KR20180081306A - Unit module of rainwater harvesting and storage integrated with solar PV modules - Google Patents

Abstract

The present invention relates to a solar power generator and rainwater collecting tank integrated unit module comprising a lower frame for supporting a lower surface, an upper frame for supporting an upper surface, a post disposed between each lower corner of the lower frame and the upper frame, A first photovoltaic power generation panel rotatably coupled to the front surface of the unit module at a predetermined angle; A second solar power generation panel rotatably coupled to the upper surface of the unit module at a predetermined angle; A third solar power generation panel rotatably coupled to the rear surface of the unit module at a predetermined angle; And a collecting tank interposed between the lower surface and the upper surface and collecting rainwater through the through holes of the upper surface.

Description

[0001] The present invention relates to an integrated unit module for solar power generation and stormwater collecting tanks,

The present invention relates to a unit module having a solar power generating function and a rainwater collecting function.

As is widely known, climate change due to global warming and / or global environmental pollution creates droughts and floods, which limits the ability to secure adequate drinking water only through conventional water management systems.

In particular, in areas where there is no water system in the island or mountainous areas, or where groundwater development is difficult due to lack of groundwater pollution and water supply, rainwater is collected and used as a shortage of living water and drinking water.

For this purpose, a rainwater storage automatic irrigation system that can receive rainwater and use it as a living water is disclosed in Patent Document 1. In addition, a solar water heater for effectively performing irrigation work in a book area or a mountainous area where power supply is not abundant, .

The rainwater storage automatic irrigation system according to Patent Document 1 is inevitably enlarged in order to obtain sufficient solar light condensation and water quantity and as a result the mobility is remarkably reduced resulting in serious inhibition of expansion of supply to the installation area requiring electricity and domestic water supply Element.

Korean Patent Publication No. 10-2011-0087543

The present invention has been made in order to solve the above-described problems, and it is an object of the present invention to provide a solar power generating apparatus capable of securely supplying power by using sunlight through a solar power generation panel, To provide a mobile unit module of the present invention.

In order to achieve the above object, a solar integrated unit and a rainwater collecting tank integrated unit module according to a preferred embodiment of the present invention includes a lower frame for supporting a lower surface, an upper frame for supporting an upper surface, A first solar power generation panel formed in a rectangular parallelepiped shape including posts arranged between respective corner portions, the first solar power generation panel being rotatably coupled at a predetermined angle on the front surface of the unit module; A second solar power generation panel rotatably coupled to the upper surface of the unit module at a predetermined angle; A third solar power generation panel rotatably coupled to the rear surface of the unit module at a predetermined angle; And a collecting tank interposed between the lower surface and the upper surface and collecting rainwater through the through holes of the upper surface.

Here, the water collecting tank has a vertical pipe disposed at the rear surface of the water collecting tank, a water inlet pipe branched from the upper side of the water pipe and communicating with the water collecting tank, An inflow portion having a floating body that floats on the water surface of the rainwater inside the vertical tube to close the sealing portion, and a drain valve that opens and closes the lower end portion of the vertical tube; A guide pipe extending in the width direction of the collecting tank so as to be in fluid communication with the rear end of the at least one outlet pipe and a connector for connecting pipes at both ends of the guide pipe, A discharge outlet; And a pair of valves disposed in a lower portion of the collecting tank.

In the present invention, the first solar power generation panel and the third solar power generation panel may be angularly adjusted on the front surface or the rear surface by means of an angle adjusting portion.

The angle adjusting portion comprises a first connecting bar hinged at a side edge of the solar power generating panel, a second connecting bar hinged to each post, and a connecting nut connecting the first connecting bar and the second connecting bar in a straight line .

Specifically, the fixed end of the first connecting bar is hinged to the side edge of the solar power generating panel and the free end of the first connecting bar forms a male thread in one direction on its outer circumference, and the fixed end of the second connecting bar And the free end of the second connecting bar can form a male screw thread in the other direction on the outer circumferential surface thereof. The connecting nut includes a first nut portion to be screwed with the free end of the first connecting bar, a second nut portion to be screwed with the free end of the second connecting bar, and a second nut portion to which the first nut portion and the second nut portion are connected in a straight line As shown in Fig.

The first crossing frame disposed across a pair of side frames arranged in parallel adjacent to the front end of the upper frame hinges the second solar power generation panel to the first crossing frame.

In addition, the present invention may further comprise a second crossing frame disposed across a pair of side frames arranged in parallel.

The present invention can adjust the rotation angle of the second solar power generation panel by means of a pivotable angle adjustment bar on the front of the second intersection frame.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

According to the present invention as described above, the present invention is designed in such a structure that a plurality of photovoltaic panels are rotatably and foldably coupled to the outer surface of a module having a rectangular parallelepiped shape, and rainwater can be collected.

In particular, the unit module of the present invention has a structure that can be aligned in a line in a lateral direction. This can maximize the productivity, transportability and expandability as an industrial product, and can be formulated to improve efficiency in construction and maintenance work.

The present invention provides an accessibility to safely supply in an area where the water supply is not smooth and a convenience to directly manage the rainwater, and is structurally simple as compared with other water supply systems.

In addition, the present invention is designed to collect rainwater in the air and can store clean rainwater that is not in contact with nonpoint sources.

FIG. 1 is a perspective view of a solar module and a rainwater collecting tank integrated unit module according to a preferred embodiment of the present invention.
FIG. 2 is a perspective view of a solar power generator and a rainwater collecting tank integrated unit module according to a preferred embodiment of the present invention, as seen from below.
FIG. 3 is a perspective view of solar power generation and rainwater collecting tank integrated unit modules according to another preferred embodiment of the present invention.
4 is a perspective view schematically showing an integrated unit module of a solar power generator and a rainwater collecting tank in which a solar power generation panel is folded.
Fig. 5 is a schematic view showing a unit module with the solar power generation panel removed. Fig. 5 (a) is a perspective view of the water collecting tank viewed from one side, and Fig. 5 (b) is an exploded perspective view of the water collecting tank viewed from the other side.
6 is a diagram sequentially illustrating the rainwater collecting process of the unit module of the present invention when collecting rainwater.
FIG. 7 is a view showing an example in which the solar power generator and the rainwater collecting tank integrated unit module according to the present invention are extended.
FIG. 8 is a perspective view of another example in which an integrated unit module for solar power generation and rainwater collecting tanks according to the present invention is extended.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages and novel features of the invention will become more apparent from the following detailed description and examples taken in conjunction with the accompanying drawings. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. In this specification, the terms first, second, etc. are used to distinguish one element from another, and the element is not limited by the terms. In the accompanying drawings, some of the elements are exaggerated, omitted or schematically shown, and the size of each element does not entirely reflect the actual size.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 schematically show a solar power generation and rainwater collecting tank integrated unit module 1, and FIG. 4 schematically shows a unit module 1 according to the present invention in which a solar power generation panel is folded. Fig. 5 is a view showing a unit module in a state in which the solar power generation panel is removed.

As shown in the drawings, the unit module 1 according to the preferred embodiment of the present invention not only collects rainwater in the air before coming into contact with a non-point pollution source, Can be easily expanded or folded through the photovoltaic panels P1, P2, and P3, thereby assuring reliable power generation efficiency. Here, the unit module according to the present invention is formed by solar power generation panels (P1, P2, P3) and solar power generation panels (P1, P2, P3) Electric wiring connecting a battery used as a power supply source and a condenser and an inverter for converting a direct current into an AC is well known to those skilled in the art and is used for a clear understanding of the present invention A detailed description thereof is excluded.

A unit module 1 according to a preferred embodiment of the present invention includes a lower frame 10 having a lower caster C on its bottom and supporting a lower surface 100, An upper frame 20 which is arranged in parallel with an interval and supports the upper surface 200 and a lower frame 20 which is disposed between the front left corner of the lower frame 10 and the left front corner of the upper frame 20, The post 31 includes a right front post 32 disposed between a front edge right corner of the lower frame 10 and a front edge right corner of the upper frame 20, A left rear post 41 disposed between the rear end side right corner of the upper frame 20 and the rear end side right corner of the upper frame 20, And a right rear post 42 It comprises a rectangular shape.

As described above, the unit module 1 in the form of a rectangular parallelepiped according to the preferred embodiment of the present invention has the first solar power generation panel P1 arranged so as to be angularly adjustable from the front, 2 solar power generation panel P2 is disposed, and the third solar power generation panel P3 is disposed so as to be adjustable in angle from the rear.

Specifically, the first solar power generation panel P1 is divided into a front end side of the lower frame 10 and a front end side defined by the front end side of the upper frame 20, the left front post 31 and the right front post 32. [ And is rotatably coupled at a predetermined angle. The upper edge of the first solar power generation panel P1 is hinged to the front end side of the upper frame 20 while the side edge of the first solar power generation panel P1 and the pair of front posts 31, 32). The angle adjusting unit 50 includes a first connecting bar 510 and a second connecting bar 520. The connecting nut 530 connects the first connecting bar 510 and the second connecting bar 520 in a straight line, . The fixed end of the first connecting bar 510 is hinged to the side edge of the first solar power generation panel P1 while the free end of the first connecting bar 510 forms a male screw in one direction on the outer circumferential surface thereof. The fixed end of the second connecting bar 520 is hinged to the front posts 31 and 32 while the free end of the second connecting bar 520 forms a male screw thread on the outer circumferential surface of the second connecting bar 520 in the other direction. The connecting nut 530 includes a first nut portion 531 for screwing the first connecting bar 510 and the second connecting bar 520 to the free end of the first connecting bar 510 so that the first connecting bar 510 and the second connecting bar 520 can be linearly connected, A second nut portion 532 for screwing the free end of the second connection bar 520 and a support portion 533 for connecting the first nut portion 531 and the second nut portion 532 in a straight line. The angle adjusting portion 50 is contracted or elongated through manipulation of the connecting nut 530 that narrows or increases the spacing between the free end of the first connecting bar 510 and the free end of the second connecting bar 520, So that it is possible to expand while adjusting various rotation angles of the photovoltaic panel P1. For example, when separating the first connecting bar 510 and / or the second connecting bar 520 from the connecting nut 530 in the angle adjusting part 50, the unit module 1 of the present invention is arranged so that the first sunlight The power generation panel P1 can be folded on the front surface of the module.

The second solar power generation panel P2 is rotatably coupled to the upper surface 200 supported on the upper frame 20 at a predetermined angle. The present invention is characterized in that the lower edge of the second solar power generation panel P2 is hinged to the vicinity of the front end side of the upper frame 20 while the side edge of the second solar power generation panel P2 and the side surface of the upper frame 20 And an angle adjusting bar 50a is interposed between the frames 20a. The fixed end of the angle adjusting bar 50a is hinged at the side edge of the second solar power generation panel P2 while the free end of the angle adjusting bar 50a forms a hanging step (not shown). The free end of the angle adjusting bar 50a can be inserted into a plurality of engagement holes (not shown) formed along the side edge of the second solar power generation panel P2 in the longitudinal direction. Through this operation, the angle adjusting bar 50a can adjust the angle of the second solar power generation panel P2. When the free end of the angle adjusting bar 50a is separated from the retaining hole of the second solar power generation panel P2, the unit module 1 of the present invention is arranged so that the second solar power generation panel P2 is disposed on the upper surface It can be folded on.

The present invention is not limited to this and the second solar power generation panel P2 may be configured such that the angle adjusting portion 50 for adjusting the turning angle of the first and third solar power generation panels P1 and P3 is replaced with the angle adjusting bar 50a And may be a constituent member such as a hydraulic cylinder capable of elongating and / or contracting the bar length, a pneumatic cylinder and the like.

In order to allow the second solar photovoltaic panel P2 to be supported and held on the upper frame 20 without being interfered by the rotation of the first solar photovoltaic panel P1, And a first crossing frame 20b disposed across the side frames 20a. Preferably, the first crossing frame 20b is arranged adjacent to the front end side of the upper frame 20. Preferably, the lower edge of the second solar power generation panel P2 may be hinged to the first crossing frame 20b.

In order to ensure the horizontality of the second solar power generation panel P2 when the second solar power generation panel P2 is folded on the top surface 200 as shown in Fig. 4, the side frames 20a And a second crossing frame 20c disposed across the first crossing frame 20c. The second crossover frame 20c is arranged in parallel with the first crossover frame 20b as shown, and is disposed adjacent to the rear end side of the upper frame. Preferably, the thickness of the second crossing frame 20c is the same as the thickness of the first crossing frame 20b, thereby helping to flatten the second photovoltaic panel P2. Further, the fixed end of the angle adjusting bar 50a is hinged to the side frame 20a in front of the second crossing frame 20b.

Similarly to the first solar power generation panel P1, the third solar power generation panel P3 includes the rear end side of the lower frame 10, the rear end side of the upper frame 20, the left rear post 41, And is rotatably coupled at a predetermined angle on the rear surface defined by the right rear post 42. The present invention is characterized in that the lower edge of the third solar power generation panel P3 is hinged to the rear end side of the upper frame 20 while the side edge of the third solar power generation panel P3 is joined to a pair of rear posts 41 And 42, respectively. The angle adjusting unit 50 includes a first connecting bar 510 and a second connecting bar 520. The connecting nut 530 connects the first connecting bar 510 and the second connecting bar 520 in a straight line, . The fixed end of the first connecting bar 510 is hinged to the side edge of the third solar power generation panel P3 while the free end of the first connecting bar 510 forms a male screw in one direction on the outer circumferential surface thereof. The fixed end of the second connecting bar 520 is hinged to the rear posts 41 and 42 while the free end of the second connecting bar 520 forms a male screw thread on the outer circumferential surface of the second connecting bar 520 in the other direction. The connection nut 530 includes a first nut portion 531 for assisting the free end of the first connection bar 510 and a screw connection and a second nut portion 532 for facilitating the screwing of the free end of the second connection bar 520, And a support portion 533 that connects the first nut portion 531 and the second nut portion 532 in a straight line and has a free end of the first connecting bar 510 and a free end of the second connecting bar 520, The rotation angle of the third solar power generation panel P3 can be adjusted by the operation of the connection nut 530 that narrows or increases the spacing between the first solar power generation panel P3 and the second solar power generation panel P3. For example, when the first connecting bar 510 and / or the second connecting bar 520 are separated from the connecting nut 530 in the angle adjusting portion 50, the unit module 1 of the present invention is configured such that the third sunlight The power generation panel P3 can be folded on the rear surface of the module

As described above, the unit module 1 according to the present invention can be mounted on the solar power generation panels P1, P2, and P3 by means of the angle adjusting portion 50 and / or the angle adjusting bar 50a, P3), as well as to expand the solar power generation panels (P1, P2, P3) so as to be able to generate electricity or to prevent damage due to the wind pressure transferred to the solar power generation panels It is possible to overlap the module with the outer surface of the module in a folded state so as to provide convenience.

The unit module 1 according to the preferred embodiment of the present invention includes a lower surface 100 of the lower frame 10, an upper surface 200 of the upper frame 20, a pair of front posts 31 and 32 And a pair of rear posts 41 and 42. The water collecting tank 60 stores rainwater.

Particularly, the present invention can collect rainwater in the air before the rain reaches the surface of the earth through the second solar power generation panel P2, the third solar power generation panel P3 and / or the upper surface 200. The method of collecting and collecting the rainwater on the surface of the earth is a method of collecting rainwater through the rainwater into the water system together with various pollutants settled in the forests, grasslands, construction sites, agricultural lands, river sediments, roads and industrial sites and contains a large amount of non- It is possible to use the water as the water only after a separate process. In contrast, the present invention adopts a method of collecting rainwater directly in the air and collecting it in the catchment tank 60 before coming into contact with the nonpoint source as described above.

The water collecting tank 60 may have an inlet 610 at the rear surface thereof, an outlet 620 disposed at the front of the water collecting tank, and a pair of drain valves 630 disposed at the bottom or rear of the collecting tank .

The inlet 610 is a component that can remove part of the nonpoint source by guiding the rainwater collected on the upper surface 200 into the catchment tank 60. 2 and 6, the inflow section 610 includes a vertical tube 611, an inflow tube 612 disposed on the upper side of the vertical tube 611 and communicating with the collecting tank 60, A floating body 613 rising from the inside to the water surface, and a drain valve 614 for opening and closing the lower portion of the vertical tube 611.

The rainwater flows along the inclined surface of the second solar power generation panel P2 to be collected on the upper surface 220 and passed through the upper penetration portion of the vertical tube 611 in fluid communication with the through hole 210, (See Fig. 6 (a)). The upper surface 200 may be in the form of a panel that is inclined downward toward the through hole 210 so that the rainwater can be gathered easily by the inlet portion 610. At this time, the lower end of the vertical tube (611) is closed by the drain valve (614). When rainwater enters the vertical tube 611, the floating body 613 floats on the surface of the rainwater. The floating body 613 floats to the ring-shaped sealing portion 611a disposed on the inner peripheral surface of the vertical tube 611. The floating body 613 contacts the ring-shaped sealing portion 611a, The flow of rainwater is blocked. The rainwater can flow into the catch tank 60 through the inflow pipe 612 branched from the vertical pipe 611 toward the catch tank 60 and stored therein (see FIG. 6 (b)). For this purpose, it is preferable that the inflow portion 610 is disposed at a position higher than the sealing portion 611a. The present invention does not directly guide the first rainwater guided to the inflow section 610 to the catchment tank 60. This allows the non-point source such as dust or the like, which has been swept down by the first rainwater, to be collected at the end of the vertical pipe 611, thereby minimizing the inflow of the non-point source into the collecting tank.

If no further inflow of rainwater into the catchment tank 60 is possible, for example, when the rain stops or the rainwater in the catchment tank 60 is completely filled, the user opens the drainage valve 614 of the passive pipe 611, So that the rainwater containing the non-point pollutant filled in the pipe end can be discharged to the external water system (see Fig. 6 (c)). The floating body 613 is spaced apart from the sealing portion 611a while the rainwater that has been filled in the tube end of the vertical tube is discharged into the external water system.

The penetration of the vertical tube 611 may further include a stopper 615. [ The cap 615 may be a pattern for filtering foreign matter such as leaves, paper and the like into the penetration portion of the vertical tube 611 through the through hole 210 of the upper surface 200.

As shown, the catchment tank (60) has a pair of valves (630) arranged at the bottom of the rear side. The pair of valves 630 may be disposed at the bottom of the collecting tank 60 so as not to overlap with the outflow portion 620 arranged in the horizontal direction. However, the pair of valves 630 are not disposed on the left and right sides in consideration of the characteristics of the unit modules extended to left and right sides.

Here, the pair of valves 630 may discharge sediment that has settled in the lower part of the collecting tank 60 to the external water system. 7, when a plurality of unit modules are extended to the right and left sides as shown in FIG. 7, the plurality of unit modules are connected to the one-way valve 630 of the unit module 1 through the connection hose H The other valves 630 of the unit module 1 may be interconnected to supply the rainwater stored in the unit module 1 to the collecting tank of the other unit module 1. [

In addition, the water collecting tank (60) has an outlet (620) arranged at a predetermined height on the front surface. The outflow section 620 includes at least one outflow pipe 621 for discharging the rainwater stored in the water collecting tank 60 and a water pipe extending in the width direction of the water collecting tank 60 so as to be in fluid communication with the rear end of the outflow pipe 621 As shown in Fig. The at least one outlet pipe (621) is arranged at the same height. The guide pipe 622 has a length that is not greater than the width of the catchment tank 60. As described above, the outflow pipe 621 of the outflow portion 620 is disposed at a predetermined height from the lower portion of the catch tank 60 to prevent the sediment that has settled in the lower portion of the catch tank when the rainwater is discharged, There will be. The guide pipe 622 is provided with a water receiver 623 to discharge the rainwater stored in the water collecting tank 60 provided in each unit module 1 to the outside to facilitate easy use as domestic water.

Both ends of the guide pipe 622 may further include a connector 624 so as to be connected to the guide pipes 622 of the other unit modules arranged adjacently to the left and right.

The water collecting tank (60) places the overflow pipe (640), which can naturally drain when the water level of the rainwater to be stored in the water collecting tank reaches a certain level, in the upper part of the collecting tank. In addition, the collecting tank 60 is provided with a cover 65 on its upper surface, which can seal an opening (not shown) allowing the flow into and out of the collecting tank. The water collecting tank (60) allows the inside of the water collecting tank to be cleaned through the opening described above.

FIG. 7 is a view showing an example in which the solar power generator and the rainwater collecting tank integrated unit module according to the present invention are extended.

The unit module 1 according to the preferred embodiment of the present invention is designed to be installed on left and right side surfaces without mounting the solar power generation panels P1, P2, and P3. In order to fix a plurality of unit modules 1, the present invention has a coupling ring 91 rotatable at the lower ends of the left front post 31 and the left rear post 41, while correspondingly, And an engagement pin 92 protruding from the lower end of the right rear post 42 and the right rear post 32.

The left front post 31 and the left rear post 41 of the unit module 1 are arranged in the right rear post 32 and the right rear post 32 of the other unit module 1, And is disposed adjacent to the post 42. The engaging hooks 91 disposed on the left front post 31 and the left rear post 41 are rotated to be disposed adjacent to the engaging pins 92 provided on the right front post 32 and the right rear post 42 So that the unit modules can be closely fixed to each other.

In particular, the unit module 1 according to the present invention can be connected to the adjacent unit module 1 in fluid communication with the adjacent unit hose H through the connection hose H, as shown in the figure, to increase the storage capacity. However, in the present invention, the individual unit modules are arranged in a line so as to be in fluid communication with each other, so that the amount of water stored in each of the water collecting tanks It is possible to improve the durability of the unit module by remarkably reducing the water pressure applied to each unit module.

FIG. 8 is a perspective view of another example in which an integrated unit module of a solar power generator and a storm water collecting tank according to the present invention is extended, wherein a plurality of unit modules are aligned in a lateral direction, It should be noted in advance that the first photovoltaic power generation panel was partially cut out for confirmation.

The present invention is characterized in that the rainwater discharged from each of the catchment tanks placed in the plurality of unit modules 1 is piped straight through the plurality of guide pipes 622 at both ends and connected to a rear end facility Can supply rainwater.

As shown in the drawing, the present invention can be applied to the unit module 1 with the faucet 623 of the outlet 620 so that the rainwater stored in the storage tanks of the plurality of unit modules 1 arranged in a row in the left- Water can be supplied quickly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be apparent to those skilled in the art that modifications and improvements can be made thereto by those skilled in the art.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1 ----- unit module,
10 ----- Lower frame,
20 ----- upper frame,
31, 32, 41, 42 ----- post,
50 ----- angle adjusting portion,
60 ----- collecting tank,
P1, P2, P3 ----- Solar power generation panel.

Claims (8)

A lower frame 10 supporting the lower surface 100 and an upper frame 20 supporting the upper surface 200. The upper frame 20 is disposed between the lower frame 10 and each corner of the upper frame 20 In the unit module in the form of a rectangular parallelepiped consisting of the posts (31, 32, 41, 42)
A first solar power generation panel P1 rotatably coupled to the front surface of the unit module 1 at a predetermined angle;
A second solar photovoltaic panel (P2) rotatably coupled on an upper surface of the unit module (1) at a predetermined angle;
A third solar photovoltaic panel P3 rotatably coupled to the rear surface of the unit module 1 at a predetermined angle; And
And a collecting tank (60) interposed between the lower surface (100) and the upper surface (200) and collecting rainwater through the through hole (210) of the upper surface (200) Photovoltaic and storm water collecting tank integrated unit module.
The method according to claim 1,
The water collecting tank (60)
A vertical pipe 611 disposed on the rear surface of the water collecting tank and having a ring-shaped sealing portion 611a around the inner circumferential surface thereof, the upper penetrating portion being coupled to the through hole 210, A floating body 613 which floats on the water surface of the rainwater inside the water pipe 611 and closes the sealing part 611a inside the water pipe 611 and a water pipe 611 which is branched from the water pipe 611, An inlet 610 having a drain valve 614 for opening and closing a lower end of the pipe;
A guide pipe (621) extending in the width direction of the water collecting tank (60) so as to be in fluid communication with a rear end of the at least one outflow pipe (621) 622), and an outlet (620) having a connector (624) for piping to both ends of the guide tube (622); And
And a pair of valves (630) disposed at a lower portion of the collecting tank.
The method according to claim 1,
Wherein the first solar power generation panel (P1) and the third solar power generation panel (P3) are angularly adjusted on the front surface or the rear surface by means of an angle adjuster (50).
The method of claim 3,
The angle adjusting unit 50 includes a first connecting bar 510 hinged at a side edge of the solar power generating panel and a second connecting bar 520 hinged at the posts 31, And a connecting nut (530) for connecting the first connecting bar (510) and the second connecting bar (520) in a straight line.
The method of claim 4,
The fixed end of the first connecting bar 510 is hinged to the side edge of the solar power generation panels P1 and P3 and the free end of the first connecting bar 510 forms a male screw mountain in one direction In addition,
The fixed end of the second connecting bar 520 is hinged to the posts 31, 32, 41 and 42, and the free end of the second connecting bar 520 forms a male screw thread on the outer circumferential surface in the other direction ,
The connecting nut 530 includes a first nut portion 531 screwed to the free end of the first connecting bar 510 and a second nut portion 532 screwed to the free end of the second connecting bar 520 , And a support portion (533) for connecting the first nut portion (531) and the second nut portion (532) in a straight line.
The method according to claim 1,
The upper frame 20 includes a first crossing frame 20b disposed across a pair of side frames 20a arranged in parallel and adjacent to a front end side of the upper frame 20,
And the second solar power generation panel (P2) is hinged to the first intersection frame (20b).
The method of claim 6,
Characterized in that the upper frame (20) further comprises a second cross frame (20c) arranged across a pair of side frames (20a) arranged in parallel.
The method of claim 7,
And the angle of rotation of the second solar power generation panel (P2) is adjusted by means of an angle adjusting bar (50a) in front of the second intersection frame (20c).

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