KR101181406B1 - Rotary type supporting structure of Solar cell module for outer wall of building - Google Patents

Abstract

The present invention relates to a mounting structure of a solar cell module, and more particularly, the solar cell module can be tilted or adhered to the wall while rotating on the outer wall of the building, and thus used as a photovoltaic device to form an aesthetic appearance of the outer wall of the building. It relates to a rotatable mounting structure of a solar cell module that can.

Rotating mounting structure of the solar cell module is installed on the outer wall of the building according to the present invention, the outer wall of the building fixed to the left and right spaced apart, a pair of fixing brackets hinged to the upper left, right of the solar cell module; An actuating part provided on each of the lower outer walls of any one of the fixing brackets or the lower outer walls of both to move the other end of the support bar up and down; A control driver provided at one side of the operation part to control driving of the operation part; And a support bar having one end hinged to the lower side of the solar cell module, the other end moving up and down while interlocking with the operation unit, such that the solar cell module is inclined or closely adhered to the outer wall.

Solar cell module, Solar power generation, Building exterior wall, Mounting

Description

Rotary type supporting structure of Solar cell module for outer wall of building}

The present invention relates to a mounting structure of a solar cell module, and more particularly, the solar cell module can be tilted or adhered to the wall while rotating on the outer wall of the building, and thus used as a photovoltaic device to form an aesthetic appearance of the outer wall of the building. It relates to a rotatable mounting structure of a solar cell module that can.

Generally, photovoltaic power generation system is a power generation equipment that supplies DC power from solar cell module that generates electric energy by solar light and supplies stable power to the phase field system and houses. It is a natural friendly power generation system that can be used conveniently.

The main purpose of the solar cell module is to receive as much light as possible from the sun and convert it into electricity. To this end, a solar cell module having various module characteristics has been developed.

Such environmentally friendly photovoltaic power generation system takes priority of good solar light due to the preconditions for producing and supplying electric power stably, ensuring the installation area of solar cell module, ease of installation, degree of interference of shadow, power mains Conditions such as the ease of installation of the

However, the solar cell module has a high cost according to the type of solar cell and low energy density of the solar light, so that a large amount of solar cell modules must be used to obtain a predetermined power, which causes a limitation in the installation place.

In addition, due to the characteristics of the photovoltaic power generation system having a change in efficiency according to the angle of the solar light, it must be installed on the roof of a building, a roof, or a separately set up post, and the solar cell module that absorbs solar energy should be facing south. .

Due to this problem, solar modules are installed and developed using the rooftop of a limited building or separate facilities, and the use of individual solar power generation facilities in apartments, multi-family houses, communal buildings, outdoor structures, etc. It has been limited.

In the related art, since the solar cell module for photovoltaic power generation is installed only on a roof, a rooftop, or other limited places, there is a disadvantage in terms of efficiency and economic efficiency.

The present invention devised to overcome the above limitations in the mounting structure of the solar cell module to be installed in the building, the solar cell module is installed to be rotatable in the outer wall of the building can form the aesthetics of the building at the same time as the utilization of the building outer wall. The purpose is to provide a rotating mounting structure of the solar cell module.

In order to solve the above problems, the pivotal mounting structure of the solar cell module installed on the outer wall of the building according to the present invention is fixed to the outer wall of the building to be spaced apart from left and right, and the upper left and right sides of the solar cell module are hinged. A pair of fixing brackets; An actuating part provided on each of the lower outer walls of any one of the fixing brackets or the lower outer walls of both to move the other end of the support bar up and down; A control driver provided at one side of the operation part to control driving of the operation part; And a support bar having one end hinged to the lower side of the solar cell module, the other end moving up and down while interlocking with the operation unit, such that the solar cell module is inclined or closely adhered to the outer wall.

According to the present invention, by using the outer wall of the building as a mounting space of the solar cell module there is an advantage that can form a beautiful appearance of the outer wall of the building at the same time to achieve the power supply by the solar power generation and efficient space utilization of the building.

Rotating mounting structure of the solar cell module is installed on the outer wall of the building according to an embodiment of the present invention, the outer wall of the building is fixed to the left and right spaced apart, a pair of hinged upper left, right of the solar cell module Fixing brackets; An actuating part provided on each of the lower outer walls of any one of the fixing brackets or the lower outer walls of both to move the other end of the support bar up and down; A control driver provided at one side of the operation part to control driving of the operation part; And a support bar having one end hinged to the lower side of the solar cell module, the other end moving up and down while interlocking with the operation unit, such that the solar cell module is inclined or closely adhered to the outer wall.

An example of the operation unit may include: a guide bracket fixed to each lower outer wall of any one of the pair of fixing brackets, or a lower outer wall of both, and having a guide groove formed in one side thereof with a space formed therein; And a pinion gear accommodated in the guide bracket and rotated by a drive motor provided in the control drive unit. And a rack gear that is engaged with the pinion gear to move up and down inside the guide bracket. In this case, the other end of the support bar is hinged to one side of the rack gear through the guide groove.

At this time, the rack gear, the guide protrusion which is formed to protrude on the left, right side can be moved up and down while being inserted into the guide wall formed in the up and down direction on the left and right inner side of the guide bracket.

On the other hand, the operation unit may further include a stopper means to adjust the rotation range of the support bar.

The pivotal mounting structure of the solar cell module installed on the building outer wall according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings, wherein the same reference numerals represent the same member or shape feature having the same function. Shall be.

1 is a perspective view showing a pivotal mounting structure of the solar cell module installed on the building exterior wall according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the mounting structure shown in Figure 1, Figure 3 is Figure 1 4 and 5 are side cross-sectional views illustrating a state of use of the mounting structure shown in FIG. 1.

1 to 5, the pivotal mounting structure 1 of the solar cell module 10 is installed on the outer wall of the building of the present embodiment is a fixed bracket 100, the operation unit 200, the control drive unit 300 and a support bar 400 are included.

The solar cell module 10 is configured to absorb light and convert light energy into electrical energy. The solar cell module 10 is formed in a rectangular plate shape and its outer frame is supported by the mounting structure 1 of the present embodiment. 11) is wrapped and combined.

The fixing bracket 100 has a configuration in which the upper left and right sides of the solar cell module 10, specifically, the upper left and right sides of the frame 11 are hinged, as much as the width of the solar cell module 10 on the outer wall of the building. Fixed left and right spaced apart.

As an example of the fixing bracket 100, as shown in FIGS. 1 and 2, an example of the fixing bracket 100 having a longitudinal cross-section L shape may be provided.

In this example of the fixing bracket 100, one side is fixed to the outer wall while being fixed by a fixing member such as a bolt. And the other side facing the front vertically from the outer wall is formed through hole 11 for the hinge coupling of the solar cell module 10.

The solar cell module 10 is hinged to the fixing bracket 100 by a hinge coupling means 50 such as a bolt member or a pin member through the through hole 11, and the line connecting the hinge coupling means 50 to the axis As a result, the lower side of the solar cell module 10 can rotate forward.

The fixed bracket 100 and the structure in which the solar cell module 10 is hinged in the fixed bracket 100 are not limited to the above-described example, and have various shapes so that the lower side of the solar cell module 10 can rotate. The fixing bracket 100 and the hinge coupling structure can be used.

The support bar 400 is connected to the lower side of the solar cell module 10, and the support bar 400 rotates forward and is inclined with respect to the outer wall when the lower side of the solar cell module 10 rotates forward. While maintaining the inclined state while supporting the lower side.

One end of the support bar 400 is hinged at the lower side of the solar cell module 10, specifically, the lower side of the frame 11 of the solar cell module 10, and the other end of the operation part 200 will be described later. ) So that it can be linked.

The support bar 400 is hinged at the lower side of the solar cell module 10 by various hinge coupling means 50, such as bolt member, pin member.

And, as will be described below, the support bar 400 may be composed of one support bar 400 hinged at the lower side of the solar cell module 10, or at both lower sides of the solar cell module 10 It may be made of a pair of support bars 400 hinged.

The lower outer wall of the fixing bracket 100 is provided with an operating part 200 connected to the support bar 400 described above.

The operation unit 200 is connected to the other end of the support bar 400 to move the other end of the support bar 400 up and down. In addition, the operation unit 200 is driven while being controlled by the control driver 300 to be described later.

The lower portion of the solar cell module 10 is supported by one support bar 400, the operating unit 200 may be made of one operating unit 200 connected to the one support bar 400. Or, the lower side of the solar cell module 10 is supported by a pair of support bars 400, the operating unit 200 is a pair of operating parts connected to the pair of support bars 400 to rotate. It may also be made of (200).

When a pair of operating parts 200 are provided, as shown in FIGS. 1 and 2, the operating parts 200 are provided on each of the lower outer walls of the pair of fixing brackets 100.

As an example of the operation unit 200, a pinion gear rotated by a guide bracket 210 fixed to the lower outer wall of the fixing bracket 100 and a drive motor 310 included in the control driver 300 to be described later. And a rack gear 230 which is engaged with the pinion gear 220 and moves up and down inside the guide bracket 210.

The guide bracket 210 is fixed to the lower outer wall of any one of the pair of fixing brackets 100, or as described above, when a pair of operating parts 200 are provided, a pair of fixing brackets 100 is provided. It may be composed of a pair of guide brackets 210 fixed to each of the lower outer wall of the).

The guide bracket 210 is provided with a space in which the pinion gear 220 and the rack gear 230 can be accommodated, and the space is formed in the vertical direction to enable the vertical movement of the rack gear 230.

One side of the guide bracket 210, that is, the side facing the other end of the support bar 400, the guide groove 211 is formed in the vertical direction.

The rack bracket 230 and the pinion gear 220 meshing with the rack gear 230 are accommodated in the guide bracket 210, and the pinion gear 220 is provided at the other side of the guide bracket 210. It is connected to the drive motor 310 of the control driver 300 to rotate.

When the pinion gear 220 is rotated by the rotation of the drive motor 310, the rack gear 230 moves up and down. At this time, the length of the rack gear 230 and the length of the guide bracket 210 are solar cells. It is formed to a suitable length considering the rotation range of the module 10.

As shown in FIGS. 4 and 5, the rack gear 230 is engaged with the pinion gear 220 provided on the rear side of the rack gear 230 in a state of showing the back inner surface of the guide bracket 210. However, the front and rear positions of the rack gear 230 and the pinion gear 220 may be formed to be opposite to each other.

The rack gear 230 may be provided with various guide means in the guide bracket 210 for stable vertical movement.

As an example of the guide means, as illustrated in FIGS. 3 to 5, a guide wall 212 is formed on the left and right inner surfaces of the guide bracket 210 in a vertical direction, and the pair of guide walls ( Means consisting of guide protrusions 231 protruding from the left and right sides of the rack gear 230 may be provided to be inserted between the 212.

The guide protrusion 231 is vertically guided while being inserted between the guide walls 212, whereby the rack gear 230 is stably moved in the vertical direction without flowing back and forth.

The support bar 400 is connected to the other end of the operation part 200, specifically the rack gear 230, and moves up and down while interlocking, the other end and the rack gear 230 of the support bar 400. The connection is made by various hinge coupling means 50, such as bolt members, pins and the like through the guide groove 211.

The other end of the support bar 400 is hinged to one side of the rack gear 230 by the hinge coupling means 50 through the guide groove 211, and move together with the vertical movement of the rack gear 230 do.

At this time, one end of the support bar 400 is hinged to the lower side of the solar cell module 10, and the other end of the support bar 400 moves upward, so that one end of the support bar 400 rotates forward. Done. As one end of the support bar 400 rotates forward, the lower side of the solar cell module 10 also rotates forward so that the solar cell module 10 is inclined at a predetermined angle with respect to the outer wall.

When the other end of the support bar 400 moves downward, one end of the support bar 400 rotates backward so that the solar cell module 10 is in close contact with the outer wall of the building.

On the other hand, the guide groove 211 may be formed side by side at the rack gear 230 side, but is formed closer to the outer wall than the side position of the rack gear 230 by moving the vertical line of the other end of the support bar 400 You can get closer to the outer wall.

To this end, as shown in FIGS. 4 and 5, the fixing piece 232 may be fixed to one side of the rack gear 230. The fixing piece 232 extends from one side of the rack gear 230 is exposed in the guide groove 211, the support bar 400 is hinged by the fixing piece 232 and the hinge coupling means (50).

In this case, when the other end of the support bar 400 moves downward, the solar cell module 10 may be in close contact with the outer wall and thus may be more helpful in forming an aesthetic appearance of the outer wall of the building.

The operation unit 200 may further include a stopper means to adjust the rotation range of the support bar 400.

As an example of the stopper means, as illustrated in FIGS. 4 and 5, a first stopper 213 protruding from one side of the guide bracket 210 facing the support bar 400 may be provided.

When the other end of the support bar 400 moves downward, the first stopper 213 limits the rotation range such that the angle formed with the solar cell module 10 is less than 180 degrees, thereby supporting the support bar 400. One end of the support bar 400 naturally rotates forward when the other end of the upper side moves upward again.

In addition, the second stopper 214 may protrude from one side surface of the guide bracket 210 so as to be located in front of the first stopper 213.

The second stopper 214 limits the rotation further when one end of the support bar 400 is rotated forward by a predetermined angle.

The control driver 300 includes a controller 320 for controlling the driving of the driving motor 310. The controller 320 controls the forward and reverse rotation of the drive motor 310 such that the pinion gear 220 rotates forward and backward according to a desired inclination angle of the solar cell module 10.

The control driver 300 may further include a memory chip (not shown). The memory chip may store data about the time when sunlight is incident on the exterior wall of the building according to a date and the angle of incidence of sunlight that changes with the passage of the incident time.

Therefore, the controller 320 reads the stored data of the memory chip and controls the driving of the driving motor 310 so that the solar cell module 10 rotates inclined at the time of incidence of sunlight, and also rotates the solar cell module 10. It can be adjusted to have an appropriate inclination angle according to the sunlight incident angle in the range. At the time when the incident of sunlight is completed, it returns again and adheres to the exterior wall of the building.

4 and 5 show the state of use of the mounting structure 1 according to the present embodiment.

4 (a) and (b) shows a state in which the solar cell module 10 is in close contact with the outer wall of the building at sunset time or other solar power generation is stopped.

5 (a) and 5 (b) illustrate a state in which the solar cell module 10 is rotated at a predetermined angle with respect to the outer wall during the time when sunlight is incident on the outer wall of the building.

When the mounting structure of the present embodiment is installed on the upper side of the window, the inclined solar cell module may also serve as an eave.

That is, the solar cell module absorbs and shields sunlight that shines in the summer, thereby reducing the solar heat incident through the window, and in rainy weather, it is possible to block rainwater entering the window by the solar cell module. It is possible to obtain the effect that the eaves are formed on the outer wall of the building by the mounting structure of the present embodiment.

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. It is not limited.

1 is a perspective view showing a pivotal mounting structure of a solar cell module installed on the building outer wall according to an embodiment of the present invention,

Figure 2 is an exploded perspective view of the mounting structure shown in Figure 1,

3 is a plan view of the operation unit shown in FIG.

4 and 5 are side cross-sectional views showing the use state of the mounting structure shown in FIG.

Explanation of symbols on main parts of drawing

One; A rotatable mounting structure 10 of the solar cell module; Solar cell module

11; Frame 50; Hinged means

100; Fixing bracket 101; Through hole

200; Actuator 210; Guide Bracket

211; Guide groove 212; Guide wall

213; First stopper 214; 2nd stopper

220; Pinion gear 230; Rack gear

231; Guide protrusion 232; Fixed piece

300; Control driver 310; Drive motor

320; A controller 400; Support bar

Claims (4)

A pair of fixing brackets fixed to the outer wall of the building by being spaced apart from the left and right sides and hinged to the upper left and right sides of the solar cell module; An actuating part provided on each of the lower outer walls of any one of the fixing brackets or the lower outer walls of both to move the other end of the support bar up and down; A control driver provided at one side of the operation part to control driving of the operation part; And One end is hinged at the lower side of the solar cell module, the other end is moved up and down while interlocking with the operation part to support the solar cell module inclined or in close contact with the outer wall; Includes, The operation unit, A guide bracket fixed to each of the lower outer walls of any one of the pair of fixing brackets or the lower outer walls of both, and having a space therein and having guide grooves formed at one side in a vertical direction; A pinion gear accommodated in the guide bracket and rotated by a drive motor provided in a control driver; And The rack gear meshes with the pinion gear and moves up and down inside the guide bracket, The other end of the support bar is a pivotal mounting structure of the solar cell module is installed on the outer wall of the building, characterized in that the hinge coupled to one side of the rack gear through the guide groove. delete The method according to claim 1, The rack gear is installed on the outer wall of the building, characterized in that the guide protrusions protruding from the left and right sides are inserted into the guide walls formed in the up and down directions on the left and right inner surfaces of the guide bracket and moved up and down while being guided. Rotating mounting structure of the solar cell module. The method according to claim 1 or 3, The operating unit is a rotational mounting structure of the solar cell module is installed on the outer wall of the building, characterized in that the stopper means is further included to adjust the rotation range of the support bar.

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