CN113504471A - Automatic detection system of waste lithium battery and detection equipment thereof - Google Patents

Abstract

The invention discloses an automatic detection system and detection equipment for waste lithium batteries, and the automatic detection system comprises a support base plate, wherein a concave supporting rod is arranged on one side of the top end of the support base plate, a detection assembly is arranged in the groove wall of the concave supporting rod, a rotating assembly is arranged on the other side of the top end of the support base plate, the detection assembly comprises two sliding racks, the two sliding racks are directly meshed with a first gear, the front side of the first gear is fixedly connected with a connecting cylinder, and the back sides of the two sliding racks are respectively provided with a connecting rod. The invention has the beneficial effects that: according to the invention, the eccentric wheel is driven to rotate by the rotating motor, so that the sliding racks reciprocate up and down, the two sliding racks are engaged through the first gear, the two sliding racks always move in opposite directions, the two detection test pens are contacted with the anode and the cathode of the waste lithium battery, and the service life of the waste lithium battery is detected through the ammeter.

Description

Automatic detection system of waste lithium battery and detection equipment thereof

Technical Field

The invention relates to detection equipment, in particular to an automatic detection system for waste lithium batteries and detection equipment thereof, and belongs to the technical field of lithium battery recovery equipment.

Background

With the development of the times, lithium batteries are widely used, the number of the generated waste lithium batteries is gradually increased, and if the discarded lithium batteries are not properly treated, lithium hexafluorophosphate, carbonate organic matters, cobalt, copper and other heavy metals contained in the discarded lithium batteries inevitably form potential pollution threats to the environment.

But the lithium battery needs to be screened when being recycled, the power lithium battery is retired, and the material recycling is carried out after the echelon utilization; pursuing economic benefits is the driving force for enterprises and social behaviors. And (4) performing gradient utilization until the available value of the battery is reduced to be lower than the maintenance cost, and then recovering raw materials to maximize the value of the battery. Therefore, the service life of the waste lithium battery needs to be detected during recovery, if the waste lithium battery has a utilization value, the waste lithium battery is continuously utilized, and the waste lithium battery can be recovered after the electric quantity of the waste lithium battery is used up to maximize the benefit and make the best use of the things.

Disclosure of Invention

The invention aims to solve the problems and provide an automatic detection system and detection equipment for waste lithium batteries.

The invention realizes the aim by the following technical scheme, and the automatic detection system and the detection equipment thereof for the waste lithium battery comprise a support bottom plate, wherein a concave supporting rod is arranged on one side of the top end of the support bottom plate, a detection assembly is arranged in the groove wall of the concave supporting rod, a rotating assembly is arranged on the other side of the top end of the support bottom plate, the detection assembly comprises two sliding racks, the two sliding racks are directly meshed with a first gear, the front surface of the first gear is fixedly connected with a connecting cylinder, the back surfaces of the two sliding racks are respectively provided with a connecting rod, the opposite surfaces of the two connecting rods are provided with a detection electroprobe, the top ends and the bottom ends of the two sliding racks are respectively fixedly connected with a limiting cylinder, the rotating assembly comprises a rotating cylinder, the bottom of the outer wall of the rotating cylinder is fixedly connected with a second gear, one side of the second gear is meshed with a third gear, the top end of the supporting cylinder is provided with a supporting cylinder, the top end of the supporting cylinder is fixedly connected with a first bevel gear, the top end of the rotating cylinder is provided with a carrying circular ring, and a plurality of object placing circular grooves are formed in the periphery of the top end of the carrying circular ring at equal intervals.

Preferably, in two circular spouts all been seted up to the cell wall top and the bottom of spill bracing piece, and four spacing cylinder difference sliding connection is in circular spout, spacing disc of spacing cylindrical one end fixedly connected with respectively, just one side fixedly connected with reset spring of spacing disc, four reset spring keeps away from the one end of spacing disc and the cell wall fixed connection of circular spout.

Preferably, an L-shaped connecting plate is arranged on the front face of one of the sliding racks, a C-shaped connecting plate is fixedly connected to one end, far away from the sliding rack, of the L-shaped connecting plate, limiting round blocks are fixedly connected to two sides of the groove wall of the C-shaped connecting plate, one end, far away from the first gear, of the connecting cylinder is rotatably connected with the groove wall of the concave supporting rod through a rotating bearing, and a rectangular sliding hole is formed in the front face of the concave supporting rod.

Preferably, the bottom of the C-shaped connecting plate is provided with an eccentric wheel, the front side and the back side of the eccentric wheel are provided with annular grooves, and the two limiting round blocks are respectively connected in the two annular grooves in a sliding manner.

Preferably, the upper portion of the back of the eccentric wheel is fixedly connected with a first rotating wheel, a first driving belt is sleeved on the outer wall of the first rotating wheel, and double rotating wheels are clamped on one side, away from the first rotating wheel, of the inner wall of the first driving belt.

Preferably, the back of the double rotating wheels is fixedly connected with a rotating column, the outer wall of the rotating column is fixedly connected with a second bevel gear, and the bottom end of the second bevel gear is respectively meshed with the two sides of the first bevel gear.

Preferably, a second transmission belt is sleeved on one side, far away from the first transmission belt, of the outer wall of the double-rotating wheel, and a second transmission wheel is clamped on one side, far away from the double-rotating wheel, of the inner wall of the second transmission belt.

Preferably, the front surface of the second driving wheel is fixedly connected with a rotating motor, and the output end of the rotating motor is fixedly connected with the front surface of the second driving wheel.

Preferably, the bottom end of the rotating motor is fixedly connected with a supporting box body, and the back surface of the supporting box body is fixedly connected with one side of the front surface of the supporting bottom plate.

The detection device comprises the following steps:

the method comprises the following steps:

an operator starts the rotating motor to enable the rotating motor to start working, and the rotating motor drives the second driving belt to rotate after being started, so that the double rotating wheels are driven to rotate;

step two:

the double rotating wheels drive the rotating columns to rotate, and drive the supporting cylinders and third gears fixedly connected with the supporting cylinders to rotate, so that the rotating cylinders and the carrying circular rings are driven to rotate, and the waste lithium batteries are rotated;

step three:

the double rotating wheels drive the first transmission belt to rotate, so that the eccentric wheel rotates to drive the C-shaped connecting plate to move up and down periodically to drive the L-shaped connecting plate to move, when the L-shaped connecting plate drives one of the sliding racks to move, the other sliding rack moves oppositely, and then a detection test pencil fixedly connected with the connecting rod is controlled to detect the waste lithium batteries;

step four:

after the detection electroprobe is contacted with the waste lithium battery, the two detection electroprobes transmit detected data to the external ammeter, and an operator can visually observe the residual current in the waste lithium battery through the external ammeter.

The invention has the beneficial effects that:

according to the invention, the eccentric wheel is driven to rotate by the rotating motor, so that the sliding racks reciprocate up and down, the two sliding racks are meshed through the first gear, so that the two sliding racks always move in opposite directions, the two detection test pens are contacted with the anode and the cathode of the waste lithium battery, the service life of the waste lithium battery is detected through the ammeter, after the detection is completed, the two detection test pens are separated, the rotating assembly drives the next waste lithium battery to move, the two detection test pens further detect the service life of the next waste lithium battery, and the continuous detection function is realized to electrically contact the anode and the cathode of the waste lithium battery.

The front side and the back side of the eccentric wheel are both provided with annular grooves, the inner wall of the C-shaped connecting plate is fixedly connected with two limiting round blocks, and the two limiting round blocks are respectively connected with the two annular grooves in a sliding manner, so that when the eccentric wheel rotates, the distance between the C-shaped connecting plate and the circle center of the eccentric wheel is the same all the time, the C-shaped connecting plate and the eccentric wheel rotate, the circular vertical movement of the C-shaped connecting plate is synchronously performed all the time, and the two limiting round blocks are arranged to prevent the eccentric wheel and the C-shaped connecting plate from being separated.

And the two rectangular sliding blocks are connected in the rectangular sliding grooves in a sliding manner, so that the limiting effect can be achieved, and the L-shaped connecting plate is prevented from swinging back and forth in the rectangular sliding holes to influence the detection of the waste lithium batteries.

The two ends of the two sliding racks are provided with the limiting cylinders, the four limiting cylinders are respectively connected in the circular sliding groove in a sliding mode, so that the stability of the detection assembly is guaranteed, the detection assembly is prevented from being deviated during detection, the detection precision is prevented from being affected, the return spring is arranged in the circular sliding groove, the limiting cylinders and the circular sliding groove are prevented from being directly and mechanically collided during detection, and the service life of the detection equipment is prolonged.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic partial cross-sectional view of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic view of a support base according to the present invention;

FIG. 5 is a schematic view of a concave support bar according to the present invention;

FIG. 6 is an enlarged view of the structure at B in FIG. 5 according to the present invention;

FIG. 7 is a schematic structural diagram of a detecting assembly according to the present invention.

In the figure: 1. a support base plate; 2. a concave support rod; 201. a rectangular slide hole; 202. a circular chute; 203. a limiting disc; 204. a return spring; 3. a detection component; 301. a sliding rack; 302. a first gear; 303. a connecting cylinder; 304. a connecting rod; 305. detecting the electroprobe; 306. a limiting cylinder; 4. a rotating assembly; 401. rotating the cylinder; 402. a second gear; 403. a third gear; 404. a support cylinder; 405. a first bevel gear; 406. a carrying ring; 407. a round storage groove; 5. an L-shaped connecting plate; 6. a C-shaped connecting plate; 7. a limiting round block; 8. an eccentric wheel; 9. an annular groove; 10. a first rotating wheel; 11. a first drive belt; 12. a double rotating wheel; 13. rotating the column; 14. a second bevel gear; 15. a second belt; 16. rotating the motor; 17. and supporting the box body.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, an automatic detection system and detection equipment for waste lithium batteries comprises a supporting base plate 1, a concave supporting rod 2 is arranged on one side of the top end of the supporting base plate 1, the bottom end of the concave supporting rod 2 is fixedly connected with the bottom end of the supporting base plate 1, a detection assembly 3 is arranged in the groove wall of the concave supporting rod 2, a rotating assembly 4 is arranged on the other side of the top end of the supporting base plate 1, the detection assembly 3 comprises two sliding racks 301, the two sliding racks 301 are directly engaged with a first gear 302, the front surface of the first gear 302 is fixedly connected with a connecting cylinder 303, the back surfaces of the two sliding racks 301 are respectively provided with a connecting rod 304, the opposite surfaces of the two connecting rods 304 are provided with detection pencils 305, the two detection pencils 305 are electrically connected with an external ammeter through a lead, the top ends and the bottom ends of the two sliding racks 301 are respectively fixedly connected with a limiting cylinder 306, rotating assembly 4 is including rotating cylinder 401, the top that the bearing was passed through to rotating cylinder 401's bottom and supporting baseplate 1 rotates to be connected, the outer wall bottom fixedly connected with second gear 402 of rotating cylinder 401, one side meshing of second gear 402 has third gear 403, there is supporting cylinder 404 on the top through connection of third gear 403, the bottom of supporting cylinder 404 is passed through the bearing and is connected with supporting baseplate 1's top rotation, the first bevel gear 405 of top fixedly connected with of supporting cylinder 404, the top of rotating cylinder 401 is provided with year thing ring 406, and the top of carrying thing ring 406 has equidistantly all around seted up a plurality ofly and has put thing circular slot 407, it is used for placing old and useless lithium cell in the thing circular slot 407 to put.

As a technical optimization scheme of the invention, the top and the bottom of the groove wall of the concave supporting rod 2 are respectively provided with two circular sliding grooves 202, four limiting cylinders 306 are respectively connected in the circular sliding grooves 202 in a sliding manner, one ends of the limiting cylinders 306 are respectively and fixedly connected with a limiting disc 203, rectangular sliding grooves are respectively arranged on two sides of the groove walls of the four circular sliding grooves 202, rectangular convex blocks are respectively arranged on the front and the back of the limiting disc 203, the rectangular convex blocks are respectively connected in the rectangular sliding grooves in a sliding manner, a return spring 204 is fixedly connected to one side of the limiting disc 203, and one ends of the four return springs 204 far away from the limiting disc 203 are fixedly connected with the groove walls of the circular sliding grooves 202.

As a technical optimization scheme of the invention, the front face of one sliding rack 301 is provided with an L-shaped connecting plate 5, the L-shaped connecting plate 5 is fixedly connected with the sliding rack 301, two sides of the L-shaped connecting plate 5 are provided with rectangular sliding blocks, two sides of the groove wall of a rectangular sliding hole 201 are provided with rectangular sliding grooves, the two rectangular sliding blocks are respectively connected in the rectangular sliding grooves in a sliding manner, one end of the L-shaped connecting plate 5 far away from the sliding rack 301 is fixedly connected with a C-shaped connecting plate 6, two sides of the groove wall of the C-shaped connecting plate 6 are fixedly connected with limiting round blocks 7, the bottom of the C-shaped connecting plate 6 is provided with an eccentric wheel 8, the front face and the back face of the eccentric wheel 8 are both provided with annular grooves 9, the two limiting round blocks 7 are respectively connected in the two annular grooves 9 in a sliding manner, the front face and the back face of the eccentric wheel 8 are both provided with annular grooves 9, and the inner wall of the C-shaped connecting plate 6 is fixedly connected with the two limiting round blocks 7, the two limit round blocks 7 are respectively connected with the two annular grooves 9 in a sliding mode, so that when the eccentric wheel 8 rotates, the distance between the C-shaped connecting plate 6 and the circle center of the eccentric wheel 8 is the same all the time, the C-shaped connecting plate 6 and the eccentric wheel 8 rotate all the time, the circular vertical movement of the C-shaped connecting plate 6 is carried out synchronously, and the two limit round blocks 7 are arranged to prevent the eccentric wheel 8 and the C-shaped connecting plate 6 from being separated.

As a technical optimization scheme of the invention, a first rotating wheel 10 is fixedly connected to the upper portion of the back face of the eccentric wheel 8, one end, far away from the eccentric wheel 8, of the first rotating wheel 10 is rotatably connected with the front face of the concave supporting rod 2, a first driving belt 11 is sleeved on the outer wall of the first rotating wheel 10, and a double rotating wheel 12 is clamped on one side, far away from the first rotating wheel 10, of the inner wall of the first driving belt 11.

As a technical optimization scheme of the invention, the back of the double rotating wheels 12 is fixedly connected with a rotating column 13, one end of the rotating column 13 is rotatably connected with a first side supporting plate, the rotating column 13 penetrates through the side supporting plate, the bottom end of the side supporting plate is fixedly connected with the top end of the supporting base plate 1, the other end of the rotating column 13 is rotatably connected with a supporting plate, the bottom end of the supporting plate is fixedly connected with the top end of the supporting base plate 1, the outer wall of the rotating column 13 is fixedly connected with a second bevel gear 14, and the bottom end of the second bevel gear 14 is respectively meshed with two sides of the first bevel gear 405.

As a technical optimization scheme of the present invention, a second transmission belt 15 is sleeved on one side of an outer wall of the dual-rotation wheel 12, which is far away from the first transmission belt 11, and a second transmission wheel is clamped on one side of an inner wall of the second transmission belt 15, which is far away from the dual-rotation wheel 12, a rotation motor 16 is fixedly connected to a front surface of the second transmission wheel, and an output end of the rotation motor 16 is fixedly connected to a front surface of the second transmission wheel, so that the rotation motor 16 drives the second transmission belt 15 to rotate after being started, the dual-rotation wheel 12 is driven by the second transmission belt 15 to rotate, the dual-rotation wheel 12 drives the rotation column 13 to rotate on one hand, so that the second bevel gear 14 rotates, and further drives the first bevel gear 405 engaged with the second bevel gear 14 to rotate, so that the support cylinder 404 fixedly connected with the first bevel gear 405 and the third gear 403 fixedly connected with the support cylinder 404 rotate, the third gear 403 rotates to drive the second gear 402 engaged therewith to rotate, thereby driving the rotating cylinder 401 and the carrying ring 406 to rotate;

on the other hand, the double-rotating wheel 12 drives the first transmission belt 11 to rotate, so that the eccentric wheel 8 rotates, the front side and the back side of the eccentric wheel 8 are both provided with an annular groove 9, a limiting round block 7 is arranged in the annular groove 9, the two limiting round blocks 7 are arranged in the C-shaped connecting plate 6, as the rotating circle center of the eccentric wheel 8 does not coincide with the circle center of the longitudinal section of the eccentric wheel 8, the height of the eccentric wheel 8 is periodically changed when the eccentric wheel 8 rotates, so that the C-shaped connecting plate 6 is driven to periodically move up and down, the top end of the C-shaped connecting plate 6 is connected with one sliding rack 301 through the L-shaped connecting plate 5, the two sliding racks 301 are meshed and connected through the first gear 302, when the L-shaped connecting plate 5 drives one sliding rack 301 to move, the other sliding rack 301 moves oppositely, so that the detection pencil 305 fixedly connected with the connecting rod 304 is controlled to detect the waste lithium battery, and when the eccentric wheel 8 rotates for a circle, the two detection test pens 305 detect the waste battery once.

The rotating motor 16 drives the eccentric wheel 8 to rotate, so that the sliding rack 301 reciprocates up and down, the two sliding racks 301 are meshed through the first gear 302, the two sliding racks 301 always move in opposite directions, the two detection test pens 305 are in contact with the positive and negative electrodes of the waste lithium battery, the service life of the waste lithium battery is detected through the ammeter, after the detection is completed, the two detection test pens 305 are separated, the rotating assembly 4 drives the next waste lithium battery to move, the two detection test pens 305 detect the service life of the next waste lithium battery, and therefore the continuous detection function is achieved to electrically contact the positive and negative electrodes of the waste lithium battery.

As a technical optimization scheme of the invention, a supporting box body 17 is fixedly connected to the bottom end of a rotating motor 16, a power supply and a power supply switch are arranged in the supporting box body 17, the power supply and the power supply switch are electrically connected with the rotating motor 16 through conducting wires, the back surface of the supporting box body 17 is fixedly connected with one side of the front surface of a supporting base plate 1, one end of a connecting cylinder 303 far away from a first gear 302 is rotatably connected with the groove wall of a concave supporting rod 2 through a rotating bearing, the front surface of the concave supporting rod 2 is provided with a rectangular sliding hole 201, the outer wall of an L-shaped connecting plate 5 is slidably connected with the rectangular sliding hole 201, two sides of the groove wall of the rectangular sliding hole 201 are provided with rectangular sliding grooves, rectangular sliding blocks are correspondingly arranged on two sides of the L-shaped connecting plate 5, the two rectangular sliding blocks are slidably connected in the rectangular sliding grooves, a limiting effect can be achieved, and the L-shaped connecting plate 5 is prevented from swinging back and forth in the rectangular sliding hole 201, the detection of the waste lithium battery is influenced.

The detection device comprises the following steps:

the method comprises the following steps:

an operator starts the rotating motor 16 to enable the rotating motor 16 to start working, and the rotating motor 16 drives the second transmission belt 15 to rotate after being started, so that the double rotating wheels 12 are driven to rotate;

step two:

the double-rotating wheel 12 drives the rotating column 13 to rotate, and drives the supporting cylinder 404 and the third gear 403 fixedly connected with the supporting cylinder 404 to rotate, so as to drive the rotating cylinder 401 and the carrying ring 406 to rotate, and thus the waste lithium battery rotates;

step three:

the double-rotating wheel 12 drives the first transmission belt 11 to rotate, so that the eccentric wheel 8 rotates, the C-shaped connecting plate 6 is driven to move up and down periodically, the L-shaped connecting plate 5 is driven to move, when the L-shaped connecting plate 5 drives one sliding rack 301 to move, the other sliding rack 301 moves oppositely, and then the detection test pencil 305 fixedly connected with the connecting rod 304 is controlled to detect the waste lithium batteries;

step four:

after the detection test pencil 305 is in contact with the waste lithium battery, the two detection test pencils 305 transmit detected data to the external ammeter, and an operator can visually observe the residual current in the waste lithium battery through the external ammeter.

When the invention is used;

carrying out operation one;

firstly, an operator puts waste lithium batteries in the article placing circular grooves 407 formed in the top ends of the article placing circular rings 406 respectively, and then the operator starts the rotating motor 16 to enable the rotating motor 16 to start working;

carrying out operation two;

after the rotating motor 16 is started, the second transmission belt 15 is driven to rotate, and the double rotating wheels 12 are driven to rotate by the second transmission belt 15;

carrying out operation three;

the double-rotating wheel 12 drives the rotating column 13 to rotate, so that the second bevel gear 14 rotates, and further drives the first bevel gear 405 meshed with the second bevel gear 14 to rotate, so that the supporting cylinder 404 fixedly connected with the first bevel gear 405 and the third gear 403 fixedly connected with the supporting cylinder 404 rotate, the third gear 403 rotates to drive the second gear 402 meshed with the third gear to rotate, so that the rotating cylinder 401 and the carrying ring 406 are driven to rotate, and the waste lithium batteries rotate;

carrying out operation four;

the double-rotating wheel 12 drives the first transmission belt 11 to rotate, so that the eccentric wheel 8 rotates, and the C-shaped connecting plate 6 is driven to move up and down periodically, the top end of the C-shaped connecting plate 6 is connected with one of the sliding racks 301 through the L-shaped connecting plate 5, the two sliding racks 301 are meshed and connected through the first gear 302, when the L-shaped connecting plate 5 drives one of the sliding racks 301 to move, the other sliding rack 301 moves oppositely, the detection electric pen 305 fixedly connected with the connecting rod 304 is controlled to detect the waste lithium battery, and when the eccentric wheel 8 rotates for a circle, the two detection electric pens 305 are contacted with the waste lithium battery once;

carrying out operation five;

after the detection test pencil 305 is in contact with the waste lithium battery, the two detection test pencils 305 transmit detected data to the external ammeter, and an operator can visually observe the residual current in the waste lithium battery through the external ammeter.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides a waste lithium battery detection equipment, includes supporting baseplate (1), its characterized in that: a concave supporting rod (2) is arranged on one side of the top end of the supporting bottom plate (1), a detection assembly (3) is arranged in the groove wall of the concave supporting rod (2), and a rotating assembly (4) is arranged on the other side of the top end of the supporting bottom plate (1);

the detection assembly (3) comprises two sliding racks (301), a first gear (302) is directly meshed with the two sliding racks (301), the front face of the first gear (302) is fixedly connected with a connecting cylinder (303), connecting rods (304) are arranged on the back faces of the two sliding racks (301), detection electropens (305) are arranged on the opposite faces of the two connecting rods (304), and the top ends and the bottom ends of the two sliding racks (301) are fixedly connected with limiting cylinders (306);

the rotating assembly (4) comprises a rotating cylinder (401), a second gear (402) is fixedly connected to the bottom of the outer wall of the rotating cylinder (401), a third gear (403) is meshed with one side of the second gear (402), a supporting cylinder (404) is arranged at the top end of the third gear (403), a first bevel gear (405) is fixedly connected to the top end of the supporting cylinder (404), a loading circular ring (406) is arranged at the top end of the rotating cylinder (401), and a plurality of storage circular grooves (407) are formed in the periphery of the top end of the loading circular ring (406) at equal intervals.

2. The waste lithium battery detection device according to claim 1, characterized in that: in two circular spout (202) were all seted up to the cell wall top and the bottom of spill bracing piece (2), and four spacing cylinder (306) sliding connection respectively is in circular spout (202), the spacing disc of the one end difference fixedly connected with (203) of spacing cylinder (306), just one side fixedly connected with reset spring (204) of spacing disc (203), four the one end that spacing disc (203) were kept away from in reset spring (204) and the cell wall fixed connection of circular spout (202).

3. The waste lithium battery detection device according to claim 1, characterized in that: one of them the front of slip rack (301) is provided with L shape connecting plate (5), just the one end fixedly connected with C shape connecting plate (6) of slip rack (301) are kept away from in L shape connecting plate (5), the spacing circle piece (7) of cell wall both sides fixedly connected with of C shape connecting plate (6), the cell wall that rolling bearing and spill bracing piece (2) were passed through to the one end that first gear (302) were kept away from in connection cylinder (303) rotates and is connected, rectangle slide opening (201) have been seted up in the front of spill bracing piece (2).

4. The waste lithium battery detection device according to claim 3, characterized in that: the bottom of the C-shaped connecting plate (6) is provided with an eccentric wheel (8), the front and the back of the eccentric wheel (8) are provided with annular grooves (9), and the two limiting round blocks (7) are respectively connected in the two annular grooves (9) in a sliding manner.

5. The waste lithium battery detection device according to claim 4, characterized in that: the back upper portion fixedly connected with first runner (10) of eccentric wheel (8), just first driving band (11) have been cup jointed to the outer wall of first runner (10), one side joint that first runner (10) was kept away from to the inner wall of first driving band (11) has two runners (12).

6. The waste lithium battery detection device according to claim 5, characterized in that: the back of the double-rotating wheel (12) is fixedly connected with a rotating column (13), the outer wall of the rotating column (13) is fixedly connected with a second bevel gear (14), and the bottom end of the second bevel gear (14) is respectively meshed with the two sides of the first bevel gear (405).

7. The waste lithium battery detection device according to claim 5, characterized in that: and a second transmission belt (15) is sleeved on one side, far away from the first transmission belt (11), of the outer wall of the double rotating wheel (12), and a second transmission wheel is clamped on one side, far away from the double rotating wheel (12), of the inner wall of the second transmission belt (15).

8. The waste lithium battery detection device according to claim 7, characterized in that: the front surface of the second driving wheel is fixedly connected with a rotating motor (16), and the output end of the rotating motor (16) is fixedly connected with the front surface of the second driving wheel.

9. The waste lithium battery detection device according to claim 8, wherein: the bottom end of the rotating motor (16) is fixedly connected with a supporting box body (17), and the back face of the supporting box body (17) is fixedly connected with one side of the front face of the supporting base plate (1).

10. The automatic detection system of the waste lithium battery detection equipment as claimed in any one of claims 1 to 9, wherein the detection equipment is used by the following steps:

the method comprises the following steps:

an operator starts the rotating motor (16) to enable the rotating motor (16) to start to work, and the rotating motor (16) drives the second transmission belt (15) to rotate after being started, so that the double rotating wheels (12) are driven to rotate;

step two:

the double-rotating wheel (12) drives the rotating column (13) to rotate, and drives the supporting cylinder (404) and the third gear (403) fixedly connected with the supporting cylinder (404) to rotate, so that the rotating cylinder (401) and the carrying ring (406) are driven to rotate, and the waste lithium batteries are rotated;

step three:

the double-rotating wheel (12) drives the first transmission belt (11) to rotate, so that the eccentric wheel (8) rotates, the C-shaped connecting plate (6) is driven to move up and down periodically, the L-shaped connecting plate (5) is driven to move, when the L-shaped connecting plate (5) drives one sliding rack (301) to move, the other sliding rack (301) moves oppositely, and then a detection test pencil (305) fixedly connected with the connecting rod (304) is controlled to detect the waste lithium batteries;

step four:

after the detection test pencil (305) is contacted with the waste lithium battery, the two detection test pencils (305) transmit detected data to the external ammeter, and an operator can visually observe the residual current in the waste lithium battery through the external ammeter.

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