KR102579263B1 - Solar module cooling system - Google Patents

Abstract

The present invention includes a module case to which a solar module is attached to the upper surface; A lower fixing part fixed to the roof surface of the building; and an upper fixing part that extends from the bottom of the module case longer than the length of the lower fixing part and is assembled with the lower fixing part; including, by forming an air flow in the space between the module case and the lower fixing part. One feature is cooling the solar module.

Description

Solar module cooling system {SOLAR MODULE COOLING SYSTEM}

The present invention relates to a solar module cooling device, and in particular, to a solar module cooling device that can be easily installed and has the function of effectively cooling the solar module.

Power generation using solar energy includes solar power generation, which converts sunlight into electrical energy, and solar power generation, which converts solar energy into electrical energy. Solar modules generate a lot of heat when producing power. The heat generated in this way increases the temperature of the solar module, and the rise in temperature of the solar module affects power production. Therefore, effectively cooling the heat generated from solar power generation is a problem directly related to power production.

Thin film solar cell modules are light and flexible, so when attached directly to the roof of a building with adhesive, there is no space for air to pass through. This means that the cooling efficiency of solar modules through air circulation decreases, reducing power generation efficiency.

When installing a solar power generation system using the roof of a building, additional components such as stands and roof perforations are required. If you drill holes into the roof of a building, the roof may be damaged and its durability may decrease, resulting in water leaks. Therefore, it is necessary to install a solar power generation system with a minimum of perforations. In addition, it is necessary to ensure that the solar module can be easily separated from the holder so that perforations on the roof are not repeated during installation and disassembly.

In this regard, Japanese Patent Application Laid-Open No. 2017-22793 discloses a hybrid solar module that uses heat generated from the solar module to provide hot water or heating water. In the above prior patent document, resin pipes are arranged in a spiral shape inside a solar panel, and an adhesive made of rubber is inserted between the spiral resin pipes to join the solar panel and the spiral resin pipe. Then, cooling water flows inside the resin pipe, using the cooling water to cool the solar panel and produce hot water.

As described above, a number of prior documents disclosing cooling devices utilizing water cooling methods have been proposed. However, in the related art, a cooling device that adopts both water cooling and air cooling for effective cooling and a cooling device that has a frame that is easy to install on the roof of a building have not been disclosed. Accordingly, a solar module cooling device was designed that has a frame that can be attached and detached from the roof of a building and that can be cooled by air cooling due to the structure of the frame.

Japanese Patent Publication No. 2017-22793 is

One object of the present invention is to provide a solar module cooling device capable of cooling by air cooling through the structure of a frame attached to the roof surface of a building.

Another object of the present invention is to provide a frame including solar modules that can be easily installed on the roof of a building.

In order to achieve the above object, the present invention includes a module case to which a solar module is attached to the upper surface; A lower fixing part fixed to the roof surface of the building; and an upper fixing part that extends from the bottom of the module case longer than the length of the lower fixing part and is assembled with the lower fixing part; including, by forming an air flow in the space between the module case and the lower fixing part. One feature is cooling the solar module.

Preferably, the module case may include a plurality of capillaries through which cooling fluid flows.

Preferably, the lower fixing part may include a plurality of holes into which fixing pins can be inserted to fix the lower fixing part to the roof surface of the building.

Preferably, the part where the upper fixing part is fastened to the lower fixing part may be formed in a ‘Y’-shaped structure.

Preferably, the upper fixing part may be fastened to the lower fixing part in a slide manner.

According to the present invention, an air flow is formed in the space between the module case and the lower fixing part, which has the advantage of providing a device that can cool the solar module by air cooling.

In addition, the present invention has the advantage that the upper fixing part can be fastened to the lower fixing part in a slide manner, so that it can be easily installed on the roof of a building.

Figure 1 shows a configuration diagram of a solar module cooling device according to an embodiment of the present invention.
Figure 2 shows a cross-sectional view of a module case including a plurality of capillaries according to an embodiment of the present invention.
Figure 3 shows a cross-sectional view of a lower fixing part including a plurality of holes according to an embodiment of the present invention.
Figure 4 shows an upper fixing part configured in a 'Y' shape and fastened in a slide manner according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the exemplary embodiments. The same reference numerals in each drawing indicate members that perform substantially the same function.

The purpose and effect of the present invention can be naturally understood or become clearer through the following description, and the purpose and effect of the present invention are not limited to the following description. Additionally, in describing the present invention, if it is determined that a detailed description of known techniques related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

Figure 1 shows a configuration diagram of a solar module cooling device 10 according to an embodiment of the present invention. Referring to FIG. 1, the solar module cooling device 10 may include a module case 100, a lower fixing part 300, and an upper fixing part 500. The solar module cooling device 10 can cool the solar module 30 by forming an air flow in the space between the module case and the lower fixing part. The solar module cooling device 10 may use an air-cooling method that cools with an air flow. The solar module cooling device 10 does not create an artificial air flow, but allows a naturally occurring air flow to pass between the module case and the lower fixture.

The solar module cooling device 10 can efficiently cool the solar module 30 and increase power production by maximizing cooling efficiency through efficient cooling.

The solar module cooling device 10 can be used in a flexible thin film solar module 30. The solar module cooling device 10 may be installed on the roof surface 50 of the building. The solar module cooling device 10 can be custom-installed without being restricted to the roof shape of the building.

The module case 100 may have a solar module 30 attached to its upper surface. A plurality of solar modules 30 may be attached to the module case 100. A plurality of solar modules 30 attached to the module case 100 can generate power by receiving sunlight. The module case 100 may be formed integrally with the upper fixing part 500. The module case 100 may be configured so that the angle of the connection portion with the upper fixing part 500 can be changed. According to this embodiment, the user can adjust the angle of the module case 100 to achieve the best power production efficiency.

The module case 100 may be in the form of a ‘ㄷ’ shape laid down so that the solar panel, which is a collection of solar modules 30, is attached and does not fall off. Since this is only one embodiment, the module case 100 can be formed in various structures to which the thin film solar module 30 can be attached and not detached.

The module case 100 may be formed with a certain space from the lower fixing part 300. The size of the space between the module case 100 and the lower fixing part 300 varies depending on the length of the upper fixing part 500. A flow of air may be formed in the space between the module case 100 and the lower fixing part 300.

Figure 2 shows a cross-sectional view of a module case including a plurality of capillaries according to an embodiment of the present invention. Referring to FIG. 2, the module case 100 may include a plurality of capillaries 110 through which cooling fluid flows. The solar module 30 exhibits the highest efficiency at a temperature of about 25 degrees in proportion to the temperature, but the power production rate gradually decreases at temperatures above that. Additionally, the temperature of the solar module 30 also affects the lifespan of the solar module 30. The plurality of capillaries 110 can cool the solar module 30 attached to the module case 100 through which cooling fluid, such as cooling water, moves. It is desirable to increase the number of capillaries 110 in order to maximize the cooling effect. The cross-sectional area of the plurality of capillaries 110 is preferably 50 to 90% of the cross-sectional area of the module case 100.

The plurality of capillaries 110 can cool the solar module 30 using a water cooling method as described above. The plurality of capillaries 110 can be used with an air cooling method using air flow between the module case 100 and the lower fixing part 300. According to this embodiment, the cooling of the solar module 30 can be maximized by primarily using an air cooling method and secondarily using a water cooling method, thereby increasing power production.

The lower fixing part 300 may be fixed to the roof surface 50 of the building. The lower fixing part 300 is fixed on the roof, and the upper fixing part 500 is detachable from the lower fixing part 300. This can provide ease of replacement when the solar module 30, the upper fixing part 500, or the module case 100 breaks down.

The lower fixing part 300 has a length extending in one direction and can be shaped so that it can be installed on the roof surface 50 of a building. The lower fixing part 300 may have a fastening portion formed in a concave shape so that the upper fixing part 500 can be fastened.

Figure 3 shows a cross-sectional view of a lower fixing part including a plurality of holes according to an embodiment of the present invention. Referring to FIG. 3, the lower fixing part 300 may include a plurality of holes 310 into which fixing pins 70 can be inserted to fix the lower fixing part 300 to the building roof surface 50. Since the lower fixing part 300 is a fixing frame for installing the solar module cooling device 10, it can be fixed to the building roof surface 50 with a fixing pin 70. A plurality of holes 310 are formed in advance in the lower fixing part 300, so no work to form holes is required during the installation process. These plural holes 310 enable installation with minimal perforations on the roof surface 50 of the building, and minimize the impact received by the roof surface 50 to prevent the roof surface 50 from being damaged or durability deteriorated. can do.

The plurality of holes 310 may be formed to completely penetrate the lower fixing part 300 in one direction so that the fixing pin 70 can pass through and be embedded in the roof surface 50. A plurality of holes 310 may be formed at regular intervals between each hole. The plurality of holes 310 may be formed in a number that can be stably fixed in consideration of the weight of the solar module cooling device 10. Depending on the number of holes 310, the durability of the lower fixing part 300 and the durability of the building roof surface 50 may be problematic, so they must be formed in an appropriate number. The radii of the plurality of holes 310 may be formed differently depending on the type of fixing pin 70.

The upper fixing part 500 may extend from the bottom of the module case longer than the length of the lower fixing part and be fastened to the lower fixing part. The upper fixing part 500 is longer than the lower fixing part 300, so a space may be formed between the lower fixing part 300 and the module case 100 connected to the upper fixing part 500. Since the air circulation speed of the upper fixing part 500 may vary depending on the space between the module case 100 and the lower fixing part 300, it must be formed to an appropriate length to secure a space that allows the fastest air circulation speed. You can.

The upper fixing part 500 has a length that extends in one direction and can form an appearance that can be fastened to the lower fixing part 300. The upper fixing part 500 may have a fastening portion formed in an embossed shape so that it can be fastened to the lower fixing part 300. The upper fixing part 500 may be formed to be detachable from the lower fixing part 300.

The upper fixing part 500 may be formed in a ‘Y’-shaped structure at a part that is fastened to the lower fixing part. The upper fixing part 500 can be firmly fixed by combining the ‘Y’ shaped fastening part with the lower fixing part 300. The angle of the ‘Y’ shaped fastening part of the upper fixing part 500 can be appropriately set depending on the installation location, direction, etc.

Figure 4 shows the upper fixing part 500 configured in a 'Y' shape and fastened in a slide manner according to an embodiment of the present invention. Referring to Figure 4, the upper fixing part 500 may be fastened to the lower fixing part 300 in a slide manner. The upper fixing part 500 can facilitate installation of the solar module cooling device 10 through a slide fastening. The upper fixing part 500 can be detached from the lower fixing part 300 without any special equipment through a slide fastening.

Although the present invention has been described in detail through representative embodiments above, those skilled in the art will understand that various modifications can be made to the above-described embodiments without departing from the scope of the present invention. will be. Therefore, the scope of rights of the present invention should not be limited to the described embodiments, but should be determined not only by the claims described later, but also by all changes or modified forms derived from the claims and the concept of equivalents.

10: Solar module cooling device
30: solar module
50: roof surface
70: fixing pin
100: module case
110: plural capillaries
300: Lower fixing part
310: Hall of Revenge
500: Upper fixing part

Claims (5)

A module case to which a solar module is attached to the upper surface;
A lower fixing part in which an inverted “Y” shaped groove is formed and one end is fixed to the roof of the building; and
It includes an upper fixing part that extends from the bottom of the module case longer than the length of the lower fixing part and is assembled to the lower fixing part,
The upper fixing part is provided to connect the center of the module case and the lower fixing part by being fastened to the inverse “Y” shaped groove of the lower fixing part in a slide manner,
The module case is
As it is fixed and installed on one side of the inverted “Y” shape of the upper fixing part,
A solar module cooling device, characterized in that it is provided to cool the solar module with an air flow formed in the space created between the module case and the lower fixing part.
According to claim 1,
The module case is,
A solar module cooling device comprising a plurality of capillaries through which cooling fluid flows.
According to claim 1,
The lower fixing part is,
A solar module cooling device comprising a plurality of holes into which fixing pins can be inserted for fixing to the roof surface of a building.
delete delete