CN218069878U - Typesetting stitch welding machine - Google Patents

Abstract

The utility model provides a type setting stitch welding machine, pick up portion, regular conveying portion, stitch welding and pick up portion and stitch welding portion including the type setting, wherein: the typesetting and picking part is used for placing the battery strings on the regular conveying part; the regulating and conveying part is used for regulating the battery string; the stitch welding pick-up part comprises string pick-up components which correspond to the battery strings in the battery string array one by one; the regular conveying part is also used for conveying the regular battery strings to a string picking station, and the stitch welding picking part drives the string picking assembly corresponding to the battery strings at the string picking station to move to the string picking station to pick up the battery strings; the stitch welding picking part moves to drive the string picking assembly with the battery string to the welding station, and the stitch welding part welds the bus bar to the remaining long welding strip of the battery string positioned at the welding station; the stitch welding pick-up part is also used for laying the battery strings picked up by the string picking-up components completing the bus bar welding on the glass plate. The utility model provides a composing stitch welding machine has reduced the number of times of grabbing of battery cluster widely, can effectively reduce the piece rate.

Description

Typesetting stitch welding machine

Technical Field

The utility model belongs to the technical field of battery production and specifically relates to a composing stitch welding machine.

Background

Photovoltaic modules are typically fabricated by encapsulating upper and lower glass sheets and an array of cell strings positioned between the upper and lower glass sheets. When the photovoltaic module is manufactured, the battery strings produced by the series welding machine need to be typeset according to the requirements of the battery string array, and the bus bars are overlaid and welded on the remaining long welding strips of the battery strings. Currently, the battery string needs to be held and placed for many times in the process of typesetting and stitch-welding the bus bars. For example, during typesetting, the battery strings are grabbed and placed on the positioning table by the grabber to perform typesetting, and then all the battery strings after typesetting are grabbed and placed on the glass plate to be output. When the bus bars are stitch-welded, all the battery strings on the glass plate are grabbed and placed on the regulating table by the aid of the grabber to be regulated, all the regulated battery strings are grabbed away from the regulating table to be welded with the bus bars, and the battery strings are placed back on the glass plate after welding is completed. In the typesetting and stitch welding process, the battery strings are subjected to grabbing and releasing for up to four times, and frequent grabbing and releasing of the battery strings are the main reasons for causing the fragments of the battery pieces, so that the reduction of the grabbing and releasing times of the battery strings in the typesetting and stitch welding process is particularly important.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a composing stitch welding machine which detailed technical scheme as follows:

the utility model provides a composing stitch welding machine for carry out composing and busbar welding to the battery cluster according to battery cluster array among the photovoltaic module, composing stitch welding machine picks up portion, regular transport portion, stitch welding pick up portion and stitch welding portion including composing, wherein:

the typesetting and picking part is arranged in front of the regulating and conveying part and is used for picking up the battery strings and placing the battery strings on the regulating and conveying part according to the requirements of the positive and negative typesetting;

the regulating and conveying part is used for receiving and regulating the battery strings arranged by the typesetting and picking part;

the stitch welding pick-up part comprises string pick-up components which are arranged in one-to-one correspondence with each battery string in the battery string array; the stacking and welding picking part moves to drive the string picking assembly corresponding to the battery string at the string picking station to move to the string picking station to pick up the battery string;

the stitch welding picking part moves to drive the string picking assembly with the picked battery strings to a welding station, and the stitch welding part welds bus bars to the remaining long welding strips at the end parts of the battery strings at the welding station;

the stitch welding pick-up part is also used for moving to lay the battery strings picked up by the string picking-up components on the glass plate after the battery strings picked up by the string picking-up components are welded by the bus bars.

The utility model provides a typesetting stitch welding machine, pick up the portion according to typesetting and put the battery cluster to regular conveying portion earlier according to the positive negative pole requirement of typesetting on, regular conveying portion requires regular good battery cluster and will regular good battery cluster to picking up the cluster station again according to the position of typesetting, stitch welding picks up portion and picks up the battery cluster from picking up the cluster station after and carry the battery cluster to welding the station, stitch welding portion directly with the busbar welding to stitch welding pick up on the battery cluster of portion, stitch welding picks up portion again and puts all battery clusters to the glass board after the whole welding of busbar is accomplished, so far accomplish typesetting and the busbar welding of a battery cluster array.

It can be seen that, the utility model provides a typesetting stitch welding machine, whole typesetting stitch welding in-process battery cluster are only held in the palm and are put twice, hold respectively for one time of the portion of picking up of typesetting and hold in the palm with one time of the portion of picking up of stitch welding, have reduced the number of times of holding in the palm of battery cluster widely, can effectively reduce the piece rate of typesetting stitch welding in-process battery piece.

In some embodiments, the typesetting and picking part places at least one component unit on the regular conveying part at intervals of preset time, each component unit comprises two battery strings which are arranged in parallel along the length direction of the battery strings, and a plurality of component units are arranged in parallel along the width direction of the battery strings to form a battery string array; the regular conveying part conveys the regularly finished assembly units to a string picking station every preset time; the stitch welding picking part moves towards the backward direction for a preset distance at preset time intervals so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to the string picking station picking assembly unit and drive the string picking assembly picked with the assembly unit to the welding station.

In the embodiment, a complete battery string array is divided into a plurality of component units, and typesetting pickup, structured conveying, stitch welding pickup and bus bar welding are performed by taking at least one component unit as a unit, namely, the battery strings are placed on the structured conveying part by the typesetting pickup part according to the component units each time; correspondingly, the regular conveying part conveys the regular assembly units to a string picking station each time; the stitch welding picking part moves a preset distance towards the backward direction every time so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to pick up the assembly unit currently positioned at the string picking station and drive the string picking assembly picked up with the assembly unit before to the welding station, the stitch welding part welds a bus bar to the assembly unit at the welding station every time, and the process is repeated until the stitch welding picking part finishes the picking of a battery string array and the welding of the bus bar, and the battery string array can be blanked onto the glass plate.

It can be seen that the regulating and conveying part regulates and conveys at least one assembly unit each time, instead of conveying all the assembly units in the battery string array after all the assembly units are regulated; the overlap welding part welds at least one assembly unit conveyed in place at every time, and welding is not performed after waiting for all assembly units to be in place, so that the structure of the regular conveying part and the overlap welding part can be simplified, equipment cost is reduced, equipment floor area is reduced, and typesetting and bus bar welding efficiency can be improved.

In some embodiments, the typesetting pick-up section comprises a moving mechanism, a rotating mechanism and a pick-up assembly, wherein: the rotating mechanism is connected to the driving end of the moving mechanism, and the picking assembly is installed on the rotating mechanism; the moving mechanism is used for driving the picking assembly to translate and lift so as to pick up the battery string; the rotating mechanism is used for driving the picking assembly to rotate so as to rotate the battery string to meet the requirements of the typesetting anode and cathode; the moving mechanism is also used for driving the picking assembly to translate and lift so as to place the picked battery strings on the regular conveying part.

The typesetting picking part with a simple structure drives the picking assembly to move and rotate through the matching of the moving mechanism and the rotating mechanism, so that the battery strings are placed on the regular conveying part after rotating according to the requirements of typesetting positive and negative electrodes.

In some embodiments, the layout pickup sections are provided in two, respectively a first layout pickup section and a second layout pickup section, wherein: the first layout picking part is used for placing one of the battery strings in the assembly units on the regular conveying part; the second typesetting and picking part is used for placing another battery string in the assembly units on the regular conveying part.

Through the arrangement of the first typesetting pickup part and the second typesetting pickup part, the synchronous grabbing and releasing of the two battery strings in the assembly unit are realized, and the typesetting efficiency of the assembly unit can be effectively improved.

In some embodiments, the structured transport portion includes first and second structured transport mechanisms that are identical in structure, the first and second structured transport mechanisms being arranged side-by-side along a first horizontal direction; the first and second regulating and conveying mechanisms are respectively used for bearing two battery strings in the assembly unit; the first structured transport mechanism includes a first translational drive mechanism and at least one structured platform coupled to a moving end of the first translational drive mechanism, wherein: the regulating platform is used for bearing a battery string and regulating the battery string; the first translation driving mechanism is used for driving the gauge leveling platform to translate along a second horizontal direction perpendicular to the first horizontal direction so as to convey the battery strings loaded on the gauge leveling platform to the string picking station.

Through the arrangement of the first regular conveying mechanism and the second regular conveying mechanism, the synchronous regular and conveying of the two battery strings in the assembly unit are realized.

In some embodiments, the structured platform comprises a second translation drive mechanism, a lift drive mechanism, a rotation drive mechanism, and a structured carrier plate, wherein: the second translation driving mechanism is connected to the moving end of the first translation driving mechanism, the lifting driving mechanism is connected to the moving end of the second translation driving mechanism, the rotary driving mechanism is connected to the moving end of the lifting driving mechanism, and the structured bearing plate is connected to the moving end of the rotary driving mechanism; the structured bearing plate is used for bearing the battery strings, the second translation driving mechanism is used for driving the structured bearing plate to translate along the first horizontal direction, the lifting driving mechanism is used for driving the structured bearing plate to lift, and the rotation driving mechanism is used for driving the structured bearing plate to rotate in the horizontal plane.

The utility model provides a simple structure's regular platform, through the cooperation drive of first translation actuating mechanism, second translation actuating mechanism and rotation driving mechanism, can drive regular bearing plate and realize the translation on first horizontal direction and second horizontal direction and the rotation of horizontal direction to the realization is regular to the position of putting the battery cluster on regular bearing plate, and realizes carrying the battery cluster after will arranging to pick up a string station according to typesetting position requirement. The lifting driving mechanism can drive the regular bearing plate to ascend after the regular platform moves to the string picking station so as to transfer the battery strings to the corresponding string picking assembly on the stitch welding picking part. .

In some embodiments, the stitch pick further comprises a stepper drive mechanism and a first mounting bracket, wherein: the first mounting bracket is connected to the moving end of the stepping driving mechanism, and all the string picking assemblies are mounted on the first mounting bracket together; the stepping driving mechanism is used for stepping driving each string picking assembly to translate so as to drive the string picking assemblies corresponding to the assembly units at the string picking stations to the string picking station to pick up the assembly units, and meanwhile, the string picking assemblies picked up with the assembly units are driven to the welding station.

The stepping driving mechanism is used for stepping each string picking assembly, so that each string picking assembly can sequentially step the assembly units conveyed by the regular conveying part from the string picking station to the welding station until a plurality of assembly units of the bus bar are welded to form a battery string array.

In some embodiments, the layout stitch bonding machine further includes a battery string supply section for producing the battery string and supplying the produced battery string to the layout pickup section.

Through setting up battery cluster feed portion, realized the automatic feed to the battery cluster.

In some embodiments, the battery string supplying portion includes a string welding machine, an output conveying line, a turnover mechanism, and a buffer mechanism, wherein: the series welding machine is used for producing the battery string; the discharging conveying line is used for outputting the battery strings produced by the series welding machine; the buffer mechanism is arranged at the side of the discharging conveying line, and the turnover mechanism is used for picking up the battery strings from the discharging conveying line, turning the picked battery strings for 180 degrees and then placing the battery strings on the buffer mechanism; the composition pickup section picks up the battery string from the buffer mechanism.

Through setting up tilting mechanism, realized the upset to the battery cluster to directly overturn the battery cluster to the state of treating the typesetting, and then promoted the pick-up efficiency of back row's typesetting pick-up portion. By arranging the cache mechanism, the cache of the battery strings is realized, and the typesetting waiting caused by the inconsistency between the production speed of the stringer and the subsequent typesetting and picking speed is avoided. In addition, tilting mechanism can pick up the battery cluster and directly place the buffer memory mechanism after the upset on, need not extra battery cluster tongs and pick up the battery cluster after the upset and put buffer memory mechanism again, through once grabbing put realize the upset and the buffer memory of battery cluster promptly, be favorable to reducing the piece rate of battery piece.

In some embodiments, the battery string supplying portion further includes an EL detecting mechanism disposed on the discharging conveyor line for detecting the battery strings output by the discharging conveyor line, and the turning mechanism is configured to pick up qualified battery strings from the discharging conveyor line through the EL detecting mechanism.

The quality detection of the battery strings is realized by arranging the EL detection mechanism, so that the battery strings which are qualified in detection are ensured to enter the subsequent typesetting and welding procedures, and the qualification rate of the photovoltaic module is finally ensured; simultaneously, EL detection mechanism directly sets up on ejection of compact conveying line, can directly carry out EL to the battery cluster on the ejection of compact conveying line and detect to need not to grab away the battery cluster from ejection of compact conveying line and detect, avoided grabbing of battery cluster and put, be favorable to reducing the piece rate of battery piece.

In some embodiments, the EL detection mechanism includes a first conduction mechanism, a second conduction mechanism, and an EL camera disposed above or below the outfeed conveyor line; the first conduction mechanism and the second conduction mechanism are used for conducting the battery strings on the discharging conveying line from two ends; the EL camera is used to acquire an infrared image of the battery string that is turned on to perform detection of the battery string.

The utility model provides a simple structure's EL detection mechanism, through with first conduction mechanism, second conduction mechanism setting on ejection of compact conveying line, realized that the battery cluster keeps can accomplish the EL and detect on ejection of compact conveying line, and need not to pick up the battery cluster from ejection of compact conveying line.

In some embodiments, the turnover mechanism includes a first lifting driving module, a second lifting driving module, a turnover motor, and a turnover adsorption component, wherein: the overturning motor is connected to the driving end of the second lifting driving module; the first end of the overturning adsorption assembly is connected to the driving end of the first lifting driving module, and the second end of the overturning adsorption assembly is connected to the driving end of the overturning motor; first lift drive module and second lift drive module cooperation drive upset adsorption component go up and down, and the upset motor is used for driving upset adsorption component and overturns between ejection of compact transfer chain and cache mechanism to drive upset adsorption component and absorb the battery cluster from ejection of compact transfer chain, and overturn the battery cluster of absorption to cache mechanism on.

The utility model provides a simple structure's tilting mechanism, it is through the cooperation of first lift drive module, second lift drive module, upset motor and upset adsorption component, directly overturns the battery cluster to the state of treating the typesetting.

In some embodiments, the buffer mechanism comprises a second mounting bracket, a plurality of support plates, a first support plate pushing mechanism and a second support plate pushing mechanism, wherein: a plurality of supporting plates are vertically stacked on the second mounting bracket, and each supporting plate is connected to the second mounting bracket through a sliding rail; the first support pushing mechanism is configured to push one supporting plate out of the second mounting bracket to the first side at a time so as to receive the battery string transferred by the turnover mechanism; the second palette pusher mechanism is configured to push out the second mounting bracket one palette carrying the battery string at a time toward the second side to supply the battery string to the layout pickup.

A plurality of supporting plates are arranged on the second mounting bracket layer by layer, so that the buffer storage of a plurality of battery strings is realized; the layer board can stretch out or withdraw from the both sides of second installing support, and when the layer board stretches out to the primary side, can receive the battery cluster that tilting mechanism transported, when the layer board stretches out to the second side, provides the battery cluster for composing pick-up unit to battery cluster buffering and taking out can go on from both sides, mutual noninterference.

In some embodiments, the stitch bond includes a bus bar preparation portion, a bus bar handling portion, a bus bar carrying portion, and a weld portion; the bus bar preparing part is configured to prepare a bus bar; the bus bar carrying part is configured to carry the bus bar to the bus bar bearing part; the bus bar bearing part is configured to move the bus bar to a corresponding position of the left long welding strip; the welding part is used for welding the bus bar carried by the bus bar carrying part to the long welding strip.

The bus bar preparation part and the bus bar conveying part can synchronously prepare and convey the bus bar when the bus bar bearing part and the welding part are matched for welding the bus bar, and the efficiency is improved.

In some embodiments, the typesetting stitch welding machine further comprises a glass sheet conveying line; the glass plate conveying line is arranged below the regular conveying part and the stitch welding part and has the same conveying direction with the regular conveying part, and the glass plate conveying line is used for conveying glass plates to a blanking station located at the rear of the welding station; and the stitch welding pick-up part is used for blanking the battery strings picked up by the string pickup assemblies onto a glass plate of a blanking station after the battery strings picked up by the string pickup assemblies are welded by the bus bars.

The glass plate conveying line is arranged to realize the on-line supply of the glass plates so as to receive the battery strings fed by the stitch welding pick-up part and facilitate the production of the next procedure.

Drawings

Fig. 1 is a schematic structural diagram of a typesetting stitch welding machine in an embodiment of the present invention at a first viewing angle;

fig. 2 is a schematic structural diagram of a typesetting stitch welding machine according to an embodiment of the present invention at a second viewing angle;

fig. 3 is a schematic structural diagram of the typesetting stitch welding machine according to the embodiment of the present invention at a third viewing angle;

FIG. 4 is a schematic structural view of a first structured conveying mechanism in an embodiment of the present invention;

fig. 5 is a schematic structural diagram of the turnover mechanism, the buffer mechanism and the EL detection mechanism in an embodiment of the present invention at a viewing angle;

fig. 6 is a schematic structural diagram of the turnover mechanism, the buffer mechanism and the EL detection mechanism in another view angle in the embodiment of the present invention;

fig. 7 is a schematic structural diagram of a supporting plate in an embodiment of the present invention;

fig. 8 is a schematic structural view of a lap welding portion in an embodiment of the present invention;

FIG. 9 is a schematic diagram of a battery string array after bus bar welding is completed in one embodiment;

the following reference numerals are included in fig. 1 to 9:

a stringer 1;

a discharging conveying line 2;

and (3) turning over a mechanism: a first lifting driving module 31, a second lifting driving module 32, a turnover motor 33, a turnover adsorption component 34, a rotating shaft 341 and an adsorption piece 342;

the buffer mechanism 4: the mounting bracket 41, the supporting plate 42, the first supporting plate pushing mechanism 43, the second supporting plate pushing mechanism 44 and the avoiding groove 421;

EL detection mechanism 5: a first conduction mechanism 51, a second conduction mechanism 52, a first electrode sheet 511, a first electrode sheet drive unit 512, a second electrode sheet 521, and a second electrode sheet drive unit 522;

a first plate-discharge pickup section 6;

a second layout pickup section 7;

a first organizing and conveying mechanism 8, a second organizing and conveying mechanism 9: a first translation driving mechanism 81, a sliding rail 811, a regulating platform 82, a second translation driving mechanism 821, a lifting driving mechanism 822, a rotation driving mechanism 823 and a regulating bearing plate 824;

stitch pickup 10: a string picking assembly 1001;

overlap-welded portion 11: a header bus bar preparation section 111, a middle and tail bus bar preparation section 112, a header bus bar carrying section 113, a tail bus bar carrying section 114, a middle bus bar carrying section 115, a header soldering section 116, a middle soldering section 117, a tail soldering section 118;

a glass sheet conveying line 12;

a glass plate 13;

a first battery string 101, a second battery string 102, a third battery string 103, a fourth battery string 104, a fifth battery string 105, a sixth battery string 106, a seventh battery string 107, an eighth battery string 108, a ninth battery string 109, a tenth battery string 110, an eleventh battery string 111, and a twelfth battery string 112;

a first intermediate bus bar 201, a first head bus bar 202, a first tail bus bar 203, a second intermediate bus bar 204, a second head bus bar 205, a second tail bus bar 206, a third intermediate bus bar 207, a third head bus bar 208, a fourth intermediate bus bar 209, a third tail bus bar 210.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the following detailed description.

The utility model relates to a stitch welding machine typesets, it is arranged in typesetting and the busbar welding to the battery cluster according to battery string array among the photovoltaic module, and at whole stitch welding in-process of typesetting, the battery cluster is only picked up twice to effectively reduce the piece rate.

As shown in fig. 1 to 3, the utility model provides a type setting stitch welding machine for typesetting and bus bar welding the battery string according to battery string array among the photovoltaic module, this type setting stitch welding machine picks up portion 10 and stitch welding portion 11 including type setting pick up portion, regular transport portion, stitch welding, wherein:

the typesetting and picking part is arranged in front of the regular conveying part and is used for picking up the battery strings and placing the battery strings on the regular conveying part according to the requirements of the positive and negative typesetting.

The regular conveying part is used for receiving and arranging the battery strings arranged by the typesetting and picking part.

Stitch bond pick-up 10 includes a string pick-up assembly 1001 arranged in one-to-one correspondence with each of the cell strings in the cell string array. The regular conveying part is also used for conveying the regular battery strings to the string picking-up station according to the requirements of the typesetting position, and the stitch welding picking-up part 10 moves to drive the string picking-up assembly 1001 corresponding to the battery strings at the string picking-up station to move to the string picking-up station to pick up the battery strings.

The stitch welding pick-up 10 moves to bring the string pick-up assembly 1001 with the battery string picked up to the welding station, and the stitch welding part welds the bus bars onto the remaining long solder strips at the ends of the battery string at the welding station.

The stitch welding pick-up portion is also configured to move to lay the battery string picked up by each string pick-up assembly 1001 on the glass plate 13 after the battery string picked up by each string pick-up assembly 1001 is subjected to bus bar welding.

It is thus clear that, adopt the utility model discloses a typesetting stitch welding machine, pick up the portion according to typesetting and put the battery cluster to regular conveying portion earlier on positive negative pole requirement, regular conveying portion requires regular good battery cluster and carries the battery cluster to picking up the cluster station according to the position of typesetting again, stitch welding pick up portion from picking up and carry the battery cluster to the welding station after the cluster station picks up the battery cluster, then, stitch welding portion directly with the busbar welding to keep staying long the solder strip on the tip of the battery cluster that the stitch welding picked up the portion. The cell string picking-up components on the stitch welding picking-up part are arranged in one-to-one correspondence with the cell strings in the cell string array, so that the typesetting of the cell strings is completed after all the cell string picking-up components pick up the cell strings, and finally, the stitch welding picking-up part lays the cell strings on the glass plate after all the picked cell strings are welded with the bus bars, so that the typesetting and the bus bar welding of one photovoltaic module are completed.

The battery string is only grabbed and placed twice in the whole typesetting and stitch welding process, so that the grabbing and placing times of the battery string are greatly reduced, and the fragment rate of the battery piece in the typesetting and stitch welding process can be effectively reduced.

The photovoltaic module can be generally divided into a monolithic module and a half-module, wherein the monolithic module is formed by packaging a battery string array formed by a plurality of monolithic battery strings, the half-module is formed by packaging a battery string array formed by a plurality of half-module battery strings, the half-module battery strings are formed by series welding small pieces formed by breaking off the monolithic battery pieces, and the half-module battery strings are about half of the length of the monolithic battery strings. And the end parts of the half battery strings and the whole battery strings are provided with long welding strips for welding with bus bars, and the bus bars can collect the current generated by each battery string and output the current through a junction box.

In general, from the viewpoint of the overall design length of the module, the battery string array in the whole module only has one group of whole battery strings, and the battery strings in the group of whole battery strings are arranged side by side, so that the long solder strips in the whole module are only positioned at the head and the tail of the module. And in order to obtain the length equivalent to that of the whole assembly, the battery string array in the half-sheet assembly comprises two groups of half-sheet battery strings, the two groups of half-sheet battery strings are arranged in parallel along the length direction of the battery strings, and the battery strings in each group of half-sheet battery strings are arranged in parallel, so that the remaining long welding strips in the half-sheet assembly are positioned at the head part, the middle part and the tail part of the assembly.

The half chip module exhibits more excellent photoelectric conversion efficiency than the whole chip module, and therefore has been attracting attention and preferred in recent years.

Aiming at the typesetting and the bus bar welding of the half-sheet assembly, the utility model has the advantages that the typesetting and picking part puts at least one assembly unit on the regular conveying part at intervals of preset time, each assembly unit comprises two battery strings which are arranged in parallel along the length direction of the battery strings, and a plurality of assembly units are arranged in parallel along the width direction of the battery strings to form a battery string array; the regular conveying part conveys the regularly finished assembly units to a string picking station at intervals of preset time; the stitch welding picking part moves towards the backward direction for a preset distance at preset time intervals so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to the string picking station picking assembly unit and drive the string picking assembly picked with the assembly unit to the welding station.

The battery string array of the half-sheet assembly is divided into a plurality of assembly units, and typesetting pickup, structured conveying, stitch welding pickup and bus bar welding are carried out by taking at least one assembly unit as a unit, namely, the battery strings are placed on the structured conveying part by the typesetting pickup part according to the assembly units each time; correspondingly, the regular conveying part conveys the regular assembly units to a string picking station each time; the stitch welding picking part moves a preset distance towards the backward direction every time so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to pick up the assembly unit currently positioned at the string picking station and drive the string picking assembly picked up with the assembly unit before to the welding station, the stitch welding part welds a bus bar to the assembly unit at the welding station every time, and the process is repeated until the stitch welding picking part finishes the picking of a battery string array and the welding of the bus bar, and the battery string array can be blanked onto the glass plate.

By using the assembly units as units to perform typesetting pickup, arranging and conveying, stitch welding pickup and bus bar welding, the arranging and conveying part does not need to convey all the assembly units in the battery string array after all the assembly units are arranged; overlap welding portion and need not to wait for all subassembly units and put in place and implement the welding again, can simplify regular conveying portion, overlap welding portion's structure on the one hand, regular conveying portion and overlap welding portion only need set up for the subassembly unit of treating the transport promptly, need not to set up for whole subassembly unit to can greatly reduced equipment cost, reduce equipment area, and can promote composing and busbar welding efficiency.

The following describes the process of performing the layout and stitch welding in the unit of the module unit in this embodiment, taking the battery string array of the half-chip module shown in fig. 9 as an example.

The battery string array in fig. 9 is formed by arranging 6 module units side by side in the width direction of the battery string (e.g., the Y-axis direction in the drawing), and each module unit includes two battery strings arranged side by side in the length direction of the battery string (e.g., the X-axis direction in the drawing). Specifically, the first module unit is formed by arranging a first cell string 101 and a second cell string 102, the second module unit is formed by arranging a third cell string 103 and a fourth cell string 104, the third module unit is formed by arranging a fifth cell string 105 and a sixth cell string 106, the fourth module unit is formed by arranging a seventh cell string 107 and an eighth cell string 108, the fifth module unit is formed by arranging a ninth cell string 109 and a tenth cell string 110, and the sixth module unit is formed by arranging an eleventh cell string 111 and a twelfth cell string 112.

Accordingly, the stitch bonding pick-up portion 10 includes 12 string pickup assemblies 1001 arranged in one-to-one correspondence with the 12 battery strings in the battery string array shown in fig. 9, and two string pickup assemblies 1001 juxtaposed to each other constitute one pickup unit, each pickup unit being for picking up one assembly unit correspondingly.

The description will be given by taking an example in which the typesetting pickup part places one component unit on the regular conveying part every predetermined time, the regular conveying part conveys one regularly completed component unit to the string picking station every predetermined time, the stitch welding pickup part moves a predetermined distance in the backward direction every predetermined time, so as to drive one pickup unit corresponding to one component unit at the string picking station to pick up the component unit, and simultaneously drive the pickup unit picked with one component unit to the welding station, and the stitch welding part welds a bus bar to the component unit at the welding station. Specifically, the matching working process of the typesetting pickup part, the regular conveying part, the stitch welding pickup part and the stitch welding part is as follows:

in an initial state, the first picking unit of the stitch welding picking part 10 is located at a string picking station, the typesetting picking part places the first assembly units, namely the first battery string 101 and the second battery string 102, on the regulating conveying part, the regulating conveying part conveys the first assembly units to the string picking station after regulating the first battery string 101 and the second battery string 102, the first picking unit of the stitch welding picking part 10 picks the first battery string 101 and the second battery string 102 conveyed by the regulating conveying part, then, the stitch welding picking part 10 moves in the backward direction for a predetermined distance, so that the first picking unit moves to a welding station, the second picking unit moves to the string picking station, and then, the stitch welding part welds the first intermediate bus bar 201 to the remaining long welding strips of the first battery string 101 and the second battery string 102 located at the welding station.

After the first assembly unit is picked up by the stitch pick-up 10, the regulating and conveying unit returns to receive the second assembly unit, i.e., the third battery string 103 and the fourth battery string 104, picked up by the composition pick-up unit, the third battery string 103 and the fourth battery string 104 are conveyed to the string pick-up station after being regulated, the second pick-up unit of the stitch pick-up unit picks up the third battery string 103 and the fourth battery string 104, then the stitch pick-up 10 moves in the backward direction by a predetermined distance so that the second pick-up unit moves to the welding station, the third pick-up unit moves to the string pick-up station, and then the stitch pick-up unit welds the first header bus bar 202 and the first tail bus bar 203 to the remaining long solder strips of the first battery string 101, the second battery string 102, the third battery string 103 and the fourth battery string 104 located at the welding station.

After the second assembly unit is picked up by the stitch pick-up 10, the regulating and conveying unit returns to receive the third assembly unit picked up by the stitch pick-up, i.e., the fifth battery string 105 and the sixth battery string 106, conveys the fifth battery string 105 and the sixth battery string 106 to the string pick-up station after regulating, picks up the fifth battery string 105 and the sixth battery string 106 by the third pick-up unit of the stitch pick-up, then moves the stitch pick-up 10 in the backward direction by a predetermined distance so that the third pick-up unit moves to the welding station, moves the fourth pick-up unit to the string pick-up station, and then welds the second intermediate bus bar 204 to the remaining long solder tapes of the third battery string 103, the fourth battery string 104, the fifth battery string 105 and the sixth battery string 106 located at the welding station.

After the third component unit is picked up by the stitch pick-up 10, the regulating and conveying unit returns to receive the fourth component unit picked up by the stitch pick-up, that is, the seventh cell string 107 and the eighth cell string 108, conveys the seventh cell string 107 and the eighth cell string 108 to the string pick-up station after regulating, picks up the seventh cell string 107 and the eighth cell string 108 by the fourth pick-up unit of the stitch pick-up, and then moves the stitch pick-up 10 in the backward direction by a predetermined distance so that the fourth pick-up unit moves to the welding station and the fifth pick-up unit moves to the string pick-up station, and then welds the second header bus bar 205 and the second tail bus bar 206 to the remaining long solder ribbons of the fifth cell string 105, the sixth cell string 106, the seventh cell string 107 and the eighth cell string 108 located at the welding station.

After the fourth assembly unit is picked up by the stitch pick-up portion 10, the regulating and conveying portion then returns to receive the fifth assembly unit, i.e., the ninth battery string 109 and the tenth battery string 110, picked up by the composition pick-up portion, conveys the ninth battery string 109 and the tenth battery string 110 to the string pick-up station after regulating, picks up the ninth battery string 109 and the tenth battery string 110 by the fifth pick-up unit of the stitch pick-up portion, and then the stitch pick-up portion 10 moves in the backward direction by a predetermined distance so that the fifth pick-up unit moves to the welding station, the sixth pick-up unit moves to the string pick-up station, and then the stitch portion welds the third intermediate bus bar 207 to the remaining long solder ribbons of the seventh battery string 107, the eighth battery string 108, the ninth battery string 109 and the tenth battery string 110 located at the welding station.

After the fifth component unit is picked up by the stitch pick-up 10, the regulating and conveying unit returns to receive the sixth component unit picked up by the stitch pick-up, that is, the eleventh cell string 111 and the twelfth cell string 112, conveys the eleventh cell string 111 and the twelfth cell string 112 to the string pick-up station after regulating, picks up the eleventh cell string 111 and the twelfth cell string 112 by the sixth pick-up unit of the stitch pick-up, then moves the stitch pick-up 10 in the backward direction by a predetermined distance so that the sixth pick-up unit moves to the welding station, and then welds the third header bus bar 208, the fourth intermediate bus bar 209 and the third tail bus bar 210 to the remaining long weld tapes of the ninth cell string 109, the tenth cell string 110, the eleventh cell string 111 and the twelfth cell string 112 located at the welding station.

To this end, the layout of the battery string array of one half sheet assembly and the bus bar welding are completed, and the stitch welding pick-up section then discharges the bus bar-welded battery string array onto a glass plate.

In order to further improve the efficiency, the typesetting and picking part can also place other numbers of battery strings such as 4 battery strings, 6 battery strings and the like on the regular conveying part at each time to form other corresponding numbers of component units such as 2 battery strings, 3 battery strings and the like, correspondingly, the regular conveying part conveys the corresponding numbers of component units to the string picking station at each time, and the stitch welding and picking part 10 moves the corresponding numbers of picking units to the string picking station and the welding station at each time. For example, the typesetting and picking part puts 4 battery strings, namely two assembly units, on the regular conveying part at each time, at the moment, the regular conveying part conveys the two assembly units to a string picking station at each time, and when the stitch welding and picking part moves at each time, the two picking units move to the welding station and the two adjacent picking units move to the string picking station at the same time.

Of course, the typesetting stitch welding machine of the utility model is also suitable for typesetting and stitch welding of the whole battery string. In this case, in some implementations, the typesetting and picking section places one battery string on the regulating and conveying section each time, and after the regulating and conveying section finishes regulating one battery string, the battery string is conveyed to a string picking station and provided to a string picking assembly corresponding to the battery string on the stitch welding and picking section; the string picking assembly picks up the battery string and then moves to a welding station, meanwhile, an adjacent string picking assembly at the back moves to the string picking station, and the stitch welding part welds a bus bar to the battery string at the welding station. The type-setting stitch-welding process of the whole piece assembly is similar to that of the half piece assembly, and will not be described in detail.

In some implementations, stitch pick up 10 further includes a stepper drive mechanism and a first mounting bracket, wherein: the first mounting bracket is connected to the moving end of the step drive mechanism, and the string picking assemblies 1001 are mounted together on the first mounting bracket. The stepping driving mechanism is used for stepping and driving each string picking assembly 1001 to translate so as to drive the string picking assembly 1001 corresponding to the assembly unit at the string picking station to the string picking station picking assembly unit, and meanwhile, the string picking assembly 1001 picked with the assembly unit is driven to the welding station.

In some implementations, the composition pick includes a moving mechanism, a rotating mechanism, and a pick assembly, wherein: the rotating mechanism is connected to the driving end of the moving mechanism, and the picking assembly is installed on the rotating mechanism; the moving mechanism is used for driving the picking assembly to translate and lift so as to pick up the battery string; the rotating mechanism is used for driving the picking assembly to rotate so as to rotate the battery string to meet the requirements of the typesetting anode and cathode; the moving mechanism is also used for driving the picking assembly to translate and lift so as to place the picked battery strings on the regular conveying part.

The moving mechanism may be a robotic arm or a truss that is capable of moving in the three directions X, Y, Z. The pick-up assembly may employ a suction cup set capable of attracting the battery string.

When the battery strings are typeset, the same ends of two adjacent battery strings which are arranged together side by side are ensured to have opposite polarities so as to facilitate the serial welding of the bus bars, and therefore, a rotating mechanism is arranged to control the picked partial battery strings to rotate in a plane so as to ensure that the same ends of the two adjacent battery strings which are finally arranged side by side have opposite polarities, so that the requirements of the positive and negative electrodes of the typesetting are met.

As shown in fig. 1 to 3, in some implementations, there are two layout pickup sections, a first layout pickup section 6 and a second layout pickup section 7, where: the first typesetting and picking part 6 is used for placing one battery string in the assembly units on the regulated conveying part, and the second typesetting and picking part 7 is used for placing the other battery string in the assembly units on the regulated conveying part. That is, when the layout of the half-cell strings and the bus bar welding are performed, the first layout pickup unit 6 and the second layout pickup unit 7 synchronously place the two cell strings in the module unit on the regular conveying unit, thereby improving the layout efficiency of the module unit.

In some implementations, as shown in FIGS. 1 and 4, the regulated transport includes first and second regulated transport mechanisms 8, 9 that are identical in structure, with the first and second regulated transport mechanisms 8, 9 being arranged side-by-side along a first horizontal direction (e.g., the X-direction in FIG. 1). The first and second regulating and conveying mechanisms 8 and 9 are respectively used for bearing two battery strings in the assembly unit.

The first normalization conveying mechanism 8 includes a first translation driving mechanism 81 and at least one normalization platform 82 connected to the moving end of the first translation driving mechanism 81, in fig. 4, the moving end of the first translation driving mechanism 81 is connected to one normalization platform 82, the normalization platform 82 is used for bearing a string of battery strings and normalizing the battery strings, and when the moving end of the first translation driving mechanism 81 is connected to a plurality of normalization platforms 82, each normalization platform 82 is used for bearing a string of battery strings and normalizing the battery strings. The first translation driving mechanism 81 is configured to drive each regulating platform 82 to translate along a sliding rail 811, and the sliding rail 811 is arranged along a second horizontal direction (e.g., a Y-axis direction in fig. 4) perpendicular to the first horizontal direction, so as to convey the battery string carried on each regulating platform 82 to the string picking station.

As described above, when the layout of the half-cell strings and the bus bar welding are performed, if the layout pickup portion places one module unit onto the structured conveying portion each time, the first structured conveying mechanism 8 and the second structured conveying mechanism 9 are respectively provided with one structured platform 82. The structured platform 82 of the first structured conveying mechanism 8 is used for placing one battery string in the assembly unit, and the structured platform 82 of the second structured conveying mechanism 9 is used for placing another battery string in the assembly unit. If the typesetting and picking part puts N component units on the regulating and conveying part every time, and N is larger than 1, the first regulating and conveying mechanism 8 and the second regulating and conveying mechanism 9 are respectively provided with N regulating platforms 82.

In some implementations, one cell string of a module unit is placed on the organizer platform 82 of the first organizing conveyor 8 by the first layout pick 6, and another cell string of a module unit is placed on the organizer platform 82 of the second organizing conveyor 9 by the second layout pick 7.

With continued reference to FIG. 4, in some implementations, the regulated platform 82 includes a second translation drive 821, a lift drive 822, a rotation drive 823, and a regulated carrier plate 824, wherein: the second translation driving mechanism 821 is connected to the moving end of the first translation driving mechanism 81, the lifting driving mechanism 822 is connected to the moving end of the second translation driving mechanism 821, the rotation driving mechanism 823 is connected to the moving end of the lifting driving mechanism 822, and the structured carrier plate 824 is connected to the moving end of the rotation driving mechanism 823. The structured bearing plate 824 is used for bearing the battery string, the second translational driving mechanism 821 is used for driving the structured bearing plate 824 to translate along a first horizontal direction (X direction in the figure), the lifting driving mechanism 822 is used for driving the structured bearing plate 824 to lift, and the rotational driving mechanism 823 is used for driving the structured bearing plate 824 to rotate in a horizontal plane.

Through the matching drive of the first translation driving mechanism 81, the second translation driving mechanism 821 and the rotation driving mechanism 823, the structured bearing plate 824 can be driven to realize translation in the direction X, Y and rotation in the horizontal direction, so that the position arrangement of the battery strings placed on the structured bearing plate 824 is realized, and the arranged battery strings are conveyed to the string picking station according to the requirements of the arrangement position. The lift drive mechanism 822 can drive the structured carrier plate 824 to rise after the structured platform moves to the string pick-up station to transfer the battery string to a corresponding string pick-up assembly on the stitch welding pick-up.

In some implementations, the first layout pickup unit 6 picks up one string of battery strings, rotates the battery strings according to the requirements of the positive and negative layout, and then puts the battery strings on the arranging platform 82 of the first arranging and conveying mechanism 8, and the second layout pickup unit 7 picks up another string of battery strings, rotates the battery strings according to the requirements of the positive and negative layout, and then puts the battery strings on the arranging platform 82 of the second arranging and conveying mechanism 9. After the first arranging and conveying mechanism 8 and the second arranging and conveying mechanism 9 respectively arrange the corresponding battery strings, the two battery strings are synchronously conveyed to the rear path and are conveyed to the preset position of the string picking station all the time.

In some implementation manners, a visual camera is arranged above the first and second arranging and conveying mechanisms 8 and 9, the visual camera is used for photographing the battery string to acquire the position information of the battery string, and the first and second arranging and conveying mechanisms 8 and 9 implement arranging and conveying of the corresponding battery string according to the position information of the corresponding battery string acquired by the visual camera.

In some implementations, the utility model discloses a composing stitch welding machine still includes battery cluster feed portion, and battery cluster feed portion is used for producing the battery cluster and offers the battery cluster of producing to typeset the portion of picking up.

With continued reference to fig. 1-3, in some implementations, the battery string supply portion includes a stringer 1, an output conveyor line 2, a turnover mechanism 3, and a buffer mechanism 4, wherein: the stringer 1 is used to produce a battery string. And the discharging conveying line 2 is used for outputting the battery strings produced by the stringer 1. Buffer memory mechanism 4 sets up the avris at ejection of compact transfer chain 2, and tilting mechanism 3 is used for picking up the battery cluster from ejection of compact transfer chain 2 to place on buffer memory mechanism 4 after 180 of battery cluster upset that will pick up. The composition pickup section picks up the battery string from the buffer mechanism 4.

In some implementations, with continued reference to fig. 1 to 3, the stringer 1 is a twin string welder, and has two battery string production lines, and accordingly, the discharge ends of the two battery string production lines are respectively and correspondingly provided with one discharge conveyor line 2 to output battery strings, the battery string output by one discharge conveyor line 2 is provided to the first layout pickup portion 6, and the battery string output by the other discharge conveyor line 2 is provided to the second layout pickup portion 7. Through adopting double-line stringer to realize the two supplies of battery cluster, promoted the feeding efficiency of battery cluster. When two discharging conveying lines 2 are arranged, correspondingly, the turnover mechanism 3 and the buffer mechanism 4 are also arranged to be two. The two turnover mechanisms 3 respectively pick up the battery strings from the corresponding discharging conveying lines 2 and cache the picked battery strings into the corresponding caching mechanisms 4.

Generally, the battery strings produced by the series welding machine are arranged with the front side facing upwards, the back side of the battery strings is required to face upwards during typesetting, and 180-degree overturning of the battery strings can be realized by arranging the overturning mechanism 3, so that the battery strings are directly overturned to a state to be typeset, and the picking efficiency of a subsequent typesetting picking part is improved. And through setting up the buffer memory mechanism 4, have realized the buffer memory to the battery cluster that the stringer 1 produces, avoid the production speed of the stringer 1 and the subsequent typesetting pick up the speed and inconsistent and cause the typesetting to wait, for the double-line stringer, the setting up of the buffer memory mechanism can also avoid the typesetting to wait because of two production line production speeds are inconsistent and cause. In addition, tilting mechanism can pick up the battery cluster and directly place the buffer memory mechanism after the upset on, need not extra battery cluster tongs and pick up the battery cluster after the upset and put buffer memory mechanism again, through once grabbing put realize the upset and the buffer memory of battery cluster promptly, be favorable to reducing the piece rate of battery piece.

In some implementations, as shown in fig. 5 and 6, the turnover mechanism 3 includes a first lifting driving module 31, a second lifting driving module 32, a turnover motor 33, and a turnover adsorption component 34, wherein: the overturning motor 33 is connected to the driving end of the second lifting driving module 32, the first end of the overturning adsorption group 34 is connected to the driving end of the first lifting driving module 31, and the second end of the overturning adsorption group 34 is connected to the driving end of the overturning motor 33. First lift drive module 31 and second lift drive module 32 cooperation drive upset adsorption component 34 go up and down, and upset motor 33 is used for driving upset adsorption component 34 and overturns between ejection of compact transfer chain 2 and buffer mechanism 4 to drive upset adsorption component 34 and absorb the battery cluster from ejection of compact transfer chain 2, and overturn the battery cluster of absorption to buffer mechanism 4.

It can be seen that, through the cooperation of the first lifting driving module 31, the second lifting driving module 32, the turnover motor 33 and the turnover adsorption assembly 34, the turnover mechanism 3 can pick up the battery string from the discharge conveying line 2, and cache the battery string in the cache mechanism 4 after turning over 180 degrees.

With continued reference to fig. 5 and 6, in some implementations, the buffer mechanism 4 includes a second mounting bracket 41, a plurality of pallets 42, a first pallet pushing mechanism 43, and a second pallet pushing mechanism 44, wherein: a plurality of support plates 42 are vertically stacked on the second mounting bracket 41, and each support plate 42 is connected to the second mounting bracket 41 through a slide rail. The first tray pushing mechanism 43 is configured to push one tray 42 out of the second mounting bracket 41 to the first side at a time to receive the battery string transferred by the turnover mechanism 3. The second pallet pushing mechanism 44 is configured to push one pallet 42 carrying the battery string out of the second mounting bracket 41 to the second side at a time to supply the battery string 42 to the layout pickup.

By providing a plurality of trays 42, the buffer mechanism 4 can buffer a plurality of battery strings. And set up into the layer board 42 and can stretch out or withdraw from the both sides of second installing support 41, when layer board 42 stretches out to first side, receive the battery cluster that tilting mechanism 3 transported, when layer board 42 stretches out to the second side, then provide the battery cluster for composing pick-up portion to realized that the battery cluster is deposited and is taken out and go on from both sides, mutual noninterference.

As shown in fig. 5, the support plate 42 is optionally provided with an escape groove 421 for the turnover absorption assembly 34 to pass through. After the completion is to the upset of battery cluster, upset adsorption component 34 is located the below of battery cluster promptly, drives the in-process that the battery cluster descends at upset adsorption component 34, and upset adsorption component 34 passes by dodging groove 421 to place the battery cluster after the upset on layer board 42. As shown in fig. 7, the evacuation slot 421 is opened at a side close to the turnover mechanism 3, so that the turnover adsorption component 34 can smoothly pass through the evacuation slot 421.

In one implementation, the turning and adsorbing assembly 34 includes a rotating shaft 341 and several adsorbing members 342, wherein: a first end of the rotating shaft 341 is connected to a driving end of the first elevation driving module 31, and a second end of the rotating shaft 341 is connected to a driving end of the reversing motor 33. The plurality of suction members 342 are installed on the rotating shaft 341 side by side in the extending direction of the rotating shaft 341. Correspondingly, the supporting plate 42 is provided with relief grooves 421 corresponding to the plurality of adsorption pieces 342 one by one.

The length direction of the battery string to be cached on the discharging conveyor line 2 is parallel to the rotating shaft 341, and when the overturning motor 33 drives the plurality of adsorbing members 342 to overturn towards the discharging conveyor line 2 through the rotating shaft 341, the plurality of adsorbing members 342 absorb the battery string from the discharging conveyor line 2. Next, the turnover motor 33 drives the plurality of adsorption members 342 to turn over toward the buffer mechanism 4 through the rotating shaft 341, and in the descending process after the turnover, the plurality of adsorption members 342 pass through the corresponding avoiding grooves 421 and place the batteries adsorbed thereon in series on the supporting plate 42 of the buffer mechanism 4.

In some implementations, as shown in fig. 5 and 6, the battery string supplying part further includes an EL detecting mechanism 5, the EL detecting mechanism 5 is disposed on the discharging conveyor line 2 and is used for detecting the battery strings output from the discharging conveyor line 2, and the turnover mechanism 3 is used for picking up qualified battery strings from the discharging conveyor line 2 through the EL detecting mechanism. Only the qualified battery strings after detection enter the subsequent typesetting and welding process, and finally the qualification rate of the photovoltaic module is ensured; simultaneously, EL detection mechanism 5 directly sets up on ejection of compact transfer chain 2, can directly carry out the EL to the battery cluster on the ejection of compact transfer chain 2 and detect to need not to grab away the battery cluster from ejection of compact transfer chain 2 and detect, avoided grabbing of battery cluster and put, be favorable to reducing the piece rate of battery piece.

In some implementations, the EL detection mechanism 5 includes a first conduction mechanism 51, a second conduction mechanism 52 disposed on the outgoing transport line in the transport direction of the outgoing transport line, and an EL camera disposed above or below the outgoing transport line 2. The battery string produced by the stringer 1 is output through the discharging conveying line 2, and when the battery string reaches a preset detection station under the conveying of the discharging conveying line 2, the discharging conveying line 2 stops conveying. The first conduction mechanism 51 and the second conduction mechanism 52 press the first end welding strip and the second end welding strip of the battery string, respectively, to conduct the battery string. The battery string heats up after being turned on, and the temperature rises. The EL camera acquires an infrared image of the conducted battery string, and performs image analysis on the infrared image to determine whether defective battery pieces such as breakage and insufficient soldering exist in the battery string.

In some implementations, the first conducting mechanism 51 includes a first electrode piece 511 connected to the positive electrode of the power supply and a first electrode piece driving part 512, wherein the first electrode piece driving part 512 is installed at a side of the discharge conveying line 2, and the first electrode piece 511 is connected to a driving end of the first electrode piece driving part 512. The second conduction mechanism 52 includes a second electrode plate 521 connected to the negative electrode of the power supply, and a second electrode plate driving portion 522, wherein the second electrode plate driving portion 522 is installed at the side of the discharge conveyor line 2, and the second electrode plate 521 is connected to the driving end of the second electrode plate driving portion 522.

When the battery string is conveyed to the detection station, the first electrode sheet driving part 512 drives the first electrode sheet 511 to move horizontally and lift, so that the first electrode sheet 511 is pressed on the first end welding strip of the battery string. The second electrode sheet driving part 522 drives the second electrode sheet 521 to move horizontally and lift up and down so as to press-connect the second electrode sheet 521 to the second end welding strip of the battery string.

In an embodiment, first electrode piece drive division 512 is the same with second electrode piece drive division 522's structure, and first electrode piece drive division 512 includes that two translations drive actuating cylinder and two lift and drive actuating cylinder, and wherein, two translations drive actuating cylinder and install respectively in ejection of compact transfer chain 2's both sides, and two lifts drive actuating cylinder and install respectively on two translations drive actuating cylinder's drive end, and the both ends of first electrode piece 511 are connected with two lift drive actuating cylinder's drive end respectively to realize the translation drive and the lift drive to first electrode piece 511.

In some implementations, the stitch weld further includes a bus bar preparation portion, a bus bar handling portion, a bus bar carrying portion, and a weld portion; the bus bar preparing part is configured to prepare a bus bar; the bus bar carrying part is configured to carry the bus bar to the bus bar bearing part; the bus bar bearing part is configured to move the bus bar to a corresponding position of the left long welding strip; the welding part is used for welding the bus bar carried by the bus bar carrying part to the stay welding strip.

The bus bar preparation part is used for preparing the bus bar, the bus bar conveying part is used for conveying the bus bar from the preparation part to the bus bar bearing part, the bus bar bearing part is used for bearing, moving and welding and supporting the bus bar, and the welding part is used for welding the bus bar to the welding strip. Wherein, the bus bar preparation portion, the bus bar carrying portion, the bus bar bearing portion and the number of the welding portions can be comprehensively considered according to the welding efficiency and the equipment cost. By arranging the bus bar preparation part, the bus bar conveying part, the bus bar bearing part and the welding part, when the bus bar bearing part and the welding part are matched with the bus bar to be welded, the bus bar preparation part and the bus bar conveying part can synchronously prepare and convey the bus bar, and the beat of bus bar stitch welding is improved.

In some implementations, as shown in fig. 8, bus bar welding for the half-sheet assemblies is suitable. The bus bar preparation section includes a header bus bar preparation section 111 and intermediate and tail bus bar preparation sections 112; the bus bar conveying part comprises a first conveying part and a second conveying branch part; the bus bar carrying section includes a header bus bar carrying section 113, a tail bus bar carrying section 114, an intermediate bus bar carrying section 115; the welds include a header weld 116, a middle weld 117, and a tail weld 118. The header bus bar preparation section 111 is used for preparing header bus bars, the first carrying section is used for carrying the header bus bars prepared by the header bus bar preparation section 111 onto the header bus bar carrying section 113, the header bus bar carrying section 113 is used for moving the header bus bars under the stay solder tape at the head of the component unit, and the header soldering section 116 is used for soldering the header bus bars onto the stay solder tape at the head of the component unit. The middle and tail bus bar preparation subsection 112 is used for preparing middle bus bars and tail bus bars, the second carrying mechanism is used for carrying the middle bus bars and the tail bus bars prepared by the middle and tail bus bar preparation subsection 112 to the middle bus bar carrying subsection 115 and the tail bus bar carrying subsection 114, the middle bus bar carrying subsection 115 moves the middle bus bars to the position below a long solder strip left in the middle of the assembly unit, the middle welding subsection 117 is used for welding the middle bus bars to the long solder strip left in the middle of the assembly unit, the tail bus bar carrying subsection 114 moves the tail bus bars to the position below the long solder strip left in the tail of the assembly unit, and the tail welding subsection 118 is used for welding the tail bus bars to the long solder strip left in the tail of the assembly unit.

In one implementation, the header busbar preparation section 111 and the intermediate and tail busbar preparation sections 112 each comprise a roll-carrying device for carrying a roll of busbar, a cutter for cutting the busbar, a drawing collet for drawing the busbar and a support table for carrying the busbar; the bus bar coil is placed on the coil bearing device, the bus bars on the coil are pulled out of the coil and pass through the middle of the cutter, the traction chuck is used for drawing the bus bars, the cutter is used for cutting the bus bars drawn to a preset position by the traction chuck, and then the traction chuck draws the bus bars to be placed on a bearing platform for bearing the bus bars.

The first carrying subsection and the second carrying subsection both comprise bus-bar suckers and carrying driving devices, and the carrying driving devices drive the bus-bar suckers to suck the bus-bars on the bus-bar bearing platforms and then carry the bus-bars to the corresponding bus-bar bearing parts. The carrying driving device can be a motor module which consists of a lifting motor and a translation motor and can drive the bus-bar sucker to move up and down and move transversely, or can be a cylinder module which consists of a lifting cylinder and a translation cylinder and can drive the bus-bar to move up and down and move transversely.

In some implementations, as shown in fig. 1-3, the typesetting stitch welding machine of the present invention further includes a glass sheet conveying line 12. The glass plate conveying line 12 is arranged below the regular conveying part and the stitch welding part 11 and has the same conveying direction with the regular conveying part, and the glass plate conveying line is used for conveying glass plates to a blanking station located at the rear of the welding station. The stitch welding pick-up portion 10 discharges the battery string picked up by each string picking assembly 1001 onto the glass plate 13 of the discharging station after the battery string picked up by each string picking assembly 1001 is subjected to bus bar welding.

The invention has been described above with a certain degree of particularity and detail. It will be understood by those of ordinary skill in the art that the description of the embodiments is merely exemplary and that all changes that may be made without departing from the true spirit and scope of the present invention are intended to be within the scope of the present invention. The scope of the invention is defined by the appended claims rather than by the foregoing description of the embodiments.

Claims (15)

1. The utility model provides a type setting stitch welding machine which characterized in that, the type setting stitch welding machine is arranged in carrying out the type setting and the busbar welding to the battery cluster according to battery cluster array in the photovoltaic module, the type setting stitch welding machine includes type setting pick up portion, regular conveying portion, stitch welding pick up portion and stitch welding portion, wherein:

the typesetting and picking part is arranged in front of the regular conveying part and is used for picking up the battery strings and placing the battery strings on the regular conveying part according to the requirements of typesetting positive and negative electrodes;

the regulating and conveying part is used for receiving and regulating the battery strings placed by the typesetting and picking part;

the stitch welding pick-up part comprises string pick-up components which are arranged in a one-to-one correspondence manner with the battery strings in the battery string array; the stacking and welding picking part moves to drive a string picking assembly corresponding to the battery string at the string picking station to move to the string picking station to pick up the battery string;

the stitch welding pick-up part moves to drive the string pick-up assembly with the battery string picked up to a welding station, and the stitch welding part welds the bus bar to a long welding strip at the end part of the battery string positioned at the welding station;

the stitch welding pick-up part is also used for moving to lay the battery strings picked up by the string picking-up components on the glass plate after the battery strings picked up by the string picking-up components are welded by the bus bars.

2. The type setting stitch welding machine according to claim 1, wherein the type setting pick-up section places at least one module unit onto the structured conveying section at predetermined time intervals, each module unit comprises two battery strings arranged side by side along the length direction of the battery strings, and a plurality of module units are arranged side by side along the width direction of the battery strings to form the battery string array;

the regulating conveying part conveys the regulated assembly units to the string picking station at preset time intervals;

the stitch welding picking part moves towards the rear direction for a preset distance at preset time intervals so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to pick up the assembly unit, and simultaneously drive the string picking assembly picked with the assembly unit to the welding station.

3. The type setting stitch welding machine as defined in claim 2, wherein the type setting pick-up portion comprises a moving mechanism, a rotating mechanism and a pick-up assembly, wherein:

the rotating mechanism is connected to the driving end of the moving mechanism, and the picking assembly is installed on the rotating mechanism;

the moving mechanism is used for driving the picking assembly to translate and lift so as to pick up the battery string;

the rotating mechanism is used for driving the picking assembly to rotate so as to rotate the battery string to meet the requirements of the typesetting anode and cathode;

the moving mechanism is also used for driving the picking assembly to translate and lift so as to place the picked battery strings on the regular conveying part.

4. The type setting stitch welding machine according to claim 3, wherein the type setting pickup portions are provided in two, which are a first type setting pickup portion and a second type setting pickup portion, respectively, wherein:

the first layout picking part is used for placing one of the battery strings in the assembly units on the structured conveying part;

the second typesetting and picking part is used for placing another battery string in the assembly unit on the structured conveying part.

5. The typesetting stitch welding machine as defined in claim 2, wherein the structured conveying section comprises a first structured conveying mechanism and a second structured conveying mechanism with the same structure, and the first structured conveying mechanism and the second structured conveying mechanism are arranged side by side along a first horizontal direction; the first structured conveying mechanism and the second structured conveying mechanism are respectively used for bearing the two battery strings in the assembly unit;

the first structured transport mechanism includes a first translational drive mechanism and at least one structured platform connected to a moving end of the first translational drive mechanism, wherein:

the regulating platform is used for bearing a battery string and regulating the battery string;

the first translation driving mechanism is used for driving the gauge leveling platform to translate along a second horizontal direction perpendicular to the first horizontal direction so as to convey the battery strings loaded on the gauge leveling platform to the string picking station.

6. The typesetting stitch welding machine as defined in claim 5, wherein the structured platform comprises a second translation driving mechanism, a lifting driving mechanism, a rotation driving mechanism and a structured bearing plate, wherein:

the second translation driving mechanism is connected to the moving end of the first translation driving mechanism, the lifting driving mechanism is connected to the moving end of the second translation driving mechanism, the rotary driving mechanism is connected to the moving end of the lifting driving mechanism, and the structured bearing plate is connected to the moving end of the rotary driving mechanism;

the structured bearing plate is used for bearing the battery strings, the second translation driving mechanism is used for driving the structured bearing plate to translate along the first horizontal direction, the lifting driving mechanism is used for driving the structured bearing plate to lift, and the rotation driving mechanism is used for driving the structured bearing plate to rotate in the horizontal plane.

7. The composition stitch welding machine as defined in claim 2, wherein: stitch welding pick-up portion still includes step drive mechanism and first installing support, wherein:

the first mounting bracket is connected to the moving end of the stepping driving mechanism, and the string picking assemblies are mounted on the first mounting bracket together;

the stepping driving mechanism is used for driving each string picking assembly to translate in a stepping mode so as to drive the string picking assembly corresponding to the assembly unit at the string picking station to pick up the assembly unit, and meanwhile, the string picking assembly with the picked assembly unit is driven to the welding station.

8. The composition stitch welding machine as defined in claim 1 or 2, wherein: the layout stitch welding machine further comprises a battery string supply part for producing battery strings and supplying the produced battery strings to the layout pickup part.

9. The type setting stitch welding machine as defined in claim 8, wherein the battery string supply portion comprises a string welding machine, an output conveyor line, a turnover mechanism, and a buffer mechanism, wherein:

the stringer is used for producing a battery string;

the discharging conveying line is used for outputting the battery strings produced by the series welding machine;

the buffer mechanism is arranged at the side of the discharging conveying line, and the turnover mechanism is used for picking up the battery strings from the discharging conveying line, turning the picked battery strings for 180 degrees and then placing the battery strings on the buffer mechanism;

the typesetting and picking part picks up the battery strings from the cache mechanism.

10. The type setting and stitch welding machine as defined in claim 9, wherein the battery string supplying section further comprises an EL detecting mechanism disposed on the discharging conveyor line for detecting the battery strings output from the discharging conveyor line, and the turnover mechanism is configured to pick up the battery strings from the discharging conveyor line that are qualified by the EL detecting mechanism.

11. The type setting stitch welding machine as defined in claim 10, wherein the EL detection mechanism comprises a first conducting mechanism and a second conducting mechanism arranged on the outfeed conveyor line along the conveying direction of the outfeed conveyor line, and an EL camera arranged above or below the outfeed conveyor line;

the first conduction mechanism and the second conduction mechanism are used for conducting the battery strings on the discharging conveying line from two ends;

the EL camera is used for acquiring an infrared image of the battery string which is conducted so as to detect the battery string.

12. The type setting stitch welding machine as defined in claim 9, wherein the turning mechanism comprises a first lifting driving module, a second lifting driving module, a turning motor and a turning adsorption component, wherein:

the overturning motor is connected to the driving end of the second lifting driving module;

the first end of the overturning adsorption assembly is connected to the driving end of the first lifting driving module, and the second end of the overturning adsorption assembly is connected to the driving end of the overturning motor;

first lift drive module and the cooperation drive of second lift drive module upset adsorption component goes up and down, the upset motor is used for the drive upset adsorption component is in ejection of compact transfer chain with overturn between the buffer memory mechanism, in order to drive upset adsorption component follows absorb the battery cluster on the ejection of compact transfer chain, and overturn the battery cluster of absorption extremely on the buffer memory mechanism.

13. The type setting stitch welding machine of claim 9, wherein the buffer mechanism comprises a second mounting bracket, a plurality of pallets, a first pallet pushing mechanism, and a second pallet pushing mechanism, wherein:

a plurality of supporting plates are vertically stacked on the second mounting bracket, and each supporting plate is connected to the second mounting bracket through a sliding rail;

the first supporting plate pushing mechanism is configured to push one supporting plate out of the second mounting bracket to the first side at a time so as to receive the battery string transferred by the turnover mechanism;

the second supporting plate pushing mechanism is configured to push one supporting plate bearing a battery string out of the second mounting bracket to the second side at a time so as to provide the battery string to the typesetting and picking part.

14. The type setting stitch welding machine according to claim 1 or 2, wherein the stitch welding portion includes a bus bar preparation portion, a bus bar carrying portion, and a welding portion;

the bus bar preparing part is configured to prepare a bus bar;

the bus bar carrying portion is configured to carry the bus bar to the bus bar bearing portion;

the bus bar bearing part is configured to move the bus bar to the corresponding position of the left long solder strip;

the welding part is used for welding the bus bar carried by the bus bar carrying part to the long welding strip.

15. The composition stitch welding machine as defined in claim 1 or 2, further comprising a glass plate conveying line;

the glass plate conveying line is arranged below the regular conveying part and the overlap welding part and has the same conveying direction with the regular conveying part, and the glass plate conveying line is used for conveying glass plates to a blanking station located at the rear of the welding station;

and the stitch welding pick-up part is used for blanking the battery strings picked up by the string pickup assemblies onto the glass plate of the blanking station after the battery strings picked up by the string pickup assemblies are welded by the bus bars.

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