KR102656003B1 - frame for setting solar module - Google Patents

Abstract

An upper surface having a solar cell panel capable of generating power by receiving sunlight on the surface and back, a flat first reflector located in an area starting from a position spaced apart from the upper side of the upper surface and extending downward, and a first reflector. It is provided with a flat second reflector extending from the bottom to the lower side of the upper surface, so that the light incident through the window, which is the space between the upper side and the upper side of the first reflector, is reflected by the first reflector and the second reflector, thereby causing solar radiation. A frame for installing a solar light collection module that enters the back of the battery panel and generates solar power, at least one side pipe extending in the longitudinal direction of the upper surface and having a nozzle for supplying cooling and cleaning water to the upper surface of the upper surface. A solar light condensing system comprising a frame for installing an upper surface and configured to install an upper part, a water pipe installed to absorb heat from the reflector while contacting at least one reflector, and a frame for installing a reflector on which the reflector is fixedly supported. A frame for module installation is disclosed.

Description

Frame for installing solar light concentrating module {frame for setting solar module}

The present invention relates to solar power generation, and more specifically, to the functional configuration of a frame for installing a solar light concentrating module configured to efficiently receive light from a solar cell that receives sunlight and generates electromotive force.

Solar power generation is a type of new renewable energy and is one of the important current and future energy sources. In general, solar power generation facilities refer to devices that convert solar light energy into electrical energy using solar cells. At this time, the solar cell is composed of a PN junction semiconductor and performs the function of inducing electricity in the process of generating free electrons when irradiated with sunlight. The most important thing in solar power generation is power generation efficiency, and many technologies are being developed to improve efficiency.

Figure 1 is a partial perspective cross-sectional view showing the basic configuration of a conventional cross-sectional solar cell module (solar concentrating module).

Assuming that sunlight is incident from above, a solar cell module usually consists of a protective filling layer (15) made of EVA material and a glass window layer (11) over the solar cell (17), which consists of a plurality of unit cells arranged in a matrix form. It is provided with a protective filling layer and a back sheet below the solar cell 17, and a sealing material so that the sides are covered by the square frame-shaped aluminum frame 13 in the solar cell module in an overlapping state. is fixed. The protective fill layer under the solar cell 17 and the rear protective plate can be made integrally with a fluorinated polyvinyl plate 19, under the trade name Tedlar. Although not shown here, the solar cell terminal of the solar concentrating module is pulled out to the rear and installed in a junction box behind the rear protection plate so that it can be connected to an external controller, and the controller can be connected to the power system through an inverter. .

Meanwhile, the development and use of double-sided light-receiving solar cells is being conducted as one of the technologies to improve the efficiency of solar power generation. For example, based on the general case where solar cells are installed at a certain angle with the ground or horizontal surface, such as the double-sided solar power collection module in Figure 2, double-sided light-receiving solar cells require less energy on bare ground when compared to existing single-sided solar cells. It is known that the efficiency can be increased to 30% in the maximum case, 10% on white stone, gravel or white painted floors, 15% on white stone or gravel floors, and 25% on optical designs such as installing reflectors. Examples include the bifacial type of Sanyo Electric's HIT cell.

According to Korean Patent Application No. 10-2013-0003199, “Manufacturing Method of Double-Sided Light-receiving Solar Cell,” a solar cell capable of generating power by receiving sunlight from both sides of the solar cell to increase power generation efficiency is disclosed.

In addition, various developments are being made on efficient configurations that can receive sunlight from both sides.

However, in order to maintain high solar power generation efficiency in existing solar cell modules, it is necessary to ensure that the solar cells are in an appropriate temperature range. For example, in a solar cell, some of the sunlight is converted into heat, which can excessively increase the surrounding temperature, reduce solar cell efficiency, and cause solar cell quality deterioration. To prevent this problem, make sure that the temperature of the solar cell and its surroundings does not get too high. It becomes necessary to do so.

In particular, when considering both the front and back of a double-sided light-receiving solar cell, more sunlight is concentrated compared to a single-sided light-receiving solar cell, so the total amount of solar energy converted into heat in the solar module increases, and thus the double-sided light-receiving solar cell For batteries, it may be more necessary to reduce the heat burden compared to single-sided light-receiving solar cells.

Regarding double-sided solar cells, from the perspective of general solar power generation, technology to increase the conversion efficiency of the solar cell itself to convert light energy into electric energy in order to increase power generation efficiency when installing solar cells. Along with development, the issue of increasing power generation efficiency relative to the installation area is important, but it is also important to configure facilities that can suppress and prevent the decline in power generation efficiency due to temperature rise, and in addition, continuously maintain solar power generation efficiency at a high level. A suitable surrounding configuration for installing the light condensing module, such as a frame configuration for installing the light condensing module, is required.

Republic of Korea patent application 10-2013-0003199 Manufacturing method of double-sided light receiving solar cell. Republic of Korea Patent Publication 10-2011-0044502 Multi-reflective solar concentrating structure. Republic of Korea Patent Registration 10-1099387 Uniform grid structure for overlapping reinforced light.

The present invention is intended to solve or improve the problems in solar power generation of the conventional double-sided light-receiving solar cells described above, and to prevent the temperature from excessively rising due to sunlight concentrated in the solar light concentrating module, thereby impeding power generation efficiency. The purpose is to provide a frame for installing solar energy concentrating modules that has a configuration that can be used to prevent.

In one aspect, the purpose of the present invention is to provide a frame for installing a solar light collection module with a structure suitable for increasing solar light collection efficiency by adjusting the relative position between the installation state of the double-sided light receiving solar cell panel and the installation state of the reflector. do.

On the one hand, the purpose of the present invention is to provide a frame for installing solar light concentrating modules that has a structure suitable for suppressing and preventing interference with incident sunlight and the resulting decrease in power generation efficiency due to surface contamination of solar cell panels.

The purpose of the present invention is to provide a frame for installing solar light concentrating modules that has a configuration that increases the durability of power generation facilities and maintains high power generation efficiency in a given state by taking into account factors that impede power generation efficiency. Do it as

The frame for installing solar energy concentrating modules of the present invention to achieve the above object is,

An upper surface having a solar cell panel capable of generating power by receiving sunlight on the surface and back, a flat first reflector located in an area starting from a position spaced apart from the upper side of the upper surface and extending downward, and a first reflector. It is provided with a flat second reflector extending from the bottom to the lower side of the upper surface, so that the light incident through the window, which is the space between the upper side and the upper side of the first reflector, is reflected by the first reflector and the second reflector, thereby causing solar radiation. As a frame for installing a solar light concentrating module that enters the back of the battery panel and generates solar power,

A frame for installing the upper surface, which extends in the longitudinal direction of the upper surface and has at least one side pipe including a nozzle for supplying cooling and cleaning water to the upper surface of the upper surface, and is configured to install the upper surface;

It is characterized by comprising a water pipe installed to absorb heat from the reflector while contacting at least one reflector, and a reflector installation frame on which the reflector is fixedly supported.

At this time, the present invention is coupled on the one hand to the upper surface installation frame and on the other hand to the reflector installation frame so that the angle between the upper surface installation frame and the reflector installation frame can be varied. An angle adjustment frame may be further provided. .

In the present invention, a frame for installing a reflector may be provided for a second reflector and a frame for a first reflector. In this case, the second angle adjustment frame is responsible for adjusting the angle between the second reflector installation frame and the upper surface installation frame, and the first reflector installation frame is responsible for adjusting the angle between the second reflector installation frame and the first reflector installation frame. It can be done to do so.

In the present invention, the angle adjustment frame can be constructed using a variety of well-known device configurations for adjusting the angle between two objects.

In the present invention, the frame for installing the upper surface may be made based on a quadrangular frame such as a picture frame.

In the present invention, the frame for installing the upper surface is itself made of a pipe body, so that water flows inside, and one or more nozzles are formed on a part of the pipe body to supply water toward the upper surface of the upper surface. The nozzle may be formed so that the water collides with the surface of the solar cell panel with water pressure to remove foreign substances on the surface, or it may be formed so that the water simply flows down the surface of the solar cell panel. The former can be seen as being focused on removing or cleaning foreign substances that prevent sunlight from entering the cell, while the latter is focused on cooling the solar module by taking away heat through contact with the surface in the process of flowing across the surface. However, in all cases, it can be seen as functioning for both cleaning and cooling purposes.

In the present invention, the solar cell panel on the upper surface is a single double-sided light-receiving solar cell panel, or two single-sided light-receiving solar cell panels are formed with the light-receiving surface facing outward, that is, their light-receiving surfaces are disposed on the surface and back of the solar cell panel. It may have been formed by overlapping to form one.

In the present invention, the space between the upper surface and the first reflector forms a window through which sunlight enters the inner space of the module. The window may be simply an open space, but the light input is a transparent plate such as glass or polycarbonate synthetic resin. It may also be provided with a window.

In the present invention, the upper installation frame may form part of a pipeline that commonly supplies water to one row or column to form a solar cell array.

In the present invention, the cooling water pipe provided in the frame for installing the reflector may be designed so that the water flowing therein always flows in one direction.

In the present invention, the upper surface forms an appropriate angle with the horizontal plane, for example, an angle of 35 degrees considering latitude, the first reflector forms an angle of 45 degrees to -45 degrees with the vertical plane, and the second reflector forms an angle of 45 degrees to -45 degrees with the vertical plane, and the second reflector forms an angle of 45 degrees to -45 degrees with the vertical plane. Depending on the installation angle of the unit and the first reflector, it may be configured to form an angle that facilitates light collection on the solar cell panel. For example, in the present invention, when the angle formed by the first reflector with the vertical plane is referred to as the inclination, it can be installed variably in the range of 45 degrees to -45 degrees, or 10 degrees to -10 degrees.

A plurality of solar light concentrating modules of the present invention may be arranged in at least one direction or in a two-dimensional matrix on one plane (inclined plane or horizontal plane) to form a solar array of a solar power generation facility.

According to the present invention, it is possible to prevent the temperature from increasing excessively due to sunlight concentrated on the solar light concentrating module in solar power generation using a double-sided light-receiving solar cell, thereby impairing power generation efficiency.

According to one aspect of the present invention, the surface of a solar cell panel can be cleaned as needed to alleviate the problem of reduced solar light incidence and reduced power generation efficiency due to foreign substances on the surface.

According to one aspect of the present invention, the installation form of the light collection module can be adjusted according to the surrounding environment and time by adjusting the angle between the installation frame parts to enable adjustment of the angle between the upper surface and the reflector forming the light collection module of the double-sided light receiving solar cell. It can make it possible to control and increase solar power generation efficiency.

Overall, the present invention can have the effect of increasing the power generation efficiency and management efficiency of solar power generation installation and light collection modules.

Figure 1 is a partial cross-sectional perspective view showing an example of a conventional cross-sectional solar light concentrating module;
Figure 2 is a conceptual diagram showing one installation form of a conventional double-sided solar concentrating module;
Figure 3 is a perspective structural diagram showing an example of a solar light concentrating module suitable for an embodiment of the present invention, and Figure 4 is a front cross-sectional view showing the structural concept of an embodiment of the present invention.
Figure 5 is a perspective configuration conceptual diagram schematically showing the state in which the solar light concentrating module of Figure 3 is equipped with a side plate and a light input window to form a solar light concentrating module that separates the external space from the internal space;
Figure 6 is a perspective view schematically showing an embodiment of the solar light concentrating module installation frame of the present invention for installing the solar light concentrating modules of Figures 3 and 4;
Figure 7 is a front view schematically showing an installation example in which the solar light concentrating module of Figure 4 is combined with the solar light concentrating module installation frame of Figure 6;
Figure 8 is a front cross-sectional view showing the structural concept of another example of a solar light concentrating module capable of varying the installation angle of the first reflector with respect to the second reflector;
Figure 9 is a front view schematically showing an installation example in which the solar light concentrating module of Figure 8 is combined with the frame for installing the solar light concentrating module of Figure 6.

Hereinafter, the present invention will be described in more detail through specific examples with reference to the drawings.

Referring to Figures 3 and 4 together, the light collection module related to this embodiment includes a top portion 110 provided with a solar cell panel capable of generating power by receiving sunlight on the surface (outer side) and back (inner side), and a top side. A flat first reflector 120 located in an area that starts at a distance from the upper side of the unit 110 and extends downward, and is installed to extend from the bottom of the first reflector 120 to be connected to the lower side of the upper surface. It is provided with a second reflector 130.

The surface of the upper surface 110 is installed at an angle to the horizon, and the horizontal component in the longitudinal direction of the upper surface is oriented towards the south.

The solar cell panel forming the upper surface 110 is formed by overlapping two single-sided light-receiving solar cell panels 111 and 113 to substantially act as a double-sided light-receiving solar cell panel.

Light incident through the window 140, which is the space between the upper side of the upper surface portion 110 and the upper side of the first reflector 120, is reflected from the inner side of the first reflector 120 and the inner side of the second reflector 130 and is reflected on the back surface. The light incident on the light-receiving surface of the cross-sectional light-receiving solar cell panel 113 on the side allows solar power generation to be performed.

The upper surface portion 110 forms a 35-degree angle with the horizon and is formed to a standard of 2 meters in length and 1 meter in width. The first reflector 120 is formed to have the same width of 1 meter as the upper surface portion 110, is rotated outward around the top (upper side), and forms an angle of 10 degrees with the vertical plane.

The length between the upper side of the upper surface portion 110 and the upper side of the first reflector 120 is 50 cm, and the space extending from the upper surface portion on the same plane as the upper surface portion becomes a window. Therefore, the width of the window is 1m and the length of the window is 50cm.

Here, the upper surface portion 110 is installed to form an angle of 35 degrees with the horizon because, considering the southern altitude of the sun, the most efficient angle to receive sunlight on an annual average is approximately 35 degrees. The second reflector 130 forms an angle of 6.8 degrees with the horizon and 86.8 degrees, which is close to a right angle with the first reflector 120, and has a length of 2269 mm and a width of 1 meter. At this time, the first reflector has a length of 1183mm.

The point where the first reflector 120 and the second reflector 130 meet lies on a line extending perpendicular to the upper surface portion 110 at a point corresponding to the upper side of the upper surface portion 110.

The incident light incident approximately perpendicular to the surface of the upper surface 110 is reflected from the inner surface, which is the reflective surface of the first reflector 120, as shown by the arrow, and enters the inner surface of the second reflector 130, and then returns to the second reflector 130. It is reflected from the inner surface of the reflector 130 and enters the single-sided light-receiving solar cell panel 113 on the back side of the upper surface. Part of the incident light on this back is generated by the solar cell, and part of it is reflected from the surface, goes back to the inner side of the second reflector, is reflected again, and enters another location on the back of the solar cell panel, and part of it also generates electricity. produced and some of it is sent to the inner side of the second reflector.

Of course, depending on the environmental conditions such as the surrounding terrain, latitude, and season where the light-concentrating module is installed, the direction in which the upper surface, the first and second reflectors are viewed, and the angle formed with the horizontal or vertical plane may be designed, variable, or adjusted in various ways. there is. For example, in another example, the angles formed by the upper surface of the light collection module and the second reflector with the horizontal plane may be 35 degrees, 15, and 35 degrees, respectively, and the first reflector may be formed parallel to the vertical plane. In another example, the upper surface and the second reflector may be formed parallel to the vertical plane. The angles formed by the second reflector with the horizontal plane may be 35 degrees and 20.96 degrees, respectively, and the first reflector may be formed at an angle of -10 degrees with the vertical plane.

In this configuration, sunlight incident on the upper surface generates solar power in cells on the surface of the double-sided light-receiving solar panel, and sunlight incident on the window is reflected through reflectors inside the light-concentrating module and is transmitted to the back of the solar panel. When solar power is generated in a side cell, some of the sunlight is reflected along the path or from an object, producing heat within the object.

Moreover, as shown in FIG. 5, the light collection module is equipped with a first reflector 120, a second reflector, and an upper surface portion 110, as well as a left side of the first reflector 120, a second reflector, and an upper surface portion 110, It may have a side plate 450 commonly installed on the right side, and the window may be made of transparent glass or a panel made of a plastic material such as polycarbonate, that is, a light input window 440.

In addition, if a reflector is also placed on the inner side of the side plate 450 to form a third reflector, as not only the altitude but also the azimuth of the sun changes from sunrise to sunset, in addition to the sunlight component incident on the front of the light collection module, the sunlight incident on the left and right sides is also reflected. By reflecting sunlight components to enter the back cell of the solar cell panel, solar power generation efficiency can be increased.

In this case, the internal space of the light collection module is blocked and sealed from the outside, preventing external foreign substances, dust, moisture, etc. from entering the internal space, contaminating the inner surface of the reflector (reflecting surface), and reducing the reflection efficiency of the light collection module. Although there are aspects that help with maintenance and management, the internal space of the light collection module is difficult to dissipate heat, so the temperature in the internal space can rise to a significant degree.

Referring to Figures 6 and 7, a frame for installing a light condensing module constituting an embodiment of the present invention is disclosed. This frame is made so that the upper surface of the light collection module and the reflector can be installed, and is therefore formed to correspond to the shape and configuration of the light collection module.

Therefore, first looking at the light collection module, as shown in FIGS. 3 and 4, the light collection module has a top portion 110 equipped with solar cell panels on the surface and back that can receive sunlight and generate power, and a position spaced apart from the upper side of the top portion. It is provided with a flat first reflector 120 located in an area starting from and extending downward, and a flat second reflector 130 installed extending from the bottom of the first reflector toward the lower side of the upper surface. 1 Light incident through the window 140, which is the space between the upper sides of the reflector, is reflected by the first and second reflectors and enters the back of the solar cell panel, thereby generating solar power.

Corresponding to this, the light collection module installation frame of this embodiment is comprised of a top installation frame 20 on which the upper surface part 110 of the light collection module can be seated and a reflector installation frame 30 on which the second reflector 130 is placed. .

The upper surface installation frame 20 has a square frame shape like a picture frame, and this square frame shape is provided with left and right side parts 21, upper side parts 25, and lower side parts 27 extending in the longitudinal direction of the upper surface. It comes true. The left and right side portions 21, upper side portion 25, and lower side portion 27 may be made of rectangular pipes that are hollow and allow water to flow therein.

A flange part 29 extending inward is installed at the inner bottom of the square pipe, and when the upper surface part 110 of the light collection module is installed on it, the upper surface part 110 can be easily installed on the upper surface installation frame 20. there is. Although not clearly shown here, passing holes or wire hangers can be installed at appropriate positions in the flange or other parts of the upper installation frame to facilitate installation of electric wires of the upper solar panel.

A plurality of water spray nozzles 23 are installed on the left and right side portions 21 along the longitudinal direction. This frame for installing light condensing modules generally forms a part of the overall frame for forming a solar array consisting of a plurality of light concentrating modules arranged in a matrix, where the water pipe 50 installed in the entire frame is connected to the valve 28. ) is connected to the lower side portion 27, and the lower side portion 27 is again connected to the left and right side portions 21.

Therefore, when the valve 28 is opened, water is supplied from the water pipe 50 to the lower side 27, and the water is supplied to the plurality of water spray nozzles 23 installed on the left and right side parts 21 connected to the lower side. It is sprayed onto the surface of the solar cell panel on the upper surface 110.

The water sprayed from the water spray nozzle 23 can be used to remove foreign substances such as dust from the surface, and the water sprayed on the surface flows down toward the bottom along the surface by gravity and comes into extensive contact with the surface. It can play a role in lowering the temperature of the light condensing module or solar panel by removing heat.

For these cleaning and cooling functions, the installation location, number, discharged water pressure, water spray angle, and direction of the water spray nozzles (23) are appropriately set to increase cleaning and cooling efficiency and to save used water. Ensure efficient use of

The water that comes down along the panel may fall directly onto the ground without any additional facilities, but it can also collect water by installing an open trough-type pipe in parallel with the water pipe, collect it, and reuse it after a separate filtration and cooling process.

The installation angle of the upper installation frame 20 with the horizontal plane is basically the same as the installation angle of the upper surface 110 of the light collecting module in Figures 3 and 4, but depending on the surrounding circumstances, the upper installation frame 20 and the upper surface Since the parts 110 may have a slightly spaced angle in each direction, the installation angle of the upper surface installation frame 20 can be determined by taking this into account.

Meanwhile, the frame 30 for installing a reflector is roughly in the shape of a ladder, and includes an inlet pipe 31 through which coolant is drawn in corresponding to one side of the ladder, an outlet pipe 35 through which coolant is drawn out corresponding to the remaining side of the ladder, and an inlet pipe 35 through which coolant is drawn out, corresponding to the remaining side of the ladder. It is comprised of a heat-absorbing pipe 33 that branches off from the pipe and the outlet pipe at a number of points approximately perpendicularly and corresponds to a step part connecting the inlet pipe and the outlet pipe.

The heat absorption pipe 33 touches the back of the second reflector of the light collection module and takes away heat from the second reflector. In order to perform this function efficiently, the heat absorption pipe is preferably made of a metal material with good thermal conductivity. Limited to this, assuming that the direction of coolant flow is longitudinal, a rectangular pipe with a wide contact plane to increase the contact area with the back of the reflector, but with a small height in the thickness direction to prevent excessive coolant flow, is used. It is desirable to use

In this embodiment, the frame 30 for installing the reflector is formed in a trapezoidal shape and installed using a hollow tubular pipe to serve as both a frame and a cooling pipe. However, the frame is installed separately and the ondol of the house is placed on the plane to which this frame belongs. It is also conceivable to separately install additional cooling water piping, such as heating piping. To increase heat exchange efficiency, a plate (not shown) with excellent thermal conductivity is placed on this cooling water piping, and a second reflector is placed in full contact with this plate. You can also consider the installation configuration.

Although not clearly shown here, in any of the above-mentioned embodiments, a valve can be installed at the inlet of the cooling water pipe to open, close, and control the supply of cooling water to the corresponding light collection module. For cooling efficiency, it is desirable for the cooling water pipe provided in the frame for installing the reflector to be designed so that the cooling water flowing inside always flows in one direction.

Typically, the coolant inlet pipe 31 will be connected to a common pipe (not shown) for coolant supply, and the coolant outlet pipe 35 will be connected to a common pipe for coolant recovery. It is conceivable to use the aforementioned water pipe 50 as a common pipe for supplying coolant, and in this case, it is also conceivable to discharge the used coolant directly to the ground without a common pipe for recovery.

The coolant coming out of the draw pipe 35 can be supplied back to the common supply pipe through the recovery common pipe and the storage tank, and in this process, sufficient internal heat is released through a heat dissipation means to a temperature that can efficiently exercise the cooling function. It is necessary to do As the heat dissipation means, various well-known heat dissipation means may be used.

The installation angle of the reflector installation frame 30 with the horizontal plane is basically the same as the installation angle of the second reflector 130 of the light collection module of Figures 3 and 4, but the reflector installation frame 30 and the second reflector are adjusted depending on the surrounding circumstances. Since (130) may have a slightly spaced angle in each direction, the installation angle of the frame for installing the reflector can be determined by taking this into account.

Adjacent ends of the reflector installation frame 30 and the upper installation frame 20 are directly fixed to have a certain angle between the reflector installation frame 30 and the upper installation frame 20 according to the installation angle with the horizontal plane. They may be combined, but here they are each connected and fixed to the angle adjustment frame 40. Here, the angle adjustment frame 40 is formed so that the installation angles of the frame for installing the reflector and the frame for installing the upper surface can be adjusted separately. Of course, a configuration in which the angle between the frame for installing the reflector and the frame for installing the upper surface is fixed at a constant level and the entire light collecting module itself is rotated around this fixed part can also be considered.

The configuration of the angle adjustment frame can employ a variety of well-known configurations, including the well-known angle adjuster configuration, such as the combination of a gear box made of gear wheels and an electric motor to drive the rotation axis of the gear box, and its specific configuration. Since is well known, its description will be omitted here.

Referring to Figure 8, here, the light collection module includes a top portion 110 that has a single-sided light-receiving solar cell panel on the back and a surface, respectively, and functions substantially like a double-sided light-receiving solar cell panel, and a first reflector 520. , and is provided with a second reflector 530.

However, here, the first reflector 520 is configured in the form of a tracking mirror so that it can rotate around one horizontal axis in the width direction, and for this purpose, the portion where the first reflector and the second reflector are connected to each other has a space between them. An angle adjustment device is provided to adjust the angle of. Among the embodiments in which the first reflector 520 rotates in this way, the rotation of the first reflector 520 is performed around an axis formed on the upper side of the first reflector, so that there is a gap between the upper side of the first reflector 520 and the upper side of the upper surface portion 110. An embodiment in which the gap, that is, the size of the window, remains unchanged may be considered, but in Figure 9, the first reflector 520 is rotated around an axis formed on the lower side of the first reflector 520, thereby creating a window 540 through which incident light enters. ) is an example of a case where the area changes.

The window (window: 540) is made of a transparent plate with a curved surface in the same shape as the trace drawn by the upper side of the first reflector when the first reflector rotates around the rotation center axis, and this window is placed at a slightly higher position than the trace. It is installed so as not to interfere with the rotation of the first reflector 520.

That is, in this embodiment, the position and inclination angle of the upper surface 110 equipped with the solar cell panel and the second reflector 530 are fixed, and the first reflector 520, which is the part that meets the second reflector 530, is fixed. A rotation center axis is installed at the lower side of and the first reflector 520 can rotate around it.

The rotation of the first reflector may be similar to the action of the angle adjustment frame. For example, various types of actuators, such as motors, may be provided in the angle adjusting device to directly move the rotation center axis or the first reflector to physically rotate the first reflector, and the operation of these actuators may be performed through constant tracking. ) This can be done by activating a controller that moves the actuator through a program. A trekking program may be designed to follow the change in altitude of the sun over time on a one-day cycle, or a trekking program with a one-day cycle and a different rotation angle value for each season or month may be used.

This rotation of the first reflector can be made much simpler and lighter than the upper surface portion, making it easier than changing the posture or installation angle of the solar cell panel forming the upper portion.

Figure 9 shows the light condensing module of Figure 8 combined with one frame of the present invention. Referring to Figure 9, considering that the light collection module installation frame used here has basically the same configuration as the embodiment of the light collection module installation frame disclosed in Figure 6, here too, the upper surface portion 110 is attached to the upper surface installation frame 20. It is coupled and fixed, and the second reflector 530 is coupled and fixed to the frame 30 for installing the reflector.

Here, the installation angle of the upper surface 110 and the second reflector 130 with respect to the horizontal or vertical plane can be adjusted by the angle adjustment frame 40, and the first reflector 520 is provided in the light collection module itself. The installation angle with respect to the horizontal plane or the vertical plane can be adjusted by the angle adjusting device 550. As a result, the solar cell panels of the first reflector 520, the second reflector 530, and the upper surface 110 are each arranged at the most efficient installation angle in consideration of the altitude of the sun at the current season and time of day. The efficiency of solar power generation can be increased.

To this end, the actuator installed on the angle adjustment frame 40 and the actuator used in the angle adjustment device can be driven by the same controller, and the angle between the first and second reflectors of the light collection module is calculated based on solar position data. By considering the installation angle of the upper surface and the installation angle between the upper surface and the second reflector by a drive program that adjusts the installation angle of each element of the frame and light collection module, the highest solar power generation efficiency can be achieved at that point. It can be done.

As an example, the rotation angle range of the first reflector 520 using the angle adjusting device is, for example, 10 degrees or 15 degrees in clockwise and counterclockwise directions, centered on the vertical position of the first reflector 520. It can be.

For example, when the altitude of the sun or the angle of incidence of sunlight to the window is small, the first reflector 520 has a position rotated clockwise by, for example, 10 degrees. In this case, the size of the window is reduced, but the incident light is transmitted to the first reflector ( It can be properly reflected from 520 and input into the second reflector 530, a cell installed on the back of the solar cell panel, and used for power generation.

Conversely, when the altitude of the sun is close to 90 degrees, the first reflector 520 is in a position rotated by 10 degrees counterclockwise based on the vertical position around the rotation center axis (angle adjusting device: 550). In this case, The size of the window increases, and the incident light can be properly reflected from the first reflector 520 and input into the second reflector 530 and the cell on the back of the solar cell panel.

If the altitude is close to 90 degrees and the first reflector 520 is rotated clockwise by about 10 degrees, the size of the window becomes smaller, and the sunlight hitting the first reflector 520 is When it touches the outer surface, it reflects outward and enters the inner space of the light collection module, making it difficult to reach the back cell of the solar cell panel.

If the altitude is about 50 degrees, which is much smaller than 90 degrees, and the first reflector is rotated about 10 degrees counterclockwise, the incident light can enter the back of the solar cell directly rather than the second reflector. In this case, the angle of incidence is Because it is so large, most of it is reflected when first incident on the solar cell panel, and this reflected light is reflected multiple times between the second reflector and the back of the solar panel and is concentrated in the corner where the second reflector and the back of the solar cell panel contact each other, resulting in low power generation efficiency. , conversion to heat can cause many problems.

In addition, when using the frame for installing a light condensing module of the present invention, when the temperature of the solar cell panel is detected to be above the standard or the surface turbidity is detected to be above the certain standard by a temperature sensor (not shown), the water spray nozzle of the upper installation frame 20 (23), water can be sprayed on the surface to lower the temperature or remove surface foreign substances that block sunlight.

Similarly, when the temperature sensor (not shown) detects that the temperature of the light collection module represented by the second reflector 530 is above a certain standard, the valve installed in the cooling water pipe of the reflector installation frame 30 is opened to allow the coolant to flow and contact the second reflector. In addition, heat can be taken away from the light-concentrating module and the internal temperature of the light-concentrating module can be managed to be below a certain standard temperature suitable for solar power generation.

Here, in the frame of the present invention, the frame 30 for installing a reflector is made in a simple form to fix the second reflector 530 while contacting the second reflector 530, and is located between the first reflector 520 and the second reflector 530. The angle adjustment is shown in a configuration achieved by the angle adjustment device 550 provided in the light condensing module itself, but instead of this configuration, a frame for installing a reflector is in contact with the second reflector and a frame for installing a second reflector is in contact with the first reflector. It is divided into a frame for installing one reflector, and the light condensing module itself does not have an angle adjusting device 550. It is also possible to have a second angle adjusting frame between the frame for installing the first reflector and the frame for installing the second reflector. In this case, the operation of the second angle adjustment frame may be substantially the same as the operation of the angle adjustment device 550 provided in the light condensing module itself in FIG. 9. Additionally, the coolant pipe configuration of the first reflector installation frame and the coolant pipe configuration of the second reflector installation frame may be similar to the configuration of the reflector installation frame 30 of FIG. 6.

In the above, the present invention is described through limited examples, but these are merely illustrative descriptions to aid understanding of the present invention and the present invention is not limited to these specific examples. Accordingly, those skilled in the art will be able to make various modifications and applications based on the present invention, and it is natural that such modifications and applications fall within the scope of the appended patent claims.

20: Frame for upper installation 21: Side part
23: Nozzle (water spray nozzle) 25: Upper side part
27: lower side 28: valve
29: Flange
30: Frame for installing reflector 31: Inlet pipe
33: heat absorption pipe 35: withdrawal pipe
40: Angle adjustment frame 50: Water pipe
110: upper surface 111, 113: single-sided light receiving solar cell panel
120, 520: first reflector 130, 530: second reflector
140: window 440, 540: light input window
450: Side plate (third reflector) 550: Angle adjuster (angle adjuster)

Claims (6)

An upper surface portion having solar cell panels capable of generating power by receiving sunlight on the surface and back, a flat first reflector located in an area starting from a position spaced apart from the upper side of the upper surface portion and extending downward, the first reflector It is provided with a flat second reflector extending from the bottom of the reflector to the lower side of the upper surface, so that light incident through the window, which is a space between the upper side of the upper surface and the upper side of the first reflector, is transmitted to the first reflector and the A frame for installing a solar light concentrating module that is reflected by a second reflector and incident on the back of the solar cell panel to generate solar power,
A frame for installing the upper surface, which extends in the longitudinal direction of the upper surface and has at least one pipe including a water spray nozzle for supplying cooling and cleaning water to the surface of the upper surface, and is configured to install the upper surface;
It includes a cooling water pipe installed to absorb heat from the reflector while contacting at least one of the first reflector and the second reflector, and includes a reflector installation frame on which the reflector is fixedly supported,
Further provided with an angle adjustment frame coupled to the upper surface installation frame on the one hand and the reflector installation frame on the other hand so as to vary the angle between the upper installation frame and the reflector installation frame,
The reflector installation frame is divided into a second reflector installation frame that is a part of the second reflector and a first reflector installation frame that is a part of the first reflector,
The second angle adjustment frame is responsible for adjusting the angle between the second reflector installation frame and the upper surface installation frame, and the first angle adjustment frame is responsible for adjusting the angle between the second reflector installation frame and the first reflector installation frame. A frame for installing solar energy concentrating modules, characterized in that it is made to take charge. delete delete According to claim 1,
The frame for installing a solar light concentrating module is made of a tube body, so that water flows internally, and one or more nozzles are formed on a portion of the tube body to supply water toward the surface of the upper part. . delete In clause 1
The cooling water pipe is a frame for installing a solar light concentrating module configured to receive cooling water from a common pipe for cooling water supply that supplies cooling water to the upper installation frame.