CN215356860U

CN215356860U - Automatic welding strip arranging device and series welding machine

Info

Publication number: CN215356860U
Application number: CN202121215750.2U
Authority: CN
Inventors: 周丰; 苏文涛; 杨勇
Original assignee: Ningxia XN Automation Equipment Co Ltd
Current assignee: Ningxia Xiaoniu Automation Equipment Co ltd
Priority date: 2021-06-02
Filing date: 2021-06-02
Publication date: 2021-12-31
Anticipated expiration: 2031-06-02

Abstract

This application is for welding take automatic device and the stringer of arranging, wherein welds the automatic device of arranging of taking, including welding take cutting device, welding take the device, welding platform, traction frame of arranging, weld take the device of arranging to pass through traction frame effect will weld take cutting device to go up to cut the area of welding that arranges for the multistage to carry extremely weld on the battery piece on the welding platform, its characterized in that: the welding strip arrangement device is provided with a plurality of grabbing and releasing mechanisms which can perform translational dislocation actions perpendicular to the direction of a welding strip line, and the grabbing and releasing mechanisms are used for grabbing and placing the welding strips; or the welding strip cutting device is provided with a plurality of cutting mechanisms which can move in a translation and dislocation way in the direction vertical to the line direction of the welding strips, and the cutting mechanisms are used for cutting the whole welding strip into a plurality of sections. So that at least two adjacent groups of welding strips are arranged on the corresponding grid lines of the battery pieces in a staggered mode.

Description

Automatic welding strip arranging device and series welding machine

Technical Field

The utility model relates to the technical field of solar photovoltaic equipment manufacturing, in particular to an automatic welding strip arrangement device and a series welding machine.

Background

With the rapid development of the solar module industry, the improvement of module power is more and more emphasized by each module manufacturer, wherein the shingle technology is also the research direction of a plurality of module manufacturers. In the current photovoltaic industry, the laser scribing area in the middle of the cell of most of the tiled photovoltaic modules is linear, and more parts of the overlapping area of the cell slices are shielded, so that the power of the module is lost.

In order to reduce the power loss of the shielded area, a plurality of groups of staggered and parallel segmented welding belts are laid on the front surface of each cell, a grid line-free connecting area between each group of segmented welding belts is a front surface laser scribing area, and the scribing edge of each cell after laser cutting is wavy. According to the technology, the welding strip is required to be cut, spaced, staggered and translated and then laid on the front surface of the whole battery for welding, as shown in fig. 1, the welding strip is cut into a plurality of battery fragments after being welded, the anodes of the battery fragments are connected with the cathodes of the adjacent battery fragments through conductive adhesives, and meanwhile, the edges of the adjacent battery fragments are overlapped.

Disclosure of Invention

In view of this, it is necessary to provide an automatic solder ribbon arrangement device capable of performing offset soldering on grid lines of a battery piece.

It is also necessary to provide a stringer with an automatic solder ribbon arrangement device.

A welding strip automatic arrangement device comprises a welding strip cutting device, a welding strip arrangement device, a welding table and a traction frame, wherein the welding strip arrangement device conveys welding strips which are cut into a plurality of sections and arranged on the welding strip cutting device to battery pieces on the welding table for welding under the action of the traction frame; or the welding strip cutting device is provided with a plurality of cutting mechanisms which can move in a translation and dislocation way in the direction vertical to the line direction of the welding strips, and the cutting mechanisms are used for cutting the whole welding strip into a plurality of sections. So that at least two adjacent groups of welding strips are arranged on the corresponding grid lines of the battery pieces in a staggered mode.

A series welding machine is used for manufacturing a solar cell module and comprises the automatic solder strip arrangement device.

Has the advantages that: when the automatic welding strip arranging device works, a whole welding strip is firstly divided into a plurality of sections by the welding strip cutting device, then the welding strip arranging device is transferred to the position right above the welding strip cutting device and clamped by the traction of the traction frame, the welding strip arranging device arranges the welding strips according to a preset array and moves the welding strips to the position right above a welding table, a battery piece is placed on the welding table, the welding strip arranging device places the welding strips on preset positions of the battery piece, and finally the welding device welds the welding strips and the battery piece. The solder strips are arranged in a staggered manner through the solder strip arranging device, so that the final solder strips can be welded on the battery piece in a staggered manner.

Drawings

Fig. 1 is a front view of a finished battery pack prepared according to the present invention.

Fig. 2 is a schematic structural diagram of an automatic solder strip arrangement device and a stringer according to the present invention.

Fig. 3 is a schematic perspective view of a horizontal driving mechanism on a solder strip arrangement apparatus according to a first embodiment of the present invention.

Fig. 4 is a schematic perspective view of a horizontal driving mechanism of a solder strip cutting apparatus according to a second embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a solder strip cutting apparatus according to a first embodiment of the present invention.

Fig. 6 is a schematic view of a structure of the solder strip cutting device and the solder strip arrangement device according to the first embodiment of the present invention.

Fig. 7 is a partially enlarged view of fig. 6.

Fig. 8 is a side view of the solder ribbon arraying device and horizontal drive mechanism in combination according to a first embodiment of the present invention.

Fig. 9 is a schematic structural diagram of the solder strip cutting device and the solder strip arrangement device according to the second embodiment of the present invention.

FIG. 10 is a side view of the solder ribbon arraying device and drive mechanism in accordance with a second embodiment of the present invention.

Fig. 11 is a diagram of the dislocation effect of the pick-and-place mechanism of the utility model.

In the figure: the automatic solder strip arranging device 10, the solder strip cutting device 20, the cutting mechanism 201, the cutter 2011, the lower clamp 2012, the base 202, the vertical guide rail 2021, the translation guide rail 2022, the distance dividing mechanism 203, the spiral lifter 2031, the driving connecting plate 2032, the inclined adjusting groove 20321, the moving guide rail seat 2033, the distance dividing motor 2034, the gear 2035, the solder strip arranging device 30, the pick-and-place mechanism 301, the vertical electric push rod 3011, the push rod seat 3012, the pushing connecting plate 3013, the clamp assembly 3014, the clamp bracket 30141, the upper clamp 30142, the spring 30143, the rotating shaft 30144, the horizontal driving mechanism 40, the traction frame 50, the solder strip 60 and the battery piece 70.

Detailed Description

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Referring to fig. 2, an automatic solder strip arrangement device 10 includes a solder strip cutting device 20, a solder strip arrangement device 30, a soldering station 40, and a traction frame 50, wherein the solder strip arrangement device 30 transports the solder strips cut into multiple sections and arranged on the solder strip cutting device 20 to the battery pieces on the soldering station 40 for soldering through the action of the traction frame 50, the solder strip arrangement device 30 is provided with a plurality of grabbing mechanisms 301 capable of performing translational dislocation motion perpendicular to the solder strip line direction, and the grabbing mechanisms 301 are used for grabbing and placing the solder strips; or the welding strip cutting device 20 is provided with a plurality of cutting mechanisms 201 which can perform translational dislocation action perpendicular to the line direction of the welding strip, and the cutting mechanisms 201 are used for cutting the whole welding strip into a plurality of sections. So that at least two adjacent groups of welding strips are arranged on the grid lines of the corresponding battery pieces 70 in a staggered mode.

In order to achieve the staggered arrangement of the solder ribbons on the pick and place mechanism 301, the present invention is implemented in two ways.

Example one

Referring to fig. 3, 5, 6, 7 and 8, the solder ribbon arrangement apparatus 30 is provided with a horizontal driving mechanism 40, and the horizontal driving mechanism 40 is fixedly connected to the spaced pick-and-place mechanisms 301 to drive the spaced pick-and-place mechanisms 301 to move in the horizontal direction, so that the adjacent pick-and-place mechanisms 301 are dislocated.

That is, the horizontally driving mechanism 40 shifts the intervals between the pick-and-place mechanisms 301 that are originally aligned, and thereby shifts the solder ribbons on the adjacent pick-and-place mechanisms 301. When the solder strip arrangement device 30 is in operation, according to the process requirements, if the solder strips are required to be distributed in a staggered manner, the horizontal electric push rod is controlled to drive the grabbing and releasing mechanisms 301 to move to the preset positions, so that the two adjacent grabbing and releasing mechanisms 301 are distributed in a staggered manner, and if the solder strips are not required to be distributed in a staggered manner, the horizontal electric push rod does not act, so that the two adjacent rows of solder strips are arranged in an aligned manner.

In this embodiment, the weld bead cutting apparatus 20 need not be offset. However, for the purpose of cutting the solder strips with different lengths and adjusting the spacing between the solder strips, it is necessary to provide a spacing mechanism 203 on the solder strip cutting device 20 to achieve spacing between the plurality of cutting mechanisms 201 on the solder strip cutting device 20, so as to separate the solder strips on the cutting mechanisms 201. To achieve this, the present invention is embodied as follows:

the welding strip cutting device 20 includes a plurality of cutting mechanisms 201, a plurality of cutting mechanisms are distributed in parallel, and further, the welding strip cutting device 20 further includes a base 202 and a distance dividing mechanism 203, the distance dividing mechanism 203 is used for adjusting the distance between the cutting mechanisms 201, the cutting mechanisms 201 are located on the base 202, the base 202 is connected with the distance dividing mechanism 203 in a sliding manner, the upper end of the distance dividing mechanism 203 is fixedly connected with the cutting mechanisms 201, the distance dividing mechanism 203 includes a spiral lifter 2031, a driving connecting plate 2032 and a movable guide rail seat 2033, the lifting rod of the spiral lifter 2031 is fixedly connected with the side edge of the driving connecting plate 2032, the driving connecting plate 2032 is provided with a plurality of inclined adjusting grooves 20321, the inclination angles of the inclined adjusting grooves 20321 are gradually reduced in sequence according to the direction of the cutting mechanisms 201, the lower end of the movable guide rail seat 2033 is lapped with the inclined adjusting grooves 20321, so that the driving connecting plate 2032 drives the movable guide rail seat to move in the horizontal direction in the vertical moving process, the upper end of the movable guide rail seat 2033 is fixedly connected with the cutting mechanism 201 to drive the cutting mechanism 201 to move, two sides of one side surface of the base 202 are provided with vertical guide rails 2021, two sides of the driving connecting plate are slidably connected with the vertical guide rails 2021, the upper end of the base 202 is provided with a translation guide rail 2022, and the translation guide rail 2022 is slidably connected with the movable guide rail seat 2033.

Along with the ascending and descending of the spiral lifter 2031, the driving connecting plate 2032 ascends and descends synchronously along the groove of the vertical guide rail 2021, and under the driving of the driving connecting plate 2032, the movable guide rail seat 2033 moves along the translational guide rail 2022, so as to drive the cutting mechanism 201 connected with the movable guide rail seat 2033 to move. Since the inclination angles of the inclination adjustment grooves 20321 are gradually decreased in the direction in which the cutting mechanisms 201 are separated, the moving speed of the distal-end cutting mechanism 201 is faster than that of the proximal-end cutting mechanism 201, and the distal-end cutting mechanism 201 moves a greater distance than that of the proximal-end cutting mechanism 201 in the case of synchronous movement, so that it is possible to ensure that each cutting mechanism 201 can be separated.

Example two

Referring to fig. 4 and 9, the solder strip cutting device 20 includes a horizontal driving mechanism 40 and a plurality of cutting mechanisms 201, wherein the horizontal driving mechanism 40 is fixedly connected to the spaced cutting mechanisms 201 to drive the spaced cutting mechanisms 201 to move in the horizontal direction, so that the adjacent cutting mechanisms 201 are dislocated.

That is, the horizontal driving mechanism 40 is located on the solder ribbon cutting apparatus 20. The cutting mechanism 201 is displaced by the horizontal driving mechanism 40, and the pick-and-place mechanism 301 does not need to be driven. However, the pick-and-place mechanism 301 is always in a dislocated state, and the dislocated pick-and-place mechanism 301 can be opposite to the dislocated cutting mechanism 201, so that the welding strip can be transferred from the cutting mechanism 201 to the pick-and-place mechanism 301. Since the cutting mechanism 201 is to perform the movement in both the lateral and longitudinal directions, the structure of the pitch mechanism 203 in the first embodiment is not applicable to this. The pitch mechanism 203 is to change the structure so that the cutting mechanism 201 can perform movements in both the lateral and longitudinal directions. The specific implementation mode is as follows:

the solder strip cutting device 20 further comprises a base 202 and a distance dividing mechanism 203, the distance dividing mechanism 203 is used for adjusting the distance between the cutting mechanisms 201, the base 202 is connected with the distance dividing mechanism 203 in a sliding manner, the upper end of the distance dividing mechanism 203 is fixedly connected with the horizontal driving mechanism 40 and the cutting mechanisms 201, the distance dividing mechanism 203 comprises a movable guide rail seat 2033, a distance dividing motor 2034 and a gear 2035, the movable guide rail seat 2033 is connected with the upper end of the base 202 in a sliding manner, the lower end of the movable guide rail seat 2033 is fixedly connected with the distance dividing motor 2034, a rotating shaft 30144 of the distance dividing motor 2034 is fixedly connected with the gear 2035, a translational guide rail 2022 is arranged at the upper end of the base 202, a rack is arranged on the side wall of the lower end of the base 202, the translational guide rail 2022 is parallel to the rack and is perpendicular to the telescopic direction of the horizontal driving mechanism 40, the translational guide rail 2022 is connected with the movable guide rail seat 2033 in a sliding manner, the rack is connected with the gear 2035 in a meshing manner, the upper end of the movable guide rail seat 2033 is fixedly connected with the horizontal driving mechanism 40 and the cutting mechanisms 201, to move the cutting mechanism 201 along the direction of the translation guide 2022 by the pitch motor 2034.

On the cutting mechanism 201 connected to the horizontal driving mechanism 40, the pitch motor 2034 drives the horizontal driving mechanism 40 and the cutting mechanism 201 to move along the direction of the translation guide 2022, and on the cutting mechanism 201 not connected to the horizontal driving mechanism 40, the pitch motor 2034 drives only the cutting mechanism 201 to move. Thus, the pitch of the cutting mechanism 201 is realized.

Preferably, the cutting mechanism 201 of the two embodiments has the same structure, please refer to fig. 4, the cutting mechanism 201 includes a cutter 2011 and a lower clamp 2012, the cutter 2011 is located at one side of the lower clamp 2012, the lower clamp 2012 is provided with a lower clamping arm at two sides of an upper end of the lower clamp 2012, so as to clamp the solder strip.

The horizontal driving mechanism 40 in the above two embodiments has the following structure:

in a preferred embodiment, the horizontal driving mechanism 40 includes a plurality of horizontal electric push rods, and the telescopic rods of the horizontal electric push rods are fixedly connected with the spaced gripping and placing mechanisms 301 or the spaced cutting mechanisms 201.

In another preferred embodiment, the horizontal driving mechanism 40 includes a horizontal electric push rod and a connecting rod, the horizontal electric push rod is fixedly connected to one end of the connecting rod, the other end of the connecting rod is provided with a plurality of branch rods, and the branch rods are fixedly connected to the spaced gripping and placing mechanisms 301 or the spaced cutting mechanisms 201.

The electric push rod is only one preferred embodiment of the driving mechanism, and a device having a telescopic driving function, such as an air cylinder or a screw lifter 2031, may be used for driving the pick-and-place mechanism 301 or the cutting mechanism 201.

The pick-and-place mechanism 301 in the above two embodiments is a device having a function of picking and placing a solder ribbon, and the form thereof is various, such as a suction cup, a pincher, and the like. A preferred pick and place mechanism 301 implemented by the present invention has the following structure:

referring to fig. 10, the grasping and releasing mechanism 301 includes a vertical electric push rod 3011, a push rod seat 3012, a pushing link plate 3013, and a clamp assembly 3014, the body of the vertical electric push rod 3011 is fixedly connected to the push rod seat 3012, the telescopic rod of the vertical electric push rod 3011 is fixedly connected to the pushing link plate 3013, the bottom of the pushing link plate 3013 is overlapped with the clamp assembly 3014, guide rods are further disposed on two sides of the bottom of the push rod seat 3012, the guide rods are sleeved on the pushing link plate 3013, the bottom of the guide rods is fixedly connected to the clamp assembly 3014, the clamp assembly 3014 includes a clamp support 30141, a plurality of integrated clamps 30142, a spring 30143, and a rotation shaft 30144, the upper end of the clamp support 30141 is fixedly connected to the lower end of the fixed seat or the movable seat, a plurality of square through slots are disposed on the clamp support 30141, the integrated clamps 30142 are disposed in the square through slots, two clamps 30142 are disposed opposite, and a spring 30143 is disposed between two opposite integrated clamps 30142, the both sides of integral type clamp 30142 are connected with the one end of a pivot 30144 respectively, and the other end of pivot 30144 is connected with the lateral wall of square through groove, the bottom that promotes even board 3013 is equipped with the V font and leads the notch, and the upper end of integral type clamp 30142 stretches into to the V font and leads the notch in, promotes even board 3013 and drives integral type clamp 30142 and open downwards to remove the in-process, and the lower extreme of integral type clamp 30142 is equipped with two at least arm locks to the synchronous centre gripping welds the area.

The grabbing and releasing mechanism 301 can grab and release a plurality of parallel welding strips synchronously, and has high synchronism and high efficiency.

Preferably, the integrated clamp comprises a clamping arm, a connecting cross rod and a clamping plate, the clamping arm, the connecting cross rod, the clamping plate and the rotating shaft form a lever, the two opposite clamping plates are close to each other, the bottom of the clamping arm is far away from each other, and the releasing action of the welding strip 60 is completed, otherwise, the clamping action of the welding strip 60 is completed.

The implementation of the gear and rack in the two embodiments described above will be described below.

After the gear 2014 is meshed and connected with the rack, when the pitch motor 2015 drives the gear 2014 to rotate, the gear 2014 drives the pitch motor 2015 to move along the rack and the translation guide rail 2012, so that the movable guide rail seat 2013 drives the cutting mechanism 202 to perform pitch division, the welding strip 60 on the cutting mechanism 202 is also subjected to pitch division, and the final pitch division of the welding strip 60 is completed.

After the weld ribbon 60 is separated, the operation of both embodiments is as follows:

first, the cutting mechanism 202 does not have the horizontal driving mechanism 40, and therefore, the welding strip 60 on the cutting mechanism 202 is not moved in a staggered manner, and after the welding strip arrangement device 30 transfers the welding strip, the horizontal driving mechanism 40 on the welding strip arrangement device 30 drives the pick-and-place mechanism 301 to realize staggered arrangement.

Secondly, the horizontal driving mechanism 40 is arranged on the cutting mechanism 202, the horizontal driving mechanism 40 drives the cutting mechanism 202 to move in a staggered manner, the welding strips 60 are staggered, then the grabbing and releasing mechanism 301 on the welding strip arrangement device 30 is in a staggered state, namely the grabbing and releasing mechanism 301 is opposite to the staggered cutting mechanism 202, the grabbing and releasing mechanism 301 grabs the welding strips 60 and transfers the welding strips to the position right above the welding table through the traction frame 50, and the grabbing and releasing mechanism 301 places the welding strips 60 on the battery piece 70.

Finally, the solder strips 60, which were originally divided into multiple sections, are distributed in a staggered manner on the battery plate 70 as shown in fig. 11.

The solder strip arrangement device 30 is generally located above the solder strip cutting device 20 and the soldering station, after the solder strip 60 is cut, the solder strip arrangement device 30 is transferred to the position right above the solder strip cutting device 20 by the traction frame 50, and due to the setting of the program, each clamp on the solder strip arrangement device 30 is opposite to the clamp on the cutting mechanism 202. When the clamp on the solder ribbon arrangement apparatus 30 clamps the solder ribbon 60, the clamp on the cutting mechanism 202 is released, and the solder ribbon arrangement apparatus 30 is lifted up by the traction frame 50, so that the solder ribbon 60 is transferred to the solder ribbon arrangement apparatus 30.

At this time, the battery plate 70 is already placed on the welding table, the traction frame 50 moves the welding strip arrangement device 30 to the position right above the welding table 40, the welding strip 60 corresponds to the grid line on the battery plate 70, the traction frame 50 moves downwards to place the welding strip 60 on the grid line of the battery plate 70, the welding strip arrangement device 30 loosens the welding strip 60, and the traction frame 50 lifts up to complete the arrangement operation of the welding strip 60 on the battery plate 70.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims

1. The utility model provides a weld and take automatic device of arranging, includes to weld and takes cutting device, welds and takes the device of arranging, welding bench, traction frame, welds and takes the device of arranging to pass through traction frame effect will weld and take cutting device to go up the area of welding that has cut for the multistage to arrange and carry extremely weld on the battery piece on the welding bench, its characterized in that: the welding strip arrangement device is provided with a plurality of grabbing and releasing mechanisms which can perform translational dislocation actions perpendicular to the direction of a welding strip line, and the grabbing and releasing mechanisms are used for grabbing and placing the welding strips; or the welding strip cutting device is provided with a plurality of cutting mechanisms which can move in a translation and dislocation way in the direction vertical to the welding strip line, and the cutting mechanisms are used for cutting the whole welding strip into a plurality of sections so as to lead at least two groups of adjacent welding strips to be arranged on the corresponding grid lines of the battery pieces in a staggered way.

2. The automatic solder strip arraying device according to claim 1, wherein: the welding strip arranging device is provided with a horizontal driving mechanism, and the horizontal driving mechanism is connected with the spaced grabbing and placing mechanisms in a sliding mode so as to drive the spaced grabbing and placing mechanisms to move in the horizontal direction and enable the adjacent grabbing and placing mechanisms to be staggered.

3. The automatic solder strip arraying device according to claim 2, wherein: the welding strip cutting device comprises a plurality of cutting mechanisms, a base and a distance dividing mechanism, wherein the cutting mechanisms are distributed on the base in parallel, the base is connected with the distance dividing mechanism in a sliding manner, the distance dividing mechanism is used for adjusting the distance between the cutting mechanisms, the upper end of the distance dividing mechanism is fixedly connected with a horizontal driving mechanism and the cutting mechanisms, the distance dividing mechanism comprises a spiral lifter, a driving connecting plate and a movable guide rail seat, a lifting rod of the spiral lifter is fixedly connected with the side edge of the driving connecting plate, the driving connecting plate is provided with a plurality of inclined adjusting grooves, the inclination angles of the inclined adjusting grooves are gradually reduced in sequence according to the direction of separation of the cutting mechanisms, the lower end of the movable guide rail seat is lapped with the inclined adjusting grooves, so that the driving connecting plate drives the movable guide rail seat to move in the horizontal direction in the vertical moving process, the upper end of the movable guide rail seat is fixedly connected with the cutting mechanisms to drive the cutting mechanisms to move, the two sides of one side of the base are provided with vertical guide rails, the two sides of the driving connecting plate are in sliding connection with the vertical guide rails, the upper end of the base is provided with a translation guide rail, and the translation guide rail is in sliding connection with the movable guide rail seat.

4. The automatic solder strip arraying device according to claim 1, wherein: the welding strip cutting device is provided with a horizontal driving mechanism, the horizontal driving mechanism is fixedly connected with the spaced cutting mechanisms to drive the spaced cutting mechanisms to move in the horizontal direction, so that the adjacent cutting mechanisms are staggered.

5. The automatic solder strip arraying device according to claim 4, wherein: the welding strip cutting device also comprises a base and a distance dividing mechanism, the distance dividing mechanism is used for adjusting the distance between the cutting mechanisms, the base is connected with the distance-dividing mechanism in a sliding way, the upper end of the distance-dividing mechanism is fixedly connected with the horizontal driving mechanism and the cutting mechanism, the distance dividing mechanism comprises a movable guide rail seat, a distance dividing motor and a gear, the movable guide rail seat is connected with the upper end of the base in a sliding way, the lower end of the movable guide rail seat is fixedly connected with the distance dividing motor, the rotating shaft of the distance dividing motor is fixedly connected with the gear, the upper end of the base is provided with a translation guide rail, the side wall of the lower end of the base is provided with a rack, the translation guide rail is parallel to the rack and is vertical to the extension direction of the horizontal driving mechanism, the translation guide rail is connected with the movable guide rail seat in a sliding way, the rack is connected with the gear in a meshing way, the upper end of the movable guide rail seat is fixedly connected with the horizontal driving mechanism and the cutting mechanism so as to drive the cutting mechanism to move along the direction of the translation guide rail through the spacing motor.

6. The automatic solder strip arraying device according to claim 2 or 4, wherein: the horizontal driving mechanism comprises a plurality of horizontal electric push rods, and telescopic rods of the horizontal electric push rods are fixedly connected with the spaced grabbing and placing mechanisms or the spaced cutting mechanisms.

7. The automatic solder strip arraying device according to claim 2 or 4, wherein: the horizontal driving mechanism comprises a horizontal electric push rod and a connecting rod, the horizontal electric push rod is fixedly connected with one end of the connecting rod, a plurality of branch rods are arranged at the other end of the connecting rod, and the branch rods are fixedly connected with the spaced catching and placing mechanisms or the spaced cutting mechanisms.

8. The automatic solder strip arraying device according to claim 1, wherein: the grabbing and releasing mechanism comprises a vertical electric push rod, a push rod seat, a pushing connecting plate and a clamp assembly, the body of the vertical electric push rod is fixedly connected with the push rod seat, a telescopic rod of the vertical electric push rod is fixedly connected with the pushing connecting plate, the bottom of the pushing connecting plate is in lap joint with the clamp assembly, guide rods are further arranged on two sides of the bottom of the push rod seat, the guide rods are sleeved with the pushing connecting plate and are connected, and the bottom of each guide rod is fixedly connected with the clamp assembly.

9. The automatic solder strip arraying device according to claim 3 or 4, wherein: the cutting mechanism comprises a cutter and a lower clamp, the cutter is positioned on one side of the lower clamp, the lower clamp is provided with a lower clamping arm on two sides of the upper end of the lower clamp so as to clamp the welding strip.

10. A series welding machine for preparing a solar cell module, which is characterized by comprising the automatic solder strip arranging device of any one of claims 2, 3, 4, 5 and 8.