CN119153372A - Solar cell silicon chip stromatolite side flower basket structure - Google Patents

Abstract

The invention discloses a solar cell silicon wafer laminated side flower basket structure, which relates to the technical field of photovoltaic cells and comprises a bottom plate, wherein universal wheels are fixedly connected to four corners of the bottom end of the bottom plate, a push-pull handle is fixedly connected to one side wall of one end of the bottom plate, two support plates are symmetrically and fixedly connected to the side wall of the top end of the bottom plate, and the same placing plate is fixedly connected to the side walls of the top ends of the two support plates. According to the invention, when the curved solar cell silicon wafer is required to be transported by using the flower basket structure, the angle of the fixing plate is adjusted according to the inclination angles of the two ends of the solar cell silicon wafer, so that the two ends of the solar cell silicon wafer are conveniently fixed by using the fixing plate, the curved solar cell silicon wafer is firmly fixed, different fixing plates are not required to be replaced according to the bending angle of the curved solar cell silicon wafer, and the working efficiency and the reliability of the solar cell silicon wafer in production are greatly improved.

Description

Solar cell silicon chip stromatolite side flower basket structure

Technical Field

The invention belongs to the technical field of photovoltaic cells, and particularly relates to a solar cell silicon wafer lamination side-discharge basket structure.

Background

When the solar cell silicon wafer is subjected to one production step, the processed solar cell silicon wafer is required to be conveyed to the position of the next production step by using the flower basket structure, the solar cell silicon wafer is conveyed by using the flower basket structure, so that the silicon wafer can be effectively protected, the loss caused by collision, scratch and the like in the conveying and processing processes is reduced, the material loss is reduced, and the production cost is further reduced.

In the prior art, a plurality of fixing plates are generally utilized to form a plurality of placing spaces, then solar cell silicon wafers are directly placed in the placing spaces, then the fixing plates with adjustable positions are utilized to fix the solar cell silicon wafers, and then the conveying of the solar cell silicon wafers is completed through moving the basket structures, but in Building Integrated Photovoltaic (BIPV) application, in order to match the curved surface design of a building, such as curved surface roofs and vertical surfaces, the solar cell silicon wafers are designed to adapt to the shapes of the curved surfaces, when the fixing plates are directly utilized to fix the curved cell silicon wafers, the surfaces of the cell silicon wafers are easily damaged, when the fixing plates with different shapes are designed according to the shapes of the curved cell silicon wafers to fix the cell silicon wafers, the required cost is higher, and when the bending angles of the produced cell silicon wafers in each batch are different, the corresponding fixing plates are also required to be replaced according to the bending angles of the cell silicon wafers, so that the working efficiency and the reliability in the production of the solar cell silicon wafers are greatly reduced.

Therefore, we propose a solar cell silicon wafer lamination side flower basket structure to solve the above problems.

Disclosure of Invention

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

The utility model provides a solar cell silicon chip stromatolite side flower basket structure, includes the bottom plate, the equal fixedly connected with universal wheel in bottom four corners department of bottom plate, the equal fixedly connected with push-and-pull handle of one end lateral wall of bottom plate, two the top lateral wall symmetry fixedly connected with of bottom plate two the same board of placing of top lateral wall fixedly connected with of extension board, place the lateral wall of board and seted up a plurality of openings of placing, place two first recesses of open-ended upper and lower both ends inner wall symmetry, the equal fixedly connected with of inner wall of first recess is electronic slide rail, the equal sliding connection of lateral wall of first electronic slide rail has first slide, the equal fixedly connected with initiative supporting component of lateral wall of first slide board, place two second recesses of open-ended upper and lower both ends inner wall symmetry and seted up, the equal fixedly connected with auxiliary support component of one end inner wall of second recess, place two third recesses of open-ended both ends inner wall symmetry and seted up, the inner wall rotation of third recess is connected with reinforcing component.

Preferably, the initiative supporting component comprises a mounting frame fixedly connected with the side wall of the first sliding plate, the inner wall of the mounting frame is fixedly connected with a second electric sliding rail, the side wall of the top end of the second electric sliding rail is fixedly connected with a second sliding plate, a first cavity is formed in the inner wall of the second sliding plate, a first motor is fixedly connected with the inner wall of the bottom end of the first cavity, and the side wall of the top end of the second sliding plate is rotatably connected with a first electric telescopic rod.

Preferably, the output end of the first motor penetrates through the side wall of the second sliding plate and is fixedly connected with one end of a corresponding first electric telescopic rod, the telescopic end of the first electric telescopic rod is fixedly connected with a first U-shaped plate, two second electric telescopic rods are symmetrically and fixedly connected to the inner walls of the two ends of the first U-shaped plate, and the telescopic end of the second electric telescopic rod is fixedly connected with a fixing plate.

Preferably, the auxiliary support assembly comprises a third electric telescopic rod fixedly connected with the inner wall of one end of the second groove, a supporting frame is fixedly connected to the telescopic end of the third electric telescopic rod, a third electric sliding rail is fixedly connected to the inner wall of the bottom end of the supporting frame, a third sliding plate is fixedly connected to the side wall of the top end of the third electric sliding rail, a second cavity is formed in the third sliding plate, and a second motor is fixedly connected to the inner wall of the second cavity.

Preferably, the top side wall of the third sliding plate is all rotationally connected with a fourth electric telescopic rod, the telescopic ends of the second motor penetrate through the side wall of the third sliding plate and one end of the corresponding fourth electric telescopic rod, the telescopic ends of the fourth electric telescopic rod are all fixedly connected with a second U-shaped plate, two fifth electric telescopic rods are symmetrically and fixedly connected with the inner walls of the two ends of the second U-shaped plate, and the telescopic ends of the fifth electric telescopic rod are all fixedly connected with clamping plates.

Preferably, the reinforcement assembly comprises a bidirectional screw rod rotationally connected with the inner wall of the third groove, two movable plates are rotationally connected with the rod wall of the bidirectional screw rod in a threaded mode, a plurality of third motors are fixedly connected with the side wall of the placement plate, the output ends of the third motors penetrate through the side wall of the placement plate and one end fixedly connected with the corresponding bidirectional screw rod, an eighth electric telescopic rod is fixedly connected with the side wall of one end of the movable plate, and a connecting plate is fixedly connected with the telescopic end of the eighth electric telescopic rod.

Preferably, the one end lateral wall of connecting plate is all fixedly connected with sixth electric telescopic handle, the flexible end of sixth electric telescopic handle rotates and is connected with first round bar, the equal fixedly connected with gusset plate of pole wall of first round bar, the one end lateral wall fixedly connected with seventh electric telescopic handle of connecting plate, the flexible end of seventh electric telescopic handle rotates and is connected with the second round bar, the fourth recess has been seted up to the one end lateral wall of gusset plate.

Preferably, the inner wall of the fourth groove is slidably connected with a moving block, the side wall of the moving block is rotationally connected with the outer wall of the second round rod, the inner walls of the two ends of the third groove are fixedly connected with the same guide rod, the rod walls of the guide rod are slidably connected with two limiting plates, and the side walls of the bottom ends of the limiting plates are fixedly connected with the side walls of the top ends of the corresponding moving plates.

Compared with the prior art, the invention has the beneficial effects that:

through initiative supporting component, auxiliary stay subassembly and the reinforcement subassembly that set up can utilize the basket of flowers structure to transport the solar cell silicon chip of curved surface when handling, the angle of fixed plate is adjusted according to the inclination at solar cell silicon chip both ends, be convenient for utilize the fixed plate to fix the both ends of solar cell silicon chip, simultaneously can make the inclination of splint and the both sides inclination phase-match of the middle bend of solar cell silicon chip, be convenient for utilize splint to fix the both sides of the middle bend of solar cell silicon chip, realize fixing the upper and lower both ends of curved surface solar cell silicon chip, can also adjust the inclination of reinforcement plate, make the reinforcement plate fix the both ends of the middle bend of solar cell silicon chip, thereby realize firmly fixing curved surface solar cell silicon chip, avoid directly utilizing the fixed plate to fix the battery silicon chip of curved surface and bring the damage to the battery silicon chip surface, and need not change different fixed plates according to curved surface solar cell silicon chip's bend angle, work efficiency and reliability when greatly improving solar cell silicon chip production.

Drawings

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

FIG. 2 is a schematic view of a second angle structure of the present invention;

FIG. 3 is a portion of the present invention schematic cross-sectional view of the structure;

FIG. 4 is an enlarged view of portion A of FIG. 3 in accordance with the present invention;

FIG. 5 is a schematic view of a portion of the structure of the present invention;

FIG. 6 is a schematic view of another part of the structure of the present invention.

In the figure, 1, a bottom plate; 2, universal wheels, 3, push-pull handles, 4, support plates, 5, placement plates, 6, placement openings, 7, first grooves, 8, first electric slide rails, 9, first slide plates, 10, active support assemblies, 101, mounting frames, 102, second electric slide rails, 103, second slide plates, 104, first cavities, 105, first motors, 106, first electric telescopic rods, 107, first U-shaped plates, 108, second electric telescopic rods, 109, fixed plates, 11, second grooves, 12, auxiliary support assemblies, 121, third electric telescopic rods, 122, support frames, 123, third electric slide rails, 124, third slide plates, 125, second cavities, 126, second motors, 127, fourth electric telescopic rods, 128, second U-shaped plates, 129, fifth electric telescopic rods, 1210, clamping plates, 13, third grooves, 14, reinforcing assemblies, 141, bi-directional screws, 142, moving plates, 143, third motors, 144, connecting plates, 145, sixth electric telescopic rods, 146, first reinforcing plates, 147, seventh electric telescopic rods, 1414, eight electric telescopic rods, 1413, eight electric telescopic rods, and eight electric guide blocks.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments.

The following electrical components are electrically connected with the peripheral PLC controller.

Referring to fig. 1-6, a solar cell silicon wafer lamination side flower basket structure comprises a bottom plate 1, universal wheels 2 are fixedly connected to four corners of the bottom end of the bottom plate 1, push-pull handles 3 are fixedly connected to one end side wall of the bottom plate 1, two support plates 4 are symmetrically and fixedly connected to the top end side wall of the bottom plate 1, one placement plate 5 is fixedly connected to the top end side wall of the two support plates 4, a plurality of placement openings 6 are formed in the side wall of the placement plate 5, two first grooves 7 are symmetrically formed in the inner walls of the upper end and the lower end of the placement openings 6, first sliding rails 8 are fixedly connected to the inner walls of the first grooves 7, first sliding plates 9 are fixedly connected to the side walls of the first sliding rails 8, active supporting assemblies 10 are fixedly connected to the side walls of the first sliding plates 9, two second grooves 11 are symmetrically formed in the inner walls of the upper end and the lower end of the placement openings 6, auxiliary supporting assemblies 12 are fixedly connected to one end inner walls of the second grooves 11, two third grooves 13 are symmetrically formed in the inner walls of the two ends of the placement openings 6, and reinforcing assemblies 14 are rotatably connected to the inner walls of the third grooves 13.

In the embodiment, the active supporting assembly 10 comprises a mounting frame 101 fixedly connected with the side wall of the first sliding plate 9, wherein the inner wall of the mounting frame 101 is fixedly connected with a second electric sliding rail 102, the top side wall of the second electric sliding rail 102 is slidably connected with a second sliding plate 103, a first cavity 104 is formed in the inner wall of the second sliding plate 103, a first motor 105 is fixedly connected with the bottom end inner wall of the first cavity 104, and the top side wall of the second sliding plate 103 is rotatably connected with a first electric telescopic rod 106;

The output end of the first motor 105 penetrates through the side wall of the second sliding plate 103 and is fixedly connected with one end of a corresponding first electric telescopic rod 106, the telescopic end of the first electric telescopic rod 106 is fixedly connected with a first U-shaped plate 107, two second electric telescopic rods 108 are symmetrically and fixedly connected with the inner walls of the two ends of the first U-shaped plate 107, and the telescopic end of the second electric telescopic rod 108 is fixedly connected with a fixing plate 109.

Specifically, when the curved solar cell silicon wafer needs to be transported by using the basket structure, the angle of the fixing plate 109 can be adjusted according to the inclination angles of the two ends of the solar cell silicon wafer, so that the two ends of the solar cell silicon wafer can be conveniently fixed by using the fixing plate 109.

In the embodiment, the auxiliary supporting component 12 includes a third electric telescopic rod 121 fixedly connected to an inner wall of one end of the second groove 11, the telescopic ends of the third electric telescopic rod 121 are all fixedly connected with a supporting frame 122, the inner walls of the bottom ends of the supporting frame 122 are all fixedly connected with a third electric sliding rail 123, the side walls of the top ends of the third electric sliding rail 123 are all slidably connected with a third sliding plate 124, a second cavity 125 is formed in the third sliding plate 124, and the inner walls of the second cavity 125 are all fixedly connected with a second motor 126;

The top side wall of the third sliding plate 124 is rotationally connected with a fourth electric telescopic rod 127, the telescopic ends of the second motor 126 penetrate through the side wall of the third sliding plate 124 and one end of the corresponding fourth electric telescopic rod 127, the telescopic ends of the fourth electric telescopic rod 127 are fixedly connected with a second U-shaped plate 128, the inner walls of the two ends of the second U-shaped plate 128 are symmetrically and fixedly connected with two fifth electric telescopic rods 129, and the telescopic ends of the fifth electric telescopic rods 129 are fixedly connected with clamping plates 1210.

Specifically, the inclination angle of the clamping plate 1210 can be matched with the inclination angles of two sides of the middle bending part of the solar cell silicon wafer, so that the clamping plate 1210 can be used for fixing two sides of the middle bending part of the solar cell silicon wafer conveniently, and the upper end and the lower end of the curved surface solar cell silicon wafer can be fixed.

In the embodiment, the reinforcing component 14 includes a bidirectional screw rod 141 rotatably connected to the inner wall of the third groove 13, the rod walls of the bidirectional screw rod 141 are all in threaded rotation connection with two moving plates 142, the side wall of the placing plate 5 is fixedly connected with a plurality of third motors 143, the output ends of the third motors 143 penetrate through the side wall of the placing plate 5 and are fixedly connected with one end of the corresponding bidirectional screw rod 141, one end side wall of the moving plate 142 is fixedly connected with an eighth electric telescopic rod 1414, and the telescopic ends of the eighth electric telescopic rod 1414 are all fixedly connected with connecting plates 144;

the side wall of one end of the connecting plate 144 is fixedly connected with a sixth electric telescopic rod 145, the telescopic end of the sixth electric telescopic rod 145 is rotationally connected with a first round rod 146, the rod wall of the first round rod 146 is fixedly connected with a reinforcing plate 147, the side wall of one end of the connecting plate 144 is fixedly connected with a seventh electric telescopic rod 148, the telescopic end of the seventh electric telescopic rod 148 is rotationally connected with a second round rod 149, and the side wall of one end of the reinforcing plate 147 is provided with a fourth groove 1410;

The inner wall of the fourth groove 1410 is slidably connected with a moving block 1411, the side wall of the moving block 1411 is rotatably connected with the outer wall of the second round rod 149, the inner walls of the two ends of the third groove 13 are fixedly connected with the same guide rod 1412, the rod walls of the guide rod 1412 are slidably connected with two limiting plates 1413, the bottom side walls of the limiting plates 1413 are fixedly connected with the top side walls of the corresponding moving plates 142, and in the moving process of the moving plates 142, the limiting plates 1413 are slidably connected on the rod walls of the guide rod 1412, at this time, the limiting plates 1413 limit the moving plates 142, so that the moving plates 142 are prevented from being unable to move due to the fact that the moving plates 142 follow the bidirectional screw rod 141 to rotate, and stable movement of the moving plates 142 is ensured.

Specifically, the inclination angle of the reinforcing plate 147 can be adjusted, so that the reinforcing plate 147 can fix the two ends of the middle bending part of the solar cell silicon wafer, and the curved surface solar cell silicon wafer can be firmly fixed.

The principle of operation of the present invention will now be described as follows:

In the invention, when a basket structure is required to convey the solar cell silicon wafer, the second electric slide rail 102 is firstly controlled to start to drive the two second slide plates 103 to move, the distance between the two second slide plates 103 is matched with the distance between two ends of the solar cell silicon wafer, then the first motor 105 is controlled to start to drive the first electric telescopic rod 106 to rotate to drive the first U-shaped plate 107 to rotate, the angle of the opening above the first U-shaped plate 107 can be matched with the inclination angle of the two ends of the solar cell silicon wafer, then the bottom end of the solar cell silicon wafer is placed in the first U-shaped plate 107 at the two ends of the bottom of the placement opening 6 by a worker, then the second electric telescopic rod 108 is controlled to start to drive the fixed plate 109 to move, and the fixed plate 109 rotates along with the rotation in the rotation process of the first U-shaped plate 107 at the moment, at this time, the inclination angle of the fixing plate 109 is matched with the inclination angle of the outer wall of the solar cell silicon wafer, the bottom of the solar cell silicon wafer is fixed by the fixing plate 109, after the fixing of the bottom of the solar cell silicon wafer is completed, the first electric telescopic rods 106 at the bottom of the placement opening 6 are controlled to be started to drive the solar cell silicon wafer to move upwards for a certain distance, then the two first electric telescopic rods 106 above the placement opening 6 are controlled to be started to drive the two corresponding first U-shaped plates 107 to move downwards, the openings of the first U-shaped plates 107 are positioned at the two ends of the solar cell silicon wafer, then the corresponding second electric telescopic rods 108 are controlled to be started, the two ends above the solar cell silicon wafer are fixed by the fixing plate 109, at this time, the simple positioning of the solar cell silicon wafer is completed, then the third electric telescopic rods 121 are controlled to be started to drive the supporting frame 122 to move, the supporting frame 122 and two sides of the middle bending position of the solar cell silicon wafer are arranged on the same plane, the third electric sliding rail 123 is controlled to start to drive the two third sliding plates 124 to move, the two third sliding plates 124 are respectively arranged under two sides of the middle bending position of the solar cell silicon wafer, the second motor 126 is controlled to start to drive the fourth electric telescopic rod 127 to rotate to drive the second U-shaped plate 128 to rotate, the angle of the second U-shaped plate 128 can be matched with the inclination angles of two sides of the middle bending position of the solar cell silicon wafer, the fourth electric telescopic rod 127 is controlled to start to drive the second U-shaped plate 128 to move towards one end of the solar cell silicon wafer, the inner wall of the second U-shaped plate 128 is positioned at two sides of the solar cell silicon wafer, the fifth electric telescopic rod 129 is controlled to start to drive the clamping plate 1210 to move, the inclination angles of the clamping plate 1210 are matched with the inclination angles of two sides of the middle bending position of the solar cell silicon wafer, the clamping plate 1210 is utilized to fix the two sides of the middle bending position of the solar cell silicon wafer at the moment, fixing of the upper end and the lower end of the solar cell is completed, the third motor 143 is controlled to rotate, the third motor 141 is driven to rotate to reinforce the two ends of the solar cell silicon wafer, the two electric telescopic rods 148 are driven to stretch out of the two electric telescopic rods 148, the two electric telescopic rods 148 are driven to stretch out and move towards one end of the middle bending position of the solar cell silicon wafer, or the two electric telescopic rods 148 are stretched out and stretch out and move to enable the two electric rods 148 to stretch out and move to enable the two electric rods to be positioned at the middle section to stretch out and to be positioned at the end of the middle section of the silicon wafer to stretch to a silicon wafer to stretch 148 to a flexible plate to stretch to a flexible plate to move 148 to a flexible plate to stretch to a flexible plate to is positioned. At this time, along with the process that the seventh electric telescopic rod 148 stretches out or contracts, the second round rod 149 drives the moving block 1411 to move inside the fourth groove 1410, at this time, the reinforcing plate 147 rotates around the first round rod 146, after the reinforcing plate 147 rotates to an angle matched with two ends of the middle bending position of the solar cell silicon wafer, the eighth electric telescopic rod 1414 is controlled to start, the connecting plate 144 and the reinforcing plate 147 are driven to move towards one side of the solar cell silicon wafer, the two sides of the solar cell silicon wafer are fixed by using the reinforcing plate 147 with an adjusted angle, the two sides of the solar cell silicon wafer are ensured to be firmly fixed by using the solar cell silicon wafer when the basket structure is used for conveying the solar cell silicon wafer, when the solar cell silicon wafer is required to be taken out from the basket structure by using the mechanical arm, the solar cell silicon wafer is not fixed by using the solar cell silicon wafer, then the reinforcing plate 147 and the clamping plate 1210 is controlled to start, the first electric slide rail 8 is driven to move, the solar cell silicon wafer is driven to move from the inside the placing opening 6, the mechanical arm is convenient to convey the solar cell silicon wafer to a production line, the solar cell silicon wafer is required to be fixed by using the basket structure to the solar cell silicon wafer, the two sides of the solar cell silicon wafer can also be fixed by using the inclined angle, the two ends of the solar cell silicon wafer can be further fixed by using the clamping plate 1210, the two sides of the solar cell silicon wafer can be fixed by using the middle bending plate 1210, and the inclined angle can be further fixed by using the middle bending plate is also can be adjusted by using the inclined angle, and the solar cell silicon wafer can be fixed by the middle plate 1210, and the two ends can be fixed by the middle plate is also can be fixed by the inclined by the angle and the solar cell silicon wafer is 109 when the middle plate is required to be fixed by the solar cell silicon wafer is positioned at the middle side and can is fixed by the bending plate and can is fixed and can be fixed by the opposite side and can be fixed and is convenient. Thereby realizing firmly fixing the curved surface solar cell silicon wafer, avoiding damage to the surface of the cell silicon wafer caused by directly fixing the curved surface cell silicon wafer by using the fixing plate 109, and replacing different fixing plates 109 according to the bending angle of the curved surface solar cell silicon wafer, thereby greatly improving the working efficiency and the reliability of the solar cell silicon wafer during production.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (5)

1. The utility model provides a solar cell silicon chip stromatolite side flower basket structure, includes bottom plate (1), its characterized in that, bottom four corners department of bottom plate (1) all fixedly connected with universal wheel (2), the equal sliding connection of one end lateral wall of bottom plate (1) has push-and-pull handle (3), the equal fixedly connected with of top lateral wall of bottom plate (1) two extension boards (4), two the top lateral wall of extension boards (4) fixedly connected with is same places board (5), place the lateral wall of board (5) and offered a plurality of openings (6), place two first recesses (7) of upper and lower both ends inner wall symmetry of opening (6) have been offered, the inner wall of first recess (7) all fixedly connected with first electronic slide rail (8), the equal sliding connection of lateral wall of first electronic slide rail (8) has first slide (9), the equal fixedly connected with initiative supporting component (10) of lateral wall of first slide rail (9), place the upper and lower both ends inner wall symmetry of opening (6) has offered two second recesses (11), the second recess (11) have the supplementary supporting component (12) of both ends (13) are offered to rotate the inner wall symmetry, the both ends (13) have the inner wall of opening (13) to be connected with.

The driving support assembly (10) comprises a mounting frame (101) fixedly connected with the side wall of a first sliding plate (9), the inner wall of the mounting frame (101) is fixedly connected with a second electric sliding rail (102), the top side wall of the second electric sliding rail (102) is slidably connected with a second sliding plate (103), a first cavity (104) is formed in the inner wall of the second sliding plate (103), a first motor (105) is fixedly connected with the bottom end inner wall of the first cavity (104), and a first electric telescopic rod (106) is rotatably connected with the top side wall of the second sliding plate (103);

The output ends of the first motors (105) penetrate through the side walls of the second sliding plates (103) and are fixedly connected with one ends of corresponding first electric telescopic rods (106), the telescopic ends of the first electric telescopic rods (106) are fixedly connected with first U-shaped plates (107), the inner walls of the two ends of the first U-shaped plates (107) are symmetrically and fixedly connected with two second electric telescopic rods (108), and the telescopic ends of the second electric telescopic rods (108) are fixedly connected with fixed plates (109);

The reinforcing component (14) comprises a bidirectional screw rod (141) rotationally connected with the inner wall of a third groove (13), two movable plates (142) are rotationally connected with the rod wall of the bidirectional screw rod (141) in a threaded mode, a plurality of third motors (143) are fixedly connected with the side wall of the placing plate (5), the output ends of the third motors (143) penetrate through the side wall of the placing plate (5) and one end fixedly connected with the corresponding bidirectional screw rod (141), an eighth electric telescopic rod (1414) is fixedly connected with one end side wall of the movable plate (142), and a connecting plate (144) is fixedly connected with the telescopic end of the eighth electric telescopic rod (1414).

2. The solar cell silicon wafer laminated side flower basket structure according to claim 1, wherein the auxiliary supporting component (12) comprises a third electric telescopic rod (121) fixedly connected with the inner wall of one end of the second groove (11), the telescopic end of the third electric telescopic rod (121) is fixedly connected with a supporting frame (122), the inner wall of the bottom end of the supporting frame (122) is fixedly connected with a third electric sliding rail (123), the side wall of the top end of the third electric sliding rail (123) is fixedly connected with a third sliding plate (124), a second cavity (125) is formed in the third sliding plate (124), and a second motor (126) is fixedly connected with the inner wall of the second cavity (125).

3. The solar cell silicon wafer laminated side flower basket structure according to claim 2, wherein the top side walls of the third sliding plate (124) are respectively and rotatably connected with a fourth electric telescopic rod (127), the telescopic ends of the second motors (126) respectively penetrate through the side walls of the third sliding plate (124) and one end of the corresponding fourth electric telescopic rod (127), the telescopic ends of the fourth electric telescopic rods (127) are respectively and fixedly connected with a second U-shaped plate (128), two fifth electric telescopic rods (129) are symmetrically and fixedly connected with inner walls of two ends of the second U-shaped plate (128), and clamping plates (1210) are respectively and fixedly connected with telescopic ends of the fifth electric telescopic rods (129).

4. The solar cell silicon wafer laminated side flower basket structure according to claim 1, wherein a sixth electric telescopic rod (145) is fixedly connected to one end side wall of the connecting plate (144), a first round rod (146) is rotatably connected to a telescopic end of the sixth electric telescopic rod (145), a reinforcing plate (147) is fixedly connected to a rod wall of the first round rod (146), a seventh electric telescopic rod (148) is fixedly connected to one end side wall of the connecting plate (144), a second round rod (149) is rotatably connected to a telescopic end of the seventh electric telescopic rod (148), and a fourth groove (1410) is formed in one end side wall of the reinforcing plate (147).

5. The solar cell silicon wafer laminated side flower basket structure according to claim 4, wherein the inner walls of the fourth grooves (1410) are all slidably connected with moving blocks (1411), the side walls of the moving blocks (1411) are rotatably connected with the outer walls of the second round rods (149), the inner walls of the two ends of the third grooves (13) are fixedly connected with the same guide rod (1412), the rod walls of the guide rod (1412) are all slidably connected with two limiting plates (1413), and the bottom side walls of the limiting plates (1413) are all fixedly connected with the top side walls of the corresponding moving plates (142).