KR101154729B1 - Solar module having high efficiency in heat dissipation - Google Patents

Abstract

PURPOSE: A photovoltaic module with superior heat dissipation efficiency is provided to significantly improve heat dissipation efficiency of a solar cell plate by introducing external air through a ventilation hole formed inside a heat dissipation part on a side surface of the solar cell plate. CONSTITUTION: A front plate(110) and a rear plate(120) are formed on the front side and the rear side of a solar cell plate(10). A heat dissipation part(20) is formed on a side surface of the solar cell plate. A ventilation hole(30) is formed inside the heat dissipation part for introducing external air. The heat dissipation part is comprised of an extension plate(210), a connection plate(220), and a bottom plate(230). The bottom plate is extended to a side surface direction of the solar cell plate from the lower side of the connection plate.

Description

Solar module with excellent heat dissipation efficiency {SOLAR MODULE HAVING HIGH EFFICIENCY IN HEAT DISSIPATION}

The present invention is a heat radiation efficiency of the solar panel because the outside air is introduced through the vent formed on the inner side of the heat dissipation portion provided on the side of the solar panel when the wind passes through the space formed inside the lower side of the solar panel smoothly The present invention relates to a solar module having excellent heat dissipation efficiency, which can be greatly improved and of course, the electric generation efficiency of the solar panel is not lowered.

In general, a solar module is a technology for converting the light of the sun into electricity through a solar panel that collects sunlight to generate electricity in a state of being installed on the roof of a building including a house, etc. The solar cell is a PN junction semiconductor It is configured to induce electricity by generating free electrons when irradiated with sunlight.

However, the photovoltaic module has a problem in that the heat generation efficiency is low due to the high temperature heat generated in the photovoltaic module while the photovoltaic module generates electricity.

The present invention was created in order to solve the above problems, and when the wind is blown outside air flows through the vent formed on the inside of the heat dissipation unit provided on the side of the solar panel while passing through the space formed inside the lower side of the solar panel Since it can be made smoothly, the heat dissipation efficiency of the solar panel can be greatly improved, and as a result, it is an object of the present invention to provide a solar module having excellent heat dissipation efficiency without fear of deteriorating the electricity generation efficiency of the solar panel. .

The present invention for achieving the above object is a solar module comprising a solar panel for generating electricity by condensing the solar light, the heat dissipation portion is formed inside the ventilation hole in which the outside air flows into the side of the solar panel It provides a solar module having excellent heat dissipation efficiency, characterized in that provided.

The heat dissipation unit may include an extension plate extending at a predetermined length from the side of the solar panel to the outside of the solar panel; A connecting plate integrally formed between the extension plates to connect the extension plates; A bottom plate extending horizontally in the lateral direction of the solar panel from the lower side of the connecting plate, wherein the ventilation holes are formed inside the extension plate and the inside of the connecting plate so as to be positioned in an upper direction of the bottom plate. desirable.

The heat dissipation unit may include one side heat dissipation unit provided on one side of the solar panel; It is preferably composed of; the other side heat-radiating portion provided on the other side of the solar panel.

Alternatively, the heat dissipation unit and one side heat dissipation unit provided on one side of the solar panel; The other heat dissipation part provided on the other side of the solar panel; A front side heat dissipation part provided on a front side of the solar panel; It is preferable that the rear heat dissipation unit provided on the rear side of the solar panel.

Further, it is preferable that a reinforcing partition wall is formed at a predetermined interval between the inner circumferential surface of the heat radiating portion and the side outer circumferential surface of the solar panel so as to be located in the vent of the heat radiating portion.

In addition, the through plate is preferably formed at a predetermined interval on the bottom plate.

Alternatively, it is preferable that a plurality of slits extending in the longitudinal direction of the bottom plate are formed at a predetermined interval on the bottom plate.

Alternatively, one bottom slit extending in the longitudinal direction of the bottom plate is preferably formed on the bottom plate.

The extension plate may include a first extension plate extending at a predetermined length from the side of the solar panel to the outside of the solar panel; And a second extension plate detachably fastened to the first extension plate by a fastening member so as to be movable from the first extension plate to the outside of the first extension plate.

In addition, it is preferable that the discharge slit is formed in the connecting plate.

The present invention is a heat radiation efficiency of the solar panel because the outside air is introduced through the vent formed on the inner side of the heat dissipation portion provided on the side of the solar panel when the wind passes through the space formed inside the lower side of the solar panel smoothly This can be greatly improved and of course there is no effect that the electricity generation efficiency of the solar panel is not reduced.

1 is a plan view schematically showing a solar module having excellent heat dissipation efficiency as a first embodiment of the present invention;
2 is a cross-sectional view taken along line AA of FIG. 1,
3 is a cross-sectional view taken along the line B-B of FIG.
4 is a plan view schematically showing a solar module having excellent heat dissipation efficiency as a second embodiment of the present invention;
5 is a cross-sectional view taken along the line C-C of FIG.
6 is a cross-sectional view taken along the line D-D of FIG.
7 and 8 are plan views schematically illustrating a state in which a reinforcing partition is provided in the ventilation hole,
9 is a cross-sectional view schematically showing a state in which the bottom plate is fixed to the slate roof,
10 and 11 are plan views schematically illustrating a state in which a plurality of slits are formed at a predetermined interval on the bottom plate, respectively;
12 and 13 are plan views schematically illustrating a state in which one slit is formed on the bottom plate, respectively.
14 and 15 are partially sectional views schematically showing another example of the extension plate.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a plan view schematically showing a solar module having excellent heat dissipation efficiency as a first embodiment of the present invention, FIG. 2 is a cross-sectional view taken along the line A-A of FIG. 1, and FIG. 3 is a line B-B of FIG. According to the cross-sectional view.

The solar module having excellent heat dissipation efficiency of the present invention is largely formed as shown in FIGS. 1 to 3, and includes a solar panel 10 and a heat dissipation unit 20.

The front panel 110 and the rear panel 120 may be integrally formed at the front side and the rear side of the solar panel 10 vertically extending at a predetermined length in the lower direction of the solar panel 10.

The solar panel 10 is to generate electricity by condensing sunlight, which is a well-known technology and those skilled in the art to which the present invention pertains will be clearly understood and can be carried out as follows. do.

The heat dissipation unit 20 is provided on the side surface of the solar panel 10.

The inside of the heat dissipation unit 20 is formed with a vent 30 through which outside air flows when the wind blows.

Next, the heat dissipation unit 20 is composed of an extension plate 210, the connecting plate 220 and the bottom plate 230.

The connection plate 210 may extend a predetermined length from the side of the solar panel 10 to the outside of the solar panel 10.

The connection plate 220 may be integrally formed between the extension plate 210 in a state orthogonal to the extension plate 210 to connect the extension plate 210.

The bottom plate 230 may be horizontally extended with a predetermined length in the lateral direction of the solar panel 10 in a state orthogonal to the connecting plate 220 on the lower side of the connecting plate 220.

The bottom plate 230 may be fixed to the roof of a building, such as a house.

The ventilation holes 30 may be formed inside the extension plate 210 and inside the connection plate 220 so as to be positioned in an upper direction of the bottom plate 230.

Next, the heat dissipation unit 20 including the extension plate 210, the connection plate 220, and the bottom plate 230 may include one heat dissipation part 21 and the other heat dissipation part 22.

The one side heat dissipation part 21 may be provided on one side of the solar panel 10.

The extension plate 210 of the one side heat dissipation part 21 extends to the outside of the solar panel 10 at a predetermined length from the front side of one side of the solar panel 10 and the rear side of one side of the solar panel 10, respectively. Can be.

The other heat dissipation part 22 may be provided on the other side of the solar panel 10.

The extension plate 210 of the other heat dissipation part 22 may extend a predetermined length from the front side of the other side of the solar panel 10 and the rear side of the other side of the solar panel 10 to the outside of the solar panel 10, respectively. Can be.

4 is a plan view schematically illustrating a solar module having excellent heat dissipation efficiency according to a second embodiment of the present invention, FIG. 5 is a cross-sectional view taken along the line C-C of FIG. 4, and FIG. 6 is a line D-D of FIG. According to the cross-sectional view.

Alternatively, as shown in FIGS. 4 to 6, the one side heat dissipation part 21, the other heat dissipation part 22, the front heat dissipation part 23, and the rear heat dissipation part 24 may be formed.

The front side heat dissipation part 23 may be provided on the front side surface of the solar panel 10.

The extension plate 210 of the front side heat dissipation part 23 may extend a predetermined length from one side of the front side of the solar panel 10 and the other side of the front side of the solar panel 10 to the outside of the solar panel 10, respectively. Can be.

Under the central surface of the front panel 110 and the rear panel 120 of the solar panel 10 guides the outside air introduced into the vent 30 to the space (S) formed in the lower direction of the solar panel 10. One guide slit 130 may be formed to extend a predetermined length in the left and right directions.

The rear side heat dissipation part 24 may be provided on the rear side of the solar panel 10.

The extension plate 210 of the rear heat dissipation part 24 may extend a predetermined length from one side of the rear side of the solar panel 10 and the other of the rear side of the solar panel 10 to the outside of the solar panel 10, respectively. Can be.

7 and 8 are plan views schematically showing a state in which the reinforcing partition 40 is provided in the ventilation opening 30.

Next, the reinforcing partition 40 is provided in the vent hole 30 of the heat dissipation unit 20 so that the durability of the heat dissipation unit 20 to the external shock applied to the heat dissipation unit 20 can be greatly improved. This may be formed at regular intervals.

The reinforcing partition 40 is spaced between the inner circumferential surface of the connecting plate 220 of the heat dissipating portion 20 and the side outer circumferential surface of the solar panel 10 so as to be located in the vent 30 of the heat dissipating portion 20. It can be integrally formed.

Next, the through hole 231 may be formed at a predetermined interval in the center of the surface of the bottom plate 230.

9 is a cross-sectional view schematically illustrating a state in which the bottom plate 230 is seated and fixed on the slate roof 91.

In the through hole 231, a fixing member 60 including a piece inserted into and fixed to a roof 9 of a building including a house and the like may be accommodated.

On the other hand, as shown in Figure 9 of the roof 9 of the building, a known slate roof 91 and a plurality of protrusions 910 protruding convex toward the bottom plate 230; And a plurality of recesses 920 formed between the plurality of protrusions 910 and protruding convexly in a lower direction of the plurality of protrusions 910.

10 and 11 are plan views schematically illustrating a state in which a plurality of slits 232 are formed at predetermined intervals on the bottom plate 230.

Here, the fixing position of the fixing member 60, including a piece that is fixed to a plurality of protrusions 910 to a predetermined depth in accordance with the interval (D ₁ ) between the plurality of protrusions 910 of the slate roof (91) In order to more easily adjust and to secure the bottom plate 230 to the slate roof 91 without being limited by the distance between the plurality of protrusions 910 (D ₁ of FIG. 9), FIGS. 10 and FIG. As shown in FIG. 11, at least two slits 232 are formed at predetermined intervals in the center of the surface of the bottom plate 230 to extend in the longitudinal direction of the bottom plate 230 to accommodate the fixing member 60. It is good to be.

Two or more slits 232 extending at a predetermined length in the front-rear direction at the center of the surface of the bottom plate 230 of the one side heat dissipation part 21 and the surface center of the bottom plate 230 of the other side heat dissipation part 22. ) May be formed at regular intervals.

Two or more slits 232 extending at a predetermined length in left and right directions at the center of the surface of the bottom plate 230 of the front side heat dissipation part 23 and the surface center of the bottom plate 230 of the rear side heat dissipation part 24. ) May be formed at regular intervals.

12 and 13 are plan views schematically illustrating a state in which one slit 233 is formed on the bottom plate 230.

Alternatively, as shown in FIGS. 12 and 13, one slit 233 is formed at the center of the surface of the bottom plate 230 to extend in the longitudinal direction of the bottom plate 230 to accommodate the fixing member 60. It could be.

One slit 233 extending in a longitudinal direction in the front-rear direction is formed at the center of the surface of the bottom plate 230 of the one side heat dissipation part 21 and the surface center of the bottom plate 230 of the other side heat dissipation part 22. Can be.

One slit 233 extending at a predetermined length in left and right directions is formed at the center of the surface of the bottom plate 230 of the front heat dissipation part 23 and the surface of the bottom plate 230 of the rear heat dissipation part 24. Can be formed.

One slit 233 extending in a longitudinal direction in a front-rear direction formed at the center of the surface of the bottom plate 230 of the one side heat dissipation portion 21 and the surface center of the bottom plate 230 of the other heat dissipation portion 22. The length of the front and rear may be equal to or shorter than the interval D ₃ between the extension plate 210 of the one side heat dissipation portion 21 and the extension plate of the other side heat dissipation portion 22.

Left and right sides of one of the slits 233 extending in a horizontal direction from the center of the surface of the bottom plate 230 of the front side heat dissipation part 23 and the surface of the bottom plate 230 of the rear side heat dissipation part 24. The length may be the same as or shorter than the interval between the extension plate 210 of the front side heat dissipation unit 23 and the extension plate 210 of the rear side heat dissipation unit 24.

14 and 15 are partial cross-sectional views schematically showing another example of the extension plate 210.

Next, as shown in FIGS. 14 and 15, the extension plate 210 may be composed of a first extension plate 211 and a second extension plate 212.

The first extension plate 211 may extend a predetermined length from the side of the solar panel 10 to the outside of the solar panel 10.

The second extension plate 212 is separable by the fastening member 50 from the first extension plate 211 to the first extension plate 211 so as to move outwardly of the first extension plate 211. Can be fastened.

One slit 211a extending in the longitudinal direction of the first extension plate 211 may be formed at the center of the surface of the first extension plate 211.

One slit extending a predetermined length in the horizontal direction in the center of the surface of the first extension plate 211 of the one side heat dissipation portion 21 and the surface center of the first extension plate 211 of the other side heat dissipation portion 22 ( 211a) may be formed.

One slit extending a predetermined length in the front-rear direction in the center of the surface of the first extension plate 211 of the front side heat dissipation unit 23 and the surface center of the first extension plate 211 of the rear side heat dissipation unit 24 ( 211a) may be formed.

One circular fixing hole 212a may be formed at the center of the surface of the second extension plate 212.

The connection plate 220 connecting the second extension plate 212 may be integrally formed between the second extension plate 212.

The fastening member 50 includes a fixing bolt 510 accommodated inside the fixing hole 212a of the second extension plate 212 and the slit 211a of the first extension plate 211; It may be configured to include; a nut 520 is screwed with the fixing bolt 510.

When the operator gradually moves the second extension plate 212 to the outside of the first extension plate 211 in the state of releasing the fastening state of the fastening member 50, the size of the vent hole 30 is gradually increased. As a result, a larger amount of outside air may be introduced into the ventilation holes 30.

When the operator gradually moves the second extension plate 212 in the direction of the solar panel 10 in the state of releasing the fastening state of the fastening member 50, the size of the vent hole 30 is gradually reduced, As a result, a small amount of outside air may be introduced into the ventilation hole 30.

In this way, by adjusting the size of the ventilation holes 30, not only the inflow amount of the outside air introduced into the ventilation holes 30 can be more easily adjusted, and in particular, the second extension plate 212 is the first extension plate 211. When gradually moving to the outside of the) the size of the vent 30 is gradually increased, so that a larger amount of outside air can be introduced into the vent 30, the heat dissipation efficiency of the solar panel 10 will be further improved It becomes possible.

Next, as shown in FIGS. 2, 3, and 5, a discharge slit 240 may be formed below the central surface of the connecting plate 220 to discharge foreign substances including rainwater.

One discharge slit 240 may be formed at a lower side of the surface center of the connection plate 220 of the one side heat dissipation unit 21 and a lower side of the surface center of the other side heat dissipation unit 22. .

One discharge slit 240 extending in a horizontal direction at a lower side of the center of the surface of the connecting plate 220 of the front side heat dissipation unit 23 and of the rear of the connecting plate 220 of the rear side heat dissipating unit 24. ) May be formed.

The foreign matter including rainwater introduced into the space S formed in the lower direction of the solar panel 10 is formed in the space S formed in the lower direction of the solar panel 10 through the discharge slit 240. It can be discharged to the outside smoothly.

According to the present invention configured as described above, when the wind blows outside air is introduced through the ventilation holes 30 formed inside the heat dissipation unit 20 provided on the side surface of the solar panel 10. Since the ventilation can be performed smoothly while passing through the space (S) formed inside the lower side, the heat dissipation efficiency of the solar panel 10 can be greatly improved, and as a result, the electricity generation efficiency of the solar panel 10 can be reduced. There is no concern.

10; Solar panels, 20; Heat sink.

Claims (10)

In the solar module comprising a solar panel 10 for collecting electricity to generate electricity,
On the side of the solar panel 10 is provided a heat dissipation unit 20 is formed inside the ventilation hole 30 for entering the outside air,
The heat dissipation unit 20 includes an extension plate 210 extending from the side of the solar panel 10 to the outside of the solar panel 10 by a predetermined length;
A connection plate 220 integrally formed between the extension plates 210 and connecting the extension plates 210;
And a bottom plate 230 horizontally extended in the lateral direction of the solar panel 10 at the lower side of the connection plate 220,
The ventilation hole 30 is formed inside the extension plate 210 and inside the connection plate 220 so as to be positioned in an upper direction of the bottom plate 230,
One slit 233 extending in the longitudinal direction of the bottom plate 230 is formed in the bottom plate 230,
The extension plate 210 may include a first extension plate 211 extending from the side of the solar panel 10 to the outside of the solar panel 10 by a predetermined length;
A second extension plate 212 detachably fastened by the fastening member 50 to the first extension plate 211 so as to move outwardly from the first extension plate 211 in the first extension plate 211; );
The solar module with excellent heat dissipation efficiency, characterized in that the discharge plate 240 is formed in the connecting plate 220. delete delete delete delete delete delete delete delete delete

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