KR100999460B1 - Photo voltaic module with heat radiating sheet formed film layer - Google Patents

Abstract

PURPOSE: A solar power generation module including a heat emitting sheet is provided to maximize the generation amount of solar power by reducing temperature in the solar power generation module through the heat emitting sheet. CONSTITUTION: Front solar ethyl vinyl acetate(EVA)(20) is formed on a glass substrate(10). A solar cell(30) is formed on the front solar EVA. A rear solar EVA(40) is formed on the solar cell. A back sheet is formed on the rear solar EVA. Coating layers(61,62) are formed on either one side or both sides of a heat emitting sheet(60) using a both-sided tape or an adhesive. The heat emitting sheet is selected from a group including aluminum, copper, brass, steel sheet, and stainless steel.

Description

Photovoltaic module with heat dissipation sheet with film layer {Photo Voltaic module with heat radiating sheet formed film layer}

The present invention is a photovoltaic module having a structure in which a heat dissipation sheet having a film layer is attached to a conventional solar power module, using the heat dissipation characteristics increased by the film layer formed on the outer surface of the heat dissipation sheet. Cooling module and its peripheral devices to maximize the amount of photovoltaic power generation, and relates to a photovoltaic module having a heat dissipation sheet having a coating layer, characterized in that the durability of the module for photovoltaic development by the coating layer of the heat dissipation sheet. .

In general, photovoltaic power generation is known to have a relatively high power generation efficiency in a high amount of sunshine, and the current solar power generation business area is also being closely connected to the amount of sunshine.

According to the above theory, the conventional photovoltaic power plant should have high solar power generation in a season when the sunshine peaks, but in reality, as shown in FIG. 1, the sunshine is less than in June when the sunshine peaks. The average solar power generation in April and November is cool, and the average solar power generation is maintained when the surface temperature of the photovoltaic module maintains a high temperature of approximately 60 to 80 ° C in August, when the atmospheric temperature is the highest. Efficiency drops to 12%. That is, as is generally known, the amount or efficiency of generation according to the surface temperature of the photovoltaic module is not significantly affected by the single crystal polysilicon or the polycrystalline silicon photovoltaic module, and the photovoltaic module itself and It can be seen that the heat of the peripheral device has a great effect on the amount of solar power generation.

This fact clearly shows a difference in power generation efficiency of approximately 5 to 10% as shown in seasonal photovoltaic power generation, as shown in FIG. 1. It is shown in the general literature that there is a difference in generation amount of about 5% or more. In other words, under the same sunshine conditions, as the temperature changes in the module and surroundings, the lower the temperature, the greater the amount of power generation. In general, photovoltaic power generation is generally the most efficient in the summer with the highest amount of sunshine. This phenomenon is the same in not only polycrystalline or monocrystalline crystalline silicon solar cells but also thin film solar cells.

As described above, the amount of photovoltaic power generation is greatly influenced by the temperature change of the photovoltaic module and its peripheral device, but a typical photovoltaic module is a glass substrate 10, the front surface as shown in FIG. EVA 20, the solar cell 30, the rear solar EVA (40), the backsheet (Backsheet) 50, the structure of the photovoltaic module having such a structure by utilizing the EVA polymer material The heat generated from the solar module itself and the heat dissipation effect of peripheral devices are low, which is the biggest obstacle to solar power generation.

On the other hand, various techniques have been developed and applied for a solution to solve the problems as described above, as a representative patent in the Republic of Korea Patent Publication No. 10-0867655 as shown in FIG. The solar cell module having the structure in which the cell 120 and the glass plate 130 are mounted, and the insulating material 160 is filled in the space between the solar cell 120 and the bottom surface of the main body 110 is disclosed. . The glass plate 130 in the solar cell module having the structure as described above covers the solar cell 120 serves to protect the cell from being contaminated or damaged, and the heat absorbing plate 170 is exposed. Although the heat generated from the cell 120 is transmitted to cool the cell 120 by the cooling fluid flowing in the cooling pipe 150, the structure is configured to effectively prevent overheating of the cell 120, but the cooling fluid By installing the cooling pipe 150 flowing in the solar module, the weight of the module is not only limited to the installation place of the module, but also the complicated structure of the module is difficult to manufacture, and stores the cooling fluid There were problems such as having to provide a place for installing the tank separately.

In addition, as a patent of a technology having a simple structure that the above problems are complemented, as shown in FIG. 4, Korean Patent Publication No. 2005-0094179, the solar cell 123 in the tempered glass plate 121 and the EVA resin 122 as shown in FIG. And a solar cell module having a heat conduction plate 124 for absorbing and dissipating heat inside the module where the cell 123 is generated on the lower surface of the EVA resin 122. The heat conduction plate 124 having a heat dissipation function is known, and mainly uses materials such as aluminum, copper, tin, stainless steel, etc. Corrosion may occur to the inside of the metal material of the heat conduction plate attached to the light emitting module, which may cause problems of deterioration of heat dissipation and durability of the heat conduction plate.

As such, the current solar module is made of materials with high moisture resistance. The reason is that the crystalline polysilicon is very weak to moisture, and when it comes into contact with moisture, it turns into silica due to whitening phenomenon, which causes the loss of the function for photovoltaic generation, and even in the case of a metallic material sheet having a heat dissipation function, high temperature and high humidity. As the inside of the metallic material is easily corroded by moisture in one region, a measure for securing the durability of a high life span of 20 years or more is urgently required in one installation.

The present invention is intended to suggest a direction to maximize the power generation efficiency of the module by lowering the temperature inside the module by lowering the heat of the photovoltaic module and its peripherals through the heat dissipation function of the heat dissipation sheet having a film layer formed.

Therefore, the present invention is a module for photovoltaic generation using a double-sided adhesive tape or adhesive having heat and thermal conductivity as a structure for bonding a heat dissipation sheet having a direct film layer formed on the outer surface of a backsheet of a conventional photovoltaic module. As the film layer is formed, the heat dissipation effect is superior to the sheet using a single metal plate, which improves the efficiency of solar power generation, and also prevents corrosion by the film layer of the heat dissipation sheet, thereby improving the durability of the module and adding new An object of the present invention is to provide a photovoltaic module having a heat dissipation sheet, which is characterized in that a module can be manufactured using only existing basic equipment and processes without requiring equipment.

And the present invention, unlike the photovoltaic module having a structure defined above, remove the backsheet (backsheet) in the existing photovoltaic module, attaching a heat-radiating sheet formed directly on the back layer EVA film As a solar photovoltaic module with a structure, the temperature inside the module is lowered by the heat dissipation effect of the heat dissipation sheet, maximizing the power generation efficiency of the existing module, and also preventing the corrosion by the coating layer of the heat dissipation sheet, thereby improving the durability of the module. Another object of the present invention is to provide a solar power module having a heat dissipation sheet, which is characterized in that the structure is simplified to lower the manufacturing cost.

As described above, the present invention selects one of the conventional surface treatment methods such as anodizing, chemical coating, or plating on both sides of the heat dissipating sheet or on the opposite side of the back contacting EVA or backsheet. By forming the film, the film layer formed on the outer surface of the heat dissipation sheet causes a difference from thermal effects such as thermal conductivity and emissivity of the base material due to the crystalline or constituents of the fine particles formed inside the film layer or the formed film. The difference is that the heat flow flows in a certain direction, resulting in higher heat dissipation effect, and improved physical properties such as durability, corrosion resistance, and moisture resistance of the heat dissipation sheet to extend the service life of the solar module. to be.

In the present invention for achieving the above object in the solar power module,

The photovoltaic module is a laminated structure in order of the glass substrate 10, the front solar EVA (20), the solar cell (30), the rear solar EVA (40), the backsheet (50),

An aspect of the invention provided with a heat dissipation sheet having a film layer formed thereon, wherein the heat dissipation sheet 60 having a film layer formed thereon is attached to the outside of the backsheet 50 using a double-sided adhesive tape or an adhesive 55. A module for light generation is used as a means for solving the problem.

And the present invention in the solar module,

Heat dissipation sheet having a film layer, characterized in that the laminated structure of the glass substrate 10, the front surface of the EVA (20), the solar cell 30, the rear surface of the EVA (40) and the heat radiation sheet 60 formed with a coating layer The solar photovoltaic module provided with another means for solving the problem.

However, the heat dissipation sheet 60 is a material having excellent thermal conductivity, it is preferable to use one of aluminum, copper, brass, steel, stainless steel, and a metal sheet having an emissivity performance equivalent to or higher than these materials,

In addition, the coating layer may be selected from a conventional surface treatment method such as anodization, chemical conversion, or plating, or may be one of physical methods such as surface pore using laser, roughness (roughness), and dissimilar metal bonding. Selectively, one or both sides of the heat dissipation sheet is treated to form a coating layer.

The present invention by the above-described problem solving means is a module for solar cells of the structure to which the heat dissipation sheet with a film layer was bonded by modifying the existing solar cell module, the film layer formed on both sides or one side of the heat dissipation sheet Due to the crystalline or constituents of the fine particles formed inside or the formed film, there is a difference from the thermal effects such as the thermal conductivity and emissivity of the base material. This thermal difference causes the heat flow to flow in a constant direction. As the temperature inside the module decreases due to the cooling effect of the photovoltaic module and its peripheral devices, the power generation and power generation efficiency are maximized through the module with the heat dissipation sheet, and as the heat dissipation sheet is applied to the photovoltaic module Regardless of the existing surface temperature change, the change in power generation can be maintained at a constant level. 3 ~ 5% increase in total quantity and 5 ~ 10% generation effect in summer. In addition, there is an advantage that can be secured in various applications by applying the same in the cold or hot and humid tropical climate zone, desert area.

In addition, the module for solar photovoltaic according to the present invention is applicable to not only a new module but also an existing produced module itself, which is an advantage that the structure can be manufactured under the same process conditions without changing existing equipment.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail with reference to Figures 5 to 9, in the detailed description and the accompanying drawings a configuration that can be easily understood by those skilled in the field related to the photovoltaic industry Detailed descriptions of components and operations not directly related to the technical features of the present invention have been omitted.

Figure 5 is an embodiment according to the present invention, a cross-sectional structure of a photovoltaic module for bonding a heat radiation sheet using a double-sided adhesive tape to the back sheet, Figure 6 is another embodiment according to the present invention, It is related with the figure which showed the cross-sectional structure of the photovoltaic module which removed the back sheet and bonded the heat radiating sheet.

In accordance with an embodiment of the present invention, as shown in FIG.

The photovoltaic module is a laminated structure in order of the glass substrate 10, the front solar EVA (20), the solar cell (30), the rear solar EVA (40), the backsheet (50),

Solar light having a heat radiation sheet having a film layer formed on the outside of the backsheet (50), characterized in that the structure is attached to the heat dissipation sheet 60 formed on the film layer using a double-sided adhesive tape or adhesive (55). It relates to a power generation module (hereinafter referred to as "attachable module").

A typical solar photovoltaic module is a glass substrate 10, front surface EVA (20), solar cell (30), rear surface EVA (40), backsheet (50) as shown in FIG. Has a laminated structure, and thus the backsheet 50 itself made of a fluorine resin material serves to lower the heat dissipation or heat transfer function.

In addition, the existing photovoltaic module production process is not easy to change the process or the material because each material at the same time using a vacuum compression heat bonding method.

Therefore, the attachable module according to the present invention is characterized in that it is a simple structure that can produce a solar power module having a heat dissipation function through a simple process by adhering a thin film heat dissipation sheet to the final product of the solar power module.

In addition, the attachable module uses a double-sided adhesive tape or adhesive having heat and thermal conductivity on the outer surface of the back sheet 50 to bond the heat dissipation sheet directly to the back sheet of the fluororesin material. The heat storage accumulated in the) is transferred to the heat dissipation sheet through both the surface adhesive tape or the adhesive layer to dissipate heat to the outside to cool the heat of the solar module and the peripheral device.

Double-sided adhesive tape usable in the present invention is a double-sided adhesive tape having a heat-resistant and heat conductive function, the general type of double-sided tape on the market can be applied, and the adhesive is also an adhesive having a heat and heat conductive function All cases are applicable.

Specific examples of such products include 3M's heat resistant silicone tape, ceramic (metal) adhesive, epoxy adhesive, structural heat resistant tape, and the like. A spray adhesive, a spray adhesive of Woofu Corporation, and the heat-resistant adhesive for gaskets of Ulpoca Corporation are mentioned.

Attachable module having the structure as described above according to the present invention by attaching a heat radiation sheet on the outer surface of the backsheet (Backsheet) the ambient temperature of the module for solar cells is up to 10 compared to the ambient temperature of the conventional solar module It could be obtained through the experiment to fall in and out of ℃.

The back sheet attachment type module according to the present invention is a situation in which the intense price competition is beginning in the market of the photovoltaic module industry. Therefore, the unit price of the heat dissipation sheet using the adhesive may be more expensive than the conventional photovoltaic module. Because it is not present, it is desirable to apply it only to premium products of 220W class.

And another embodiment according to the present invention in the solar module, as shown in Figure 6,

Heat dissipation sheet having a film layer, characterized in that the laminated structure of the glass substrate 10, the front surface of the EVA (20), the solar cell 30, the rear surface of the EVA (40) and the heat radiation sheet 60 formed with a coating layer It relates to a photovoltaic module having a (hereinafter referred to as "alternative sheet module").

As shown in FIG. 6, the replacement sheet type module having the above structure removes the existing back sheet 50 from the structure of the conventional solar module and replaces the heat dissipation sheet 60 instead of the back sheet 50. As a structure, all the work is done in the basic equipment and process for manufacturing solar photovoltaic, which eliminates the need for additional equipment, thus reducing the work process and price competition and process improvement can be achieved at the same time. As the polymer type backsheet 50 is removed, the module can be improved so that heat dissipation is performed more smoothly.

In the case of the alternative module as described above has a heat dissipation effect of about 10 ℃ compared to the conventional module for photovoltaic generation, in the case of the alternative module, the heat dissipation effect is increased by 1.5 times or more compared to the attached module about 15 ℃ or more It brings the effect of lowering the surface temperature of the solar module.

The heat dissipation effect as described above is a result obtained by applying only the heat dissipation sheet to the pure solar module without considering the heat transfer efficiency of the back-side EVA.

In the present invention, the heat dissipation sheet 60 used in the attachment type module and the replacement sheet type module forms heat conductive coating layers 61 and 62 on both or one side of the surface thereof, thereby increasing the heat dissipation effect and increasing moisture resistance and resistance. Corrosion, durability, heat resistance, solvent resistance has the advantage that can be enhanced.

In the present invention, the thin plate of the heat dissipation sheet used in the attachment type module or the replacement sheet type module is a material having excellent thermal conductivity, and is one of aluminium, copper, brass, steel, stainless steel, and metals having emissivity performance equivalent to or higher than those of such materials. Or it is preferable to use more than that, and considering the price of the material, the thermal conductivity, etc. comprehensively considering the copper thermal conductivity relative to the price of the raw material is about 2 times higher than the thermal conductivity of aluminum, it is most preferable to use the same material.

In addition, the heat dissipation sheet 60 used in the attachable module and the replacement sheet type module has a surface treated on one side to form a coating layer 62, and the opposite side bonded to the EVA resin improves the adhesion between the heat dissipation sheet and the EVA resin. In order to change the surface roughness of the sanding, grinding and the like depending on the material, the bonding property is further improved.

In the present invention, it is preferable that the heat dissipation sheet 60 is formed by coating one or both surfaces of the heat dissipation sheet by selecting one method from a conventional surface treatment method such as anodizing, chemical coating, or plating. .

At this time, the coating layer 62 formed on one side of the heat dissipation sheet is formed on the heat dissipation sheet on the opposite side of the surface bonded to the EVA resin.

For reference, FIGS. 5A and 6C illustrate that the coating layers 61 and 62 are formed on both sides of the heat dissipation sheet 60, and FIGS. 5B and 6D show one side of the heat dissipation sheet. The formation of the coating layer 62 to be formed is shown.

In detail, the surface treatment method is anodizing, and an anodizing method forms an oxide film on the surface of the heat-radiating sheet metal to form a kind of ceramic thin film. Due to the crystalline or constituents of the fine particles formed on the film or the formed film, a difference from the thermal effects such as the thermal conductivity and the emissivity of the base material occurs. This thermal difference causes the flow of heat to flow in a constant direction. There are advantages to be made.

In general, the chemical coating method is a surface treatment method in which the surface of the metal is ceramicized by chemically coating the surface of the metal, and there are phosphate coating and chromate coating. Phosphate coating method (electrolytic method, electroless method) can be found to be able to control the thickness, excellent paintability, excellent corrosion resistance and have a beautiful surface. In addition, the most representative of the chemical conversion treatment of the metal surface is the chromate coating method, in addition to the inorganic chemical conversion coating method has the advantage that the heat dissipation effect can be excellent through the ceramicization of the metal surface.

In addition, the plating method is the most commonly used surface coating method for coating other metals, homogeneous metals, alloys, etc. on the metal surface.The plating method is electroless plating, electrolytic plating, strike plating, spray coating, vacuum deposition, thermal deposition, Spray coating method, heterogeneous and homogeneous metal plating method. All of these plating methods can maximize the emissivity by treating the surface through the bonding of dissimilar metal to the surface. Therefore, the desired emissivity can be adjusted, it is also suitable for using a heat radiation sheet.

In addition, the coating layer of the heat dissipation sheet according to the present invention may form a coating layer by selecting one of physical methods such as surface pore method using laser, roughness (roughness) method, and dissimilar metal bonding method.

Module for photovoltaic generation according to the present invention, the thickness of the material constituting each layer, that is, the thickness of the glass substrate 10, the front solar EVA (20), the solar cell (30), the rear solar EVA (40), respectively It is preferably 1 to 5 mm, 0.1 to 2 mm, 0.15 to 0.3 mm, 0.1 to 2 mm, and the thickness of each material is not necessarily limited to the above-mentioned thickness, but according to the needs of consumers or the needs of manufacturers. Can be adjusted accordingly.

In the present invention, the thickness of the coating layer formed on the surface of the heat dissipation sheet 60 is such as to increase the physical properties such as durability, corrosion resistance, moisture resistance, etc. of the heat dissipation sheet. In the case of the oxidation method, it is preferable to form a coating layer of 5 to 100 µm, 20 to 1000 µm for the chemical conversion method and 10 to 50 µm for the plating method, and the thickness of the coating layer is necessarily limited within the above range. It may be adjusted appropriately as necessary.

For reference, each component material used in the photovoltaic module according to the present invention typically uses the same material as the material used in the conventional photovoltaic module, and briefly describes each component constituting the photovoltaic module. The description is as follows.

In the present invention, as a substrate for injecting sunlight into the solar cell 30 and protecting the solar cell 30, it is preferable to use a transparent or translucent tempered glass substrate or a synthetic resin substrate, and typically, glass More preferably, the substrate 10 is used.

In addition, the front or rear solar EVA (20) 40 is located on the front and rear surfaces of the solar cell 30 as an essential material for maintaining the lifespan of the solar module for 20 to 30 years, thereby preventing damage to the solar cell 30. As a protective layer that serves as a cushioning material to prevent, it serves as an adhesive for bonding the glass substrate 10 and the back sheet 50, which are parts to be bonded to the solar cell 30. Solar EVA 20, 40 used in the protective layer in the present invention is used as a form of a sheet, the material may be selected from among EVA, EEA, fluorocarbon resin or resin having a performance equivalent to or higher.

In addition, the solar cell 30 is a semiconductor device that converts light into electricity. The minimum unit is called a cell, and since the voltage from one cell is usually 0.5 to 0.6 V, the voltage is very small. Modules are manufactured in the form of panels that can be connected in series to obtain voltages from several volts to several hundreds of volts.

In addition, the backsheet (50) is located on the back of the solar module, a layer that serves to protect the solar cell 30 from the outside environment by preventing moisture penetrating from the back, mainly fluorine resin Is used.

Conventional photovoltaic modules consisting of such parts are laminated by laminating the parts and then vacuum-compressed by a laminator by a conventional method, and then the edge of the photovoltaic module is aluminum by a conventional method. It is manufactured so that it can withstand external shocks and have waterproofness by finishing with a finish.

Hereinafter, the configuration of the present invention will be described in more detail based on the following examples, but the present invention is not necessarily limited only to the following examples.

1. Fabrication of heat dissipation effect measuring equipment for photovoltaic module

As shown in the photo of Figure 7, the facility for measuring the heat dissipation effect of the module for photovoltaic generation is a self-produced facility, installed two solar modules for the acrylic chamber, the surface temperature of the acrylic chamber It is equipped with a surface measuring thermometer to measure, an internal thermometer to measure the temperature inside the acrylic chamber, and a sensed temperature measuring instrument for measuring the temperature of the surface of two solar modules.

For reference, Figure 7 is a photograph taken a facility for measuring the heat radiation effect.

The heat dissipation effect measuring equipment of the solar power module having the structure as described above is a facility having the structure as shown in the photograph of FIG. 7, so that the power generation amount, voltage, and current can be simultaneously measured using the solar module efficiency device. It is designed to control the internal temperature, and the measuring equipment used in the present invention is a surface temperature measuring apparatus at an experimental level.

2. Fabrication of solar photovoltaic module with heat dissipation function

Example 1 Fabrication of Attachable Module

Glass substrate 10, front surface EVA (20), solar cell (30), rear surface EVA (40), backsheet (Backsheet) 50, double-sided adhesive tape (55) and the heat radiation sheet formed with a coating layer (60) Attached modules having a stacked structure in the order of) were manufactured.

And the thickness of the glass substrate 10, the front surface EVA (20), the front cell 30, the back surface EVA (40), the back sheet 50 and the heat radiation sheet 60 in the module of Example 1 are each 2 ± 0.1 mm, 1.5 ± 0.1 mm, 0.2 ± 0.05 mm, 1.5 ± 0.1 mm, 0.3 ± 0.1 mm, 0.3 ± 0.1 mm.

In addition, the heat dissipation sheet material used in Example 1 is an aluminum thin film, the backsheet material is fluorine resin, and the thickness of the coating layer formed on both sides of the heat dissipation sheet is 50 ± 10 μm in the case of anodizing, and In the coating method, a coating layer was formed at 500 ± 50 μm, in the chromate treatment method at 20 ± 5 μm and in the plating method at 20 ± 5 μm, respectively.

Example 2 Fabrication of Replacement Sheet Module

An alternative sheet type module having a laminated structure was formed in order of the glass substrate 10, the front solar EVA 20, the solar cell 30, the rear solar EVA 40, and the heat dissipation sheet 60 formed with the coating layer.

And the thickness of the glass substrate 10, the front solar EVA 20, the solar cell 30, the rear solar EVA 40 and the heat dissipation sheet 60 in the module of the second embodiment is the same as the first embodiment Applied.

In addition, the material of the heat dissipation sheet and the backsheet used in Example 2 was the same as that of Example 2, and the thickness of the film layer formed on both sides of the heat dissipation sheet by the anodizing method and the chemical coating method was also used. The same conditions as 1 were applied.

Comparative Example 1 Fabrication of Existing Structure

The solar cell substrate 10, the front solar EVA (20), the solar cell (30), the rear solar EVA (40) and the heat dissipation sheet 60 made of a conventional solar module for producing a first embodiment and Used as a control for comparison with the module of Example 2.

And the thickness of each laminated material of the module of Comparative Example 1 was applied to the thickness of the same condition as the thickness defined in the above embodiment, the material of the heat dissipation sheet used in Comparative Example 1 uses an aluminum thin film without a coating layer It was.

3. Heat dissipation effect by heat dissipation sheet material and surface treatment

The heat dissipation sheet 60 applied to the first and second embodiments using the heat dissipation effect measuring equipment of the solar power generation module having the structure as described above in 1 is a film as shown in Table 1 below. Using the treated material, the surface temperature of the module was measured during the day (9 to 5 o'clock) for 2 days by selecting sunny days from March to April, and then by the relative temperature difference for the control module. The results of the average value converted from the heat dissipation effect are shown in Table 1 below.

Surface treatment technique Material Heat dissipation effect Remarks Attachment
module Alternative sheet type
module Anodization
(Anodizing) Aluminum thin film ● ●
Heat treated sheet without surface
Attachment Module and Heat Sink Not Attached
Temperature relative to the module
Assessment of change

1) Evaluation result
Very good (●)-Above 15 ℃
Good (○)-10 ~ -14 ℃
Medium (△)-5 ~ -10 ℃
Poor (×)-below 5 ℃

2) Measuring temperature range
Normal temperature-90 degrees Celsius Steel Plate (CR Material) ○ ○ stainless ○ ○ copper ● ● Brass plate ● ● Chemical coating method
(Phosphate coating) Aluminum thin film ● ● Steel Plate (CR Material) ● ● stainless ○ ○ copper ● ● Brass plate ● ● Chemical coating method
(Chromate processing) Aluminum thin film ● ● Steel Plate (CR Material) ○ ○ stainless ○ ○ copper ● ● Brass plate ● ● Plating method
(Ni electroless) Aluminum thin film ● ● Steel Plate (CR Material) ○ ○ stainless ○ ○ copper ○ ○ Brass plate ○ ○

As a material of the heat dissipation sheet, as shown in Table 1, the surface of aluminum thin film, steel plate, stainless steel, copper plate, brass plate was applied to both the attachment module of Example 1 and the replacement module of Example 2 All of the above materials could be confirmed to be suitable materials for use in the thermal radiation sheet for solar modules.

4. Measurement of heat dissipation effect of module for solar power generation

The surface temperature of the photovoltaic modules of Examples 1 and 2 according to the present invention is clear in April, using Comparative Example 1 as a control module, which is a conventional photovoltaic module having a structure defined in 2 above. The results of the average value of the heat dissipation effect based on the relative temperature difference for the control module were measured after 10 days each day (9 to 5 o'clock) after selecting the day. The results are shown in Table 2 below.

(Unit: ℃) division Example Comparative example Remarks One 2 One a) anodization -13 to -17 -15 to -20 -5 to -10 Module reference temperature
20 ~ 90 ℃ b) phosphorylation coating method -10 to -15 -13 to -15 c) chromate treatment -8 to-12 -9 to 14 d) Plating method (copper plating) -9 to-13 -10 to 15

According to the contents of [Table 2], in the case of Example 1 and Example 2, all of the methods treated by the method of a) to d) showed better heat dissipation effect than Comparative Example 1.

In addition, Example 2, which is a module that removes the backsheet and replaces the heat-dissipating sheet having a film layer, is an attachable module in which a heat-dissipating sheet is formed by using a double-sided adhesive tape on the outer surface of the backsheet. It can be seen that the heat dissipation effect is higher than in Example 1.

That is, in the case of the attachable module according to the first embodiment, even though the heat conductive property of the backsheet, which is a fluorine resin material, is degraded, even if the heat dissipation sheet is attached to the outer surface of the backsheet, the heat dissipates directly to the back surface EVA 40. Compared to the alternative module of Example 2 with the sheet attached, it could be confirmed by the above example that the temperature falls further up to 10 ° C.

In addition, in the case of Examples 1 and 2, although the thickness of the coating layer by the anodizing method was about 1/10 thinner than the thickness of the coating layer by the anodizing method, the module which formed the coating layer by the anodizing method The heat dissipation effect was found to be better than that of the module on which the coating layer was formed. As a result, it was found that the oxide film formed by oxidizing the metal on the surface has an excellent heat dissipation effect as compared to the compound type film composed of the general chemical film.

In the case of the plating method, it was confirmed that the heat dissipation effect is lower than that of the coating layer formed by the anodizing method or the phosphorylated coating method.

For reference, FIG. 8 is a view of Comparative Example 1, which is a conventional solar module having a heat dissipation sheet, and Example 1, which is an attachable module to which a heat dissipation sheet is formed according to the present invention, and an alternative module. The graph shows the average value of the temperature change with the surface temperature of the module over time for the light emitting module. The surface temperature of Comparative Example 1, which is a conventional module with a heat dissipation sheet, is the highest, It can be seen that the surface temperature of Example 1, which is an attached module to which a heat dissipation sheet is attached, is the next highest, and the surface temperature of Example 1, which is an alternative sheet type module to which the back sheet is removed and the heat dissipation sheet is applied, is the lowest.

5. Measurement of the amount of power generated by the heat dissipation effect of the monthly photovoltaic module

The result of measuring the amount of power generation according to the monthly heat dissipation effect using the solar power module of Example 2 according to the present invention is as shown in the graph shown in FIG.

As a result of preparing for the generation amount and efficiency of the module of Example 2 and the general solar module without applying the heat dissipation sheet, Example 2 is equivalent to the conventional amount of photovoltaic generation in April and November, when the temperature is cool. In particular, in August, when the temperature is high, the surface temperature of the conventional general photovoltaic module is 87.5 ° C, and the photovoltaic efficiency is 12% as shown in the graph shown in FIG. In the case of the module of Example 2, the heat dissipation sheet is applied to the module, but the temperature of the surface of the module is only up to 65.8 ° C, and the efficiency of solar power generation is improved to 16%, as shown in the graph shown in FIG. It was found.

For reference, the actual amount of monthly power measured for a general photovoltaic module without applying the module and the heat dissipation sheet of Example 2 is as described in the following [Table 3] and [Table 4].

Generation of fixed modules division General solar module
(No heat sheet applied) Example 2 monthly/
compare Total power generation
(kW) Daily average
Power generation (kW) efficiency(%) Total power generation
(kW) Daily average
Power generation (kW) efficiency(%) January 219.73 7.32 13.1% 242.92 7.83 14.8 February 233.25 7.77 14.5% 254.21 8.47 15.7 In March 251.85 8.12 15.6% 269.47 8.69 16.7 April 271.87 9.06 16.9% 275.18 9.17 17.0 In May 266.44 8.85 16.5 266.11 8.58 16.5 June 244.52 8.15 15.2 267.21 8.90 16.6 In July 212.79 6.86 12.9 265.47 8.83 16.4 August 199.59 6.43 12.1 260.27 8.39 16.2 September 222.68 7.42 13.5 266.92 8.89 16.5 October 243.34 7.82 14.8 268.31 8.65 16.7 November 261.42 8.71 15.9 271.53 9.05 16.9 December 245.12 7.90 14.9 242.32 7.81 15.1

  * Taean area, measured in 2008.

 Comparison of generation amount of tracked module compare General solar module
(No heat sheet applied) Example 2 monthly/
compare Total power generation
(kW) Daily average
Power generation (kW) efficiency(%) Total power generation
(kW) Daily average
Power generation (kW) efficiency(%) January 243.57 8.12 15.07 265.49 8.85 16.42 February 269.60 8.98 16.68 293.87 9.79 18.18 In March 290.05 9.67 17.94 319.06 10.63 19.73 April 306.03 10.20 18.93 339.69 11.32 21.01 In May 298.79 9.96 18.48 325.68 10.85 20.14 June 275.24 9.17 17.02 302.77 10.09 18.73 In July 239.85 7.99 14.84 287.82 9.59 17.80 August 224.98 7.50 13.92 281.22 9.37 17.39 September 251.01 8.36 15.53 313.76 10.46 19.41 October 275.18 9.17 17.02 308.20 10.27 19.06 November 295.63 9.85 18.29 331.11 11.03 20.48 December 269.81 8.99 16.69 296.52 9.88 18.34

  * Taean area, 2008 measurement

Therefore, as confirmed in Example 2, it can be seen that the amount of photovoltaic power generation has a great influence on the amount of photovoltaic power generated by the photovoltaic module itself and peripheral devices.

For reference, Figure 9 relates to a graph showing the efficiency of the power generation according to the monthly standard heat dissipation effect of the solar module according to the present invention.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention described in the claims below. It will be appreciated.

       1 is a graph showing the amount of photovoltaic power generation according to the amount of sunshine per month by a conventional photovoltaic module,

2 is a view showing a cross-sectional structure of a conventional photovoltaic module,

3 is a view showing a cross-sectional structure of a conventional solar module for solar,

4 is a view showing a cross-sectional structure of another conventional solar module for solar,

Figure 5 is an embodiment according to the present invention, a cross-sectional structure of a photovoltaic module for bonding a heat dissipation sheet using a double-sided adhesive tape to the backsheet (Backsheet),

6 is a view showing a cross-sectional structure of a solar module for removing the backsheet and bonding the heat dissipation sheet as another embodiment according to the present invention;

7 is a photograph taken a facility for measuring the heat dissipation effect,

8 is a graph showing the average value of the temperature change between the surface temperature of the conventional module for photovoltaic generation having a heat dissipation sheet and the attached module and the replaceable module in which the coating layer is formed,

Figure 9 relates to a graph showing the efficiency of the power generation according to the monthly standard heat dissipation effect of the solar module according to the present invention.

Explanation of symbols on the main parts of the drawings

10: glass substrate 20: front shoot EVA

30: solar cell 40: rear solar EVA

50 backsheet 55 double-sided adhesive tape or adhesive

60: heat dissipation sheet 61, 62: film layer

Claims (5)

In the solar module, The photovoltaic module is a laminated structure in order of the glass substrate 10, the front solar EVA (20), the solar cell (30), the rear solar EVA (40), the backsheet (50), On the outside of the backsheet (Backsheet) 50 is a structure in which a heat-dissipating sheet 60 is formed by using a double-sided adhesive tape or adhesive 55 to form a coating layer, And the heat dissipation sheet 60 is used to select one of aluminum, copper, brass, steel plate, stainless steel metal sheet, The coating layer may be selected from a conventional surface treatment method such as anodization, chemical conversion, or plating, or may be selected from physical treatment methods such as surface pore using laser, using roughness, and dissimilar metal bonding. Process one or both sides of the heat dissipation sheet to form a coating layer, The thickness of the coating layer is 5 ~ 100 ㎛ in the case of the anodizing method, 20 ~ 1000 ㎛ in the case of the chemical coating method, 10 ~ 50 ㎛ in the plating method is provided with a heat radiation sheet having a coating layer, characterized in that formed One solar module. In the solar module, The glass substrate 10, the front solar EVA (20), the solar cell 30, the rear solar EVA (40) and the heat-dissipating sheet (60) formed with the coating layer is laminated in order. And the heat dissipation sheet 60 is used to select one of aluminum, copper, brass, steel sheet, stainless steel metal sheet, The coating layer may be selected from a conventional surface treatment method such as anodization, chemical conversion, or plating, or may be selected from physical treatment methods such as surface pore using laser, using roughness, and dissimilar metal bonding. Process one or both sides of the heat dissipation sheet to form a coating layer, The thickness of the coating layer is 5 ~ 100 ㎛ in the case of the anodizing method, 20 ~ 1000 ㎛ in the case of the chemical coating method, 10 ~ 50 ㎛ in the plating method is provided with a heat radiation sheet having a coating layer, characterized in that formed One solar module. delete delete delete

Images