CN220195593U - Full-automatic solar cell bending detection device - Google Patents

Abstract

The utility model discloses a full-automatic solar cell bending detection device, which belongs to the technical field of solar cell detection and comprises the following components: the fixed frame is rotationally provided with two driving rollers, and the two driving rollers are provided with the same conveying belt in a transmission way; the two sides of the top of the fixing frame are fixedly provided with fixing plates, the tops of the two fixing plates are fixedly connected with the same top plate, the right side of the top plate is fixedly provided with two mounting seats, electric push rods are fixedly arranged in the two mounting seats, the output ends of the two electric push rods are fixedly connected with the same detection plate, and the bottoms of the detection plates are fixedly connected with inductors; the top left side fixed mounting of roof has the swash plate, and the outside sliding sleeve of swash plate has linked together the sliding frame, and the bottom fixedly connected with of sliding frame dials the board. According to the utility model, through the mutual coordination between the rotating plate and the inclined plate, the shifting plate can be controlled to perform oblique reciprocating movement, and the solar cell is shifted, so that the solar cell is dispersed, and the influence of stacking on the detection result is prevented.

Description

Full-automatic solar cell bending detection device

Technical Field

The utility model relates to the technical field of solar cell detection, in particular to a full-automatic solar cell bending detection device.

Background

After the printed battery piece is sintered, the battery piece which is partially back-sintered is bent due to shrinkage of the slurry, but the bending degree exceeds a certain degree, so-called bent piece is formed. Bending sheets not only can form many fragments in subsequent tests, but also can affect the grade of the battery sheet (according to the test standard, a battery sheet with a degree of bending exceeding a certain degree is rated as B or the like, even as a defective product). When the test procedure is carried out, the battery piece is turned over by the piece turning device, the sucking disc of the piece turning device cannot completely contact the surface of the bent piece, so that the vacuum sucking action cannot be completed, and in the turning process, the bent battery piece can be thrown out by the piece turning device, and fragments are caused. Fragments are not only generated during the flipping process, but also form at the turntable of the test area. Because the battery piece is also required to be sucked by the sucker at the rotary disc, the bent piece can be thrown out when rotating when the bent piece cannot be sucked by the sucker, and a large amount of fragments are formed.

The patent document with the publication number of CN206602504U discloses a full-automatic solar cell bending detection device, a lifting detection plate is arranged on a conveyor belt conveyor, an inductor is fixedly arranged on the lower surface of the detection plate, a solar cell moves towards the detection plate along with the conveyor belt, a flat solar cell passes through the detection plate along with the movement of the conveyor belt, when the bending piece passes through a gap between the detection plate and the conveyor belt, a bending part on the bending piece touches the inductor on the lower surface of the detection plate, and a controller controls the conveyor belt conveyor to stop working and simultaneously controls a push plate to push the bending piece into a storage box.

In the technical scheme, the solar cell is placed on the conveyor belt for conveying detection, but the detection mode is only suitable for detecting a small amount of flat cell, and once more cells are placed on the conveyor belt, the cell stacks, so that misjudgment of the sensor can be caused, and the detection result is influenced; therefore, we propose a fully automatic solar cell bending detection device to solve this problem.

Disclosure of Invention

The utility model aims to provide a full-automatic solar cell bending detection device so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

a full-automatic solar cell bending detection device comprises: the conveying device comprises a fixing frame, a plurality of driving rollers and a plurality of conveying belts, wherein the two driving rollers are rotatably arranged in the fixing frame, and the same conveying belt is arranged on the two driving rollers in a transmission manner;

the two sides of the top of the fixing frame are fixedly provided with fixing plates, the tops of the two fixing plates are fixedly connected with the same top plate, the right side of the top plate is fixedly provided with two mounting seats, the two mounting seats are internally and fixedly provided with electric push rods, the output ends of the two electric push rods are fixedly connected with the same detection plate, and the bottoms of the detection plates are fixedly connected with inductors;

the top left side fixed mounting of roof has the swash plate, the outside sliding sleeve of swash plate has a sliding frame, and the bottom fixedly connected with of sliding frame dials the board, and the through-hole has been seted up to the front side of swash plate, the connecting axle is installed in the through-hole internal rotation, and the equal fixedly connected with of both ends changes the board around the connecting axle, two it has the round bar to change the equal fixed mounting in one side that the board kept away from each other, the outside rotation of round bar has cup jointed the connecting plate, two the connecting plate rotates respectively and connects both sides around the sliding frame.

Preferably, the front side of mount fixed mounting has the connecting rod, the top fixedly connected with installation section of thick bamboo of connecting rod, fixed mounting has the cylinder in the installation section of thick bamboo, fixedly connected with push pedal on the output of cylinder.

Preferably, the front side of mount fixed mounting has L board, the rear side fixedly connected with servo motor of L board, servo motor's output shaft and corresponding driving roller fixed connection.

Preferably, the top of swash plate fixed mounting has driving motor, fixedly connected with worm on driving motor's the output shaft, the outside of connecting axle has fixedly cup jointed the worm wheel, worm and worm wheel meshing mutually.

Preferably, the front side and the rear side of the sloping plate are fixedly connected with connecting columns, two ends of the connecting columns, which are far away from each other, are fixedly connected with supporting rods, and the bottom ends of the two supporting rods are respectively fixedly connected with the tops of the corresponding fixing plates.

Preferably, a square hole is formed in the top of the inclined plate, and the worm wheel is arranged in the square hole.

According to the full-automatic solar cell bending detection device, an electric push rod is started to drive a detection plate to conduct lifting movement, then a solar cell is placed on a conveying belt, a driving roller is driven to rotate by starting a servo motor, so that the conveying belt is driven to operate to transport the solar cell, a driving motor is started to drive a worm to rotate, the worm drives two rotating plates to conduct circular movement through meshing with a worm wheel, the two rotating plates respectively drive a sliding frame to conduct reciprocating movement along an inclined plate through corresponding connecting plates, and the sliding frame drives a poking plate to conduct oblique reciprocating movement, so that stacked solar cells are scattered;

according to the full-automatic solar cell bending detection device, the sensor is used for blocking the solar cell bending, the servo motor is controlled to be closed, so that the conveying belt is stopped, the pushing plate is driven to move backwards by the starting cylinder, the solar cell bending is pushed backwards, and therefore the solar cell bending is conveniently sorted;

the solar cell stirring device is reasonable in structural design, and the stirring plate can be controlled to perform oblique reciprocating movement through the mutual coordination among the rotating plate, the connecting plate, the sliding frame and the inclined plate, so that the solar cell can be stirred, and the solar cell can be uniformly dispersed, and the phenomenon that the detection result is influenced by stacking is prevented.

Drawings

Fig. 1 is a schematic perspective view of a full-automatic solar cell bending detection device according to the present utility model;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

fig. 3 is a schematic cross-sectional structure diagram of a full-automatic solar cell bending detection device according to the present utility model.

In the figure: 1. a fixing frame; 2. a driving roller; 3. a conveyor belt; 4. a fixing plate; 5. a top plate; 6. an electric push rod; 7. a detection plate; 8. an inductor; 9. a sloping plate; 10. a poking plate; 11. a connecting column; 12. a cylinder; 13. a push plate; 14. a connecting plate; 15. a connecting shaft; 16. a round bar; 17. a rotating plate; 18. a worm wheel; 19. a worm; 20. a driving motor; 21. a sliding frame; 22. a servo motor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-3, a full-automatic solar cell bending detection device includes: the device comprises a fixing frame 1, two driving rollers 2 are rotatably arranged in the fixing frame 1, and the two driving rollers 2 are provided with the same conveying belt 3 in a transmission way;

the two sides around the top of the fixing frame 1 are fixedly provided with fixing plates 4, the tops of the two fixing plates 4 are fixedly connected with the same top plate 5, the right side of the top plate 5 is fixedly provided with two mounting seats, the two mounting seats are internally and fixedly provided with electric push rods 6, the output ends of the two electric push rods 6 are fixedly connected with the same detection plate 7, and the bottoms of the detection plates 7 are fixedly connected with an inductor 8;

the top left side fixed mounting of roof 5 has swash plate 9, and the outside sliding sleeve of swash plate 9 has linked together slide frame 21, and the bottom fixedly connected with of slide frame 21 dials board 10, and the through-hole has been seted up to the front side of swash plate 9, and connecting axle 15 is installed to the through-hole internal rotation, and the front and back both ends of connecting axle 15 are all fixedly connected with swivel plate 17, and the equal fixed mounting in one side that two swivel plates 17 kept away from each other has round bar 16, and connecting plate 14 has been cup jointed in the outside rotation of round bar 16, and two connecting plates 14 rotate respectively and connect the front and back both sides at slide frame 21.

In this embodiment, the front side fixed mounting of mount 1 has the connecting rod, and the top fixedly connected with installation section of thick bamboo of connecting rod, fixedly mounted with cylinder 12 in the installation section of thick bamboo, fixedly connected with push pedal 13 on the output of cylinder 12, the front side fixed mounting of mount 1 has the L board, and the rear side fixedly connected with servo motor 22 of L board, servo motor 22's output shaft and the driving roller 2 fixed connection that corresponds are convenient for drive driving roller 2 rotation.

In this embodiment, a driving motor 20 is fixedly mounted on the top of the swash plate 9, a worm 19 is fixedly connected to an output shaft of the driving motor 20, a worm wheel 18 is fixedly sleeved on the outer side of the connecting shaft 15, and the worm 19 is meshed with the worm wheel 18.

It should be noted that, square holes are formed at the top of the inclined plate 9, and the worm wheel 18 is disposed in the square holes, so that the worm wheel 18 is convenient to be disposed.

In this embodiment, the front and back both sides of swash plate 9 are all fixedly connected with spliced pole 11, and the equal fixedly connected with bracing piece of one end that two spliced poles 11 keep away from each other, the bottom of two bracing pieces respectively with the top fixed connection of corresponding fixed plate 4, promote the installation stability to swash plate 9.

The working principle of the utility model is as follows: the detection plate 7 is driven to move up and down by starting the electric push rod 6, then the solar cell is placed on the conveying belt 3, the driving roller 2 is driven to rotate by starting the servo motor 22, so that the conveying belt 3 is driven to move to transport the solar cell, then the driving motor 20 is started to drive the worm 19 to rotate, the worm 19 drives the two rotating plates 17 to move circularly through meshing with the worm wheel 18, the two rotating plates 17 respectively drive the sliding frame 21 to reciprocate along the inclined plate 9 through the corresponding connecting plate 14, the sliding frame 21 drives the poking plate 10 to move obliquely and reciprocally, and therefore stacked solar cell is scattered, the bent solar cell is blocked through the sensor 8, and the conveying belt 3 is stopped by controlling the servo motor 22, the push plate 13 is driven to move backwards through the starting cylinder 12, the bent solar cell is pushed backwards, and therefore the bent solar cell is conveniently sorted.

The full-automatic solar cell bending detection device provided by the utility model is described in detail. The principles and embodiments of the present utility model have been described herein with reference to specific examples, which are intended to be merely illustrative of the methods of the present utility model and their core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the utility model can be made without departing from the principles of the utility model and these modifications and adaptations are intended to be within the scope of the utility model as defined in the following claims.

Claims (6)

1. A full-automatic solar wafer bending detection device is characterized by comprising: the conveying device comprises a fixing frame (1), wherein two driving rollers (2) are rotatably arranged in the fixing frame (1), and the same conveying belt (3) is arranged on the two driving rollers (2) in a transmission manner;

the two sides around the top of mount (1) all fixedly mounted with fixed plate (4), two the top of fixed plate (4) fixedly connected with same roof (5), the top right side of roof (5) fixedly mounted with two mount pads, all fixedly mounted with electric putter (6) in two mount pads, two fixedly connected with same pick-up plate (7) on the output of electric putter (6), the bottom fixedly connected with inductor (8) of pick-up plate (7);

the top left side fixed mounting of roof (5) has swash plate (9), the outside sliding sleeve of swash plate (9) has cup jointed sliding frame (21), and the bottom fixedly connected with of sliding frame (21) dials board (10), and the through-hole has been seted up to the front side of swash plate (9), connecting axle (15) are installed to the through-hole internal rotation, and both ends are all fixedly connected with revolving plate (17) around connecting axle (15), two equal fixed mounting in one side that revolving plate (17) kept away from each other has round bar (16), the outside rotation of round bar (16) cup joints connecting plate (14), two connecting plate (14) rotate respectively and connect both sides around sliding frame (21).

2. The full-automatic solar cell bending detection device according to claim 1, wherein a connecting rod is fixedly installed on the front side of the fixing frame (1), an installation cylinder is fixedly connected to the top end of the connecting rod, an air cylinder (12) is fixedly installed in the installation cylinder, and a push plate (13) is fixedly connected to the output end of the air cylinder (12).

3. The full-automatic solar cell bending detection device according to claim 1, wherein an L plate is fixedly installed on the front side of the fixing frame (1), a servo motor (22) is fixedly connected to the rear side of the L plate, and an output shaft of the servo motor (22) is fixedly connected with a corresponding driving roller (2).

4. The full-automatic solar cell bending detection device according to claim 1, wherein a driving motor (20) is fixedly arranged at the top of the inclined plate (9), a worm (19) is fixedly connected to an output shaft of the driving motor (20), a worm wheel (18) is fixedly sleeved on the outer side of the connecting shaft (15), and the worm (19) is meshed with the worm wheel (18).

5. The full-automatic solar cell bending detection device according to claim 1, wherein connecting columns (11) are fixedly connected to the front side and the rear side of the inclined plate (9), support rods are fixedly connected to one ends, away from each other, of the two connecting columns (11), and the bottom ends of the two support rods are fixedly connected to the tops of the corresponding fixing plates (4) respectively.

6. The full-automatic solar cell bending detection device according to claim 4, wherein a square hole is formed in the top of the inclined plate (9), and the worm wheel (18) is arranged in the square hole.