KR102526737B1 - Solar photovoltaic panel louver system - Google Patents

Abstract

According to the present invention, a solar photovoltaic panel louver system comprises: a frame which includes a support frame unit, and a movement frame unit provided within the support frame unit; solar photovoltaic blades which are disposed at a set interval in the movement frame unit, are provided with a solar photovoltaic panel for solar photovoltaic generation, and are rotated at a predetermined angle, respectively; linkage modules which are provided on left and right facing surfaces of the movement frame unit, respectively, to link both ends of the solar photovoltaic blades; and a rotation angle adjustment module which is provided at an upper side of the movement frame unit to adjust the rotation angles of the blades through one linkage module at the same time. According to the present invention, unlike an existing system in which only blades are angle-adjustable, the movement frame unit, in which each of the separately disposed solar photovoltaic blades is provided to be rotatable at a predetermined angle, is fixed or rotated in the support frame unit, so that the angle of the solar photovoltaic blades or the movement frame unit can be adjusted according to an angle of sunlight so as to enable efficient solar photovoltaic generation even when the angle of the sunlight on lower or higher floors of an apartment building is different. In addition, the present invention has the support frame unit fixed to a wall, and has the movement frame unit, in which solar photovoltaic blades are installed, coupled into the support frame unit by an insertion method, so it is possible to facilitate the maintenance of the solar photovoltaic blades even when a cable line extends to the solar photovoltaic panel for solar photovoltaic generation, and external factors such as water and moisture outdoors cause disconnection or short circuit to require maintenance.

Description

Solar panel louver system {SOLAR PHOTOVOLTAIC PANEL LOUVER SYSTEM}

The present invention relates to a solar panel louver system, and more particularly, to a solar panel louver system installed in a ventilation window of each building to enable solar power generation with a function of opening and closing external air.

In general, louver-type windows are often used in ventilation windows. These ventilation windows are installed for the purpose of ventilation, such as an outdoor air conditioner room provided on a veranda of a commercial building in an apartment building or a residential-commercial complex, or a machine room on a rooftop of an apartment building.

Recently, louvered windows equipped with photovoltaic power generation modules are installed in the louvers of louvered windows, and the louvers can be operated using electricity generated from each photovoltaic power generation module or used at home. is being initiated

In this way, a technology related to a photovoltaic module louver has been proposed in Korean Patent Registration No. 1853189.

However, Patent Document 1 has a limitation in adjusting the angle of the photovoltaic module louver, and when maintenance of the photovoltaic module louver is required, the entire frame must be separated, so there is a problem in that a lot of work time is required.

Korean Patent Registration No. 1853189 (2018.04.23)

The present invention has been devised in view of the above points, and the problem of the present invention is to provide a support frame and a movable frame in a double structure, and to rotate the entire solar blade by the individual angle of the solar blade and the rotation of the movable frame. An object of the present invention is to provide a solar panel louver system in which an angle is adjusted and a movable frame equipped with solar blades can be separated from a support frame.

A solar panel louver system according to the present invention for achieving the above object includes a frame including a support frame unit and a movable frame unit provided inside the support frame unit; solar blades disposed within the moving frame unit at set intervals, provided with solar panels for photovoltaic power generation, and each rotated at a predetermined angle; Interlocking modules provided on the left and right opposite surfaces of the moving frame unit to interlock both ends of the solar blades; and a rotation angle adjusting module provided on the upper side of the movable frame unit to simultaneously adjust rotation angles of the blades through an interlocking module on one side.

The movable frame unit may be fixedly or rotatably provided in the support frame unit.

The movable frame part may be provided with a fixing part fixed to or separated from the support frame part while contacting or spaced apart from the inner wall surface of the short side opposite to the support frame part at the short side.

The movable frame unit may be rotated based on a transverse axis provided at a center of a long side of the movable frame unit and the support frame unit.

The solar blade includes a blade frame having fixing grooves formed on one surface to fix the solar panel, protrusions formed at opposite positions to each other, and shafts extending from both ends of the lower surface of the solar panel exposed; and a frame cover inserted at both ends of the blade frame so that the axis passes through the center.

The interlocking module may include: a first connection unit that moves in one of the left and right directions according to the rotation direction of the rotation angle adjusting module; Rotating parts to which central parts are respectively coupled to each of the shaft parts on both sides of the solar blade; and a second connection unit that is interlocked by the rotation unit when the first connection unit moves by connecting the eccentric one end and the other end of the rotation unit to each other.

The rotational angle adjusting module has an end coupled to a moving slit hole formed in a direction orthogonal to the moving direction of the first connecting portion of the interlocking module to move the first connecting portion according to the rotational direction, and an angle adjusting protrusion is formed on one side of the upper portion. rotational force providing unit; an angle adjusting unit seated on an upper portion of the rotational force providing unit and having a radial angle adjusting groove formed at a lower portion such that the angle adjusting protrusion is bound to one of the angle adjusting grooves; an angle adjusting lever located on the upper side of the moving frame unit to rotate the rotational force providing unit; and an elastic unit positioned between the angle adjusting unit and the angle adjusting lever and providing elastic force to bring the upper portion of the rotational force providing unit into close contact with the lower portion of the angle adjusting unit.

The photovoltaic blades located at both ends of the photovoltaic blades may be rotated or non-rotated while the ends are inserted into the inner wall surface of the moving frame unit.

According to the present invention, unlike the conventional case in which only the blades are angle-adjustable, since the moving frame unit provided so that each of the divided solar blades can be rotated at a predetermined angle is provided inside the support frame unit to be fixed or rotatable, according to the angle of sunlight The angle of the solar blade or moving frame can be adjusted, enabling efficient photovoltaic power generation even if the angle of receiving sunlight is different from the lower or upper floors in an apartment, etc., and the support frame is fixed to the wall and the solar blade is installed in the support frame. Since the moving frame part is combined by an insert method, as the cable line is extended to the solar panel for photovoltaic power generation, it is easy to maintain the solar blade even if maintenance is required due to disconnection or short circuit due to external factors such as water or moisture outdoors. has an easy effect.

1 is a perspective view showing a state in which a solar blade and a moving frame unit are not rotated in a solar panel louver system according to a first embodiment of the present invention.
2 is a perspective view showing a state in which the solar blade is rotated and the moving frame unit is not rotated in the solar panel louver system according to the first embodiment of the present invention.
FIG. 3 is a perspective view illustrating a rotated state of a solar blade and a moving frame unit in a solar panel louver system according to a first embodiment of the present invention.
4 is a perspective view illustrating a moving frame unit provided in a state in which a solar blade is rotated in a solar panel louver system according to a first embodiment of the present invention.
5 is a perspective view showing a state in which a fixing part is provided to a second short side frame in the solar panel louver system according to the first embodiment of the present invention.
6 is a cross-sectional view showing a state in which a fixing part is provided in a second short frame in the solar panel louver system according to the first embodiment of the present invention.
7 is a cross-sectional view showing a state in which only outer solar blades among solar blades are non-rotated and a state in which all solar blades are rotated in the solar panel louver system according to the first embodiment of the present invention.
8 is a perspective view showing an interlocking module and a rotation angle adjusting module in the solar panel louver system according to the first embodiment of the present invention.
9 is a perspective view showing a state in which a rotation angle adjusting module is connected to a first connection part of an interlocking module in the solar panel louver system according to the first embodiment of the present invention.
10 is an exploded perspective view showing an interlocking module and a rotation angle adjusting module in the solar panel louver system according to the first embodiment of the present invention.
11 is an exploded perspective view showing a rotation angle adjusting module in the solar panel louver system according to the first embodiment of the present invention.
12 is an exploded perspective view showing an interlocking module in the solar panel louver system according to the first embodiment of the present invention.
13 is an exploded perspective view partially showing a solar blade in the solar panel louver system according to the first embodiment of the present invention.
14 is a perspective view showing a state in which the movable frame part is separated from the support frame part in the solar panel louver system according to the second embodiment of the present invention.
15 is a perspective view showing a movable frame part separated from the support frame part in the solar panel louver system according to the second embodiment of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a solar panel louver system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 13, the solar panel louver system 10 according to the first embodiment of the present invention includes a frame 100, a solar blade 200, an interlocking module 300, and a rotation angle adjusting module ( 400), and is installed upright on ventilation windows of each building to enable solar power generation along with ventilation.

The frame 100 is connected in a frame structure as shown in FIGS. 1 to 4 and includes a support frame unit 110 and a moving frame unit 120 .

The support frame unit 110 is connected in a square frame structure in an extruded state and fixed to a wall, etc., and the first long side frame 112 is parallel and the first side is connected in parallel to the end facing surface of the first long side frame 112. A short side frame 114 is included.

At this time, the shaft portion 116 is connected in the transverse direction to the center of the first long side frames 112 and the center of the second long side frames 122 adjacent thereto, so that the moving frame portion 120 rotates with the shaft portion 116 as the starting point. do.

The moving frame unit 120 is extruded in a square frame structure so as to be located inside the support frame unit 110, and is parallel to the second long side frame 122 and the end facing surface of the second long side frame 122. It includes a second short side frame 124 connected thereto.

Furthermore, as shown in FIGS. 5 and 6 , the second short frame 124 is provided with fixing parts 126 on both upper and lower sides, respectively, on the inner wall surface of the first short frame 114 of the support frame 110. The moving frame part 120 is rotated or fixed to the support frame part 110 while being in contact with or separated from each other.

That is, the fixing part 126 is located at each of four upper and lower points on both sides of the second short-side frame 124 on one side and the other side, so that the end moves in the direction of the first short-side frame 114 .

At this time, the fixing part 126 includes a nut 126a and a spiral shaft 126b. The nut 126a is positioned and fixed in the fixing groove 1240 provided in a direction corresponding to the longitudinal direction of the second long-side frame 122 on the top and bottom of the front surface of the second short-side frame 124 .

The spiral shaft 126b is provided in a direction corresponding to the longitudinal direction of the second long side frame 122, one end of which is spirally fastened to the nut 126a, and a tool insertion groove formed at the other end of the second short side frame 124. It is exposed through the hole H formed up and down, and when a tool such as an L wrench is inserted into the hole H and rotated, one end penetrates the nut 126a and the penetrating end moves up and down the rear surface of the first short frame 114. will be pressurized

In addition, holes are formed on the inner wall surface of the second short frame 124 at positions corresponding to the spiral shaft 116b, and the moving frame unit 120 is supported when one end is located inside the hole while the spiral shaft 116b is fastened. It is prevented from rotating in the frame part 110 .

At this time, although not shown in the drawing, the first short frame 114 has an angle around the shaft portion 116 so that the coupling position of the spiral shaft 126b can be adjusted to adjust the rotational angle of the moving frame portion 120. It can be formed in multiple so that it is different.

In addition, although not shown in the drawing, the movable frame unit 120 can have a hole through which the shaft unit 116 passes in a “-” or “+” shape of the second long-side frame 122, so that the frame unit 110 has a straight line. It can move in either direction or cross direction.

As shown in FIGS. 1 to 7 and 13 , the solar blades 200 are disposed within the moving frame unit 120 at set intervals and each rotates at a predetermined angle, and the blade frame 210, the solar panel ( 220) and frame cover 230.

At this time, the solar blade 200 is provided in a fixed manner without being rotated at both ends of the center and the second short-side frame 124 side of the second long-side frame 122 of the moving frame unit 120, and when provided in a fixed manner, the solar blade 200 The light panel 220 is not installed.

In particular, when the solar blade 200 is fixedly provided at both ends of the second short-side frame 124 (see FIG. 7(a) ), a groove is formed on the inner wall surface of the second short-side frame 124, and the ends are in the groove. When the solar blades 200 are provided in a non-fixed manner at both ends of the second short-side frame 124 (see FIG. 7(b)), the ends are spaced apart from the inner wall surface of the second short-side frame 124.

The blade frame 210 is formed by extrusion, and a fixing groove 212 is formed on one surface so that the solar panel 220 is fixed, and jaws 214 at opposite positions are formed at the front and rear ends.

At this time, the jaw 214 prevents the blade frame 210 from rotating any further while the jaw 214 of the adjacent blade frame 210 contacts.

Moreover, the blade frame 210 is applied to a synthetic resin including acrylic or PC (polycarbonate), etc., and is not limited thereto, and any transparent material can be applied.

The solar panel 220 is coupled to the fixing groove 212 of the blade frame 210 and is provided for solar power generation, and the shaft 240 extends from the center of both sides of the bottom surface to the rotation origin of the blade frame 210, respectively. do.

Meanwhile, the shaft 240 may have a polygonal structure although not shown, and in this case, the through hole 312 of the rotation unit 310 may also have a corresponding shape.

The frame cover 230 has coupling protrusions 236 formed on opposite surfaces so as to be inserted at both ends of the blade frame 210, and protrusions 232 at opposite positions to extend from the protrusions 214 of the blade frame 210. is formed, and the extension shaft 234 extends so that the shaft 240 passes through the center and the shaft 240 passes through.

At this time, the extension shaft 234 has inclined protrusions 2340 formed on opposite sides, and when coupled to the through hole 312 of the rotating part 310, the protrusion 2340 is caught in the through hole 312 and the rotating part 310 prevent the departure of

As shown in FIGS. 4 and 8 to 12, the interlocking module 300 is provided on the outer wall surface of the second long side frame 122 of the moving frame unit 120 to interlock both ends of the blade frames 210, When the rotation angle adjusting module 400 provided on the second long side frame 122 on one side is operated, one side and the other side provided on the second long side frame 122 on the other side are interlocked.

Here, the interlocking module 300 includes a rotation unit 310, a first connection unit 320, a second connection unit 330, and a third connection unit 340.

The rotation part 310 is formed in an elliptical shape, and the through hole 312 is inserted so that the extension shaft 234 of the frame cover 230 through which the shafts 240 provided at the center of both sides of the lower surface of the solar panel 220 pass. It is formed at the center and includes an eccentric shaft 314 vertically eccentric in the through hole 312.

The first connection part 320 is connected in the horizontal direction to the upper eccentric shaft 314 of the rotation parts 310 of the solar blades 200 positioned adjacent to the center side of the second long side frame 122 to form a rotation part 310 is rotated in either direction from the left or right with the through hole 312 as a starting point.

At this time, both ends of the first connection part 320 are rotatably fixed to the upper eccentric shaft 314 of the adjacent rotation part 310, respectively, and the moving slit hole 322 in a direction orthogonal to the moving direction of the first connection part 320. ) is formed.

The movable slit hole 322 rotates in one direction of the rotational force providing unit 410 in a state in which the eccentric shaft 412 provided in the rotational force providing unit 410 of the rotation angle adjusting module 400 is coupled to the eccentric shaft 412 While moving to one end, the first connection part 320 is moved to the right direction, and when the rotational force providing part 410 rotates in the other direction, the eccentric shaft 412 moves to one end while moving the first connection part 320 to the left direction. let it be

The second connection part 330 connects the eccentric upper and lower eccentric shafts 314 of the remaining rotation parts 310 to which the first connection part 320 is not connected in the transverse direction, respectively, so that when the first connection part 320 moves, the rotation part 310 ) is uniformly interlocked by

The third connection part 340 connects the shaft 240 of the solar panel 220 passing through the passage hole 312 of the rotating part 310 to each other.

As shown in FIGS. 1, 2, 4, and 8 to 11, the rotation angle adjusting module 400 is both upper ends of the second long side frame 122 of the moving frame unit 120, which is both sides of the shaft unit 116. It is provided in each side to simultaneously adjust the rotational angle of the blades 200 through the interlocking module 300 on one side, and the rotational force providing unit 410, the angle adjusting unit 420, the angle adjusting lever 430 and the elastic unit 440 includes

The rotational force providing unit 410 is coupled with an eccentric shaft 412 extending from an end to a moving slit hole 322 formed in a direction orthogonal to the moving direction in the first connection unit 320 of the interlocking module 300, In the process of moving the eccentric shaft 412 from one side of the movable slit hole 322 to the other side, the movable slit hole 322 is pressed to move the first connection part 320, and the angle adjusting protrusion 414 on one side of the upper part is formed

That is, the rotational force providing unit 410 converts the rotational motion of the eccentric shaft 412 into a linear reciprocating motion in the moving slit hole 322 during rotation to move the first connection unit 320 .

In addition, the rotational force providing unit 410 has a radial coupling groove 4100 formed thereon, and is coupled to a radial coupling protrusion 432 formed at a lower portion of the angle adjustment lever 430 to interlock with the angle adjustment lever 430. .

At this time, the rotational force providing unit 410 is rotatably fixed to the inner wall of the second long side frame 122 by the fixing bracket 416 .

The angle adjusting unit 420 is positioned inside the second long side frame 122, which is an upper part of the rotating force providing unit 410, and a radial angle adjusting groove 422 is formed at the lower portion of the rotating force providing unit 410. The angle adjusting protrusion 414 is provided to be coupled to any one of the angle adjusting grooves 422 .

The angle adjusting lever 430 is located at both upper ends of the second long side frame 122 to rotate the rotational force providing unit 410, and is fixed on the rotational force providing unit 410 by screws.

The elastic part 440 is located between the angle adjusting part 420 and the angle adjusting lever 430 and provides elastic force so that the upper part of the rotational force providing part 410 is brought into close contact with the lower part of the angle adjusting part 420 . In this way, the elastic part 440 prevents the angle adjusting protrusion 414 of the rotational force providing unit 410 from being separated from the angle adjusting groove 422 of the angle adjusting unit 420, and prevents rotation of the rotational force providing unit 410. Even if the angle adjusting protrusion 414 is separated from the angle adjusting groove 422 by pulling the rotational force providing unit 410 toward the angle adjusting portion 420, it can be coupled to the next angle adjusting groove 422.

On the other hand, the rotation angle control module 400 is illustrated as being operated manually, but is not limited thereto and may be operated automatically. That is, although not shown in the drawing, when the blade frame 210 is made of a material such as aluminum having excellent thermal conductivity, a drive motor is provided instead of the angle control lever 430 and the temperature on the back surface of the angle control lever 430 located in the room It is possible to adjust the rotation angle of the solar blade 200 by controlling the number of rotations of the drive motor according to the indoor temperature by being provided with a sensor.

In this way, the operation process of the solar panel louver system 10 according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 13 as follows.

First, when the solar blade 200 is rotated for ventilation or photovoltaic power generation, when the user rotates the angle control lever 430 of the rotation angle control module 400 while holding it, the angle control lever 430 When the angle adjusting protrusion 414 is separated from the angle adjusting groove 422 of the angle adjusting unit 420 and positioned in the adjacent angle adjusting groove 422 while the rotational force providing unit 410 is interlocked by ), the elastic part 440 As the angle adjusting protrusion 414 is coupled to the angle adjusting groove 422 by the restoring force of ), the angle adjusting lever 430 is rotated by the minimum angle between the angle adjusting groove 422 and the angle adjusting groove 422.

And, when the rotating force providing unit 410 rotates in one direction, the eccentric shaft 412 pressurizes the moving slit hole 322 while being positioned in the moving slit hole 322 of the first connection part 320, and the first connection part 320 moves in one direction.

In addition, while the first connection part 320 moves in one direction, the rotation part 310 connected to both ends of the first connection part 320 rotates in the same direction, and the other rotation part 310 is also interlocked by the second connection part 330 to rotate both sides of the rotation part. The solar blade 200 supported on 310 rotates uniformly.

Next, when the moving frame unit 120 supported by the solar blades 200 is rotated in the support frame unit 110 to improve the efficiency of photovoltaic power generation, the rear surface of the second short side frame 124 is top and bottom. When the tool is rotated in a state in which the tool is coupled to the tool insertion groove of the spiral shaft 126b through the formed hole H, the tip of the spiral shaft 126b interferes with the first short frame 114 and then the nut 126a While retracting from ), it is spaced apart from the rear surface of the first short frame 114.

In addition, as the front end of the spiral shaft 126b pressing the rear surface of the first short frame 114 retreats, the moving frame unit 120 in a fixed state moves within the support frame unit 110 starting from the shaft unit 116. rotated

Next, when it is desired to separate the movable frame unit 120 from the support frame unit 110 for maintenance of the solar panel 220, etc., the holes H formed on the upper and lower sides of the rear surface of the second short frame 124 When the tool is rotated while the tool is coupled to the tool insertion groove of the helical shaft 126b, the tip of the helical shaft 126b interferes with the first short frame 114 and retreats from the nut 126a to first It is spaced apart from the rear side of the short frame 114 .

In addition, the moving frame part 120 is separated from the support frame part 110 by separating the shaft parts 116 respectively connected in the transverse direction to the center of the first long side frames 112 and the center of the second long side frames 122 adjacent thereto. make it separate

14 and 15, the solar panel louver system 10' according to the second embodiment of the present invention includes a frame 100, a solar blade 200, an interlocking module 300, and a rotation angle adjusting module. 400, and since the solar blade 200, the interlocking module 300, and the rotation angle adjusting module 400 have the same structure and function as those of the previous embodiment, a detailed description thereof will be omitted.

On the other hand, in the solar panel louver system 10' according to the second embodiment of the present invention, the frame 100 allows the moving frame unit 120 to rotate from the support frame unit 110 to the shaft unit 116 as a starting point. Unlike the previous embodiment provided, the movable frame unit 120 is different in that it can be coupled to or separated from the support frame unit 110 without being rotated.

To this end, a jaw 1140 is provided on the lower side of the inner wall of the first short-side frame 114 of the support frame 110 so that the second long-side frame 122 of the moving frame 120 is seated and not rotated. As a result, the fixing part 126 in a state where the second long-side frame 122 of the moving frame part 120 is seated on the ledge 1140 provided on the lower side of the inner wall surface of the first short-side frame 114 of the support frame part 110. ), and when maintenance is required, the moving frame unit 120 is separated from the support frame unit 110 in a state in which the fixing unit 126 is spaced apart.

The configurations included in the various embodiments described above may also be implemented in other possible embodiments of various modified combinations not described exemplarily above, unless they are clearly excluded from each other in terms of implementation.

10, 10': solar panel louver system 100: frame
110: support frame part 120: moving frame part
200: solar blade 210: blade frame
220: solar panel 230: frame cover
300: interlocking module 310: rotating part
320: first connection part 330: second connection part
340: third connection part 400: rotation angle adjustment module
410: rotational force providing unit 420: angle adjusting unit
430: angle control lever 440: elastic part

Claims (8)

A frame including a support frame unit and a movable frame unit provided inside the support frame unit;
solar blades disposed within the moving frame unit at set intervals, provided with solar panels for photovoltaic power generation, and each rotated at a predetermined angle;
Interlocking modules provided on the left and right opposite surfaces of the moving frame unit to interlock both ends of the solar blades; and
A rotation angle adjustment module provided on the upper side of the moving frame unit to simultaneously adjust the rotation angles of the blades through an interlocking module on one side; includes,
The rotation angle adjustment module
An end portion coupled to a moving slit hole formed in a direction orthogonal to the moving direction of the first connecting portion of the interlocking module to move the first connecting portion according to the rotational direction, and a rotating force providing unit having an angle adjusting protrusion formed on one side of the upper portion;
an angle adjusting unit seated on an upper portion of the rotational force providing unit and having a radial angle adjusting groove formed at a lower portion such that the angle adjusting protrusion is bound to one of the angle adjusting grooves;
an angle adjusting lever located on the upper side of the moving frame unit to rotate the rotational force providing unit; and
The solar panel louver system, characterized in that it includes; an elastic part located between the angle adjusting part and the angle adjusting lever and providing elastic force to bring the upper part of the rotational force providing part into close contact with the lower part of the angle adjusting part. According to claim 1,
The solar panel louver system, characterized in that the movable frame part is fixedly or rotatably provided in the support frame part. According to claim 2,
The solar panel louver system, characterized in that the movable frame part is provided with a fixing part to be fixed or separated from the support frame part while contacting or spaced apart from the inner wall surface of the short side opposite to the support frame part. According to claim 2,
The moving frame unit is a solar panel louver system, characterized in that the movement frame unit and the support frame unit are rotated based on a transverse axis provided at the center of the long side of the support frame unit. The method of claim 1, wherein the solar blade,
a blade frame having fixing grooves formed on one surface to fix the solar panel, protrusions formed at opposite sides of each other, and shafts extending from both ends of the lower surface of the solar panel exposed; and
The solar panel louver system comprising a; frame cover inserted at both ends of the blade frame and passing through the center of the shaft. The method of claim 1, wherein the interlocking module,
a first connection unit that moves in one of left and right directions according to the rotation direction of the rotation angle adjusting module;
Rotating parts to which central parts are respectively coupled to each of the shaft parts on both sides of the solar blade; and
The solar panel louver system, characterized in that it comprises a; second connection part connected by the rotation part when the first connection part moves by connecting the eccentric one end and the other end of the rotation part. delete According to claim 1,
The solar panel louver system, characterized in that the solar blades located at both ends of the solar blades are rotated or non-rotated while the ends are inserted into the inner wall surface of the moving frame unit.

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