KR102023151B1 - Supporting assembly for photovoltaic array - Google Patents

Abstract

The present invention relates to a supporting assembly for a photovoltaic array, which is able to prevent a roof panel from being damaged by a deformation of the support assembly for the photovoltaic array by wind, and to improve the durability of a part treated to be waterproof. According to the present invention, the supporting assembly for the photovoltaic assembly comprises: an upper plate made from rectangular plate materials to have an upper fastening hole for fastening bolts on each corner and to be placed on an upper surface of an upper flange of a roof frame; a lower plate which has a lower fastening hole formed at a point corresponding to the upper fastening hole, being placed on a lower surface of the upper flange or a lower surface of a lower flange of the roof frame; a bolt set which includes four support bolts, whose upper side penetrates the roof panel to be exposed to the outdoors and whose lower side is inserted into the upper fastening hole and lower fastening hole; and a sealing cover in a dome shape to have a waterproof layer formed inside and to have a penetrating hole formed on a part of a peak, through which the support bolts pass. Each of the support bolts is successively fastened with a first nut, a second nut, and a third nut. The first nut and the second nut fixate the upper plate and the lower plate on the roof frame. The third nut allows the sealing cover to come in full contact with the roof panel.

Description

Supporting assembly for photovoltaic array

The present invention relates to a solar array support assembly, and more particularly, to a solar array support assembly to prevent the roof panel from being damaged by deformation of the solar array support assembly caused by wind and to improve the durability of the waterproofing site. will be.

Photovoltaic power generation facilities, which are representative of clean energy, have been largely constructed in forests and freshwater lakes in recent years, and recently, construction has been performed on various building structures such as rooftops and roofs of buildings.

In the roof construction of photovoltaic power generation facilities, after fixing the fixing member (hereinafter referred to as 'solar array support assembly') on the part of the roof panel which is folded part of the roof panel or the protruding part of the roof panel having corrugated section, Construction is done by fixing the frame or bracket for mounting the ray (hereinafter referred to as the 'installation member').

However, there is a problem in that the solar array is a heavy load, and in particular, due to the plate-like structure, a strong external force caused by the wind is applied to the solar array support assembly to deform and damage the roof panel.

The module support assembly fixed to the roof support frame disposed below the roof panel for a more robust fixing is introduced in Korea Patent Registration No. 10-1533773 (Registration Date: 2015.06.29.).

As shown in FIG. 1, the conventional technique fixes the fixing bracket or the fixing plate E to the beam 200h, and forms a through hole 200a in the roof panel 200 at an upper portion thereof, and then guide pipes therein. Insert (G).

Next, in the state in which the connecting rod (F) is inserted into the guide pipe (G), while fixing the lower end of the connecting rod (F) to the fixing plate (E) and connecting the installation member on the top, while the guide pipe (G) for the waterproof Construction is made by the process of covering the waterproof cap (J) on.

The prior art is to prevent the roof panel 200 from being damaged during deformation of the connecting rod (F) by the external force by forming a space between the connecting rod (F) and the roof panel 200 through the guide pipe (G). It features.

However, the prior art is to form a through-hole 200a having a large diameter in the roof panel 200, the heat insulation performance of the roof may be reduced by the inflow of cold / warm air through the rain, even though the rain cap through the waterproof cap (J) Inflow can be blocked, but the moisture barrier is limited, so the beam 200h may be corroded.

In addition, the roof panel 200 and the guide pipe (G) and the boundary portion of the roof panel 200 and the waterproof cap (J) is waterproofed using an adhesive such as silicone. In particular, the waterproof portion between the roof panel 200 and the waterproof cap (J) is a repetitive deformation of the waterproof cap (J) by the wind, the adhesive portion is lifted, rainwater may flow into the waterproof space.

In addition, in the construction of the module support assembly, the drilling of the large through-hole 200a and the sealing of the roof panel 200 and the guide pipe G, and the roof panel 200 and the waterproof cap J boundary area are performed. Work is required, and construction is cumbersome.

KR 10-1533773 B1 2015.06.29.

The problem to be solved in the present invention is fixed to the roof frame to prevent damage to the roof panel by the solar array support assembly, the waterproofing of the roof panel penetrating portion is maintained for a long time, easy to install the solar array support assembly To provide.

The solar array support assembly of the present invention for solving the above problems, the upper plate is formed of a rectangular plate material and formed in the upper fastening hole which is a bolt fastening hole in each corner is disposed on the upper flange upper surface of the roof frame; A lower plate formed at a point corresponding to the upper fastening hole, the lower plate being disposed on the lower surface of the upper flange or the lower surface of the lower flange of the roof frame; A bolt set including an upper portion of the support panel having four support bolts inserted into the upper and lower fastening holes and exposed to the outside through the roof panel; And a sealing cover formed in a dome shape and having a waterproof layer formed therein and a through hole for passing the support bolt at a vertex portion, wherein each of the support bolts includes a first nut, a second nut, and a third nut. Nuts are fastened sequentially, the first nut and the second nut is fixed to the upper and lower plates to the roof frame, the third nut is characterized in that the sealing cover is in close contact with the roof panel.

In addition, the solar array support assembly of the present invention is characterized in that the lower plate is composed of a first lower plate and a second lower plate which is fastened to the upper plate in a state arranged on the lower surface of the upper flange.

In addition, the solar array support assembly of the present invention, characterized in that the upper plate or the lower plate is further provided with a pair of protruding end is male and female coupled to the roof frame.

In addition, the solar array support assembly of the present invention, characterized in that the support washer and the spring washer is interposed between the sealing cover and the third nut.

According to the solar array support assembly of the present invention, the roof panel damage is prevented through a bolt set that is fixed to the roof frame up and down on the roof frame and the lower plate is fixed to the upper and lower plates, the roof panel in a state where a waterproof layer is formed therein The waterproof cover of the roof panel penetrating portion is maintained for a long time through the sealing cover in close contact with the sealing cover, and the construction is facilitated through the protruding end, thereby improving the productability of the solar array support assembly according to the present invention.

1 is a schematic diagram showing an installation state of a solar array support assembly according to the prior art.
2 is a perspective view illustrating a solar array support assembly according to the present invention.
3 is a perspective view showing a modified embodiment of the solar array support assembly according to the present invention.
4 is a cross-sectional view of FIG. 3.
Figure 5 is an enlarged front view showing a sealing cover portion of the solar array support assembly according to the present invention.
6 is a front view showing a load relationship acting on the solar array support assembly according to the present invention.
7 is a rear exploded perspective view illustrating a case in which the protruding end is provided in the solar array support assembly according to the present invention.

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

2 is a perspective view showing a solar array support assembly according to the present invention, Figure 3 is a perspective view showing a modified embodiment of the solar array support assembly according to the present invention, Figure 5 is a solar array according to the present invention An enlarged front view of the sealing cover portion of the support assembly.

2, 3 and 5, the present invention is a solar array support assembly which is constructed on a roof consisting of a roof panel (1) and a roof frame (2) of H beam material disposed directly below the roof array (1), the roof The upper plate 10 disposed on the upper flange 2a of the frame 2, the lower plate 20 disposed on the lower flange 2b of the roof frame 2 so as to correspond to the upper plate 10 up and down, the upper plate 10 and the lower plate 20 includes a bolt set 30 to be fixed to the roof frame 2 and a sealing cover 40 provided on the bolt set 30, wherein the protruding end 13 is It is characterized in that it is optionally provided.

Hereinafter, the specific details of the present invention with reference to the above components, first, the upper plate 10 is a configuration for fixing the solar array support assembly to the roof frame 2 together with the lower plate 20, the rectangular The upper fastening hole 11, which is made of a metal plate and is a bolt fastening hole, is formed in each corner.

The lower plate 20 is usually made of a single plate of the same size as the upper plate 10, in which case the lower fastening hole 21 is formed at a point corresponding to the upper fastening hole (11).

However, in some roof frames (2), the distance between the roof frame (2) and the roof panel (1) is too far away, or other installations of the building is disposed directly below the lower flange (2b), the lower flange (2b) When it is difficult to arrange the lower plate 20 in the lower plate 20 may be disclosed as a double plate of the first lower plate 20a and the second lower plate 20b disposed on the lower surface of the upper flange 2a instead of a single plate.

The first lower plate 20a and the second lower plate 20b are made of the same size, and a pair of lower fastening holes 21 'are formed in the longitudinal direction x of the roof frame 2, respectively.

In addition, the bolt is fastened to the upper plate 10 in a state in which the upper flange 2a is inserted at one side, and as shown in FIG. 3, the inclined (β) is inclined due to the thickness of the upper flange 2a, so that the coupling becomes incomplete. In order to prevent this, as shown in FIG. 4, the upper flanges 2a are disposed between the upper plate 10 and both lower plates 20a and 20b by fixing the auxiliary portions 23 to one side of the lower plates 20a and 20b, respectively. ), The tightening work is performed.

As the auxiliary part 23, a plate or a bar of various metal materials having the same thickness as the upper flange 2a may be used.

The bolt set 30 is configured to fix the upper plate 10, the lower plate 20, and the sealing cover 40, and four support bolts 31, 32, 33, inserted into the fastening holes 11 and 21. 34).

A first nut A, a second nut B, and a third nut C are sequentially fastened to each of the support bolts 31, 32, 33, and 34, and the first nut A is the lower plate 20. The second nut (B) is fixed to the roof frame (2) of the upper plate 10 and the lower plate 20 through the tightening in the state arranged on the upper surface of the upper plate (10).

In addition, the third nut (C) is inserted into the support bolts 31, 32, 33, 34 exposed to the upper portion of the roof panel 1 to press the sealing cover 40, the sealing cover 40 is the roof panel ( 1) Make sure that it adheres to the upper surface.

At this time, when the third nut (C) is in direct contact with the sealing cover 40 to press the sealing cover 40 may cause deformation or damage of the sealing cover 40, the upper portion of the sealing cover 40 and the third Preferably, the support washer 51 is interposed between the lower portions of the nuts C, and a spring washer 52 which provides an elastic force in the axial direction of the third nut C to prevent loosening of the third nut C is provided. It is preferable that the support washer 51 and the third nut C are further provided.

The sealing cover 40 forms a waterproof layer 41 therein to seal the perforated portion of the roof panel 1 through which the support bolts 31, 32, 33, and 34 pass. It is made of a metal material having a shape, the through-hole 43 for passing the support bolts (31, 32, 33, 34) is formed in the apex.

The waterproof layer 41 is formed by the support bolts 31, 32, 33, and 34 exposed to the upper part of the roof panel 1, and a sealing cover 40 having a waterproof adhesive around the upper part of the roof panel 1. ) When the inside of the sealing cover is completely filled, apply sufficient amount of excess to the sealing cover, and then tighten the third nut (C) so that the sealing cover 40 adheres to the roof panel 1, and then the waterproof adhesive is applied. Filled in the sealing cover 40 and is formed through a process that is subsequently cured.

Therefore, the waterproof layer 41 is deteriorated by delaying contact with sunlight or rainwater by the sealing cover 40, and repeated bending deformation of the support bolts 31, 32, 33, 34 caused by wind. ) Can also maintain the waterproof function without lifting due to the pressure of the third nut (C) and the sealing cover (40).

Bending load (M) and shear load (S) act on the support bolts (31, 32, 33, 34) by the external force transmitted from the solar array as shown in Figure 5, blowing in an unspecific direction Due to the nature of the wind, the bending load (M) acts on the support bolts 31, 32, 33, 34 in all directions.

When the support bolts 31, 32, 33, and 34 are deflected by the bending load M, bolts penetrating the roof panel 1 may damage the roof panel 1 or the waterproof layer 41. (Hereinafter referred to as 'fouling')

However, in the present invention, fouling is effectively prevented by suppressing the bending deformation θ through the combination of the respective support bolts 31, 32, 33, 34 and the double fixing of the first nut A and the second nut B. do.

For example, as shown in FIG. 6, when an external force is applied in the longitudinal direction x of the roof frame 2, a bending load M acts on the support bolts 31, 32, 33, 34. ) And the fourth bolt 34 to suppress the tensile strain and the first bolt 31 and the second bolt 32 to suppress the compressive strain to minimize the bending strain (θ), this deformation suppression force is due to the characteristics of the bending load The distance between the tension side and the compression side (L) is strengthened the farther.

In addition, each of the support bolts (31, 32, 33, 34) has a cantilever structure protruding upward, the lower portion is bent in the state fixed double to the upper plate 10 and lower plate 20 having a predetermined interval (H) Deformation (θ) is prevented, which also enhances the strain suppression force than when the nut is fixed only in one place.

As described above, in the present invention, the protruding end 13 may be selectively provided, and is provided on the upper plate 10 or the lower plate 20 and has a structure in which a pair is male and female coupled to the roof frame 2.

Hereinafter, assuming that the upper end 10 is provided with a protrusion end 13, the protrusion end 13 is a pair of projections having a semi-circular or wedge shape in plan view as shown in FIG. Each position is provided at the boundary portion between both edges (m, n) of the upper flange (2a) and the lower surface of the upper plate (10a) in close contact with the upper plate (10) and the upper flange (2a).

In addition, a wedge-shaped or semi-circular groove 2c is formed at a point corresponding to the edges m and n of the upper flange 2a, so that the upper plate 10 and the upper flange 2a are protruded from the groove 2c. Stage 13 is male and female coupled.

The protruding end 13 performs a jig function during construction, thereby providing convenience for the alignment of the perforations of the roof panel 1 and the fastening holes 11 and 21.

In addition, after construction also serves to prevent fouling by the shear load (S).

That is, when repeated external force by wind is applied, the bolts of the upper plate 10 and the lower plate 20 may be loosened, and the fixing of the roof frame 2 of the upper plate 10 and the lower plate 20 is loose. When an unspecified shear load (S) is applied, the photovoltaic array support assembly moves finely in the direction of action, and the support bolts 31, 32, 33, and 34 pass through the roof panel 1 due to such fine movement. The pressurization causes fouling, and the male and female coupling structures of the grooves 2c and the protruding end 13 suppress such fine movement.

Although the preferred embodiment of the present invention has been described above, the scope of the present invention is not limited thereto, and it should be understood that the scope of the present invention extends to the range that is substantially equivalent to the embodiment of the present invention. Various modifications can be made by those skilled in the art without departing from the spirit of the invention.

10: tops
11: upper fastening hole 13: protrusion
20: bottom plate
21: lower fastening hole 23: auxiliary part
30: bolt set
31: 1st bolt 32: 2nd bolt
33: 3rd bolt 34: 4th bolt
40: sealing cover
41: waterproof layer 43: through hole
51: support washer 52: spring washer

Claims (4)

In the solar array support assembly fixed to the roof panel (1) and the roof frame (2),
An upper plate (10) formed of a rectangular plate and having upper fastening holes (11) which are bolt fastening holes formed at respective corners, and disposed on an upper surface of the upper flange (2a) of the roof frame (2);
A lower fastening hole 21 is formed at a point corresponding to the upper fastening hole 11, and a lower plate 20 disposed on the lower surface of the upper flange 2a of the roof frame 2 or the lower surface of the lower flange 2b. );
The upper part is exposed to the outdoors through the roof panel 1 and the lower part includes four support bolts 31, 32, 33, and 34 inserted into the upper fastening hole 11 and the lower fastening hole 21. Bolt set 30; And
A sealing cover 40 formed in a dome shape and having a waterproof layer 41 formed therein and a through hole 43 passing through the support bolts 31, 32, 33, and 34 at a vertex;
It is made, including
The first nut A, the second nut B and the third nut C are sequentially fastened to each of the support bolts 31, 32, 33, and 34, and the first nut A and the second nut C are sequentially fastened. Nut (B) is fixed to the upper plate 10 and the lower plate 20 to the roof frame (2), the third nut (C) so that the sealing cover 40 is in close contact with the roof panel (1) Solar array support assembly characterized in that. The method of claim 1,
The lower plate 20 is a solar array support assembly comprising a first lower plate 20a and a second lower plate 20b fastened to the upper plate 10 in a state arranged on a lower surface of the upper flange 2a. . The method of claim 1,
The upper plate 10 or the lower plate 20 is a solar array support assembly, characterized in that it is further provided with a pair of protruding end 13 is male and female coupled to the roof frame (2). The method of claim 1,
The support assembly of claim 3, wherein a support washer (51) and a spring washer (52) are interposed between the third nut and the sealing cover (40).

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