KR20200079472A - Method manufacturing for solar cell string of shingled module structure and solar cell module - Google Patents

Abstract

The present invention relates to a method for manufacturing a solar cell string of a shingled module structure and a solar cell module, which increase output and conversion efficiency of a solar cell by controlling an application amount of a conductive adhesive. The method comprises: a step (a) of preparing a solar cell provided with a front side electrode composed of silver (Ag) and a rear side electrode composed of aluminum (Al); a step (b) of forming a plurality of unit cells by cutting the solar cell in the step (a); a step (c) of applying the conductive adhesive to the rear side electrode of the unit cell arranged in the step (b); and a step (d) of forming the solar cell string of the shingled module structure by connecting the rear side electrode, to which the conductive adhesive is applied in the step (c), in series to the front side electrode, wherein applying the conductive adhesive in the step (c) is performed by RPM-controlling the discharge amount of the conductive adhesive discharged from a needle of a micro dispenser with the diameter of 250 μm, forming the string in the step (d) is performed under heat treatment conditions of 25-35 seconds and 130-150°C, and the conductive adhesive with an amount of 0.02 g or more is applied to the rear side electrode, thereby increasing output and conversion efficiency of the solar cell.

Description

{Method manufacturing for solar cell string of shingled module structure and solar cell module}

The present invention relates to a method for manufacturing a solar cell string with a shingled module structure and a solar cell module, and in particular, to manufacture a solar cell string with a shingled module structure that increases the output and conversion efficiency of a solar cell by controlling the amount of conductive adhesive applied. It relates to a method and a solar cell module.

Currently, fossil fuel, the main energy source, is gradually depleting its reserves and adversely affecting the global environment such as global warming, so humans are accelerating the development of alternative energy. There are wind energy, hydro power, nuclear power, and solar energy as alternative energy that does not cause environmental problems and depletion. Among them, solar power, known as an infinite energy source, is rapidly emerging as a future alternative to fossil fuels.

Solar power generation is a technology that directly converts infinite, pollution-free solar energy into electrical energy. The basic principle of photovoltaic power generation is when electrons and holes are paired by light energy when sunlight is irradiated to a solar cell composed of a semiconductor PN junction, electrons and holes move, and an electric current crosses the n and p layers. Electromotive force is generated by the photovoltaic effect that flows through, and current flows in the load connected to the outside.

The solar cell module has a multilayer structure to protect the solar cell from the external environment. The solar cell module frame maintains the mechanical strength of the solar cell module, and serves to strongly bond the materials stacked on the front and rear surfaces of the solar cell and the solar cell.

In the photovoltaic module manufacturing using solar cells, it is generally possible to reduce fixed costs through large-scale expansion, reduce raw material usage such as reducing cell thickness to reduce the cost of silicon wafers, or reduce process losses. It was effective to reduce the module cost, but with the development of technology, large-scale expansion and reduction of raw material usage are no longer easy.

On the other hand, the solar module is composed of a plurality of strings (string) are connected in series. For example, four strings constitute one photovoltaic module, each of which has a photovoltaic power generation function independently. In the solar module string, a power cable is directly connected to a load, and often, unnecessary power consumption is seriously accumulated due to a short circuit of a line.

An example of such a technique is disclosed in documents 1 to 3 below.

For example, in the following Patent Document 1, as shown in FIG. 1, preparing a PERC (Passivated Emitter and Rear Cell) solar cell 102 cell including the front electrode 150 and the back electrode 160, Forming uneven portions 151 and 161 on at least one of the front electrode and the rear electrode, preparing a plurality of PERC solar cell units 101 by singulating the PERC solar cell and the plurality of PERCs Bonding each other in a shingled array structure through a conductive adhesive 190 in a bonding region 180 between the front electrode of the PERC solar cell unit on one side and the rear electrode of the PERC solar cell unit on the other side of the solar cell unit. Containing, the step of bonding to each other is performed by using a conductive filler-filled thermosetting resin as the conductive adhesive, the conductive filler-filled thermosetting resin is a high-efficiency comprising a silver flake as a conductive filler and a polyfunctional epoxy as a thermosetting resin A method for manufacturing a PERC solar cell is disclosed.

In addition, in the following Patent Document 2, as shown in FIG. 2, a conductive adhesive application step of applying a conductive adhesive 702 to the electrodes across each of the solar cell submodules 710, a transparent adhesive to the protective cover glass 720 ( 704) applying a transparent adhesive, applying a plurality of solar cell sub-modules to each other and arranging the solar cell sub-modules arranged on the protective cover glass, and heating and curing to heat and cure the conductive adhesive and the transparent adhesive. A method of manufacturing a dye-sensitized solar cell comprising steps is disclosed.

Meanwhile, in Patent Document 3, a solar cell forming step of forming a solar cell including a plurality of unit cells on a metal flexible substrate, a conductive adhesive layer forming step of forming a conductive adhesive layer on each of the plurality of unit cells, and the plurality of And a singulation step of separating the unit cells from each other to form a plurality of solar cells and a series connection step of connecting the plurality of solar cells in series with each other to form a solar cell module. Disclosed is a method of manufacturing a solar cell module in which a first conductive adhesive layer is formed on one end of a unit cell on an upper surface of a transparent electrode, and a second conductive adhesive layer is formed on the other end of a unit cell on a lower surface of the metal flexible substrate.

Republic of Korea Registered Patent Publication No. 10-1874016 (Registered on June 27, 2018) Republic of Korea Patent Publication No. 2013-0117090 (2013.10.25 published) Republic of Korea Registered Patent Publication No. 10-1895025 (registered on August 29, 2018)

In the technology disclosed in Patent Literatures 1 and 3 as described above, for manufacturing a shingled module type solar cell string by connecting the front electrode and the rear electrode of each cell divided by a conductive adhesive (ECA) in series with each other. Although described, the application amount of the conductive adhesive in consideration of the output and economical efficiency of the solar module has not been disclosed.

In addition, in Patent Document 2, the curing temperature of the conductive adhesive and the transparent adhesive is only disclosed for the room temperature (25° C.) to 100° C. range. In this Patent Document 2, the application amount of the conductive adhesive in consideration of the output and economical efficiency of the solar module is also disclosed. It has not been disclosed.

In addition, in the conventional technique as described above, in the case of the string of the shingled module, the length can be adjusted within 50 to 100 cm, and as shown in FIG. 3, the front electrode (Ag) and the back electrode (Ag) are bonded when divided. ) It is a structure that joins with ECA (Electroconductive Adhesive) after matching of lines. In this conventional shingled module, as shown in FIG. 3(b), silver (Ag) is gridd on the rear electrode to be bonded to the silver (Ag) of the front electrode, so a silver (Ag) line is added. There is a problem that the manufacturing cost of the solar module is increased because expensive silver (Ag) is used.

That is, in the conventional technique as described above, both the front electrode and the rear electrode of the junction are silver (Ag), and the Ag has a thickness of 50 to 70 μm or more. However, the back electrode of a typical solar cell uses aluminum (Al), and a process in which Ag is applied to the back electrode for bonding as described above is added, which increases the process cost. In addition, the current solar cell companies do not produce the front electrode and the back electrode all in silver (Ag), so it is necessary to manufacture the silver (Ag) line on the back electrode separately at the request of the manufacturer. There was a problem that the manufacturing cost of was added.

The object of the present invention was made to solve the problems as described above, and the solar cell string manufacturing method and the sun of the shingled module structure that can reduce the manufacturing cost of the solar cell by controlling the discharge amount (or coating amount) of the conductive adhesive It is to provide a battery module.

Another object of the present invention is to apply a front electrode formed of silver (Ag) and a rear electrode formed of aluminum (Al), and a solar cell string manufacturing method and solar cell module having a shingled module structure that increases the output and conversion efficiency of a solar cell. Is to provide

In order to achieve the above object, a method for manufacturing a solar cell string with a shingled module structure according to the present invention is a method for manufacturing a solar cell string with a shingled module structure, wherein (a) a front electrode made of silver (Ag) and aluminum (Al ) Preparing a solar cell provided with a rear electrode, (b) cutting the solar cell of step (a) to form a plurality of unit cells, (c) the prepared in step (b) Applying a conductive adhesive to the back electrode of the unit cell and (d) forming a solar cell string having a shingled module structure by connecting the back electrode and the front electrode coated with the conductive adhesive in step (c) in series with each other. In the step (c), the application of the conductive adhesive in step (c) is performed by RPM control of the discharge amount of the conductive adhesive discharged from the needle of the micro-dispenser having a diameter of 250 μm, and forming the string in step (d). Silver is carried out under the heat treatment conditions of 25 ~ 35 seconds and 130 ~ 150 ℃, the conductive adhesive is characterized in that applied to the back electrode 0.02g or more.

In addition, in the method of manufacturing a shingled module structure solar cell string according to the present invention, the conductive adhesive is characterized in that 0.0209g to 0.0265g is applied on the back electrode.

In addition, in the method of manufacturing a shingled module structured solar cell string according to the present invention, the conductive adhesive is characterized in that it is applied to the back electrode with a thickness of 10 μm and a width of 1.5 mm.

In the method of manufacturing a shingled module structure solar cell string according to the present invention, the conductive adhesive includes a conductive filler, a binder, a solvent and an additive, and the conductive filler is Au, Pt, Pd, Ag, Cu, Ni and carbon It characterized in that it comprises at least one material selected from.

In addition, to achieve the above object, the solar cell module according to the present invention is characterized by being formed by the above-described method for manufacturing a string of solar cells having a shingled module structure.

As described above, according to the method of manufacturing a solar cell string having a shingled module structure and a solar cell module according to the present invention, the discharge amount (or application amount) of a conductive adhesive discharged from a needle of a micro-dispenser during the application of the conductive adhesive is controlled. Accordingly, even when the front electrode formed of silver (Ag) and the rear electrode formed of aluminum (Al) are applied, an effect that the output and conversion efficiency of the solar cell can be increased is obtained. That is, according to the present invention, the conventional solar cell structure consisting of the front electrode formed of silver (Ag) and the rear electrode formed of aluminum (Al) is divided and joined, and the output is output from the existing structure without additional process by controlling the discharge amount of ECA. It has the advantage of being able to fit.

In addition, according to the method of manufacturing a solar cell string having a shingled module structure and a solar cell module according to the present invention, the silver (Ag) is gridd on the rear electrode to be bonded to the silver (Ag) of the front electrode to further process the silver (Ag) line. Compared to the conventional technology using generated and expensive silver (Ag) itself, the additional process is omitted and a conductive adhesive (ECA) containing silver (Ag) is applied, so that an effect of saving more than 67% can be obtained. Lose.

1 is a view for explaining a shingled array structure in which a conductive adhesive is interposed between a front electrode and a rear electrode of a conventional PERC solar cell unit;
2 is a view for explaining a method of manufacturing a dye-sensitized solar cell,
3 is a view showing an example of a conventional 5 divided front electrode and rear electrode,
Figure 4 is a process diagram for explaining the manufacturing process of the solar cell module using the solar cell string of the shingled module structure according to the present invention,
5 is a photo of a solar cell applied to the present invention,
Figure 6 is a photograph showing the coating phenomenon according to the RPM change in the micro-dispenser of the sprayed conductive adhesive (ECA),
7 is a photograph showing the discharge amount change according to the RPM change in the micro-dispenser of the sprayed conductive adhesive (ECA),
8 is a graph showing output and conversion efficiency in a solar cell module manufactured by a method of manufacturing a shingled module structured solar cell string according to the present invention.

The above and other objects and new features of the present invention will become more apparent through the description of the present specification and the accompanying drawings.

As used herein, the term "Electroconductive Adhesive" is an electrically conductive adhesive used for wiring bonding of electrical and electronic products or circuits, and uses an epoxy resin compounded with silver particles. The principle that the conductive adhesive expresses conductivity is that the conductive filler dispersed in the adhesive exhibits conductivity by contacting the filler with the filler in the curing or solidifying step. In addition, the conductive adhesive is applied using a micro-dispenser, and the discharge amount (or application amount) from the needle must be constant and does not flow. As the conductive filler, metal powders such as gold, platinum, silver, copper, and nickel, carbon or carbon fibers, graphite, and composite powders can be used.

In the present invention, in order to increase conversion efficiency and output per unit of the solar cell module, a shingled array process in which the front electrode and the back electrode are connected with a conductive adhesive is applied.

In addition, the solar cell module according to the present invention has a glass on the front, an EVA sheet is disposed on the back, a string line is installed, and an EVA and a backsheet to protect the cell are placed on the back of the cell and the lamination process is performed. It is executed and means that wiring for extracting electricity to the outside is included.

Hereinafter, embodiments according to the present invention will be described according to the drawings.

4 is a process diagram for explaining a manufacturing process of a solar cell module using a shingled module structured solar cell string according to the present invention, and FIG. 5 is a photo of a solar cell applied to the present invention.

The manufacturing of the solar cell using the solar cell string of the shingled module structure according to the present invention first, as shown in FIG. 5, prepares a solar cell in which the front electrode and the rear electrode are provided (S10).

The solar cell is, for example, a cell structure as shown in FIG. 5, a substrate, an emitter formed on the front surface which is an incident surface from which light enters, an antireflection film formed on the emitter, facing the front surface of the substrate Includes a plurality of passivation layers formed on the back side of the substrate, a plurality of front electrodes electrically connected to the emitter, a plurality of protective films and an integral back electrode formed on the substrate, and a plurality of back electric field layers formed between the back electrode and the substrate. can do.

The substrate may be a semiconductor made of silicon of a first conductivity type, for example, n-type or p-type conductivity type, and the emitter may be of a second conductivity type, for example, p-type or n opposite to the conductivity type of the substrate. As an impurity of the conductivity type, a pn junction is formed with the semiconductor substrate.

The anti-reflection film may be formed by depositing a silicon nitride film (SiNx) or a silicon oxide film (SiOx) on the emitter, and the plurality of protective films are formed on the back surface of the substrate and reduce the recombination rate of charge near the back surface of the substrate. Have a function.

The plurality of front electrodes are formed on the emitter and are electrically connected to the emitter, aligned in a predetermined direction spaced apart from each other, and collect electric charges, for example, holes/electrons, moved to the emitter to external devices (load) Has the function of outputting to, nickel (Ni), copper (Cu), silver (Ag), aluminum (Al), tin (Sn), zinc (Zn), indium (In), titanium (Ti), gold (Au) ) And combinations thereof, and in the present invention, the front electrode is made of silver (Ag).

The back electrode is made of a conductive material, and may be integrally formed on a back surface of a plurality of protective films and substrates, nickel (Ni), copper (Cu), silver (Ag), aluminum (Al), tin (Sn), It may be made of zinc (Zn), indium (In), titanium (Ti), gold (Au), and combinations thereof. In the present invention, a configuration made of aluminum (Al) is applied to the rear electrode in consideration of manufacturing costs. Did.

The rear electric field layer may be formed between the rear electrode and the substrate, and has a function of preventing holes/electrons from moving toward the rear surface of the substrate and preventing electrons and holes from recombining and disappearing from the rear surface of the substrate.

As described above, in the present invention, the front electrode formed of silver (Ag) and the back electrode formed of aluminum (Al) applied to a normal solar cell are applied, and the discharge amount of the conductive adhesive is controlled without additional process for the back electrode. A solar cell string with a shingled module structure is manufactured. Therefore, it is possible to shorten the manufacturing process due to the post-processing of the back electrode and reduce the cost, thereby providing a relatively inexpensive solar cell module.

Next, the solar cell prepared in step S10 is cut to form a plurality of unit cells (S20).

The cutting in step S20 may be performed, for example, by a nanosecond laser (532 nm, 20 ns, 30-100 KHz from Coherent). That is, it can be executed by setting the average power of 10W, frequency of 50KHz, and scan speed of 1,300mm/s in a 20ns laser using a 532nm wavelength.

Subsequently, a conductive adhesive is applied to at least one of the front electrode and the rear electrode of the unit cell provided in step S20 (S30).

As such a conductive adhesive, a product having a high conductivity and a suitable viscosity suitable for the present invention among the conductive adhesives on the market, for example, EL-3012, EL-3556, EL-3653, EL-3655 of SKC Panacol, and CE3103WLV of Henkel , CA3556HF can be applied, for example, viscosity of 28,000 to 35,000 mPa·s (cP) at 25° C., as electrical properties, volume resistivity 0.0025 Ω·cm, curing temperature of 130 to 150° C., curing time of 25 to 35 The adhesive with the properties of candles is applied. In addition, the conductive filler in the conductive adhesive may include at least one material selected from Au, Pt, Pd, Ag, Cu, Ni and carbon.

In step S30, the application of the conductive adhesive is performed by controlling the discharge amount of the conductive adhesive discharged from the needle of the micro dispenser. Application of the above-mentioned conductive adhesive is, for example, viscosity of 28,000 to 35,000 mPa·s (cP) at 25° C., volume resistivity of electrical properties of 0.0025 Ω·cm, curing temperature of 130 to 150° C., and curing time of 25 to 35 seconds. This conductive adhesive is discharged from the needle of a micro-dispenser having a diameter of 250 µm and is controlled by controlling the RPM.

6 is a photograph showing the coating phenomenon according to the RPM change in the micro-dispenser of the sprayed conductive adhesive (ECA), Figure 7 is the discharge amount (or coating amount) change according to the RPM change in the micro-dispenser of the sprayed conductive adhesive (ECA) It is a picture to show.

7 is the same discharge condition using the conductive adhesive (ECA) of "Henkel", so the discharge rate is determined according to the scan speed and RPM of the dispenser of the bonding device in the structure of the dispenser having a constant discharge amount, and the thickness is about 10 It is applied with a thickness of µm. In addition, the width of the applied conductive adhesive (ECA) should be matched with the width of the electrode at the junction, and thus is formed to be about 1.5 mm.

As can be seen from FIGS. 6 and 7 (a) and (b), it can be seen that the width of the sprayed conductive adhesive (ECA) is not uniform under RPM 60. FIG. 7(a) shows a state in which the conductive adhesive (ECA) was applied at an RPM of 0.0085 g at RPM 40, and FIG. 7(b) shows a state where the conductive adhesive (ECA) was applied at an RPM of 60 at an application amount of 0.0129 g. It is a picture.

On the other hand, as can be seen from (c) and (d) of FIGS. 6 and 7, it is possible to spray the conductive adhesive (ECA) with a uniform width from RPM 90 or higher, and the amount of the sprayed conductive adhesive (ECA) is applied to the RPM. It can be seen that it increases proportionally. In particular, it was found that when spraying at a speed of 120 RPM, it was uniformly applied with a specific thickness on the front electrode made of silver (Ag) or the rear electrode made of aluminum (Al). FIG. 7(c) shows a state in which the conductive adhesive (ECA) is applied at an RPM 90 of 0.0209 g, and FIG. 7(d) shows a state in which the conductive adhesive (ECA) is applied at an RPM 120 of 0.0265 g. It is a picture.

That is, in the present invention, the front electrode made of silver (Ag) and aluminum (Al) are controlled by controlling the discharge amount (or coating amount) of the conductive adhesive (ECA) by a micro-dispenser used for discharging a conventional conductive adhesive (ECA). In the junction structure of the back electrode made of silver, the output and conversion efficiency can be improved compared to the junction structure of the electrode made of silver (Ag) only.

Application of the above-described conductive adhesive may be performed on either the front electrode or the back electrode, or may be performed on the front electrode and the back electrode, respectively. The positioning of the coating on the front electrode and the back electrode may be determined according to the characteristics of the conductive adhesive and the discharge amount.

In the step of applying the conductive adhesive according to the present invention (S30), it is preferable to apply to the back electrode made of aluminum (Al). That is, although it may be applied to the front electrode or the back electrode according to the flip-flop condition of the equipment, when the conductive adhesive is applied to the front electrode portion, the front sun is caused by the dispersing phenomenon of the conductive adhesive (ECA). There is a concern that the light incident region may be contaminated and the output may be lowered.

However, the present invention is not limited thereto, and the conductive adhesive may be sprayed at a speed of 120 RPM from a microneedle having a diameter of 250 μm to be applied on a front electrode and a rear electrode with a specific thickness and width, respectively. As described above, when applied to the front electrode and the back electrode, respectively, in the bonding process of the front electrode and the back electrode, the thickness and width to be applied are 1/2, respectively, compared to applying only to the back electrode made of aluminum (Al). It might be.

Next, in step S30, the front electrode and the back electrode coated with the conductive adhesive are connected in series to each other to form a shingled module structure solar cell string (S40). String formation in step S40 may be performed under heat treatment conditions of 25 to 35 seconds and 130 to 150°C.

Subsequently, each string provided in step S40 is connected in series, parallel or in series to form a solar cell module (S50).

8 shows the results of measuring the output and conversion efficiency in the solar cell module manufactured as described above.

8 is a graph showing output and conversion efficiency in a solar cell module manufactured by a method of manufacturing a shingled module structured solar cell string according to the present invention.

As can be seen in FIG. 8, the average power according to the present invention applying the front electrode formed of silver (Ag) and the rear electrode formed of aluminum (Al) is 26.13 W, and the average conversion efficiency is 20.78%.

That is, FIG. 8 shows a result of optimizing an ECA discharge amount by dividing the existing solar cell structure consisting of a front electrode formed of silver (Ag) and a rear electrode formed of aluminum (Al), and less than 90 RPM (application amount 0.0209 (less than g), it does not output, and is the data confirmed by making samples at 90 RPM and 120 RPM several times. As can be seen in Figure 8, the output value was implemented more stably at 120 RPM than at 90 RPM.

In addition, the conductive adhesive (ECA) is made of expensive silver (Ag) of about 80% of the ECA constituent materials, but in the present invention, silver (Ag) is gridd on the back electrode to bond with the silver (Ag) of the front electrode. (Ag) Compared to the conventional technology that uses the additional process of the line and the expensive silver (Ag) itself, the additional process is omitted and the conductive adhesive (ECA) containing silver (Ag) is applied, reducing the cost by more than 67% can do.

In other words, compared to the conventional technique in which the front electrode and the rear electrode are made only of silver (Ag), the present invention takes about 2 times the conductive adhesive (ECA), but the manufacturing cost is about 3 times by adding the process according to the prior art. Compared to this addition, simplification of the manufacturing process and the addition of cost of conductive adhesive (ECA) are not a problem.

Although the invention made by the present inventors has been described in detail according to the above-described embodiments, the present invention is not limited to the above-described embodiments and can be variously changed within a range not departing from the gist thereof.

The solar cell string manufacturing method of the shingled module structure according to the present invention and the use of the solar cell module can increase the output and conversion efficiency of the solar cell.

Claims (5)

As a method of manufacturing a solar cell string of a shingled module structure,
(a) preparing a solar cell having a front electrode made of silver (Ag) and a rear electrode made of aluminum (Al),
(B) cutting the solar cell of the step (a) to form a plurality of unit cells,
(c) applying a conductive adhesive to the rear electrode of the unit cell prepared in step (b); and
(d) forming a solar cell string having a shingled module structure by connecting the back electrode and the front electrode coated with the conductive adhesive in series with each other in step (c),
In step (c), the application of the conductive adhesive is performed by RPM control of the discharge amount of the conductive adhesive discharged from the needle of the micro dispenser having a diameter of 250 μm,
String formation in the step (d) is carried out under the heat treatment conditions of 25 ~ 35 seconds and 130 ~ 150 ℃,
The conductive adhesive is a method of manufacturing a solar cell string of a shingled module structure, characterized in that applied to the back electrode 0.02g or more. In claim 1,
The conductive adhesive is a method of manufacturing a solar cell string with a shingled module structure, characterized in that 0.0209g to 0.0265g is applied on the back electrode. In claim 2,
The conductive adhesive is a method of manufacturing a solar cell string with a shingled module structure, characterized in that it is applied to the back electrode with a thickness of 10 μm and a width of 1.5 mm. In claim 1,
The conductive adhesive includes a conductive filler, a binder, a solvent and an additive,
The conductive filler is a method of manufacturing a shingled module structure solar cell string comprising at least one material selected from Au, Pt, Pd, Ag, Cu, Ni and carbon. A solar cell module, characterized by being formed by a method of manufacturing a solar cell string having a shingled module structure according to any one of claims 1 to 4.

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