KR102137004B1 - Solar module with anti-contamination texturing layer, anti-contamination texturing layer forming method on solar module, heat treatment apparatus used for forming texturing layer - Google Patents

Abstract

The present invention relates to a solar cell module formed with an anti-contamination texturing layer, a method for forming the texturing layer, and a heat treatment device used for forming the anti-contamination texturing layer through heat treatment in the field. The solar cell module formed with an anti-contamination texturing layer comprises: a solar cell plate formed by gathering solar cells; and an upper plate which is positioned on an upper side of a solar cell layer and through which incident sunlight passes. The solar cell module formed with an anti-contamination texturing layer is formed with the anti-contamination texturing layer formed with a plurality of protrusions on the plate to increase power generation efficiency.

Description

Solar module with anti-pollution texturing layer formed, method of forming anti-pollution texturing layer formed on solar cell module, heat treatment device used to form texturing layer {Solar module with anti-contamination texturing layer, anti-contamination texturing layer forming method on solar module , heat treatment apparatus used for forming texturing layer}

The present invention is a solar cell module that can increase the power generation efficiency by forming a texturing layer that has an anti-pollution ability and can increase the amount of incident, a method of forming a pollution-preventing texturing layer on the solar cell module, and a solar cell module installation site It relates to a heat treatment apparatus that enables the formation of a texturing layer to prevent contamination through heat treatment.

As shown in FIG. 1, a conventional solar cell module is disposed on a solar cell layer 1 in which solar cell cells are gathered, and disposed on the upper and lower sides of the solar cell layer 1 and surrounding the solar cell layer 1 to protect it. The sealing material layer 2 and the glass layer 3 which are located on the upper surface of the sealing layer 2 and protect the solar cell layer 1 from externally applied forces, and the lower surface of the sealing material layer 2 It is located in the solar cell cell from external environmental requirements such as heat, humidity, and ultraviolet rays, and re-reflects the incident sunlight to increase the power generation efficiency, and the module that integrates each of these components It comprises a frame 5 to form a.

However, such a conventional solar cell module, as shown in Figure 2, because the ratio of the sunlight reflected from the glass layer 3 could not be reduced to a certain level or less, it is difficult to increase the power generation efficiency to a certain value or more. There is a problem in that the surface of the layer 3 is easily contaminated and the solar cell module needs to be continuously managed in order to prevent a decrease in power generation efficiency. That is, since the amount of sunlight entering the solar cell layer 1 is limited, it is not only difficult to improve the power generation ability, but also because the glass layer 3 is easily contaminated, the amount of sunlight reflected in response to the degree of contamination increases over time. It also had a problem of increasing and decreasing the amount of power generation.

Accordingly, there is a need to increase the transmittance of the glass layer 3 and to improve the anti-pollution ability of the glass layer 3, thereby increasing the power generation efficiency of the solar cell module.

Patent Document 1) Domestic Publication Patent Publication No. 2019-0119496 (Name: solar cell module, manufacturing method and vehicle, publication date: 2019.10.22.)

The present invention has been devised to solve the problems as described above, the object of the present invention is to increase the amount of sunlight incident on the solar cell, a solar cell module capable of solving the problem of easy contamination of the solar cell module Is to provide.

In addition, to increase the amount of incident sunlight, and to provide a method of forming a pollution-preventing texturing layer on the surface of the solar cell module in order to solve the problem that the solar cell module is easily contaminated.

And, it is to provide a heat treatment device used for forming the anti-pollution texturing layer.

The solar cell module having the anti-pollution texturing layer formed by the present invention for achieving the above object includes: a solar cell cell plate 100 in which solar cell cells are gathered; And an upper plate 200 positioned on an upper side of the solar cell cell plate 100 and through which incident sunlight passes. Containing the upper plate 200, a plurality of protrusions 211 are formed on the surface. It characterized in that the anti-texturing layer 210 is formed.

In addition, the upper plate 200 protects the solar cell cell plate 100, the upper surface includes a glass layer 230 in contact with the anti-pollution texturing layer 210, the glass layer 230 is It is characterized in that the protrusion 231 having a constant pattern is formed on the upper surface.

In addition, the method of forming the anti-pollution texturing layer, which is the present invention for achieving the above object, is a silica mixture forming step (S100) in which silica forms a silica mixture in which particles are mixed; Silica mixture coating step of applying a silica mixture on the surface of the top plate (200) (S200); And a silica mixture crystallization step (S300) of crystallizing silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200).

And, the silica mixture is characterized in that it comprises fine particles of silica and metal ions.

In addition, the silica mixture crystallization step (S300) is characterized in that made at 280 degrees to 320 degrees.

In addition, the heat treatment device of the present invention for achieving the above object, the heat treatment unit 10 for applying heat to the solar cell module; And a separation distance maintaining unit 20 maintaining a constant distance between the heat treatment unit 10 and the solar cell module.

In addition, the separation distance holding unit 20 is a base plate 21 to which the heat treatment unit 10 is coupled, and a pair of fixed plates 22 facing each other on both sides in the longitudinal direction of the base plate 21 ), a connecting bar 23 connecting the fixed plate 22, and a support plate 24 moving on the connecting bar 23 and contacting the edge of the solar cell module.

In addition, the support plate 24 is characterized in that the step portion 24-1 is formed at one end facing the solar cell module.

The method of forming the anti-pollution texturing layer, which is the present invention for achieving the above object, is a silica mixture forming step (S100) in which silica is used to form a silica mixture in which particles are mixed; Silica mixture coating step of applying a silica mixture on the surface of the upper plate (200) (S200); And a silica mixture crystallization step (S300) of crystallizing silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200); and the silica mixture crystallization step (S300). The crystal of the silica mixture crystallized in is characterized by having a particle diameter of 1 micrometer to 1.3 micrometers.

In addition, a silica mixture forming step (S100) in which silica forms a silica mixture in which particles are mixed; Silica mixture coating step of applying a silica mixture on the surface of the top plate (200) (S200); And a silica mixture crystallization step (S300) of crystallizing silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200); and the silica mixture crystallization step (S300). It is characterized in that made at 280 degrees to 320 degrees.
In addition, the solar cell cell plate 100 is made of solar cells are gathered; And a glass layer 230 positioned on an upper side of the solar cell cell plate 100 and allowing incident sunlight to pass through, and a protrusion 231 having a certain pattern on the upper surface is formed, and the glass layer 230. In the solar cell module comprising; a top plate 200 including a frame 240 surrounding the rim and a pollution-preventing texturing layer 210 forming a plurality of protrusions 211 on the surface of the glass layer 230. In the method of forming the anti-pollution texturing layer formed, a silica mixture forming step (S100) in which silica forms a silica mixture in which particles are mixed; A silica mixture application step (S200) of applying a silica mixture on the surface of the glass layer 230 by spraying; And a silica mixture crystallization step (S300) of crystallizing silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200); and the silica mixture crystallization step (S300). In the crystallization of the silica contained on the silica mixture is made from 280 degrees to 320 degrees, the heat treatment device for applying heat on the silica mixture in the silica mixture crystallization step (S300) heat treatment unit for applying heat (10 ), and a separation distance maintaining unit 20 that maintains a constant distance between the heat treatment unit 10 and the solar cell module, and the separation distance maintaining unit 20 is coupled to the heat treatment unit 10 A base plate 21, a pair of fixed plates 22 disposed opposite to each other on both sides in the longitudinal direction of the base plate 21, and a connecting bar 23 connecting the fixed plates 22, and It comprises a support plate 24 that moves on the connecting bar 23 and is in contact with the frame 240 located at the edge of the solar cell module, wherein the support plate 24 has the frame 240 coupled to its end. It characterized in that the stepped portion (24-1) is formed.

The solar cell module having the anti-pollution texturing layer formed according to the present invention has an advantage that an anti-pollution texturing layer on which a plurality of protrusions are formed is formed to increase the amount of transmitted sunlight.

In addition, since the contact angle between the contaminant and the anti-pollution texturing layer is small due to the protrusion formed on the surface, there is an advantage that the solar cell module can have high contamination resistance.

In addition, in the method of forming the anti-pollution texturing layer according to the present invention, it is possible to set the heat treatment temperature for crystallizing the silica particles to an optimal temperature to maximize the light transmittance, thereby maximizing the power generation efficiency of the solar cell module having the anti-pollution texturing layer There are advantages.

In addition, the heat treatment device according to the present invention is capable of heating the silica mixture in a state spaced apart from the surface of the solar cell module coated with the silica mixture, so that it is possible to more easily form a pollution-preventing texturing layer in the field.

1 is an exploded perspective view showing a conventional solar cell module.
Figure 2 is a cross-sectional view showing a conventional solar cell module.
3 is a conceptual view showing a solar cell module having a pollution-preventing texturing layer according to a first embodiment of the present invention.
4 is a conceptual diagram showing a solar cell module having a pollution-preventing texturing layer according to a second embodiment.
Figure 5 is an enlarged photograph of the projections formed on the anti-pollution texturing layer and the anti-pollution texturing layer.
Figure 6 is a flow chart showing a method for forming a texturing prevention layer formed on the solar cell module according to the present invention.
Figure 7 is a graph showing the particle diameter of the projection variable according to the heat treatment temperature of the silica mixture.
8 is an enlarged photograph of projections in which the particle diameter is varied according to the heat treatment temperature of the silica mixture.
Figure 9 is a photographic data showing the change in the light transmittance of the anti-pollution texturing layer that varies depending on the heat treatment temperature of the silica mixture.
10 is a graph quantifying a change in silver light transmittance of a pollution-preventing texturing layer that varies depending on a heat treatment temperature of a silica mixture.
11 is a perspective view of a heat treatment apparatus used in the method for forming a contamination-preventing texturing layer according to the present invention.
12 is a cross-sectional view of the heat treatment apparatus used in the method of forming the anti-pollution texturing layer according to the present invention.

Advantages and features of the embodiments of the present invention, and methods for achieving them will be made clear by referring to embodiments described below in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

In describing embodiments of the present invention, when it is determined that a detailed description of known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, with reference to the accompanying drawings will be described with respect to the solar cell module 1000 is formed anti-pollution texturing layer according to the present invention.

3 is a conceptual diagram showing a solar cell module having a pollution-preventing texturing layer according to a first embodiment.

Referring to FIG. 3, the solar cell module 1000 having the anti-pollution texturing layer according to the first embodiment includes a solar cell cell plate 100 in which solar cell cells are collected and an upper side of the solar cell cell plate 100. The solar cell module includes an upper plate 200 through which the incident sunlight passes, and a lower plate 300 positioned below the solar cell plate 100, wherein the upper plate 200 is the solar cell module. A sealing material layer 220, the glass layer 230, and a frame 240 that appreciates the rim of each component may be included on the upper side of the solar cell module. An anti-pollution texturing layer 210 which may include a sealing material layer 310 and a backsheet layer 320, which are sequentially positioned on the lower side, and wherein a plurality of protrusions 211 are formed on the surface of the glass layer 230. It can be formed.

In detail, as described above with reference to FIG. 1, since the glass layer 230 positioned at the outermost and passing sunlight has a flat surface shape, it has a high surface reflectance and is easily contaminated. , In the present invention, by forming the anti-pollution texturing layer 210 formed with a protrusion 231 having a certain pattern on the surface of the glass layer 230, to lower the surface reflectance and at the same time to increase the contamination resistance.

Once again, by making the surface of the solar cell module 1000 through the texturing layer 210 into an embossed shape, the reflected sunlight L as shown in FIG. 3A is re-incident. And, as shown in Figure 3 (b), the contaminant (D) is the contact angle is minimized by the protrusion 231, it is not attached to the surface of the solar cell module can be removed by flowing down along the surface will be.

4 is a conceptual view showing a solar cell module having a pollution-preventing texturing layer according to a second embodiment, and FIG. 5 is an enlarged view of the projection 211 and the pollution-preventing texturing layer 210.

Referring to FIG. 4, the solar cell module 1000 having the anti-pollution texturing layer according to the second embodiment includes a protrusion having a certain pattern on the surface of the glass layer 230 contacting the anti-pollution texturing layer 210 ( 231) is formed, anti-contamination texturing layer 210 may be formed in the form of coating the protrusion 231.

5, the projection 211 has a very small particle size of several hundred to several hundred microns, as shown in FIG. 5(a), and the anti-pollution texture formed with the projection 211?? The layer 210 has a structure in which a plurality of protrusions 211 are formed on the surface, as shown in FIG. 5B. Accordingly, as shown in FIG. 5, the protrusions 231 are formed on the glass layer 230, and the anti-pollution texturing layer 210 is formed on the surface of the glass layer 230 on which the protrusions 231 are formed, respectively. It is possible to form a plurality of the projections 211 in the protrusion 231 of the.

At this time, the protrusions 211 formed on the protrusions 231 widen the surface area of the protrusions 231 and make the solar cell surface shape into a shape enabling re-incident sunlight, so that the surface reflectance of the solar cell module Of course, it is possible to increase power generation efficiency by lowering.

6 is a flow chart showing a method of forming a pollution-preventing texturing layer formed on a solar cell module according to the present invention.

Referring to FIG. 6, a method (S1000) of forming an anti-pollution texturing layer formed on a solar cell module includes a silica mixture forming step (S100) of forming a silica mixture in which silica particles are mixed, and a top surface 200 of the silica mixture. Silica mixture coating step (S200) applied to the surface of the silica mixture crystallization step (S300) to crystallize the silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200) It can be made including.

In detail, in the step of forming the silica mixture (S100), fine-sized silica particles and several metal materials such as lithium (Li) and potassium (K) are mixed to form a liquid silica mixture in which metal ions are mixed. Thereafter, the silica mixture is applied to the surface of the glass layer 230 by spraying using a sprayer in the step of applying the silica mixture (S200), or a silica liquid layer is applied through a flattening operation after applying a certain liquid silica mixture After making the mixture, in the crystallization step (S300), heat is applied to the silica mixture layer to form the anti-pollution texturing layer 210, but fine silica particles mixed in the silica mixture are aggregated in the process of applying heat. It is to form the projection (211).

7 is a graph showing the size of the projections that vary depending on the heat treatment temperature of the silica mixture, FIG. 8 is a photographic image of these projections enlarged, and FIG. 9 is a contamination-preventing texturing layer that varies depending on the heat treatment temperature of the silica mixture ( 210) is a photographic data showing changes in light transmittance, and FIG. 10 is a graph quantifying the photographic data in FIG.

7 to 10, it is recommended that the silica mixture crystallization step (S300) is performed at 280 degrees to 320 degrees, and the optimized temperature may be 300 degrees. In detail, as shown in FIG. 8, the particle diameter of the aggregated silica particles constituting the protrusion 211 has an average size of 0.97 Mm when heat-treated at 200 degrees, and an average size of 1.12 Mm when heat-treated at 300 degrees. , It has an average size of 1.66Mm when heat treated at 400 degrees, and such a size change can be confirmed by referring to FIGS. 8(a) to 8(c).

However, the light transmittance of the anti-pollution texturing layer 210 is not simply increased as the particle size of the protrusion 211 increases, but as shown in FIG. 9, the transmittance has a formation temperature of the anti-pollution texturing layer 210 of 200. 93.76 percent for the degree, 95.92 percent for the 300 degree, 95.09 percent for the 400 degree, the highest when the particle diameter of the projection 211 is made at 1.12 Mm at 300 degrees, as shown in FIG. 9, and this permeability improvement is developed Since the efficiency is increased, the present invention heats the silica mixture in a region of about 280 to 320 degrees, so that the protrusion 211 has a size of 1.12 Mm, which has the highest power generation efficiency.

11 is a perspective view of a heat treatment device used in the method of forming the anti-pollution texturing layer of the present invention, and FIG. 12 is a cross-sectional view of the heat treatment device used in the method of forming the anti-pollution texturing layer of the present invention.

Referring to FIG. 11, the heat treatment device H includes a heat treatment part 10 that applies heat to a solar cell module, and a separation distance maintaining part that maintains a constant distance between the heat treatment part 10 and the solar cell module ( 20), may include a temperature control unit 30 for adjusting the temperature of the heat treatment unit 10, the separation distance maintaining unit 20 and the base plate 21 to which the heat treatment unit 10 is coupled , Riding a pair of fixed plates 22 disposed opposite to each other on both sides of the base plate 21 in the longitudinal direction, a connecting bar 23 connecting the fixed plates 22, and the connecting bar 23 A movable plate includes a support plate 24 that is in contact with the edge of the solar cell module, and a step portion 24-1 may be formed at one end of the support plate 24 facing the solar cell module.

In detail, in order to form the anti-pollution texturing layer 210 on the solar cell module, the silica mixture applied through the mixture crystallization step (S300) must be cured and crystallized fine silica particles. At this time, if the anti-pollution texturing layer 210 is not formed on the surface of the solar cell module in the manufacturing process, the anti-pollution texturing layer 210 must be formed through the texturing layer formation method at the site where the solar cell module is installed. Therefore, in the present invention, heat can be constantly applied to the surface of the solar cell module using the heat treatment device.

Referring again to FIG. 12, the size at which the silica particles are crystallized in the mixture crystallization step (S300) affects the heating temperature, and since the heating temperature is variable according to the separation distance, a pair of widths can be adjusted. After forming the step portion 24-1 on the support plate 24, after adjusting the width of the support plate 24 according to the size of the solar cell module (S), the step portion 24-1 By supporting the frame 5, while the solar cell module and the heat treatment unit 10 maintain a constant distance, it is possible to apply heat at a constant temperature to the solar cell module.

In addition, such a heat treatment device can adjust the width of the support plate in correspondence with the width of the solar cell module, so it goes without saying that it can be used for various solar cell modules.

The present invention is not limited to the above-described embodiments, and of course, the scope of application is various, and anyone who has ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications are possible.

10: heat treatment part
20: separation distance holding unit 21: base plate
22: fixing plate 23: connecting bar
24: support plate 24-1: step
30: temperature control unit
100: solar cell cell plate
200: upper plate 210: anti-pollution texturing layer
211: projection
220: sealing material layer
230: glass layer 231: protrusion
300: lower plate
S100: silica mixture formation step S200: silica mixture application step
S300: silica mixture crystallization step

Claims (10)

A solar cell cell plate 100 in which solar cell cells are collected; And
Located on the upper side of the solar cell cell plate 100 and passes the incident sunlight, a glass layer 230 on which a protrusion 231 having a certain pattern is formed on an upper surface, and an edge of the glass layer 230 It is formed on a solar cell module comprising; a frame 240 surrounding the, and an upper plate 200 including a pollution-preventing texturing layer 210 forming a plurality of protrusions 211 on the surface of the glass layer 230. In the method of forming the anti-pollution texturing layer,
A silica mixture forming step (S100) of forming a silica mixture in which silica particles are mixed;
A silica mixture application step of applying a silica mixture on the surface of the glass layer 230 by spraying (S200); And
Including the silica mixture crystallization step (S300) to crystallize the silica contained on the silica mixture by applying heat to the silica mixture applied in the silica mixture application step (S200);
Crystallization of the silica contained on the silica mixture in the silica mixture crystallization step (S300) is made at 280 to 320 degrees,
In the silica mixture crystallization step (S300), the heat treatment device for applying heat on the silica mixture maintains a separation distance that maintains a constant distance between the heat treatment part 10 for applying heat, and the heat treatment part 10 and the solar cell module. It is made, including the part 20,
The separation distance holding unit 20 includes a base plate 21 to which the heat treatment unit 10 is coupled, and a pair of fixed plates 22 disposed opposite to each other in the longitudinal direction of the base plate 21. , Comprising a connecting plate 23 connecting the fixed plate 22 and a supporting plate 24 in contact with the frame 240 located at the edge of the solar cell module while moving on the connecting bar 23 However, the support plate 24 is characterized in that the step portion 24-1 is coupled to the frame 240 is formed at the end, the anti-pollution texturing layer forming method formed in the solar cell module.
delete delete According to claim 1,
The silica mixture is characterized in that it comprises fine particles of silica and metal ions, a method of forming a pollution-preventing texturing layer formed on a solar cell module.

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