KR101444818B1 - Photovoltaic module support for roof of factory - Google Patents

Abstract

The present invention relates to an improved photovoltaic module mount for a factory roof, which can easily install a photovoltaic module even when an obstacle is present at a perimeter, easily adjust an inclination angle of the photovoltaic module and prevent vibration and noise. The photovoltaic module mount of the present invention, which is installed on a prefabricated roof panel on which mountain shaped convex parts are formed, for supporting a photovoltaic module includes: a plurality of roof brackets fixed on the convex part of the roof panel following the vertical and horizontal directions of the photovoltaic module; a pair of base beams coupled to left and right parts of the roof bracket; a pair of left and right girders slantingly and vertically coupled to a lower surface of the photovoltaic module to support the photovoltaic module; a plurality of clamps to fix the photovoltaic module on the girder; a pair of supports having a lower end coupled to a rear upper end of the base beam and an upper end coupled to an upper end of the girder; a first supporting bracket, which rotates around a transverse support shaft member, allowing the support to rotate in a direction adapted to adjust a degree of inclination of the photovoltaic module; a second supporting bracket to support the rotation of the support; and a third support bracket coupled to an upper part of the base beam and a second slot of the girder.

Description

[0001] The present invention relates to a photovoltaic module support for a roof,

The present invention relates to a solar module module stand mounted on a roof of a factory, and more particularly, to a solar module module which can easily adjust the inclination angle of a solar module and can prevent the generation of vibration and noise The present invention relates to an improved photovoltaic module cradle for a plant roof.

Recently, a new energy and renewable energy industry that is capable of actively responding to sustainable energy supply and environmental regulation has been attracting attention as the fossil fuel reserves are finite and environmental pollution due to the use of fossil fuels becomes a serious problem.

In Korea, renewable energy is divided into three categories: renewable energy, solar energy, solar energy, biomass, wind power, hydro power, geothermal energy, marine energy, and waste energy. Field is specified.

Among them, in the solar power generation industry related to the present invention, there are a module (solar panel) which is a collection of solar cells that convert solar energy into electric energy by using a photoelectric effect, It is important to develop a stand that stably supports a plurality of modules while fixing them in a state suitable for incident angle of sunlight.

The holder for the solar module is known as a number of patented technologies at home and abroad. Particularly, as a mount installed on the roof of a building such as a factory, registered patent No. 10-0978756 (name: 10-1207236 (name: lightweight solar photovoltaic device for roof installation), registered patent No. 10-1306909 (name: solar cell module supporter installed on a roof), registered patent 10- No. 1317568, entitled "Photovoltaic Power Generation System for Roof Attachment with Enhanced Waterproofing Function", Registered Utility Model No. 20-0467819 (Name: Structure System for Supporting Solar Cell Module), Registered Utility Model No. 20-0470558 (Name: A photovoltaic device for a roof-mounted installation), and the like. However, in these prior patents, it is impossible to change or adjust the direction or the position in a state where the components are combined, so that there is a problem that it is difficult to mount the cradle when an obstacle exists in the installation position of the cradle.

Meanwhile, it is necessary to adjust the inclination angle of the solar module in accordance with the sun's angle of incidence according to the sun's changing angle according to the season. In the conventional solar module module, the configuration for controlling the inclination angle of the solar module is complicated It is necessary to simplify this.

In addition, a solar module is a collection of solar cells that are closed in a panel form by connecting solar cells to each other. As a result, the solar modules are subjected to mechanical load due to strong winds or earthquakes. As a result, the modules are deformed, Fatigue is induced in the material, and materials such as copper wire connecting the solar cell may be easily broken. Even weak winds will cause the modules to vibrate, so coping with these vibrations is necessary in view of the lifetime of the photovoltaic modules. It is also required to prevent vibrations or noise that may occur between the solar module and the mount or between the mount and the roof panel.

Korean Patent No. 10-0978756 Korean Patent No. 10-1207236 Korean Patent No. 10-1306909 Korean Patent No. 10-1317568 Korean Utility Model Registration No. 20-0467819 Korean Registered Utility Model No. 20-0470558

As described above, the conventional roof mount solar module has a complicated structure for adjusting the inclination angle of the solar module, which increases manufacturing costs and inconvenient operation. It is an object of the present invention to provide a solar module cradle for a plant roof which can easily adjust the inclination angle of a solar module by solving such a problem.

In addition, the conventional stand for a roof-mounted solar module has a problem that it is difficult to install a stand when an obstacle is present at an installation position of the stand. The present invention can easily install the stand even if an obstacle exists at the installation position of the stand Another object of the present invention is to provide a photovoltaic module cradle for a factory roof which can be made to be made of a solar cell.

In addition, the present invention prevents deformation or breakage of a module by mitigating a load applied to a solar module when a wind or an earthquake occurs, and also prevents vibrations that may occur between a solar module and a mount or a roof panel Another object of the present invention is to provide a photovoltaic module cradle for a plant roof which can prevent noise and leakage.

According to an aspect of the present invention, there is provided a photovoltaic module cradle for a plant roof, which is installed on a prefabricated roof panel on which protrusions are formed, and supports the photovoltaic module, A plurality of roof brackets fixed on the protrusions; a base beam having a first slot formed in the upper surface thereof and coupled to the roof bracket in a pair of right and left sides; A pair of left and right girders each having a second slot formed on the left and right sides thereof for supporting the module, a plurality of clamps for fixing the solar module on the girder, and a lower end connected to the rear upper end of the base beam, And a lower end portion of the strut is coupled to the base beam at a position where the lower end of the strut is coupled to the base beam, Is coupled with the first longitudinal support shaft member and is coupled with the support by the transverse support shaft member in a state in which the support is inserted so that the support member adjusts the inclination of the solar module with the transverse support shaft member as the central axis And the upper part is slidably coupled along the second slot of the girder through the first fastener and the lower part is coupled to the upper part of the support via the second fastener, A second support bracket coupled to the side portion of the girder and supporting a rotation of the strut; and a second support bracket connected to the second support bracket and having a U- And a third support bracket coupled to the slot side.

In the above configuration, the clamp may have a first concave-convex portion on the inner side in contact with the solar module, and a first elastic pad may be interposed between the first concave-convex portion and the solar module to absorb vibration and noise.

In the above configuration, the roof bracket has a second concave-convex portion on an inner side surface in contact with the projection of the roof panel, and absorbs vibration and noise between the second concave-convex portion and the roof panel, A pad may be interposed.

In the above configuration, the roof bracket has a fixing member penetrating portion to be coupled to the roof panel via a fixing member, and the fixing member penetrating portion can be subjected to the caulking finishing process in a state where the roof bracket is fixed to the roof panel.

In the above arrangement, the base beam is supported by the third bracket, and the horizontal portion is fixed on the roof bracket by the third longitudinal support shaft member, and the side portion is supported by the side portion of the base beam and the fixing bolt Brackets may be further provided.

The solar module module holder for a factory roof according to the present invention can easily adjust the inclination angle of the solar module by means of the brackets having a simple structure. Even if an obstacle exists in the installation position, There is an effect that installation can be easily performed.

In addition, in the solar cell module holder for a factory roof of the present invention, an elastic pad is interposed between a clamp for coupling the solar module and the girder, and an elastic pad is interposed between the roof panel and the roof bracket. The load applied to the optical module is mitigated to prevent deformation or breakage of the module, and vibration, noise, and leakage that may occur between the solar module and the mount or the roof panel can be prevented.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view illustrating a construction of an embodiment of the present invention. FIG.
2 is a side view of an embodiment of the present invention.
3 is a front view of an embodiment of the present invention.
4 is an enlarged view of part B of Fig.
5 is a view showing an embodiment of a first support bracket constituting the present invention.
6 is a view showing an example in which the inclination degree of the solar module is adjusted in the state of FIG.
FIG. 7 is a view illustrating a state in which the embodiment of FIG. 1 is installed in another direction. FIG.
8 is an enlarged view of part A of Fig.
9 is an exploded perspective view showing an embodiment of a loop bracket constituting the present invention.
FIG. 10 is a view showing a state where a caulking finishing process is performed after installing the loop bracket of FIG. 9;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it should be understood that the following embodiments are provided so that those skilled in the art can understand the present invention without departing from the scope and spirit of the present invention. It is not.

In general, the number of columns is minimized because the continuous production activities are carried out in a state where a plurality of machines are arranged in a complicated arrangement inside the factory building, and the roof is supported only on the side walls of the building. It should be constructed. Therefore, the roof of the plant is often constructed with prefabricated panels such as urethane or sandwich panels with styrofoam. In order to secure the rigidity of such a prefabricated panel, the roof panel is formed with mountain-shaped protrusions capable of supporting the load, and is sloped so that drainage can be smoothly performed in case of rainfall or snowfall.

The solar module cradle of the present invention is a solar cell module cradle for a plant roof that enables a solar panel module to be installed on a factory roof on which such a panel panel type roof panel is installed, A specific configuration will be described.

First, a plurality of roof brackets 10 are installed on a plurality of mountain-like projections P1 formed on a roof panel P. In this embodiment, four roof brackets 10 are arranged in front of and behind the solar module M Direction and the left-right direction. The roof bracket 10 has a shape conforming to the shape of the projecting portion P1 of the roof panel P and has a through hole 11 to which the fastening screw 12 is fastened as shown in Figures 9 and 10, And burrs 11a are formed. The loop bracket 10 is firmly fixed to the protruding portion P1 of the roof panel P by the fastening screw 12 fastened through the through portion 11. [

On the loop bracket 10, the base beam 20 is engaged. This base beam 20 may be directly coupled onto the roof bracket 10 but in this embodiment the base beam 20 is coupled to the roof bracket 10 in the state where the auxiliary bracket 30 is mediated . That is, the auxiliary bracket 30 is of an inverted T shape, and the horizontal surface portion is fixed on the roof bracket 10 by the third longitudinal support shaft member 31 to support the base beam 20, And is joined to the side portion of the beam 20 by the fixing bolt 32.

The base beam 20 may be made of an extruded material having slots formed in the upper and lower surfaces and the left and right surfaces. In particular, the slots formed in the upper surface portion are essentially formed as the first slots 21, It is preferable that the bracket 30 is formed so as to be easily connected to the bracket 30 with a bolt, and a slot may not be formed in the bottom portion, but the ease of use and compatibility (the base beam has the same structure as the 'girder' It is preferable that the slots are formed on the upper and lower surfaces and the left and right sides, respectively. These base beams 20 are coupled on the roof bracket 10 with a pair of left and right as shown in Fig. 1 or Fig.

A pair of left and right girders 40 are provided at the bottom of the solar module M to support the solar module M. The left and right sides of the girder 40 are provided with second slots 41 are formed. As described above, since the girder 40 is extrusion-made so as to be compatible with the base beam 20, slots can be formed not only on the left and right sides but also on the upper and lower sides.

As the member for fixing the solar module (M) to the girder (40), a plurality of clamps (50) are provided. As shown in detail in FIG. 8, which is an enlarged view of part A of FIG. 2, the clamp 50 has a shape bent in a continuous manner so as to be in close contact with the upper surface portion and the side surface portion of the solar module M and the upper surface portion of the girder 40, The photovoltaic module M is fixed on the girder 40 via the bolts 51 fastened to the upper surface portion of the solar cell module 40. Particularly, in this embodiment, the clamp 50 has the first concave-convex portion 50a on the inner side in contact with the solar module M as shown in Fig. 8, and the first concave- The first elastic pad 52 such as a rubber pad tightly held by the first concave and convex portion 50a is interposed between the first elastic pad P and the first elastic pad 52. Therefore, 52 can be absorbed.

Next, a pair of pillars 60 are provided on the base beam 20 for supporting the solar module M at a predetermined inclination angle. That is, in the state where the base beams 20 are coupled to the roof brackets 10 in a pair in left and right directions with reference to the direction of the solar module M as shown in FIG. 1, And the lower end of the strut 60 is coupled to the upper end of the girder 40. As shown in Fig. The lower end of the strut 60 is coupled to the base beam 20 by the first support bracket 70 and the upper end of the strut 60 is coupled to the girder 40 by the second support bracket 80. [ .

In particular, the first support bracket 70 is U-shaped as shown in FIG. 5, and at the position where the lower end of the strut 60 is coupled to the base beam 20, the horizontal lower end of the first support bracket 70 Is fixed to the base beam (20) by a first longitudinal support shaft member (71) fastened longitudinally on the base beam (20). The first support bracket 70 is engaged with the support 60 by a transverse support shaft member 72 which is laterally fastened in a state where the lower end of the support 60 is inserted, So that it can rotate in the direction to adjust the inclination angle of the solar module (M) with the transverse support shaft member (72) as a central axis.

1, an upper portion of the second supporting bracket 80 is connected to a second slot (not shown) of the girder 40 via a first fastening hole 81. The second supporting bracket 80 has an H- 41 and the lower portion of the second support bracket 80 is engaged with the upper portion of the support 60 via the second fastener 82 so that the support 60 can be slidably engaged with the sun And supports the rotation of the strut 60 when it rotates in a direction to adjust the tilt angle of the optical module M. [

A third support bracket 90 is provided which is coupled between the base beam 20 and the girder 40 in correspondence with the struts 60 on the front side of the solar module M. [ The third support bracket 90 has the same U-shape as the first support bracket 70 described above. The mounting structure of the third support bracket 90 is such that the base beam 20 is coupled to the roof bracket 10 in a left and right pair, And the vertical upper portion of the third support bracket 90 is fixed to the upper surface of the girder 40 through the third fastener 92. The upper end of the third support bracket 90 is fixed to the front side of the base beam 20 by the second longitudinal support shaft member 91, And the second slot 41 formed on the side surface of the second slot 41. [ 6, when the struts 60 are rotated in the direction to adjust the inclination angle of the solar module M while being supported by the first support bracket 70 and the second support bracket 80, The front side of the girder 40 is supported by the third support bracket 90 as the inclination of the girder 40 is also changed.

9, the roof bracket 10 is provided with a second concavo-convex portion 13 on the inner side thereof in contact with the projection P1 of the roof panel P, and the second concavo-convex portion 12, A second elastic pad 14 such as a rubber pad firmly held by the second concavo-convex portion 13 is interposed between the front panel 10 and the roof panel P to absorb vibration and noise generated by an external force externally applied thereto As well as to block any leaks that may occur during rain or snowfall.

As described above, the roof bracket 10 is provided with the penetration portion 11 to be coupled to the roof panel P via the fixing screw 12, and the roof bracket 10 is provided on the roof panel P, the penetrating portion 11 is subjected to the caulking finish treatment, so that the caulking finish processing portion 15 can completely block the leakage of water through the penetrating portion 11. [

Hereinafter, construction and use of the solar cell module cradle for a factory roof according to the present invention will be described.

First, referring to FIGS. 1 and 6, four loop brackets 10 are installed at four places on the front, rear, left, and right sides of the protruding portion P1 of the roof panel P, A pair of base beams 20 are installed on the left and right sides of the roof bracket 10 via the auxiliary bracket 30. The lower ends of the pair of struts 60 are coupled to the rear upper end side of the left and right base beams 20 by the first supporting brackets 70 and the upper ends of the struts 60 are engaged with the second supporting brackets 80 To be coupled to the girder 40. [0050] The first support bracket 70 is engaged with the support 60 by the transverse support shaft member 72 while being fixed to the base beam 20 by the first longitudinal support shaft member 71 . The upper portion of the second support bracket 80 is slidably coupled along the second slot 41 of the girder 40 via the first fastener 81 and the upper portion of the second support bracket 80 And the lower portion is engaged with the upper portion of the support 60 via the second fastening member 82. [ A third support bracket 90 is provided between the front of the base beam 20 and the girder 40. A horizontal lower end of the third support bracket 90 is disposed on the upper side of the base beam 20 And the vertical upper portion of the third support bracket 90 is fixed to the second slot 41 side formed on the side portion of the girder 40 via the third fastener 92 Lt; / RTI >

6, when the pair of struts 60 are tilted toward the front side of the solar module M, the upper and lower ends of the struts 60 are connected to the second fastening holes 82 in the lateral direction The solar module M is rotated in the direction in which the inclination angle of the solar module M increases with the support shaft member 72 as a center axis. The second support bracket 80 connecting the upper portion of the strut 60 to the girder 40 is slid along the second slot 41 of the girder 40 by the first fastener 81, Since the third support bracket 90 supports the front side of the girder 40 by the third fastening member 92, the angle of inclination of the girder 40 becomes larger as the support 60 rotates, The inclination of the module M becomes large.

When there is an obstacle in the installation position of the solar module M or when the right and left directions are changed without adjusting the inclination degree of the solar module M as shown in FIG. 7, the protrusion P1 of the roof panel P ) Of the roof bracket 10 is changed. 7 shows a state in which the solar module M is oriented in the same direction as the state shown in FIG. 1, and the illustration shown in the dark is a state in which the fixed position of the roof bracket 10 is changed It shows the construction.

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 exemplary embodiments, but, on the contrary, This is possible.

10: loop bracket 11:
11a: Burr 12: Fixing screw
13: second uneven portion 14: second elastic pad
15: caulking finish processing unit 20: base beam
21: first slot 30: auxiliary bracket
31: third longitudinal supporting shaft member 32: fixing bolt
40: girder 41: second slot
50: clamp 50a: first concave-
51: bolt 52: first elastic pad
60: support 70: first support bracket
71: first longitudinal support shaft member 72: transverse support shaft member
80: second support bracket 81: first fastener
82: second fastener 90: third support bracket
91: second longitudinal support shaft member 92: third fastener
M: Solar module P: Roof panel
P1: protrusion

Claims (5)

1. A solar cell module cradle for a plant roof, which is installed on a prefabricated roof panel having mountain-shaped protrusions to support the solar cell module,
And a second concavo-convex portion on an inner side surface of the roof panel that is fixed on the protruding portion of the roof panel along the front, rear, left, and right directions of the solar module. The roof panel has vibration and noise And a fixing member penetrating portion for fixing the roof panel to the roof panel through a fixing member, wherein the fixing member penetrating portion is fixed to the roof panel by a caulking finish A plurality of loop brackets to be processed,
A base beam having a first slot formed on an upper surface thereof and coupled to the roof bracket in a pair,
A pair of right and left girders each having a second slot formed on a left side and a right side thereof for supporting the solar module on a bottom surface of the solar module,
A first elastic pad for absorbing vibrations and noise is interposed between the first concave-convex part and the solar module, and a second elastic pad for absorbing vibration and noise is interposed between the first concave-convex part and the solar module. A plurality of clamps,
And a pair of struts connected to a lower end of the base beam at a rear upper end thereof and coupled to the girder at an upper end thereof,
U-shaped and connected to the first longitudinal support shaft member on the base beam at a position where the lower end of the support is coupled to the base beam, and the support member A first support bracket coupled with the support to allow the support to rotate in a direction to adjust the inclination of the solar module with the transverse support shaft member as a central axis;
Wherein the upper portion is slidably coupled along a second slot of the girder through a first fastener and the lower portion is engaged with an upper portion of the strut via a second fastener to rotate the strut A second support bracket supporting the first support bracket;
And a third supporting bracket that is coupled to the second slot side of the girder through a third fastening hole is formed on the upper side of the third supporting bracket Wherein the solar cell module is mounted on a ceiling.
delete delete delete The method according to claim 1,
And a side bracket for supporting the base beam while being fixed on the roof bracket by a third longitudinal support shaft member and the side portion being coupled to the side portion of the base beam by a fixing bolt, A photovoltaic module cradle for a plant roof.

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