KR20120014407A - Mechanism for supporting solar modules on roof panels - Google Patents

Abstract

The present invention provides a mechanism for supporting the photovoltaic module 10 on a roof woven with a plurality of panel boards 20: A pair of clasps 30 is opposed to the woven portion of the panel board 20 and lower Coupled through the through-hole 35, the clasp 30 is vertical to the upper side of the engaging portion 31 with the engaging portion 31 to be engaged with the groove portion 21, 22 formed in the panel plate 20. It is provided with an opposing surface 33 adjacent to each other, characterized in that for supporting the solar module 10 through the support means connected to the upper side of the opposing surface (33).
Accordingly, the solar modules can be mounted steadily and quickly on the roof which is bent and joined in a certain shape, and there is an effect of reducing durability of leakage and improving durability.

Description

Device for supporting solar cell module on a roof panel

The present invention relates to a mechanism for supporting a photovoltaic module on a roof panel, and more specifically, to support a photovoltaic module on a roof panel that can be mounted on a roof panel that is bent and joined to a certain shape on a solid and fast basis. It is about a mechanism.

Conventional prefabricated roofs are contacted by outside air and indoor air through gaps and insulators that must be formed at the edge overlapping or connecting portions between the sandwich panel, the sandwich panel, and the upper and lower plates constituting the upper and lower plates respectively, so that the insulating material is insulated. In particular, condensation occurs on the surface of the lower plate in winter, and this phenomenon is increased due to the expansion of the gap between the unit plates and the change of the insulation itself over time as the service life of the roof becomes longer. Therefore, it is difficult to apply the prefabricated roof as described above in a clean room such as a semiconductor manufacturing plant, which requires strict management control such as temperature and humidity.

In view of this situation, the patent application No. 2008-91583 by the present applicant is laminated with a two-layered insulating material on the upper surface of the lower plate, and the upper plate is placed on the upper end of the support that protrudes through the insulating material in the state standing on the lower plate. As a result, a natural ventilation layer is formed between the heat insulating material and the upper plate, and a moisture barrier film is laminated and bonded to each overlapping portion of the edge of the unit lower plate constituting the lower plate, and a thermal block is interposed between the lower plate and the support. We propose a prefabricated roof having a ventilation layer.

However, in order to install a solar module on such a roof, a bracket having a complicated structure must be erected separately.

"Solar cell module fixing clamp" of Korean Unexamined Patent Publication No. 2010-0002482 is to be used in place of the support on the inclined surface of the solar module, in the clamp component for connecting the other battery module, it is connected to the frame 110 End clamp 300 to be bent, the connection clamp (500) to serve as a frame framing linkage between the modules, the upper fixing clamp (510) for fixing to the upper frame of the module, the lower fixing clamp base for fixing the module and the roof surface (500) And a solar cell module fixing clamp assembly including a fixing bolt 400 and a spring nut 410 and a bolt 400 and a spring nut 410 for fixing and connecting the roof slope and the solar cell module to each other. Suggest.

However, this also has a complex structure including a clamp, which causes a material cost increase, and also has a closed end that is difficult to apply to a roof constructed by connecting prefabricated steel sheets.

In addition, the above-described prior art requires a perforation of the panel of the roof, which requires additional work for watertightness, and there is a disadvantage in that there is always a risk of leakage if not regularly managed.

SUMMARY OF THE INVENTION An object of the present invention is to provide a mechanism for supporting a photovoltaic module on a roof panel that can be mounted on a roof that is bent to a certain shape and rapidly mounted on the roof panel. have.

In order to achieve the above object, the present invention provides a mechanism for supporting a photovoltaic module on a roof woven with a plurality of panel boards: a pair of clasps are opposed to the woven portion of the panel board and coupled through the lower through The clasps have opposing surfaces vertically adjacent to the upper side of the engaging portion together with the engaging portions engaged with the recesses formed in the panel plate, and support the solar module through supporting means connected to the upper side of the opposing surface. It is characterized by.

As a first embodiment of the present invention, the support means is characterized in that the support piece which is integrally extended to the upper side on the opposite surface of the clasp and having an upper hole for fastening.

As a second embodiment of the invention, the support means is characterized in that the support is coupled between the opposing surface of the clasp and having an upper through hole for fastening.

As a third embodiment of the present invention, the support means is characterized in that the support tube is coupled between the opposing surface of the clasp and having an upper through hole for fastening.

In addition, according to the present invention is characterized in that the woven portion of the panel plate member further comprises a reinforcing frame.

According to the mechanism of the present invention as described above, it is possible to mount the solar module on the roof which is bent and jointed in a certain shape steadily and quickly, and there is an effect of improving durability while reducing the risk of leakage.

1 is a configuration diagram showing the mechanism according to the first embodiment of the present invention in the installation state
2 is a configuration diagram showing the mechanism according to the second embodiment of the present invention in an installed state
3 is a configuration diagram showing the mechanism according to the third embodiment of the present invention in an installed state;

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

The present invention relates to a mechanism for supporting a solar module 10 on a roof woven with a plurality of panel board 20. The panel plate 20 is usually formed by plastic processing a steel sheet to impart unevenness, and is continuously joined in one direction to form a roof. The photovoltaic module means a light collecting plate of a solar cell, but is not limited thereto and may include a solar module or other roof mounted structure.

The panel plate 20 has an asymmetrical structure in which a first recess 21 and an uneven portion 26 are formed at one end and a hook 24 is formed at the other end based on a U-shaped cross section. One panel board 20 is fixed to the roof, and the hook part 24 of the next panel board 20 is continuously connected to the first recess 21 of the previous panel board 20 by hanging. According to the roof of the concave-convex structure, the first concave portion 21 and the second concave portion 22 are repeatedly arranged at each peak. In general, in the panel plate 20, the first recess 21 is a rectangular cross section which is formed relatively deep, and the second recess 22 is an arc cross section which is relatively shallow.

In the present invention, a pair of clasps 30 oppose the woven portion of the panel plate 20 and take a method of coupling through the lower through hole 35. The clasp 30 of the present invention is fixed to the recesses 21 and 22 formed on the peaks of the roof woven with the panel board 20, and in the state of mutually symmetrically facing each other using two pairs of the same type. Insert the bolt onto the lower hole (35) and tighten with a nut.

At this time, according to the present invention, the clasp 30 is vertically adjacent to the upper side of the catching portion 31 together with the catching portion 31 engaged with the recesses 21 and 22 formed in the panel plate 20. The opposing surface 33 is provided. Clasp 30 is bent at least three times at a right angle to form a horizontal plane and four horizontal planes. The lowermost horizontal surface is called the locking portion 31, and the uppermost vertical surface is called the opposing surface 33. The engaging portion 31 is bent to the groove portion 21 and 22 and bent to a length that does not excessively contact the panel plate 20. The lower through hole 35 is formed on the opposite surface 33.

In addition, according to the present invention is characterized in that for supporting the solar module 10 through the support means connected to the upper side of the opposing surface (33). The support means means a member interposed between the clasp 30 and the photovoltaic module 10. The support piece 40 of FIG. 1 is the first embodiment of the present invention, the support 50 of FIG. 2 is the first embodiment of the present invention, and the support tube 60 of FIG. 3 is the third embodiment of the present invention. .

As a first embodiment of the present invention, the support means may be composed of a support piece 40 which is integrally extended upwardly from the opposing surface 33 of the clasp 30 and having an upper hole 47 for fastening. have. The support piece 40 extending from the opposing surface 33 of the clasp 30 has a horizontal plane that is bent at a right angle and an upper through hole 47 is formed on the horizontal plane. The upper through hole 47 is a part for fastening the solar module 10 with the bolt (B) and the nut (N).

Since the support piece 40 configured as described above is integral with the clasp 30, the work piece is relatively simple, which is advantageous for reducing the airborne.

As a second embodiment of the present invention, the support means may be composed of a support 50 coupled between the opposing surfaces 33 of the clasp 30 and having an upper through hole 57 for fastening. Using a separate support 50 having an angle form, and forms a lower through-hole 55 and the upper through hole 57 on the support (50). The lower through-hole 55 of the support 50 is a portion that is fastened to the lower through-hole 35 of the clasp 30, and the upper through-hole 57 is a bolt (B) and a nut ( N) is the part to be fastened.

The support 50 configured as described above is suitable for the purpose of easily fixing the modified fastening position when the capacity of the solar module 10 is increased.

As a third embodiment of the present invention, the support means may be composed of a support tube 60 coupled between the opposing surfaces 33 of the clasp 30 and having an upper through-hole 67 for fastening. Using a separate support tube 60 having a rectangular cross-sectional shape, and forms a lower through-hole 65 and the upper through-hole 67 on the support tube (60). The lower through hole 65 of the support tube 60 is a portion that is fastened to the lower through hole 35 of the clasp 30, and the upper through hole 67 is a bolt B without a nut to the solar module 10 as described above. It is the part to be fastened only. In the case of the third embodiment, unlike the first embodiment and the second embodiment, it must be accompanied by some dimensional change on the clasp 30 to accommodate the wide support tube 60.

The support tube 60 configured as described above is advantageous when the size of the solar module 10 is large or the influence of wind power is large.

In addition, the support tube 60 may use a section steel in which one side is not necessarily a rectangular cross-section tube shape, and may use a resin or rubber packing for dust prevention instead of a metal material.

At this time, according to the present invention, the woven portion of the panel plate 20 is preferably provided with a reinforcing frame 70. The reinforcement frame 70 uses a material having a higher strength than the panel plate 20 and is fixed to the binding portion of the panel plate 20 through the sliding bolt 73. When the reinforcing frame 70 is installed, the panel plate 20 may be prevented from being deformed due to excessive stress in the process of coupling the pair of clasps 30.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

10: solar module 20: panel plate
21, 22: groove 24: hook portion
30: latch 31: latching portion
33: facing surface 35, 55, 65: lower through hole
47, 57, 67: upper aperture 40: support piece
50: support 60: support tube
70: reinforcement frame 73: sliding bolt

Claims (5)

In a mechanism for supporting the photovoltaic module 10 on a roof woven with a plurality of panel boards 20:
A pair of clasps 30 are opposed to the woven portion of the panel plate 20 and coupled through the lower through hole 35,
The clasp 30 has an opposing surface 33 vertically adjacent to an upper side of the engaging portion 31 together with the engaging portion 31 engaged with the recesses 21 and 22 formed in the panel plate 20. Equipped,
Mechanism for supporting the solar module on the roof panel, characterized in that for supporting the solar module 10 through the support means connected to the upper side of the opposing surface (33). The method of claim 1,
The supporting means supports the solar module to the roof panel, characterized in that the support piece 40 extending integrally upward from the opposing surface 33 of the clasp 30 and having an upper hole 47 for fastening. Appliance. The method of claim 1,
The support means is a mechanism for supporting the solar module on the roof panel, characterized in that the support (50) is coupled between the opposing surface (33) of the clasp (30) having an upper through hole (57) for fastening. The method of claim 1,
The support means is a mechanism for supporting a solar module on the roof panel, characterized in that the support pipe 60 is coupled between the opposing surface 33 of the clasp 30 and having an upper through hole 67 for fastening. The method of claim 1,
The woven portion of the panel plate 20 is a mechanism for supporting a solar module on the roof panel, characterized in that it further comprises a reinforcement frame (70).

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