KR102194268B1 - Rollable hybrid solar cell module device - Google Patents

Abstract

The present invention relates to a composite solar cell module device capable of simultaneously utilizing non-converging power generation (PV) and condensing power generation (CPV), and a composite solar cell module device utilizing both non-converging power generation and condensing power generation at the same time. In the following, a non-condensing type solar cell array, a lower panel in which condensing type solar cells each formed in an empty area of a corner portion of the non-condensing type solar cell are disposed, and formed on an upper side of the lower panel, Rolling means comprising an upper panel on which an optical sheet for transmitting or condensing light is formed, and a support for separating and fixing the upper panel from the lower panel at predetermined intervals, and is formed on the upper panel to rollably drive the optical sheet A rollable composite solar cell module device characterized in that it is provided is a technical gist. Accordingly, an optical system for non-condensing power generation and condensing power generation is continuously formed on a rollable optical sheet and can be easily replaced in response to irradiation conditions of sunlight, thereby providing a solar cell module device capable of high-efficiency power generation.

Description

Rollable hybrid solar cell module device

The present invention relates to a composite solar cell module device capable of simultaneously utilizing non-condensing power generation (PV) and condensing power generation (CPV), and in particular, an optical system for non-condensing power generation and condensing power generation is applied to a rollable optical sheet. The present invention relates to a rollable composite solar cell module device that is continuously formed and can be easily replaced in response to the irradiation condition of solar light and thus can generate high efficiency.

Due to the depletion of fossil fuels, environmental pollution, and global warming, the need to develop new and renewable energy is increasing, and environmentally friendly and infinitely renewable solar cells are drawing attention as the next-generation energy source.

A solar cell is a key device for photovoltaic power generation, and as a device that directly converts solar energy into electric energy using a photovoltaic effect, many studies have been attempted to improve efficiency.

Such solar power generation is divided into non-condensing power generation (PV) and condensing power generation (CPV) according to a condensing method.

Non-condensing type power generation (PV) is manufactured to suit the climate of Korea and is mainly installed and used in a fixed type.However, the fixed type decreases the efficiency as the angle of incidence of sunlight to the solar cell increases, so the difference in sunlight time is large as in Korea. There is a limit to the amount of power generation in the four seasons type area.

In addition, a tracking system can be applied to obtain more high efficiency in the case of non-condensing power generation.The tracking system can improve power production by 50% or more by increasing the use of sunlight compared to the fixed type, but the conversion efficiency of PV modules is condensed III. -As it is lower than that of a group V compound solar cell, there is a limit to significantly increase the amount of power generation.

In CPV, the efficiency of group III-V compound solar cells is twice as high as that of silicon, so its effectiveness is being evaluated in sunny weather in deserts or low-latitude regions with high direct solar radiation, but when the weather is not clear. In many areas and areas where direct sunlight is not maintained, there is an area limitation that decreases its effectiveness.

Research has recently been conducted for high-efficiency power generation regardless of region or weather by supplementing the shortcomings while utilizing the advantages of such non-condensing power generation and condensing power generation.

In particular, it is a technology for a hybrid solar cell module that uses a non-condensing type power generation device and a condensing type power generation device appropriately in the solar cell module and simultaneously utilizing them.

As a technology using a conventional composite solar cell module, there is a "solar cell module with improved power generation efficiency" (registration number 10-1685178).

The prior art relates to a solar cell module in which a condensing type solar cell unit and a non-condensing type solar cell are combinedly installed to generate electricity by sunlight, and the non-condensing type solar cell in a square shape with a cut corner, A cell support panel in which condensing solar cell cells are arranged in a grid form, and a plurality of condensing solar cells installed in each uninstalled area where the cut corners of the non-condensing solar cells arranged in a grid form in the cell support panel are gathered and formed. And a condensing cover including a unit, and a lens unit disposed on the upper part of the solar cell module to condense light to the condensing solar cell unit.

This is to prevent damage to the non-condensing solar cell and improve power generation efficiency by arranging the condensing solar cell unit in an uninstalled area where the cut corners of the non-condensing solar cell are gathered and formed.

However, the prior art has limitations in improving its efficiency because sunlight is received by the same optical system regardless of the amount of direct or scattered light, and in consideration of a condition in which a lot of direct light is generated or a condition in which a lot of scattered light is generated. There is a need to further improve the efficiency by adjusting the optical system of the solar cell module.

In particular, when the irradiation condition of sunlight is close to the scattered light, there is a limit to the efficiency improvement.

The present invention has been conceived by the above necessity, and an object thereof is to provide a rollable hybrid solar cell module device capable of responding to conditions of irradiation of sunlight.

In order to achieve the above object, the present invention provides a composite solar cell module device that simultaneously utilizes non-condensing type power generation and condensing type power generation, comprising: a non-condensing type solar cell array, and a corner portion of the non-condensing type solar cell. A lower panel in which condensing solar cell cells respectively formed in an empty area of the are disposed, an upper panel formed on an upper side of the lower panel and having an optical sheet for transmitting or condensing sunlight, and the upper panel from the lower panel A rollable composite solar cell module device comprising a support spaced apart and fixed at predetermined intervals, and a rolling means formed on the upper panel for rolling the optical sheet is provided.

In addition, in the optical sheet, it is preferable that the non-converging optical portion and the condensing optical portion are continuously formed in different regions.

Here, the condensing optical unit of the optical sheet is implemented in the form of a condensing pattern or a Fresnel lens, and is preferably formed to correspond to the position of the condensing solar electron cell, and the condensing optical unit of the optical sheet includes the condensing pattern or Fresnel. It is preferable that a plurality of condensing optical units different in the shape, size and number of lens shapes are continuously formed in different regions.

In addition, the rolling means is implemented by rollers respectively formed on both side ends of the upper panel, and the optical sheet is formed to be wound or unwound on the roller, so that the non-condensing optical unit and the condensing optical unit are It is preferable to be selectively positioned on the lower panel.

In addition, the optical sheet is preferably any one of PET (polyethylene terephthalate), PEN (polyethylene naphthalate), PP (polypropylene), PI (polyimide), PS (polystylene), and PC (polycarbonate).

In addition, the lower panel is formed on a tempered glass substrate, a non-condensing solar cell array disposed on the tempered glass substrate, and an empty area at a corner portion of the non-condensing solar cell on the tempered glass substrate, It is preferable to include a coupling hole formed to couple the condensing solar cell, the condensing solar cell coupled to the coupling hole, and a frame formed on the edge of the tempered glass substrate.

In addition, in the condensing solar cell, it is preferable that a solar cell is formed on a substrate, a reflector waveguide is formed on the solar cell, and a radiating fin is formed on the lower side of the substrate.

On the other hand, it is preferable that the rollable hybrid solar cell module device is coupled with a solar tracker.

The present invention relates to a composite solar cell module device capable of simultaneously utilizing non-condensing power generation (PV) and condensing power generation (CPV), and in particular, an optical system for non-condensing power generation and condensing power generation is applied to a rollable optical sheet. It is to provide a solar cell module device that is formed continuously and can be easily replaced in response to the irradiation condition of solar light, thereby enabling high efficiency power generation.

Accordingly, the present invention has a time when the solar irradiation condition is favorable for condensing and a time when condensing is unfavorable due to a large number of scattered light, and it is possible to simultaneously respond to such solar irradiation conditions. In the case of a non-condensing condition and a condition with a lot of direct light, the optical system of the solar cell module can be easily changed to a condensing condition, thereby enabling high-efficiency power generation.

In addition, the solar cell module device according to the present invention enables condensing-type power generation and non-condensing-type power generation to be simultaneously implemented.In regions with high direct sunlight, the amount of direct sunlight is reduced by the diffraction effect of the condensing optical unit (CPV condensing lens). It is possible to prevent a decrease in the efficiency of non-condensing solar cell (PV Cell), and to realize a high-efficiency module by increasing the efficiency of condensing solar cell.

In addition, in mid-latitudes such as Korea, in areas with low direct solar radiation, CPV cells are not sufficiently utilized, but can be compensated for by non-condensing solar cells (PV Cells), so high efficiency can be achieved. It has the advantage of being able to provide regional custom module designs according to conditions.

1-A schematic view of a main part of a rollable hybrid solar cell module device according to the present invention.
Figure 2-Schematic diagram of the rollable optical sheet of the rollable composite solar cell module device according to the present invention ((a) is an optical sheet having a condensing optical unit, (b) is an optical sheet having a non-converging optical unit).
Figure 3-Schematic diagram of a rollable optical sheet according to various embodiments of the present invention.
Figure 4-A schematic diagram of a lower panel (a) and a non-condensing solar cell array (b) of the rollable composite solar cell module device according to the present invention.
Figure 5-An example operation of the condensing optical unit and the condensing solar cell of the rollable composite solar cell module device according to the present invention.

The present invention relates to a composite solar cell module device that simultaneously utilizes non-condensing power generation and condensing power generation, and to a rollable composite solar cell module device capable of responding to irradiation conditions of sunlight.

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

1 is a schematic diagram showing a main part of a rollable composite solar cell module device according to the present invention, and FIG. 2 is a schematic diagram of a rollable optical sheet of a rollable composite solar cell module device according to the present invention ((a ) Is an optical sheet in which a condensing optical part is formed, (b) shows an optical sheet in which a non-condensing optical part is formed, and FIG. 3 shows a rollable optical sheet according to various embodiments of the present invention, and FIG. 4 is A schematic diagram of a lower panel (a) and a non-condensing solar cell array (b) of a rollable composite solar cell module device is shown, and FIG. 5 is a condensing optical unit of the rollable composite solar cell module device according to the present invention. And an exemplary operation for a condensing solar cell.

As shown, the rollable composite solar cell module device according to the present invention is a composite solar cell module device that simultaneously utilizes non-condensing power generation and condensing power generation, and includes a non-condensing solar cell 110 array and , The lower panel 100 in which the condensing solar cell 120 formed respectively formed in the empty area of the corner of the non-condensing solar cell 110 is disposed, and is formed on the upper side of the lower panel 100, An upper panel 200 on which an optical sheet 210 for transmitting or condensing sunlight is formed, and a support 300 for separating and fixing the upper panel 200 from the lower panel 100 at predetermined intervals, It is formed on the upper panel 200, characterized in that the rolling means 400 for rolling the optical sheet 210 is provided.

The present invention relates to a composite solar cell module device capable of simultaneously utilizing non-converging type power generation (PV) and condensing type power generation (CPV), and in particular, an optical system for non-converging type power generation and condensing type power generation is a rollable optical sheet ( It is to provide a solar cell module device that is continuously formed at 210) and can be easily replaced in response to the irradiation condition of solar light, thereby enabling high-efficiency power generation.

Accordingly, the present invention has a time when the solar irradiation condition is favorable for condensing and a time when condensing is unfavorable due to a large number of scattered light, and it is possible to simultaneously respond to such solar irradiation conditions. In the case of a non-condensing condition and a condition with a lot of direct light, the optical system of the solar cell module can be easily changed to a condensing condition, thereby enabling high-efficiency power generation.

First, in the rollable composite solar cell module device according to the present invention, the lower panel 100 includes an array of non-condensing solar cell 110 and an empty area at the corner of the non-condensing solar cell 110 It is characterized in that the condensing solar cell 120 formed in each is disposed.

In general, the non-condensing solar cell 110 and the condensing solar cell 120 are formed of a silicon solar cell or a compound solar cell according to an installation environment or a work environment.

Specifically, the lower panel 100 includes a tempered glass substrate 130, an array of non-condensing solar cells 110 disposed on the tempered glass substrate 130, and the ratio of the tempered glass substrate 130 to the tempered glass substrate 130. A coupling hole formed in an emptied area of the corner of the condensing solar cell 110 and formed to couple the condensing solar cell 120, the condensing solar cell 120 coupled to the coupling hole, and And a frame formed on the edge of the tempered glass substrate 130.

4 is a schematic diagram showing a lower panel 100 (a) and an array (b) of a non-condensing solar cell 110 in the rollable hybrid solar cell module device according to the present invention, as shown in FIG. As described above, the array of the non-condensing solar cell 110 is formed by being bonded to the tempered glass substrate 130 of a thin plate, and the cover tempered glass substrate 130 may be formed thereon.

In addition, the array of non-condensing solar cell 110 is laminated encapsulating with EVA film to protect the array of non-condensing solar cell 110 from external environment or moisture, and then strengthened. It may be provided by being adhered to the glass substrate 130.

Thereafter, the condensing solar cell 120 is formed on the tempered glass substrate 130, and the rim of the tempered glass substrate 130 is surrounded by a predetermined frame to protect the lower panel 100 from external shock or When a light tracker is installed, it is fixed to the frame.

In general, in the case of a non-condensing solar cell 110 of a circular or square shape, the corners of the non-condensing solar cell 110 are provided in a cut shape, so that the portion where the corners of the neighboring non-condensing solar cell 110 meet when arranged is a toughened glass substrate ( 130) will form an empty area.

The condensing solar cell 120 is formed in the emptied region, and a coupling hole is formed so that the condensing solar cell 120 is coupled to the emptied region.

The condensing solar cell 120 is bonded to or screwed into the coupling hole, and may be formed over the entire edge region or partially formed in consideration of condensing power generation efficiency.

As described above, condensed power generation and non-condensing power generation are simultaneously implemented in the lower panel 100 according to the present invention, so that the advantages of each cell can be utilized and the disadvantages can be compensated. That is, in an area where direct sunlight is high, the efficiency of the non-condensing solar cell 110 can be prevented by reducing the amount of direct light due to the diffraction effect of the condensing optical unit (CPV condensing lens) 212. In addition, the efficiency of the condensing solar cell 120 (CPV Cell) is increased so that a high-efficiency module can be implemented.

Meanwhile, in the condensing solar cell 120, as shown in FIG. 5, a solar cell 122 is formed on a substrate 121, and a reflector waveguide 123 is formed on the solar cell 122. And, a heat radiation fin 124 is formed under the substrate 121

The substrate 121 is completed by designing an epoxy-coated copper plate circuit on an aluminum oxide plate, and a solar cell 122 is bonded thereon.

The solar cell 122 uses a high-efficiency solar cell in which heterogeneous compound solar cells are bonded, and the condensed light is incident so that a heat dissipation fin 124 is formed to radiate high heat. In addition, an aluminum reflector waveguide 123 is formed on the solar cell 122 so that incident light is provided onto the solar cell 122 without loss.

In addition, a frame for protecting the tempered glass substrate 130 and the non-condensing solar cell 110 and the condensing solar cell 120 is formed on the edge of the tempered glass substrate 130, and the frame is durable. And it is formed of aluminum or stainless steel in consideration of workability and light weight.

In addition, the upper panel 200 is formed on the upper side of the lower panel 100, and an optical sheet 210 for transmitting or condensing sunlight is formed.

The upper panel 200 is spaced apart from and fixed at a predetermined interval by a support 300 above the lower panel 100. The support 300 is formed of a material such as aluminum, is formed at an appropriate height in consideration of the focal length of the condensing optical unit 212, and is formed at the edge between the upper panel 200 and the lower panel 100. desirable.

Rolling means 400 for rolling the optical sheet 210 are formed on the upper panel 200. In one embodiment of the present invention, the rolling means 400 is fixed and driven on the support 300 formed at the square corners of the lower panel 100, and can be automatically or manually driven according to the irradiation condition of sunlight. have.

The rolling means 400 is implemented by rollers 410 respectively formed on both side ends of the upper panel 200 and a motor for driving them. The roller 410 is formed to enable speed and direction control, and is formed on both ends of the optical sheet 210 so that when one roller 410 rotates toward the optical sheet 210, the other roller 410 ) Is rotated toward the optical sheet 210 is released.

Accordingly, the optical system of the optical sheet 210 optimized according to the solar irradiation condition (condensing or non-condensing) is positioned on the upper side of the lower panel 100.

Since the optical sheet 210 in the present invention should be rollable, it should be formed of a flexible polymer film material, and in consideration of transparency and durability, PET (polyethylene terephthalate), PEN (polyethylene naphthalate), PP (polypropylene), PI (polyimide), PS (polystylene), or PC (polycarbonate) is used.

As shown in FIGS. 2 and 3, the optical sheet 210 is continuously formed in different regions in which the non-condensing optical unit 211 and the condensing optical unit 212 are formed, and the rolling means 400 The non-condensing optical unit 211 and the condensing optical unit 212 are formed to be easily replaced according to light irradiation conditions.

That is, if the condition of sunlight is favorable to the scattered light, the optical sheet 210 has the non-converging optical unit 211 located on the lower panel 100 so that non-condensing power generation is mainly performed, and the condition of sunlight is If the situation is advantageous for condensing, the optical sheet 210 allows the condensing optical unit 212 to be positioned on the lower panel 100 so that condensing power is mainly performed.

To this end, a rollable optical sheet 210 is provided, and a rolling means 400 is provided so that the optical sheet 210 can be rollably driven.

The non-condensing optical part 211 of the optical sheet 210 is formed in the form of a transparent film, and the condensing optical part 212 is implemented in the form of a condensing pattern or a Fresnel lens, and corresponds to the location of the condensing solar electron cell. Is formed.

Here, in order to implement the condensing pattern or Fresnel lens shape constituting the condensing optical part 212, the condensing pattern or the Fresnel lens type optical system is laminated on a transparent polymer film, or imprinted on the polymer film itself. I can.

In addition, as shown in FIG. 3, the condensing optical unit 212 of the optical sheet 210 has a plurality of condensing optical units 212 having different shapes, sizes, and numbers of the condensing pattern or Fresnel lens. Can be formed continuously.

This makes it possible to easily change the shape, condensing performance, and condensing efficiency of the condensing optical unit 212 according to the irradiation condition of sunlight or the type and arrangement of the condensing solar cell 120 of the lower panel 100. will be.

3(a) shows that a non-condensing optical part 211 and a single type of condensing optical part 212 are formed on the optical sheet 210, and FIG. 3(b) shows that the non-condensing optical part 212 is formed on the optical sheet 210. It is illustrated that the condensing optical unit 211 and various types of condensing optical units 212 are continuously formed.

Accordingly, the rolling means 400 is operated as needed so that the appropriately selected light-converging optical unit 212 is positioned on the lower panel 100 so that it can be customized to various installation environments.

Meanwhile, the rollable composite solar cell module device according to the present invention may be provided as a fixed type, or may be provided as a tracking type in which a solar tracker is combined for higher efficiency.

5 is a view showing an exemplary operation of the condensing optical unit 212 and the condensing solar cell 120 of the rollable composite solar cell module device according to the present invention, and the condensing optical unit formed on the upper panel 200 Sunlight incident by the (Fresnel lens type) is condensed and incident on the condensing solar cell 120, and scattered light generated in this process is incident on the non-condensing solar cell 110.

That is, if the solar condition is favorable for direct sunlight, the condensing optical unit 212 of the optical sheet 210 is positioned above the lower panel 100 by using the rolling means 400 to achieve condensing power generation efficiency. In this case, the scattered light is generated and the generated scattered light is incident on the non-condensing solar cell 110.

In addition, if the solar condition is favorable to the scattered light (for example, a plant factory, etc.), the non-condensing optical unit 211 of the optical sheet 210 is positioned above the lower panel 100 using the rolling means 400. Thus, the non-condensing power generation efficiency was improved.

Accordingly, the present invention provides a solar cell module capable of simultaneously responding to such solar irradiation conditions, although there is a time when sunlight is advantageous for condensing and a time when condensing is disadvantageous due to a large number of scattered light.

As described above, the solar cell module device according to the present invention enables condensed power generation and non-condensing power generation to be simultaneously implemented, thereby making use of the advantages of each cell and supplementing the disadvantages. In other words, in an area with a lot of direct sunlight, it is possible to prevent a decrease in the efficiency of a non-condensing solar cell (PV Cell) due to heat by reducing the amount of direct sunlight due to the diffraction effect of the condensing optical unit (CPV condensing lens). By increasing the efficiency of the cell, it is possible to implement a high-efficiency module.

In addition, in mid-latitudes such as Korea, in areas with low direct solar radiation, CPV cells are not sufficiently utilized, but can be compensated for by non-condensing solar cells (PV Cells), so high efficiency can be achieved. It has the advantage of being able to provide regional custom module designs according to conditions.

100: lower panel 110: non-condensing solar cell
120: condensing solar cell 121: substrate
122: solar cell 123: reflector waveguide
124: radiating fin 130: tempered glass substrate
131: coupling hole 140: frame
200: upper panel 210: optical sheet
211: non-condensing optical unit 212: condensing optical unit
300: support 400: rolling means
410: roller

Claims (9)

In the composite solar cell module device that simultaneously utilizes non-condensing power generation and condensing power generation,
A non-condensing type solar cell array and a lower panel in which condensing type solar cells each formed in an empty area of a corner portion of the non-condensing type solar cell are disposed;
An upper panel formed on the upper side of the lower panel and having an optical sheet for transmitting or condensing sunlight;
Includes; a support for separating and fixing the upper panel at a predetermined interval from the lower panel,
Rolling means formed on the upper panel to rollably drive the optical sheet; is provided,
The optical sheet,
A non-condensing optical unit and a condensing optical unit are continuously formed in different regions, and one of the non-condensing optical unit and the condensing optical unit is positioned on the lower panel by the rolling means. Solar cell module device. delete The method of claim 1, wherein the condensing optical unit of the optical sheet,
A rollable hybrid solar cell module device, characterized in that it is implemented in the form of a condensing pattern or a Fresnel lens, and is formed to correspond to a location of the condensing solar cell. The method of claim 3, wherein the condensing optical unit of the optical sheet,
A rollable composite solar cell module device, characterized in that a plurality of condensing optical units having different shapes, sizes, and numbers of the condensing pattern or Fresnel lens shape are continuously formed in different regions. The method of claim 1, wherein the rolling means,
It is implemented with rollers respectively formed on both side ends of the upper panel,
The optical sheet is formed to be wound or unwound on the roller,
The rollable composite solar cell module device, characterized in that the non-condensing optical unit and the condensing optical unit are selectively positioned on the lower panel according to irradiation conditions of sunlight. The method of claim 1, wherein the optical sheet,
Polyethyleneterephthalate (PET), polyethylene naphthalate (PEN), polypropylene (PP), polyimide (PI), polystylene (PS), and polycarbonate (PC). The method of claim 1, wherein the lower panel,
Tempered glass substrate;
A non-condensing solar cell array disposed on the tempered glass substrate;
A coupling hole formed on the tempered glass substrate in an empty area of a corner portion of the non-condensing solar cell, and formed to couple the condensing solar cell;
A condensing solar cell coupled to the coupling hole; And
A rollable composite solar cell module device comprising: a frame formed on the edge of the tempered glass substrate. The method of claim 1, wherein the condensing solar cell,
A solar cell is formed on the substrate,
A reflector waveguide is formed on the solar cell,
A rollable composite solar cell module device, characterized in that a heat dissipation fin is formed under the substrate. The method according to any one of claims 1, 3 to 8, wherein the rollable composite solar cell module device,
A rollable composite solar cell module device, characterized in that a solar tracker is combined.

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