CN111306019A

CN111306019A - Power generation device utilizing animal motion kinetic energy

Info

Publication number: CN111306019A
Application number: CN202010312329.7A
Authority: CN
Inventors: 吴琪琪
Original assignee: Shengzhou Tubai Power Generation Technology Co ltd
Current assignee: Shengzhou Tubai Power Generation Technology Co ltd
Priority date: 2020-04-20
Filing date: 2020-04-20
Publication date: 2020-06-19
Also published as: GB202012305D0

Abstract

The invention discloses a power generation device utilizing animal motion kinetic energy, which comprises a shell, wherein a power generation cavity is arranged in the shell, the power generation cavity is internally provided with leg kinetic energy conversion devices which are symmetrical up and down and are used for converting the motion of the hind legs of quadruped mammals into unidirectional rotation motion, a damping adjusting device is arranged in the leg kinetic energy conversion device, a movable kinetic energy conversion device positioned on the right side of the leg kinetic energy conversion device is arranged in the power generation cavity, the moving kinetic energy conversion device can convert the up-down movement and the left-right movement of the animal body in the moving process into one-way airflow kinetic energy, the power generation device positioned on the left side of the mobile kinetic energy conversion device is arranged in the power generation cavity, the invention can generate power by utilizing the movement of animals, the freedom of the animal is not limited, and the amount of exercise of the animal can be increased by adjusting the exercise damping, so that the animal health is facilitated.

Description

Power generation device utilizing animal motion kinetic energy

Technical Field

The invention relates to the technical field of animal power generation, in particular to a power generation device utilizing animal motion kinetic energy.

Background

The existing mainstream power generation method mainly comprises thermal power generation, and then comprises water conservancy power generation, wind power generation and solar power generation, along with the increase of domestic pets, and the increase of the work of feeders leads to insufficient exercise amount of the domestic pets, and the domestic pets need to consume a certain amount of food, so the problem caused by the insufficient exercise amount of the pets can be reduced by increasing the exercise burden of the pets, and the power generation can be carried out by utilizing the kinetic energy of the pet movement.

Disclosure of Invention

The technical problem is as follows: the existing animal driving power generation device is basically fixed, so that animals cannot move freely, the freedom of the animals is limited, and the animal driving power generation device is not beneficial to the health of the animals.

In order to solve the problems, the power generation device utilizing the kinetic energy of animal motion is designed in the embodiment, the power generation device utilizing the kinetic energy of animal motion comprises a shell, a power generation cavity is arranged in the shell, vertically symmetrical leg kinetic energy conversion devices are arranged in the power generation cavity and are used for converting the motion of the rear legs of the quadruped mammals into unidirectional rotation motion, each leg kinetic energy conversion device comprises two fixing plates fixedly connected to the inner wall of the rear side of the power generation cavity, the two fixing plates are vertically symmetrical, a rotating shaft is rotatably connected to each fixing plate, one side of the rotating shaft, far away from the symmetry center, extends out of the end face of the power generation cavity, a third gear positioned on one side of each fixing plate, close to the symmetry center, is fixedly connected to each rotating shaft, the device comprises a shell, a transmission shaft, a fixed plate, a transmission shaft, a first gear, a second gear, a third gear, a torsion spring, a rotating shaft, a secondary bevel gear, a rope wheel, a damping adjusting device and a power generation cavity, wherein the third gear is fixedly connected to the transmission shaft and is positioned on one side, away from the symmetry center, of the fixed plate, the torsion spring is connected between the third gear and the fixed plate, the rotating shaft is fixedly connected with the secondary bevel gear, away from the symmetry center, of the third gear, the rope wheel is fixedly connected to the rotating shaft and is positioned outside the end surface of the shell, two gear shafts which are bilaterally symmetrical are rotatably connected to the end surface, away from the symmetry center, of the fixed plate, the damping adjusting device is arranged in the leg kinetic energy conversion device and can adjust the motion resistance applied to animals by the leg kinetic energy conversion device, so that, the power generation cavity is internally provided with a power generation device positioned on the left side of the movable kinetic energy conversion device, and the power generation device can generate power by utilizing the kinetic energy converted by the leg kinetic energy conversion device and the movable kinetic energy conversion device.

Preferably, the gear shaft extends towards one side far away from the symmetry center, the gear shaft on the right side extends towards one side near the symmetry center, the gear shaft is provided with one-way clutches located at one side far away from the symmetry center of the fixing plate, the two one-way clutches can drive the corresponding gear shaft to rotate in opposite directions, so that the third gear can rotate in one direction all the time, the one-way clutches are provided with first gears, the first gears are meshed with the third gear, the gear shaft on the left side is fixedly connected with fourth gears located at one side near the fixing plate of the first gears, the gear shaft on the right side is fixedly connected with sixth gears meshed with the third gear, the end surface of the fixing plate on one side far away from the third gear is rotatably connected with sixth gears located on the left side of the gear shaft, the sixth gear extends up and down, a fifth gear in meshed connection with the fourth gear on the left side is fixedly connected to the sixth gear, a second gear located on one side, close to the symmetry center, of the fixing plate is fixedly connected to the sixth gear, the second gear is in meshed connection with the third gear, two cylinders which are symmetrical up and down are fixedly connected to the inner wall of the rear side of the power generation cavity and located between the two sixth gears, an air cavity with an opening facing left is arranged in each cylinder, a piston is connected in each air cavity in a sliding manner, a piston rod extending leftwards into the power generation cavity is fixedly connected to the end face of the left side of each piston, a connecting rod is hinged between each piston rod and the third gear, a second one-way valve communicated in a one-way and rightwards manner is arranged on the end face of the right side of each air cavity, and a third one-way valve, the rope wheel is wound with a rope, the end face of the left side of the rope is fixedly connected with a binding band, the binding band is used for being bound on the back leg of the animal, the end face of the right side of the shell is fixedly connected with an auxiliary binding band, and the auxiliary binding band is used for being bound on the animal.

Preferably, the damping adjusting device comprises two damping boxes fixedly connected to the inner wall of the front side of the power generation cavity, the two damping boxes are vertically symmetrical, a damping cavity is arranged in each damping box, damping fluid is filled in each damping cavity, a bevel gear shaft extending forwards and backwards is rotatably connected to the inner wall of the rear side of each damping cavity, the bevel gear shaft is in movable sealing connection with the damping cavity, a bevel gear positioned on the lower side of each damping box is fixedly connected to the bevel gear shaft, the bevel gear is in meshed connection with the auxiliary bevel gear, a lifting rod extending forwards and backwards is rotatably connected to the inner wall of the front side of each damping cavity and extends forwards to the outer end face of the power generation cavity, an impeller positioned in each damping cavity is rotatably connected to the lifting rod and is positioned on the front side of the bevel gear shaft, and a sliding cavity with a backward opening is arranged in each impeller, the sliding cavity is connected with the bevel gear shaft through a flat key, five limiting holes distributed from the front to the back are formed in the lifting rod, the limiting holes are communicated with each other left and right, a secondary fixing plate is fixedly connected to the end face of the front side of the power generation cavity and located on the right side of the lifting rod, sliding holes communicated with each other left and right are formed in the secondary fixing plate, limiting rods extending left and right are connected to the sliding holes in a sliding mode, the limiting rods can extend into the limiting holes, a baffle is fixedly connected to the limiting rods and located on the right side of the secondary fixing plate, and extension springs are connected between the baffle and the secondary fixing plate.

Preferably, the movable kinetic energy conversion device comprises a kinetic energy conversion box fixedly connected to the inner wall of the rear side of the power generation cavity and located between the two cylinders, a kinetic energy conversion cavity is arranged in the kinetic energy conversion box, a mass slide block is connected to the inner wall of the lower side of the kinetic energy conversion cavity in a sliding manner, an auxiliary cylinder is fixedly connected to each of the left side of the kinetic energy conversion cavity and the front side end face of the kinetic energy conversion cavity, an auxiliary air cavity communicated with the kinetic energy conversion cavity is arranged in each auxiliary cylinder, an auxiliary piston is connected in each auxiliary air cavity in a sliding manner, an auxiliary piston rod is connected to the end face of one side, close to the kinetic energy conversion cavity, of the auxiliary piston rod extends into the kinetic energy conversion cavity, the auxiliary piston rod is fixedly connected with the mass slide block, a first check valve is arranged on the end face of one side, far away from the kinetic energy conversion box, and a fourth one-way valve is arranged on the end surface of one side of the auxiliary air cavity, which is far away from the kinetic energy conversion box, and the fourth one-way valve is communicated towards one side close to the kinetic energy conversion box in a one-way mode.

Preferably, the power generation device comprises a lithium battery fixedly connected to the inner wall of the rear side of the power generation cavity, the lithium battery is positioned between the second gears, the inner wall of the rear side of the power generation cavity is fixedly connected with a motor base positioned on the right side of the lithium battery, a motor shaft extending rightwards is rotatably connected on the end surface of the right side of the motor base, a generator fixedly connected on the motor base is connected on the motor shaft in a power mode, an electric wire is electrically connected between the generator and the lithium battery, an impeller positioned on the right side of the generator is fixedly connected on the inner wall of the rear side of the power generation cavity, the motor shaft extends into the impeller, and the impeller can drive the generator to rotate through the motor shaft to generate electricity, an auxiliary air passage pipe is communicated and connected between the right end face of the impeller and the first one-way valve, and an air passage pipe is communicated and connected between the right end face of the impeller and the second one-way valve.

The invention has the beneficial effects that: the invention is a wearable device which can be directly worn on the body of an animal, thereby avoiding the limitation of the freedom of the animal, the leg kinetic energy conversion device can utilize the kinetic energy of the hind legs of the animal when the animal walks and runs to generate electricity, the damping adjustment device on the leg kinetic energy conversion device can manually adjust the motion resistance of the hind legs of the animal, thereby being capable of adapting to the motion requirements of different metering, and the mobile kinetic energy conversion device can convert the kinetic energy generated when the animal body moves into electric energy, therefore, the invention can utilize the motion of the animal to generate electricity, does not limit the freedom of the animal, and can increase the motion amount of the animal by adjusting the motion damping, thereby being beneficial to.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic diagram of the overall structure of a power generation device using kinetic energy of animals according to the present invention;

FIG. 2 is an enlarged view of the structure at "A" in FIG. 1;

FIG. 3 is an enlarged view of the structure at "B" of FIG. 2;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 2;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 3;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 6, for the sake of convenience of description, the following orientations are now 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.

The invention relates to a power generation device utilizing animal motion kinetic energy, which is mainly applied to animal power generation, and the invention is further explained by combining the attached drawings of the invention:

the invention relates to a power generation device utilizing animal motion kinetic energy, which comprises a shell 11, wherein a power generation cavity 12 is arranged in the shell 11, an up-and-down symmetrical leg kinetic energy conversion device 101 is arranged in the power generation cavity 12, the leg kinetic energy conversion device 101 is used for converting the motion of the hind legs of quadruped mammals into unidirectional rotation motion, the leg kinetic energy conversion device 101 comprises two fixing plates 13 fixedly connected to the inner wall of the rear side of the power generation cavity 12, the two fixing plates 13 are vertically symmetrical, a rotating shaft 16 is rotatably connected to the fixing plates 13, the rotating shaft 16 extends out of the end surface of the power generation cavity 12 towards the side far away from the symmetry center, a third gear 28 positioned on the side, close to the symmetry center, of the fixing plates 13 is rotatably connected to a transmission shaft 48, and the transmission shaft 48 is fixedly connected to the third gear 28 positioned on the side, far away from the symmetry center, of the fixing plates 13 A torsion spring 36 is connected between the third gear 28 and the fixed plate 13, a secondary bevel gear 35 located on one side of the third gear 28 away from the symmetry center is fixedly connected to the rotating shaft 16, a rope pulley 14 located outside the end surface of the shell 11 is fixedly connected to the rotating shaft 16, two bilaterally symmetrical gear shafts 57 are rotatably connected to one side end surface of the fixed plate 13 away from the symmetry center, a damping adjusting device 102 is arranged in the leg kinetic energy conversion device 101, the damping adjusting device 102 can adjust the movement resistance applied to the animal by the leg kinetic energy conversion device 101, so that the training intensity to the animal can be adjusted, a mobile kinetic energy conversion device 103 located on the right side of the leg kinetic energy conversion device 101 is arranged in the power generation cavity 12, and the mobile kinetic energy conversion device 103 can convert the up-down movement and the left-right movement of the body of the animal in the movement process into one, a power generation device 104 positioned on the left side of the mobile kinetic energy conversion device 103 is arranged in the power generation cavity 12, and the power generation device 104 can generate power by using the kinetic energy converted by the leg kinetic energy conversion device 101 and the mobile kinetic energy conversion device 103.

Advantageously, the gear shaft 57 extends away from the side of the symmetry center, the gear shaft 57 on the right side extends toward the side close to the symmetry center, the gear shaft 57 is provided with a one-way clutch 32 located on the side of the fixing plate 13 away from the symmetry center, two one-way clutches 32 can drive the corresponding gear shaft 57 to rotate in opposite directions, so that the third gear 28 can always rotate in one direction, the one-way clutch 32 is provided with a first gear 18, the first gear 18 is meshed with the third gear 28, the gear shaft 57 on the left side is fixedly connected with a fourth gear 37 located on the side of the first gear 18 close to the fixing plate 13, the gear shaft 57 on the right side is fixedly connected with a sixth gear 39 meshed with the third gear 28, the end surface of the fixing plate 13 far away from the third gear 28 is rotatably connected with the sixth gear 39 located on the left side of the gear shaft 57 on the left side, the sixth gear 39 extends up and down, the sixth gear 39 is fixedly connected with a fifth gear 38 engaged with the fourth gear 37 on the left side, the sixth gear 39 is fixedly connected with a second gear 21 positioned on one side of the fixing plate 13 close to the symmetry center, the second gear 21 is engaged with the third gear 28, the inner wall of the rear side of the power generation cavity 12 is fixedly connected with two cylinders 29 which are symmetrical up and down, the two cylinders 29 are positioned between the two sixth gears 39, a gas cavity 46 with an opening facing left is arranged in the cylinder 29, a piston 47 is connected in the gas cavity 46 in a sliding manner, the left end face of the piston 47 is fixedly connected with a piston rod 27 extending leftwards into the power generation cavity 12, a connecting rod 50 is hinged between the piston rod 27 and the third gear 28, and a second one-way valve 45 communicated rightwards in a one-way manner is arranged on the right end face of the gas cavity 46, a third one-way valve 49 communicated upwards in one way is arranged on the lower side end face of the air cavity 46, a rope 15 is wound on the rope wheel 14, a binding band 20 is fixedly connected to the left side end face of the rope 15, the binding band 20 is used for being bound on the back leg of the animal, an auxiliary binding band 31 is fixedly connected to the right side end face of the shell 11, and the auxiliary binding band 31 is used for being bound on the body of the animal.

Advantageously, the damping adjustment device 102 includes two damping boxes 58 fixedly connected to the inner wall of the front side of the power generation cavity 12, and the two damping boxes 58 are vertically symmetrical, a damping cavity 59 is provided in the damping box 58, damping fluid is provided in the damping cavity 59, a bevel gear shaft 34 extending forward and backward is rotatably connected to the inner wall of the rear side of the damping cavity 59, the bevel gear shaft 34 and the damping cavity 59 are in dynamic sealing connection, a bevel gear 17 located at the lower side of the damping box 58 is fixedly connected to the bevel gear shaft 34, the bevel gear 17 and the bevel pinion 35 are in meshing connection, a lifting rod 62 extending forward and backward is rotatably connected to the inner wall of the front side of the damping cavity 59, the lifting rod 62 extends forward to the end surface of the power generation cavity 12, an impeller 60 located in the damping cavity 59 is rotatably connected to the lifting rod 62, and the impeller 60 is located at the front side of the bevel gear shaft 34, a sliding cavity 61 with a backward opening is arranged in the impeller 60, the sliding cavity 61 is in flat key connection with the bevel gear shaft 34, five limiting holes 63 distributed in an array from front to back are arranged on the lifting rod 62, the limiting holes 63 are communicated from left to right, an auxiliary fixing plate 40 positioned on the right side of the lifting rod 62 is fixedly connected to the front side end face of the power generation cavity 12, a sliding hole 65 communicated from left to right is arranged in the auxiliary fixing plate 40, a limiting rod 64 extending from left to right is connected in the sliding hole 65 in a sliding manner, the limiting rod 64 can extend into the limiting hole 63, a baffle 67 positioned on the right side of the auxiliary fixing plate 40 is fixedly connected to the limiting rod 64, a tension spring 66 is connected between the baffle 67 and the auxiliary fixing plate 40, and the length of the impeller 60 positioned in damping fluid is changed by moving the lifting rod 62 and the impeller 60 back and forth, so that the rotational damping of the, thereby achieving an adjustment of the resistance to movement applied to the animal.

Advantageously, the mobile kinetic energy conversion device 103 includes a kinetic energy conversion box 30 fixedly connected to the inner wall of the rear side of the power generation cavity 12 and located between the two air cylinders 29, a kinetic energy conversion cavity 55 is disposed in the kinetic energy conversion box 30, a mass slider 56 is slidably connected to the inner wall of the lower side of the kinetic energy conversion cavity 55, a secondary air cylinder 44 is fixedly connected to each of the left side and the front side end surface of the kinetic energy conversion cavity 55, a secondary air cavity 52 communicated with the kinetic energy conversion cavity 55 is disposed in the secondary air cylinder 44, a secondary piston 53 is slidably connected to the secondary air cavity 52, a secondary piston rod 54 is slidably connected to the end surface of the secondary piston 53 close to the kinetic energy conversion cavity 55, the secondary piston rod 54 extends into the kinetic energy conversion cavity 55, the secondary piston rod 54 is fixedly connected to the mass slider 56, and a first check valve 43 is disposed on the end surface of the secondary air cavity 52 far from the, the first one-way valve 43 is communicated towards one side far away from the kinetic energy conversion box 30 in one way, the end surface of one side of the auxiliary air cavity 52 far away from the kinetic energy conversion box 30 is provided with a fourth one-way valve 51, the fourth one-way valve 51 is communicated towards one side near the kinetic energy conversion box 30 in one way, the animal can move up and down and move left and right when moving and can be converted into the mass slide block 56 to move up and down and move left and right, and the auxiliary piston 53 is driven to move through the auxiliary piston rod 54 to generate air flow, so that the kinetic energy of the animal movement is converted into the air.

Advantageously, the power generation device 104 comprises a lithium battery 22 fixedly connected to the inner wall of the rear side of the power generation cavity 12, the lithium battery 22 is located between the second gears 21, a motor base 33 located at the right side of the lithium battery 22 is fixedly connected to the inner wall of the rear side of the power generation cavity 12, a motor shaft 25 extending rightward is rotatably connected to the end surface of the right side of the motor base 33, a generator 23 fixedly connected to the motor base 33 is rotatably connected to the motor shaft 25, an electric wire 24 is electrically connected between the generator 23 and the lithium battery 22, a turbine 26 located at the right side of the generator 23 is fixedly connected to the inner wall of the rear side of the power generation cavity 12, the motor shaft 25 extends into the turbine 26, and the turbine 26 can drive the generator 23 to rotate through the motor shaft 25 to generate power, an auxiliary gas path pipe 42 is connected between the end surface of the right side of the turbine 26 and the first one-way valve 43, an air path pipe 41 is connected between the end surface of the right side of the impeller 26 and the second one-way valve 45, and the air flow drives the impeller 26 and the motor shaft 25 to rotate, so that the generator 23 can generate electricity.

The following describes in detail the use steps of a power generation device using kinetic energy of animal motion with reference to fig. 1 to 6: initial state: under the action of gravity, the mass slider 56 is located at the lower limit; in operation, the shell 11 is manually placed on the back of the animal, the auxiliary binding bands 31 are bound on the animal body, and the two binding bands 20 are respectively bound on the two back legs of the animal; the baffle 67 can be manually pulled rightwards to drive the limiting rod 64 to move rightwards, so that the limiting rod 64 is separated from the limiting hole 63, the limitation on the lifting rod 62 is removed, then the lifting rod 62 is manually driven to move forwards and backwards, the lifting rod 62 drives the impeller 60 to move forwards and backwards, the length of the impeller 60 in the damping fluid is changed, the rotary damping of the impeller 60 is changed, then the baffle 67 is released, the limiting rod 64 moves leftwards to extend into one limiting hole 63 to reset under the action of the extension spring 66, and the lifting rod 62 is locked again; when an animal moves and the back legs of the animal rotate to the left, the back legs drive the rope pulley 14 and the rotating shaft 16 to rotate through the binding bands 20 and the ropes 15, the rotating shaft 16 drives the movable bevel gear shaft 34 to rotate through the meshed connection of the auxiliary bevel gear 35 and the motor base 33, the bevel gear shaft 34 drives the movable bevel gear 60 to rotate through the flat key, damping fluid in the damping cavity 59 applies rotary damping to the impeller 60, so that set movement resistance is applied to the animal, the movement amount of the animal is increased, the animal with insufficient long-term movement is helped to exercise, meanwhile, the rotating shaft 16 drives the third gear 28 to rotate, the third gear 28 drives the first gear 18 to rotate through the meshed connection, the first gear 18 on the left side drives the gear shaft 57 on the left side to rotate through the one-way clutch 32 on the left side, at the moment, the first gear 18 on the right side cannot drive the gear shaft 57 to rotate through the one-way clutch 32, the gear shaft 57 on the, the sixth gear 39 drives the third gear 28 to rotate through the second gear 21, when the hind legs of the animal rotate to the right, under the action of the torsion spring 36, the third gear 28 and the rotating shaft 16 are reversely reset, the third gear 28 drives the first gear 18 to reversely rotate through the meshing connection, at this time, the first gear 18 on the right side can drive the gear shaft 57 on the right side and the sixth gear 39 to rotate through the one-way clutch 32 on the right side, the sixth gear 39 drives the third gear 28 through the meshing connection, so that the third gear 28 always rotates in the same direction, the third gear 28 drives the piston rod 27 and the piston 47 to reciprocate left and right through the connecting rod 50, when the piston 47 moves to the right, the airflow generated by the piston 47 is conveyed into the impeller 26 through the impeller 26 and the second one-way valve 45, so that the motor shaft 25 on the working site of the impeller 26 rotates, the motor shaft 25 drives the generator 23 to generate electricity, the electric energy generated by the generator, when the piston 47 moves leftwards, external air flow enters the air cavity 46 through the third one-way valve 49, so that the piston 47 can move leftwards, and kinetic energy of the motion of the hind legs of the animal is converted into electric energy; meanwhile, as the body of the animal moves up and down and left and right, the body of the animal can drive the mass slide block 56 to move up and down and left and right when moving, the mass slide block 56 drives the corresponding auxiliary piston 53 to move back and forth to the side far away from and close to the kinetic energy conversion box 30 through the auxiliary piston rod 54, when the auxiliary piston 53 moves to the side far away from the kinetic energy conversion box 30, the airflow generated by the auxiliary piston 53 is conveyed into the turbine 26 through the first one-way valve 43 and the auxiliary air path pipe 42, so as to drive the turbine 26 to work, the turbine 26 drives the motor shaft 25 to rotate, the motor shaft 25 drives the generator 23 to generate electricity, the electric energy generated by the generator 23 is conveyed into the lithium battery 22 through the electric wire 24 to be stored, and therefore the.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. The utility model provides an utilize power generation facility of animal motion kinetic energy, includes the casing, its characterized in that: the shell is internally provided with a power generation cavity, the power generation cavity is internally provided with vertically symmetrical leg kinetic energy conversion devices, the leg kinetic energy conversion devices are used for converting the motion of the hind legs of the quadruped mammals into unidirectional rotation motion, each leg kinetic energy conversion device comprises two fixed plates which are fixedly connected to the inner wall of the rear side of the power generation cavity, the two fixed plates are vertically symmetrical, a rotating shaft is rotatably connected onto each fixed plate, one side of the rotating shaft, which is far away from the symmetry center, extends out of the end face of the power generation cavity, a third gear which is positioned on one side of the fixed plate, which is close to the symmetry center, is fixedly connected onto the rotating shaft, a transmission shaft is rotatably connected onto the end face of one side of the fixed plate, which is close to the symmetry center, a third gear which is positioned on one side of the, fixedly connected with is located in the pivot the vice bevel gear of symmetry center one side is kept away from to the third gear, fixedly connected with is located in the pivot rope sheave outside the shell body end surface, the fixed plate is kept away from the gear shaft that is connected with two bilateral symmetry on the symmetry center side end surface in the rotation, be equipped with damping adjusting device in the shank kinetic energy conversion device, damping adjusting device can adjust the motion resistance for the animal is applyed to shank kinetic energy conversion device to can adjust the training intensity to the animal, be equipped with in the electricity generation intracavity and be located the removal kinetic energy conversion device on shank kinetic energy conversion device right side, removal kinetic energy conversion device can be with the reciprocating of the health in the animal motion process with remove the removal and turn into one-way air current kinetic energy, be equipped with in the electricity generation intracavity and be located the left power generation facility of removal kinetic energy conversion device, power generation facility can utilize shank kinetic energy conversion device with Can generate electricity.

2. A power generation apparatus using kinetic energy of animal as claimed in claim 1, wherein: the gear shaft is extended from one side far away from the symmetric center, the gear shaft on the right side is extended from one side near the symmetric center, the gear shaft is provided with one-way clutches positioned on one side far away from the symmetric center of the fixing plate, the two one-way clutches can drive the corresponding gear shaft to rotate in opposite directions, so that the third gear can rotate in one way all the time, the one-way clutches are provided with first gears which are meshed with the third gear, the gear shaft on the left side is fixedly connected with a fourth gear positioned on one side near the fixing plate of the first gear, the gear shaft on the right side is fixedly connected with a sixth gear meshed with the third gear, the end surface on one side far away from the third gear of the fixing plate is rotatably connected with the sixth gear positioned on the left side of the gear shaft, and the sixth gear extends up and down, the sixth gear is fixedly connected with a fifth gear in meshed connection with the fourth gear on the left side, the sixth gear is fixedly connected with a second gear positioned on one side, close to the symmetric center, of the fixing plate, the second gear is in meshed connection with the third gear, two cylinders which are symmetrical up and down are fixedly connected on the inner wall of the rear side of the power generation cavity and positioned between the two sixth gears, an air cavity with an opening facing left is arranged in each cylinder, a piston is connected in each air cavity in a sliding manner, a piston rod which extends into the power generation cavity leftwards is fixedly connected on the end face of the left side of the piston, a connecting rod is hinged between each piston rod and the third gear, a second one-way valve which is communicated rightwards in a one-way manner is arranged on the end face of the right side of each air cavity, a third one-way valve which is communicated upwards is arranged on, the rope is characterized in that a binding band is fixedly connected to the end face of the left side of the rope and used for being bound to the back leg of an animal, an auxiliary binding band is fixedly connected to the end face of the right side of the shell and used for being bound to the animal.

3. A power generation apparatus using kinetic energy of animal as claimed in claim 1, wherein: the damping adjusting device comprises two damping boxes fixedly connected to the inner wall of the front side of the power generation cavity, the two damping boxes are vertically symmetrical, a damping cavity is arranged in each damping box, damping liquid is filled in each damping cavity, a bevel gear shaft extending forwards and backwards is rotatably connected to the inner wall of the rear side of each damping cavity, the bevel gear shaft is in rotary sealing connection with the damping cavity, a bevel gear positioned on the lower side of each damping box is fixedly connected to each bevel gear shaft, the bevel gears are in meshed connection with the auxiliary bevel gears, a lifting rod extending forwards and backwards is rotatably connected to the inner wall of the front side of each damping cavity and extends forwards to the outer side of the end face of the power generation cavity, an impeller positioned in each damping cavity is rotatably connected to each lifting rod and is positioned on the front side of the corresponding bevel gear shaft, and a sliding cavity with an opening facing backwards is arranged in each impeller, the sliding cavity is connected with the bevel gear shaft through a flat key, five limiting holes distributed from the front to the back are formed in the lifting rod, the limiting holes are communicated with each other left and right, a secondary fixing plate is fixedly connected to the end face of the front side of the power generation cavity and located on the right side of the lifting rod, sliding holes communicated with each other left and right are formed in the secondary fixing plate, limiting rods extending left and right are connected to the sliding holes in a sliding mode, the limiting rods can extend into the limiting holes, a baffle is fixedly connected to the limiting rods and located on the right side of the secondary fixing plate, and extension springs are connected between the baffle and the secondary fixing plate.

4. A power generation apparatus using kinetic energy of animals as claimed in claim 2, wherein: the movable kinetic energy conversion device comprises a kinetic energy conversion box which is fixedly connected to the inner wall of the rear side of the power generation cavity and is positioned between two air cylinders, a kinetic energy conversion cavity is arranged in the kinetic energy conversion box, a mass slide block is connected to the inner wall of the lower side of the kinetic energy conversion cavity in a sliding manner, an auxiliary air cylinder is respectively and fixedly connected to the left side of the kinetic energy conversion cavity and the front side end face of the kinetic energy conversion cavity, an auxiliary air cavity communicated with the kinetic energy conversion cavity is arranged in the auxiliary air cylinder, an auxiliary piston is connected in the auxiliary air cavity in a sliding manner, an auxiliary piston rod is connected in a sliding manner on the end face of one side, close to the kinetic energy conversion cavity, of the auxiliary piston rod extends into the kinetic energy conversion cavity, the auxiliary piston rod is fixedly connected with the mass slide block, a first one-way valve is arranged on the end face, and a fourth one-way valve is arranged on the end surface of one side of the auxiliary air cavity, which is far away from the kinetic energy conversion box, and the fourth one-way valve is communicated towards one side close to the kinetic energy conversion box in a one-way mode.

5. A power generation apparatus using kinetic energy of animal as claimed in claim 4, wherein: the power generation device comprises a lithium battery fixedly connected to the inner wall of the rear side of the power generation cavity, the lithium battery is positioned between the second gears, a motor base positioned at the right side of the lithium battery is fixedly connected on the inner wall at the rear side of the power generation cavity, a motor shaft extending rightwards is rotatably connected on the end surface at the right side of the motor base, the motor shaft is in power connection with a generator fixedly connected to the motor base, an electric wire is electrically connected between the generator and the lithium battery, the inner wall of the rear side of the power generation cavity is fixedly connected with a turbine positioned on the right side of the generator, the motor shaft extends into the turbine, and the impeller can drive the generator to rotate through the motor shaft to generate electricity, an auxiliary air passage pipe is communicated and connected between the right end face of the impeller and the first one-way valve, and an air passage pipe is communicated and connected between the right end face of the impeller and the second one-way valve.