KR20150103350A - Photovoltaic System And Method Using Uniformly Condensed Solar Beam by Flat Mirrors and Cooling Method of Direct Contact - Google Patents

Abstract

The present invention relates to a photovoltaic power generation device and a method using photoelectric effect, and provides a device and a method of producing more power from a solar cell of the same surface area by combining relatively cheap additional devices such as flat mirror, sunlight tracking device, and a cooling member with an expensive solar cell. Especially, the present invention provides a device and a method for effectively preventing the degradation of the photoelectric conversion efficiency according to an increase in temperature. The present invention provides the photovoltaic power generation device having a cooling system, and the cooling system comprises: a sealing housing having at least one opened portion in at least one side; a transparent window sealing the housing by closing the opened portion, and allowing an incident light, so that the light can be incident on the light receiving surface by transmitting the incident light; a holder fixing the solar cell so as to be arranged with predetermined intervals from the inner surface of the transparent window inside the housing; a refrigerant cooling by surrounding the solar cell by filling the inside of the housing.

Description

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a photovoltaic power generating apparatus and method using a uniformly condensed light beam and a direct contact cooling method using planar mirrors,

The present invention is directed to providing a commercially available solar power generation method and apparatus. In particular, by combining sunlight condensation, solar tracking, and cooling of solar cell substrates, the price of solar power generation can be lowered and solar power generation, which can compete with conventional power generation methods such as thermal power generation and nuclear power generation, The technical purpose is to provide the technology.

It has been over a century since Einstein discovered the photovoltaic phenomenon, and solar cells developed by US NASA have been used for satellites for more than half a century. However, the solar power generation business, which has been known for decades, is still not successful as a profitable self-reliance project. The main reason is the price of expensive solar cell substrates. As of April 2013, solar cell substrates are reported to be available at a price of approximately $ 1 / 1W. In Korea, the power supply price is reported to be approximately 0.1 $ / KWh. The comparison between the purchase price of solar cell substrates required for a 1MW solar cell power plant and the annual electricity production (electricity sales) is as follows. (In Korea, it is reported that when converted to averages over the year, solar power generation can be performed by receiving 1KW / m ² of sunlight for an average of about 3.5 hours per day.)

1MW Solar Cell Board Price: $ 1,000,000; 1 $ / 1W

Annual production of 1MW solar cell substrate (annual electricity price): 1MW × 3.5h × 365 days = 1,277.5 MWh / year ($ 127,750 / year)

In other words, only the cost of purchasing a solar cell substrate is required to input 7.8 years of electric power sales income, and other incidental costs (except for the land cost, it is reported that the solar cell substrate cost is almost equal to the solar cell substrate cost). The solar power industry is not attractive at this point. Exceptionally, there are reports that some areas, such as Italy and Hawaii, where commercial power prices are high and solar radiation are abundant, are close to grid parity. (Grid Parity: When the commercial power price is equal to the PV price; in Korea, the power supply is relatively low, so it is more difficult to achieve the grid parity.)

At present, governments including Korea are trying to foster the photovoltaic power generation industry through FIT and RPS, but there is a limit due to the financial burden. Therefore, there is an urgent need to secure commercially viable solar power generation technology, which means that a technology for lowering the power generation cost in the photovoltaic power generation field is needed.

It is important to produce more power on a solar cell substrate of a given area. To this end, attempts have been made to increase the photoelectric conversion efficiency of the solar cell, to increase the efficiency of the solar cell by suppressing the temperature rise of the solar cell module, to increase the cost of the power production by concentrating light, .

The prior art, which is deeply related to the technical idea of the present invention, is a photovoltaic power generation technology in which light is condensed and cooled.

Figs. 1A to 1D are representative views of a conventional patented technology relating to solar power generation technology using condensation. A representative diagram of the patent of JP 2009-545186 A (FIG. 1A), JP 2003-536244 A (FIG. 1B), JP 2009-533841 A (FIG. 1C) and JP 2009-545877 A (FIG. Figures 1A, 1B, and 1C all use lenses or spherical mirrors, thus still including the problems of the prior art described below. 1D is related to the content of the present invention in that a flat mirror is used for condensing, but under the structure shown in FIG. 1D, the present invention (hereinafter, referred to as " condensing using planar mirrors " It is difficult to concentrate the high level of pursuit.

FIG. 1E is a view attached to explain the problem of the prior art pointed out in "Convergence using Planar Mirrors" of the "Challenge Solution " In the conventional case using a curved lens, a Fresnel lens or a curved mirror, the condensed beam has a non-uniform intensity in a radial direction, and the condensed beam has a circular shape Therefore, there is a problem that the shape of the rectangular solar cell substrate is not matched.

In order to use a tandem type solar cell having a high photoelectric conversion efficiency but a small area and a high photoelectric conversion efficiency, the conventional light collecting technique requires a uniform light intensity Which is not suitable for focusing.

In the related art related to cooling, there is a method such as air-cooling by a heat sink, water-cooling method in which a back surface of a solar cell module is brought into contact with a heat sink in which a coolant is loaded or flowing, but only the back surface of a solar cell substrate is cooled And the refrigerant does not directly contact the outer surface of the solar cell substrate, and thus the cooling efficiency is insufficient.

JP 2009-545186 A JP 2003-536244 A JP 2009-533841 A JP 2009-545877 A

The problem to be solved by the present invention is to lower the price of photovoltaic power generation so that the photovoltaic power generation business can be carried out commercially without a support policy in the public sector. That is, it is a technical object to provide a method and apparatus capable of producing a large amount of electric power from a solar cell substrate having a constant area.

The task solution of the present invention is to selectively combine the following three main technical ideas.

1. Convergence using plane mirrors

Problems of the conventional condensing technique using a condensing lens or a concave mirror are as follows.

(2) a rectangular solar cell substrate and a concentrically focused beam (a concave mirror using a convex lens, a Fresnel lens, or a parabolic curved surface), and (3) the weight of the condenser is not small, (4) the intensity of the condensed sunlight is non-uniform in the radial direction, and the like. (See Figure 1e)

The unevenness of the light intensity of the condensed beam has a bad influence on solar power generation. In the case of the solar heat collecting apparatus distinguished from the photovoltaic power generation, even if the light intensity of the condensed beam is not uniform, it is not a problem. In the case of using solar heat, the total amount of condensed solar light reaching the solar collector is of concern, and the uniformity of the condensed sunlight beam has little effect on the performance. However, in the case of photovoltaic power generation, the uniformity of the condensed sunlight beam has a very important influence on the performance. This is because the output current of the unit cells connected in series is determined by the smallest value among the output currents of the unit cells connected in series and the output current of each unit cell is proportional to the local light intensity of the sunlight incident on each unit cell to be.

The present invention can easily and inexpensively avoid the problems associated with the conventional condensing method by concentrating the uniform reflected light with the rectangular planar mirrors so as to match the shape (rectangle) of the solar cell substrate by superimposing the reflected light on the solar cell substrate have.

2. Solar tracking system

Since the present invention is a photovoltaic power generation system through condensation, a high efficiency can be obtained by applying a solar tracking system together. The solar tracking system is a long known and commercially available system in the art.

3. Cooling

Even in the case of a conventional silicon-based solar cell module that does not concentrate solar light, it is reported that the photoelectric conversion efficiency is decreased by a certain rate (about 0.5%) every time the temperature rises by 1 degree Celsius have. When the sunlight is collected several to ten times from the solar cell substrate by the present invention, the temperature rise and the rapid decrease of the photoelectric conversion efficiency will be inevitable. The inventors' prediction is as follows. The semiconductor layer is most sensitive to temperature rise and has the greatest effect on photoelectric conversion efficiency. The conventional cooling method is a method of cooling the outer surface of the rear surface relatively far away from the semiconductor layer. In this method, the temperature rise of the semiconductor layer, which absorbs sunlight and generates free electrons and has the greatest influence on the photoelectric conversion efficiency, can not be effectively prevented.

One embodiment of the present invention proposes to dispose a solar cell substrate in a container containing a refrigerant. The light receiving surface of the solar cell substrate is disposed facing a transparent window through which sunlight is transmitted. A preferred example of a refrigerant is water (cold water). The solar cell substrate is spaced apart from the inner surface of the transparent window by an appropriate distance so that convection of the cooling water can be smoothly performed, and the interval is set small so as to minimize the amount of sunlight absorbed by the cooling water.

Cooling water with a large specific heat will directly contact the entire outer surface (front and back) of the solar cell substrate, resulting in much higher cooling efficiency than conventional cooling techniques.

1. We lower the price of solar power generation. That is, when the same cost is invested in the photovoltaic power generation equipment, maintenance and repair, it produces more electric power than the conventional method. Planar mirrors are much cheaper, lighter and more mass-produced than the prior art means (lenses, curved mirrors, etc.) required for focusing.

2. Prevent deterioration of solar cell substrate and prolong its service life. This is an added effect that can be gained from the embodiment in which the solar cell substrate is placed inside the cooling container.

3. Sufficient light intensity can be illuminated on each solar cell substrate even under low sunlight conditions (morning, late afternoon, winter, high latitude, cloudy or misty weather). If the number of planar mirrors is sufficiently increased, the solar light can be uniformly collected on the solar cell substrate even when the solar light intensity is very low, which is higher than the solar light intensity when the sun is at the ceiling.

4. Concentration of uniform light intensity can be easily performed on the entire solar cell substrate even if the precision is low. This is an effect that can be obtained by adding the horizontal and vertical widths of the plane mirrors to a margin larger than a value given by m _x = p _x cos? _X and m _y = p _y cos? _Y described later. The greater the magnitude of the margin, the lower the accuracy required. (It is easy for an ordinary technician to understand the reason through the contents of Figs. 4 and 5.)

1A to 1D are representative views of prior art patents related to solar power generation using condensing.
1E is a view for explaining a problem of a conventional condensing technique using a lens or a curved mirror.
2 is a view for explaining a light collecting method and a solar tracking system using a planar mirror according to the present invention.
3 is a view for explaining a cooling method using a container of the present invention and a condensing method using planar mirrors. (Representative of the present invention)
FIGS. 4 and 5 are diagrams for explaining a condensing capability calculation process and a magnitude relation by plane mirrors of the present invention.
FIG. 6 is a diagram for explaining a light-condensing capability calculation process assuming the arrangement of 24 plane mirrors and the case of xy symmetry in FIG. 2;
7 is a view for explaining a cooling container of the present invention in detail;
8 is a view for explaining a center of gravity Q of a frame, showing a form of a frame different from that of Fig. 2; Fig.
9 is a view for explaining an auxiliary solar cell substrate (Supplementary Panel).
Figs. 10A, 10B and 10C are diagrams for explaining the calculation of the passing distance of the atmospheric layer according to the altitude change of the sun and the attenuation according to the altitude change of the solar light intensity. Fig.
FIG. 10D is a graph for calculating a change in condensing ability according to a change in distance between a solar cell substrate and a structure in which a plane mirror is arranged. FIG.
11A and 11B are diagrams for explaining the calorific power discharge capability of a solar photovoltaic module submerged in cooling water;

The present invention provides a method and apparatus for producing maximum power in the same solar cell substrate by applying a method of collecting light by a plane mirror, tracking solar light for collecting light, and cooling heat by condensing, Will be described in detail with reference to the accompanying drawings. FIG. 2 is a diagram for intuitively understanding the uniform light collection by the planar mirror and the solar light tracking method for collecting light. FIG. 3 shows an example of a method of cooling heat by condensation.

Referring to FIG. 2, the following will be described.

The solar cell substrate (photovoltaic panel) is arranged so that its light receiving surface is parallel to the direction of incidence of sunlight. That is, when the traveling direction of sunlight is defined as the + z-axis, the normal to the light receiving surface side of the solar cell substrate is the + z-axis direction. I will go over one point here. (0, 0, 1) in the normal direction of the solar cell substrate light receiving surface when the unit vector in the solar propagation direction is (0, 0, 1) is the best, efficient, and easy to calculate . However, in order to avoid an attempt to avoid the claims of the present invention in the claims of the present invention, unit vectors in the normal direction of the solar cell substrate light receiving surface are not limited to (0, 0, 1) as described above.

Each of the plurality of flat mirrors is fixed while being inclined at an appropriate angle in the x-axis direction and the y-axis direction, respectively, so that the incident sunlight is incident on the solar cell substrate at a uniform intensity And reflects as reflected light. Each planar mirror is set to have a different size and direction depending on its position, but it must be set so that its reflected light completely covers the light receiving surface of the solar cell substrate.

BRIEF DESCRIPTION OF THE DRAWINGS In the following, the present invention will be described in more detail with reference to the accompanying drawings. It is an important point of the present invention that the light receiving surface of the solar cell substrate is arranged while the sun is upside down. I will express it as follows. When the unit vector in the traveling direction of sunlight is (0, 0, 1), the z-axis component of the normal direction unit vector of the solar cell substrate light receiving surface is positive. Otherwise, it means that the z-axis component of the unit vector in the normal direction of the solar cell substrate light receiving surface is negative or zero, which means that the light receiving surface of the solar cell substrate is facing the sun or parallel to the traveling direction of the sunlight. ) It is very difficult to raise the light intensity of the uniform light intensity to a high level using a planar mirror. It is easy to grasp using plane geometry, so a detailed explanation will be omitted.

By applying the condensing technique of the present invention, it is possible to easily project sunlight condensed on a large and uniform solar cell substrate at a high level. The degree of condensation can be easily adjusted by adjusting the number of flat mirrors. When the sunlight intensity is too high in the summer (one day), some of them are covered with opaque objects, and the direction is changed. (Intensity of incident light) can be varied by the method of FIG. To this end, it is preferable to further include another means for varying the number of plane mirrors used for focusing among the plane mirrors.

The frame fixes the solar cell substrate and the plurality of plane mirrors so that the above-mentioned positional relationship is maintained with respect to the traveling direction of the sunlight. The frame is also connected to a rotation tracking system that rotates in both horizontal and vertical directions.

The rotation mechanism rotates the frame in the horizontal and vertical biaxial directions according to the change of the position of the sun so that the arrangement relationship for concentrating the solar cell substrate fixed on the frame and the plane mirrors is maintained. do.

The post (also referred to herein as the supporting structure) supports the weight of the components (frame, solar tracking system, solar cell substrate, planar mirrors) and is primarily fixed to the ground However, it may be designed to be mobile.

One embodiment of the cooling system will be described with reference to FIG.

In the case of using the 24 plane mirrors as in the embodiment of FIG. 2, the intensity of the sunlight incident on the solar cell substrate can be increased to 20 times or more as compared with the usual case. Such a strong incident light causes the temperature of the solar cell substrate to rapidly rise, and in particular, the crystalline silicon (Si) type solar cell loses its function at a high temperature. Therefore, in the case of at least a crystalline silicon (Si) -based solar cell, cooling is indispensable.

As shown in FIG. 3, the most effective method is to dispose a solar cell substrate in a container having a transparent window through which solar light can pass, and to cool the remaining space inside the container to a coolant. Most typically water). It is more effective to let refrigerant flow into / out of the container.

It is also conceivable to provide a circulator (Circulator of FIGS. 7 and 9) so that the solvent is circulated inside the container even when the refrigerant does not flow into / out of the container. Even if the refrigerant does not flow in / out and forced circulation, if the mass of refrigerant is sufficient, at least the outer surface of the solar cell substrate can be cooled to a certain temperature range by thermal convection of the refrigerant itself.

4, 5, and 6, the positional relationship between the solar cell substrate and the plane mirror, the size, and the intensity of the reflected light will be described in more detail.

4, it is assumed that the traveling direction of sunlight is the + z-axis direction. Assume that the light receiving surface of the solar cell substrate is oriented in the + z axis direction (that is, the light receiving surface of the solar cell substrate is in the sun), and the center P of the light receiving surface is located at (0, 0, 0) .

When the angle M between the line segment PM and the z axis is 2 ?, the reflection light from the plane mirror is reflected by the plane mirror in the direction of the -z axis and the center M of the reflection plane is located at (0, d, If the entire solar cell substrate is to be covered, the plane mirror must be tilted by θ about a straight line (y = d, z = 1) parallel to the x axis. (Hereinafter, such rotation is referred to as "[theta] _y " regardless of the direction of the center axis of rotation.) Likewise, the angle of the plane mirror, which should be inclined along the x- The angle is called "θ _x ".)

In this case, the relationship tan2? = D / l, cos? = M / p, cos? = B / m holds. (Where p is the y- axis direction width, and b is the y-axis direction width of sunbeam reflected by the plane mirror and incident on the solar cell substrate.

Therefore, in order to completely cover the solar panel with the length p of one side with the reflected light, the minimum length m of the corresponding side of the plane mirror is m = pcosθ, and the light width b of the incident side of the sunlight at that time is b = pcos ² θ.

The above relationship applies equally to a plane mirror spaced apart in the x-axis direction.

Thus, the extent of θ _x as long as, in the case of the reflected light of θ _y plane mirror (Mirror) inclined by the y-axis direction, b _x × b _y = p _x cos ² θ _x × p _y cos ² θ _y in the x-axis direction because uniformly reflect the sunlight on the solar cell substrate having the width of the p _x × _y p incident to, and is given a light collecting power of the plane mirror inclined by the (θ _x, θ _y) as follows:

(θ _x , θ _y ) = cos ² θ _x × cos ² θ _y .

For example, the condensing ability will be described below.

When the reflection surface center point M of a certain plane mirror is located at (d _x , d _y , l) and the light receiving surface center point P of the solar panel panel is located at (0, 0, 0) The angle formed is 2θ _y in the yz plane and 2θ _x in the xz plane, and the following relationship holds between them.

_{tan2θ y = d y / l,} cosθ y = m y / p y, cosθ y = b y / m y

_x d = _x tan2θ / l, cosθ = _x m _x / p _x, b _x = _x cosθ / m _x

가 되고, 그때 상기 평면거울에 의해서 반사되어 태양전지기판으로 균일하게 입사되는 태양광은, 반사되기 전의 원래 태양광 진행방향에 수직인 직사각형 평면

로 입사되는 광량을 태양전지기판의 면적 p_x×p_y 에 균일하게 투사한다는 것을 의미한다.The above formula relate to the required minimum (width x length) size of the plane mirror when the (horizontal x vertical) size of the solar cell substrate is p _x x p _y

And the sunlight uniformly incident on the solar cell substrate by the reflection by the plane mirror at that time is a rectangular plane perpendicular to the original solar light traveling direction before reflection

Means that the amount of light incident on the solar cell substrate is uniformly projected onto the area p _x x p _y of the solar cell substrate.

이다.Thus, the condensing ability of a planar mirror inclined to (θ _x , θ _y )

to be.

Referring to FIGS. 5 and 6, let us consider how much the 24 plane mirrors of FIG. 2 condense solar light of a certain amount of light. For convenience of calculation, suppose that p _x = p _y = p, that is, the solar cell panel is a square shape, and the arrangement of the planar mirrors is symmetrically arranged in the xy plane. Then, as shown in FIG. 6, 24 plane mirrors will have five condensing powers of G1 to G5.

In Fig. 5, d1 = 1.2p and d2 = 2.4p are set, and when L = 3p, 5p, and 0.5p, respectively, the light condensing ability is calculated as follows.

When L = 5p,

,

,

,

(4개); (θ_x1 , θ_y1 중 하나는 0도)Concentration of G1:

(4); (one of? _x1 and? _y1 is 0 degree)

(4개); (θ_x2 , θ_y2 중 하나는 0도)Concentration of G2:

(4); (one of? _x2 and? _y2 is 0 degree)

(4개)Concentration of G3:

(4)

(8개)G4's condensing ability:

(8)

(4개)Concentration of G5:

(4)

When L = 5p, 24 planar mirrors converge the incident light to 22.756 times (under symmetrical arrangement conditions as above)

When L = 3p,

,

,

,

,

(4개); (θ_x1, θ_y1 중 하나는 0도)Concentration of G1:

(4); (one of? _x1 and? _y1 is 0 degree)

(4개); (θ_x2, θ_y2 중 하나는 0도)Concentration of G2:

(4); (one of? _x2 and? _y2 is 0 degree)

(4개)Concentration of G3:

(4)

(8개)G4's condensing ability:

(8)

(4개)Condensation power of? G5:

(4)

When L = 3p, 24 planar mirrors condense the incident light to 21.164 times (under the symmetric arrangement conditions above)

When L = 0.5p,

,

,

,

,

(4개); (θ_x1, θ_y1 중 하나는 0도)Concentration of G1:

(4); (one of? _x1 and? _y1 is 0 degree)

(4개); (θ_x2, θ _y2 중 하나는 0도)Concentration of G2:

(4); (one of? _x2 and? _y2 is 0 degree)

(4개)Concentration of G3:

(4)

(8개)G4's condensing ability:

(8)

(4개)Concentration of G5:

(4)

When L = 0.5p, 24 planar mirrors converge the incident light to 11.876 magnifications (under the symmetric arrangement conditions above)

That is, even though the distance L between the solar cell substrate panel and the plane plane in which the planar mirrors are arranged is a short distance of 0.5p, it can be seen that the 24 plane mirrors of FIG. 2 converge to 10 times or more .

In principle, it is as follows. Under the condition that the reflecting surfaces of the plane mirrors are all on the right (z> 0) of the plane where z = 0 (that is, the plane in which the light receiving surface of the solar cell substrate is infinitely extended, that is, the xy plane) Even though? ₁ and? ₂ are smaller than 45 degrees. Therefore, the condensing powers of G1 to G5 are 0.5 (four), 0.5 (four), and 0.25 (four), respectively, under the conditions of the 24 plane mirror arrangement and the xy symmetrical arrangement (square shape) 0.25 (8), 0.25 (4), and the total light collecting ability is larger than 8. (However, it is possible that the above analogy can be arranged so that the plane mirrors do not interfere with the incident light and the reflected light.) If L is too small, it is difficult to align the plane mirrors so that no obstacle is located in the optical path .

Assume that L = 0.25p. L = 0.25p, and any other criteria, (d1, d2 size) surfaces is also the same as the examples of the above, θ ₁ = 39.16 FIG, ₂ θ = 42.03 degrees and the condensing ability of the G1 ~ G5 are respectively 0.601, 0.552, 0.361, 0.332, 0.305, and the total condensing power of 24 mirrors is 9.932.

If L has an infinite size (θ ₁ , θ ₂ converge at all 0), the light collecting ability of G 1 to G 5 is all 1, so the total light collecting ability by the 24 plane mirrors of FIGS. .

However, it is very inefficient to set L to increase the total condensing ability. If the size of L exceeds 5p (5p is approximately equal to the width and width of the reflector structure formed by the 24 planar mirrors in Fig. 2), the structure volume of the solar photovoltaic system (exactly z- While the increase in the total condensing ability is not so great. It is easier and more effective to reduce the distance L to the plane formed by the centers of the reflecting surfaces of the plane mirrors as small as possible and instead increase the number of plane mirrors. (In the above, it can be assumed that the centers of the reflective surfaces of the planar mirrors are approximately in the same plane, but this does not mean that the centers of the reflective surfaces of the planar mirrors must be strictly coplanar.)

Increasing the number of planar mirrors can be accomplished simply by placing another 24 planar mirrors outside the planar mirrors of FIG. That is, in FIG. 2, the planar mirrors are doubly surrounded (8 + 16) around the planar mirror, and if necessary, 24 planar mirrors can be further disposed on the third outline.

In addition, since the planar mirrors always project uniformly reflected light on the light receiving surface of the solar cell substrate, regardless of the number and arrangement of the plane mirrors used, do.

In the range of 0.1?? 10, the light condensing ability of 24 planar mirrors of FIG. 6 is set to L =? P in the above condition (square solar cell substrate (px p), d1 = 1.2p, d2 = 2.4p) Are shown in the graphs of Table 1 and Figure 10d below.

(Here, G1 = cos ² θ _{1 ^{and, G2 = cos 2 θ 2,}} G3 = cos 4 θ 1, G4 = cos 2 θ 1 × cos 2 θ 2, G5 = cos 4 θ 2,

2? ₁ = arctan (d1 / L) and 2? ₂ = arctan (d2 / L).

From the graph of FIG. 10D, it can be understood that it is reasonable and realistic to set? Within a range of 0.5 to 5. [

It has already been stated that the centers of the reflective surfaces of planar mirrors need not all be on the same plane. Rather, the centers of planar mirrors may be better spaced alternately to two or more imaginary planes spaced apart moderately. This is due to the smooth flow of wind to the empty space between the planar mirrors and the planar mirror or frame to withstand strong winds. The fact that the distance between planar mirrors is sufficiently large, such as d1 = 1.2p and d2 = 2.4p in the previous embodiment, is also taken into account in order to reduce the effect of this wind (in fact, , Because planar mirrors must be set to have a margin of sufficient magnitude that the required minimum width is needed to overcome the alignment error, as described below.)

The width m of one side of the planar mirrors is preferably slightly larger than the required minimum size pcos?. This is because the reflected light can completely cover the light receiving surface of the solar cell substrate all the time, despite the misalignment of the plane mirrors, the alignment error of the solar cell substrate, and the operation error of the solar tracking system.

This has been fully explained by the use of planar mirrors for solar light condensation.

Hereinafter, the cooling method will be described in more detail.

As can be seen from the above, by using the 24 plane mirrors of FIG. 2, the light can be condensed at 8 to 24 times according to the z-axis direction distance L between the solar cell panel and the planar mirrors. In this case, particularly in a crystalline silicon (Si) -based solar cell, power can not be normally produced without cooling due to temperature rise due to light condensation.

It is a well-known phenomenon that the efficiency of power generation increases when the solar cell substrate is cooled. The crystalline silicon (Si) -based solar cell module has a temperature rising to 60 to 70 degrees Celsius in a clear summer day, and the photoelectric conversion efficiency is lowered at a constant rate every 1 degree Celsius, Over 100 degrees Celsius is reported to stop functioning. Cooling of the solar cell substrate, particularly cooling of the crystalline silicon-based solar cell substrate, may be indispensable when the incident sunlight is condensed to 10 times or more as in the embodiment of the present invention. Even if the cost is slightly increased, Need to increase.

Another aspect of the present invention is based on the above facts.

A preferred embodiment of the cooling method of the present invention will be described with reference to Fig.

The solar cell substrate is detachably installed in a sealed container by a holder. A transparent window is removably provided in the container so that sunlight reflected by the plane mirrors can be transmitted in front of the light receiving surface of the solar cell substrate. (The reason for separating the solar cell substrate and the window is that, This is because it is convenient for maintenance such as parts replacement and repair, removal of impurities such as water moss and sediment.)

The container couples together with the window to seal the interior.

The container is provided with a valve (inlet, outlet) through which refrigerant (typically water) flows in / out. The container is also provided with a separate hole (not shown) so that various electric wires accompanying various sensors and controllers, such as two or more power lines belonging to the solar cell substrate, a refrigerant circulator, a temperature sensor that can be added as needed, There is. It is natural that the container should be sealed so that the refrigerant does not leak as a whole.

The use of water as a refrigerant is inexpensive, readily available, present in large quantities, harmless to the environment, and one of the highest specific heat. The large specific heat means that the temperature rise of the solar cell substrate is effectively suppressed. (Conventional air-cooling method has insufficient cooling efficiency.) The embodiment of the present invention is characterized in that water, which is a refrigerant, The cooling efficiency is significantly higher than that of the conventional water-cooling method in which only the rear surface of the solar cell substrate is cooled.

Of course, the solar cell substrate will be immersed in water, which requires extra attention to insulation and additional costs. However, the cooling method of the present invention will have sufficient economic efficiency, even if it can be sufficiently overcome with the present technology level and considering the added cost.

The solar cell substrate, the terminals and the electric wiring all surround the insulator, and in particular, the insulator covering the light receiving surface must have excellent permeability (especially for light in the wavelength band contributing to photoelectric conversion). It is preferable that the above-mentioned insulator has high heat transfer efficiency as much as possible, as well as good insulation. The thickness of the insulator should be as thin as possible in order to increase the heat transfer efficiency, but it should be thick enough not to deteriorate the insulation and durability.

The inner surface of the window and the light receiving surface of the solar cell substrate are arranged as close as possible. This is to reduce the amount of sunlight absorbed by the coolant (cooling water). However, it is avoided that the coolant (cooling water) in the vicinity of the light receiving surface of the solar cell substrate is arranged so close as to be difficult to convect.

Assume that the refrigerant is water, and calculate the replacement cycle of the cooling water. If the light receiving surface area of the solar cell substrate is A, the window area of the container should be larger than A. Assume that the cross-sectional area of the housing including the window is A. When the inner thickness of the container is D, the volume of the cooling water accommodated in the container is AD (the volume occupied by the solar cell substrate, etc. is negligible). The temperature of the cooling water is increased from 20 degrees Celsius to 50 degrees Celsius T = 30K), the following equation holds.

Δ Q = ADρσ ΔT = αl ₀ At

The above equation means that the amount of energy required to raise the temperature of the water in the container by 30 degrees and the amount of energy introduced by the reflected light incident on the solar cell substrate are equal.

Here, ρ = 1 g / cm ³ (water density), σ = 4.2 J / gK (specific heat of water), and α ₀ is the intensity of the condensed reflected light incident on the solar cell substrate, It means the condensing ability by the mirror, and its size has a value between 8 and 24 (in reality between 10 and 22). l ₀ is sufficient to apply AM1 = 925 W / m ² (the intensity of sunlight emitted from the sun in a clear day ceiling), which is the largest value on the earth's surface as the intensity of sunlight (the above condition is worst Condition.

When the above numerical values are substituted into the above equation, the relationship t = (D /?) (1362) (sec / cm) [sec] holds.

From FIG. 10D, it can be seen that the worst case (in terms of temperature rise) in reality is about? = 22. When this value is substituted, t = (D) (61.9) (sec / cm) [sec] is obtained.

This means that when the inner width D of the container is 10 cm, it takes 619 seconds (10 minutes or more) to raise the temperature by 30 degrees. D of 60 cm means that the temperature of the cooling water can be kept within the maximum setting value (50 ° C) without replacing the cooling water for more than 1 hour.

Whether D is designed to be small and the coolant is replaced frequently, or D is designed to be large and coolant replacement is rare, can be selected by the operator in consideration of the weight of the container and the maintenance cost. It is not difficult to keep the temperature of the cooling water in the container within a very small constant range by flowing an appropriate amount of cooling water in a proper cycle or by controlling the circulation speed of the cooling water by attaching a temperature sensor.

The housing is further provided with inlets and outlets through which refrigerant flows in and out. It is also noted that a circulator for forcedly circulating the refrigerant in the container may be further provided. The circulator may be implemented as a rotating fan or a jet device. The circulator is useful for preventing the cooling water temperature near the light receiving surface of the solar cell panel from rising more than the cooling water temperature of other parts. However, a circulator is not absolutely necessary and may be left to the dispersion of heat by the thermal convection of the cooling water.

Next, with reference to FIGS. 11A and 11B, let us calculate whether the solar cell substrate immersed in the cooling water can emit heat as much as the amount of heat obtained by receiving the sunlight condensed by the cooling water. 11A is a general structure of a solar cell module using crystalline silicon (Si).

Assuming that the thermal conductivity of the sealing material is k1, the thickness of the sealing material to the front transparent substrate is d1, the thermal conductivity of the front transparent substrate is k2, and the thickness of the front transparent substrate is d2, the thermal resistance R1 = d1 / k1 And the thermal resistance R2 = d2 / k2 of the front transparent substrate. Therefore, the total heat resistance R = R1 + R2 = d1 / k2 + d2 / k2 of the path from the solar cell element to the front side cooling water, and the heat transfer is obtained by Q = A (DELTA T) t / R. (Where DELTA T is the temperature difference between the cooling water and the surface of the solar cell element, and t is the time during which the amount of heat has flowed).

Assuming that d1 = 2 mm, d2 = 5 mm, k1 = 1 W / mK (a type of resin with a very high thermal conductivity), k2 = 0.8 W / mK (ΔT) = (ΔT) / R = (60 ° C.), the temperature of the cooling water is assumed to be 50 ° C.), the total heat resistance R is 8.25 × 10 ^-3 (m ² K / W) 1,212 W / m ² . That is, 1,212 W per 1 m ² means that the heat can be radiated to the front side. Since the back side of the solar cell module does not need to be transparent, it is possible to design the rear side heat resistance to be smaller than the front side heat resistance (for example, the rear substrate is made of a transparent glass substrate It may be composed of a metal plate, which has a much higher thermal conductivity.)

Therefore, it can be understood that at least the heat release capability is at least 2 x 1,212 = 2,424 W / m < ² > in consideration of both the front and rear sides by the embodiment of Fig. 11A and the variable value designation. the total heat resistance R can be further reduced by decreasing d1 and d2 and by selecting k1 and k2 to be larger (i.e., heat dissipation capability toward cooling water can be further increased).

In addition, if the temperature of the cooling water is low and the value of DELTA T is large, the amount of heat released can be further increased.

11B is a typical structure of a thin film solar cell (amorphous silicon, CdTe, CIGS, etc.) module. Since the transparent resin on the front side is not required, the total thermal resistance can be further reduced as compared with the case of FIG. 11A. In the case of Fig. 11B, unlike the case of Fig. 11A, the sealing material (generally, a polymer resin) may be opaque, so that the range of selection for setting the thermal conductivity k to a larger value also advantageously works.

On the other hand, since a polymer resin having a thermal conductivity k of 7 W / mK is commercially available, it is not difficult to reduce the total thermal resistance as compared with the above-described embodiment.

In the above, it has been fully examined that a solar cell module in a state of being submerged in cooling water can emit heat as much as the amount of heat it receives from condensed sunlight into cooling water.

In order to minimize the absorption of sunlight by the cooling water, the light receiving surface of the solar cell substrate and the inner surface of the window are arranged as close as possible. However, since the distance between the two surfaces is too close, it is difficult for convection of cooling water to become difficult. The cooling water whose temperature has risen near the light receiving surface of the solar cell substrate must be sufficiently convected.

A small amount of defoaming agent that suppresses the generation of bubbles can be added to the cooling water. This is because when the amount of air bubbles floating in the cooling water increases, the path of sunlight incident on the solar cell substrate is disturbed. The solid precipitate is formed by the impurities contained in the refrigerant, or the formation of the biological sediment such as the water-swirling algae may obstruct the course of the sunlight inside the vessel. Therefore, it is also possible to consider a configuration in which a filtering device for filtering and supplying the refrigerant is further provided, or the refrigerant further contains an antibiotic substance.

When the temperature drops below freezing, you can mix a certain amount of antifreeze with cooling water. However, it is best to use pure water as cool water as possible, considering the adverse effects on the environment, the increase in corrosion of solar photovoltaic systems, and the additional costs required for the purchase and management of antifreeze. During sunlight daylight (solar power generation) on a clear day, the cooling water will hardly freeze due to heat from the condensation of planar mirrors. The problem that occurs when cooling water freezes is that in the morning when the temperature drops below freezing, the path of sunlight incident on the solar cell panel is disturbed by ice, resulting in poor power production efficiency. What is more problematic is that, due to the volumetric expansion that occurs when the water freezes, pressure builds up inside the container, valve, hose, etc., and mechanical damage may occur. This problem will most likely occur during periods when power production has ceased (shut down), ie, during periods of no sunlight (night, cloudy days).

However, even if the coolant is pure water, there is no way to prevent mechanical damage. At night when the temperature drops below freezing, or when the freezing of the sun is not likely to occur, freezing water in the system, such as containers, valves, cooling water inflow / outflow pipes, etc., If the cooling water is filled, it is possible to solve the above-mentioned problems such as the problem that the cooling water is frozen and the operation of the photovoltaic power generation is delayed and the mechanical damage due to the volume expansion. Thin ice on the windows due to heat caused by condensation will melt soon.

In addition, since the solar cell substrate is provided inside the container and is protected by the container as shown in FIG. 7, the solar cell substrate can be made thinner (within a range where the mechanical strength is acceptable) (Mainly due to exposure to short-wavelength radiation such as ultraviolet rays, temperature change, etc.) can be reduced.

Another embodiment related to Fig. 2 will be described with reference to Fig.

8 shows four subframes each having one solar cell substrate and twenty-four planar mirrors arranged. In this case, unlike the case shown in FIG. 2, the solar tracking system includes a center of gravity Q Is best. This is because the driving force required to rotate the frame when the sun tracking system is connected to the center of gravity of the entire frame is minimized and mechanical fatigue due to gravity or wind can be minimized. In the case of FIG. 2, it is of course better to connect the center of gravity of the frame to the sun tracking sheath.

It is also natural that the shape of the frame should be designed so as not to interfere with the course of the sunlight.

As shown in FIG. 9, an auxiliary solar cell substrate (supplementary panel) may be additionally provided on the back surface of the solar cell substrate (or the cooling container) that receives the sunlight reflected by the plane mirror. This is because solar photovoltaic tracking system can be used and the sunlight incident on the rear surface of the solar cell panel or the container is uselessly used and only the temperature is raised. (In the case of the above embodiment, at least energy corresponding to the conversion efficiency of the auxiliary solar cell substrate is externally discharged in the form of electric power.)

Although not shown in the drawings, the optical filter layer may further be provided on the surface of the window and / or the mirror so as to filter light in a wavelength band not contributing to photoelectric conversion. This has an additional effect of suppressing temperature rise and deterioration of the solar cell substrate (Panel). Bandpass optical filters are best placed on flat mirrors. Because the maximum intensity of the sunlight received by the planar mirrors is AM1 (925 W / m ² ), it is possible to minimize deterioration of the optical filter due to heat or strong light. However, in this case, since the required amount of the optical filter is increased, the cost is disadvantageous. The opposite is true when attaching the optical filter to the window of the container. The optical filter can be attached on the light receiving surface of the solar cell substrate. However, this is the worst way. This means that heat is accumulated in an object (optical filter) which is in direct contact with the light receiving surface of the solar cell substrate. In addition, a substance (e.g., a dye) that performs a function similar to that of the optical filter may be mixed with the refrigerant inside the container. The use of the optical filter can be adopted alone or in combination of two or more of the above four cases (plane mirror, window, solar cell substrate, and refrigerant) depending on the position.

For incident light (especially incident light in a wavelength band contributing to photoelectric conversion), a planar mirror must have a high reflectivity, a low transmittance and a low absorption rate, and a window must have low reflectance, high transmittance and low absorption do.

I will give a few notes on the technical idea of the present invention.

1. Embodiments of the present invention have been described in consideration of a commercially available crystalline silicon (Si) -based solar cell. However, it is also possible to use thin film solar cells such as amorphous silicon, CIS, CIGS and CdTe, compound multi-junction solar cells composed of Group III-V or II-VI elements, solar cells having quantum structures, dye- , A plasmon solar cell, and the like can be applied to embodiments of the present invention.

2. The cooling system of the present invention is expected to be indispensably required in a silicon (Si) -based solar cell. However, in the case of using a solar cell substrate of a type in which the photoelectric conversion efficiency does not drop so much as the temperature rises, the cooling device disclosed in the embodiment of the present invention is not necessarily required.

3. The photovoltaic generation method using the condensing and solar tracking system of the present invention is based on the general principle of the photoelectric effect found by Einstein that the produced current (i.e., power) is proportional to the incident light intensity (or light intensity) . (The output voltage from the solar cell substrate is directly proportional to the output current because the output voltage is uniquely determined in proportion to the number of series connections of the unit cells inside the solar cell substrate regardless of the intensity of incident sunlight.) However, When the incident light intensity (light intensity) continues to increase, the solar cell substrate will not continuously increase the output current (power) value in proportion thereto. If the incident light intensity (intensity) exceeds a predetermined value, the output current (power) of the solar cell substrate converges to a certain value (saturation) or the increase rate dp / di It is predicted that the value becomes smaller. However, the aspect of the current (power) saturation value or the rate of change (dp / di) of the output current according to the light intensity is not limited to that of the semiconductor material of the solar cell substrate Type, semiconductor layer thickness, doping concentration, depletion layer thickness, lamination structure, and the like. The simplest method is to thicken the thickness of the semiconductor layer (active layer or functional layer). On lines 10-12 of patent document KR 10-2007-0004928 A (corresponding to WO 2005-096394 A1), "... incident radiation can be absorbed by functional layers, where the thickness of each functional layer is The ratio of the radiated power absorbed in the functional layer is determined and is described as ", and as the thickness of the semiconductor active layer (functional layer) is thicker, more light is absorbed and more current is generated , Supporting the inventors' expectation that the saturation value of the power or the rate of change (dp / di) of the output current will be related to the thickness of the semiconductor layer as described above.

4. As the light intensity (i) mentioned above increases

The technique of increasing the current (power) saturation value of the solar cell substrate or keeping the dp / di value high will be a very meaningful and profitable invention in itself. However, if such inventions are made, the inventions obtained motives of inventions from the inventions disclosed by the present invention, and therefore, they should be recognized as modified inventions (inventions) in relation to the present invention.

5. As described in the above item 3, the power produced by the solar cell substrate will eventually become saturated or the rate of increase will become slower as the light intensity increases. However, at least the light intensity is up to 1,000 W / m ² , at least in the case of a commercially available silicon (Si) solar cell substrate, the dp / di value has a constant value. This advantage clearly supports the utility of the present invention. This is because when the present invention is used in a case where the intensity of the sunlight is weak (when the sunlight is low, morning and late afternoon, winter, high latitude region, cloudy or misty weather, etc.) to 1KW / m ² (the value when the sun is on the ceiling, that is slightly higher than the solar light intensity of AM1 (925 W / m ²⁾ when the sunlight shines perpendicularly to the ground surface) to the light intensity over This means that it can emit sunlight. That is, when the same area solar cell substrate is used, although the number of the planar mirrors and the land area required for the solar power generation facilities will increase, the present invention can be applied even in an environment where the solar power intensity is weak, If it can produce power. This means that solar power generation projects are possible even in regions where there is a lot of cheap land available for solar power generation in Mongolia, Siberia, and Canada, but the solar power generation business is not competitive because it is a high latitude region and lacks solar radiation.

6. Regardless of the claims of the present invention, a very simplified model is used to predict how the intensity of sunlight will change with the altitude change of the sun (see FIGS. 10A, 10B, and 10C).

As shown in FIG. 10A, the lower the altitude of the sun is, the smaller the intensity of sunlight is because sunlight is blocked (absorbed, reflected, scattered) by particles such as molecules or dust in the air. The greater the number of blocking particles (gas liquid molecules, solid particles) in the path of sunlight, the more the sunlight intensity decreases. This means that the longer the path in the atmosphere of the sunlight beam is, the lower the solar light intensity is.

Compare Fig. 10 (a) and Fig. 10 (b), and compare the point P ₀ on the surface of the earth coming from the vertical direction (ceiling) with the point P on the surface of the sun Is established.)

The sunlight sunk down to P ₀ moves by H (atmospheric thickness) in the atmosphere.

로 되며, x에 대한 2차 방정식으로 정리하면

이다.Let P be the moving distance of sunlight in the atmosphere to P (distance between PQs). In the relation of the cosine second law in triangle OPQ,

, And the quadratic equation for x

to be.

이다.(Where R is the Earth's radii, H is the thickness of the atmosphere, 0 is the Earth's center, Q and Q ₀ are the (imaginary) points where the solar rays traveling at P and P ₀ meet the outermost surface of the atmosphere, Assuming that the Earth is a perfectly spherical sphere, and that solar light is not refracted as it travels in the atmosphere, finding the solution of the physically meaningful quadratic equation,

to be.

로 정의하면,here,

Lt; / RTI >

이다. (태양광의 입사각이 수직과 φ각을 이룰 때, 태양광의 대기 중 경로 길이가 x(φ)이고, β(φ)는 대기 두께 H에 대한 태양광의 대기 중 경로 길이 x(φ)의 비율이다.)

to be. (When the angle of incidence of sunlight is vertical and φ angle, the atmospheric path length of sunlight is x (φ) and β (φ) is the ratio of the atmospheric path length x (φ) of sunlight to atmospheric thickness H. )

Assuming that R = 6,400 Km and H = 100 Km,

이다.

to be.

(In fact, the Earth is an ellipsoid with an equatorial radius of 6,378 km and a polar radius of 6,357 km, but it can be assumed to be spherical.

The thickness H of the atmosphere is not actually a definite figure. Since the altitude is about 1/100 of atmospheric pressure at 30 km, and the altitude is about 1/100 million at 100 km, assuming atmospheric thickness is 100 km, there will be no big mistake. First of all, no matter how you set the thickness of the atmosphere, β (φ) has a similar shape. However, if H is set large, the value of? (?) According to? Decreases. Assuming that H = 32 Km, β (φ = 90 degrees) = 6.403, assuming that β = (φ = 90 degrees) = 20.02 and H = .

Next, let's set up a simple model of how the sunlight attenuates as it passes through the atmosphere and combine it with actual measurements to predict. It can be assumed that the amount of change in light intensity di during the atmospheric path dx changes as follows.

(The above equation is one of the most frequent and useful differential equations for analyzing natural phenomena.)

The assumption that the attenuation coefficient [gamma] (p, [lambda]) is a variable dependent on the wavelength [lambda] and the air pressure p is a physically easily acceptable assumption. (Because the atmospheric pressure p is directly related to the altitude h, the number of air molecules, and the density from the surface of the ground, neglecting temperature changes).

로 정리되고, 적분을 통해서 그 해를 구하면,The equation

, And if we obtain the solution through integration,

로 주어진다. ( l₀는 대기권 진입 직전의 태양광 세기이고, 수식의 적분은 태양광의 대기 중 진로를 따라서 계산한다.)

. ( ₁₀ is the solar intensity immediately before entering the atmosphere, and the integral of the formula is calculated along the atmospheric course of the sunlight.)

A more general solution is given below.

( l₀ ⁱ 는 대기권에 진입하기 직전의 태양광 중 파장 λ_i인 광 성분의 광 세기이고, γ_i(p)는 파장 λ_i인 광 성분의 대기 중 기압 p 인 환경에서의 감쇄 계수이다. )

(l ₀ ⁱ is the light intensity of the light component of wavelength λ _i in the solar light immediately before entering the atmosphere and γ _i (p) is the attenuation coefficient in the atmosphere of the atmospheric pressure p of the light component of wavelength λ _i . )

By measuring each wavelength band λ _i , the intensity model of the actual sunlight according to the altitude change of the sun can be accurately established. However, since it is sufficient to grasp only the approximate mode, let us simplify assumption and infer the change in intensity of sunlight according to the change in solar altitude.

The assumptions are as follows. It is assumed that sunlight consists of only two light components, λ _A , which can reach the earth's surface, and λ _B , which is attenuated before reaching the earth's surface. (Due to the absorption of ozone and the like in the upper atmosphere, the light of short wavelength such as ultraviolet rays can hardly reach the ground surface.)

로 주어진다.in this case,

.

In other words, at least in some section p, γ _B (p) >> γ _A (p), so l ₀ ^A (out-of-atmospheric light with wavelength λ _A ) attenuates in the atmosphere and reaches the remaining value.

값을 구해보자.The model is substituted into the measured values to obtain l ₀ ^A , l ₀ ^B ,

Let's get the value.

AM0 = 1353 W / m ² : Solar constant outside the atmosphere

AM1 = 925 W / m ² : Solar power when φ = 0 °

AM1.5 = 832 W / m ² : solar light intensity when φ = 45 degrees

AM1 = 691 W / m ² : Solar power when φ = 60 degrees

In Figure 10a, AM0 is the solar intensity measured in the atmosphere of the outermost Q or Q _0, AM1 is the solar intensity measured sunlight passing through the path ~ Q ₀ P ₀ P ₀ on the surface, AM1.5 And AM2 are the solar light intensities measured on the ground surface P (φ = 45 ° and φ = 60 °, respectively) from the path Q to P.

이 서로 어떠한 관계가 있는지 고찰해 보자. 태양광이 0경로(경로 Q₀P₀)를 지나갈 때의 적분값

라고 한다면, 결론적으로 태양광이 φ경로(경로 QP)를 지나갈 때의 적분값

의 관계가 성립한다.Before the actual value is substituted, the integral value when passing the path Q ₀ P ₀ (hereinafter referred to as "0 path") and the path QP (hereinafter referred to as the "φ path")

Let's consider how they relate to each other. The integral value when the sunlight passes through 0 path (path Q ₀ P ₀ )

, It is concluded that the integral value when the sunlight passes through the? Path (path QP)

.

) 또한 1:β(φ)이다. 즉, 두 경로에 따른 적분값의 비율은 두 경로의 길이 사이의 비율과 같은 것이다.The reason is as follows. As shown in FIG. 10-B, the sunlight AM1, which tilts in a vertical direction when passing through the atmospheric layers A1, A2, and A3 at different pressures, and the sunlight AM () γ _A (p), and the ratio of the paths in each atmosphere layer is 1: β (φ). Thus, the ratio of the integrals calculated along different paths

) Is also 1:? (?). In other words, the ratio of the integral values according to the two paths is the same as the ratio between the lengths of the two paths.

Therefore, applying the result discussed above with T, the following equation is established.

로 주어짐은 앞서 밝혔다.The ratio β (φ), which is the ratio of the H-to-atmosphere air passage length according to φ, assuming an atmospheric thickness of H = 100 Km,

As stated earlier.

l ₀ ^A , l ₀ ^B , T The value of? (?) Necessary for the calculation of?

In the relationship between Eqs. 10b, 10c and 10d, T is calculated as shown in Table 3 below.

The values of I ₀ ^A calculated by applying the four T values to the equations 10b, 10c, and 10d are given in Table 4 below.

Considering that it is based on extremely simplistic assumptions and deduced based on almost a qualitative consideration, the fluctuation value of T and the fluctuation value of I ₀ ^A are not so large. T values derived from the relation of AM1-AM2 to be closest to the mean value (0.3051), and the T value, the l ₀ ^A value obtained to correspond to the AM2 (1,255 W / m ²⁾ to take, AM0 (formula the l ₀ ^A value substituted in 10a) it will be to take a l ₀ ^B value (98 W / m ²⁾ obtained. (Since the light component of the λ _B wavelength is not transmitted to the surface of the earth, it does not matter what value l ₀ ^B is in terms of solar power generation.)

로 모델링 할 수 있다.In conclusion, the intensity of sunlight diverging obliquely from the vertical line and φ angle,

. ≪ / RTI >

(In the above analogy, the attenuation coefficient γ (p), which is a function of the pressure p, was not used directly.)

The calculated results of the atmospheric path length ratio? (?) And the solar intensity model i (?) According to the incident angle? Are shown in Table 5 below. FIG. 10C shows normalized? (?) And i (?) Graphs.

(In the graph of Fig. 10C, i () is expressed by Intensity ()

Although the above model relies on an extremely simplified assumption, since the constant value is determined by combining the measured values, the model may be regarded as the average intensity of the light component substantially reaching the surface of the earth. It has already been mentioned that a more accurate model can be obtained by disassembling and measuring the size of the wavelength λ _i . In particular, it would be advantageous to analyze the wavelength band contributing to photoelectric conversion in more detail.

Referring to FIG. 10C, it can be seen that the intensity of the sunlight is reduced to half when φ is in the range of 70 to 75 degrees. Even if the altitude of the sun is very low, it implies that the solar power generation is sufficiently possible through the uniform light focusing using the planar mirror of the present invention. (Of course, the lower the altitude of the sun, the higher the chance of being covered in the clouds.)

Therefore, although solar power is low enough to abandon solar power generation in the conventional system, solar power generation can be performed by the present invention.

As described above, the detailed description of the present invention fully explains the technical idea and applicability of the present invention with reference to the embodiments shown in the drawings. It should be understood, however, that the above-described embodiments are merely illustrative and that those skilled in the art will be able to make various modifications and other equivalent embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

The present invention relates to a technology relating to solar power generation, and in particular, it is a technical purpose to lower the power generation cost, and is of course industrially applicable.

Claims (14)

1. A solar power generation apparatus having a cooling system (cooling system) for cooling a photovoltaic panel, the cooling system comprising:
A hermetic container in which at least a part of at least one surface is opened,
A transparent window that closes the open portion of the container to seal the container and allow incident light to enter the light receiving surface of the solar cell substrate,
A holder for fixing the solar cell substrate inside the container so as to be spaced apart from the inner surface of the transparent window (that is, the surface facing the inside of the container)
And a coolant filled in the container to surround and cool the solar cell substrate; Wherein the photovoltaic device is a photovoltaic device. [3] The solar cell of claim 1, further comprising a solar light condensing device, wherein the solar light condensing device comprises:
The solar cell substrate is placed on the light-receiving surface with a sun so as to prevent direct sunlight incident from the sun,
Two or more planar mirrors are provided so that the planar mirrors are arranged to reflect sunlight uniformly onto the light receiving surface of the solar cell substrate,
Further comprising a frame for maintaining alignment of the planar mirrors with the solar cell substrate,
Further comprising: a rotating device for rotating the frame in two dimensions so as to follow the change of the position of the sun so that the reflected sunlight of the plurality of plane mirrors is incident on the solar cell substrate; Wherein the photovoltaic device is a photovoltaic device. [2] The apparatus of claim 1, further comprising a plurality of valves or holes in a part of the container so that refrigerant can flow into / out of the container, and an electric wiring can be connected thereto; Wherein the photovoltaic device is a photovoltaic device. The apparatus of claim 1, further comprising a circulator for forcedly convecting the refrigerant in the container; Wherein the photovoltaic device is a photovoltaic device. 2. The solar cell module of claim 1, wherein the window and the solar cell substrate are removably coupled to the container and the support, respectively; Wherein the photovoltaic device is a photovoltaic device. The solar panel of claim 1, wherein the transparent window of the cooling device further comprises an optical filter selectively transmitting only light of a wavelength band effective for photoelectric conversion of the solar cell substrate; Wherein the photovoltaic device is a photovoltaic device. The solar cell module according to claim 1, wherein the coolant of the cooling device further comprises a light filtering material (dye, etc.) selectively transmitting only light of a wavelength band effective for photoelectric conversion of the solar cell substrate; Wherein the photovoltaic device is a photovoltaic device. The method of claim 1, wherein the refrigerant is water (H ₂ O); Wherein the photovoltaic device is a photovoltaic device. The refrigerating machine of claim 1, further comprising a defoaming agent in the refrigerant to suppress the generation of bubbles in the refrigerant; Wherein the photovoltaic device is a photovoltaic device. The refrigerating machine of claim 1, further comprising an antifreeze in the refrigerant so that the refrigerant does not freeze; Wherein the photovoltaic device is a photovoltaic device. The photovoltaic device according to claim 1, further comprising a filtering device for filtering and supplying the refrigerant so that a solid precipitate is not formed on the inner surface of the container and the inner surface of the transparent window. The photovoltaic device according to claim 1, further comprising an antibiotic material in the refrigerant so that a biological sediment such as a moss or an algae is not formed on the inner surface of the container and the inner surface of the transparent window. An electric energy produced using the solar power generator according to any one of claims 1 to 12. A method for producing electrical energy using the solar power generation apparatus according to any one of claims 1 to 12.

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