KR101723148B1 - Solar Cell Unit for Photovoltaic Power Generation and Method for Manufacturing the Same - Google Patents

Abstract

The present invention relates to a solar cell unit for photovoltaic power generation and a fabrication method thereof. The present invention comprises: a body part having a reflector inside thereof, wherein the reflector consists a part of an ellipsoid; a cover part connected to the reflector, consisting another part of the ellipsoid, and configured to transmit the sun light of the outside and reflect the sun light of the inside; and a solar cell located at the vertex of the long axis of the ellipsoid, wherein the solar light passing through the cover part is repeatedly reflected in the inside the cover part to be converged on the solar cell.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photovoltaic cell unit,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell unit for solar power generation and a manufacturing method thereof, and more particularly, to a solar cell unit for solar power generation capable of improving light collection efficiency and power generation efficiency, and a manufacturing method thereof.

Recently, various environmental regulations such as the Convention on Climate Change have been strengthened around the world. In addition, fossil fuels such as petroleum and coal are finite resources, so they become depleted over time. Therefore, development of new energy sources that are sustainable and environmentally friendly is required. For example, the use of renewable energy such as solar energy, geothermal energy, wind power, and tidal power has been developed, among which solar energy is one of the most promising alternative energy sources because it can be continuously used without generating pollution . Solar power generation is a PV system.

Referring to FIG. 1, a photovoltaic power generation system will be schematically described as follows. Solar power generation system can be divided into stand-alone system (Stand Alone System) and grid-connected system (hereinafter, referred to as grid-connected system).

Generally, a stand-alone solar power generation system is comprised of a solar cell array 20, a power controller 4, an inverter 6 and a battery 9. [ The solar cell array 20 converts sunlight into electric energy, and the power controller 4 controls electricity generated in the solar cell array 20 to output stable electricity. Electricity generated in the solar cell array 20 is DC, and inverter 6 converts DC into AC. That is, the direct current is converted into AC in the inverter 6 and supplied to the load 8 such as a lamp. In a stand-alone photovoltaic power generation system, it is common to include a battery 9 for storing extra electricity. On the other hand, the grid connection system is a combination of solar power generation and other types of power generation, and therefore, batteries are generally not used. Grid-connected systems are also the same in that they convert solar energy into electrical energy in solar cell arrays.

As described above, the portion that converts sunlight to electrical energy is the solar cell array 20, and thus the solar cell array 20 is an important part of the solar power generation system. The solar cell array 20 will be described in detail as follows. The solar cell 23 primarily converts the sunlight into electric energy. However, since the output voltage of the solar cell 23 is very low, a solar module (solar module) 21 is formed by assembling a plurality of solar cells 23 in series on one panel. And a solar cell array 20 in which the solar cell modules 21 are connected in series and in parallel.

As described above, the solar cell 23 converts solar light into electric energy, and thus, it is very important to efficiently convert sunlight into electric energy in the solar cell 23. For this purpose, it is effective to concentrate the sunlight to the solar cell 23, and it is also effective to make the solar light enter the solar cell 23 vertically as much as possible. Therefore, a concentrated photovoltaic generation (concentrating photovoltaic generation) in which sunlight is concentrated to the solar cell 23 using a reflector or a lens has been proposed. Centralized solar power includes a centralized solar cell unit.

Referring to FIG. 2, an example of the centralized solar power generation will be described below.

The centralized solar cell unit 30 includes a parabolic reflector 25 and a solar cell 23 located at the focal point of the parabola of the parabolic reflector 25. [ The sunlight S incident in parallel to the parabolic reflector 25 is optically gathered at the focus of the parabola. Therefore, the sunlight incident parallel to the parabolic reflector 25 is focused on the solar cell 23 located at the focus of the parabola.

3, another example of the centralized solar power generation will be described.

Another example of the centralized solar cell unit 30a includes a Fresnel lens 25a and a solar cell 23a located at the focal point of the Fresnel lens 25a. The sunlight incident in parallel to the Fresnel lens 25a optically converges at the focal point of the Fresnel lens 25a. Therefore, the sunlight incident parallel to the Fresnel lens 25a is focused on the solar cell 23a located at the focal point of the Fresnel lens 25a.

As described above, there has been proposed a convergent solar power generation system in which sunlight is concentrated by the reflector or the lens to the solar cells 30 and 30a. However, in order to increase energy conversion efficiency even in this power generation system, It is important to direct the sun, that is, to make the angle of incidence of sunlight normal to the reflector or lens. This is because, even in the case of centralized solar power generation, the sunlight incident on the reflector or the lens in parallel is concentrated by the reflector or the lens to the solar cell.

However, in a stationary solar power generation system in which the solar cell module is fixedly mounted on the ground, the incidence angle of the sunlight can not be made normal to the solar cell, the reflector, or the lens. This is because the position of the sun constantly changes with the passage of time. Therefore, in order to make the concentrated solar power generation more efficient, a tracking type solar power generation system has been proposed in which the position of the solar cell module is changed according to the change of the position of the sun. In the tracking type photovoltaic power generation system, a tracker is used which grasps the orbit of the sun and changes the position of the solar cell module so that the sunlight always enters the solar cell, the reflector, or the lens perpendicularly. Such tracking type solar power generation can increase the efficiency of light collection compared with fixed type solar power generation. However, in tracking type solar power generation, a tracker must be used unlike fixed type solar power generation. Incidentally, the tracker includes a sensor for detecting the position of the sun, a drive unit for moving the solar array, and the like, so that the apparatus is complex. In addition, the tracker has a complicated device, and accordingly, it is disadvantageous that the device is liable to be defective in a harsh environment such as a desert or a subtropical region depending on a place of installation. Trackers are also relatively expensive equipment. Therefore, development of a photovoltaic power generation system that is low in cost and high in power generation efficiency is required.

SUMMARY OF THE INVENTION The present invention provides a solar cell unit for solar power generation and a method of manufacturing the solar cell unit, which can improve light-condensing efficiency and power generation efficiency.

According to an embodiment of the present invention, the present invention provides a light emitting device having a body part having a reflecting mirror therein, the body part constituting a part of an ellipsoid; A cover part connected to the reflector and constituting another part of the ellipsoid, the cover part transmitting outside sunlight and reflecting solar light inside; And a solar cell positioned at a vertex of a long axis of the ellipsoid, wherein solar light transmitted through the cover portion is repeatedly reflected within the reflector and the cover portion to converge on the solar cell do. The body portion and the cover portion may constitute half of the ellipsoid, respectively.

The cover portion preferably includes a first member and a second member that is always coupled to the inner surface of the first member and is different in optical property from the first member. The first member may be glass, and the first member may be a film coated on the glass.

Meanwhile, it is preferable that the body portion is fixedly installed. The cover may be provided with a coating layer that reflects sunlight having a long wavelength and absorbs sunlight having a short wavelength.

According to another embodiment of the present invention, the cover portion includes a reflection portion which forms a part of the ellipsoid and has a reflection surface inside; And a light transmitting part connected to the reflecting part and constituting another part of the ellipsoid, having a plurality of through holes and having a reflecting surface inside. Preferably, the reflective portion constitutes an ellipsoid positioned outside the second focus, and the light transmissive portion constitutes an ellipsoid positioned between the first focus and the second focus. The reflective portion and the light transmitting portion are preferably provided with a chromium coating serving as a reflector. The body portion is preferably fixedly installed.

According to another aspect of the present invention, there is provided a method of manufacturing a reflector comprising the steps of: forming a reflector so as to constitute a part of an ellipsoid; Forming a cover part which constitutes another part of the ellipsoid and which transmits external sunlight and reflects sunlight inside; A step of installing a solar cell positioned at the end of the long axis of the ellipsoid, wherein the sunlight transmitted through the cover portion is infinitely reflected inside the reflector and the cover portion to converge on the solar cell, Of the present invention.

The above-described solar cell unit for solar power generation according to the present invention and its manufacturing method have the following effects.

First, according to the present invention, there is an advantage that the structure is simple and the light-condensing efficiency and the power generation efficiency can be improved.

Second, according to the present invention, there is an advantage that the light collection efficiency and the power generation efficiency can be effectively improved even at a relatively low cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram schematically showing a configuration of a general solar power generation system;
FIG. 2 is a cross-sectional view schematically showing a conventional solar cell unit of a centralized solar cell
3 is a cross-sectional view schematically showing a solar cell unit of another example of a conventional centralized solar cell
4 is a cross-sectional view schematically showing an embodiment of a solar cell unit for photovoltaic power generation according to the present invention.
5 is a conceptual diagram illustrating the principle of a solar cell unit for solar power generation according to the present invention.
6 is a cross-sectional view schematically showing another embodiment of the solar cell unit for photovoltaic power generation according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a solar cell unit and method for manufacturing solar cell according to the present invention will be described with reference to the accompanying drawings. The embodiments described below are intended to facilitate understanding of the present invention, and thus the present invention is not limited to the embodiments described below.

4, a preferred embodiment of a solar cell unit for photovoltaic power generation according to the present invention will be described.

The solar cell unit 100 for solar power generation includes a body 110, a cover 130 connected to the body 110, and a solar cell 130 disposed at a predetermined position of the cover 130 140). The solar cell 140 may be supported by a predetermined support 150. Of course, the solar cell 140 may be installed directly on the cover 130.

Meanwhile, the solar cell unit for photovoltaic power generation according to the present embodiment can fix the mounting position, not the position, according to the position of the sun. However, it is preferable that the fixed installation position is provided so as to correspond to the position of the sun in the time zone in which the incident amount is the greatest. For example, in the mid-latitude region, it can be installed in the South Pacific.

Each component of the solar cell unit 100 for a photovoltaic power generation will be described in detail as follows.

The body 110 has a reflector 111 therein. The reflector constitutes a part of the ellipsoid (P). The inner surface of the cover part 130 constitutes another part of the ellipsoid P. That is, the inner surface of the reflector 111 and the cover 130, to form a complete ellipsoid P.

The reflector 111 of the body 110 and the cover 130 merge to form one ellipsoid P and the reflector 111 of the body 110 and the cover 130 May constitute half of the ellipsoid P, respectively. The ellipsoid (P) forms a hollow revolving body formed by rotating the ellipse 360 degrees about the long axis. Since the ellipsoid (P) is a rotating body having one ellipse turned around the major axis, all the cross sections of the rotating body are elliptical, and the focus of the ellipse is the same. On the other hand, the solar cell 140 is provided at the vertex of the long axis Y of the ellipsoid P. That is, the solar cell is provided at a predetermined position of the cover 130, that is, at the vertex C2 of the long axis Y of the ellipsoid P.

Meanwhile, basically, the cover unit 130 is configured to transmit sunlight incident from the outside and to reflect sunlight incident therein. For example, the cover 130 may be configured such that all or a part of sunlight incident from the outside is transmitted, and most of the sunlight incident to the inside is reflected inside.

The cover 130 includes an outer first member 131 and a second member coupled to the inside of the first member 131 and having a different optical characteristic from the first member 131 132). In this embodiment, light is transmitted from the outside to the inside of the cover 130, that is, the ellipsoid P, and the light transmitted into the inside of the ellipsoid P is only partially transmitted to the outside of the ellipsoid P, And reflects in the interior of the ellipsoid P. That is, the light incident on the inside of the ellipsoid is reflected inside the ellipsoid and guided to the solar cell. In the ellipsoid, the light is guided to the solar cell while reflecting the light many times, using the optical properties of the ellipsoid.

In this embodiment, it is most preferable that the light transmitted to the inside of the ellipsoid (P) is not transmitted back to the outside of the ellipsoid but is entirely reflected inside the ellipsoid. However, A part of the ellipsoid may be reflected to the outside of the ellipsoid or at least a part of the light may be reflected inside the ellipsoid. This is because, if at least a part of the light incident on the inside of the ellipsoid P is reflected to the inside of the ellipsoid without being re-transmitted to the outside, and is directed toward the solar cell, the light collection efficiency is improved.

A structure for reflecting at least a part of the light transmitted to the inside of the ellipsoid P inside the ellipsoid will be described. The first member 131 and the second member 132 constituting the cover part 130 preferably have different transmittance, refractive index and reflectance, which are different from each other in optical properties. For example, the first member 131 may be made of glass, and the second member 132 may be made of a film layer or glass paint which is different from glass. Since the light passes through the first member 131 and the second member 132 having different optical properties from each other, the entire light incident on the inside of the ellipsoid P is guided to the outside of the ellipsoid P You can leave it out and at least partially reflect back inside. However, if the first member 131 and the second member 132 constituting the cover part 130 are all made of the same material, for example, glass, light that is not directed to the solar cell among light incident into the ellipsoid (P) Will all go out of the ellipsoid (P). The second member 132 may be made of semitransparent glass, a coating film, or the like.

Referring to FIG. 5, the operation principle of the solar cell unit 100 for solar power generation according to this embodiment will be described as follows.

First, the sunlight S3 incident on the focus F1 of the ellipsoid P will be described. The sunlight S3 incident at the focus of the ellipse P follows the long axis Y of the ellipsoid P when the reflection is repeated inside the ellipsoid P in the nature of the ellipse. That is, the sunlight S3, L1 incident on the focus (first focus) F1 of the ellipsoid P is incident on another focus (second focus) F2 after being reflected by the inner surface of the ellipsoid P (Refer to L2) The sunlight L2 incident on the second focal point of the ellipsoid is incident on the first focal point F1 again after being reflected from the inner surface of the ellipsoid (refer to L3). The light converges to the long axis Y of the ellipsoid P. The solar cell 140 is provided at the vertex C2 of the long axis P of the ellipsoid P in the present embodiment do. The sunlight incident on the first focus F1 or the second focus F2 of the ellipsoid P repeatedly reflects inside the ellipsoid P and finally collects in the solar cell 140. [ By appropriately adjusting the size of the ellipsoid P or the size of the solar cell 140, light can be converged to the solar cell 140 after a small number of reflections, for example, about 4-5 times of reflection.

The sunlight entering near the focuses F1 and F2 of the ellipsoid P also follows the long axis Y of the ellipsoid P while repeating reflection in the ellipsoid P as well. This is because the incident light at the non-focal point of the ellipsoid P has the same incident angle and the same reflection angle at the reflective surface. Therefore, if the reflection is repeated inside the ellipsoid, the light is gradually oriented in the focusing direction, (Y). On the other hand, sunlight incident in parallel with the long axis Y of the ellipsoid P can obtain similar results. This is because the incidence angle and the reflection angle are the same in the case of the sunlight incident parallel to the long axis Y of the ellipsoid P and therefore the sunlight incident on the long axis Y of the ellipsoid P in parallel Substantially coincides with the long axis Y of the ellipsoid P. [ The sunlight other than the sunlight incident on the short axis X of the ellipsoid P is all directed to the solar cell 140 located at the vertex C2 of the long axis Y of the ellipsoid P, Convergence.

As described above, in the solar cell unit 100 according to the present embodiment, sunlight is incident on the ellipsoid P, incident solar light is reflected inside the ellipsoid P, As shown in Fig. Therefore, theoretically, it is most preferable that the light incident on the inside of the ellipsoid P can be totally reflected inside without externally retransmitting. However, a part of the light incident on the inside of the ellipsoid P goes out to the outside, and the light collecting efficiency is increased even if only a part of the light is reflected inside the ellipsoid P. This is because, in the conventional stationary solar power generation system, the solar power generation is substantially performed only for the time when the sunlight is vertically incident on the solar cell, and when the sunlight inclines to the solar cell, . Actually, sunlight used for solar power generation is only about 3.5 hours a day, depending on the region. In this embodiment, however, even when the sunlight inclines to the solar cell, the sunlight is generated irrespective of the orbit of the sun because the solar cell repeatedly reflects from the inside of the ellipsoid repeatedly. An effect of extending is generated. Therefore, even if all of the sunlight incident on the ellipsoid P does not reflect inside the ellipsoid P, the generation of sunlight reflected at the inside of the ellipsoid P is increased at least. Therefore, according to this embodiment, there is an advantage that the power generation efficiency can be improved at almost the same cost as the fixed solar power generation. Of course, conventional tracking solar power generation may provide more effective solar power generation, but as described in the prior art, tracking solar power requires the use of a tracker, which requires complex equipment and a significant increase in cost. Therefore, according to the present invention, the power generation efficiency can be improved at least as compared with the fixed solar power generation without using the tracker.

On the other hand, as described above, the position of the solar cell unit 100 for solar power generation according to the present embodiment is not changed depending on the position of the sun, but the installation position is fixed. It is preferable that the fixed installation position is provided so as to correspond to the position of the sun in the time zone in which the incident amount is the greatest. As described above, according to the solar cell unit 100 for solar power generation according to this embodiment, the solar light other than the sunlight incident in the short axis direction S4, that is, the focus direction S3 and the long axis direction S1 The sunlight entering in the direction of the focal point and the long axis S2 follows the long axis Y and is finally collected by the solar cell 140 installed at the vertex C2 of the long axis Y of the ellipsoid P . That is, according to the present invention, although the position of the solar cell unit 100 for the solar power generation is fixed, the position of the sun is changed, so that even if sunlight is incident in any direction (except for the short axis direction S4) Reflection is repeated in the inside of the cover part 130, and finally collected in the solar cell 140, so that the solar power generation time is extended, and consequently, the light collection efficiency and the power generation efficiency are improved. Therefore, according to the solar cell unit for solar power generation according to the present invention, it is possible to improve the light-condensing efficiency and the power generation efficiency without using an expensive tracker.

6, another embodiment 100a of the solar cell unit for photovoltaic power generation according to the present invention will be described.

The present embodiment is similar to the above-described embodiment in working principle. However, the structure of the cover portion is different from the above-described embodiment. Therefore, the structure of the cover portion 200 will be mainly described. The cover portion 200 according to the present embodiment also constitutes a part of the ellipsoid P in the same manner as the above-described embodiment. The cover unit 200 according to the present embodiment includes a reflector 230 that forms an ellipsoid in the outer direction of the second focus F2 and a second focus F2 that is connected to the reflector 230, And a light transmitting portion 220 constituting an ellipsoid P between the first focus F1 and the first focus F1. The inside of the reflection portion 230 and the light transmission portion 220 are both processed to serve as reflectors. The light transmitting portion 220 is provided with a plurality of through holes 240 for guiding light into the ellipsoid. Therefore, in the present embodiment, the light passing through the through hole 240 of the light transmitting portion 220 is reflected from the inside and converged into the solar cell 140.

For example, the entire cover 200 may be made of glass, chromium plating may be applied to the inside or the outside of the cover 200, and the light transmitting part 220 may be provided with a predetermined number The through-holes 24 of the through-holes can be formed.

In this embodiment, since light is incident into the ellipsoid P through the through hole 240 of the light transmitting portion 220, the incident amount incident on the inside of the ellipsoid P is smaller than that of the above embodiment have. However, since the light is repeatedly reflected by the inside of the ellipsoid P and converged to the solar cell 140, solar light can be incident on the solar cell 140 perpendicularly regardless of the orbit of the sun, Thereby improving the light collecting efficiency and power generation efficiency.

In the solar cell unit 100a for solar power generation according to the present embodiment, the installation position can be fixed instead of changing the position according to the position of the sun. In this embodiment, it is also possible to provide the solar cell unit 100a in the focal direction of the ellipsoid P. Of course, it can also be installed in the South Pacific.

According to another embodiment of the solar cell unit for photovoltaic power generation according to the present invention, a coating layer that reflects sunlight of a long wavelength and absorbs sunlight of a short wavelength is provided outside the cover parts 130 and 200 desirable. With this configuration, it is possible to prevent heat from being generated in the solar cell units 100 and 100a. In the photovoltaic unit for solar power generation according to the present invention, the solar cell may use various types such as silica series and gallium arsenide series, but it is preferable to use a gallium arsenide series. The present invention can also be applied to a tracking type photovoltaic power generation system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. That is, the present invention is not limited to the embodiments described above, and various modifications and variations are possible in light of the above description of the present invention.

100: solar cell unit 111: reflector
130: Cover part 140: Solar cell

Claims (11)

The reflector having a body portion constituting a part of the ellipsoid;
A cover part connected to the reflector and constituting another part of the ellipsoid, the cover part transmitting outside sunlight and reflecting solar light inside;
A solar cell positioned at a vertex of the major axis of the ellipsoid and converting the solar light into electric energy,
Wherein the solar light is incident substantially through the entire cover portion, and the incident solar light is repeatedly reflected within the body portion and the cover portion to converge on the solar cell, and the solar light is reflected by the solar cell Solar cell unit for solar power conversion into energy. 2. The solar cell unit for solar power generation according to claim 1, wherein the body portion and the cover portion constitute half of the ellipsoid. 2. The solar cell unit for solar power generation according to claim 1, wherein the cover portion includes a first member and a second member that is always coupled to an inner surface of the first member and is different in optical property from the first member. 4. The solar cell unit for solar power generation according to claim 3, wherein the first member is glass, and the second member is one of a film and a glass paint coated on the glass. 5. The solar cell unit for solar power generation according to any one of claims 1 to 4, wherein the body portion is fixedly installed. The solar cell unit for solar power generation according to claim 5, wherein the cover portion is provided with a coating layer which reflects sunlight of a long wavelength and absorbs sunlight of a short wavelength. [2] The apparatus of claim 1, wherein the cover comprises: a reflector having a reflective surface and a reflective surface; And a light transmitting portion connected to the reflecting portion and constituting another part of the ellipsoid, the light transmitting portion including a plurality of through holes and having a reflecting surface. [8] The apparatus of claim 7, wherein the reflective portion constitutes an ellipsoid positioned outside the second focal point, and the light transmitting portion constitutes an ellipsoid positioned between the first focal point and the second focal point. Solar cell unit. [10] The solar cell unit of claim 8, wherein the reflective portion and the light transmitting portion are provided with a chromium coating serving as a reflector. 10. The solar cell unit for solar power generation according to claim 9, wherein the body portion is fixedly installed. Making a reflector to construct a part of the ellipsoid;
Forming a cover part which constitutes another part of the ellipsoid and which transmits external sunlight and reflects sunlight inside;
And installing a solar cell for converting the solar light into electrical energy at apexes of the long axis of the ellipsoid,
Wherein the solar light is incident substantially through the entire cover portion, and the incident sunlight is repeatedly reflected within the reflector and the cover portion to converge on the solar cell, and the solar light is converted into electric energy Wherein the solar cell module is a solar cell module.

Images