KR102600895B1 - Clamp for roof-integrated solar power generation - Google Patents

Abstract

The roof-integrated solar power generation clamp 100 according to the present invention includes a first frame 110, a second frame 120, a connecting frame 130, and a spring member 140. The first frame 110 has a shape corresponding to the shape of the solar roof panel and includes a pair of first fastening parts (112) that surround a part of the solar roof panel and a first fastening hole (117). 116). The second frame 120 includes a support portion 122 in which a through hole is formed in the center. A pair of fastening holes 127 are formed at a position corresponding to the first fastening hole 117 of the first fastening part 116 and have a second fastening hole 127 for bolting together with the first fastening hole 117. 2 Includes a fastening portion 126. The connection frame 130 is located in the space between the support part 122 and the clamp part 112 and is a support structure for supporting an empty cylindrical insertion tube 132 with a closed top and an open bottom and a solar module. It includes a connection portion 136 in which a coupling hole 137 for bolting is formed. A spring member 140 is inserted into the insertion tube, the upper end of which contacts the bottom of the insertion tube, and the lower end of which contacts the upper surface of the clamp unit.

Description

Clamp for roof-integrated solar power generation}

The present invention relates to a clamp for roof-integrated solar power generation, and more specifically, to a clamp for roof-integrated solar power generation for connecting a panel installed on the roof of a building and a solar power structure in order to install a solar power structure on the roof of a building. It's about.

Recently, technology has been actively developed to install solar modules on the roofs of buildings and use the energy obtained from the solar modules.

When constructing a building, the roof body must be installed with a focus on several elements that can largely insulate, sound absorb, block water leaks, and increase bearing capacity. Mainly, fillers such as polyester wool, which has high insulating and sound absorbing properties, or Claswool, an inorganic insulating material, are used on steel plates. The roof panels located in between are laid side by side and the ends of each roof panel are connected to each other for construction.

However, when constructing the roof of such a building, there is a disadvantage that water leakage occurs at the fastening area of the bolts used to secure the roof panel. In addition, in the case of existing buildings, in order to install a solar structure on the roof, a clamp is bolted to the roof panel (aka sandwich panel), a support structure such as C fluorescent light is coupled to the clamp, and a solar module is attached to the support structure. will be installed. However, when bolting a clamp to a roof panel, there is a problem that the fastening area is exposed and water leaks occur.

Therefore, taking this into account, for example, bolts between roof panels, such as the roof panel disclosed in Registered Patent Publication No. 10-1322690 or the roof panel manufactured and sold by the present applicant (homepage http://www.wp-pv.com) A roof panel with no exposed fastening area (so-called 'roof-integrated panel') is installed on the roof panel of an existing building, and a clamp such as the following prior art, Patent Registration No. 10-1530576, is installed on the protrusion, which is the connection part of the roof-integrated panel. become combined. When installing a solar structure in a new building, a roof-integrated panel can be applied to the roof from the beginning.

The clamp of prior art No. 10-1530576 as shown in FIGS. 1 to 3 includes a first fixing member 20, a second fixing member 30, and a bracket 60.

The first fixing member 20 has a first gripping part 21 formed at the lower end that hangs on one end of the assembly piece 15, which is a protrusion of the solar roof panel 10, and holds the assembly piece 15, and is positioned in the middle in a vertical direction. As it is formed, a first body portion 22 having a plurality of fastening holes 23 is formed, and a first body portion 22 is formed at the upper end of the first body portion 22 in the direction from the first body portion 22 to the second fixing member 30. 1 A protrusion 24 is formed to protrude.

The second fixing member 30 is formed at the lower part of the second holding part 31, which hangs on the other end of the assembly piece 15 of the solar roof panel 10 and holds it, and is formed in the vertical direction in the middle part. A second body 32 having a plurality of fastening holes 33 is formed, and a second protrusion 34 is formed on the upper part of the second body 32 to protrude in the direction of the first fixing member 20. .

With the solar roof panel 10 installed on the roof, first, on the ground, the fastening hole 23 of the first fixing member 20 and the fastening hole 33 of the second fixing member 30 are connected with the fastening bolt 40. After passing, the fastening nut (41) is screwed in a provisionally fastened state. That is, the first fixing member 20 and the second fixing member 30 are in a tentatively coupled state. After that, the worker carries the temporarily coupled first fixing member 20 and the second fixing member 30 up to the roof and holds the temporarily coupled first fixing member 20 and the second fixing member 30 at an appropriate position on the solar roof panel 10. After positioning the fixing member 30, the fastening bolt 40 and the fastening nut 41 are tightened to completely couple and firmly fix the fastener.

Thereafter, the worker inserts the bracket fixing bolt 50 into the fixing groove 38 formed in the upper center of the roof body 37 of the second fixing member 30 and places it on the horizontal surface of the 'L' shaped bracket 60. After inserting the formed groove 61 into the bracket fixing bolt 50, the fastening nut 51 is fastened and tightened to firmly fix it. Meanwhile, a groove 62 is formed on the vertical surface of the bracket 60 for bolting a support structure such as a C-beam 70 for fixing the solar module. Therefore, as shown in FIG. 3, a support structure such as a C-beam 70 is coupled through the groove 62. A solar module can be directly coupled to the C-beam 70, or a separate inclined support may be used. The member may be coupled to the C-beam 70 in the height direction, and the solar module may be coupled to the inclined support member.

However, in the case of this prior art, two fastening bolts 40 and nuts 41 are fastened to couple the first fixing member 20 and the second fixing member 30 to the solar roof panel 10, and 2 In order to fasten the fixing member 30 and the bracket 60, one fixing bolt 50 and a fastening nut 51 must be fastened, so a total of three bolts and nuts must be fastened. Here, at least hundreds to thousands of clamps (the first fixing member 20 and the second fixing member 30) are usually required to be fastened in a single workshop, so fastening of bolts and nuts takes excessive time and requires a lot of work from workers. As fatigue increases and ultimately leads to a decrease in productivity, improvement is required.

In addition, since the clamp and the photovoltaic structure connected to it do not have a separate structure to buffer vibration in the event of an earthquake, there is a problem that damage or damage may increase in the event of an earthquake or vibration.

The following prior art registration patent publication No. 10-2003883 discloses a roof assembly for earthquake-resistant reinforcement, and registration patent registration no. 10-2076511 discloses a building-integrated solar power generation roof with earthquake resistance function. These prior arts As it is applied to roof assemblies and building-integrated solar power generation roofs, it is difficult to apply it to clamps for connecting solar structures to roof panels installed on the roofs of general buildings, and its structure is also complicated.

Registered Patent Publication No. 10-1530576 (announced on June 23, 2015) Registered Patent Publication No. 10-2003883 (announced on July 25, 2019) Registered Patent Publication No. 10-2076511 (announced on February 13, 2020)

The present invention was developed in consideration of the above points, and simplifies the structure of the clamp for combining the roof-integrated panel and the solar structure, thereby shortening the time required for tightening the bolts and nuts for the connection. In addition, the purpose is to provide a roof-integrated solar power generation clamp that has an earthquake-resistant function.

The clamp for roof-integrated solar power generation according to the present invention for achieving the above object has a shape corresponding to the shape of the solar roof panel, a tong part surrounding a part of the solar roof panel, and a clamp part in the upper vertical direction from the tong part. A first frame that extends and includes a pair of first fastening parts in which first fastening holes are formed; A support portion having a through hole formed in the center, and extending vertically downward from the support portion to face the pair of first fastening portions, is formed at a position corresponding to the first fastening hole of the first fastening portion, and is formed at a position corresponding to the first fastening hole of the first fastening portion. A second frame including a pair of second fastening parts in which second fastening holes for bolting, such as fastening holes, are formed; And, an empty cylindrical insertion tube with a closed top and an open bottom, located in the space between the support part and the clamp part, and extending upward from the insertion tube and passing through a through hole of the support part, A support structure for supporting the optical module includes a connection frame including a connection portion in which a coupling hole for bolting is formed. Here, the upper end of the insertion tube of the connection frame is larger than the diameter of the through hole of the second frame and cannot pass through the through hole, and inside the insertion tube, the upper end contacts the bottom of the insertion tube and the lower end of the clamp part. A spring member in contact with the upper surface is inserted.

The clamp portion of the first frame is such that the pair of first fastening portions extend upward from both sides and correspond to a horizontal portion in contact with the lower end of the spring member, and a shape of the solar roof panel from below both ends of the horizontal portion. It has an inclined portion that extends obliquely or curvedly, and the lower end of the second fastening portion of the second frame contacts the top of the horizontal portion of the tongs, and the first fastening portion of the first frame has a shorter length than the second fastening portion. It may not contact the support portion of the second frame.

In addition, a panel coupling hole for bolting to the solar roof panel is formed in the clamp portion of the first frame, and a waterproof pad may be attached to the bottom of the clamp portion.

According to the present invention, the insertion tube of the connection frame is positioned in the space between the first frame and the second frame so that it does not fall out, and a spring member for absorbing or buffering vibration is inserted into the space, and a C-beam and a C-beam are placed at the connection part of the connection frame. By combining the same support structure, another bolt and nut fastening process for connecting the bracket for fastening the conventional support structure such as C-beam to the clamp (first fastening member and second fastening member) can be eliminated, ultimately This has the effect of shortening working hours and increasing productivity, while also allowing the solar structure to have an earthquake-resistant function.

In addition, according to the present invention, the clamp is divided into a lower first frame and an upper second frame, the second frame has a fixed shape, and the first frame has various shapes corresponding to the shape of the solar roof panel. , since only the first frame needs to be replaced to suit the working environment in which the solar structure is to be installed, installation costs can ultimately be reduced, thereby improving productivity.

1 to 3 are diagrams showing the structure and installation state of a roof-integrated solar power generation clamp according to the prior art;
Figure 4 is a perspective view of a combined roof-integrated solar power generation clamp according to an embodiment of the present invention;
Figure 5 is an exploded perspective view of Figure 4.
Figure 6 is a front view of Figure 4;
Figure 7 is a side view of Figure 4;
Figure 8 is a cross-sectional view of Figure 6;
Figure 9 is an enlarged view of the first frame of Figure 4;
Figure 10 is an enlarged view of the second frame of Figure 4;
Figure 11 is a diagram showing a first frame of a clamp for roof-integrated solar power generation according to another embodiment of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a clamp for roof-integrated solar power generation according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Here, roof-integrated solar power generation means that a panel is installed on the roof of a building, and a solar structure including a solar module and a support structure (for example, C-beam steel) supporting the solar module is installed on the roof panel of the building. The clamp serves to connect and support the solar structure to the roof panel. Meanwhile, a roof panel may refer to a panel installed on the roof of an existing building, or it may refer to a so-called roof-integrated panel in which bolt fastening areas are not exposed between panels installed on the panel installed on the roof of a standard building.

4 to 8, the roof-integrated solar power generation clamp 100 according to an embodiment of the present invention includes a first frame 110, a second frame 120, a connecting frame 130, and a spring member. Includes (140).

Referring to FIGS. 4 to 9 , the first frame 110 includes a clamp portion 112 and a pair of first fastening portions 116.

The clamp portion 112 has a shape that corresponds to the shape of the solar roof panel and surrounds a portion of the solar roof panel. Specifically, the tongs 112 include a horizontal plate-shaped horizontal portion 113 and inclined portions 115 extending obliquely from below both ends of the horizontal portion 113. Here, the inclined portion 115 may have various shapes corresponding to the shape of the solar roof panel (see Figure 11).

In addition, in one embodiment of the present invention, in order to strengthen the coupling force between the clamp and the solar roof according to the embodiment of the present invention, the horizontal portion 113 of the clamp portion 112 is provided with a panel coupling hole for bolting to the solar roof panel. (114) may be formed, but if the coupling force between the clamp and the solar roof panel is strong, the panel coupling hole may be omitted.

In addition, a waterproof pad (not shown) can be attached to the bottom of the clamp portion 112, making it possible to perform a waterproofing function at the fastening portion according to bolt fastening of the panel coupling hole 114.

The first fastening part 116 has a plate shape extending vertically upward from the tongs 112, and a first fastening hole 117 is formed. The pair of first fastening parts 116 are formed to be spaced apart from each other by a predetermined distance, and the pair of first fastening parts 116 extend upward from both sides of the tongs 112. In addition, according to this embodiment, two first fastening holes 117 are formed in each first fastening part 116, but the present invention is not limited to this and one or more than two first fastening holes 117 can be formed. You can.

4 to 8 and 10, the second frame 120 includes a support portion 122 and a pair of second fastening portions 126.

The support portion 122 has a horizontal plate shape and a through hole 123 is formed in the center.

The second fastening part 126 has a plate shape extending vertically downward from the support part 122 to face the first fastening part 116 of the first frame 110. In addition, the second fastening part 126 is formed with a second fastening hole 127 formed at a position corresponding to the first fastening hole 117 of the first fastening part 116. Accordingly, the second fastening hole 127 is bolted together with the first fastening hole 117, and thus the first frame 110 and the second frame 120 can be firmly coupled.

Referring to FIGS. 4 to 8 , the connection frame 130 includes an insertion tube 132 and a connection portion 136.

The insertion tube 132 is located in a space formed by the first fastening part 116 of the first frame 110 and the second fastening part 126 of the second frame 120, and the upper end is closed and the lower end is closed. It has a cylindrical structure with an open interior.

The connection portion 136 extends from the insertion tube 132 to the top and passes through the through hole 123 of the support portion 122 of the second frame 120. Meanwhile, a coupling hole 137 is formed in the connection portion 136, and a support structure such as a C-beam steel for supporting the solar module is bolted to this coupling hole 137.

Then, a spring member 140 is inserted into the insertion tube 132. The upper end of the spring member 140 is in contact with the upper end of the insertion tube 132, and the lower end of the spring member 140 is connected to the first frame ( It contacts the horizontal portion 113 of the clamp portion 112 of 110. This spring member 140 functions to buffer or absorb vibration when vibration occurs in the building.

As shown, the upper end of the insertion tube 132 is larger than the diameter of the through hole 123 of the support part 122, so it cannot pass through the through hole 123, so the insertion tube 132 is connected to the first frame. It is located in the space between the clamp portion 112 of (110) and the support portion 122 of the second frame 120.

In addition, the lower end of the second fastening portion 126 of the second frame 120 contacts the upper end of the horizontal portion 113 of the clamp portion 112 of the first frame 110. ) of the first fastening part 116 is shorter than the second fastening part 126 and does not contact the support part 122 of the second frame 120.

Therefore, both ends of the spring member 140 are not fixed and only the ends of the second fastening portion 126 of the second frame 120 come into contact with the clamp portion 112 of the first frame 110, causing vibration in the building. When vibration occurs, the spring member 140 can effectively buffer or absorb the vibration.

Figure 11 shows the first frame 210 of a clamp for roof-integrated solar power generation according to another embodiment of the present invention. The first frame 210 according to another embodiment of the present invention is similar to the previous embodiment. Like the first frame 110, it is provided with a clamp part 212 and a first fastening part 216. Here, the shape of the first fastening part 216 is the same as that of the first fastening part of one embodiment, but the shape of the tongs 212 is different from that of the tongs of one embodiment. This difference is due to the fact that the tongs are solar as described above. This is because it may vary depending on the shape of the roof panel.

Specifically, the tongs 212 include a horizontal plate-shaped horizontal portion 213 and an inclined portion 215 that extends obliquely from below both ends of the horizontal portion 213 and has curved ends. And, the first fastening part 216 has a plate shape extending vertically from the tongs 212 to the top, and a first fastening hole 217 is formed.

According to the present invention, the insertion tube of the connection frame is positioned in the space between the first frame and the second frame so that it does not fall out, and a spring member for absorbing or buffering vibration is inserted into the space, and a C-beam and a C-beam are placed at the connection part of the connection frame. By combining the same support structures, another bolt and nut fastening process for fastening a bracket for fastening a support structure such as a conventional C-beam to a clamp (first fastening member and second fastening member) can be eliminated, Ultimately, this has the effect of shortening work hours, increasing productivity, and at the same time enabling the solar structure to have an earthquake-resistant function.

In addition, according to the present invention, the clamp is divided into a lower first frame and an upper second frame, the second frame has a fixed shape, and the first frame has various shapes corresponding to the shape of the solar roof panel. , since only the first frame needs to be replaced to suit the working environment of the solar roof panel where the solar structure is to be installed, this ultimately has the effect of reducing equipment costs and improving productivity.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to the specific embodiments described above. In other words, a person skilled in the art to which the present invention pertains can make numerous changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications can be made. Equivalents should also be considered to fall within the scope of the present invention.

100. Roof-integrated solar power generation clamp 110,210. 1st frame
112, 212. Clamp part 113, 213. Horizontal part
116, 216. First fastening part 117, 217. First fastening hole
120. Second frame 122. Support part
123. Through hole 126. Second fastening part
127. Second fastening hole 130. Connection frame
132. Insertion tube 136. Connection part
137. Coupling hole 140. Spring member

Claims (3)

It has a shape corresponding to the shape of the solar roof panel, and includes a tong part that surrounds a part of the solar roof panel, and a pair of first fastening parts extending vertically from the tong part to the upper part and forming a first fastening hole. first frame;
A support portion having a through hole formed in the center, and extending vertically downward from the support portion to face the pair of first fastening portions, is formed at a position corresponding to the first fastening hole of the first fastening portion, and is formed at a position corresponding to the first fastening hole of the first fastening portion. A second frame including a pair of second fastening parts in which second fastening holes for bolting, such as fastening holes, are formed; and,
A cylindrical insertion tube located in the space between the support part and the clamp part and having an empty interior with a closed top and an open bottom, and extending upward from the insertion tube and passing through a through hole of the support part, the solar module. A support structure for supporting a connection frame including a connection portion in which a coupling hole for bolting is formed,
The upper end of the insertion tube of the connection frame is larger than the diameter of the through hole of the second frame and cannot pass through the through hole, and inside the insertion tube, the upper end contacts the bottom of the insertion tube and the lower end touches the upper surface of the clamp unit. A spring member in contact is inserted,
The clamp portion of the first frame is such that the pair of first fastening portions extend upward from both sides and correspond to a horizontal portion in contact with the lower end of the spring member, and a shape of the solar roof panel from below both ends of the horizontal portion. It has an inclined portion that extends inclinedly or curvedly,
The lower end of the second fastening part of the second frame contacts the upper end of the horizontal part of the tongs, and the first fastening part of the first frame is shorter than the second fastening part and does not contact the support part of the second frame. Features a roof-integrated solar power generation clamp.
delete According to claim 1,
A panel coupling hole for bolting to the solar roof panel is formed in the clamp portion of the first frame,
A roof-integrated solar power generation clamp, characterized in that a waterproof pad is attached to the bottom of the clamp portion.

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