KR20100125987A - Heating device for attaching ribon onto solar cell - Google Patents

Abstract

PURPOSE: A heating device for attaching ribbon to a solar cell is provided to minimize the thermal stress to the solar cell caused by the cooling by implementing the annealing process of heating with the temperature more than certain temperature on the top and the bottom of the solar cell. CONSTITUTION: A pre-heating unit(20) preheats a solar cell(1) and a ribbon(2) with the constant temperature range. A main heating unit(30) solders the solder paste interposed between the solar cell and the ribbon. An annealing unit(40) heats the solar cell and the ribbon with the constant temperature range. A halogen heater(31) heats the top of the ribbon and the solar cell.

Description

Heating device for attaching ribbon of solar cell {Heating Device for Attaching Ribon onto Solar Cell}

The present invention relates to a heating apparatus for attaching a conductive ribbon to a solar cell, and more particularly, to a tabbing process of attaching a conductive ribbon interconnecting a plurality of solar cells to a surface of the solar cell. In performing the process, the present invention relates to a heating apparatus and method for attaching a ribbon of a solar cell that can minimize the thermal shock applied to the solar cell when soldering by heating the soldering portion of the solar cell and the ribbon.

Solar cells convert solar energy into electrical energy, and semiconductor materials such as silicon, gallium arsenide, cadmium tellurium, cadmium sulfide, indium phosphide, or a combination thereof are used. Usually, mainly silicon is used.

The solar cell is manufactured by a pn junction of a semiconductor material by a diffusion method, using a photovoltaic effect that a small amount of current flows when receiving the light, most of the conventional solar cell is a large area pn junction It consists of a diode, and when the electromotive force generated at the anode end of the pn junction diode is connected to an external circuit, it acts as a unit solar cell.

Since the solar cell formed as described above has a small electromotive force, a plurality of unit solar cells are connected to form a photovoltaic module having an appropriate electromotive force. In this case, each unit solar cell is made of lead. It is connected by a conductor ribbon of constant length coated.

The soldering and fixing of the conductor ribbon to the solar cell is one of the most complicated and sensitive processes in various manufacturing steps of the solar cell module. The soldering is performed after contacting the conductor ribbon to the surface electrode of the solar cell before soldering. You lose.

That is, as shown in FIG. 1, each of the solar cells 1 has a structure in which a positive electrode collecting electrode 1 a is formed on an upper surface thereof and a negative electrode collecting electrode 1 b is formed on a lower surface thereof. It is connected to each other by conductive ribbons 2 attached to the collecting electrode 1a on the upper surface of the upper surface and the collecting electrode 1b on the lower surface of the adjacent solar cell 1 to form a solar cell module. .

The ribbon 2 is soldered and attached to the solar cell 1 in a tabbing process during the manufacturing process of the solar cell module. In the tabbing process, the ribbon 2 is cut into a predetermined length to form a flat band shape. Two solar cells coated with solder paste on each of the top electrode 1a and the bottom electrode 1b of the solar cell 1, and then applying the solder paste to the ribbon 2. The upper and lower surfaces of the cell 1 are brought into contact with each other, and in this state, the contact portion is heated in a reflow manner to solder and fix the ribbon to each unit solar cell.

However, as described above, since soldering is performed by heating the contact portion of the solar cell and the ribbon to a high temperature in the tabbing process, there is a problem such that internal cracks are generated due to thermal shock during the cooling of the solar cell.

The present invention is to solve the above problems, an object of the present invention in performing a tabbing process for bonding the ribbon to the solar cell, minimizing the thermal shock applied to the solar cell to prevent damage to the solar cell The present invention provides a heating device for attaching a ribbon to a solar cell.

The present invention for achieving the above object, the transfer unit which is transported by placing the ribbon in contact with the electrode of the solar cell via the solder paste; A pre-heating unit for preheating by applying heat of a first temperature range to the solar cell and the ribbon conveyed by the conveying unit; A main heating unit for soldering and fixing the solar cell and the ribbon by applying heat of a second temperature range higher than the first temperature range to the solar cell and the ribbon transferred through the preheating unit; Heating apparatus for attaching a ribbon of a solar cell including an annealing heating unit for cooling by applying heat of a third temperature range lower than the second temperature range to the solar cell and the ribbon transferred through the main heating unit. to provide.

According to the present invention, after performing the soldering by applying a high temperature heat to the junction portion of the solar cell and the ribbon, the annealing process of applying a heat of a predetermined temperature or more to the upper and lower parts of the solar cell is cooled Due to this can minimize the thermal stress applied to the solar cell, there is an effect that can prevent damage to the solar cell.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the heating device for ribbon attachment of the solar cell according to the present invention.

Figure 2a to Figure 4 shows an embodiment of the heating device for ribbon attachment of the solar cell according to the present invention, referring to Figure 2a, the heating device for ribbon attachment of the solar cell of the present invention is a solar cell prior to full soldering The pre-heating unit 20 for preheating the cell 1 and the ribbon 2 to a predetermined temperature range, and the solar cell 1 and the ribbon 2 are heated to a temperature range where soldering is performed. The main heating unit 30 for soldering the solder paste interposed between the solar cell 1 and the ribbon 2, and the solar cell 1 and the ribbon are heated to a predetermined temperature range The annealing unit 40 (annealing unit) and the solar cell (1) and the ribbon (2) to allow the cell (1) and the ribbon (2) is gradually cooled without sudden cooling, the preheating unit (20) And a conveying unit which conveys sequentially to the main heating unit 30 and the annealing unit 40. do.

The conveying unit may be composed of a conveying belt 10 of a conveyor structure on which the solar cell 1 is seated. The conveying belt 10 is not deformed by heat, it is preferably made of a metal material so as to transfer the heat released from the lower annealing heater 42 of the annealing unit 40 to be described later.

The preheating unit 20 is installed on the upper side of the solar cell 1 is composed of a halogen heater 21 for heating by irradiating the beam to the lower side. The preheating unit 20 preheats the solar cell 1 and the ribbon 2 in a set temperature range, for example, 130 ~ 160 ℃.

In addition, the main heating unit 30 is installed on the upper side of the solar cell (1) and the halogen heater 31 for heating the upper portion of the solar cell (1) and the ribbon (2) by irradiating a beam downward; The lower heating block 33 is configured to be movable up and down from the lower side of the solar cell 1 and to heat while pressing the ribbon 2 in contact with the lower surface of the solar cell 1 upward. Under the halogen heater 31, a pressing member 32 made of a light transmissive and heat resistant material for pressing the ribbon 2 against the solar cell 1 is provided to be movable upward and downward.

The main heating unit 30 is heated to a temperature of approximately 280 ~ 320 ℃ to melt the solder paste to solder the ribbon 2 to the solar cell (1).

The lower heating block 33 has an electrothermal heater (not shown) installed therein to transfer heat to the ribbon 2 and the solar cell 1 in a heat transfer manner.

The annealing unit 40 includes an upper annealing heater 41 for applying heat at the upper portion of the solar cell 1 and a lower annealing heater 42 for applying heat at the lower portion of the solar cell 1.

The upper annealing heater 41 is installed on the upper side of the solar cell is composed of a halogen heater for heating the upper portion of the solar cell (1) and the ribbon (2) by irradiating a beam to the lower side, the lower annealing heater (42) ) Is installed in the lower side of the conveying belt 10 is composed of a heat transfer heater for transferring heat to the lower portion of the solar cell (1) through the conveying belt (10).

The annealing unit 40 performs a function of gradually cooling the solar cell 1 rapidly heated in the main heating unit 30 by applying heat to a temperature range of about 80 ~ 100 ℃.

Meanwhile, the halogen heaters 21, 31, and 41 formed on the preheating unit 20, the main heating unit 30, and the annealing unit 40 have a length of the ribbon 2 as shown in FIG. 3. The semi-cylindrical reflector 50 is formed to extend in a direction, and reflects the light emitted from the halogen heater 21 to focus on the ribbon 2 on the upper side of the halogen heater 21, 31, 41. It consists of a provided configuration. In this embodiment, a halogen heater is used as an upper heater of the preheating unit 20, the main heating unit 30, and the annealing unit 40, but an infrared heater may be used differently.

In addition, the halogen heaters 21, 31, and 41 may be formed in a lengthwise direction as described above, but may also be formed in a spherical shape.

The heating apparatus for attaching the ribbon of the solar cell configured as described above acts as follows.

When the solar cell 1 which the ribbon 2 contacted on the conveyance unit is seated, the conveyance belt 10 conveys the solar cell 1 below the preheating unit 20.

When the solar cell 1 is positioned below the preheating unit 20, a beam is emitted from the halogen heater 21 and the temperature of the upper part of the solar cell 1 and the ribbon 2 is about 150 ° C. Preheat to.

When the preheating for a predetermined time is completed, the transfer unit transfers the solar cell 1 to the lower side of the main heating unit 30.

Subsequently, the pressing member 32 of the main heating unit 30 is lowered to press the ribbon 2 to a predetermined pressure against the upper surface of the solar cell 1, and the beam is emitted from the halogen heater 31. The upper part of the solar cell 1 and the ribbon 2 is heated to the temperature of about 300 degreeC. Thus, the ribbon 2 in contact with the upper surface of the solar cell 1 is soldered and fixed by solder paste.

Subsequently, the lower heating block 33 rises upward to press the ribbon 2, which is in contact with the lower surface of the solar cell 1, to the solar cell 1 while pressing the ribbon 2 upward, thereby heating the solar cell. The ribbon 2 is soldered and fixed to the lower part of (1).

When the ribbon 2 is soldered and fixed to the upper and lower portions of the solar cells 1 in the main heating unit 30, the conveying unit conveys the solar cell 1 to the lower side of the annealing unit 40.

At this time, the beam is emitted from the halogen heater, which is the upper annealing heater 41 of the annealing unit 40, and the upper part of the solar cell 1 is heated to a temperature of approximately 80 ° C., while the lower annealing heater 42 is heated. As power is applied, heat is transferred to the lower portion of the solar cell 1 through the conveyance belt 10. Accordingly, the solar cell 1 passing through the main heating unit 30 is gradually cooled instead of being cooled rapidly. Accordingly, the phenomenon in which the solar cell 1 is subjected to thermal stress due to a temperature difference due to rapid cooling is prevented, and the solar cell 1 is prevented from being damaged.

1 is a longitudinal sectional view and a plan view showing a state in which a ribbon is attached to a typical solar cell

Figures 2a to 2c is a cross-sectional view of the main part from the side view schematically showing the configuration and operation of one embodiment of the heating device for attaching the ribbon of the solar cell according to the present invention

Figure 3 is a perspective view schematically showing the structure of a halogen heater of the heating device for ribbon attachment of the solar cell of Figure 2a

Explanation of symbols on the main parts of the drawings

1 solar cell 2 ribbon

10: conveying belt 20: preheating unit

21: halogen heater 30: main heating unit

31 halogen heater 32 pressurizing member

33: lower heating block 40: annealing unit

41: upper annealing heater (halogen heater) 42: lower annealing heater

Claims (5)

A conveying unit in which the ribbon is placed in contact with the electrodes of the solar cell via the solder paste and is conveyed; A pre-heating unit for preheating by applying heat of a first temperature range to the solar cell and the ribbon conveyed by the conveying unit; A main heating unit for soldering and fixing the solar cell and the ribbon by applying heat of a second temperature range higher than the first temperature range to the solar cell and the ribbon transferred through the preheating unit; And an annealing unit configured to apply heat to a solar cell and a ribbon transferred through the main heating unit to a third temperature range lower than the second temperature range, thereby cooling the ribbon. The heating apparatus for attaching a ribbon of a solar cell according to claim 1, wherein the preheating unit is configured of a halogen heater or an infrared heater installed on an upper side of the solar cell and irradiating a beam downward to heat the solar cell. According to claim 1, wherein the main heating unit is installed on the upper side of the solar cell, a halogen heater or an infrared heater for heating the upper part of the solar cell and the ribbon by irradiating a beam to the lower side, and the upper and lower sides of the solar cell Heating device for attaching the ribbon of the solar cell, characterized in that configured to be movable to the lower heating block for heating while pressing the ribbon in contact with the lower surface of the solar cell upward. The heating apparatus of claim 1, wherein the annealing unit comprises an upper annealing heater and a lower annealing heater that apply heat to each of the upper and lower portions of the solar cell. The method of claim 4, wherein the upper annealing heater is installed on the upper side of the solar cell is composed of a halogen heater or an infrared heater for heating the upper portion of the solar cell and the ribbon by irradiating a beam downward; The lower annealing heater is installed on the lower side of the conveying unit is a heating device for ribbon attachment of a solar cell, characterized in that consisting of a heat transfer heater for transferring heat to the lower portion of the solar cell seated on the conveying unit.

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