyclic power generation device and further improving the efficiency of the cyclic power generation device.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic power generation device has a primary power output corresponding to only one actuation of the power generation unit, thereby avoiding the cyclic actuation of the power generation unit for multiple actuations, and being beneficial to prolonging the service life of the cyclic power generation device.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein one cyclic operation of the cyclic decomposition device only corresponds to one actuation of the power generation unit and has smaller mechanical energy requirement, which is beneficial to reduce the force of one cyclic operation of the cyclic decomposition device, thereby improving the operation experience of the cyclic power generation device.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the power generation unit has a first position state and a second position state, wherein a switching of the power generation unit between the first position state and the second position state can generate a pulse power, wherein an actuation of the power generation unit corresponds to a switching of the power generation unit between the first position state and the second position state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic decomposition device includes a cyclic key, wherein the cyclic key has an initial state and a trigger state, and wherein the cyclic key is switched from the initial state to the trigger state corresponding to an actuation of the power generation unit to form a switching of the power generation unit between the first position state and the second position state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic key is provided with a reset element, wherein the reset element is configured to return the cyclic key from the triggered state to the initial state, so as to switch the cyclic key from the initial state to the triggered state by actuating the cyclic key once under external force, and after the external force is removed, the cyclic key can return from the triggered state to the initial state to form a cyclic operation on the cyclic decomposition device, i.e. a cyclic operation on the cyclic decomposition device is formed by actuating the cyclic key once, so that the cyclic decomposition device is faster and simpler.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein one actuation of the cyclic button can form one cyclic operation on the cyclic decomposition device, and one cyclic operation on the cyclic decomposition device corresponds to only one actuation of the power generation unit, thereby saving more labor.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic decomposition device further includes a transposition driving unit, wherein the transposition driving unit is disposed between the cyclic key and the power generation unit and has a first driving state and a second driving state, and a switching of the cyclic key from the initial state to the trigger state corresponds to a switching of the transposition driving unit between the first driving state and the second driving state, so as to form a switching of the transposition driving unit between the first driving state and the second driving state through a cyclic operation of the cyclic decomposition device.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein one switching of the transposition driving unit between the first driving state and the second driving state corresponds to one switching of the power generation unit between the first position state and the second position state, so as to form one switching of the power generation unit between the first position state and the second position state by one cyclic operation of the cyclic decomposition device.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the transposition driving unit comprises a transposition member, wherein the transposition member is operatively coupled to the power generation unit and has a first driving position and a second driving position, wherein driving the transposition member at one of the first driving position and the second driving position can form a switch of the power generation unit between the first position state and the second position state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein one switching of the index driving unit between the first driving state and the second driving state corresponds to driving the index member at one of the first driving position and the second driving position, so as to form one switching of the power generation unit between the first position state and the second position state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the indexing driving unit further comprises a driving arm, wherein the driving arm is movably coupled to the cyclic button, wherein the indexing member comprises a guiding tooth, and wherein the driving arm can be guided by the guiding tooth to selectively drive the indexing member at one of the first driving position and the second driving position during the process of switching the cyclic button from the initial state to the trigger state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the extending direction of the driving arm is maintained in an initial direction in the initial state of the cyclic button, and the guiding tooth is maintained in the first driving state and the second driving state to be obliquely intersected with the initial direction so as to guide the driving arm to a corresponding driving position of the first driving position and the second driving position during the process of switching the cyclic button from the initial state to the trigger state.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the cyclic decomposition device further includes a guide member, wherein the guide member is configured to guide the driving arm when the cyclic key returns to the initial state from the triggered state, so that the extending direction of the driving arm can be maintained in the initial state of the cyclic key.

Another objective of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the power generation unit is switched from the first position state to the second position state, and is switched back from the second position state to the first position state to form a cyclic operation of the power generation unit, so that the power generation unit is suitable for a main flow seesaw type reciprocating power generation unit, and the cyclic power generation device has better applicability.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the driving arm drives the index member at the first driving position during the process of switching the index driving unit from the first driving state to the second driving state, and wherein the driving arm drives the index member at the second driving position during the process of switching the index driving unit from the second driving state to the first driving state.

Another object of the present invention is to provide a cyclic decomposition device and a cyclic power generation device and a cyclic decomposition method, wherein the guide teeth are disposed between the first driving position and the second driving position and have a first guide wall and a second guide wall extending to the first driving position and the second driving position, respectively, wherein in the first driving state of the index driving unit, the driving arm corresponds to the first guide wall and in the process of the index driving unit being switched from the first driving state to the second driving state, the driving arm can drive the index member guided to the first driving position by the first guide wall; wherein in the second drive state of the index drive unit, the drive arm corresponds to the second guide wall and, in a process in which the index drive unit is switched from the second drive state to the first drive state, the drive arm can drive the index member guided to the second drive position by the second guide wall.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device, and a cyclic decomposition method, wherein when the power generation unit is in the first position state, the power generation unit is switched from the first position state to the second position state by driving the displacement member at the first driving position of the displacement member, and the power generation unit is switched from the second position state to the first position state by subsequently driving the displacement member at the second driving position of the displacement member.

Another object of the present invention is to provide a cyclic decomposition device, a cyclic power generation device and a cyclic decomposition method, wherein the guide teeth are vertically disposed on the index member between the first driving position and the second driving position, such that in the initial state of the cyclic key, when the power generation unit configured as a seesaw-type reciprocating power generation unit is in the first position state, the first driving position is higher than the second driving position in an initial direction so that the driving arm corresponds to the first guide wall, and when the power generation unit configured as a seesaw-type reciprocating power generation unit is in the second position state, the second driving position is higher than the first driving position in an initial direction so that the driving arm corresponds to the second guide wall.

To achieve at least one of the above objects, the present invention provides a cyclic decomposition device, wherein the cyclic decomposition device comprises:

the circulating key is provided with an initial state and a triggering state and is provided with a reset element, and when the circulating key is pressed and actuated in the initial state by applying external force and is in the triggering state, the circulating key can be restored to the initial state by the reset element after the external force is removed;

a driving arm, wherein one end of the driving arm is disposed at the circulation button, wherein the driving arm is maintained in an initial direction when the circulation button is in the initial state; and

a index member, wherein the index member is configured to be pivotable, wherein the index member has a first driving position and a second driving position and a first guide wall and a second guide wall extending from the first driving position and the second driving position, respectively, wherein when the circulation button is in the initial state, the first guide wall is inclined to the initial direction and corresponds to the driving arm in the initial direction, such that when the circulation button is pressed from the initial state to the activated state, the driving arm can be guided by the first guide wall and drive the index member to perform a pivoting motion in the first driving position, so as to form a state in which the second guide wall is inclined to the initial direction and corresponds to the driving arm in the initial direction after the circulation button is returned to the initial state, and further, subsequently, when the circulation button is pressed from the initial state to the activated state again, the driving arm can be guided by the second guide wall and drive the index member to perform a pivoting motion in the second driving position.

In one embodiment, the circulation breaking apparatus further comprises a guiding member, wherein the guiding member is provided with a guiding groove, wherein one end of the driving arm is pivotally disposed on the circulation key, and the other end of the driving arm is embedded in the guiding groove, so as to guide the movement of the driving arm through the guiding groove during the process of the circulation key returning from the triggered state to the initial state, and maintain the driving arm in the initial direction by limiting the movement of the driving arm through the guiding groove in the initial state of the circulation key.

In one embodiment, the index member includes a guide tooth, wherein the guide tooth is disposed between the first driving position and the second driving position to form the first guide wall and the second guide wall at two sides of the guide tooth corresponding to the first driving position and the second driving position, respectively, such that one cyclic reciprocating pivotal motion of the index member is formed by two cyclic operations of the cyclic button.

In an embodiment, the index member is provided in a gear shape and includes a plurality of guide teeth, wherein each tooth of the gear-shaped index member is the guide tooth, wherein a tooth space is formed between any two adjacent guide teeth, wherein any two adjacent tooth spaces are the first driving position and the second driving position, respectively, wherein the first guide wall and the second guide wall respectively extend in the same direction to the corresponding tooth space, that is, the first guide wall and the second guide wall are sidewalls of any two adjacent guide teeth in the same direction, so that one circular pivoting motion of the index member is formed through a plurality of circular operations of the circular key corresponding to the number of the tooth spaces.

According to another aspect of the present invention, there is also provided a cycle power generation apparatus, wherein the cycle power generation apparatus includes:

the circulating key is provided with an initial state and a triggering state and is provided with a reset element, and when the circulating key is pressed and actuated in the initial state by applying external force and is in the triggering state, the circulating key can be restored to the initial state by the reset element after the external force is removed;

a power generating unit, wherein the power generating unit has a first position state and a second position state, wherein a switching of the power generating unit between the first position state and the second position state can generate a pulse power; and

the transposition driving unit is operatively coupled between the circulation key and the power generation unit and has a first driving state and a second driving state, wherein the transposition driving unit is adapted to be driven by the circulation key to perform a switching between the first driving state and the second driving state when the circulation key is switched from the initial state to the trigger state, so that the power generation unit coupled with the transposition driving unit performs a switching between the first position state and the second position state by a switching operation of the transposition driving unit between the first driving state and the second driving state.

In one embodiment, the index driving unit includes a driving arm and an index member, wherein the driving arm is disposed at the circulation button, and the driving arm is maintained in an initial direction when the circulation button is in the initial state, wherein the index member has a first driving position and a second driving position, and a first guiding wall and a second guiding wall respectively extending from the first driving position and the second driving position, wherein in the first driving state of the index driving unit, when the circulation button is in the initial state, the first guiding wall is inclined to the initial direction and corresponds to the driving arm in the initial direction, so that the driving arm can be guided by the first guiding wall and drive the index member in the first driving position when the circulation button is pressed from the initial state to the trigger state, thereby forming the second guiding wall inclined to the initial direction and corresponding to the second driving position in the initial direction after the circulation button is returned to the initial state, and further forming the second guiding wall in the subsequent driving state, when the circulation button is pressed from the initial state to the trigger state, the second guiding wall can be guided again to the trigger state.

In one embodiment, the index driving unit further includes a guide member, wherein the guide member is provided with a guide groove, wherein one end of the driving arm is pivotally disposed on the circulation key, and the other end of the driving arm is embedded in the guide groove, so as to guide the movement of the driving arm through the guide groove during the process of returning the circulation key from the triggered state to the initial state, and maintain the driving arm in the initial direction by restricting the movement of the driving arm through the guide groove in the initial state of the circulation key.

In one embodiment, the power generating unit is arranged to adopt a reciprocating pivoting actuation structure, i.e. one switching of the power generating unit from the first position state to the second position state and one switching from the second position state to the first position state form one reciprocating cyclic actuation of the power generating unit.

In an embodiment, the index member includes a guide tooth, wherein the guide tooth is disposed between the first driving position and the second driving position, so as to form the first guide wall and the second guide wall on two sides of the guide tooth respectively corresponding to the first driving position and the second driving position, so as to form a cyclic reciprocating switching of the index driving unit between the first driving state and the second driving state through two cyclic operations of the cyclic key.

In one embodiment, the power generation unit is configured to adopt a rotary type pivot actuating structure so as to be capable of being rotated in one direction for one circle to form multiple times of switching between the first position state and the second position state.

In an embodiment, the index member is configured as a gear and includes a plurality of guide teeth, wherein each tooth of the gear is the guide tooth, wherein a tooth space is formed between any two adjacent guide teeth, wherein any two adjacent tooth spaces are the first driving position and the second driving position, respectively, wherein the first guide wall and the second guide wall respectively extend in the same direction to the corresponding tooth space, that is, the first guide wall and the second guide wall are sidewalls of any two adjacent guide teeth in the same direction, so as to form a circumferential pivoting driving of the index member through a plurality of cycles of the number of the cycle keys corresponding to the tooth spaces.

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

Drawings

Fig. 1A and 1B are schematic structural diagrams of a conventional reset power generation device.

Fig. 2A and 2B are schematic perspective views of a cycle power generation device according to an embodiment of the invention.

Fig. 3 is a schematic structural cross-sectional view of the cycle power generation device according to the above embodiment of the present invention.

Fig. 4 is an exploded view of the cycle power generation device according to the above embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a power generation unit of the cycle power generation apparatus according to the above embodiment of the invention.

Fig. 6A to 6D are schematic structural diagrams of a cyclic decomposition device of the cyclic power generation device according to the above embodiment of the present invention in different states.

Fig. 7 is a schematic perspective view of the cycle power generation device according to a modified embodiment of the above embodiment of the present invention.

Fig. 8 is an exploded view of the cycle power generation device according to the above modified embodiment of the present invention.

Detailed Description

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

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in 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" preceding non-limiting terms are not to be interpreted as limiting, but rather as meaning that the terms "a" and "an" or "one or more" may be used, i.e., that a single element may be present in one embodiment, and that a plurality of elements may be present in another embodiment.

Referring to fig. 2A, 2B, 3 and 4 of the drawings of the present specification, a cycle power generation apparatus 10 according to an embodiment of the present invention is illustrated and disclosed and described in the following description, wherein the cycle power generation apparatus 10 includes a power generation unit 20 and a cycle decomposition device 30, wherein the cycle decomposition device 30 is operably coupled to the power generation unit 20, wherein the power generation unit 20 is configured to be capable of generating a pulse power once, and wherein the cycle power generation apparatus 10 is configured to provide a power output with a single pulse power, thereby avoiding the integration of multiple pulses and facilitating the simplification of the circuit structure of the cycle power generation apparatus 10, and simultaneously facilitating the reduction of the circuit loss of the cycle power generation apparatus 10, thereby improving the efficiency of the cycle power generation apparatus 10.

Further, the cyclic decomposition device 30 is configured to be capable of being actuated once by one cyclic operation of the power generation unit 20, that is, one cyclic operation of the cyclic decomposition device 30 corresponds to one actuation of the power generation unit 20, so as to be capable of decomposing one cyclic operation of the power generation unit 20 into a plurality of cyclic operations of the cyclic decomposition device 30, thereby reducing the mechanical energy requirement for a single cyclic operation of the cyclic decomposition device 30, facilitating reduction of the force for the single cyclic operation of the cyclic decomposition device 30, and facilitating improvement of the operation experience of the cyclic power generation device 10.

It should be noted that the primary electric energy output of the circulation power generation apparatus 10 corresponds to only one operation of the circulation decomposition device 30 on the power generation unit 20, so as to reduce the mechanical loss of the primary electric energy output of the circulation power generation apparatus 10 on the power generation unit 20, thereby prolonging the service life of the circulation power generation apparatus 10.

Specifically, the circulation breaking device 30 includes a circulation key 301, wherein the circulation key 301 has an initial state and a triggered state, and the circulation key 301 can be switched between the initial state and the triggered state. Preferably, a reset element 3011 is disposed at a lower portion of the circulation key 301, wherein the reset element 3011 can make the circulation key 301 transition from the activated state to the initial state. That is, the circulation breaking device 30 includes the circulation key 301 and the reset element 3011 disposed at the lower portion of the circulation key 301, so that when the circulation key 301 is operated to switch from the initial state to the trigger state, the reset element 3011 can be operated by the circulation key 301 to change the initial state, for example, be compressed to be in a compressed state, so that subsequently, the reset element 3011 switches the circulation key 301 from the trigger state to the initial state in the process of restoring the initial state. The initial state is a state of the circulation button 301 when the circulation breaking device 30 is not driven by an external force. Referring to fig. 2A and 2B, when the circulation key 301 is pressed in the initial state illustrated in fig. 2A by an external force and is in the triggered state illustrated in fig. 2B, the circulation key 301 can be returned to the initial state by the reset element 3011 after the external force is released. Thus, one cycle operation on the cycle key 301 is formed by pressing and actuating the cycle key 301 once under the action of external force, namely, one cycle operation on the cycle decomposition device 30 is formed by actuating the cycle key 301 once, so that the operation is quicker and simpler.

It is worth mentioning that the reset element 3011 is configured to be in the activated state of the cycle key 301, and when the external force applied to the cycle key 301 is released, the cycle key 301 can be returned to the initial state from the activated state, wherein it should be understood by those skilled in the art that the reset element 3011 may be configured as an element having elasticity. Such as, but not limited to, compression springs, torsion springs, and elastic rubbers. In addition, the reset element 3011 may be configured as two magnets configured by using the principle that like poles of magnetic materials repel each other, which is not a limitation of the present invention. That is, the reset component 3011 of the present invention may be any device or mechanism configured to return the cycle key 301 from the activated state to the initial state.

Further, the cyclic decomposition device 30 further comprises a shift driving unit 302, wherein the shift driving unit 302 is operably coupled between the cyclic key 301 and the power generating unit 20, wherein the shift driving unit 302 has a first driving state and a second driving state, wherein a cyclic operation of the cyclic key 301 corresponds to a switching of the shift driving unit 302 between the first driving state and the second driving state, i.e. the cyclic key 301 can be operated to drive the shift driving unit 302 to switch between the first driving state and the second driving state in a cyclic operation, so as to actuate the power generating unit 20 coupled to the shift driving unit 302 once by a switching of the shift driving unit 302 between the first driving state and the second driving state, thereby generating a pulse power at the power generating unit 20 by cyclically operating the cyclic key 301.

In detail, the index drive unit 302 includes an index 3021, wherein the index 3021 is coupled to the power generation unit 20 and has a first drive position 30211 and a second drive position 30212, wherein a switching of the index drive unit 302 between the first drive state and the second drive state corresponds to a driving of the index 3021 in one of the first drive position 30211 and the second drive position 30212, resulting in an actuation of the power generation unit 20, i.e. a driving of the index 3021 in one of the first drive position 30211 and the second drive position 30212 corresponds to an actuation of the power generation unit 20.

In particular, the shift element 3021 is pivotably coupled to the power generating unit 20 in order to be able to be driven in a pivoting manner to actuate the power generating unit 20, wherein two successive operating cycles of the circulation button 301 each correspond to one of the first drive position 30211 and the second drive position 30212 for driving the shift element 3021, i.e. two successive operating cycles of the circulation button 301, wherein one operating cycle corresponds to a pivoting drive of the shift element 3021 in the first drive position 30211 and the other operating cycle corresponds to a pivoting drive of the shift element 3021 in the second drive position 30212, such that a pivoting drive of the shift element 3021 in different positions results in one operating cycle of the shift element 3021 and thus of the power generating unit 20 coupled to the shift element 3021 in different positions results in a pivoting drive of the shift element 3021 in different positions.

Further, the indexing drive unit 302 further comprises a driving arm 3022, wherein the driving arm 3022 is movably disposed on the circulation button 301, wherein when the circulation button 301 is in the initial state, the driving arm 3022 is maintained in an initial direction in the first driving state and the second driving state of the indexing drive unit 302, and during the process that the circulation button 301 is pressed from the initial state to the trigger state, the driving arm 3022 can be selectively driven by the indexing member 3021 through the pivoting of the indexing member 3021 to index the indexing member 3021 at the first driving position 30211 and the second driving position 30212 respectively.

In particular, the index 3021 further has a first guide wall 302131 and a second guide wall 302132 extending from the first driving position 30211 and the second driving position 30212, respectively, wherein in the first driving state of the index driving unit 302, when the cycle key 301 is in the initial state, the first guide wall 302131 is inclined to the initial direction and corresponds to the driving arm 3022 in the initial direction, such that when the cycle key 301 is pressed from the initial state to the trigger state, the driving arm 3022 can be guided by the first guide wall 302131 to drive the index 3021 to pivot in the first driving position 30211, thereby forming the second guide wall 302132 inclined to the initial direction and corresponding to the driving arm 3022 in the initial direction after the cycle key 301 is returned to the initial state, and when the second guide wall 3022 is again driven from the initial driving state to the second driving position 3022, the driving arm 3022 can be guided to pivot again in the subsequent driving state, and when the second index key 301 is pressed from the initial state to the second driving position 3926. Thus, the index 3021 can be pivotally driven at different positions by a plurality of cycles of the cycle button 301 to form a one-cycle driving of the index 3021 by the reciprocating pivotal driving or the circumferential pivotal driving.

It should be noted that one cycle operation on the cycle key 301 corresponds to only one driving of the displacement element 3021 and one actuation of the power generation unit 20, that is, the process of returning the cycle key 301 to the initial state in the triggered state does not form the driving of the displacement element 3021 and the actuation of the power generation unit 20, so that the reset element 3011 has a smaller mechanical energy requirement in the triggered state of the cycle key 301, that is, the mechanical energy required for the cycle key 301 to be pressed from the initial state to the triggered state corresponds to only one mechanical energy required for actuating the power generation unit 20 and returning the cycle key 301, which makes the pressing of the cycle key 301 have a smaller mechanical energy requirement and is more labor-saving, thereby facilitating the operation experience of the cycle power generation device 10.

It should be understood by those skilled in the art that, in any two consecutive cyclic operations of the cyclic key 301, the cyclic decomposition device 30 of the present invention selects the shift of the driving arm 3022 by the shift 3021, so that the driving arm 3022 can drive the shift 3021 at different positions, and further decompose one cyclic drive of the shift 3021 into a plurality of cyclic operations of the cyclic key 301, so as to decompose one cyclic actuation of the power generation unit 20 coupled to the shift 3021 into a plurality of cyclic operations of the cyclic key 301.

Further, in this embodiment of the present invention, the power generating unit 20 has a first position state and a second position state, wherein one switching of the power generating unit 20 between the first position state and the second position state corresponds to one actuation of the power generating unit 20 to be able to generate one pulse power at the power generating unit 20. That is, one cycle operation of the cycle button 301, i.e., one cycle operation of the cycle decomposition device 30, corresponds to one switching of the index drive unit 302 between the first drive state and the second drive state, and corresponds to one switching of the power generation unit 20 between the first position state and the second position state.

In particular, in this embodiment of the present invention, the power generation unit 20 is configured to adopt a reciprocating pivoting actuation structure, i.e., one switching of the power generation unit 20 from the first position state to the second position state and one switching from the second position state to the first position state form one reciprocating pivoting cycle actuation of the power generation unit 20. That is, two consecutive cyclic operations of the cyclic button 301 form one reciprocating pivotal cyclic actuation of the power generation unit 20 between the first position state and the second position state.

Accordingly, in this embodiment of the present invention, the index 3021 includes a guide tooth 30213, wherein the guide tooth 30213 is disposed between the first driving position 30211 and the second driving position 30212, wherein two sides of the guide tooth 30213 corresponding to the first driving position 30211 and the second driving position 30212 are the first guide wall 302131 and the second guide wall 302132, respectively.

Further, in this embodiment of the present invention, the shift member 3021 further includes a pivot shaft 30217 and a coupling groove 30214, wherein the pivot shaft 30217 of the shift member 3021 is disposed at a position of the shift member 3021 opposite to the guide tooth 30213 and in the initial direction, wherein the power generation unit 20 is operatively coupled to the coupling groove 30214 of the shift member 3021, wherein the coupling groove 30214 is disposed at a position of the shift member 30214 corresponding to one of the first driving position 30211 and the second driving position 30212, so as to form a structural relationship that the shift member 3021 is pivotably coupled to the power generation unit 20, and further, the power generation unit 20 is actuated by the shift driving of the driving arm 3022 to the shift member 3021.

It is understood that the power generating unit 20 is coupled between the coupling groove 30214 and the index 3021 to be able to link the power generating unit 20 and the index 3021, wherein the coupling manner between the power generating unit 20 and the index 3021 may be variously modified, and the coupling manner is not limited to coupling the power generating unit 20 to the coupling groove 30214 of the index 3021 to the index 3021, and the present invention is not limited thereto.

Referring to fig. 4 and 5 of the drawings of the present specification, a schematic structural diagram of the power generating unit 20 of the cyclic power generating apparatus 10 according to this embodiment of the present invention is illustrated, wherein the power generating unit 20 includes a magnetic core 201, a coil 202, a magnet assembly 203 and a driving rod 204, wherein the coil 202 is surrounded by the magnetic core 201, wherein the magnetic core 201 is configured to be made of a magnetic conductive material and includes two end portions 2011 extending in the same direction, wherein the magnet assembly 203 includes a permanent magnet 2033, wherein a magnetic field environment is provided for the power generating unit 20 by the permanent magnet 2033, wherein the magnet assembly 203 is disposed between the two end portions 2011, wherein the driving rod 204 has the first position state and the second position state, wherein one end of the driving rod 204 is disposed on the magnet assembly 203 to toggle the other end of the driving rod 204 to form the switching of the driving rod 204 between the first position state and the second position state, so that the magnetic flux of the magnet assembly 203 is configured to change the magnetic flux of the magnetic core 201 at a time and generate a pulse of electric energy at the coil 202.

Specifically, two ends 2011 of the core 201, that is, a first end 20111 and a second end 20112, wherein the first end 20111 and the second end 20112 are disposed to extend in the same direction to the core 201, so as to increase the length of the core 201 while maintaining the first end 20111 and the second end 20112 at a suitable distance, thereby increasing the number of turns of the coil 202 while facilitating to shorten the length of the space occupied by the core 201. It can be understood that the number of turns of the coil 202 is increased, so that the power generation efficiency of the power generation unit 20 is improved.

Further, the magnet assembly 203 has a first pole end 2031 and a second pole end 2032, wherein the first end 20111 is adjacent to the first pole end 2031 and the second pole end 2032 simultaneously with respect to the first pole end 2031 and the second pole end 2032, and the second end 20112 is adjacent to the first pole end 2031 and the second pole end 2032 simultaneously with respect to the first pole end 2031 and the second pole end 2032.

In particular, the magnetic core 201 is maintained static with respect to the magnet assembly 203, such that the coil 202 looped around the magnetic core 201 can be maintained static, reducing the requirement for fatigue resistance of the coil 202, thereby enhancing the stability of the power generation unit 20. In addition, the coil 202 is kept static, so that the structural design of the power generation unit 20 does not need to reserve a movement space for the coil 202, which is beneficial to reducing the volume of the power generation unit 20. In other words, under the condition of maintaining the volume of the power generation unit 20, the coil 202 is maintained in a static state, so that the structural design of the power generation unit 20 does not need to reserve a movement space of the coil 202, which is beneficial to improving the volume ratio of the coil 202 of the power generation unit 20, and further improving the power generation efficiency of the power generation unit 20.

It can be understood that the magnet assembly 203 is configured to move between the first end 20111 and the second end 20112 to switch the core 201 between the first end 20111 and the first pole end 2031, and the second end 20112 and the second pole end 2032, i.e., to switch between the first position of the driving rod 204 and the first end 20111 and the second pole end 2032, and to switch between the second end 20112 and the first pole end 2031, i.e., to switch between the second position of the driving rod 204, so as to form a reverse switching of the magnetic field in the core 201 by the movement of the magnet assembly 203 between the first end 20111 and the second end 20112, thereby improving the power generation efficiency of the power generation unit 20.

It is understood that the first pole end 2031 and the second pole end 2032 are configured to have different magnetic pole magnetism, that is, when the first pole end 2031 is magnetic pole magnetism of S pole, the second pole end 2032 is magnetic pole magnetism of N pole, and when the first pole end 2031 is magnetic pole magnetism of N pole, the second pole end 2032 is magnetic pole magnetism of S pole, which is not limited by the present invention.

Further, in this embodiment of the present invention, the magnet assembly 203 is configured to move in a pivoting manner, specifically, the magnet assembly 203 is configured to be capable of pivoting back and forth between the first end 20111 and the second end 20112 around a point between the first pole end 2031 and the second pole end 2032, so that when the first pole end 2031 is in a position close to the first end 20111 and communicating with the first end 20111, the second pole end 2032 is in a position close to the second end 20112 and communicating with the second end 20112; when the second pole end 2032 is positioned close to the first end 20111 and in contact with the first end 20111, the first pole end 2031 is positioned close to the second end 20112 and in contact with the second end 20112. This causes a reversal of the magnetic field in the core 201 by the reciprocating rotation of the magnet assembly 203 between the first end 20111 and the second end 20112.

In particular, in this embodiment of the present invention, the power generation unit 20 further comprises at least one pivoting arm 205, wherein the pivoting arm 205 is fixed to the magnet assembly 203, wherein the magnet assembly 203 can pivot back and forth around the pivoting arm 205, wherein the driving rod 204 is disposed on the magnet assembly 203 via the pivoting arm 205, so that the pivoting arm 205 can be driven by the driving rod 204 to pivot the magnet assembly 203. That is, the drive lever 204 is provided to the pivot arm 205 so that the magnet assembly 203 can be driven by the drive lever 204 to pivot reciprocally about the pivot arm 205.

It should be noted that, in this embodiment of the present invention, the power generation unit 20 includes two pivoting arms 205, wherein the two pivoting arms 205 are symmetrically disposed on two sides of the magnet assembly 203 in a direction perpendicular to the pivoting direction of the magnet assembly 203, so that the pivoting motion of the magnet assembly 203 about the two pivoting arms 205 is more stable. In addition, the driving rod 204 is arranged to extend from the two pivoting arms 205 respectively, so that when the driving rod 204 is pulled, the force applied to the magnet assembly 203 is more uniform, and the pivoting motion can be stabilized by using the two pivoting arms 205 as axes.

Further, in this embodiment of the present invention, the power generating unit 20 further comprises a mounting base 206, wherein the magnetic core 201 is disposed on the mounting base 206, wherein the mounting base 206 is further provided with two pivoting slots 2061, wherein the pivoting arm 205 can be clamped by the pivoting slots 2061 to be pivotably clamped in the mounting base 206, such that the magnet assembly 203 is mounted on the mounting base 206 between the first end 20111 and the second end 20112 together with the magnetic core 201.

Specifically, the pivot latch 2061 is configured as a C-shape, and is left out of the opening of the C-shape, so that the pivot arm 205 can be pressed from the opening of the pivot latch 2061 to be latched to the pivot latch 2061 in a pivotable state, wherein the pivot latch 2061 is further configured to be recessed in the groove corresponding to the opening of the C-shape, so that the opening of the pivot latch 2061 is more easily pressed and expanded by the pivot arm 205, and the pivot arm 205 can be latched to the pivot latch 2061 in a pivotable state. The mounting of the magnet assembly 203 to the mounting base 206 is thus advantageously simple and quick.

It should be noted that the magnet assembly 203 further includes a magnetic conductive assembly 2034, wherein the magnetic conductive assembly 2034 is magnetically conductive to the permanent magnet 2033, so that the magnetic conductive assembly 2034 forms the first pole end 2031 and the second pole end 2032, and the magnetic conductive assembly 2034 is magnetically conductive to the permanent magnet 2033, so that the positions of the first pole end 2031 and the second pole end 2032 are matched with the movement mode of the magnet assembly 203. That is, the magnetic conductive assembly 2034 is configured to be magnetically connected to the permanent magnet 2033, so as to form a position relationship that the first end portion 20111 is close to the first magnetic pole end 2031 and the second magnetic pole end 2032 simultaneously corresponding to the first magnetic pole end 2031 and the second magnetic pole end 2032, and the second end portion 20112 is close to the first magnetic pole end 2031 and the second magnetic pole end 2032 simultaneously corresponding to the first magnetic pole end 2031 and the second magnetic pole end 2032.

Specifically, the magnetic conductive assembly 2034 includes a first magnetic conductive plate 20341 and a second magnetic conductive plate 20342, wherein the first magnetic conductive plate 20341 and the second magnetic conductive plate 20342 are respectively magnetically connected to two poles (i.e., S pole and N pole) of the permanent magnet 2033, that is, each of the two poles of the permanent magnet 2033 is magnetically connected to one of the first magnetic conductive plate 20341 and the second magnetic conductive plate 20342, so that the first magnetic conductive plate 20341 forms the first magnetic pole end 2031 simultaneously close to the first end 20111 and the second end 20112, and the second magnetic pole end 2032 forms the second magnetic pole end 20342 simultaneously close to the first end 20111 and the second end 20112, and thus the first magnetic pole end 2031 and the second magnetic pole end 2032 have different magnetic polarities.

Specifically, the first magnetic conducting plate 20341 and the second magnetic conducting plate 20342 are respectively close to the first end 20111 and the second end 20112 simultaneously, that is, the permanent magnet 2033 and the first magnetic conducting plate 20341 and the second magnetic conducting plate 20342 respectively disposed at two pole ends of the permanent magnet 2033 form the magnet assembly 203 in an "H" shape, where the left and right sides of the "H" shape are formed by the first magnetic conducting plate 20341 and the second magnetic conducting plate 20342, so that the upper and lower ends of the "H" shape are respectively close to the first end 20111 and the second end 20112, thereby forming a positional relationship that the first end 20111 and the second end 20112 are respectively close to the first pole 20111 and the second pole 20112 simultaneously.

It should be noted that in this embodiment of the present invention, in the direction perpendicular to the pivoting direction of the magnet assembly 203, the size of the first magnetic conductive plate 20341 and the second magnetic conductive plate 20342 is smaller than and close to the size of the magnetic core 201, so as to reduce the volume of the magnet assembly 203 while maintaining a larger contact area between the magnetic core 201 and the first magnetic conductive plate 20341 and the second magnetic conductive plate 20342, respectively, so that when the driving rod 204 is switched between the first position state and the second position state, the magnetic core 201 has a larger amount of change of magnetic flux, which is favorable for improving the power generation efficiency of the power generation unit 20.

In addition, the driving rod 204 extends to the magnet assembly 203, so that the stroke of the driving rod 204 swinging between the first position state and the second position state is enlarged relative to the stroke of the magnet assembly 203 rotating, that is, the pivoting motion of the magnet assembly 203 between the first end 20111 and the second end 20112 can be set to have a smaller motion stroke, which is beneficial to reducing the motion space of the magnet assembly 203, reducing the volume of the power generation unit 20, and obtaining a suitable swinging stroke of the driving rod 204 by enlarging the pivoting stroke of the magnet assembly 203 through the driving rod 204, thereby being beneficial to enhancing the operational feeling of the power generation unit 20.

It should be noted that the driving rod 204 is made of an elastic material, so as to be capable of being forcedly stored with a certain elastic potential energy and when the stored elastic potential energy reaches a certain critical value, the driving rod drives the magnet assembly 203 to pivotally switch the core 201 between a state where the first end 20111 is connected to the first pole end 2031 and the second end 20112 is connected to the second pole end 2032, and a state where the first end 20111 is connected to the second pole end 2032 and the second end 20112 is connected to the first pole end 2031.

In other words, the driving rod 204 will switch between the first position state and the second position state only when the elastic potential energy stored in the driving rod 204 reaches a certain threshold, so as to shorten the completion time of the switching action, thereby being beneficial to increasing the change rate of the magnetic flux of the coil 202, enhancing the power generation efficiency of the power generation unit 20, and making the completion time of each switching action tend to be the same, thereby being beneficial to enhancing the stability of the power generation efficiency of the power generation unit 20.

In this way, the driving rod 204 is inserted into the coupling slot 30214 to form a structural relationship that the power generating unit 20 is operatively coupled to the displacement member 3021, so that the power generating unit 20 is driven by the driving arm 3022 to perform a displacement driving operation on the displacement member 3021.

Specifically, in this embodiment of the present invention, the coupling groove 30214 is configured to be suitable for the driving rod 204 of the power generating unit 20 to be inserted into the coupling groove 30214 in a direction perpendicular to the index 3021 to form a structural relationship that the power generating unit 20 is operatively coupled to the index 3021, wherein the coupling manner between the power generating unit 20 and the index 3021 may be varied in many ways, and is not limited to the driving rod 204 being inserted into the coupling groove 30214 in a direction perpendicular to the index 3021, which is not limited by the present invention.

It is worth mentioning that in this embodiment of the present invention, the index member 3021 is further provided with a first limit tooth 30215 and a second limit tooth 30216, wherein the guide tooth 30213 is disposed between the first limit tooth 30215 and the second limit tooth 30216 to form the first driving position 30211 and the second driving position 30212 between the first limit tooth 30215 and the guide tooth 30213 and between the second limit tooth 30216 and the guide tooth 30213, respectively, so that the driving arm 3022 is restricted from leaving the first driving position 30211 by the first limit tooth 30215 when the driving arm 3022 drives the index member 3021 at the first driving position 30211, and the driving arm 3022 is restricted from leaving the second driving position 30212 by the second limit tooth 30216 when the driving arm 3022 drives the index member 3021 at the second driving position 30212.

Further, in this embodiment of the present invention, the indexing drive unit 302 further comprises a guide 3023, wherein the guide 3023 is provided with a guide groove 30231, wherein the guide groove 30231 is configured to guide the drive arm 3022 to return to the state of being maintained in the initial direction when the circulation key 301 returns from the activated state to the initial state.

Specifically, in this embodiment of the present invention, the driving arm 3022 has a driving end 30221, wherein the driving arm 3022 has an end opposite to the driving end 30221 pivotally arranged on the circulation key 301 to drive the index member 3021 at the driving end 30211, wherein the driving end 30221 is extended into the guiding groove 30231 to limit or guide the movement of the driving end 30221 of the driving arm 3022 through the guiding groove 30231.

It will be appreciated that the guide slot 30231 is configured and adapted to restrict movement of the driving end 30221 of the drive arm 3022 such that when the guide slot 30231 has a suitable shape and size, the first and second limiting teeth 30215 and 30216 may not be provided and are capable of restricting the driving end 30221 of the drive arm 3022 from driving the index member 3021 at a corresponding one of the first and second driving positions 30211 and 30212 during depression of the cycle key 301 from the initial state to the activated state, although the invention is not limited thereto.

To further describe the cyclic decomposition method of the cyclic power generation facility 10 according to this embodiment of the present invention, the schematic structural diagram of the cyclic decomposition facility 30 in different states is illustrated with reference to fig. 6A to 6D of the drawings attached to the present specification.

As shown in fig. 6A, in the first driving state of the index driving unit 302, when the circulation key 301 is in the initial state, the guide teeth 30213 are inclined to the initial direction, and the driving arm 3022 corresponds to the first guide wall 302131 of the guide teeth 30213 in the initial direction.

In this way, when the circulation button 301 is pressed from the initial state to the activated state, the driving arm 3022 is guided by the first guide wall 302131 to drive the index 3021 to pivotally actuate the power generation unit 20 once at the first driving position 30211, and a state is formed in which the guide tooth 30213 is inclined to the initial direction and the second guide wall 302132 corresponds to the initial direction, as shown in fig. 6B.

Further, after the circulation button 301 is returned to the initial state from the triggered state by the reset element 3011, the driving arm 3022 is maintained in the initial direction to form a state where the driving arm 3022 corresponds to the second guiding wall 302132 of the guiding tooth 30213 in the initial direction, i.e., the second driving state of the index driving unit 302, as shown in fig. 6C.

Further, when the circulation button 301 is pressed again from the initial state to the activated state, the driving arm 3022 is guided by the second guiding wall 302132 to drive the index 3021 to pivotally move back to the power generating unit 20 once at the second driving position 30212, and a state is formed in which the guiding tooth 30213 is inclined to the initial direction and the first guiding wall 302131 corresponds to the initial direction, as shown in fig. 6D.

Thus, when the circulation button 301 returns from the activated state to the initial state, the first driving state is formed again, in which the guide teeth 30213 are inclined to the initial direction, and the driving arm 3022 corresponds to the first guide wall 302131 of the guide teeth 30213 in the initial direction, as shown in fig. 6A.

It should be understood by those skilled in the art that when the power generation unit 20 is configured to adopt a rotary type pivot actuating structure, that is, the power generation unit 20 can be rotated in one direction for a circle to form multiple times of switching between the first position state and the second position state. Accordingly, the shift element 3021 may be configured as a gear, wherein each tooth of the gear-shaped shift element 3021 is the guide tooth 30213, wherein a tooth space is formed between any two adjacent guide teeth 30213, wherein any two adjacent tooth spaces are the first driving position 30211 and the second driving position 30212, respectively, and wherein the first guide wall 302131 and the second guide wall 302132 extend in the same direction in the corresponding tooth space, respectively, i.e., the first guide wall 302131 and the second guide wall 302132 are sidewalls of any two adjacent guide teeth 30213 in the same direction, so as to form a pivot driving of one circle of the shift element 3021 through a plurality of cycles of the number of the cycle keys 301 corresponding to the tooth space, which is not limited by the present invention.

Thus, the present invention also provides a cyclic decomposition method of the cyclic power generation device 10, comprising the steps of:

a. in the initial state of the circulation button 301, the first guide wall 302131 of the index member 3021 is formed in the initial direction of the driving arm 3022 to correspond to and be inclined with respect to the driving arm 3022, i.e., the first driving state of the index driving unit 302;

b. during the process that the circulation button 301 is pressed from the initial state to the trigger state, the circulation button 301 actuates the driving arm 3022 so that the driving arm 3022 drives the index 3021 at the first driving position 30211 guided by the first guiding wall 302131, so as to form a state that the second guiding wall 302132 of the index 3021 corresponds to and is inclined to the initial direction;

c. in the process of returning the circulation button 301 from the triggered state to the initial state, the driving arm 3022 is maintained in the initial direction by the guide 3023, so as to form a state where the second guide wall 302132 of the index member 3021 corresponds to and is inclined to the driving arm 3022, i.e., the second driving state of the index driving unit 302.

In particular, in this embodiment of the present invention, the cycle decomposition method of the cycle power generation device 10 further includes the steps of:

d. during the process that the circulation button 301 is pressed from the initial state to the trigger state, the circulation button 301 actuates the driving arm 3022 so that the driving arm 3022 drives the index 3021 at the second driving position 30212 guided by the second guiding wall 302132, so as to form a state that the first guiding wall 302131 of the index 3021 corresponds to and is inclined to the initial direction;

e. in the process of returning the circulation button 301 from the triggered state to the initial state, the driving arm 3022 is maintained in the initial direction by the guide 3023, so as to form a state where the first guide wall 302131 of the index member 3021 corresponds to and is inclined to the driving arm 3022, i.e., the first driving state of the index driving unit 302.

In this way, the index 3021 is driven at different positions by two consecutive cyclic operations of the cyclic key 301, so that one cyclic drive of the index 3021, corresponding to one cyclic operation of the power generation unit 20, is divided into two cyclic operations of the cyclic key 301.

To further describe the cyclic power generation apparatus 10 of the present invention, referring to fig. 7 and 8 of the drawings of the specification of the present invention, the cyclic power generation apparatus 10A according to a modified embodiment of the above-mentioned embodiment of the present invention is illustrated, wherein the cyclic power generation apparatus 10A includes a power generation unit 20A and a cyclic decomposition device 30A, wherein the cyclic decomposition device 30A is operably coupled to the power generation unit 20A, wherein the power generation unit 20A is configured to be capable of generating a pulse power once, wherein the cyclic power generation apparatus 10A is configured to provide a power output with a single pulse power, thereby avoiding integration of multiple pulses and facilitating simplification of a circuit structure of the cyclic power generation apparatus 10A, and simultaneously facilitating reduction of a circuit loss of the cyclic power generation apparatus 10A, thereby improving an efficiency of the cyclic power generation apparatus 10A.

Further, the circulation decomposition device 30A is configured to be capable of being operated by one-time circulation operation to actuate the power generation unit 20A, that is, one-time circulation operation to the circulation decomposition device 30A corresponds to one-time actuation to the power generation unit 20A, so as to be capable of decomposing one-time circulation operation to the power generation unit 20A into multiple-time circulation operation to the circulation decomposition device 30A, thereby reducing the mechanical energy requirement for one-time circulation operation of the circulation decomposition device 30A, and being beneficial to reducing the strength of word circulation operation to the circulation decomposition device 30A and improving the operation experience of the circulation power generation device 10A.

Specifically, the cyclic decomposition device 30A includes a cyclic key 301A and an index driving unit 302A, wherein the cyclic key 301A has an initial state and a trigger state and is provided with a reset element 3011A, wherein when the cyclic key 301A is in the trigger state by being pressed by an external force in the initial state, the cyclic key 301A can be restored to the initial state by the reset element 3011A after the external force is released, wherein the index driving unit 302A is operably coupled between the cyclic key 301A and the power generating unit 20A and has a first driving state and a second driving state, wherein the index driving unit 302A is adapted to be driven by the cyclic key 301A to complete a switching between the first driving state and the second driving state when the cyclic key 301A is switched from the initial state to the trigger state, so as to perform a switching between the first position state and the second position state by a switching operation of the cyclic key 301A between the first driving state and the second driving state, so that the index driving unit 302A is coupled with the power generating unit 302A in the first position and the second position state by switching of the cyclic key 302A.

Further, the index driving unit 302A includes a driving arm 3022A and an index 3021A, wherein the driving arm 3022A is disposed on the rotation key 301A, and the driving arm 3022A is maintained in an initial direction when the rotation key 301A is in the initial state, wherein the index 3021A has a first driving position 30211A and a second driving position 30212A, and a first guiding wall 302131A and a second guiding wall 302132A respectively extending from the first driving position 30211A and the second driving position 30212A, wherein in the first driving state of the index driving unit 302A, when the rotation key 301A is in the initial state, the first guiding wall 302131A is inclined to the initial direction and corresponds to the driving arm 3022A in the initial direction, so that the driving arm 3022A can be guided by the first guiding wall 302131A to drive the index 3021A at the first driving position 30211A during the pressing of the circulation button 301A from the initial state to the activated state, thereby forming the second driving state in which the second guiding wall 302132A is inclined to the initial direction and corresponds to the driving arm 3022A at the initial direction after the circulation button 301A is returned to the initial state, and subsequently, the driving arm 3022A can be guided by the second guiding wall 302132A to drive the index 3021A at the second driving position 30211A during the pressing of the circulation button 301A from the initial state to the activated state again.

That is, the circulation key 301A can be operated to drive the transposition driving unit 302A to switch between the first driving state and the second driving state once, so as to operate the power generating unit 20A coupled to the transposition driving unit 302A once by switching the transposition driving unit 302A between the first driving state and the second driving state once, thereby generating a pulse power at the power generating unit 20A once by operating the circulation key 301A once.

Further, the index 3021A is pivotably coupled to the power generating unit 20A in order to be able to be driven in a pivoting manner to actuate the power generating unit 20A, wherein two successive loop operations of the loop button 301A each drive the index 3021A in one of the first drive position 30211A and the second drive position 30212A, i.e. two successive loop operations of the loop button 301A, one of which corresponds to the pivoting drive of the index 3021A in the first drive position 30211A and the other corresponds to the pivoting drive of the index 3021A in the second drive position 30212A, in such a way that the index 3021A can be driven in a pivoting manner in different positions to form a single loop drive of the index 3021A, and the index 3021A can be driven in a pivoting manner to form a single loop actuation of the power generating unit 20A coupled to the index 3021A in different positions.

Similarly, the power generating unit 20A has a first position state and a second position state, wherein a switch of the power generating unit 20A between the first position state and the second position state corresponds to an actuation of the power generating unit 20A to generate a pulse power at the power generating unit 20A. That is, one cycle operation of the cycle key 301A, i.e., one cycle operation of the cycle decomposition device 30A, corresponds to one switching of the transposition drive unit 302A between the first drive state and the second drive state, and corresponds to one switching of the power generation unit 20A between the first position state and the second position state.

In particular, in this modified embodiment of the present invention, the power generation unit 20A is configured to adopt a reciprocating pivoting actuation structure and includes a driving rod 204A, wherein the driving rod 204A is configured to be capable of reciprocating pivoting around a shaft in the middle of the driving rod 204A to form the switching between the first position state and the second position state.

Accordingly, the shift 3021A further comprises a pivot 30217A, a first abutting portion 30218A and a second abutting portion 30219A, wherein the pivot 30217A of the shift 3021A is disposed at a position of the shift 3021A opposite to the guide tooth 30213A and in the initial direction, wherein two ends of the driving rod 204A abut against the first abutting portion 30218A and the second abutting portion 30219A, respectively, so as to form a structural relationship that the shift 3021A is pivotably coupled to the power generation unit 20A, and the power generation unit 20A is actuated by the shift driving of the driving arm 3022A to the shift 3021A.

It should be understood that, when the two ends of the driving rod 204A are respectively embedded in the first abutting portion 30218A and the second abutting portion 30219A, the axis of the driving rod 204A is the pivot axis 30217A of the displacement member 3021A, i.e. the pivot axis 30217A is not physically disposed on the displacement member 3021A, which is not limited by the invention.

Further, in this modified embodiment of the present invention, the index 3021A includes a guide tooth 30213A, wherein the guide tooth 30213A is disposed between the first driving position 30211A and the second driving position 30212A, wherein two sides of the guide tooth 30213A corresponding to the first driving position 30211A and the second driving position 30212A are the first guide wall 302131A and the second guide wall 302132A, respectively.

In this way, in the first driving state of the index driving unit 302A, when the circulation key 301A is in the initial state, the guide tooth 30213A is inclined to the initial direction in which the driving arm 3022A corresponds to the first guide wall 302131A of the guide tooth 30213A. When the circulation button 301A is pressed from the initial state to the activated state, the driving arm 3022A is guided by the first guide wall 302131A to drive the index 3021A to pivotally actuate the power generation unit 20A once at the first driving position 30211A, and a state is formed in which the guide teeth 30213A are inclined to the initial direction and the second guide wall 302132A corresponds to the initial direction. Further, when the circulation button 301A is returned to the initial state from the triggered state by the reset element 3011A, the driving arm 3022A is maintained in the initial direction to form a state where the driving arm 3022A corresponds to the second guide wall 302132A of the guide tooth 30213A in the initial direction, i.e., the second driving state of the index driving unit 302A. So that, subsequently, when the circulation button 301A is pressed again from the initial state to the activated state, the driving arm 3022A is guided by the second guide wall 302132A to drive the index 3021A to pivotally reverse the power generation unit 20A once at the second driving position 30212A, and a state is formed in which the guide tooth 30213A is inclined to the initial direction and the first guide wall 302131A corresponds to the initial direction. So that the first driving state in which the guide teeth 30213A are inclined to the initial direction and the driving arm 3022A corresponds to the first guide wall 302131A of the guide teeth 30213A in the initial direction is formed again after the circulation key 301A returns from the activated state to the initial state.

It is worth mentioning that in this variant of the invention, the index 3021A is further provided with a first limit tooth 30215A and a second limit tooth 30216A, wherein the guide tooth 30213A is arranged between the first limit tooth 30215A and the second limit tooth 30216A to form the first driving position 30211A and the second driving position 30212A between the first limit tooth 30215A and the guide tooth 30213A and between the first limit tooth 30216A and the guide tooth 30213A, respectively, so that the driving arm 3022A is restricted from leaving the first driving position 30211A by the first limit tooth 30215A when the driving arm 3022A drives the index 3021A in the first driving position 30211A, and the driving arm 3022A is restricted from leaving the second driving position 30212A by the second limit tooth 30216A when the driving arm 3022A drives the index 3021A in the second driving position 30212A.

Further, in this modified embodiment of the present invention, the indexing drive unit 302A further comprises a guide 3023A, wherein the guide 3023A is provided with a guide groove 30231A, wherein the guide 30231A is configured to guide the drive arm 3022A to return to the state of being maintained in the initial direction when the circulation key 301A returns from the activated state to the initial state.

Specifically, in this modified embodiment of the present invention, the driving arm 3022A has a driving end 30221A, wherein an end of the driving arm 3022A opposite to the driving end 30221A is pivotably provided to the circulation key 301A to be able to drive the index member 3021A at the driving end 30211A, wherein the driving end 30221A is inserted into the guide groove 30231A so as to be able to restrict or guide the movement of the driving end 30221A of the driving arm 3022A through the guide groove 30231A.

It is understood that the guiding slot 30231A is configured to limit the movement of the driving end 30221A of the driving arm 3022A, such that when the guiding slot 30231A has a suitable shape and size, the first and second limiting teeth 30215A and 30216A may not be provided, and the driving end 30221A of the driving arm 3022A can be limited to drive the index member 3021A at a corresponding position of the first and second driving positions 30211A and 30212A by the guiding slot 30231A during the pressing of the circulation key 301A from the initial state to the activated state, which is not limited by the present invention.

It should be understood by those skilled in the art that, in any two consecutive cyclic operations of the cyclic button 301A, the cyclic decomposition device 30A of the present invention selects the position of the driving arm 3022A by the position-changing member 3021A, so that the driving arm 3022A can drive the position-changing member 3021A at different positions, and thus, one cyclic driving of the position-changing member 3021A is decomposed into a plurality of cyclic operations of the cyclic button 301A, so that one cyclic operation of the power generation unit 20A coupled to the position-changing member 3021A is decomposed into a plurality of cyclic operations of the cyclic button 301A.

Therefore, in some embodiments of the present invention, when the power generation unit 20A is configured to adopt a rotary type pivot actuation structure, that is, the power generation unit 20A can be switched between the first position state and the second position state a plurality of times in a single rotation. Accordingly, the shift element 3021A may be provided as a gear, wherein each tooth of the gear-shaped shift element 3021A is the guide tooth 30213A, wherein a tooth space is formed between any two adjacent guide teeth 30213A, wherein any two adjacent tooth spaces are the first driving position 30211A and the second driving position 30212A, respectively, wherein the first guide wall 302131A and the second guide wall 302132A extend in the same direction to the corresponding tooth space, respectively, i.e., the first guide wall 302131A and the second guide wall 302132A are the same-direction side walls of any two adjacent guide teeth 30213A, so as to form a pivoting action on one circle of the shift element 3021A through a plurality of cycles corresponding to the number of tooth spaces of the cycle key 301A.

It is to be understood that the first, second, third and fourth are used herein only to describe the nomenclature of the various components (or elements) of the invention and to distinguish between the various components, elements and structures of the invention. Unless otherwise indicated, it does not have an ordinal or numerical meaning by itself.

It will be appreciated by persons skilled in the art that the above embodiments are only examples, wherein features of different embodiments may be combined with each other to obtain embodiments which are easily conceivable in accordance with the disclosure of the invention, but which are not explicitly indicated in the drawings.

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 embodiments, and any variations or modifications may be made to the embodiments of the present invention without departing from the principles described.

Claims (30)

1. A cyclic power generation device, applied to a passive wireless switch and comprising a power generation unit and a cyclic decomposition device, wherein the power generation unit is configured to be actuated once to generate a pulse of power, wherein the cyclic decomposition device is operably coupled to the power generation unit and configured to be operated once per cycle to actuate the power generation unit once, such that the cyclic power generation device is capable of providing a power output in a single pulse of power;

wherein the power generating unit has a first position state and a second position state, wherein a switching of the power generating unit between the first position state and the second position state is capable of generating a pulse of electrical energy, wherein an actuation of the power generating unit corresponds to a switching of the power generating unit between the first position state and the second position state;

wherein the cyclic decomposition device comprises a cyclic key, wherein the cyclic key has an initial state and a trigger state, and wherein the cyclic key is switched from the initial state to the trigger state corresponding to one actuation of the power generation unit to form one switching of the power generation unit between the first position state and the second position state;

the circulating key can be restored to the initial state by the reset element after the external force is removed, so that one circulating operation on the circulating key can be formed by one action;

when the circulating key returns to the initial state and is switched to the triggering state again, the reset element only resets the circulating key and does not reset the transposition driving unit, the transposition driving unit drives the driving rod to move reversely, so that the power generation unit generates an action again to convert the mechanical energy generated by the movement of the driving rod into the single pulse electrical energy, and under the action of pressing the circulating key again, the transposition driving unit is reset, so that the driving rod is reset.

2. The cyclic power generation device of claim 1, wherein the return element is configured as a compression spring, a torsion spring, or an elastic rubber.

3. The cyclic power generation device of claim 1, wherein the transposition drive unit is operably coupled between the cyclic key and the power generation unit, wherein the transposition drive unit has a first drive state and a second drive state, wherein a cyclic operation of the cyclic key corresponds to a switching of the transposition drive unit between the first drive state and the second drive state to actuate the power generation unit coupled to the transposition drive unit once by a switching of the transposition drive unit between the first drive state and the second drive state, thereby generating a pulse of power at the power generation unit once cyclically operating the cyclic key.

4. The cyclic power generation device of claim 3, wherein the index drive unit comprises an index member, wherein the index member is coupled to the power generation unit and has a first drive position and a second drive position, wherein a switch of the index drive unit between the first drive state and the second drive state corresponds to driving the index member in one of the first drive position and the second drive position to provide an actuation of the power generation unit.

5. The cyclic power generation device of claim 4, wherein the index member is pivotably coupled to the power generation unit to be capable of being pivotably driven to actuate the power generation unit, wherein two cyclic operations adjacent to the cyclic key drive the index member corresponding to one of the first drive position and the second drive position, respectively, such that pivoting the index member at different positions forms one cyclic drive of the index member, and such that pivoting the index member at different positions forms one cyclic actuation of the power generation unit coupled to the index member.

6. The cyclic power generation device of claim 5, wherein the indexing drive unit further comprises a drive arm, wherein the drive arm is movably disposed on the cyclic key, wherein the drive arm is maintained in an initial orientation when the cyclic key is in the initial state, and the drive arm can be indexed by the indexing member to selectively drive the indexing member in the first drive position and the second drive position respectively due to the pivoting of the indexing member during the switching of the cyclic key from the initial state to the trigger state.

7. The cycle power generating apparatus according to claim 6, wherein the index driving unit further comprises a guide member, wherein the guide member is provided with a guide slot, wherein the guide slot is configured to guide the driving arm to return to the state maintained in the initial direction when the cycle key returns from the activated state to the initial state.

8. The cycle power unit according to claim 7, wherein the drive arm has a drive end, wherein an end of the drive arm opposite the drive end is pivotably disposed at the cycle key to enable the index member to be driven at the drive end, wherein the drive end extends into the guide slot, wherein the guide slot is configured to limit movement of the drive end of the drive arm.

9. The cyclic power generation device of claim 6, wherein the index member further has a first guide wall and a second guide wall extending from the first driving position and the second driving position, respectively, wherein in the first driving state of the index driving unit, the first guide wall is inclined to the initial direction and corresponds to the driving arm in the initial direction when the cyclic key is in the initial state, so that the driving arm can be guided by the first guide wall to drive the index member to pivot in the first driving position during switching of the cyclic key from the initial state to the trigger state, thereby forming the second guide wall inclined to the initial direction and corresponding to the driving arm in the initial direction after the cyclic key returns to the initial state, and further wherein subsequently, during pressing of the cyclic key again from the initial state to the trigger state, the driving arm can be guided by the second guide wall to drive the index member to pivot in the second driving position.

10. The cyclic power generation device of claim 9, wherein the index member comprises a guide tooth, wherein the guide tooth is disposed between the first driving position and the second driving position, such that a side of the guide tooth corresponding to the first driving position forms the first guide wall, and a side of the guide tooth corresponding to the second driving position forms the second guide wall, such that in the second driving state of the index driving unit, when the cyclic key is pressed from the initial state to the trigger state, the driving arm is guided by the second guide wall to drive the reverse pivoting of the index member in the second driving position, and further, after the cyclic key is returned to the initial state, the index driving unit can be returned to the first driving state in which the first guide wall is inclined to the initial direction and corresponds to the driving arm in the initial direction, so as to resolve one reciprocating cyclic driving of the index member into two cyclic operations adjacent to the cyclic key.

11. The cyclic power generation device of claim 10 wherein the index member is further provided with a first index tooth and a second index tooth, wherein the guide tooth is disposed between the first index tooth and the second index tooth to establish the first drive position and the second drive position between the first index tooth and the guide tooth and between the second index tooth and the guide tooth, respectively.

12. The cycle power unit according to claim 11, wherein the first limit tooth is configured to limit the drive arm from disengaging the first drive position when the drive arm drives the index member in the first drive position, and wherein the second limit tooth is configured to limit the drive arm from disengaging the second drive position when the drive arm drives the index member in the second drive position.

13. The cyclic power generation device of claim 12, wherein the index member further comprises a pivot shaft and a coupling groove, wherein the pivot shaft is disposed at a position opposite to the guide tooth of the index member and in the initial direction, wherein the power generation unit is operatively coupled to the index member at the coupling groove, wherein the coupling groove is disposed at a position of the index member corresponding to one of the first driving position and the second driving position, such that a state in which the index member is pivotably coupled to the power generation unit is formed.

14. The cyclic power generation device according to any one of claims 1 to 13, wherein the power generation unit comprises a magnetic core, a coil, and a magnet assembly, wherein the coil is wound around the magnetic core, wherein the magnetic core is configured to be made of a magnetically conductive material and comprises two end portions extending in the same direction, wherein the magnet assembly is disposed between the two end portions, wherein one end of the driving rod is disposed on the magnet assembly so as to toggle the other end of the driving rod to form a switching of the power generation unit between the first position state and the second position state, thereby forming a change in magnetic flux of the magnetic core to generate a pulse of power at the coil upon actuation of the magnet assembly.

15. The cyclic power generation device of claim 14, wherein the magnetic core is maintained in a static state to enable an increase in a volume fraction of the coil to the power generation unit, thereby increasing a power generation efficiency of the power generation unit.

16. The cyclic power generation device of claim 15, wherein the ends of the magnetic core are a first end and a second end, wherein the magnet assembly has a first pole end and a second pole end, wherein the second pole end is connected to the second end when the first pole end is connected to the first end and the second pole end is connected to the first end when the first pole end is connected to the second end.

17. The cycle power unit of claim 16, wherein the magnet assembly is further configured to pivotally move about a point between the first pole end and the second pole end such that when the first pole end is in the position in communication with the first end portion, the second pole end is in the position in communication with the second end portion, and when the second pole end is in the position in communication with the first end portion, the first pole end is in the position in communication with the second end portion.

18. The cyclic power generation device of claim 17, wherein the magnet assembly comprises a magnetically conductive assembly and a permanent magnet, wherein the magnetically conductive assembly is magnetically coupled to the permanent magnet to form the first and second pole ends from the magnetically conductive assembly, and wherein the magnetically conductive assembly is magnetically coupled to the permanent magnet to form the positional relationship of the first and second pole ends between the first and second ends, respectively, proximate the first and second ends simultaneously.

19. The cycle power unit of claim 18, wherein the magnetic conductive assembly comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein the first magnetic conductive plate and the second magnetic conductive plate are magnetically coupled to the two poles of the permanent magnet, respectively, to form the first pole end on the first magnetic conductive plate and the second pole end on the second magnetic conductive plate.

20. The cycle power generating device according to claim 19, wherein the permanent magnet and the first magnetic conductive plate and the second magnetic conductive plate respectively disposed at two magnetic pole ends of the permanent magnet form an "H" shaped magnet assembly, wherein left and right sides of the "H" shape are formed by the first magnetic conductive plate and the second magnetic conductive plate, wherein upper and lower ends of the "H" shape are respectively close to the first end portion and the second end portion, so as to form a position relationship in which the first end portion is simultaneously close to the first magnetic pole end and the second magnetic pole end, and the second end portion is also simultaneously close to the first magnetic pole end and the second magnetic pole end.

21. The hydrokinetic electrical generating device of claim 20, wherein the drive rod is configured to be made of an elastic material.

22. The cyclic power generation device of claim 20, wherein the power generation unit further comprises two pivoting arms, wherein the two pivoting arms are symmetrically disposed on both sides of the magnet assembly in a direction perpendicular to the pivoting direction of the magnet assembly, so that the magnet assembly can be pivotally actuated with the two pivoting arms as a shaft.

23. The cycle power unit of claim 22, wherein the drive rods are configured to extend from the two drive arms, respectively, such that the arrangement of the drive rods to the magnet assembly is formed by the two drive arms.

24. The cyclic power generation device of claim 23, wherein the power generation unit further comprises a mounting base, wherein the magnetic core is disposed on the mounting base, wherein the mounting base is disposed with two pivot slots, wherein the pivot arm can be clamped by the pivot slots to be pivotably snapped into the mounting base, such that the magnet assembly can be pivotably mounted to the mounting base between the first end and the second end.

25. The cyclic power generation device of claim 24, wherein the pivot slot is configured in a "C" shape and is skimmed off an opening of the "C" shape, so that the pivot arm can be pressed from the opening of the pivot slot to be pivotably engaged with the pivot slot.

26. The cycle power unit of claim 25, wherein the pivot slot is further configured to be recessed at a slot corresponding to the opening of the "C" shape, such that the opening of the pivot slot is more easily squeezed and expanded by the pivot arm, thereby simplifying installation of the magnet assembly to the mounting block.

27. The cyclic power generation device of any one of claims 10 to 12, wherein the power generation unit is configured to adopt a reciprocating pivoting actuation structure, wherein the driving rod is configured to be capable of reciprocating pivoting about a shaft in the middle of the driving rod, so as to toggle the driving rod to form one switching of the power generation unit between the first position state and the second position state.

28. The cyclic power generation device of claim 27, wherein the shifting member further comprises a pivot shaft, a first abutting portion and a second abutting portion, wherein the pivot shaft of the shifting member is disposed at a position of the shifting member opposite to the guide teeth and in the initial direction, wherein two ends of the driving rod are abutted against the first abutting portion and the second abutting portion respectively to form a structural relationship that the power generation unit is operably coupled to the shifting member, and further the driving rod is actuated in a reversing manner by the driving arm to shift the driving rod by shifting the shifting member, so as to break down one reciprocating cycle of the driving rod into two adjacent cycles of the cyclic key.

29. The cyclic power generation device of claim 27, wherein the shifting element further comprises a first abutting portion and a second abutting portion, wherein two ends of the driving rod are respectively embedded in the first abutting portion and the second abutting portion to form a structural relationship that the power generation unit is operably coupled to the shifting element, and further the driving rod is actuated in a reversing manner by the shifting driving of the driving arm to the shifting element, so as to toggle one reciprocating cycle of the driving rod into two adjacent cycles of the cyclic key.

30. The cyclic power generation device according to claim 9, wherein the index member is configured as a gear and comprises a plurality of guide teeth, wherein each tooth of the gear is the guide tooth, wherein a tooth space is formed between any two adjacent guide teeth, wherein any two adjacent tooth spaces are the first driving position and the second driving position, respectively, wherein the first guide wall and the second guide wall respectively extend in the same direction in the corresponding tooth space, i.e. the first guide wall and the second guide wall are sidewalls of any two adjacent guide teeth in the same direction, so as to form a pivot driving of one circumference of the index member through a plurality of cyclic operations on the number of the cyclic keys corresponding to the tooth spaces.

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