KR102129979B1 - Roof mounting bracket for solar module to prevent leakage - Google Patents

Abstract

The present invention relates to a bracket for installing a roof of a solar module for preventing water leakage.
Specifically, when a solar module is installed on the roof top surface, a solar module for preventing water leakage to prevent water leakage from the roof top surface generated by processing one side of the roof by bolts or anchors that are fastened for solid installation It is about the bracket for the roof installation of

Description

Roof mounting bracket for solar module to prevent leakage}

The present invention relates to a bracket for installing a roof of a solar module for preventing water leakage.

Specifically, when a solar module is installed on the roof top surface, a solar module for preventing water leakage to prevent water leakage from the roof top surface caused by processing one side of the roof by bolts or anchors that are fastened for a solid installation It is about the bracket for the roof installation of

In recent years, due to the exhaustion of fossil fuels and the serious environmental pollution resulting therefrom, as a substitute for fossil energy, photovoltaic modules capable of obtaining pollution-free, noiseless and infinite supply energy have been widely used. As the production efficiency is proportional to the area of the light collecting plate used, economic efficiency is greatly reduced when installed on a general site, so it is to be installed on a sloping roof of a large warehouse type building such as a warehouse or a factory.

In addition, because these various warehouse-type buildings are large, they require a lot of construction cost and require insulation, so most of them are built with cheap sandwich panels.

However, in the case of general sandwich panels used for roofs of various warehouse-type buildings, styrofoam is simply formed between the upper and lower thin plates, and the upper plate repeatedly forms the main and protruding parts to reinforce the strength while inducing the flow of rainwater. As it is configured to give, this is not only very weak in strength compared to thickness or volume, but also leaks when the plate is damaged by screws, so it is necessary to firmly install expensive heavy solar modules on the roof of the building made of such sandwich panels without leaking. It must be tricky and cautious.

In addition, a roof panel or an upper sandwich panel is damaged by an anchor or a bolt used for installing the solar module, and leaks may occur as rainwater flows into the crack.

The present applicant intends to propose a bracket structure for installation of a solar module that can prevent this. At this time, the bracket described in this specification is sufficient to be interpreted as a structure connecting heterogeneous structures.

As a related technology, the registered patent publication No. 10-1493967 describes a solar module installation device for a building roof made of sandwich panels.

The above technology relates to a solar module installation device for a building roof made of a sandwich panel, each of which is coupled to a support plate 18 with a front and rear packing 16 interposed between the selected protrusions 14 of the sandwich panel 12, respectively. Through a connecting hole 44 inside the protruding frame 42 protruding from the surface of the top plate 34, a plurality of long connecting pieces 20 are fixed and connected, and a plurality of connecting pieces (at a given position of each supporting plate 18) 22) is coupled and fixed to the direct connection piece 24 through the side portion 52 in contact with the support portion 38 of the support plate 18, and then connect the solar modules 26 between the neighboring left and right connecting pieces 22. By supporting and fixing the support frame 28 with bolts 30 and nuts 32, the solar module 26 has a simple structure and is firmly connected to the sandwich panel 12 having weak strength without leakage. To give.

In addition, Patent No. 10-1403826 discloses a fastener for installing a solar panel on the roof of a prefabricated building.

The above technology is to install a solar panel on the roof of a prefabricated building that allows a simple and robust installation of a solar panel on the top of the roof at a lower cost while constructing to prevent leakage of the roof when the common roof panel is attached. For fasteners.

In addition, Patent Publication No. 10-1498554 describes a fastener for installing a solar panel applied to a prefabricated roof.

The above technology relates to a fastener for installing a solar panel applied to a prefabricated roof that allows a simple and robust installation of a solar panel at a lower cost while constructing a general roof panel to prevent leakage.

In addition, Patent Publication No. 10-2020-0008833 describes a solar module fixing device for a prefabricated roof.

The above technology is possible to install directly on the top of the pre-installed prefabricated roof panel without dismantling the existing old prefabricated roof panel for the installation of the solar module, and by connecting and minimizing the components of the coupling member accordingly Not only can the strength of the supporting force be improved by reducing, but it is also easy to install while greatly reducing the time required for construction by simplifying the process of the work, and it is leaked by rain water through the waterproof structure of the connection part where the bolt is fastened. It relates to a fixed module of a prefabricated roof solar module that can be prevented from occurring.

However, there is a need for a new structure that can make the construction method simpler and improve the watertight effect on water leakage. In addition, it is not limited to the sandwich panel, there is a need for a structure that can be applied to all roofs.

Registered Patent Publication No. 10-1493967 (announced on February 16, 2015) Registered Patent Publication No. 10-1403826 (announced on June 5, 2014) Registered Patent Publication No. 10-1498554 (2015.03.05. announcement) Patent Publication No. 10-2020-0008833 (2020.01.29.)

An object of the present invention is to prevent water leakage from the roof top surface caused by processing one side of the roof by bolts or anchors, etc., which are fastened for a solid installation when installing the solar module on the top surface of the roof, the sun for preventing water leakage It is to provide a bracket for installing the roof of the optical module.

The bracket for installing the roof of the solar module for preventing water leakage according to the present invention was devised to achieve the above-mentioned object,

A fixing member 10 installed on the upper surface of the roof with a predetermined length;

A lower plate 20 installed on the upper surface of the roof using the fixing member 10;

A vertical plate 30 formed in a direction perpendicular to the upper surface of the lower plate 20;

An upper plate 40 formed in a horizontal direction with the lower plate 20 on an upper side of the vertical plate 30; And

The lower module 20, the vertical plate 30 and the upper plate 40 by being moved forward and backward, the solar module installation plate 70 seated on the upper surface of the upper plate 30 and the lower plate 20 It is composed of, including,

The hole formed in the fixing member 10 for coupling with the roof, the hole formed on one side of the lower plate 20, and the hole formed to penetrate in the order of the upper plate 40-vertical plate 30-lower plate 20 By fastening a bolt or an anchor, the water-tightness is improved by not exposing the bolt or anchor to the outside of the solar module mounting plate 70.

At this time, the fixing member 10,

A fixed plate (11) having a predetermined length, which is in surface contact with the roof and fastened by bolts or anchors, and the like.

It characterized in that it comprises an intermittent plate 12 formed to have a predetermined height in a direction perpendicular to one end of the fixed plate (11).

In addition, the lower plate 20,

A guide groove 21 formed in a longitudinal direction on one side of the lower surface of the lower plate 20 and having a predetermined depth,

It is characterized in that the airtight groove 22 having one side open in a circular shape is formed at an end of the lower plate 20.

In addition, the hermetic groove 22,

It is characterized in that it is formed on both side end portions or both side end portions and the rear end portion of the lower plate 20.

In addition, the airtight member 22 is inserted into the airtight member 50,

The hermetic member 50,

It includes a body 51 having a length corresponding to the hermetic groove 22, and a pressing layer 52 of a flexible material formed on the outer surface of the body 51,

A through hole 51a formed in the longitudinal direction is formed inside the body,

In the through hole (51a),

It characterized in that the airtight member moving means 60 formed longer than the length of the airtight member 50 is inserted.

In addition, the hermetic member 50,

After the airtight member moving means 60 is inserted into the through-hole 51a of the airtight member 50, it is rolled using both ends exposed from the airtight member 50 and inserted into the airtight groove 22 by force fitting. It is characterized by.

According to the bracket for installing a roof of a solar module for preventing water leakage according to the present invention, when installing the solar module on the upper surface of the roof, the roof is generated by processing one side of the roof by bolts or anchors, etc., which are fastened for solid installation. Leakage can be prevented.

1 shows a bracket for installing a roof of a solar module for preventing water leakage according to the present invention.
Figure 2 shows the configuration of the airtight member of the roof mounting bracket of the solar module for preventing leakage according to the present invention.
3 and 4 show an example in which a bracket for installing a roof of a solar module for preventing water leakage according to the present invention is installed on the roof.

The terms or words used in the present specification and claims should not be construed as being limited to ordinary or lexical meanings, and the inventor can appropriately define the concept of terms to describe his or her invention in the best way. Based on the principles, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the examples shown in the embodiments and drawings described herein are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, and various equivalents can be substituted at the time of the application. It should be understood that there may be water and variations.

Hereinafter, prior to the description with reference to the drawings, not necessary for revealing the gist of the present invention, that is, a well-known configuration that can be added by those of ordinary skill in the art will not be shown or not specifically described Well, reveal the notes.

The present invention relates to a bracket for installing a roof of a solar module for preventing water leakage.

Specifically, when a solar module is installed on the roof top surface, a solar module for preventing water leakage to prevent water leakage from the roof top surface caused by processing one side of the roof by bolts or anchors that are fastened for a solid installation It is about the bracket for the roof installation of

1 shows a bracket for installing a roof of a solar module for preventing water leakage according to the present invention.

The present invention according to Figure 1 of the accompanying drawings, the fixing member 10; Bottom plate 20; Vertical plate 30; Top 40; Basic member 50; Airtight member moving means 60; And a solar module mounting plate 70.

First, the fixing member 10 is a structure that is installed on the upper surface of the roof, having a predetermined length, fixed to the roof 11 is fixed and fixed by a bolt or anchor, etc. on the roof, and the fixed plate 11 It includes an intermittent plate 12 formed to have a predetermined height in a direction perpendicular to one end of the.

At this time, the height of the intermittent plate 12 may be formed by a height up to the upper plate 40 to be described later or a height up to the solar module installation plate 70.

In addition, the lower plate 20 may be formed with a guide groove 21 having a predetermined depth and having a predetermined depth on one side of the lower surface, and an airtight groove 22 having an open side at one end in a circular shape. have.

At this time, the guide groove 21 is formed to correspond to the position and size of the fixing plate 11 of the fixing member 10, when the fixing member 10 is composed of two as shown in Figure 1, guide groove ( 21) It can consist of two. That is, when the fixing member 10 has a number exceeding two, the guide groove 21 also has a number corresponding to the number exceeding two.

In addition, the hermetic groove 22 may be formed on both side ends of the lower plate 20 if different from FIG. 1. However, depending on design conditions, when the left side of FIG. 1 is referred to as the front, the airtight groove 22 may be formed in a circular shape with an open shape in the end direction. The airtight member 50, which will be described later, is inserted into and fixed to the airtight groove 22, so that the airtight member 50 can also be inserted into the airtight groove 22 formed at the rear of the lower plate 20 described above.

In this case, the length of the rear airtight groove 22 is shorter than that of the airtight groove 22 in both side ends, or by shortening only the airtight grooves 22 in both side end directions, thereby allowing the airtight groove 22 in three sides. Will be able to form.

A plurality of through-holes arranged on one side of the upper surface of the lower plate 20 described above may be formed to penetrate a bolt or an anchor so that the roof and the lower plate 20 are coupled.

That is, the lower plate 20 also has its lower surface directly contacting the roof together with the fixing member 10.

The vertical plate 30 extends from the central side of the lower plate 20 in the longitudinal direction of the lower plate 20, and is formed to have a vertical direction from the lower plate 20.

An upper plate 40 having a horizontal direction with respect to the lower plate 20 is formed above the vertical plate 30.

The upper plate 40 is formed with a plurality of through holes arranged on one side of the vertical plate 30, the through hole of the upper plate 40 is an upper plate 40-vertical plate 30-lower plate 20 ).

Bolts or anchors, etc., are also penetrated into these through-holes to make the coupling with the roof more robust.

The solar module installation plate 70 is coupled to a structure including the lower plate 20, the vertical plate 30, and the upper plate 40 (in this case, the structure may be integrally configured). The solar tube module mounting plate 70, by using any method that can be predicted by a person skilled in the art to install a conventionally disclosed solar module.

The solar tube module installation plate 70 is slided from rear to front based on the above-mentioned rear and front, and is coupled to a structure including the lower plate, the vertical plate, and the upper plate, wherein the solar tube module installation plate ( Even if a hole is drilled and a bolt or an anchor is fastened to join the solar module to 70), it is not directly fastened to the roof, and thus it is possible to prevent water from leaking to the roof even when rainwater enters.

In addition, as the solar tube module installation plate 70 blocks through holes formed in the lower plate 20 and through holes formed in the upper plate-vertical plate-lower plate, holes or grooves may be formed by bolts or anchors penetrated into the roof. Even if formed, leakage can be prevented.

To this end, the solar tube module installation plate 70 may be formed in the longitudinal direction, the second guide groove 71 corresponding to the vertical plate 30 and the top plate 40.

That is, the lower surface of the solar tube module installation plate 70 is seated on the upper surface of the lower plate 20, and the uppermost inner surface of the second guide groove 71 is mounted on the upper surface of the upper plate 40.

The solar tube module installation plate 70 slided and seated in this way is intermittently prevented from moving further forward by the intermittent plate 12 of the fixing member 10.

In addition, after the lower plate 20, the vertical plate 30 and the upper plate 40 are also coupled to the fixing plate 10 of the fixing member 10, they may be intermittently prevented from moving further forward.

The strength for the interruption of the intermittent plate 12 may be achieved by increasing the number of the fixing members 10 as described above.

In the above-described structure, watertightness can be maintained from rainwater or water sprayed in the falling direction, but airtightness from rainwater or water falling on the roof cannot be guaranteed.

Therefore, the airtight member 50 is inserted into the airtight groove 22 described above to improve airtightness.

The airtight member 50 will be described with reference to FIG. 2 of the accompanying drawings.

Figure 2 shows the configuration of the airtight member of the bracket for mounting the roof of the solar module for preventing water leakage according to the present invention, showing the airtight member (a) according to one embodiment and the airtight member (b) according to another embodiment Doing.

The airtight member 50 of one embodiment according to (a) of FIG. 2 of the accompanying drawings has a body 51 having a length corresponding to the airtight groove 22, and is formed in a longitudinal direction inside the body. The through hole 51a is formed.

In addition, a pressing layer 52 having a flexible material (eg, silicon) may be formed on the outer surface of the main body 51. In other words, a through hole is formed inside the pressing layer 52, and the main body 51 is positioned in the through hole.

The airtight member 50 is inserted into the airtight groove 22 through the airtight member moving means 60 having a rod shape. The hermetic member moving means 60 has an outer diameter corresponding to the inner diameter of the through hole 51a, and is inserted to penetrate the through hole 51a in the longitudinal direction. At this time, the airtight member moving means 60 is formed to have a longer length than the airtight member 50, so that both ends can be exposed after being inserted into the airtight member 50.

Accordingly, by holding and rolling both ends of the exposed airtight member moving means 60, the airtight member 50 is rolled into an open circular airtight groove 22, forcibly fitted to join.

Thereafter, the airtight member moving means 60 is removed.

In this case, the through-hole 51a of the hermetic member 50 is in a hollow state, and accordingly, even when the amount of rainwater is high in rainy weather, it serves as a flow path through which rainwater does not stagnate and can be discharged. In addition, after the pressing layer 52 is inserted into the hermetic groove 22, the hermeticity is improved by being pressed by a load, thereby preventing rainwater from flowing into the lower surface of the lower plate 20.

On the other hand, according to (b) of FIG. 2, the hollow is included between the main body 51 and the pressing layer 52.

That is, the outer diameter of the body 51 is formed smaller than the inner diameter of the through hole of the pressing layer 52.

At this time, the insertion groove 52a is formed on one side of the inner surface of the pressing layer 52, but the insertion groove 52a extends in the longitudinal direction of the pressing layer 52 so that both ends have an open shape. In addition, four insertion grooves 52a may be formed in a symmetrical direction as illustrated.

The guide plate (G) is inserted into the insertion groove (52a), the guide plate (G) is also extended in the longitudinal direction corresponding to the length of the insertion groove (52a).

And the spring (S) may be coupled to one surface of the guide plate (G) with an adhesive, a bolt, etc., the spring (S) may be arranged in a plurality of lines with respect to one guide plate (G).

Each of these springs S is formed to be coupled to the outer surface of the body 51 with an adhesive, a bolt, or the like.

Therefore, the pressing layer 52 slides from the main body 51 to which the spring S and the guide plate G are coupled, so that the guide plate G is inserted into the insertion groove 52a to be coupled. .

By having the above-described structure, the pressing action of the pressing layer 52a can be further improved to further improve airtightness, and a flow path through which rainwater is discharged can be further formed.

At this time, in order to prevent the spring from rusting by contact with rainwater, a material that prevents rusting of the spring material may be employed, or a rust-preventing coating may be pretreated.

In addition, even if there is a fluctuation in the load in the above-described structure described as a solar module or a bracket according to the present invention due to repetition such as snow melting and melting in the solar module due to snow, the spring (S) Since it can be adjusted, it also has a great effect on improving durability and airtightness. If the pressed layer 52 is pressed and is not restored due to the large amount of snowfall, a moxibustion occurs between the pressed layer 52 and the roof top surface, and there is a fear that airtightness may be weakened.

As described above, the preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the embodiments described above is common knowledge in the art. It is obvious to those who have.

Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and can be changed within the scope of the appended claims and their equivalents.

10: fixing member
11: fixed plate
12: intermittent plate
20: bottom
21: guide home
22: confidential home
30: vertical plate
40: top
50: airtight member
51: main body
51a: Through hole
52: pressing layer
52a: Insertion groove
60: airtight member moving means
70: solar module installation plate
71: 2nd guide home

Claims (6)

A fixing member 10 installed on the upper surface of the roof with a predetermined length;
A lower plate 20 installed on the upper surface of the roof using the fixing member 10;
A vertical plate 30 formed in a direction perpendicular to the upper surface of the lower plate 20;
An upper plate 40 formed in a horizontal direction with the lower plate 20 on an upper side of the vertical plate 30; And
The lower module 20, the vertical plate 30 and the upper plate 40 by being moved forward and backward, the solar module installation plate 70 seated on the upper surface of the lower plate 20 and the upper plate 30 It is composed of, including,
The hole formed in the fixing member 10 for coupling with the roof, the hole formed on one side of the lower plate 20, and the hole formed to penetrate through in the order of the upper plate 40-vertical plate 30-lower plate 20 By tightening a bolt or anchor, the watertightness is improved by not exposing the bolt or anchor to the outside of the solar module mounting plate 70;
The lower plate 20,
A guide groove 21 formed in a longitudinal direction on one side of the lower surface of the lower plate 20 and having a predetermined depth,
A bracket for roof installation of a solar module for preventing water leakage, characterized in that an airtight groove (22) having an open side is formed in a circular shape at an end of the lower plate (20).
The method according to claim 1,
The fixing member 10,
A fixed plate (11) having a predetermined length, which is in surface contact with the roof and fastened by bolts or anchors,
It characterized in that it comprises an intermittent plate (12) formed to have a predetermined height in a direction perpendicular to one end of the fixed plate (11), the roof mounting bracket of the solar module for preventing leakage.
The method according to claim 1,
The confidential groove 22,
The bracket for roof installation of the solar module for preventing water leakage, characterized in that formed on both side ends or both side ends and the rear end of the lower plate (20).
The method according to claim 1,
The airtight groove 22, the airtight member 50 is inserted,
The hermetic member 50,
It includes a body 51 having a length corresponding to the hermetic groove 22, and a pressing layer 52 of a flexible material formed on the outer surface of the body 51,
A through hole 51a formed in the longitudinal direction is formed inside the body,
In the through hole (51a),
It characterized in that the airtight member moving means 60 formed longer than the length of the airtight member 50 is inserted, the roof mounting bracket of the solar module for preventing water leakage.
The method according to claim 4,
The hermetic member 50,
After the airtight member moving means 60 is inserted into the through hole 51a of the airtight member 50, it is rolled using both ends exposed from the airtight member 50 and inserted into the airtight groove 22 by force fitting. Characterized in that, the roof mounting bracket of the solar module to prevent water leakage.
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