KR20130047876A - Solar power unit - Google Patents

Abstract

PURPOSE: A photovoltaic power generation apparatus is provided to protect a solar cell module from an external shock by forming a separate glass cover in the upper part of the solar cell module. CONSTITUTION: A housing member(12) has a space for forming vacuum. A projection part(24) is formed in the opened upper surface of the housing member. A support part(14) is formed in the bottom of the hollow part(13) of the housing member and supports the lower surface of a solar cell module(20). A glass cover(31) is adhered to the inner side of the projection part without a gap. The solar cell module is installed to the lower part of the glass cover to produce electricity.

Description

Photovoltaic devices

The present invention relates to a photovoltaic device, and more particularly, by combining a solar cell module with a rigid housing member, excellent shock resistance and durability that can withstand waterproofing, moisture-proof function and wind pressure, and excellent durability. It is easy to separate the cell, and converts solar energy into electrical energy to produce electricity and relates to an environmentally friendly solar power generation device.

Recently, due to global warming and climate change, regulations are being enforced around the world to suppress the emission of carbon dioxide. Therefore, development of new power generation equipment without carbon dioxide emission is required.

There is no emission of carbon dioxide, and as a power generation device using clean energy, a solar power generation device is typical, and in recent years, the development and installation cost of the technology has become more and more widespread. There are many types of photovoltaic devices. The general solar cell module has a structure in which a solar cell is positioned between a cover glass and an insulator, and a filler is filled between the cover glass and the insulator and subjected to compression molding at a high temperature. Is completed.

However, the filler reduces the solar transmittance of the solar cell module, and furthermore, after a certain time, a yellowing phenomenon is inevitably generated in the filler, resulting in shortening the life of the solar cell module. In addition, before high temperature pressing, each component constituting the solar cell module is easily separated by maintaining the form of raw subsidiary materials, whereas after high temperature pressing, each component is integrated with a filler and is disposed of at the end of its life. It is impossible to separate and collect each component, and even if a defect occurs in the manufacturing process of the solar cell module, since it is difficult to separate, there is a problem that is difficult to repair.

In addition, conventionally, if the glass cover located on the front of the solar cell module is damaged, there was a problem that the entire solar cell module can not be used.

In addition, the conventional solar cell module in the desert due to the problem of damage to the backsheet (backsheet) of the synthetic resin material on the back of the solar cell module due to the sand storm conditions are a lot of constraints in the photovoltaic power generation in the desert,

In addition, the conventional solar cell module has a limitation in installing in the water due to problems such as a short circuit due to moisture, waterproof, etc. when installed in the water, such as lakes, seas, dams.

In addition, the solar cell module used in conventional solar power generation is required to be installed in the blind area of the herbal field and used for impact resistance and durability capable of withstanding a long life of about 25 years and changes in the natural environment of adverse conditions. However, there are various reasons that the conventional solar cell module loses its efficiency. Among them, dust or foreign matter accumulates on the glass of the solar cell module glass, and there is a reason to physically prevent solar transmission, thereby decreasing efficiency. Although it is necessary to clean the foreign matter artificially, the most serious reason for the efficiency decrease and the short lifespan are many cases in which heat or moisture is generated when the electrode is rusted due to air or moisture penetration into the solar cell module. That is, even if only one of about 60 solar cells shows this phenomenon, the entire solar cell connected in series follows the efficiency of this one sheet.

In addition, the solar cell module must have a very solid structure because it must withstand the harsh environment due to the wind pressure of about 280kg, the current solar cell module has a problem that is vulnerable to the structure to properly withstand moisture and wind pressure.

An object of the present invention is to solve the above-mentioned problems of the prior art, the solar cell apparatus has a waterproof and moisture-proof function as well as a structure that can withstand the wind pressure, and maintain the mutual separation space on the upper part of the solar cell module In addition, the glass cover can protect the solar cell module safely, prevent the yellowing of the solar cell, facilitate the separation of raw materials of each solar cell module, and produce electricity from the solar cell module. It is to provide a photovoltaic device.

The solar cell apparatus according to the present invention for achieving the above object is made of a waterproof, moisture-proof and wind pressure-resistant structure, having a stepped portion inward, and a housing member having a hollow portion formed of a space of a certain depth groove and A support part formed on the bottom of the hollow part to support the lower surface of the solar cell module;

A glass cover disposed on the inner circumferential surface of the stepped portion and sealed and installed without a gap;

It is installed under the glass cover and includes a solar cell module for producing electricity by receiving sunlight.

The solar cell module may include a first substrate made of a transparent material, a second substrate made of an insulating material, and the first substrate and the second substrate are joined by a bonding material formed at an edge of the solar cell. The solar cell may not be formed of the bonding material.

The first substrate and the second substrate may be formed while maintaining a space apart from each other.

In addition, a bonding material for separation may be disposed at a portion excluding the solar cell between the first substrate and the second substrate.

A plurality of perforations may be formed on the first substrate.

In addition, a plurality of perforations may be formed on the second substrate.

And, the transparent material of the glass cover may use a multilayer glass.

In addition, a protective film may be further laminated on the transparent material of the glass cover.

In addition, a lens for condensing or refracting sunlight may be stacked on a transparent material of the glass cover.

The support portion may be integrally formed in the concave-convex shape on the lower surface of the housing member.

The support portion may be configured separately from the housing member and coupled to the lower surface of the housing member.

The hollow portion may include a valve for injecting, discharging or cleaning the inside of the vacuum forming and inert gas on one surface thereof.

An inert gas may be filled in the hollow part.

The hollow part may be vacuum molded.

In addition, a hole through which a power line penetrates is formed on one surface of the hollow part, and the hole may be provided with a waterproof connector for blocking air or moisture or water from flowing into the hollow part.

The housing member may include a flange portion having a predetermined width extending from the outer circumference thereof.

The flange portion may be changed into various shapes such as a flat plate, a circular shape, and a curved surface.

At least one fastening hole for fastening to the photovoltaic device support structure may be formed in the flange portion.

The solar cell apparatus according to the present invention configured as described above is configured with a separate glass cover on the solar cell module to protect the solar cell module from external shocks, and also omit the filler between the solar cell and the glass and the insulator. It significantly reduces the production cost of the solar cell module, improves the transmittance of the solar light to increase the output, and prevents yellowing due to the composition of the filler to increase the life of the solar cell module.

In addition, according to an embodiment of the present invention, it is easy to separate and repair each raw subsidiary material, the repair and repair of the solar cell module is easy, and the separate collection and recovery of the used solar cell is possible, so that each element can be recycled separately It has the effect of saving resources.

In addition, the side and bottom surface of the solar cell module are made of waterproof, moisture-proof function and wind load, and made of hard material against external impact, so that even in the weak environment, the desert, water, polar (North pole, Antarctica) Solar power generation is possible without restriction in places.

In addition, it does not use an expensive aluminum frame coupled to the outer circumferential surface of the existing solar cell module to form a robust structure while reducing material costs and assembly costs.

In addition, it is possible to acquire carbon dioxide emission rights in the future by using an eco-friendly power generation method that does not generate carbon dioxide, and it is also possible to generate new profits by trading the carbon emission rights thus obtained.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. If it is determined that the detailed description of the known technology related to the present invention may obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, embodiments of the solar cell apparatus according to the present invention will be described in detail with reference to the accompanying drawings, in the following description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and Duplicate explanations will be omitted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a structural cross-sectional view of a photovoltaic device according to the present invention, Figure 2 is a perspective view of the photovoltaic device according to the present invention. 3 is a structural cross-sectional view of a solar cell module according to the present invention.

1 to 3, the solar cell apparatus 10 according to the present embodiment includes a housing member 12, a glass cover 31, a hollow part 13, a stepped part 24, and a support part 14. The valve 21, the waterproof connector 18, the flange portion 19, and the solar cell module 20 may be included.

The housing member 12 is a structure in which a hollow part having a space for vacuum molding or a space of a predetermined depth for filling an inert gas is formed therein.

The housing member 12 has an open upper portion, and a stepped portion 24 is formed on the open upper circumferential surface. The stepped portion 24 supports the glass cover 31 and is sealed with an adhesive layer 23. It may be combined, the solar cell module 20 may be installed under the glass cover 31.

In the present embodiment, the stepped part 24 may have a structure having a depth similar to the thickness of the glass cover 20.

The stepped part 24 may be changed into various shapes in a cross-sectional structure such as a right angle shape, an inclined shape, a curved shape, and some uneven shapes.

The solar cell module 20 is a solar cell disposed between a first substrate 25 made of a transparent material and a second substrate 26 made of an insulating material and between the first substrate 25 and the second substrate 26. 27, the first substrate 25 and the second substrate 26 may be combined by a bonding material 30 formed on the edge of the solar cell 27, the solar cell The junction material 30 may not be formed in a space in which the 27 is located, and one surface of the solar cell module 20 is connected to an external power line 16 to supply electricity generated by sunlight to the outside. Electrode terminal 17 is installed to

The solar cell module 20 may be configured by connecting a plurality of solar cells 27 in series.

For example, the plurality of solar cells 27 may be configured by serially connecting the solar cells 27 belonging to the horizontal column or the vertical column in a state in which the plurality of solar cells 27 are arranged so as to be installed in plural numbers at regular intervals. .

The solar cell module 20 may be connected in series or in parallel.

The solar cell 27 may be understood as a solar cell generating electricity, which is generally used, and detailed description thereof will be omitted.

The electrode terminal 17 may be equipped with electronic components according to the voltage, current, and the like output from the solar cell module 20.

In the present embodiment, the solar cell module 20 may form a plurality of perforations 29 on the surface of the first substrate and the second substrate 26, and may not be so.

These perforations 29 may be used as a moving passage of the inert gas 28, it can be expected to the effect of dissipating heat generated from the solar cell 27 quickly.

In addition, the solar cell 27 between the first substrate 25 and the second substrate 26 may block the penetration of moisture or air from the inside and the outside without being integrally heat-sealed with a filler. 13) It will be solved by vacuum forming or filling of inert gas inside.

The first substrate 25 and the second substrate 26 may be formed while maintaining a space apart from each other.

A bonding material 30 for separation may be disposed at a portion excluding the solar cell 27 between the first substrate 25 and the second substrate 26.

The bonding material 30 may be any material having a bonding force in a liquid material or a solid material.

In addition, the transparent material of the glass cover 31 may be made of tempered glass, and there will be no limitation as long as the strength is excellent among synthetic resin materials.

The transparent material of the glass cover 31 may be made of multilayer glass.

The multilayer glass will have an effect of blocking the heat transmitted to the solar cell to some extent.

In addition, the glass cover 31 may be further laminated with a protective film.

In addition, the glass cover 31 may be laminated with a lens for collecting or refracting sunlight.

In the present embodiment, the supporting portion 14 may be integrally formed in the concave-convex shape on the lower surface of the housing member 12 or may be configured to couple the supporting portion 14 separately configured to the lower surface of the inner housing member 12. .

In addition, a plurality of perforation holes may be formed on the surface of the support part 14.

The separate support 14 material may be used a variety of materials, such as metal or synthetic resin material and composite materials, the shape may be changed according to the dimensions or shape of the solar cell module (20).

As an example, the concave-convex shape and the size of the base 14 are not limited.

In addition, the arrangement and number of the base 14 may be changed.

In addition, a flange portion 19 having a predetermined width extending from the outer circumferential surface of the upper portion of the housing member 12 and formed of a flat plate, a circle, a curved surface or the like may be formed. In the present embodiment, the flange portion 19 may be formed with at least one fastening hole 15 for fastening to the photovoltaic device support structure.

The fastening hole 15 may be changed in a shape such as a circle or an ellipse or a right angle in shape thereof.

In addition, the side of the hollow portion 13 inside the housing member 12 is provided with a valve 21 for injection, discharge or cleaning of the vacuum forming and inert gas. The valve 21 penetrates one surface of the hollow part 13 and consists of a pipe or the like, and the position or quantity of the valve 21 can be adjusted.

The valve 21 may use a metal material or a synthetic resin material used for general gas and air injection or fluid injection.

In addition, a hole 22 through which the power line 16 penetrates is formed at a side surface of the hollow part 13 in the housing member 12, and the hole 22 has moisture or water inside the hollow part 13. Waterproof connector 18 may be installed to block the inflow.

The waterproof connector 18 is made of a material made of a water-resistant and dense structure as well as waterproof, as an example, it is possible if the injection molding of a metal or synthetic resin material.

In addition, the hollow part 13 may be vacuum molded in order to block contact of moisture or air through the valve 21.

In addition, the hollow part 13 may be filled with an inert gas 28 to block moisture or air through the valve 21.

Vacuum forming or filling of the inert gas into the hollow portion 13 will be understood as a means for the solar cell 27 to block contact by air or moisture due to the influence of the inside or outside of the hollow portion 13.

In the present embodiment, the inert gas 28 is not limited as long as it is classified as an inert gas such as helum or nitrogen.

The photovoltaic device 10 configured as described above is waterproof in a dense and rigid structure of the housing member 12 even when installed in any place such as desert or polar region (North pole, Antarctica, etc.), sea, lake, river, dam, and ground. Moisture-proof as well as to maintain the wind pressure so as not to affect the efficiency and life of the solar cell module 20 significantly imposes an economic benefit to the photovoltaic power generation business.

In addition, the appearance of the solar cell apparatus 10 of the present invention is not specified, the overall shape is described as a quadrangle as shown in Figure 2, but is not limited to this may be formed in various forms such as circular, elliptic, hemispherical. have.

As described above, the solar cell apparatus according to the present invention has been described with reference to the illustrated drawings, but the present invention is not limited to the above-described embodiments and drawings, and the present invention belongs to the scope of the claims. Of course, various modifications and variations can be made by those skilled in the art.

1 is a cross-sectional view of a photovoltaic device according to the present invention.

2 is a perspective view of a photovoltaic device according to the present invention.

3 is a structural cross-sectional view of a solar cell module of the solar cell apparatus according to the present invention.

<Description of the reference numerals for the main parts of the drawings>

10 solar power device 12 housing member

13 hollow part 14 support part

15 fastening hole 16 power line

17: electrode terminal 18: waterproof connector

20: solar cell module 19: flange

21: valve 22: hole

23: adhesive layer 24: stepped portion

25: first substrate 26; second substrate

27: solar cell 28: inert gas

29: punching hole 30: bonding material

31: glass cover

Claims (18)

It is made of waterproof, moisture-proof and wind pressure-resistant structure from the outside, and has a stepped portion inward, and a housing member having a hollow portion formed with a space of a certain depth, A support part formed on the bottom of the hollow part to support the lower surface of the solar cell module; A glass cover disposed on the inner circumferential surface of the stepped portion and sealed and installed without a gap; The solar cell apparatus is installed under the glass cover and comprises a solar cell module for producing electricity by receiving sunlight The method according to claim 1, The solar cell module may include a first substrate made of a transparent material, a second substrate made of an insulating material, and the first substrate and the second substrate may be attached by a bonding material formed at an edge of the solar cell. It may be, the solar cell is characterized in that the space where the solar cell is located may not be formed of the bonding material. The method according to claim 2, The first substrate and the second substrate is a photovoltaic device characterized in that it can be formed while maintaining a space between each other. The method according to claim 2, The photovoltaic device of claim 1, wherein a bonding material for separation may be disposed at a portion excluding the solar cell between the first substrate and the second substrate. The method according to claim 2, Photovoltaic device, characterized in that a plurality of perforations can be formed on the first substrate The method according to claim 2, Photovoltaic power generation device, characterized in that a plurality of perforations can be formed on the second substrate The method according to claim 1, The transparent material of the glass cover is a photovoltaic device, characterized in that it can use a multi-layer glass The method according to claim 1, Photovoltaic device characterized in that the protective film can be further laminated to the transparent material of the glass cover The method according to claim 1, Photovoltaic device, characterized in that the transparent material of the glass cover may be laminated with a lens for condensing or refracting sunlight The method according to claim 1, The support part is a solar cell apparatus, characterized in that the lower surface of the housing member can be integrally molded in the form of unevenness The method according to claim 1, The support unit is configured separately from the housing member, the solar cell apparatus, characterized in that can be coupled to the housing member lower surface The method according to claim 1, The hollow portion is a solar power generation device, characterized in that the side wall may include a valve for injection, discharge or cleaning the inside of the vacuum forming and inert gas The method according to claim 1, Photovoltaic device characterized in that the inert gas can be filled in the hollow portion The method according to claim 1, The hollow portion is a solar cell apparatus characterized in that the vacuum can be molded The method according to claim 1, A hole through which a power line penetrates is formed on one surface of the hollow portion, and the hole may be provided with a waterproof connector for blocking air or moisture or water from flowing into the hollow portion. The method according to claim 1, The housing member side has a photovoltaic device comprising a flange portion having a predetermined width extending from the outer circumference 18. The method of claim 16, Photovoltaic device, characterized in that the flange portion can be selectively applied in the form of a flat plate or a round, curved surface 18. The method of claim 16, At least one fastening hole is formed in the flange portion for fastening to the solar cell support structure.

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