KR101205462B1 - Light Guide Type CPV Module with Bifacial Solar cell - Google Patents

Abstract

PURPOSE: A solar concentrator module in a light guiding mode using a double-faced solar cell is provided to reduce the scale of a generator by concentrating sunlight on a small number of a solar cells. CONSTITUTION: A condensing lens(3) concentrates sunlight from the outside. A left solar cell(5) is formed on the lower part of the condensing lens in the vertical direction. A right solar cell(7) generates electricity by receiving sunlight. A solar cell receiver is formed on the back of the left solar cell. A heat cooling mechanism(9a,9b) cools heat transferred to the solar cell receiver.

Description

Light Guide Type CPV Module with Bifacial Solar cell}

The present invention focuses primarily on light incident from the outside, and then condenses the collected solar light in the direction of the solar cell so that the solar cell can produce electricity. Type module.

Human beings are developing new energy sources to replace fossil energy due to depletion of fossil energy and global climate change. Among these alternative energy sources, humanity has great interest in the solar energy field, which is pollution-free and infinitely available.

Power generation using solar energy includes photovoltaic power generation that converts sunlight into electrical energy, and solar devices that collect solar energy and use it for heating or hot water.

Among them, the solar power generation has the advantage that, unlike the existing power generation facilities such as thermal power or nuclear power, fuel costs are not consumed and noise and pollution are not generated.

In addition, photovoltaic power generation does not require large-scale power generation equipment, and since small-scale power generation is possible, there is an advantage that it can be used for home use.

As a result, photovoltaic power generation is widely used in developed countries such as Germany, Japan, and the United States, and the recent implementation of alternative energy utilization promotion law has been revised and published in Korea, and concrete implementation plans such as construction of 10,000 solar power plants have been realized.

This photovoltaic power generation consists of a light collecting unit for collecting solar light and a solar module for converting sunlight into electrical energy. In addition, the light collecting unit of the photovoltaic power generation according to the prior art is provided with a reflecting plate for reflecting and condensing sunlight on the photovoltaic module, which reflects the sun light in a flat plate shape.

However, the solar module combined with the flat reflector according to the prior art has a problem in that the solar light reflected from the flat reflector is not transmitted and the power generation efficiency of the solar module is not good.

In addition, the conventional photovoltaic device has a problem in that a fixed distance between the lens and the solar cell by placing the solar cell at a certain distance away from the lens or reflector.

In order to solve the above problems, the present invention minimizes the loss of solar light when delivering solar light incident from the outside toward the solar cell, thereby improving the power generation performance of the solar cell, and miniaturizing the size of the solar power generation facility. It is an object of the present invention to provide a light guiding light collecting module using a double-sided solar cell that can minimize the manufacturing cost for the equipment.

In addition, the present invention provides a light guiding light concentrating module using a double-sided solar cell that can effectively release the heat generated from the solar cell to optimize the power generation performance of the solar cell. have.

The light guiding light concentrating module using a double-sided solar cell according to the present invention for achieving the above object is provided with two or more convex lenses arranged in a lattice form on the bottom while being laid down in a horizontal direction and transmitted from the outside. A condenser lens unit for condensing light, a left solar cell which is erected in a vertical direction from the lower part of the condenser lens part, and receives electricity from a left refractive lens part to produce electricity, and is erected in a vertical direction from a lower part of the condenser lens part The right solar cell generates electricity by receiving the solar light transmitted from the right refractive lens unit, and is installed on the back of the left solar cell and the back of the right solar cell, respectively, to be generated from the left solar cell and the right solar cell. Energy can be transferred to the outside and the left solar cell A solar cell receiver which transfers heat generated from the right solar cell to a thermal cooling mechanism, and is sandwiched between the one solar cell receiver and the other solar cell receiver and is transferred to the solar cell receiver through the left and right solar cells It is provided with a heat cooling mechanism for cooling the heat. In addition, the present invention is a left refraction lens unit lying in the horizontal direction on the left side of the left solar cell and refracted by the prism in the direction of the left solar cell, and a horizontal direction on the right side of the right solar cell A right refractive lens unit lying down by the prism and refracting the solar light refracted by the prism toward the right solar cell cell, and a lower refractive lens unit facing the convex lens and a lower refraction lens unit facing the convex lens and condensed by the convex lens. And a prism that refracts sunlight to the left refractive lens portion or the right refractive lens portion.

In the light guiding light concentrating module using the double-sided solar cell according to the present invention having such a structure, when the convex lens provided in the condenser lens unit condenses sunlight into a prism facing the convex lens, the prism is condensed. The light is refracted by the left refraction lens portion or the right refraction lens portion, and the left refraction lens portion and the right refraction lens portion refract the sunlight transmitted from the prism to the left solar cell and the right solar cell, and thus the left solar cell and the right solar cell. Let the cell produce electricity

Therefore, the light guiding light concentrating module using the double-sided solar cell according to the present invention focuses the solar light collected by the convex lens on the prism, so that the focal length between the convex lens and the prism is shortened. In addition to reducing size, manufacturing costs can also be reduced.

In addition, there is an advantage that the cost consumed by the solar cell can be reduced by condensing sunlight on a few solar cells erected in the vertical direction.

1 is a plan view of the present invention,
2 is a longitudinal sectional view of the present invention;
3 is a view illustrating a process in which sunlight is refracted in the direction of the left and right refraction lens units by varying the refraction angle according to the intrinsic wavelength of light through the prism.

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

In the light guiding light converging module using the double-sided solar cell according to the present invention, as shown in FIGS. 1 and 2, two or more convex lenses 1 arranged in a lattice form are laid on the lower side while being laid down in the horizontal direction. Condensing lens unit 3 for condensing the sunlight transmitted from the outside and the vertical direction from the lower portion of the condensing lens unit 3 to receive the sunlight transmitted from the left refractive lens unit 15 to produce electricity The left solar cell 5, the right solar cell 7 erected vertically from the lower portion of the condensing lens unit 3 to receive electricity from the right refraction lens unit 17 to generate electricity to produce electricity. It is installed on the back of the left solar cell 5 and the back of the right solar cell 7, respectively, to transfer electricity generated from the left solar cell 5 and the right solar cell 7 to the outside and generate electricity.The solar cell receiver 11 which transfers the heat | fever which generate | occur | produced from the left solar cell 5 or the right solar cell 7 to the thermal cooling mechanism 9a, 9b, and the said solar cell receiver 11 in the middle. ) And a thermal cooling mechanism (9a, 9b) is inserted between the other solar receiver 11 to cool the heat transferred to the solar receiver 11 through the left and right solar cells (5, 7) do.

In addition, the present invention, the left refraction lens unit 15 lying in the horizontal direction on the left side of the left solar cell 5 and refracting the solar light refracted by the prism 13a in the direction of the left solar cell 5. And a right refractive lens unit 17 lying in a horizontal direction on the right side of the right solar cell 7 and refracting the solar light refracted by the prism 13b toward the right solar cell 7, and the Mounted under the left refraction lens unit 15 and the right refraction lens unit 17 facing the convex lens 1, the sunlight condensed by the convex lens 1 is refracted by the left refraction lens unit 15 or the right refraction. It further includes prisms 13a and 13b that are refracted by the lens portion 17.

In addition, the thermal cooling mechanisms 9a and 9b are structures made of copper or aluminum, and effectively discharge heat generated from the left solar cell 5 and the right solar cell 7 by circulating water or air therein. You can.

In addition, as shown in FIGS. 2 and 3, the solar light collected by the convex lens 1 to the prisms 13a and 13b has an angle of refraction depending on the intrinsic wavelength of light through the prisms 13a and 13b. Differently refracted in the direction of the left and right refraction lens portions 15 and 17, and the left and right refraction lens portions 15 and 17 receive the light incident from the prisms 13a and 13b to the left and right solar cells. Refraction in the (5,7) direction.

In this case, the condensing lens unit 3 is made of glass, and the left and right refractive lens units 15 and 17 are made of borosilicate glass, and a prism installed in the left refractive lens unit 15. It is preferable that the vertical section of 13a is a right triangle facing the left solar cell 5 at a vertex formed at right angles.

In addition, it is preferable that a vertex of the vertical cross section of the prism 13b provided on the right refractive lens unit 17 faces a right solar cell 7 as a right triangle.

In addition, the size of the prism (13a, 13b) is preferably made of 99㎛ ~ 1000㎛.

The operation of the light guiding light concentrating module using the double-sided solar cell according to the present invention having the above structure will be described with reference to FIG. 2 as follows.

First, when sunlight is incident on the condensing lens unit 3 according to the present invention, the convex lenses 1 arranged in a lattice form on the condensing lens unit 3 have a prism facing the convex lens 1. 13a and 13b) to collect sunlight.

At this time, the two or more prisms 13a provided on the lower surface of the left refractive lens unit 15 refract the sunlight collected by the convex lens 1 to the left refractive lens unit 15, and the left refractive lens The part 15 refracts the solar light refracted by the prism 13a back to the left solar cell 5 to cause the left solar cell 5 to produce electricity.

On the other hand, at least two prisms 13b provided on the bottom surface of the right refractive lens unit 17 refract the sunlight condensed by the convex lens 1 to the right refractive lens unit 17, and the right refractive lens The unit 17 refracts the solar light refracted by the prism 13b back to the right solar cell 7 to cause the right solar cell 7 to produce electricity using sunlight.

In addition, the left solar cell 5 and the right solar cell 7 transfer the heat generated during the power generation process through the solar cell receiver 11 to the thermal cooling mechanisms 9a and 9b, and the thermal cooling mechanism. 9a and 9b may release heat generated from the left solar cell 5 and the right solar cell 7 to increase power generation performance of the left solar cell 5 and the right solar cell 7. .

In the light guiding light concentrating module using the double-sided solar cell according to the present invention having the above structure, the convex lens 1 of the first condensing lens unit 3 faces the prism 13a facing the convex lens 1. When the solar light is focused on 13b, the prisms 13a and 13b refract the collected sunlight to the left refraction lens unit 15 or the right refraction lens unit 17, and the left refraction lens unit 15 The right refractive lens unit 17 refracts the sunlight transmitted from the prisms 13a and 13b into the left solar cell 5 and the right solar cell 7, so that the left solar cell 5 and the right solar cell Causes cell 7 to produce electricity.

Therefore, the light guiding light concentrating module using the double-sided solar cell according to the present invention focuses the sunlight collected by the convex lens 1 on the prisms 13a and 13b, so that the convex lens 1 and the prism ( Shorter focal lengths between 13a and 13b) reduce the size of the photovoltaic device and reduce manufacturing costs.

In addition, it is possible to reduce the cost consumed by the solar cell by condensing sunlight to a few solar cells erected in the vertical direction.

1. Convex lens 3. Condensing lens unit
5. Left Solar Cell 7. Right Solar Cell
9a. Thermal Cooling Apparatus 11. Solar Cell Receiver
13a. Prism 15. Left refractive lens part
17. Right refractive lens unit

Claims (2)

delete A condensing lens unit 3, which is laid down in the horizontal direction and provided with two or more convex lenses 1 arranged in a lattice form on the lower surface to condense sunlight transmitted from the outside;
A left solar cell 5 which is erected in a vertical direction under the condensing lens unit 3 and receives electricity transmitted from the left refraction lens unit 15 to generate electricity;
A right solar cell 7 that is erected in a vertical direction under the condensing lens unit 3 and receives electricity from the right refractive lens unit 17 to generate electricity;
It is installed on the back of the left solar cell 5 and the back of the right solar cell 7, respectively, and transfers electricity generated from the left solar cell 5 and the right solar cell 7 to the outside. A solar cell receiver 11 for transferring heat generated from the left solar cell 5 or the right solar cell 7 to the thermal cooling mechanisms 9a and 9b during the power generation process;
Heat that is inserted between the solar cell receiver 11 and the other solar cell receiver 11 and cools the heat transferred to the solar cell receiver 11 through the left and right solar cells 5 and 7. Cooling mechanisms 9a and 9b;
A left refraction lens unit 15 lying down in the horizontal direction on the left side of the left solar cell 5 and refracting the solar light refracted by the prism 13a in the direction of the left solar cell 5;
A right refracting lens unit 17 lying in a horizontal direction on the right side of the right solar cell 7 and refracting solar light refracted by the prism 13b in the direction of the right solar cell 7;
Mounted under the left refraction lens unit 15 and the right refraction lens unit 17 facing the convex lens 1, the light condensed by the convex lens 1 receives the left refraction lens unit 15 or the right side. It consists of prisms 13a and 13b which are refracted by the refractive lens unit 17,
The material of the condensing lens unit 3 is glass,
The left and right refractive lens parts 15 and 17 are made of borosilicate glass.
The vertical cross section of the prism 13a provided in the left refraction lens unit 15 is a right triangle, and a vertex formed at right angles faces the left solar cell 5,
The longitudinal section of the prism 13b installed in the right refractive lens unit 17 is a right triangle, and a vertex formed at right angles faces the right solar cell 7. Type module.

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