KR102321182B1 - Flux supply device for solar panel tabbing machine - Google Patents

Abstract

The present invention relates to a flux supply device for a solar panel tabbing machine. More specifically, in a tabbing machine for manufacturing solar panels, when a conductive ribbon interconnecting each unit cell is fixed to each unit cell, a flux used as a fusion medium is provided at a fixed position and in a fixed amount. In particular, when the length of the conductive ribbon is a length of connecting an adjacent pair of unit cells, a flux in the form of a point is precisely provided to a portion where the conductive ribbon is in contact with the unit cells. To this end, the present invention is to apply a flux to a position where a conductive ribbon for connecting adjacent unit cells in a unit cell constituting a solar panel is thermally fused. It includes: posts arranged vertically to support a load transmitted from above; a horizontal moving means disposed on the upper surface of the post and operated by the applied power and signal; a vertical body moving in a horizontal direction by the horizontal moving means; vertical movement means disposed on the vertical body and operated by the applied power and signal; a support arm coupled to the vertical moving means; and a plurality of flux application modules arranged to be spaced apart from each other in the support arm.

Description

Flux supply device for solar panel tabbing machine

The present invention relates to an apparatus for providing a flux for a solar panel tabbing machine, and more particularly, a fusion medium for fixing a conductive ribbon interconnecting each unit cell to each unit cell in a tabbing machine for manufacturing a solar panel. It is intended to provide the flux used as a device in a certain position and in a certain amount. In particular, when the length of the conductive ribbon is composed of a length connecting an adjacent pair of unit cells, the flux is applied in the form of a point to the area where the conductive ribbon and the unit cells are in contact. to provide precision.

As is known, solar light is a representative of eco-friendly energy, and in particular, it is a technology attracting attention because it does not generate pollution during energy production.

For such photovoltaic power generation, a semiconductor device that converts solar energy into electrical energy is required, and it is called a solar cell. In this way, a unit solar cell, that is, a unit cell connected and modularized is called a solar panel.

The solar panel manufacturing process can be divided into a cell test process, a tabbing process, a lay-up process, a lamination process, and a module test process.

Here, the tabbing process for connecting a plurality of unit cells is the most essential process among the solar panel manufacturing processes. If the conductive ribbon is not properly bonded to the cells, the overall performance and quality of the solar panel deteriorate.

Looking at the tabbing process schematically, after cutting a plurality of conductive ribbons supplied from a reel, one side of the cell is seated so that it spans, and the cell is again seated and stacked on the other side, and exposed to a high-temperature atmosphere while repeating. In a high-temperature atmosphere, the conductive ribbon is soldered to the cell, and the plurality of cells are electrically connected by the conductive ribbon.

That is, in the solar panel generated through the conventional tabbing process, the conductive ribbon is disposed across the entire unit cell and then bonded to the conductive ribbon disposed across the other adjacent unit cell.

Here, since the conductive ribbon disposed across each unit cell has to be fixed to the surface in contact with the unit cell, flux, which is a fusion medium, had to be applied to the entire conductive ribbon disposed in the unit cell.

In order to integrally fuse the flux applied to the entire conductive ribbon to the unit cell, it must be continuously exposed to a high-temperature atmosphere. There were problems such as an increase in the amount of flux applied to the unit cell and an increase in the amount of flux applied to fix the entire conductive ribbon to the unit cell, as well as adhesion of the applied flux to the surface of the unit cell.

Republic of Korea Patent Publication No. 10-2017-26684 (2017.03.09., published)

The present invention has been proposed to solve the above problems, and the length of the conductive ribbon is configured to have a length connecting a pair of adjacent unit cells, thereby reducing the time required for fusion and curing of the conductive ribbon and the unit cells. An object of the present invention is to provide a flux providing device for a solar panel tabbing machine that can accurately apply the flux, which is a medium for fusion, in the form of a point at the point where the conductive ribbon and the unit cell contact each other.

In addition, the present invention can accurately discharge a certain amount of the flux, which is a medium for fusion, and prevent the flux from being exposed to the outside air while not in use, thereby preventing foreign substances and moisture contained in the outside air from being mixed with the flux, thereby maintaining the performance of the flux. An object of the present invention is to provide a flux providing device for a solar panel tabbing machine.

In order to achieve the above object, the present invention is to discharge a flux to a position where a conductive ribbon for connecting adjacent unit cells in a unit cell constituting a solar panel is thermally fused,

Posts arranged vertically to support the load transmitted from above;

a horizontal moving means disposed on the upper surface of the post and operated by the applied power and signal;

a vertical body moving in a horizontal direction by the horizontal moving means;

Vertical movement means disposed on the vertical body and operated by the applied power and signal;

a support arm moving in the vertical direction by the vertical movement means;

and a plurality of flux application modules arranged to be spaced apart from each other in the support arm.

In addition, the flux application module includes: a storage tank in which the flux is stored; a discharge tip for discharging a predetermined amount of the flux stored in the storage tank to the outside; It is characterized in that it includes a coupling clamp detachably coupled to the support arm.

In addition, the discharge tip is made of a soft material having its own elastic restoring force, and an outlet through which the flux is discharged is formed at the end in the longitudinal direction, and the outlet is opened when pressure is supplied from the pressure control means to point the flux. ), and is closed in the atmosphere to prevent the inflow of outside air.

In addition, the pressure control means, characterized in that it comprises a suction port provided at the upper end of the storage tank, a compression tank for sucking the internal air of the storage tank, and a connection tube connecting the suction port and the compression tank.

According to the present invention made as described above, when the length of the conductive ribbon is relatively short compared to the prior art and the contact area with the unit cell in contact is narrow, the location and amount of flux provided for fusing the conductive ribbon and the unit cell are precisely determined. By shortening the time required for fusion and hardening because it can control the

In addition, the present invention improves the structure of the discharge tip for discharging the flux to discharge only a certain amount of flux to the outside and prevents outside air from entering the storage tank where the flux is stored, so that foreign substances and moisture contained in the outside air are mixed with the flux. It is possible to prevent it from happening, so it has the effect of maintaining the performance of the flux.

1 is an exemplary view showing an apparatus for providing a flux for a solar panel tabbing machine according to the present invention.
Figure 2 is an exemplary view showing the flux providing device for a solar panel tabbing machine according to the present invention from another angle.
Figure 3 is a schematic diagram schematically showing the operating state of the flux providing device for solar panel tabbing machine according to the present invention.
4 is an exemplary view illustrating a solar panel tabbing machine in which a flux providing device for a solar panel tabbing machine according to the present invention is disposed.

Hereinafter, in addition to the above objects, other objects and features of the present invention will become apparent through the description of the embodiments with reference to the accompanying drawings.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, a preferred embodiment of the flux providing apparatus for a solar panel tabbing machine according to the present invention will be described with reference to the accompanying drawings.

First, as shown in FIGS. 1 and 2, the flux providing device 1 for a solar panel tabbing machine according to the present invention includes a post 10 arranged vertically to support a load transmitted from above, and the post ( 10) a horizontal moving means 20 disposed on the upper surface and operated by the applied power and signal, a vertical body 30 moving in the horizontal direction by the horizontal moving means 20, and the vertical body 30 ) and the vertical movement means 40 operated by the applied power and signals, the support arm 50 coupled to the vertical movement means 40 and the support arm 50 are arranged to be spaced apart from each other and a flux application module (60).

The post 10 supports the above other components from below and supports the other components to be disposed above the ground or the floor.

These posts 10 are formed to extend in the vertical direction, and plates 11 made of flat plate materials are disposed at the top and bottom, respectively.

The plate 11 is made in the form of a flat square plate to form a stable support force on the ground or bottom surface in contact with the lower end, and a horizontal moving means 20 to be described later is disposed on the upper end thereof.

The horizontal moving means 20 is disposed on the plate 11 provided on the upper surface of the post 10, and moves the vertical body 30 in the horizontal direction while operating by the applied power and signal.

Here, moving the vertical body 30 in the horizontal direction is for setting the flux discharge position of the flux application module 60, which will be described later, and does not move in real time during the process of discharging the flux from the flux application module to the outside.

The horizontal moving means 20 includes a horizontal driving unit 21 operated by applied power and a signal, a pair of horizontal rails 22 extending in the horizontal direction and arranged side by side at positions spaced apart from each other, and the horizontal rail It includes a horizontal movement block 23 movably disposed on the 22 , and a position detection sensor 24 for detecting the position of the horizontal movement block 23 .

The horizontal driving unit 21 may be configured by any one of a motor or a cylinder operated by applied power and a signal.

A pair of the horizontal rails 22 are arranged side by side at positions spaced apart from each other to guide the movement direction of the horizontal movement block 23 .

It is movably disposed on the horizontal rail 22 of the horizontal movement block 23, and receives power from the horizontal driving unit 21 through a power transmission body to move in the horizontal direction. At this time, the power transmission body may be composed of a rotating shaft having a spiral for movement formed on the outer circumferential surface.

The position detection sensor 24 is for detecting the position of the horizontal movement block 23, and a plurality of them are disposed at positions spaced apart from each other, and the sensed value is a control unit for controlling the operation of the horizontal driving unit 21 (not shown in the drawing).

The horizontal movement means 20 made as described above moves the horizontal movement block 23 at a specified speed and position in the horizontal direction. At this time, the current position of the horizontal movement block 23 is sensed in real time through the position detection sensor 24 . In this way, the precise position value can be confirmed.

The vertical body 30 is disposed on the horizontal movement block 23 to move in conjunction with the horizontal movement block 23, and a vertical movement means 40 to be described later is disposed.

The vertical body 30 is formed in the form of a plate extending in the vertical direction and is vertically disposed on the upper surface of the horizontal moving block 23 .

The shape and length of the vertical body 30, as well as the number of arrangements, can be variously changed by the load of the vertical movement means 40 and the flux application module 60 coupled thereto, which will be described later, so that the shapes shown in the drawings Of course, it is not limited.

The vertical movement means 40 is disposed on the vertical body 30 and ascends or descends while operating by the applied power and signal. It includes a driving unit 41, a pair of upper and lower rails 42 arranged side by side at positions spaced apart from each other, and a vertical movement block 43 arranged to be movable up and down on the upper and lower rails 42 .

The vertical drive unit 41, the vertical rail 42, and the vertical movement block 43 include the horizontal drive unit 21, the horizontal rail 22, and the horizontal movement block 23 constituting the horizontal movement means 20 described above. Since the configuration is the same, overlapping descriptions will be omitted.

On the other hand, the horizontal moving means 20, the vertical body 30, and the vertical moving means 40 made as described above have the discharge tip 62 of the flux application module 60, which will be described later, disposed at the flux application position of the unit cell. When the flux application module 60 is fixed in position by the horizontal movement means 20 and the vertical movement means 40, through the pressure adjusting means 63 provided in the flux application module 60 The flux is discharged to the outside.

The support arm 50 is coupled to the vertical movement block 43 and is formed of a flat plate material so that one side is coupled to the vertical movement block 43 and the other end is exposed to the outside of the vertical movement block 43 . do.

The support arm 50 is preferably made of a material having high rigidity so as to support the load of the flux application module 60, but is not limited thereto.

In addition, the length at which the support arm 50 is exposed to the outside of the vertical movement block 43 can be changed according to the arrangement number of the flux application module 60 and the distance between them, and is not limited to the ratio shown in the drawing. is of course

A plurality of the flux application module 60 is disposed at positions spaced apart from each other on the support arm 50, and is for applying a flux, which is a fusion medium, to a position for fusing the conductive ribbon to the unit cell.

As described above in the present invention, since the length of the conductive ribbon is cut to a length connecting a pair of adjacent unit cells, the conductive ribbon has a relatively short length compared to the related art.

Therefore, in the flux application module 60 of the present invention, when a short conductive ribbon is fused to a unit cell, the flux is precisely applied to the fusion site, and the amount of the applied flux must also be precisely applied in the form of a point.

That is, the flux supply means provided in the conventional tabbing machine has a structure in which a conductive ribbon is disposed across the entire unit cell and the flux is sprayed in the form of a spray to fuse the entire disposed conductive ribbon to the unit cell, whereas

In the flux application module 60 of the present invention, since the length of the conductive ribbon is short and the fusion site is designated, the application position and the application amount must be precisely controlled.

For this purpose, the flux application module (60) of the present invention includes a storage tank (61) in which flux is stored, a discharge tip (62) for discharging a predetermined amount of the flux stored in the storage tank (61) to the outside, and the storage tank (61). ) includes a pressure control means 63 for adjusting the internal pressure, and a coupling clamp 64 for detachably coupling the storage tank 61 to the support arm 50 .

The storage tank 61 is formed in the form of an empty enclosure so that flux for fusion is stored therein. Since the shape and size of the storage tank 61 can be variously changed according to the amount of flux to be stored, it is shown in the drawing. Of course, it is not limited to the shape and size made.

However, the reason that the storage tank 61 has an empty cylindrical shape is relatively high in efficiency compared to the polygonal shape when the pressure inside the storage tank 61 is removed so that the lower movement of the stored flux is smoothly performed. It is preferably made in a cylindrical shape.

On the other hand, the storage tank 61 may be formed in a shape gradually inclined toward the bottom so that the lower end to which the discharge tip 62 is coupled to guide the movement of the flux to the discharge tip 62 .

The discharge tip 62 is disposed at the lower end of the storage tank 61 to discharge a predetermined amount of the flux stored in the storage tank 61 to the outside. It is desirable to discharge the air and to prevent the outside air from flowing through the exhaust tip by closing the air and during movement.

To this end, the discharge tip 62 is made of a soft material having its own elastic restoring force, and an outlet 621 through which flux is discharged is formed at the longitudinal end, and the outlet 621 waits in the closed state. The outlet 621 is opened by a moving force that moves the flux by the pressure supplied from the pressure adjusting means 63 to discharge the flux to the outside.

The discharge tip 62 made as described above discharges the flux to the outside while the discharge port 621 is opened when pressure is supplied by the pressure control means 63, and the discharge port 621 is closed in the atmosphere to prevent the inflow of outside air. At the same time, it is possible to prevent the erroneous discharge of flux.

The pressure regulating means 63 is for adjusting the internal pressure of the storage tank 61 , and the suction port 631 provided at the upper end of the storage tank 61 and the internal air of the storage tank 61 are sucked in. and a compression tank 632 and a connection tube 633 connecting the suction port 631 and the compression tank 632 .

The pressure regulating means 63 is for discharging the stored flux through the outlet 621 by providing a compressive force to the storage tank.

The suction port 631 is disposed on the upper end of the storage tank 61 and communicates with the inside of the storage tank, and the compression tank 632 operates by the applied power and signal, and is spaced apart from the storage tank 61. It is disposed to prevent vibration generated during operation from being transmitted to the flux application module 60 . And the connecting tube 633 is a tube for transport with an empty inside.

This pressure control means 63 provides compressed air through the connection tube 633 while the compression tank 632 operates, and into the storage tank 61 through the suction port 631 to which the connection tube 633 is coupled. Provide compressed air to expel the flux.

The coupling clamp 64 is to detachably couple the storage tank 61 to the support arm 50 and prevent positional displacement during ascent and descent. and the storage tank 61 is coupled to each coupling clamp 64 .

The flux application module 60 configured as described above can provide the flux at an accurate position and in a certain amount in the form of a point compared to the conventional flux providing device, so after being cut to a length connecting between a pair of adjacent unit cells. The time required for fusion and curing of the fused conductive ribbon can be shortened, manufacturing costs can be reduced because there is no unnecessary flux wastage, and errors caused by the curing of the flux on the surface or the back surface of the unit cell are prevented in advance. it can be done

As described above, the present invention has been described with specific matters such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

1: Flux providing device for solar panel tabbing machine
10 : Post
11: plate
20: horizontal movement means
21: horizontal driving unit 22: horizontal rail
23: horizontal movement block 24: position detection sensor
30: vertical body
40: Shanghai East Sudan
41: vertical drive unit 42: vertical rail
43: vertical movement block 44: return member
441: fixed block 442: variable block
443: elastic body
50: support arm
60: flux application module
61: storage tank 62: discharge tip
63: pressure control means 64: coupling clamp
621: outlet

Claims (4)

By discharging the flux to the position where the conductive ribbon for connecting adjacent unit cells in the unit cells constituting the solar panel is thermally fused,
Post (10) disposed vertically to support the load transmitted from above;
a horizontal moving means 20 disposed on the upper surface of the post 10 and operated by the applied power and signal;
a vertical body 30 moving in the horizontal direction by the horizontal moving means 20;
Vertical movement means 40 disposed on the vertical body 30 and operated by the applied power and signal;
a support arm 50 coupled to the vertical movement means 40;
A plurality of flux application modules (60) arranged to be spaced apart from each other in the support arm (50); including,
The flux application module 60,
A storage tank 61 in which the flux is stored, and
a discharge tip 62 for discharging a predetermined amount of the flux stored in the storage tank 61 to the outside;
Pressure regulating means (63) for regulating the internal pressure of the storage tank (61);
and a coupling clamp 64 for detachably coupling the storage tank 61 to the support arm 50,
The discharge tip 62 is,
It is made of a soft material having its own elastic restoring force, and an outlet 621 through which the flux is discharged is formed at the end in the longitudinal direction,
The outlet 621 is opened when pressure is supplied from the pressure regulating means 63 to discharge the flux in the form of a point, and is closed in the atmosphere to prevent the inflow of outside air. Flux providing device for ice age. delete delete The method according to claim 1, The pressure regulating means (63),
A suction port 631 provided at the upper end of the storage tank 61,
a compression tank 632 for providing compressed air to the storage tank 61;
and a connection tube (633) connecting the suction port (631) and the compression tank (632).

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