KR101960728B1 - Apparatus of cooling and snow removal in building integrated photovoltaic module - Google Patents

Abstract

The present invention provides a cooling and snow removing apparatus for a building-integrated photovoltaic power generation facility. The cooling and snow removing apparatus comprises: a spray unit (300) including a main pipe (310) having a predetermined length and positioned along a seating end (210), a branch pipe (320) having one end side connected to the main pipe (310) and the other side extended by a predetermined length to one side of the inside of a drain unit (100), a spray nozzle (330) coupled to an end of the other side of the branch pipe (320) and having an upper end side exposed through a through hole (142) of a cover plate (140), a first valve (340) installed between the branch pipe (320) and the spray nozzle (330) to control movement of a fluid through the branch pipe (330), a second valve (350) installed between the first valve (340) and the spray nozzle (330) to constantly adjust the flow of a fluid through the branch pipe (330), and a control box (360) installed inside the other side of the drain unit (100) to control an operation of each of the first and second valves (340, 350); and a storage tank unit (400) including a first storage tank (410) installed on the ground adjacent to a building (B) and storing cooling water, a second storage tank (420) installed on the ground adjacent to the first storage tank (410) and storing a snow removing solution, and a pump (430) connected to each of the first and second storage tanks (410, 420) to supply cooling water or snow removing solution to the main pipe (310). Heat and snow can be removed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooling and snow removal system for a building-

More particularly, the present invention relates to an apparatus capable of cooling and snowing, and more particularly, to an apparatus capable of cooling and snowing, and more particularly, To cool the cooling water or to make it possible to very easily remove the snow accumulated on the top surface of the solar module.

There is a growing interest in the building integrated photovoltaic module, which closes the roof of the building itself as a photovoltaic module, in order to protect the environment and secure electric energy for a long time in construction of modern buildings .

Since the integrated PV system of the building is constructed to directly construct the solar module itself on the building without any separate facilities, it is advantageous to reduce the construction cost as well as the construction period. However, There is a need for an apparatus for preventing the deterioration of the structural stability of the building due to winter snow.

Korean Patent No. 1663782 discloses a technique for eliminating overheating or snowing of a solar module. 6, when the temperature of the solar module is appropriately measured, the cooling water is sprayed when the solar module is overheated, and when the solar module is cooled or snow falls, the hot water is sprayed to the solar module There is a technical feature in cooling the module or removing snow.

However, most of the technologies proposed to date, including this technology, are not directed to building integrated photovoltaic power generation facilities. Instead, they are installed on the ground separately from buildings, It is difficult to directly apply them to a building integrated solar power generation facility because it is intended to be applied to an installed solar power facility.

Korean Patent No. 1238211 Korean Patent No. 1337475 Korea Patent No. 1663782 Korean Patent No. 1758767

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the related art, and it is an object of the present invention to provide a solar cell module, which is installed inside a solar power generation facility and removes heat generated in the solar power generation process, In which the apparatus is provided.

In order to achieve the above object, the present invention is characterized in that a plurality of units arranged at a certain distance from each other are provided, each of which has a fixed vertical height 12 at a central portion thereof, A plurality of solar modules 20 arranged in a series and placed on the mounting stage 12 of each of the mounting bars 10 facing each other on both left and right ends thereof, The solar cell module 20 includes a solar cell module 20 having a plate-like structure having a predetermined area, and a plurality of solar cell modules 20, A drain plate 110 located in the drainage passage 16 and a pair of right and left ends of the drainage plate 110 bent at a predetermined vertical height and each outer side portion extending in the longitudinal direction in a central portion of the drainage passage 16 A coupling plate 120 fixedly coupled to the partition wall 17 protruding vertically at a vertical height, a coupling plate 120 bent at a predetermined vertical height at both front and rear ends of the drain plate 110, A drainage guide plate 130 having drainage grooves 132 formed at the left and right ends of the drainage plate 110 and a plate-like structure having a predetermined area and sealing the upper space of the drainage plate 110 at a predetermined distance vertically above the drainage plate 110 A drainage section 100 composed of a cover plate 140; And a plurality of installation bars 10 which are mutually opposed to each other and are spaced apart from each other along a drainage passage 16 of the installation bar 10, 210), and a coupling clip (220) provided at one side of the installation stage (210) and fixed to the partition (17). A main pipe 310 having a predetermined length and located along the installation stage 210 and a branch pipe 320 connected to the main pipe 310 at one end and extending a certain length to one side of the inside of the drainage unit 100, An injection nozzle 330 coupled to an end of the other branch of the branch tube 320 and having an upper end exposed through the through hole 142 of the cover plate 140 and a branch nozzle 330 extending between the branch tube 330 and the injection nozzle 330 A first valve 340 installed between the first valve 340 and the injection nozzle 330 for controlling the flow of the fluid through the branch pipe 330 and a second valve 340 installed between the first valve 340 and the injection nozzle 330 for controlling the flow of the fluid through the branch pipe 330 A spraying part 300 provided inside the other side of the drainage part 100 and having a control box 360 for controlling the operation of the first and second valves 340 and 350; A first storage tank 410 in which cooling water is stored and installed on the ground adjacent to the building B, a second storage tank 420 installed in the ground adjacent to the first storage tank 410 with the snow remover stored therein, And a storage tank unit 400 connected to each of the first and second storage tanks 410 and 420 and having a pump 430 for supplying the cooling water or the snow remover to the main pipe 310. [ .

According to the present invention, it is possible to selectively spray coolant and snow-removing liquid according to season or weather conditions, thereby preventing structural damage of a building due to overheating or snowing of a solar module, Can be installed in a separate internal space between the photovoltaic modules provided with the drainage function, so that the rainwater flowing into the building can be discharged to the outside without damaging the appearance of the building at all.

Further, the present invention proposes a method of installing the main pipe to which the cooling water and the snow remover are supplied by the separate means above the drainage channel, thereby minimizing occupancy of the drainage space by the main pipe and, at the same time, Even if a part of the snow remover leaks out, it is possible to discharge the snow remover naturally through the drainage path without infiltration into the inside of the building.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic overall view of a cooling and snow removal system for a solar power generating facility integrated with a building according to the present invention; FIG.
FIG. 2 is a schematic view of a building roof according to the present invention in a cooling and snow removal system of a solar power generating facility with integrated buildings. FIG.
FIG. 3 is a schematic perspective view of an installation bar, a drainage unit, and a spraying unit in a cooling and snow removal system of a solar power generation facility with a built-in building according to the present invention.
FIG. 4 is a schematic side cross-sectional view of an installation bar, a drainage part, and a spraying part in a cooling and snow removal system of a solar power generation facility with a built-in building according to the present invention.
FIG. 5 is a schematic view showing a connection structure between an installation bar and a drainage part in a cooling and snow removal system of a solar power generation facility with a built-in building according to the present invention. FIG.
6 is a schematic view showing an example of a cooling and snow removal apparatus of a solar power generation facility fixedly installed on the ground in the past.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

1 and 2 show a schematic overall external structure of a cooling system and a snow removal system of a building integrated solar power generation facility according to the present invention and a schematic external structure of a roof part, In the cooling and snow removal system of the integrated solar power generation facility, a schematic view of the installation bar, the drainage part, and the spray part is shown.

As shown in the drawings, the present invention includes a mounting bar 10, a solar module 20, a drainage unit 100, a mounting unit 200, a spraying unit 300, and a storage tank unit 400 There is a technical feature to be achieved. Hereinafter, each of these configurations will be described in detail.

The installation bar 10 is a means for supporting the solar module 20 and guiding rainwater infiltrating between adjacent solar modules 20 to the outside, and is composed of a plurality of units arranged at a certain distance from each other. Each installation bar 10 having a predetermined length is provided with a mounting stage 12 and a drainage passage 16.

The mounting terminal 12 is formed in a longitudinal direction with a predetermined vertical height at a central portion of the mounting bar 10. The left and right end portions of the solar module 20 are fixed to the left and right sides of the mounting stage 12, respectively.

The drainage passage 16 is formed to have a predetermined length along the left and right sides of the stationary stage 12, and the respective end portions of the left and right sides are formed with a latching end 18 bent at a predetermined vertical height. A partition wall 17 having a predetermined vertical height and extending in the longitudinal direction is provided at a central portion of the drainage passage 16.

It is preferable that the height of the mounting end 12 is larger than the height of the barrier rib 17 and the height of the barrier rib 17 is greater than the height of the holding end 18. As the partition wall 17 is formed, the space of each drainage passage 16 is partitioned to the left and right.

The installation bar 10 is fixed on the upper surface of a horizontal bar (not shown) for reinforcing the lower lateral supporting force of the building roof. At this time, a pier plate and a heat insulating material may be further provided between the installation bar 10 and the horizontal bar. These various configurations are well known in the related art, and detailed description will be omitted.

A plurality of solar modules 20 are installed in series in a mounting stage 12 of each installation bar 10, which are arranged so that their left and right ends are opposed to each other. Typically, the solar module is closed by a metal frame, and the end of the metal frame is mounted on the mount 12 and coupled.

The drainage section 100 is a means for supporting the spraying section 300 and for guiding the penetrating rainwater to the outside. The drainage unit 100 includes a drainage plate 110, a coupling plate 120, a drainage guide plate 130, and a cover plate 140.

The drain plate 110 has a plate-like structure having a predetermined area and is disposed between the solar modules 20. The opposite ends of the drain plate 110 are located in the drainage passage 16 of each of the installation bars 10 facing each other .

4 and 5, the coupling plate 120 is bent at a predetermined vertical height on both left and right ends of the drain plate 110, and the outer surface of the coupling plate 120 is fixedly coupled to the partition 17. Accordingly, the drain plates 110 are mutually opposed and tightly fixed to the adjacent mounting bars 10 to be integrated. Reference numeral 122 denotes a fastening bolt.

The drainage guide plate 130 is bent at a predetermined vertical height on both the front and rear ends of the bottom plate 110 as shown in the figure. Particularly, at the both left and right ends adjacent to the coupling plate 120, . The discharge groove 132 is a portion for guiding the rainwater introduced into the drain plate 110 to the drainage passage 16.

The cover plate 140 has a plate-like structure having a predetermined area similar to the drain plate 110 and is located at a certain distance from the vertical direction of the bottom plate 110 to seal the upper space of the bottom plate 110. Accordingly, a receiving space of a predetermined size is provided between the bottom plate 110 and the cover plate 140. At least one through hole 142 for the injection nozzle 330 to be described later is formed in the cover plate 140.

Between the bottom plate 110 and the installation bar 10 and between the bottom plate 110 and the solar module 20 there can be provided coupling bars 152 and 156, (152, 156).

The drainage unit 100 may be disposed between the plurality of solar modules 20. Whether or not the drainage unit 100 is disposed between the plurality of the solar modules 20 is determined by the total solar panel area, The spraying ability of the spraying unit 300, and the like.

As described above, in installing the spraying unit 300 for spraying the cooling water or the snow remover, an additional drainage unit 100 is provided between the solar modules 20 and installed in the interior space of the spraying unit 300, The discharge grooves 132 connected to the discharge port 16 are formed separately so that rainwater flowing into the building without damaging the appearance of the building can be discharged naturally to the outside.

The mounting portion 200 is a means for mounting a main pipe 310 to be described later and is installed at a predetermined distance from each other along a drainage passage 16 of one of the installation bars 10 of the mutually opposing installation bars 10 .

At this time, each of the stationary parts 200 may be formed as an engagement clip 220 having an integral structure with the stationary end 210 and the stationary end 210. The attachment terminal 210 is convexly bent downward as shown in the drawing for a stable installation of the main pipe 310. The attachment clip 220 is provided at one side of the installation terminal 210 and is fastened as a fastening bolt 222 to the partition wall 17 ).

The sprayer 300 is a means for spraying the cooling water or the snow remover supplied to each solar module 20 and includes a main pipe 310, a branch pipe 320, a spray nozzle 330, a first and a second valve 340 350, and a control box 360.

The main pipe 310 has a predetermined length and is located along the seating 210. One end of the branch pipe 320 is connected to the main pipe 310, and the other end of the branch pipe 320 is extended to one side of the inside of the drainage unit 100 by a predetermined length. Here, the inside of the drainage unit 100 is an internal storage space formed by the drainage plate 110 and the cover plate 140.

It is possible to minimize the space occupied by the main pipe 310 in the drainage passage 16 as the main pipe 310 is supported by the installation stage 210 having a predetermined vertical height above the drainage passage 16. Further, if leakage occurs from the main pipe due to damage of the main pipe 310, the water falls down to the drainage passage 16 below the main pipe 310 and can be discharged to the outside.

At this time, it is preferable that the main pipe 310 is made of a metal or synthetic resin pipe having a predetermined shape, and the branch pipe 320 is preferably made of a structure capable of elongating and expanding. If a plurality of jetting units 300 are provided, the branch tube 320 should also be branched from the main tube 310 in accordance with the number.

The injection nozzle 330 is coupled to the other end of the branch pipe 320 and the upper end thereof is exposed through the through hole 142 of the cover plate 140. The reason for exposing the upper end portion of the injection nozzle 330 through the through hole 142 is to minimize inflow of rainwater through the through hole 142.

The injection nozzle 330 according to the present invention may be a pop up nozzle. When the high-pressure fluid flows into the nozzle, the nozzle tip 332 of the nozzle vertically ascends a certain distance as shown in FIG. 4, and when the flow of the fluid is stopped, the nozzle tip 332 of the nozzle descends and returns to the original position . Such pop-up nozzles are widely known in the related art in various configurations, so detailed description is omitted.

The first valve 340 is installed between the branch pipe 330 and the injection nozzle 330 and controls the movement of the fluid through the branch pipe 330. The second valve 350 is installed between the first valve 340 and the injection nozzle 330 and regulates the flow of the fluid through the branch pipe 330 in a constant manner. Each of the first and second valves 340 and 350 may be composed of a conventional solenoid valve and a flow control valve.

The control box 360 is installed inside the other side of the drainage unit 100. Inside the control box 360, a control board for controlling the operation of the first and second valves 340 and 350 is provided. Reference numeral 370 denotes a pipe for protecting the power supply and the communication cable. If a plurality of jetting parts 300 are provided, it is needless to say that the protective pipe 370 is extended as shown in the drawing.

The storage tank unit 400 includes the first and second storage tanks 410 and 420 and the pump 430 as means for storing and supplying the cooling water and the snow remover. Cooling water is stored in the first storage tank 410 and installed on the ground adjacent to the building B. The second storage tank 420 stores the remained liquid, and is installed on the ground adjacent to the first storage tank 410.

The pump 430 is connected to each of the first and second storage tanks 410 and 420 as means for selectively supplying the cooling water or the snow remover to the main pipe 310. Means for controlling the operation of the pump 430 may be separately provided in the building B. Although the case where the storage tank unit 400 is provided outside the building B is shown in the drawing, it is needless to say that the storage tank unit 400 may be provided inside the building B.

As described above, according to the present invention, it is possible to selectively supply the cooling water and the snow remover to the spray nozzles in accordance with season or weather conditions while separately storing the cooling water and the snow remover, respectively, And the structural stability of the building roof can be prevented from being damaged due to the snow cover.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

10: Installation Bar 20: Solar Module
100: drain part 200: mounting part
300: jetting part 400: storage tank part

Claims (1)

(12) having a predetermined vertical height are provided at the central portions of the plurality of installation bars (12), and the installation bar (16) is provided at each of the left and right sides of the installation platform Integrated solar power generation equipment including a plurality of solar modules 20 arranged in series and placed on the mounting stage 12 of each of the installation bars 10 facing each other on both left and right sides, Or snowing,
A drainage plate 110 disposed in the drainage passage 16 of each of the installation bars 10 disposed between the solar modules 20 and having opposite ends facing each other, A coupling plate 120 which is bent at a predetermined vertical height at each of both end portions and each outer surface portion is formed at a central portion of the drainage passage 16 in the longitudinal direction and fixedly coupled to the partition wall 17 vertically protruding at a vertical height, A drainage guide plate 130 which is bent at a predetermined vertical height on both front and rear ends of the drainage plate 110 and which has drainage grooves 132 formed at the left and right ends adjacent to the coupling plate 120, And a cover plate 140 for sealing the upper space of the drain plate 110 at a predetermined distance vertically above the drain plate 110;
And a plurality of installation bars 10 which are mutually opposed to each other and are spaced apart from each other along a drainage passage 16 of the installation bar 10, 210), and a coupling clip (220) provided at one side of the installation stage (210) and fixed to the partition (17).
A main pipe 310 having a predetermined length and located along the installation stage 210 and a branch pipe 320 connected to the main pipe 310 at one end and extending a certain length to one side of the inside of the drainage unit 100, An injection nozzle 330 coupled to an end of the other branch of the branch tube 320 and having an upper end exposed through the through hole 142 of the cover plate 140 and a branch nozzle 330 extending between the branch tube 330 and the injection nozzle 330 A first valve 340 installed between the first valve 340 and the injection nozzle 330 for controlling the flow of the fluid through the branch pipe 330 and a second valve 340 installed between the first valve 340 and the injection nozzle 330 for controlling the flow of the fluid through the branch pipe 330 A spraying part 300 provided inside the other side of the drainage part 100 and having a control box 360 for controlling the operation of the first and second valves 340 and 350;
A first storage tank 410 in which cooling water is stored and installed on the ground adjacent to the building B, a second storage tank 420 installed in the ground adjacent to the first storage tank 410 with the snow remover stored therein, A storage tank 400 connected to each of the first and second storage tanks 410 and 420 and having a pump 430 for supplying cooling water or a snow remover to the main pipe 310;
And the cooling and snowing device of the integrated solar power generation facility.

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