KR102165092B1 - Double sided solar light concentrator using Valley Type reflector - Google Patents

Abstract

The present invention relates to a double-sided solar light condensing device using a valley type reflector. More particularly, the present invention relates to a double-sided solar light condensing device using a valley type reflector which places the valley type reflector on a lower side of a double-sided solar light condensing plate to be coupled to a solar cell module holder (100), and forms the reflector in various valley types to reflect sunlight to a rear surface of a double-sided solar cell module (200), thereby increasing rear surface power generation efficiency.

Description

Double sided solar light concentrator using Valley Type reflector}

The present invention relates to a double-sided solar condensing device using a bone-shaped reflector, and more particularly, a bone-shaped reflector is placed under the double-sided solar collecting plate to be coupled to the solar cell module holder 100, and formed in various valleys. Thus, it relates to a double-sided solar condensing device using a bone-shaped reflector for increasing the rear power generation efficiency by reflecting sunlight to the rear of the double-sided positive battery module 200.

Recently, a method of using solar energy, which is one of clean energy, has emerged as a problem of rising energy prices due to depletion of fossil energy resources and prevention of environmental pollution caused by combustion of fossil energy.

In general, the method of using solar energy is solar power generation, which uses solar cells to generate electricity, absorbs solar heat using a solar heat collecting tube or plate, and uses it for hot water production or heating, and lighting or plant growth. Alternatively, there are natural sunlight natural sunlight using a solar natural light module or a reflector for use as a photocatalyst.

In particular, a photovoltaic device converts solar energy into electrical energy by injecting sunlight into a solar cell, and the temperature of the solar cell rises as the sunlight is focused on the solar cell, thereby deteriorating the solar cell. There is a problem.

In addition, since the photovoltaic device generally has a power generation efficiency of 10-15%, only 10-15% of the solar energy incident on the solar cell is used for solar power generation, and the remaining 85-90% of the energy is It is not used effectively and is discarded as heat.

In addition, in the photovoltaic device, there is a need to increase the incident amount of sunlight incident on the solar cell in order to increase power generation efficiency.

Therefore, the photovoltaic device must efficiently concentrate sunlight in order to maximize the use of solar energy, and various photovoltaic concentrators are used for this purpose, and the light intensity of the condenser is solar power generation, solar heat collection, and solar power. Whatever method of use, such as natural light, is directly connected to solar energy efficiency.

The solar concentrator is a point-focus dish type, a point-focus Fresnel lens type, a linear-focus Fresnel lens type, and a heliosted type. (Heliostat type), Gregorian/Casegrain concentrator, condensing using a holographic prism sheet, etc., and numerous other methods are known.

However, the solar concentrator is inevitable to increase the size of the solar concentrator structure in order to increase the amount of power generation/solar heat collection/natural sunlight of the solar power generation facility in general. There is also a problem in which it is very difficult to expect economical efficiency compared to investment because many restrictions are generated in the market.

In addition, the lens-type solar concentrator has a problem in that the cost of manufacturing the solar power generation device increases because the component price of the lens is high.

In addition, countries around the world are investing a lot of time and money to improve the power generation efficiency by 1 to 2%, but there is a very difficult problem in the development of solar modules that dramatically increase power generation efficiency in the near future.

Accordingly, there is a need for a solar condensing technology that is inexpensive and can increase power generation efficiency than before.

Korean Patent Publication No. 10-2019-0004243

Therefore, the present invention was devised to solve the above conventional problems,

An object of the present invention is to place a corrugated reflector underneath the double-sided photovoltaic light collecting plate to couple it to the solar cell module holder 100, and to reflect sunlight to the rear side of the double-sided type positive cell module 200 by forming it in various valleys. To increase the power generation efficiency in the rear.

In order to achieve the problem to be solved by the present invention, a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention,

Horizontal frames 110 and 110a configured to be installed horizontally at regular intervals;

Vertical frames (120, 120a) configured to be installed vertically at any one position of the horizontal frame;

Inclined frames 130 and 130a each configured to be installed at a predetermined angle at the upper end of the vertical frame;

Modules anti-falling stopper 140 which is configured to be installed on the inclined frame at a predetermined distance apart;

Consisting, including, a double-sided shape including; is coupled to one side of the vertical frame at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination. A solar cell module cradle 100 that installs and configures a plurality of battery modules 200 at regular intervals,

The solar cell module cradle 100 and a reflective plate cradle 300 configured to be installed in parallel with the solar cell module cradle at a position spaced apart from the solar cell module cradle 100 and to couple the solar light reflection plate to the inside,

The problem of the present invention is solved by including the solar reflector 400 for increasing the rear power generation efficiency by reflecting the sunlight incident on the reflective plate holder to the rear surface of the double-sided positive battery module 200.

A double-sided solar condensing device using a bone-shaped reflector according to the present invention,

The corrugated reflector is located under the double-sided solar light collecting plate and is coupled to the solar cell module holder 100, and it is formed in various corrugations to reflect sunlight to the rear of the double-sided type positive cell module 200 to increase rear power generation efficiency. It provides an increasing effect.

In addition, by improving the power generation efficiency, there is a better economic effect of reducing the initial investment cost and maintenance cost by reducing the installation area of the power plant.

In addition, by improving power generation efficiency, there is a better effect of reducing the installation area of a solar power plant, solving the problem of insufficient site, and further protecting the natural environment.

1 is an exemplary view showing the length of a reflector by a solar reflector 400 formed in a double-sided solar concentrator using a bone reflector according to an embodiment of the present invention.
2 is a perspective view of a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention.
3 is an exemplary view in which a solar reflector 400 of a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention is configured as an east-west bone-shaped portion 410.
4 is an exemplary view in which the solar reflecting plate 400 of the double-sided solar condensing device using the bone-shaped reflecting plate according to an embodiment of the present invention is constituted by the inclined bone-shaped portion 420.
5 is an exemplary view of a solar reflector 400 in the shape of an arc 430 of a double-sided solar concentrator using a bone reflector according to an embodiment of the present invention.
6 is an exemplary view in which the solar reflector 400 of the double-sided solar concentrator using the bone-shaped reflector according to an embodiment of the present invention is formed as an east-west single bone-shaped portion 450.
7 is an exemplary view in which the solar reflecting plate 400 of the double-sided solar condensing device using the bone-shaped reflector according to an embodiment of the present invention is formed as a single bone-shaped portion 460 in the direction of the inclined surface.
8 is an exemplary view in which a conventional double-sided solar panel is installed.

In order to solve the problem of the present invention, a double-sided solar concentrator using a bone-shaped reflector according to a preferred embodiment,

Horizontal frames 110 and 110a configured to be installed horizontally at regular intervals;

Vertical frames (120, 120a) configured to be installed vertically at any one position of the horizontal frame;

Inclined frames 130 and 130a each configured to be installed at a predetermined angle at the upper end of the vertical frame;

Modules anti-falling stopper 140 which is configured to be installed on the inclined frame at a predetermined distance apart;

Consisting, including, a double-sided shape including; is coupled to one side of the vertical frame at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination. A plurality of battery modules 200 are installed and configured to be spaced apart at regular intervals, but the solar cell module cradle 100 is configured such that a gap 160 is generated between the double-sided positive battery modules by a module flow prevention stopper,

The solar cell module cradle 100 and a reflective plate cradle 300 configured to be installed in parallel with the solar cell module cradle at a position spaced apart from the solar cell module cradle 100 and to couple the solar light reflection plate to the inside,

It is characterized in that it comprises a solar reflector 400 for increasing the rear power generation efficiency by reflecting the sunlight incident on the reflective plate holder to the rear surface of the double-sided type positive battery module 200.

At this time, the solar reflector 400,

East-west direction bone shape portion 410 in which semicircular valleys are formed at regular intervals in the east-west direction perpendicular to the slope direction;

Inclined surface direction bone-shaped portion 420 in which semicircular valleys are formed at predetermined intervals in the inclined surface direction; It is characterized in that it comprises any one of the shape parts.

At this time, the solar reflector 400,

When formed in the shape of an arc 430,

Characterized in that it includes; a semicircular reflection plate sag prevention unit 440 formed at the center of the reflective plate holder 300 in a semicircular shape in the east-west direction perpendicular to the inclined surface direction to prevent the solar reflection plate in the shape of an arc 430 from sagging. To do.

At this time, the solar reflector 400,

East-west direction single bone shape portion 450 in which single-shaped valleys are formed at regular intervals in the east-west direction perpendicular to the inclined surface direction;

Inclined surface direction single bone-shaped portion 460 in which single-shaped valleys are formed at predetermined intervals in the inclined surface direction; It is characterized in that it comprises any one of the shape parts.

At this time, on the solar reflector 400,

The reflector material used is characterized in that the reflective aluminum coil.

Hereinafter, it will be described in detail through an embodiment of a double-sided solar concentrator using a bone-shaped reflector according to the present invention.

1 is an exemplary view showing the length of a reflector by a solar reflector 400 formed in a double-sided solar concentrator using a bone reflector according to an embodiment of the present invention.

As shown in Figure 1, in order to check the shadows projected on the reflector in the standard of Ipchun, Haji, Ipchu, and Winter solstice, between the double-sided type positive battery modules by means of a stopper to prevent the falling of the module included in the solar cell module holder 100. It has a structure such that the gap 160 is generated in the.

For example, in the case of the inset standard, the shadow of the reflector is shaded from a position spaced apart from the upper end of the reflector by a certain distance, and the shade of the reflector is shaded at the lower end of the reflector if the lower end of the reflector is based. The angles of the module and the reflector were set so that the shadow of the reflector is shaded from a position spaced apart from the lower end of the reflector by a certain distance, and in the winter solstice standard, the shade of the reflector is shaded at the upper end of the reflector.

Accordingly, a preferred inclination angle of the double-sided positive battery module 200 and the solar reflector 400 is set based on an angle of 25 degrees.

2 is a perspective view of a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention.

As shown in Figure 2, a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention,

Horizontal frames 110 and 110a configured to be installed horizontally at regular intervals;

Vertical frames (120, 120a) configured to be installed vertically at any one position of the horizontal frame;

Inclined frames 130 and 130a each configured to be installed at a predetermined angle at the upper end of the vertical frame;

Modules anti-falling stopper 140 which is configured to be installed on the inclined frame at a predetermined distance apart;

Consisting, including, a double-sided shape including; is coupled to one side of the vertical frame at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination. A plurality of battery modules 200 are installed and configured to be spaced apart at regular intervals, but the solar cell module cradle 100 is configured such that a gap 160 is generated between the double-sided positive battery modules by a module flow prevention stopper,

The solar cell module cradle 100 and a reflective plate cradle 300 configured to be installed in parallel with the solar cell module cradle at a position spaced apart from the solar cell module cradle 100 and to couple the solar light reflection plate to the inside,

It is characterized in that it comprises a solar reflector 400 for increasing the rear power generation efficiency by reflecting the sunlight incident on the reflective plate holder to the rear surface of the double-sided type positive battery module 200.

Specifically, the solar cell module cradle 100 forms horizontal frames 110 and 110a that are configured to be installed horizontally at regular intervals.

In addition, vertical frames 120 and 120a that are configured to be installed vertically at any one position of the horizontal frame are formed.

In addition, inclined frames 130 and 130a configured to be respectively installed to be inclined at a predetermined angle are formed at the upper end of the vertical frame.

At this time, it is to be configured to install the module flow preventing stopper 140, respectively, spaced apart at a predetermined interval on the inclined frame.

In addition, in order to maintain a certain angle, it is coupled to one side at any one position on the lower side of the vertical frame, and the other side is coupled to any one position on the lower side of the inclined frame to maintain a certain angle of inclination fixed frame 150 Is forming.

At this time, a plurality of double-sided type positive battery modules 200 are installed and configured to be spaced apart at regular intervals with the module flow prevention stopper 140 interposed therebetween.

Accordingly, the gap 160 is generated between the double-sided positive battery modules by the module flow prevention stopper.

In addition, solar light may be introduced into the solar reflector and reflected through the gap 160 to increase power generation efficiency.

That is, by forming a plurality of gaps 160 by the module anti-falling stopper 140, sunlight flows into and reflects the solar reflector through the gaps, thereby increasing power generation efficiency.

On the other hand, as shown in the lower left drawing of Fig. 2, when the above-described gap is formed, it is reflected to the rear surface of the double-sided positive battery module 200 at 21 degrees, 23 degrees, and 25 degrees of incidence, respectively, thereby increasing rear power generation efficiency. It becomes possible to increase.

In addition, the reflective plate holder 300 is configured to be installed in parallel with the solar cell module holder at a position spaced apart from the solar cell module holder 100 by a predetermined distance, and the solar reflector plate is coupled to the inside.

On the other hand, according to an additional aspect, in the reflective plate holder 300,

It is coupled to one side at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination fixed frame (150a); Is to maintain the formed angle.

In addition, the solar reflector 400 reflects sunlight incident on the reflecting plate holder to the rear surface of the double-sided positive battery module 200 to increase rear power generation efficiency.

Hereinafter, various bone shapes will be described in detail with reference to the drawings.

That is, according to an additional aspect, the solar reflector 400,

East-west direction bone shape portion 410 in which semicircular valleys are formed at regular intervals in the east-west direction perpendicular to the slope direction;

Inclined surface direction bone-shaped portion 420 in which semicircular valleys are formed at predetermined intervals in the inclined surface direction; It is characterized in that it comprises any one of the shape parts.

According to another additional aspect, the solar reflector 400,

When formed in the shape of an arc 430,

Characterized in that it includes; a semicircular reflection plate sag prevention unit 440 formed at the center of the reflective plate holder 300 in a semicircular shape in the east-west direction perpendicular to the inclined surface direction to prevent the solar reflection plate in the shape of an arc 430 from sagging. To do.

According to another additional aspect, the solar reflector 400,

East-west direction single bone shape portion 450 in which single-shaped valleys are formed at regular intervals in the east-west direction perpendicular to the inclined surface direction;

Inclined surface direction single bone-shaped portion 460 in which single-shaped valleys are formed at predetermined intervals in the inclined surface direction; It is characterized in that it comprises any one of the shape parts.

3 is an exemplary view in which a solar reflector 400 of a double-sided solar concentrator using a bone-shaped reflector according to an embodiment of the present invention is configured as an east-west bone-shaped portion 410.

That is, as shown in Figure 3, the solar reflector 400,

It is configured to form an east-west direction bone-shaped portion 410 in which semicircular valleys are formed at regular intervals in the east-west direction perpendicular to the slope direction.

When configured as described above, as shown in the lower left drawing of FIG. 3, the east-west direction bone-shaped portion toward the rear surface of the double-sided battery module 200 at an incident angle of 21, 23, and 25 degrees through the gap as described above. By reflecting more than that of Fig. 2, it is possible to increase the rear power generation efficiency.

4 is an exemplary view in which the solar reflecting plate 400 of the double-sided solar condensing device using the bone-shaped reflecting plate according to an embodiment of the present invention is constituted by the inclined bone-shaped portion 420.

That is, as shown in Fig. 4, the solar reflector 400,

The inclined surface direction bone-shaped portion 420 in which semicircular valleys are formed at regular intervals in the inclined surface direction; is configured to form one after another.

When configured as described above, as shown in the lower left drawing of FIG. 4, the inclined bone-shaped portion toward the rear side of the double-sided battery module 200 at an incident angle of 21 degrees, 23 degrees, and 25 degrees through the above gap. By reflecting more than that of FIG. 2 by 420, it is possible to increase the rear power generation efficiency.

5 is an exemplary view of a solar reflector 400 in the shape of an arc 430 of a double-sided solar concentrator using a bone reflector according to an embodiment of the present invention.

As shown in FIG. 5, the solar reflector 400 is formed in an arc 430 shape.

That is, a flexible solar reflector is formed in an arc shape, and at this time, a problem occurs in that the solar reflector is stretched due to the overall weight. In order to prevent this, the central part of the reflector holder 300 is at right angles to the inclined surface direction. It is formed in a semicircular shape in the east-west direction to constitute a semi-disc reflective plate sag prevention unit 440 that prevents the solar reflector of the arc 430 from sagging.

This prevents the solar reflector from sagging.

And, if configured as described above, as shown in the lower left drawing of FIG. 5, arcs to the rear surface of the double-sided battery module 200 at 21 degrees, 23 degrees, and 25 degrees of incidence through the above gaps ( It is possible to increase the rear power generation efficiency by reflecting more than that of FIG. 2 by the solar reflector 400 of the 430) shape.

6 is an exemplary view in which the solar reflector 400 of the double-sided solar concentrator using the bone-shaped reflector according to an embodiment of the present invention is formed as an east-west single bone-shaped portion 450.

As shown in Fig. 6, the solar reflector 400,

It is configured to form an east-west single bone-shaped portion 450 in which single-shaped valleys are formed at regular intervals in the east-west direction perpendicular to the slope direction.

When configured as described above, as shown in the lower left drawing of FIG. 6, through the gap as described above, at an incident angle of 21 degrees, 23 degrees, and 25 degrees to the rear of the double-sided battery module 200, the east-west single bone type By reflecting more than that of FIG. 2 by the upper part 450, it is possible to increase the rear power generation efficiency.

In other words, it means a solar reflector in which a single valley shape having a valley in the east-west direction is continuously formed.

7 is an exemplary view in which the solar reflecting plate 400 of the double-sided solar condensing device using the bone-shaped reflector according to an embodiment of the present invention is formed as a single bone-shaped portion 460 in the direction of the inclined surface.

As shown in Figure 7, the solar reflector 400,

The inclined surface direction single bone-shaped portion 460 in which single-shaped valleys are formed at regular intervals in the inclined surface direction; is configured to form one after another.

When configured as described above, as shown in the lower left drawing of FIG. 7, through the gap as described above, at an incident angle of 21 degrees, 23 degrees, and 25 degrees to the rear side of the double-sided battery module 200, the inclined surface direction single bone By reflecting more than that of FIG. 2 by the upper portion 460, it is possible to increase the rear power generation efficiency.

That is, it means a solar reflector in which a single valley shape having a valley shape in an inclined direction is continuously formed.

At this time, the solar reflector 400 is characterized in that the reflective plate material used is a reflective aluminum coil.

For example, the reflective plate material is made to be curved in the form of a reflective aluminum coil to increase durability and reflectivity in an external environment.

As shown in FIG. 8, the conventional double-sided solar panel is installed in a general structure, and a white cloth is installed at the bottom of the array, so that the rear power generation is insufficient due to the shading, and the power generation efficiency is remarkable compared to the installation cost. It was not popularized.

In addition, as another example, the independent pad was slightly enlarged and white paint was applied. However, the rear power generation was insufficient, and the power generation efficiency compared to the installation cost was remarkably decreased, and thus it was not popularized.

However, if configured as in the present invention, it is possible to solve the problem of installing the conventional double-sided photovoltaic panel.

Through the present invention, the corrugated reflector is placed under the double-sided photovoltaic panel to be coupled to the solar cell module holder 100, and formed into various corrugations to reflect sunlight to the rear of the double-sided type positive cell module 200 This provides an effect of increasing the rear power generation efficiency.

In addition, by improving the power generation efficiency, there is a better economic effect of reducing the initial investment cost and maintenance cost by reducing the installation area of the power plant.

In addition, by improving power generation efficiency, there is a better effect of reducing the installation area of a solar power plant, solving the problem of insufficient site, and further protecting the natural environment.

Those skilled in the art to which the present invention with the above contents pertains will be able to understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, the embodiments described above are exemplified in all respects and should be understood as non-limiting.

100: solar cell module holder
200: Double-sided type positive battery module
300: reflector stand
400: solar reflector

Claims (2)

In the double-sided solar concentrator using a corrugated reflector,
Horizontal frames 110 and 110a configured to be installed horizontally at regular intervals;
Vertical frames (120, 120a) configured to be installed vertically at any one position of the horizontal frame;
Inclined frames 130 and 130a each configured to be installed at a predetermined angle at the upper end of the vertical frame;
Modules anti-falling stopper 140 which is configured to be installed on the inclined frame at a predetermined distance apart;
Consisting, including, a double-sided shape including; is coupled to one side of the vertical frame at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination. A plurality of battery modules 200 are installed and configured to be spaced apart at regular intervals, but the solar cell module cradle 100 is configured such that a gap 160 is generated between the double-sided positive battery modules by a module flow prevention stopper,
The solar cell module cradle 100 and a reflective plate cradle 300 configured to be installed in parallel with the solar cell module cradle at a position spaced apart from the solar cell module cradle 100 and to couple the solar light reflection plate to the inside,
Consisting of including a solar reflector 400 for increasing the rear power generation efficiency by reflecting the incident sunlight coupled to the reflective plate holder to the rear surface of the double-sided type positive battery module 200,
The solar reflector 400,
East-west direction bone shape portion 410 in which semicircular valleys are formed at regular intervals in the east-west direction perpendicular to the slope direction;
Inclined surface direction bone-shaped portion 420 in which semicircular valleys are formed at predetermined intervals in the inclined surface direction; It constitutes any one of the shapes, or
The solar reflector 400,
When formed in the shape of an arc 430,
Characterized in that it includes; a semicircular reflection plate sag prevention unit 440 formed at the center of the reflective plate holder 300 in a semicircular shape in the east-west direction perpendicular to the inclined surface direction to prevent the solar reflection plate in the shape of an arc 430 from sagging. And
In the reflective plate holder 300,
It is coupled to one side at any one position on the lower side of the vertical frame, and the other side is coupled to any one position at the lower side of the inclined frame to maintain a predetermined angle of inclination fixed frame (150a); Double-sided solar condensing device using a bone-shaped reflector, characterized in that to maintain the formed angle.
The method of claim 1,
On the solar reflector 400,
Double-sided solar concentrator using a corrugated reflector, characterized in that the reflector material used is a reflective aluminum coil.

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