CN111106663A

CN111106663A - Self-charging remote controller capable of timing shutdown

Info

Publication number: CN111106663A
Application number: CN202010011658.8A
Authority: CN
Inventors: 不公告发明人
Original assignee: Xinchang Vowel Electronics Co ltd
Current assignee: Xinchang Vowel Electronics Co ltd
Priority date: 2020-01-06
Filing date: 2020-01-06
Publication date: 2020-05-05

Abstract

The invention discloses a self-charging remote controller capable of timing shutdown; including the main tank body, the terminal surface is equipped with a plurality of buttons before the main tank body, the main tank incasement is equipped with the opening forward, the left side is equipped with mode switching mechanism, the downside is equipped with the meshing chamber, meshing chamber right side intercommunication is equipped with the electricity generation chamber, electricity generation chamber lower extreme wall normal running fit is connected to the first driven shaft that extends to upper and lower both sides, can accomplish the switching of charging and regularly shutting down through stirring the mode handle from top to bottom, rotates the self-charging that the remote control board can be accomplished to the runner, has reduced the subsequent use cost of remote controller, also provides a hand motion mode when watching TV simultaneously, and on the other hand is the timing mechanism energy storage through rotating the runner, adjusts the timing time through rotating the timing handle, accomplishes regularly shutting down through mechanical system, need not consider whether the TV end is from the timing shutdown function of taking, and general strong.

Description

Self-charging remote controller capable of timing shutdown

Technical Field

The invention relates to the technical field of electric switches, in particular to a self-charging remote controller capable of being turned off at regular time.

Background

The remote controller is used as an operation end for controlling equipment such as a television and a projector, the electricity consumption is low, but most of the existing remote controllers still use batteries for supplying power, the use cost of the remote controller is increased, meanwhile, the discarded batteries can cause adverse effects on the environment, on the other hand, most of the existing remote controllers and televisions do not have a timing power-off function, modern people are used to turn on the television before sleeping, and if the remote controllers are forgotten to be turned off when the television falls asleep, the power is wasted, and meanwhile, the sleep quality is also affected.

Disclosure of Invention

Aiming at the technical defects, the invention provides a self-charging remote controller capable of being turned off at fixed time, which can overcome the defects.

The invention relates to a self-charging remote controller capable of being turned off at fixed time, which comprises a main body box, wherein a plurality of keys are arranged on the front end surface of the main body box, the main body box is provided with a forward opening, the left side of the main body box is provided with a mode switching mechanism, the lower side of the main body box is provided with a meshing cavity, the right side of the meshing cavity is communicated with a power generation cavity, the lower end wall of the power generation cavity is connected with a first driven shaft which extends upwards and downwards in a matched manner, the lower end surface of the first driven shaft is fixedly connected with a power generator which is positioned in the main body box and positioned at the lower side of the power generation cavity, a first gear which is fixedly connected with the upper end of the first driven shaft and extends leftwards into the meshing cavity is arranged in the power generation cavity, a spline shaft is connected in a rotated and matched, the meshing intracavity be equipped with the terminal fixed connection of initiative pivot downside and can with first gear engagement's second gear, be equipped with in with initiative pivot fixed connection just extends to external gyro wheel forward meshing chamber left side intercommunication is equipped with and is located the timing power chamber of electricity generation chamber upside, timing power chamber downside is equipped with the timing regulation chamber, timing regulation chamber downside is equipped with the bevel gear chamber, bevel gear chamber downside intercommunication is equipped with the rack chamber, rack chamber downside is equipped with timing shutdown mechanism.

On the basis of the technical scheme, the mode switching mechanism comprises a connecting rod lifting cavity, the connecting rod lifting cavity is positioned on the left side, the connecting rod lifting cavity is communicated with the communication right and the outside leftwards, a rotating disc which is connected with the driving rotating shaft in a rotating matching manner and positioned on the upper side of the roller is arranged in the connecting rod lifting cavity, a first compression spring which extends leftwards into the connecting rod lifting cavity is fixedly connected to the rotating disc, a limiting block moving cavity is arranged on the rear side of the connecting rod lifting cavity in a communicating manner, limiting cavities are symmetrically communicated with the front side of the limiting block moving cavity up and down and are communicated with the connecting rod lifting cavity forwards, a mode connecting rod which extends leftwards into the outside is arranged in the connecting rod lifting cavity, a connecting rod sliding cavity with a right opening is arranged in the mode connecting rod, the connecting rod sliding cavity is connected with the rotating disc in a sliding matching manner, and a first compression spring is fixedly connected between the left, the rear end face of the mode connecting rod is fixedly connected with a connecting rod limiting block which extends backwards into the limiting cavity, and the tail end of the left side of the mode connecting rod is fixedly connected with a mode grip.

On the basis of the technical scheme, the timing power cavity comprises a second driven shaft, the second driven shaft is located in the timing power cavity and is connected with the lower end wall of the timing power cavity in a rotating fit mode, the second driven shaft extends upwards into the timing power cavity and extends downwards to penetrate through the timing adjusting cavity to the bevel gear cavity, a one-way bearing fixedly connected with the tail end of the upper side of the second driven shaft is arranged in the timing power cavity, a third gear capable of being meshed with the second gear is connected to the one-way bearing in a rotating fit mode, and a spiral spring is fixedly connected between the upper end face of the second driven shaft and the upper end wall of the timing power cavity.

On the basis of the technical scheme, the timing adjusting cavity comprises an articulated rod, the articulated rod is positioned at the rear side of the second driven shaft and is articulated with the left end wall of the timing adjusting cavity, the right end of the front end surface of the articulated rod is fixedly connected with a friction block which can be abutted against the second driven shaft, the rear side of the timing adjusting cavity is communicated with a sliding block cavity, the rear side of the sliding block cavity is communicated with a connecting block cavity with a left opening, the sliding block cavity is connected with a sliding block in a sliding fit manner, the front end surface of the sliding block is fixedly connected with a second compression spring, the other end of the second compression spring is abutted against the rear end surface of the articulated rod, the rear end surface of the sliding block is fixedly connected with a connecting block which extends backwards into the connecting block cavity, the left end surface of the connecting block is fixedly connected with a sleeve, the timing rotating shaft is fixedly connected with a timing handle at the left end.

On the basis of the technical scheme, the bevel gear cavity comprises a third driven shaft, the third driven shaft is connected with the rear end wall of the bevel gear cavity in a rotating fit mode and extends forwards to the bevel gear cavity, a first bevel gear fixedly connected with the front end of the third driven shaft is arranged in the bevel gear cavity, a second bevel gear fixedly connected with the tail end of the lower side of the second driven shaft is further arranged in the bevel gear cavity, and the second bevel gear is meshed with the first bevel gear.

On the basis of the technical scheme, the rack cavity comprises a rack, the rack is connected with the rack cavity in a sliding fit manner and meshed with the first bevel gear, the left side and the right side of the rack are symmetrically communicated with a trigger block cavity, the trigger block cavity is connected with a trigger block in a sliding fit manner, the right side of the left end face of the trigger block is fixedly connected with a contact switch, and a third compression spring is fixedly connected between the left end face of the rack and the left end wall of the rack cavity.

On the basis of the technical scheme, the timing shutdown mechanism comprises an upper communicating cavity and a lower communicating cavity, the upper communicating cavity and the lower communicating cavity are located on the lower side of the trigger block cavity and are communicated with the trigger block cavity, the upper communicating cavity and the lower communicating cavity are communicated with each other and are arranged in a left-right mode, the lower end face of the trigger block is fixedly connected with upper connecting rods, the lower connecting rods extend downwards and penetrate through the upper communicating cavity and the lower connecting rods in the left-right communicating cavity from top to bottom to prime numbers, the upper connecting rods and the lower connecting rods are fixedly connected with left-right end faces of the upper connecting rods and lower.

The invention has the beneficial effects that: can accomplish the switching of charging and timing shutdown through stirring the mode handle from top to bottom, rotate the runner and can accomplish the self-charging of remote control board, reduced the subsequent use cost of remote controller, also provide a hand motion mode when watching TV simultaneously, on the other hand, be the timing mechanism energy storage through rotating the runner, adjust the timing time through rotating timing handle, accomplish timing shutdown through mechanical system, need not consider whether the TV end is from taking the timing shutdown function, the universality is strong.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a self-charging remote controller capable of being turned off at regular time according to the present invention;

FIG. 2 is a schematic sectional view taken along the line A-A in FIG. 1;

FIG. 3 is a schematic sectional view taken along line B-B in FIG. 1;

FIG. 4 is a front view of the present invention;

fig. 5 is an enlarged schematic view of the structure at C in fig. 1.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

As shown in fig. 1-4, the self-charging remote controller capable of timing shutdown of the apparatus of the present invention comprises a main body box 10, a plurality of keys 55 are disposed on a front end surface of the main body box 10, a forward opening 13 is disposed in the main body box 10, a mode switching mechanism is disposed on a left side of the 13, a meshing cavity 15 is disposed on a lower side of the 13, a power generation cavity 17 is communicated with a right side of the meshing cavity 15, a first driven shaft 18 extending upward and downward is rotatably connected to a lower end wall of the power generation cavity 17, a power generator 19 disposed in the main body box 10 and below the power generation cavity 17 is fixedly connected to a lower end surface of the first driven shaft 18, a first gear 16 fixedly connected to an upper end of the first driven shaft 18 and extending leftward into the meshing cavity 15 is disposed in the power generation cavity 17, a spline shaft 35 is rotatably connected to an upper end wall of the 13, a spline cavity 36 communicating downward with the 13 is disposed in the, a driving rotating shaft 34 which extends downwards and penetrates through the meshing cavity 15 is connected in the spline cavity 36 in a matched mode, a second gear 14 which is fixedly connected with the tail end of the lower side of the driving rotating shaft 34 and can be meshed with the first gear 16 is arranged in the meshing cavity 15, a roller 12 which is fixedly connected with the driving rotating shaft 34 and extends forwards to the outside is arranged in the meshing cavity 13, a timing power cavity 29 which is located on the upper side of the power generation cavity 17 is communicated with the left side of the meshing cavity 15, a timing adjusting cavity 48 is arranged on the lower side of the timing power cavity 29, a bevel gear cavity 26 is arranged on the lower side of the timing adjusting cavity 48, a rack cavity 51 is communicated with the lower side of the bevel gear cavity 26, and a timing shutdown mechanism is arranged on the lower side of the rack cavity 51; when the second gear 14 is engaged with the first gear 16, the roller 12 is rotated to rotate the driving shaft 34, so that the first gear 16 is rotated by the second gear 14, and the first driven shaft 18 is rotated, so that mechanical energy is converted into electric energy for storage by the generator 19.

In addition, in one embodiment, the mode switching mechanism includes a link lifting cavity 62, the link lifting cavity 62 is located on the left side of the roller 13, the link lifting cavity 62 is communicated with the roller 13 to the right and communicated with the outside to the left, a rotary disc 11 connected with the driving shaft 34 in a rotating fit manner and located on the upper side of the roller 12 is arranged in the roller 13, a first compression spring 60 extending to the link lifting cavity 62 to the left is fixedly connected to the rotary disc 11, a limit block moving cavity 63 is communicated with the rear side of the link lifting cavity 62, limit cavities 64 are communicated with the front side of the limit block moving cavity 63 in an up-down symmetrical manner, the limit cavities 64 are communicated with the link lifting cavity 62 forwards, a mode link 57 extending to the outside to the left is arranged in the link lifting cavity 62, a link sliding cavity 56 with a right opening is arranged in the mode link 57, and the link sliding cavity 56 is connected with the rotary disc link 61 in a sliding, a first compression spring 60 is fixedly connected between the left end surface of the rotating disc connecting rod 61 and the bottom wall of the connecting rod sliding cavity 56, a connecting rod limiting block 58 which extends backwards into the limiting cavity 64 is fixedly connected to the rear end surface of the mode connecting rod 57, and a mode handle 33 is fixedly connected to the left end of the mode connecting rod 57; the mode handle 33 moves rightwards to drive the mode connecting rod 57 to move rightwards against the thrust of the first compression spring 60, so as to drive the connecting rod limiting block 58 to move rightwards to the limiting block moving cavity 63, the mode handle 33 moves upwards and downwards to drive the connecting rod limiting block 58 to move upwards and downwards to correspond to the limiting block 64, so that the driving rotating shaft 34 is driven to move upwards and downwards through the rotating disc connecting rod 61 and the rotating disc 11, the mode handle 33 is released, the connecting rod limiting block 58 and the mode connecting rod 57 move leftwards under the thrust of the first compression spring 60 until the connecting rod limiting block 58 is completely positioned in the limiting block 64, the mode connecting rod 57 is fixed, and the mode switching is completed.

In addition, in one embodiment, the timing power cavity 29 includes a second driven shaft 47, the second driven shaft 47 is located in the timing power cavity 29 and is connected with the lower end wall of the timing power cavity 29 in a rotating fit manner, the second driven shaft 47 extends upwards into the timing power cavity 29 and downwards extends through the timing adjusting cavity 48 to the bevel gear cavity 26, a one-way bearing 31 fixedly connected with the upper end of the second driven shaft 47 is arranged in the timing power cavity 29, a third gear 30 capable of being meshed with the second gear 14 is connected to the one-way bearing 31 in a rotating fit manner, and a spiral spring 32 is fixedly connected between the upper end surface of the second driven shaft 47 and the upper end wall of the timing power cavity 29; when the second gear 14 is engaged with the third gear 30, the second gear 14 rotates to drive the third gear 30 to rotate, so that the second driven shaft 47 is driven to rotate by the one-way bearing 31 against the elastic force of the coil spring 32, when the second gear 14 stops rotating, the second driven shaft 47 rotates reversely under the elastic force of the coil spring 32, and the third gear 30 does not rotate under the left and right of the one-way bearing 31.

In addition, in one embodiment, the timing adjusting cavity 48 includes an articulated rod 45, the articulated rod 45 is located at the rear side of the second driven shaft 47 and is articulated with the left end wall of the timing adjusting cavity 48, the right end of the front end surface of the articulated rod 45 is fixedly connected with a friction block 46 capable of abutting against the second driven shaft 47, the rear side of the timing adjusting cavity 48 is communicated with a sliding block cavity 44, the rear side of the sliding block cavity 44 is communicated with a connecting block cavity 43 with a left opening, the sliding block cavity 44 is connected with a sliding block 41 in a sliding fit manner, the front end surface of the sliding block 41 is fixedly connected with a second compression spring 42, the other end of the second compression spring 42 abuts against the rear end surface of the articulated rod 45, the rear end surface of the sliding block 41 is fixedly connected with a connecting block 40 extending backwards into the connecting block cavity 43, the left end surface of the, a timing rotating shaft 38 extending to the outside leftwards is connected with the sleeve 39 in a matching mode through internal threads, and a timing handle 37 is fixedly connected to the tail end of the left side of the timing rotating shaft 38; the timing handle 37 rotates to drive the timing rotating shaft 38 to rotate, so as to drive the sleeve 39 to move left and right, and thus the connecting block 40 and the sliding block 41 drive the second compression spring 42 to move left and right, so as to adjust the force of the friction block 46 against the second driven shaft 47, and thus the reverse rotation time of the second driven shaft 47 is adjusted by adjusting the friction resistance, and the adjustment of the timing time is realized.

In addition, in one embodiment, the bevel gear cavity 26 includes a third driven shaft 22, the third driven shaft 22 is connected with the rear end wall of the bevel gear cavity 26 in a rotating fit manner and extends forwards into the bevel gear cavity 26, a first bevel gear 27 fixedly connected with the front end of the third driven shaft 22 is arranged in the bevel gear cavity 26, a second bevel gear 28 fixedly connected with the lower end of the second driven shaft 47 is arranged in the bevel gear cavity 26, and the second bevel gear 28 is meshed with the first bevel gear 27; the second driven shaft 47 rotates to drive the second bevel gear 28 to rotate, so that the third driven shaft 22 is driven to rotate through the first bevel gear 27.

In addition, in one embodiment, the rack cavity 51 includes a rack 53, the rack 53 is connected with the rack cavity 51 in a sliding fit manner and meshed with the first bevel gear 27, the left side and the right side of the rack 53 are symmetrically communicated with trigger block cavities 49, trigger blocks 50 are connected in the trigger block cavities 49 in a sliding fit manner, a contact switch 52 is fixedly connected to the left end face of the right trigger block 50, and a third compression spring 54 is fixedly connected between the left end face of the rack 53 and the left end wall of the rack cavity 51; the reverse rotation of the first bevel gear 27 causes the rack 53 to move leftward against the urging force of the third compression spring 54.

In addition, in one embodiment, the timing shutdown mechanism comprises an upper and lower communicating cavity 25, the upper and lower communicating cavity 25 is located at the lower side of the trigger block cavity 49 and is communicated with the trigger block cavity 49 upwards, a left and right communicating cavity 20 is communicated with the lower side of the upper and lower communicating cavity 25, an upper and lower connecting rod 21 which extends downwards and penetrates through the upper and lower communicating cavity 25 to the prime left and right communicating cavity 20 is fixedly connected to the lower end surface of the trigger block 50, a left and right connecting rod 24 is fixedly connected to the lower end surface of the upper and lower connecting rod 21, and a left and right connecting rod 24 which is abutted upwards with the left and right connecting rod 24 is fixedly connected to the; the left trigger block 50 moves leftwards to drive the right left communicating chamber 20 to move leftwards by overcoming the friction force of the friction plate 23 through the upper and lower connecting rods 21 and the left and right connecting rods 24, and the right left communicating chamber 20 moves rightwards to drive the left communicating chamber 20 to move rightwards by overcoming the friction force of the friction plate 23 through the upper and lower connecting rods 21 and the left and right connecting rods 24.

The applicant will now specifically describe a self-charging remote control capable of being powered off at regular intervals according to the present application with reference to fig. 1 to 4 and the above description:

in an initial state, the contact switch 52 is positioned in the left side trigger block cavity 49, the third compression spring 54 is in a relaxed state, the right end surface of the rack 53 is abutted with the right end wall of the rack cavity 51, the spiral spring 32 is in a relaxed state, the left end surface of the sliding block 41 is abutted with the left end wall of the sliding block cavity 44, the second compression spring 42 is in a compressed state, the first compression spring 60 is in a relaxed state, the connecting rod limit block 58 is positioned in the upper side limit cavity 64, and the second gear 14 is meshed with the third gear 30;

when the remote control device starts to work, the timing handle 37 is rotated to drive the second compression spring 42 to move rightwards so as to adjust the pressure of the friction block 46 on the second driven shaft 47, so that the reversing time of the second driven shaft 47 is adjusted by adjusting the friction resistance, the timing time is adjusted, the roller 12 is rotated to drive the second driven shaft 47 to rotate until the spiral spring 32 is completely tightened, the timed shutdown can be completed by releasing the roller 12, the spiral spring 32 drives the second driven shaft 47 to reverse so as to drive the rack 53 to move leftwards against the thrust of the third compression spring 54, so that the left side trigger block 50 moves leftwards, the right side trigger block 50 is driven to move leftwards, so that the contact switch 52 moves rightwards into the rack cavity 51, after the elastic force of the spiral spring 32 is completely released, the rack 53 moves rightwards under the thrust of the third compression spring 54 to an initial position and contacts with the contact switch 52, so that the remote control, the contact switch 52 moves rightward to the initial position;

when manual charging is needed, the mode grip 33 is pushed rightwards and then pressed downwards, the mode grip 33 is loosened, the connecting rod limiting block 58 is moved into the lower side limiting cavity 64 through the limiting block moving cavity 63, so that mode switching is completed, the roller 12 is rotated to drive the first driven shaft 18 to rotate, mechanical energy is converted into electric energy through the generator 19, and therefore manual charging is completed.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a can regularly close self-charging remote controller, includes the main tank body, its characterized in that: the front end face of the main body box is provided with a plurality of keys, the main body box is internally provided with a forward opening, the left side is provided with a mode switching mechanism, the lower side is provided with a meshing cavity, the right side of the meshing cavity is communicated with a power generation cavity, the lower end wall of the power generation cavity is connected with a first driven shaft which extends upwards and downwards in a matched manner, the lower end face of the first driven shaft is fixedly connected with a power generator which is positioned in the main body box and positioned at the lower side of the power generation cavity, a first gear which is fixedly connected with the upper end of the first driven shaft and extends leftwards into the meshing cavity is arranged in the power generation cavity, the upper end wall is connected with a spline shaft in a rotating and matched manner, a spline cavity which is communicated downwards is arranged in the spline cavity, the spline cavity is connected with a driving rotating shaft which extends downwards into the meshing cavity, and a second gear which is fixedly connected, be equipped with initiative pivot fixed connection and the gyro wheel that extends to the external world forward meshing chamber left side intercommunication is equipped with and is located the timing power chamber of electricity generation chamber upside, timing power chamber downside is equipped with the timing and adjusts the chamber, timing is adjusted the chamber downside and is equipped with the bevel gear chamber, bevel gear chamber downside intercommunication is equipped with the rack chamber, rack chamber downside is equipped with timing shutdown mechanism.

2. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the mode switching mechanism comprises a connecting rod lifting cavity, the connecting rod lifting cavity is positioned on the left side, the connecting rod lifting cavity is communicated with the outside to the right side and the left side, a rotating disc which is connected with the active rotating shaft in a rotating matching way and positioned on the upper side of the roller is arranged in the connecting rod lifting cavity, a first compression spring which extends into the connecting rod lifting cavity to the left side is fixedly connected to the rotating disc, a limiting block moving cavity is arranged on the rear side of the connecting rod lifting cavity in a communicating way, limiting cavities are symmetrically arranged on the front side of the limiting block moving cavity in an up-and-down communicating way and are communicated with the connecting rod lifting cavity forwards, a mode connecting rod which extends into the outside to the left side is arranged in the connecting rod lifting cavity, a connecting rod sliding cavity with a right opening is arranged in the mode connecting rod, the connecting rod sliding cavity is connected with the connecting rod of the rotating disc in a, the rear end face of the mode connecting rod is fixedly connected with a connecting rod limiting block which extends backwards into the limiting cavity, and the tail end of the left side of the mode connecting rod is fixedly connected with a mode grip.

3. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the timing power cavity comprises a second driven shaft, the second driven shaft is located in the timing power cavity and is connected with the lower end wall of the timing power cavity in a rotating fit mode, the second driven shaft extends upwards into the timing power cavity and extends downwards to penetrate through the timing adjusting cavity to the bevel gear cavity, a one-way bearing fixedly connected with the tail end of the upper side of the second driven shaft is arranged in the timing power cavity, a third gear capable of being meshed with the second gear is connected to the one-way bearing in a rotating fit mode, and a spiral spring is fixedly connected between the upper end face of the second driven shaft and the upper end wall of the timing power cavity.

4. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the timing adjusting cavity comprises a hinged rod which is positioned at the rear side of the second driven shaft and hinged with the left end wall of the timing adjusting cavity, the right end of the front end surface of the hinged rod is fixedly connected with a friction block which can be abutted against the second driven shaft, the rear side of the timing adjusting cavity is communicated with a sliding block cavity, the rear side of the sliding block cavity is communicated with a connecting block cavity with a left opening, the sliding block is connected in the sliding block cavity in a sliding fit manner, the front end face of the sliding block is fixedly connected with a second compression spring, the other end of the second compression spring is abutted against the rear end face of the hinge rod, the rear end face of the sliding block is fixedly connected with a connecting block which extends backwards into the connecting block cavity, the connecting block left end face fixedly connected with sleeve, the interior screw thread fit connection of sleeve has the timing pivot that extends to the external world left, the terminal fixedly connected with of timing pivot left side holds the hand.

5. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the bevel gear cavity comprises a third driven shaft, the third driven shaft is connected with the rear end wall of the bevel gear cavity in a rotating fit mode and extends forwards to the bevel gear cavity, a first bevel gear fixedly connected with the tail end of the front side of the third driven shaft is arranged in the bevel gear cavity, a second bevel gear fixedly connected with the tail end of the lower side of the second driven shaft is further arranged in the bevel gear cavity, and the second bevel gear is meshed with the first bevel gear.

6. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the rack cavity comprises a rack, the rack is connected with the rack cavity in a sliding fit manner and meshed with the first bevel gear, the left side and the right side of the rack are symmetrically communicated with a trigger block cavity, a trigger block is connected in the trigger block cavity in a sliding fit manner, a contact switch is fixedly connected to the left end face of the trigger block on the right side, and a third compression spring is fixedly connected between the left end face of the rack and the left end wall of the rack cavity.

7. The self-charging remote controller capable of being powered off at regular time according to claim 1, wherein: the timing shutdown mechanism comprises an upper communicating cavity and a lower communicating cavity, the upper communicating cavity and the lower communicating cavity are located on the lower side of the trigger block cavity and communicated with the trigger block cavity in an upward mode, the upper communicating cavity and the lower communicating cavity are communicated with each other in a left-right mode, the lower end face of the trigger block is fixedly connected with upper connecting rods and lower connecting rods, the upper connecting rods and the lower connecting rods extend downwards and penetrate through the upper communicating cavity and the lower communicating cavity to prime numbers in a left-right mode, the upper connecting rods and the lower connecting rods are fixedly connected with end faces of the upper connecting rods and the.