CN116021198A - Series welding equipment for solar cell - Google Patents

Abstract

The invention discloses solar cell series welding equipment, which belongs to the technical field of solar cell processing and comprises a base, wherein a double-station feeding component for continuous feeding is arranged at the upper end of the base; the base is provided with a conveying assembly for driving the materials to move to the hot pressing assembly; the base is provided with a hot pressing assembly for series welding; a carding component for carding materials is arranged at the feeding end of the conveying component; the conveying assembly is provided with a negative pressure assembly for carrying out negative pressure adsorption on materials; the double-station feeding assembly comprises a driving assembly, a telescopic feeding assembly, a translational feeding assembly and a guiding assembly; the driving assembly and the guiding assembly are all installed on the base, and the driving assembly is connected with the telescopic feeding assembly and the translational feeding assembly. Through the mode, the double-station wire feeding device is capable of achieving normal operation of wires on double stations through a simpler structure, and is easier to control.

Description

Series welding equipment for solar cell

Technical Field

The invention relates to the technical field of solar cell processing, in particular to solar cell series welding equipment.

Background

In order to produce solar cell modules with different power levels, solar cell sheets need to be welded together in series through a cell sheet welding strip in the production process of the solar cell modules.

However, solar cell series welding equipment still has the following drawbacks: in order to realize double-station wire feeding, the problems of dislocation, height, fixed point and the like of the double stations are required to be considered so as to ensure the normal operation of the double stations, so that a complex structure is required to be designed to realize double-station wire feeding, and the control process is relatively complicated.

Based on the above, the invention designs a solar cell series welding device to solve the above problems.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention provides solar cell series welding equipment.

In order to achieve the above purpose, the invention is realized by the following technical scheme:

the solar cell series welding equipment comprises a base, wherein a double-station feeding component for continuous feeding is arranged at the upper end of the base;

the base is provided with a conveying assembly for driving the materials to move to the hot pressing assembly;

the base is provided with a hot pressing assembly for series welding, and the hot pressing assembly is positioned at the outer side of the conveying assembly;

a carding component for carding materials is arranged at the feeding end of the conveying component;

the conveying assembly is provided with a negative pressure assembly for carrying out negative pressure adsorption on materials;

the double-station feeding assembly comprises a driving assembly, a telescopic feeding assembly, a translational feeding assembly and a guiding assembly; the driving assembly and the guide assembly are arranged on the base, the driving assembly is connected with the telescopic feeding assembly and the translational feeding assembly, and the driving assembly drives the telescopic feeding assembly and the translational feeding assembly to reciprocate towards opposite directions, and the telescopic feeding assembly is connected with the guide assembly.

Further, the driving assembly comprises a second driving motor, a synchronous belt and a synchronous wheel; the second driving motor is fixedly arranged at the bottom of the base, two groups of synchronous wheels are rotatably arranged on the base, the two groups of synchronous wheels are connected through a synchronous belt, and one group of synchronous wheels is fixedly connected with the output end of the second driving motor; the translation feeding component and the telescopic feeding component are respectively connected with the front end and the rear end of the synchronous belt.

Further, the translational feeding assembly comprises a straight plate, a second transverse plate, a first connecting fixing seat, a first sliding block and a first guide rail; the lower extreme of straight board passes through first connection fixing base and the front end fixed connection of hold-in range, and the upper end fixedly connected with second diaphragm of straight board, the bottom fixedly connected with first slider of straight board, first slider sliding connection is on first guide rail, first guide rail fixed mounting is on the base.

Further, the telescopic feeding assembly comprises a sleeve, a sliding plate, a first transverse plate, a second sliding block, a second guide rail and a second connecting fixing seat; the bottom of the sleeve is fixedly connected with a second sliding block, the second sliding block is connected onto a second guide rail in a sliding manner, the second guide rail is fixedly arranged on the base, the lower end of the sleeve is fixedly connected with the rear end of the synchronous belt through a second connection fixing seat, the inside of the upper end of the sleeve is connected with a sliding plate in a sliding manner, and the upper end of the sliding plate is fixedly connected with a first transverse plate; the rear end of the sliding plate is fixedly connected with a sliding rod which is in sliding connection with the guide component.

Further, the guide assembly comprises a guide frame, the lower end of the guide frame is fixedly connected to the base, a first transverse groove, a first chute, a second transverse groove, a second chute and a third transverse groove which are communicated with each other are sequentially formed in the upper end of the guide frame from left to right, the first transverse groove, the first chute, the second transverse groove, the second chute and the third transverse groove form a sliding groove, and the sliding rod is connected in the sliding groove in a sliding way; the height of the second transverse groove is greater than that of the first transverse groove and the third transverse groove; and clamping assemblies for clamping materials are fixedly arranged on the first transverse plate and the second transverse plate.

Further, the conveying assembly comprises a synchronous belt assembly, a first fixing frame, a first driving motor, a conveying belt and a conveying roller; two groups of conveying rollers are rotatably arranged on the first fixing frame, the two groups of conveying rollers are connected through a conveying belt, a first driving motor is fixedly arranged on the base, and the output end of the first driving motor is connected with one group of conveying rollers through a synchronous belt assembly.

Further, the negative pressure assembly comprises a middle pipe, an exhaust pipe, a negative pressure hole, a supporting plate and a negative pressure cover; a plurality of groups of negative pressure holes are uniformly formed in the conveyor belt, a negative pressure cover is fixedly connected to the inner wall of the first fixing frame through a supporting plate, the top of the negative pressure cover is in fit contact with the inner wall of the conveyor belt, one end of the exhaust pipe is fixedly connected with the exhaust pump, the other end of the exhaust pipe is fixedly connected with the middle pipe, and the other end of the middle pipe is fixedly connected with the supporting plate.

Further, the hot pressing assembly comprises a second fixing frame, an air cylinder, a guide rod and a belt pressing device; the lower extreme fixed mounting of second mount is on the base, and the top fixedly connected with cylinder of second mount, the output fixedly connected with of cylinder presses the area device, presses the upper end fixedly connected with of area device two sets of guide bars, and the upper end sliding connection of guide bar is on the second mount.

Still further, the carding assembly includes a cross plate; the transverse plate is fixedly arranged at one feeding end of the first fixing frame, and a plurality of groups of transverse grooves are formed in the transverse plate; the transverse plate is also provided with a plurality of groups of V-shaped grooves; the V-shaped grooves and the transverse grooves are consistent in number and are communicated in a left-right one-to-one correspondence manner.

Advantageous effects

According to the invention, the telescopic feeding assembly and the translational feeding assembly are driven to reciprocate towards opposite directions by the driving assembly, so that the telescopic feeding assembly and the translational feeding assembly can realize the repeated feeding process, and further realize continuous feeding, the guiding assembly is used for guiding the telescopic feeding assembly, and when the telescopic feeding assembly and the translational feeding assembly are intersected, the telescopic feeding assembly is stretched by the guiding assembly, so that the telescopic feeding assembly is higher than the translational feeding assembly, and collision between the telescopic feeding assembly and the translational feeding assembly is avoided; the material is carded through the carding component, then the material moves to the hot pressing component through the conveying component to be subjected to series welding, and the material is adsorbed through the negative pressure component, so that the stability of the material in the moving process can be ensured; the invention realizes the normal operation of the double-station upper wire through a simpler structure, and is easier to control.

According to the invention, the synchronous wheel is driven to rotate by the second driving motor, the synchronous wheel drives the synchronous belt to rotate, and the telescopic feeding assembly and the translational feeding assembly are driven to reciprocate by the synchronous belt and move towards opposite directions; the synchronous belt drives the straight plate to reciprocate through the first connecting fixing seat, the straight plate drives the second transverse plate to reciprocate, and the straight plate drives the first sliding block to reciprocate along the first guide rail, so that the moving stability of the straight plate is ensured; the synchronous belt drives the sleeve to reciprocate through the second connecting fixed seat, the sleeve drives the sliding plate to reciprocate, the sliding plate drives the sliding rod to reciprocate, and meanwhile, under the guiding action of the guiding component, the second transverse plate is positioned at the inner side of the first transverse plate when the second transverse plate is intersected with the first transverse plate, so that the first transverse plate is higher than the second transverse plate, and collision of the first transverse plate and the second transverse plate is avoided; before the second transverse plate is intersected with the first transverse plate, the sliding rod is guided through the sliding groove, so that the sliding plate slides along the sleeve, when the sliding rod is positioned in the second transverse groove, the sliding plate moves to the highest position, and when the second transverse plate is intersected with the first transverse plate, the second transverse plate is positioned on the inner side of the first transverse plate, so that the first transverse plate is higher than the second transverse plate, and collision of the first transverse plate and the second transverse plate is avoided; when the materials enter the transverse plate, the V-shaped grooves are used for guiding feeding, and carding is carried out through the transverse grooves, so that the influence of excessive confusion on subsequent processing during feeding of the materials can be avoided; the conveying roller is driven to rotate by the first driving motor, the conveying roller drives the conveying belt to rotate, and the conveying belt drives the materials to move; the middle pipe and the exhaust pipe are used for exhausting air, so that negative pressure is formed in the supporting plate, an adsorption force is generated on the conveyor belt above the supporting plate, the conveyor belt generates a negative pressure adsorption force on materials through the negative pressure holes, and the stability of the materials in the moving process can be ensured; when the material is transported to the lower part of the belt pressing device, the cylinder is started to drive the belt pressing device to move, and the material is subjected to series welding.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

Fig. 1 is a perspective view of a main structure of a solar cell series welding device according to the present invention;

fig. 2 is a front view of a solar cell series welding device according to the present invention;

fig. 3 is a left side view of a solar cell series welding device structure according to the present invention;

fig. 4 is a second perspective view of a main structure of a solar cell series welding device according to the present invention;

fig. 5 is a perspective view of a main structure of a solar cell series welding device according to the present invention;

fig. 6 is a perspective view of a main structure of a solar cell series welding device according to the present invention;

fig. 7 is a cross-sectional view taken along the A-A direction of fig. 3.

Reference numerals in the drawings represent respectively:

1. base 2, suction assembly 21, intermediate tube 22, suction tube 23, suction opening 24, support plate 25, suction hood 3, transfer assembly 31, timing belt assembly 32, first mount 33, first drive motor 34, transfer belt 35, transfer roll 4, hot press assembly 41, second mount 42, guide bar 44, pressure belt assembly 5, carding assembly 51, cross plate 52, v-groove 53, cross plate 6, dual-station feed assembly 61, guide frame 62, first cross plate 63, first chute 64, clamping assembly 65, second cross plate 66, second chute 67, third cross plate 68, second drive motor 69, sleeve 610, straight plate 611, slide plate 612, first cross plate 613, second cross plate 614, timing belt 615, first connecting mount 616, first slide 617, second slide 618, second guide rail, first guide 620, second connecting mount 622, 619.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention is further described below with reference to examples.

Example 1

Referring to fig. 1-7 of the specification, a solar cell series welding device comprises a base 1, wherein a double-station feeding component 6 for continuous feeding is arranged at the upper end of the base 1;

a conveying assembly 3 for driving the materials to move to the hot pressing assembly 4 is arranged on the base 1;

the base 1 is provided with a hot pressing assembly 4 for series welding, and the hot pressing assembly 4 is positioned at the outer side of the conveying assembly 3;

a carding component 5 for carding materials is arranged at the feeding end of the conveying component 3;

the conveying component 3 is provided with a negative pressure component 2 for carrying out negative pressure adsorption on materials;

the double-station feeding assembly 6 comprises a driving assembly, a telescopic feeding assembly, a translational feeding assembly and a guiding assembly; the driving assembly and the guide assembly are both arranged on the base 1, the driving assembly is connected with the telescopic feeding assembly and the translational feeding assembly, the driving assembly drives the telescopic feeding assembly and the translational feeding assembly to reciprocate towards opposite directions, and the telescopic feeding assembly is connected with the guide assembly;

the telescopic feeding assembly and the translational feeding assembly are driven to reciprocate towards opposite directions through the driving assembly, so that the telescopic feeding assembly and the translational feeding assembly can be used for feeding in a reciprocating manner, continuous feeding is further achieved, the guiding assembly is used for guiding the telescopic feeding assembly, when the telescopic feeding assembly and the translational feeding assembly meet, the telescopic feeding assembly is stretched through the guiding assembly, and therefore the telescopic feeding assembly is higher than the translational feeding assembly, and collision between the telescopic feeding assembly and the translational feeding assembly is avoided; the carding component 5 is used for carding the materials, then the materials are moved to the hot pressing component 4 through the conveying component 3 for series welding, and the negative pressure component 2 is used for adsorbing the materials, so that the stability of the materials in the moving process can be ensured; the invention realizes the normal operation of the double-station upper wire through a simpler structure, and is easier to control.

Example 2

On the basis of embodiment 1, referring to fig. 1-7 of the specification, the driving assembly includes a second driving motor 68, a timing belt 614 and a timing wheel 620; the second driving motor 68 is fixedly arranged at the bottom of the base 1, two groups of synchronous wheels 620 are rotatably arranged on the base 1, the two groups of synchronous wheels 620 are connected through a synchronous belt 614, and one group of synchronous wheels 620 is fixedly connected with the output end of the second driving motor 68; the translation feeding component and the telescopic feeding component are respectively connected with the front end and the rear end of the synchronous belt 614;

the synchronous wheel 620 is driven to rotate by the second driving motor 68, the synchronous wheel 620 drives the synchronous belt 614 to rotate, and the telescopic feeding assembly and the translational feeding assembly are driven to reciprocate by the synchronous belt 614 and move towards opposite directions;

the translational feeding assembly comprises a straight plate 610, a second transverse plate 613, a first connection fixed seat 615, a first sliding block 616 and a first guide rail 619; the lower end of the straight plate 610 is fixedly connected with the front end of the synchronous belt 614 through a first connecting fixed seat 615, the upper end of the straight plate 610 is fixedly connected with a second transverse plate 613, the bottom of the straight plate 610 is fixedly connected with a first sliding block 616, the first sliding block 616 is slidingly connected on a first guide rail 619, and the first guide rail 619 is fixedly arranged on the base 1;

the synchronous belt 614 drives the straight plate 610 to reciprocate through the first connecting fixed seat 615, the straight plate 610 drives the second transverse plate 613 to reciprocate, and the straight plate 610 drives the first sliding block 616 to reciprocate along the first guide rail 619, so that the moving stability of the straight plate 610 is ensured;

the telescopic feeding assembly comprises a sleeve 69, a sliding plate 611, a first transverse plate 612, a second sliding block 617, a second guide rail 618 and a second connecting fixing seat 621; the bottom of the sleeve 69 is fixedly connected with a second slider 617, the second slider 617 is slidably connected to a second guide rail 618, the second guide rail 618 is fixedly arranged on the base 1, the lower end of the sleeve 69 is fixedly connected with the rear end of the synchronous belt 614 through a second connecting fixing seat 621, the upper end of the sleeve 69 is internally and slidably connected with a sliding plate 611, and the upper end of the sliding plate 611 is fixedly connected with a first transverse plate 612; the rear end of the sliding plate 611 is fixedly connected with a sliding rod 622, and the sliding rod 622 is in sliding connection with the guide assembly;

the synchronous belt 614 drives the sleeve 69 to reciprocate through the second connecting fixed seat 621, the sleeve 69 drives the sliding plate 611 to reciprocate, the sliding plate 611 drives the sliding rod 622 to reciprocate, and meanwhile, under the guiding action of the guiding component, when the second transverse plate 613 is intersected with the first transverse plate 612, the second transverse plate 613 is positioned at the inner side of the first transverse plate 612, so that the first transverse plate 612 is higher than the second transverse plate 613, and collision between the first transverse plate and the second transverse plate is avoided;

the guide assembly comprises a guide frame 61, the lower end of the guide frame 61 is fixedly connected to the base 1, a first transverse groove 62, a first chute 63, a second transverse groove 65, a second chute 66 and a third transverse groove 67 which are communicated with each other are sequentially formed in the upper end of the guide frame 61 from left to right, the first transverse groove 62, the first chute 63, the second transverse groove 65, the second chute 66 and the third transverse groove 67 form a sliding groove, and a sliding rod 622 is slidably connected in the sliding groove; the second transverse groove 65 has a height greater than the heights of the first and third transverse grooves 62, 67; the first transverse plate 612 and the second transverse plate 613 are fixedly provided with a clamping assembly 64 for clamping materials;

before the second cross plate 613 meets the first cross plate 612, the sliding rod 622 is guided by the sliding groove, so that the sliding plate 611 slides along the sleeve 69, when the sliding rod 622 is positioned in the second cross plate 65, the sliding plate 611 moves to the highest position, and when the second cross plate 613 meets the first cross plate 612, the second cross plate 613 is positioned on the inner side of the first cross plate 612, so that the first cross plate 612 is higher than the second cross plate 613, and collision between the two is avoided.

Example 3

On the basis of embodiment 2, referring to fig. 1 to 7 of the specification, the conveying assembly 3 includes a timing belt assembly 31, a first fixing frame 32, a first driving motor 33, a conveying belt 34, and a conveying roller 35; two groups of conveying rollers 35 are rotatably arranged on the first fixing frame 32, the two groups of conveying rollers 35 are connected through a conveying belt 34, a first driving motor 33 is fixedly arranged on the base 1, and the output end of the first driving motor 33 is connected with one group of conveying rollers 35 through a synchronous belt assembly 31;

the first driving motor 33 drives the conveying roller 35 to rotate, the conveying roller 35 drives the conveying belt 34 to rotate, and the conveying belt 34 drives the materials to move;

the negative pressure assembly 2 comprises a middle pipe 21, an exhaust pipe 22, a negative pressure hole 23, a supporting plate 24 and a negative pressure cover 25; a plurality of groups of negative pressure holes 23 are uniformly formed in the conveyor belt 34, a negative pressure cover 25 is fixedly connected to the inner wall of the first fixing frame 32 through a supporting plate 24, the top of the negative pressure cover 25 is in fit contact with the inner wall of the conveyor belt 34, one end of an exhaust pipe 22 is fixedly connected with an exhaust pump, the other end of the exhaust pipe 22 is fixedly connected with an intermediate pipe 21, and the other end of the intermediate pipe 21 is fixedly connected with the supporting plate 24;

the middle pipe 21 and the exhaust pipe 22 are used for exhausting air, so that negative pressure is formed in the supporting plate 24, an adsorption force is generated on the conveyor belt 34 above the negative pressure, and the conveyor belt 34 generates a negative pressure adsorption force on materials through the negative pressure holes 23, so that the stability of the materials in the moving process can be ensured;

the hot press assembly 4 includes a second fixing frame 41, an air cylinder 42, a guide rod 43 and a belt pressing device 44; the lower end of the second fixing frame 41 is fixedly arranged on the base 1, the top of the second fixing frame 41 is fixedly connected with an air cylinder 42, the output end of the air cylinder 42 is fixedly connected with a belt pressing device 44, the upper end of the belt pressing device 44 is fixedly connected with two groups of guide rods 43, and the upper ends of the guide rods 43 are slidably connected on the second fixing frame 41;

when the material is transported to the lower part of the belt pressing device 44, the cylinder 42 is started to drive the belt pressing device 44 to move so as to carry out series welding on the material;

carding assembly 5 comprises a cross plate 51; the transverse plate 51 is fixedly arranged at the feeding end of the first fixing frame 32, and a plurality of groups of transverse grooves 53 are formed in the transverse plate 51;

preferably, the transverse plate 51 is also provided with a plurality of groups of V-shaped grooves 52; the V-shaped grooves 52 and the transverse grooves 53 are consistent in number and are communicated in a left-right one-to-one correspondence manner;

when the material enters the transverse plate 51, the V-shaped groove 52 is used for guiding feeding, and the transverse groove 53 is used for carding, so that the influence of excessive confusion on subsequent processing during material feeding can be avoided.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (9)

1. Solar wafer series welding equipment, including base (1), its characterized in that:

the upper end of the base (1) is provided with a double-station feeding assembly (6) for continuous feeding;

a conveying assembly (3) for driving the materials to move to the hot pressing assembly (4) is arranged on the base (1);

a hot pressing assembly (4) for performing series welding is arranged on the base (1), and the hot pressing assembly (4) is positioned at the outer side of the conveying assembly (3);

a carding component (5) for carding materials is arranged at the feeding end of the conveying component (3);

the conveying assembly (3) is provided with a negative pressure assembly (2) for carrying out negative pressure adsorption on materials;

the double-station feeding assembly (6) comprises a driving assembly, a telescopic feeding assembly, a translational feeding assembly and a guiding assembly; the driving assembly and the guiding assembly are both arranged on the base (1), the driving assembly is connected with the telescopic feeding assembly and the translational feeding assembly, and the driving assembly drives the telescopic feeding assembly and the translational feeding assembly to reciprocate towards opposite directions, and the telescopic feeding assembly is connected with the guiding assembly.

2. The solar cell string welding apparatus of claim 1, wherein the drive assembly comprises a second drive motor (68), a timing belt (614), and a timing wheel (620); the second driving motor (68) is fixedly arranged at the bottom of the base (1), two groups of synchronous wheels (620) are rotatably arranged on the base (1), the two groups of synchronous wheels (620) are connected through a synchronous belt (614), and one group of synchronous wheels (620) is fixedly connected with the output end of the second driving motor (68); the translation feeding component and the telescopic feeding component are respectively connected with the front end and the rear end of the synchronous belt (614).

3. The solar cell series welding device according to claim 2, wherein the translational feeding assembly comprises a straight plate (610), a second transverse plate (613), a first connection fixing base (615), a first slider (616) and a first guide rail (619); the lower extreme of straight board (610) is through first connection fixing base (615) and the front end fixed connection of hold-in range (614), and the upper end fixedly connected with second diaphragm (613) of straight board (610), the bottom fixedly connected with first slider (616) of straight board (610), first slider (616) sliding connection is on first guide rail (619), first guide rail (619) fixed mounting is on base (1).

4. A solar cell series welding apparatus according to claim 3, wherein the telescopic feeding assembly comprises a sleeve (69), a slide plate (611), a first cross plate (612), a second slide block (617), a second guide rail (618) and a second connecting fixing seat (621); the bottom of the sleeve (69) is fixedly connected with a second slider (617), the second slider (617) is slidably connected to a second guide rail (618), the second guide rail (618) is fixedly arranged on the base (1), the lower end of the sleeve (69) is fixedly connected with the rear end of the synchronous belt (614) through a second connecting fixing seat (621), the upper end of the sleeve (69) is internally slidably connected with a sliding plate (611), and the upper end of the sliding plate (611) is fixedly connected with a first transverse plate (612); the rear end of the sliding plate (611) is fixedly connected with a sliding rod (622), and the sliding rod (622) is in sliding connection with the guide assembly.

5. The solar cell series welding device according to claim 4, wherein the guide assembly comprises a guide frame (61), the lower end of the guide frame (61) is fixedly connected to the base (1), a first transverse groove (62), a first chute (63), a second transverse groove (65), a second chute (66) and a third transverse groove (67) which are communicated are sequentially formed in the upper end of the guide frame (61) from left to right, the first transverse groove (62), the first chute (63), the second transverse groove (65), the second chute (66) and the third transverse groove (67) form a sliding groove, and the sliding rod (622) is slidably connected in the sliding groove; the height of the second transverse groove (65) is greater than the heights of the first transverse groove (62) and the third transverse groove (67); the first transverse plate (612) and the second transverse plate (613) are fixedly provided with clamping assemblies (64) for clamping materials.

6. A solar cell string welding apparatus according to claim 1, characterized in that the conveyor assembly (3) comprises a timing belt assembly (31), a first mount (32), a first drive motor (33), a conveyor belt (34) and a conveyor roller (35); two groups of conveying rollers (35) are rotatably arranged on the first fixing frame (32), the two groups of conveying rollers (35) are connected through a conveying belt (34), a first driving motor (33) is fixedly arranged on the base (1), and the output end of the first driving motor (33) is connected with one group of conveying rollers (35) through a synchronous belt assembly (31).

7. The solar cell series welding equipment according to claim 6, wherein the negative pressure assembly (2) comprises a middle tube (21), an exhaust tube (22), a negative pressure hole (23), a support plate (24) and a negative pressure cover (25); a plurality of groups of negative pressure holes (23) are uniformly formed in the conveyor belt (34), a negative pressure cover (25) is fixedly connected to the inner wall of the first fixing frame (32) through a supporting plate (24), the top of the negative pressure cover (25) is in fit contact with the inner wall of the conveyor belt (34), one end of an exhaust pipe (22) is fixedly connected with an exhaust pump, the other end of the exhaust pipe (22) is fixedly connected with an intermediate pipe (21), and the other end of the intermediate pipe (21) is fixedly connected with the supporting plate (24).

8. Solar cell series welding equipment according to claim 1, characterized in that the hot-pressing assembly (4) comprises a second fixing frame (41), a cylinder (42), a guide rod (43) and a belt pressing device (44); the lower extreme fixed mounting of second mount (41) is on base (1), and the top fixedly connected with cylinder (42) of second mount (41), the output fixedly connected with of cylinder (42) presses area device (44), presses the upper end fixedly connected with two sets of guide bars (43) of area device (44), and the upper end sliding connection of guide bar (43) is on second mount (41).

9. Solar cell string welding device according to claim 6, characterized in that the carding assembly (5) comprises a transverse plate (51); the transverse plate (51) is fixedly arranged at one feeding end of the first fixing frame (32), and a plurality of groups of transverse grooves (53) are formed in the transverse plate (51); the transverse plate (51) is also provided with a plurality of groups of V-shaped grooves (52); the number of the V-shaped grooves (52) is consistent with that of the transverse grooves (53) and the V-shaped grooves are communicated in a left-right one-to-one correspondence manner.

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