KR101726338B1 - Cooling system for building integrated photovoltaic system - Google Patents

Abstract

A cooling system for a building integrated photovoltaic power generation system is disclosed. A cooling system of a building-integrated solar power generation system of the present invention includes a water-cooled cooling unit provided between a solar cell module of a building-integrated solar power generation system and an outer wall of a building to cool the solar cell module; A cooling tower provided in the building to supply cooling water to a water-cooled cooling unit; A conduit portion connected to the cooling tower and the water-cooled cooling portion and provided as a flow path of the cooling water; And a valve portion provided in the conduit portion to open and close the conduit portion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling system for an integrated photovoltaic (PV)

The present invention relates to a cooling system, and more particularly, to a cooling system of a building-integrated solar power generation system for cooling a solar cell module of a building-integrated solar power generation system using cooling water supplied from a cooling tower.

A building integrated photovoltaic system is a system that constructs the exterior of a building by integrating a solar panel in a building exterior. Building integrated photovoltaic power generation system can be used in buildings by installing solar power modules on the exterior of buildings such as windows, walls, and balconies and producing electricity by itself.

In addition to producing electricity from solar energy and supplying it to consumers, it is also used as a design element to reduce the construction cost and increase the value of the building by using the integrated solar module as building exterior material.

Meanwhile, the solar cell module of the building integrated solar power generation system has a problem that the amount of solar radiation irradiated to the surface, the self heat of the solar battery module generated in the electric production process, the surrounding atmosphere state in which the solar battery module is installed, The thermal efficiency and the electric power generation efficiency are influenced by the heat load of the electric power generation system.

For example, when the temperature of the solar cell module rises by about 1 degree, the electric energy conversion efficiency drops to about 0.5%, and when the temperature rises by about 20 degrees, the electric energy conversion efficiency drops to about 10%.

Further, since a plurality of solar cells are provided at predetermined intervals between the front glass and the rear glass, and a back sheet for protecting cells is additionally provided, it is difficult to dissipate heat.

Therefore, as the self-temperature of the solar cell module is kept as low as possible, it is necessary to improve the electric energy conversion efficiency and the insulation effect of the indoor space where the solar cell module is installed, so that the temperature rise of the solar cell module can be effectively suppressed.

The above-described technical structure is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

Korean Registered Patent No. 10-0976353 (Sunchon National University Industry & University Collaboration Foundation) 2010. 08. 10

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide a cooling system for a building-integrated photovoltaic power generation system in which a solar cell module of a building integrated solar power generation system is cooled using cooling water supplied from a cooling tower.

According to an aspect of the present invention, there is provided a solar cell module comprising: a water-cooled cooling unit provided between a solar cell module of a building-integrated solar power generation system and an outer wall of a building to cool the solar cell module; A cooling tower provided in the building to supply cooling water to the water-cooled cooling unit; A conduit part connected to the cooling tower and the water-cooled cooling part and provided as a flow path of the cooling water; And a valve unit provided in the conduit to open and close the conduit part.

The solar cell module may further include a temperature sensor provided in the solar cell module, and the valve unit may open and close the duct part based on a temperature sensed by the temperature sensor.

Wherein the conduit portion comprises: a supply conduit connecting the water-cooled cooling portion and the cooling tower to supply the cooling water to the water-cooled type supply portion; A return pipe connecting the cooling-water cooling unit and the cooling tower to return the cooling water discharged from the solar cell module to the cooling tower; And a check valve provided on the return pipe to prevent backflow of the cooling water returned to the cooling tower.

Wherein the valve unit comprises: a main on-off valve provided on the supply conduit at a position close to the cooling tower for selectively opening and closing the cooling water discharged from the cooling tower; And a plurality of open / close valves provided on the supply conduit at a position close to the water-cooled cooler and opening / closing the supply conduit connected to each of the water-cooled coolers.

And a bypass unit provided in the conduit to bypass the cooling water supplied from the cooling tower to the cooling tower.

Wherein the bypass unit includes: a bypass pipe connecting the return pipe to the supply pipe; A bypass valve provided in the bypass conduit to open the bypass conduit; And a bypass check valve provided in the return conduit to prevent backflow of the cooling water bypassed.

Wherein the plurality of solar cell modules and the water-cooled cooling unit are provided, and when cooling only selected solar cell modules of the plurality of solar cell modules, And the cooling water can be supplied only to the water-cooled cooling unit coupled to the selected solar cell module by closing the on-off valve.

Embodiments of the present invention make it possible to utilize cooling towers which are substantially operated in summer in consideration of heat generation of solar cell modules in summer, And the cooling performance can also be increased.

In addition, the cooling water of the cooling tower can be used to lower the temperature of the outer wall of the building, thereby improving the cooling performance of the building.

FIG. 1 is a perspective view schematically illustrating a cooling system of a building-integrated photovoltaic power generation system according to an embodiment of the present invention.
2 is a schematic cross-sectional view of the water-cooled cooling unit shown in Fig.
FIG. 3 is an operation diagram when a plurality of water cooling type cooling units and solar cell modules shown in FIG. 1 are provided.
FIG. 4 is an operation diagram showing that the water-cooled cooling unit shown in FIG. 3 and a part of the solar cell module are operated.
5 is an operation diagram of the bypass section shown in Fig.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

FIG. 1 is a perspective view schematically showing a cooling system of a solar power generation system according to an embodiment of the present invention, FIG. 2 is a schematic cross-sectional view of the water-cooled cooling unit shown in FIG. 1, FIG. 4 is an operation diagram showing that a part of the water-cooled cooling unit and the solar cell module shown in FIG. 3 are operated, and FIG. 5 is a diagram 3 is an operation diagram of the bypass unit shown in Fig.

As shown in these drawings, the cooling system 1 of the building-integrated solar power generation system according to the present embodiment is provided between the solar cell module M of the building-integrated solar power generation system and the outer wall of the building B A cooling tower 200 provided in the building B for supplying cooling water to the water cooling type cooling unit 100; a cooling tower 200 for cooling the solar cell module M; a water cooling type cooling unit 100 And a temperature sensor 400 provided in the solar cell module M and a valve unit 300 provided in the duct unit 300 for opening and closing the duct unit 300, A bypass unit 600 provided in the conduit unit 300 to directly supply the cooling water supplied from the cooling tower 200 to the cooling tower 200 by bypassing the water cooled cooling unit 100, And a pump for returning the cooling water heat-exchanged in the water-cooled cooling unit 100 to the cooling tower 200 700).

1, one side of the cooling unit 100 is in contact with the bottom of the solar battery module M and the other side of the cooling unit 100 is in contact with the outer wall of the building B, To the cooling water supplied from the cooling tower (200).

Also, in this embodiment, since the water-cooled cooling unit 100 can be brought into contact with the outer wall of the building B, it can also cool the building B.

In this embodiment, the water-cooled cooling unit 100 may be bolted to the outer wall of the solar cell module M and the building B using a bracket detachably.

2, the water-cooled cooling unit 100 includes a cooling body 110 having an inlet 111 through which cooling water flows and an outlet 112 through which heat-exchanged cooling water is discharged, And a plurality of partition walls 120 provided in a jig jig shape to delay the flow of the cooling water.

The cooling tower 200 is a known structure provided on the roof of the general building B to supply cooling water for cooling the air conditioner. In this embodiment, the piping of the cooling tower 200 and the cooling tower 200, Can be used.

That is, the supply pipe 310 connected to the water-cooled cooling unit 100 and the return pipe 320 are connected to the piping of the installed cooling tower 200 to supply the cooling water discharged from the cooling tower 200 to the water-cooled cooling unit 100 And cooling water whose temperature has been increased by heat exchange in the water-cooled cooling unit 100 can be cooled in the cooling tower 200.

The conduit unit 300 supplies the cooling water of the cooling tower 200 to the water cooling type cooling unit 100 and the cooling water that is heat-exchanged in the water cooling type cooling unit 100 is returned to the cooling tower 200 again.

3, the conduit unit 300 includes a supply pipe 310 connecting the water-cooled cooling unit 100 and the cooling tower 200 to supply the cooling water to the water-cooled supply unit, A return duct 320 connected to the cooling tower 200 to return the cooling water discharged from the solar cell module M to the cooling tower 200 by connecting the cooling tower 100 and the cooling tower 200, And a check valve 330 for preventing reverse flow of the cooling water.

The cooling water discharged from the cooling tower 200 may be supplied to the water cooling type cooling unit 100 through the supply pipe 310 by gravity because the cooling tower 200 is at the top of the building B, have.

The cooling water heat exchanged with the solar cell module M in the water cooling type cooling unit 100 is supplied to the cooling water supplied to the building B through the supply pipe 310 and the pumping power of the pump 700 installed on the roof of the building B, May be returned to the cooling tower 200 through the cooling tower 320.

The cooling water discharged through the return pipe 320 can be prevented from being returned to the water-cooled cooling unit 100 by the check valve 330 provided in the return pipe 320.

1 and 3, the temperature sensor 400 is provided on the solar cell module M to sense the temperature of the solar cell module M, and the temperature sensed by the temperature sensor 400 is controlled by the control unit Not shown). The control unit selectively opens and closes the main on-off valve 510 and the on-off valve 520 based on this temperature to selectively cool the solar cell module M. [

3, the valve unit 500 includes a main on-off valve 510 provided on a supply line 310 at a position close to the cooling tower 200 and selectively opening and closing the cooling water discharged from the cooling tower 200, And an open / close valve 520 which is provided in a supply pipe 310 at a position close to the water-cooled cooling unit 100 and opens and closes the supply pipe 310 connected to the respective water-cooled cooling units 100 do.

In this embodiment, when the main on-off valve 510 is locked, the cooling water is not supplied to the water-cooling unit 100. Therefore, when it is not necessary to cool the solar cell module M because the temperature of the outside air is low, The cooling water can be prevented from being supplied to the water-cooled cooling unit 100.

In addition, in the present embodiment, the opening and closing valve 520 serves to lock the flow path of the cooling water supplied to each of the water-cooled cooling units 100.

4, when it is necessary to supply cooling water only to the water-cooled cooling unit 100 arranged in the middle, only the corresponding on-off valve 520 is opened and all the other on-off valves 520 are locked, There is an advantage that the cooling unit 100 can be cooled more quickly and efficiently.

The bypass unit 600 bypasses the water-cooled cooling unit 100 when the water-cooled cooling unit 100 is required to be completely checked or the water-cooled cooling unit 100 needs to be repaired during operation of the cooling tower 200, (200).

3 and 5, the bypass unit 600 includes a bypass pipe 610 connecting the supply pipe 310 and the return pipe 320, a supply pipe 310 connecting the supply pipe 310 and the return pipe 320, An auxiliary bypass conduit 620 connected to the return conduit 320 and used as a bypass for the bypass conduit 610 and a bypass conduit 610 provided in the bypass conduit 610 and the auxiliary bypass conduit 620, A bypass valve 630 for opening and closing the auxiliary bypass pipe 620 and a bypass check valve 640 provided in the return pipe 320 to prevent the reverse flow of the cooling water bypassed.

Hereinafter, the operation of the bypass unit 600 will be briefly described with reference to FIG.

When the cooling water should not be supplied to the water cooling type cooling unit 100 because the water cooling type cooling unit 100 needs to be entirely inspected, an on / off valve 520 disposed close to each water cooling type supply unit, The installed bypass valve 630 is closed.

Cooling water is not supplied to each of the water-cooled cooling units 100 as shown in FIG. 5 when the on-off valve 520 and the bypass valve 630 provided on the auxiliary bypass line 620 are locked. The cooling water supplied from the cooling tower 200 is returned to the cooling tower 200 through the bypass conduit 610 and the return conduit 320 when the bypass valve 630 in the bypass conduit 610 is opened .

As described above, in the present embodiment, considering the fact that the heat of the solar cell module is a problem in summer, it is possible to utilize the cooling tower which is practically operated in summer, so that the cooling and circulation structure for using the water- And the cooling performance can also be increased.

In addition, the cooling water of the cooling tower can be used to lower the temperature of the outer wall of the building, thereby improving the cooling performance of the building.

Further, it is possible to facilitate the inspection and repair of the water-cooled cooling part through the bypass part.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1: Cooling system of building integrated PV system
100: water-cooled cooling unit 110: cooling body
111: inlet 112: outlet
120: bulkhead 200: cooling tower
300: conduit part 310: supply conduit
320: return pipe 330: check valve
400: Temperature sensor 500:
510: main opening / closing valve 520: opening / closing valve
600: Bypass unit 610: Bypass pipe
620: auxiliary bypass line 630: bypass valve
640: Bypass check valve 700: Pump
B: Building M: Solar module

Claims (7)

A water cooling type cooling unit provided between the solar cell module of the building integrated solar power generation system and the outer wall of the building to cool the solar cell module;
A cooling tower provided in the building to supply cooling water to the water-cooled cooling unit;
A cooling water supply unit for supplying cooling water to the water cooling type cooling unit, a cooling water supply unit for cooling the water cooling type water cooling type cooling unit, And a check valve provided on the return pipe to prevent backflow of the cooling water returned to the cooling tower;
A main opening / closing valve provided on the supply pipe at a position close to the cooling tower for selectively opening / closing the cooling water discharged from the cooling tower, and a plurality of water supply / A valve unit having an open / close valve for opening / closing the supply channel connected to the valve unit;
A temperature sensor provided in the solar cell module; And
And a bypass unit provided in the conduit for bypassing the cooling water supplied from the cooling tower to the cooling tower,
Wherein the water cooling type cooling unit includes a cooling body having a solar cell module and a cooling body provided with a discharge port through which the cooling water heat exchanged with the solar cell module is detachably attached to the outer wall of the building by using a bracket and an inlet port through which the cooling water flows and a zigzag And a plurality of partition walls provided to delay the flow of the cooling water,
Wherein the bypass unit includes a bypass pipe connecting the supply pipe and the return pipe, a bypass valve provided in the bypass pipe to open the bypass pipe, and a bypass valve provided in the return pipe to prevent backflow of the cooling water bypassed A bypass check valve,
The plurality of solar cell modules and the water-cooled cooling unit are provided,
Wherein when the selected solar cell module is cooled only by the plurality of solar cell modules, the open / close valve provided in the other water-cooled cooling unit except for the water-cooled cooling unit coupled to the selected solar cell module is closed, Cooling water is supplied only to the cooling part,
Wherein the water-cooled cooling part is in contact with an outer wall of the building to cool the building,
Wherein the cooling tower is installed on a roof of the building as it is. delete delete delete delete delete delete

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