KR102352382B1 - Photovoltaic roof system having simplified electric connecting structure - Google Patents

Abstract

Provided is a solar power roof system which comprises: a plurality of combined insulating blocks of a block form that become an insulating material of a roof of a building; a protruding support bracket inserted into the insulating blocks and having a protrusion protruding upwardly; a coated steel plate made of a plate formed to cover an upper surface of the insulating blocks and the protruding support bracket; a solar panel holder coupled to a position where the protruding support bracket and the coated steel sheet are stacked and having a solar panel seated on an upper surface thereof; and the solar panel that generates electricity with sunlight and is coupled to the upper surface of the solar panel holder.

Description

Photovoltaic roof system having simplified electric connecting structure

The present invention relates to a roof system used in solar power generation.

In general, photovoltaic power generation devices use the light of the sun to produce electricity, and by integrating solar cells that directly convert solar energy into electrical energy in a plate shape, a large amount of electrical energy is produced at the same time, and fossil energy As energy is gradually being depleted, the demand for it is gradually increasing as one of the alternative energy sources.

Such a photovoltaic device is typically installed on the roof or roof of a building where sunlight is irradiated smoothly, and includes a separate support for installation on the roof.

For example, Patent Registration No. 10-1982769 discloses a photovoltaic structure for a roof and a construction method thereof. However, such a conventional method has a problem in terms of reducing the installation cost because many parts are required.

Registered Patent No. 10-1982769 (Registered on May 21, 2019)

Embodiments of the present invention are to provide a photovoltaic roof system formed in a simple structure to replace the conventional photovoltaic structure for a roof.

According to an aspect of the present invention, a plurality of combined form of a block-type insulating block that becomes the insulating material of the roof of the building; a protrusion support bracket inserted into the insulating block and having a protrusion protruding upward; a coated steel plate formed of a plate formed to cover the upper surface of the insulating block and the protruding support bracket; a photovoltaic panel holder coupled to a position in which the protruding support bracket and the coated steel sheet are stacked and mounted on the upper surface of the photovoltaic panel; and a solar panel that generates electricity with sunlight and is coupled to the upper surface of the solar panel holder. A solar power roof system comprising a may be provided.

The photovoltaic power generation roof system according to this embodiment replaces a plurality of frames and a plurality of brackets to install a photovoltaic panel, so that a photovoltaic panel can be installed only by combining a protruding support bracket and a photovoltaic panel holder. can be advantageous in terms of cost.

1 is a perspective view schematically showing a solar power generation roof system according to an embodiment of the present invention.
FIG. 2 is a view showing the heat insulating block shown in FIG. 1 .
3 (a) and (b) are views showing the protruding support bracket shown in FIG.
4 is a view schematically showing the coated steel sheet shown in FIG.
5 is a view schematically showing the solar panel holder shown in FIG.
6 to 8 are views showing the construction of the solar power roof system of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, it should be noted that the following examples are provided to help the understanding of the present invention, and the scope of the present invention is not limited to the following examples. The following embodiments are provided to more completely explain the present invention to those with average knowledge in the relevant technical field, and detailed description for known configurations that may unnecessarily obscure the technical gist of the present invention to be omitted.

1 is a perspective view schematically illustrating a solar power generation roof system according to an embodiment of the present invention.

Referring to FIG. 1 , the solar power generation roof system according to the present embodiment includes a block-type insulation block 100 that is a heat insulator of the roof of a building in a combined form, and is inserted into the insulation block 100 , A protruding support bracket 200 in which a protrusion protruding in the upward direction is formed, and a plate-shaped coated steel plate 300 formed in a form to cover the upper surface of the insulating block 100 and the protruding support bracket 200, A photovoltaic panel holder 400 that is coupled to a position in which the protruding support bracket 200 and the coated steel sheet 300 are stacked and the photovoltaic panel is seated on the upper surface; and a photovoltaic panel 500 that generates electricity with sunlight and is coupled to the upper surface of the photovoltaic panel holder 400 ; may include

The solar power roof system according to this embodiment replaces a plurality of frames and a plurality of brackets in order to install the solar panel 500, so that only the combination of the protruding support bracket 200 and the solar panel holder 400 is provided. Since the optical panel 500 can be installed, it can be advantageous in terms of cost compared to the prior art.

Hereinafter, each configuration shown in FIG. 1 will be described in more detail with reference to the drawings.

FIG. 2 is a view showing the heat insulating block shown in FIG. 1 .

Referring to FIG. 2 , the solar power generation roof system of the present invention may include an insulating block 100 . Insulation block 100 may be formed in a box shape formed with a predetermined volume to prevent heat exchange on the upper side of the roof. The insulating block 100 may have a stepped 100a formed on at least one side thereof. The step 100a may have a shape such as a staircase. A plurality of steps 100a may be formed to form a multi-step shape. In this way, a plurality of heat insulating blocks 100 in which the stepped 100a is formed may be formed by being coupled to each other. At this time, the step 100a of the portion connected to the insulating block 100 may be coupled to each other in a complementary form. Accordingly, the phenomenon of easy separation by loads applied in the upper and lower directions can be prevented.

In addition, the insulating block 100 may be formed with a protruding support bracket groove 111 on one side. The protruding support bracket groove 111 may be a groove in the front and rear of the insulating block 100 having a penetrating shape. Also, the protruding support bracket groove 111 may be a groove in which the upper surface of the heat insulating block 100 is opened. At this time, the size opened to the insulating block 100 by the protruding support bracket groove 111 may be the open width W1. The open width W1 may be formed to be smaller than the insertion portion of the protruding support bracket 200 to be described later. The protruding support bracket groove 111 may be formed in a cross-section in the form of a groove of the upper and lower beams. In addition, the protruding support bracket groove 111 may be formed in a shape corresponding to the protruding support bracket 200 . The protruding support bracket groove 111 may be a groove to which the protruding support bracket 200 is coupled.

In addition, the insulating block 100 may include a coupled partial insulating block (110). The coupling part insulating block 110 may be a part in which the protruding support bracket groove 111 is formed. The coupling partial insulation block 110 may be individually manufactured and coupled to the structure. The insulating block 100 in which the protruding support bracket groove 111 is formed is formed as a part having a different shape from the part where the insulation effect of the roof is formed and can be individually manufactured. In addition, the coupling partial insulating block 110 may be formed in a structure in which the insulating material effect is formed and the insulating block 100 is fitted and complemented with each other. In addition, a flow path space 112 of a predetermined size may be formed between the coupling partial insulating block 110 and the insulating block 100 of the insulating material. The flow path space 112 may be a space in which the head of a bolt bolted to form a coupling between the coupling partial insulating block 110 and the insulating block 100 of the insulating material faces. The coupling partial insulation block 110 may be filled when the protruding support bracket 200 is coupled, so that thermal circulation may not be smoothly formed. Accordingly, the flow path space 112 is formed between the coupling partial heat insulating block 110 and the heat insulating block 100 of the heat insulating material, so that heat circulation can be easily formed. In addition, the head of the bolt applied to the coupling between the coupling partial insulating block 110 and the insulating block 100 of the insulating material may be located. Due to the high risk of exposure by the protruding support bracket 200 that is formed to protrude, the coupling portion insulating block 110 and the protruding support bracket 200 may require maintenance. Accordingly, sufficient space is formed in which the bolting head can be positioned, so that the replacement of the coupling part insulating block 110 and the protruding support bracket 200 can be facilitated.

3 (a) and (b) are views showing the protruding support bracket 200 shown in FIG. 1 .

1 and 3 , the solar power generation roof system of this embodiment may include a protruding support bracket 200 . The protruding support bracket 200 may be a bracket inserted into and coupled to the insulating block 100 .

The protruding support bracket 200 may have an insertion part 210 coupled to the heat insulating block 100 at the lower side thereof. The insertion part 210 may be a part to be inserted into the protruding support bracket groove 111 of the heat insulating block 100 . The insertion part 210 may be formed in the form of an upper and lower light. The shape of the insertion part 210 may be a stacked shape by bending a metal plate to form a predetermined area on the lower side thereof, as shown in FIG. 3A , and bending it in a 'U' shape. In this case, the predetermined area formed on the lower surface of the insertion part 210 may be formed to have a size corresponding to the lower surface of the protruding support bracket groove 111 . In addition, the insertion part 210 may be formed with engaging ends 211 protruding from the left and right sides. The locking end 211 may be formed to protrude from the side surface of the insertion part 210 . The locking end 211 may be formed as a portion supported in contact with the protruding support bracket groove 111 . Such a locking end 211 may be formed in a horizontal form on the left and right sides of the insertion unit 210, but extends to the insertion unit 210 inclined at a predetermined angle to facilitate support for loads applied at various angles. can be formed.

On the other hand, the support part 220 may be formed on the upper side of the protruding support bracket 200 . The support part 220 may be formed to extend in an upper direction of the insertion part 210 . In addition, the size of the support portion 220 extending from the insertion portion 210 may be formed in a width (W2). In this case, the width W2 may be formed to be smaller than the width W1. The upper surface exposed to the support 220 by the difference in the size of the width W2 and the width W1 will be the surface in contact with the coated steel plate 300 to be described later to support the upper portion of the protruding support bracket 200 . can

In addition, the support part 220 may have an end bent to form a support surface 221 . The support surface 221 may be a surface on which the solar panel holder 400 is coupled and supported. The support surface 221 may be bent in a curved shape as shown in (a) of FIG. 3 , but is not limited thereto.

As shown in (b) of FIG. 3 , the support surface 221 may be formed as a curved side of the support part 220 formed by being bent in a 'L' shape. The support surface 221 may be bent in a U' shape so that two parallel ends are stacked. The support surface 221 formed in this way may be a surface supporting the lower side of the solar panel holder 400 .

4 is a view schematically showing the coated steel sheet shown in FIG.

1 and 4, the solar power roof system of this embodiment may include a coated steel sheet.

The coated steel plate 300 may be a plate that covers the upper surface of the insulating block 100 and protects it from external rain or snow. The coated steel sheet 300 may be formed by coating the outside with a painting. In this case, the paint to be applied may be formed of silicone-polyester. The coated steel plate 300 may be formed of a thin plate. The coated steel plate 300 may be formed to overlay the upper portion of the protruding support bracket 200 together with the insulating block 100 . Accordingly, the coated steel plate 300 and the protruding support bracket 200 may be in a stacked form. The coated steel plate 300 and the protruding support bracket 200 stacked in this way may be formed as a rail on which a horizontal surface is formed on the upper surface and the solar panel holder 400 is moved.

In addition, the coated steel sheet 300 may be formed with a bent portion 310 in a bent form. The bent portions 310 may be formed in a plurality of shapes spaced apart from the coated steel sheet 300 at uniform intervals. The bent portion 310 may be a bent portion in the shape of 'П' by bending the coated steel sheet 300 . Such a curved portion 310 may increase the surface area of the coated steel sheet in contact with the air. In addition, the space 311 formed on the lower side according to the shape of the bent portion 310 may be a space through which air flows. Accordingly, heat exchange can be easily formed in the portion where the coated steel plate 300 is installed.

5 is a view schematically showing the solar panel holder shown in FIG.

5 and 1 , the solar discharge roof system of the present embodiment may include a solar panel holder 400 .

The solar panel holder 400 may be formed in an 'H' shape in cross section. The photovoltaic panel holder 400 is based on the connecting end 410 formed to be connected in the lateral direction to the center side forming the 'H' shape, the lower side is the holder support part 420 is formed, and the upper side is the panel coupling part 430. can be formed.

The cradle support 420 may be a portion coupled to the protruding support bracket 200 . The coupling of the cradle support 420 and the protruding support bracket 200 may be coupled in such a way that the protruding support bracket 200 is in contact with the lower surface of the connection end 410 to be supported.

On the other hand, the cradle support 420 may have a shape in which two ends horizontally extending in the downward direction are formed on the left and right sides of the connecting end 410 . At this time, a rolling friction end portion 421 may be formed at the end of the end formed on the left side of the cradle support portion 420 . The rolling friction end portion 421 may be a moving portion in contact with one side of the support portion of the protruding support bracket 200 . The rolling friction end portion 421 may be an end in the form of an inwardly curved end perpendicular to the end extending from the connecting end 410 . The rolling friction end portion 421 may be in contact with the protruding support bracket 200 to be coated with a dissimilar material to facilitate rolling movement. For example, the end of the rolling friction end portion 421 may be coated with a dissimilar material such as a plastic bushing having a low friction force. Accordingly, the movement of the solar panel holder 400 along the path of the protruding support bracket 200 can be easily formed to facilitate positioning of the solar panel 500 .

On the other hand, the support clamping hole 420a may be formed in the cradle support part 420 in the form of penetrating left and right. In the support clamping hole 420a, two bolts may be inserted from the left side and the right side from the outside to the inside. The bolt inserted into the support clamping hole 420a as described above may be fastened to clamp both sides of the surface formed by vertically extending the protruding support bracket 200 and the coated steel plate 300 in a stacked form. Accordingly, the solar panel holder 400 may be fixed to the installation position.

The solar panel holder 400 may have a panel coupling part 430 formed above the connection end 410 .

The panel coupling part 430 may be formed in a form in which two 'a' ends 431 extending vertically in a symmetrical form on the upper side of the connection end 410 face each other on the left and right sides. In this case, a predetermined distance W1 may be formed to be spaced apart between the opposite 'a' ends 431 . The distance W1 spaced apart between the 'a' ends 431 may be formed to have a size corresponding to the size of the screw portion of the bolt inserted and fastened to the solar panel 500 . In addition, the distance W1 spaced apart between the 'a' ends 431 may be formed to be smaller than the head of the bolt inserted and fastened to the solar panel 500 to be caught. The end of the 'a' end 431 may be formed with a bolt contact surface 431a protruding downward to a predetermined size. The bolt contact surface 431a may be a portion in contact with the head of the bolt fastened to the solar panel 500 . The bolt contact surface 431a may be formed as a horizontal surface of a predetermined size and protrude so as to be spaced apart from an end extending in the lateral direction from the 'a' end 431 by a predetermined distance. The bolt contact surface 431a protruded in this way minimizes friction with the bolt head, so that the bolt is loosely fastened to the solar panel 500 and the solar panel holder 400, and then it can be easily moved to a desired position. In addition, the bolt contact surface 431a is a portion where friction with the bolt is formed, and may be coated with a wear-resistant material.

6, 7 and 8 are views showing the construction of the solar power roof system of the present invention.

Referring to FIGS. 6 (a) and 6 (b), first, the insulating block 100, which forms an insulating effect on the roof of a building, may be installed on the roof. After the heat insulating block 100 having a heat insulating effect is disposed at an installation position, the heat insulating block 100 may be installed at a coupling portion where the protruding support bracket groove 111 is formed.

The insulating block 100 may be coupled to the protruding support bracket 200 in an inserted form as shown in FIG. 6 (b). The protruding support bracket 200 may be coupled to the protruding support bracket groove 111 formed in the heat insulating block 100 in an insertion form.

Referring to (a) and (b) of FIG. 7 as a next step, the upper surface of the insulating block 100 to which the protruding support bracket 200 is coupled is covered with a coated steel plate 300 and can be combined. have. The protruding support bracket 200 and the coated steel plate 300 coupled as described above are coupled, and the solar panel holder 400 may be coupled to the protruding portion. The solar panel holder 400 may be guided to a path partitioned by the protruding support bracket 200 and the protruding portion of the coated steel plate 300 to move to the installation position.

Referring to FIGS. 8 (a) and (b), the solar panel 500 may be moved to the installation position in a locked state in which the bolts are fastened to the solar panel holder 400 . At this time, the jammed state may be a state in which the bolts are loosely fastened. The photovoltaic panel 500 seated at the installation position is fixed by fastening the nut at the upper part, so that the installation can be completed.

As described above, the photovoltaic power generation roof system according to the present embodiments is a photovoltaic power generation installed on a conventional roof with a simple coupling structure of the heat insulating block 100 , the protruding support bracket 200 , and the solar panel holder 400 . It can be installed with a simplified structure compared to the system. In particular, the solar power generation roof system of the present embodiments as described above can be advantageous in terms of cost because the number of installation parts is small.

Above, although embodiments of the present invention have been described, those of ordinary skill in the art can add, change, delete or add components within the scope that does not depart from the spirit of the present invention described in the claims. It will be possible to variously modify and change the present invention by, etc., which will also be included within the scope of the present invention.

100: insulation block 100a: step
200: protrusion support bracket 210: insertion part
211: catch end 220: support
300: coated steel plate 310: bent part
400: solar panel holder 410: connection end
420: cradle support part 420a: support part clamping hole
430: panel coupling part 431: 'a' end
500: solar panel

Claims (7)

Insulation block 100 in the form of a block that is a heat insulator of the roof of a building in a combined form;
a protrusion support bracket 200 inserted into the insulating block 100 and having a protrusion protruding upwardly;
a coated steel plate 300 formed of a plate formed to cover the upper surface of the insulating block 100 and the protruding support bracket 200;
a photovoltaic panel holder 400 that is coupled to a position where the protruding support bracket 200 and the coated steel sheet 300 are stacked and the photovoltaic panel is seated on the upper surface; and
A solar panel 500 that generates electricity by sunlight and is coupled to the upper surface of the solar panel holder 400; includes
The insulating block 100 is
At least one side is formed in a stepped step (100a) is formed in a form complementary to each other to form a box shape, and
It includes a combined partial insulation block 110 that is individually manufactured and coupled, and
The coupling partial insulation block 110 is
A protrusion support formed in a shape in which the upper surface of the insulating block 100 is opened with a groove passing through the front and rear, and the opened width W1 of the upper surface is smaller than the insertion portion of the protruding support bracket 200 . bracket groove (111); is formed
a passage space 112 of a predetermined size between the heat insulating block 100 and the coupling; is formed
The flow path space 112 is
The head of the bolt where the coupling between the insulating block 100 and the coupling partial insulating block 110 is formed is directed.
The solar panel holder 400 is
a connection end 410 having a cross-section formed in an 'H' shape to be connected to the center side in the transverse direction;
a cradle support part 420 having two ends extending horizontally in a downward direction from the left and right sides of the connection end 410 to be coupled to the protruding support bracket 200; and
Two 'a' ends 431 extending vertically in a symmetrical form from the left and right sides of the connection end 410 are formed, and the solar panel 500 and the bolt are inserted and fastened as a part. The panel coupling portion 430 is formed; includes
The 'a' end 431 is
A bolt contact surface 431a protruding downward to a predetermined size is formed.
The bolt contact surface 431a is
It is formed as a horizontal surface of a predetermined size and is formed to be spaced a predetermined distance from the end extending in the lateral direction from the 'a' end 431 so that the bolts are loosely attached to the solar panel 500 and the solar panel holder 400 . It is formed to be movable after fastening, and is formed by coating with a wear-resistant material.
The cradle support 420 is
A rolling friction end 421 is formed at the end of the end formed on the left side,
The rolling friction end 421 is
Solar power roof coated with a plastic bushing material that is moved in contact with one side of the support part of the protruding support bracket 200 in the form of an end bent inward in a direction perpendicular to the end extending from the connection end 410 system. delete The method according to claim 1
The protruding support bracket 200 is
an insertion part 210 formed on the lower side and coupled to be inserted into the insulating block 100, formed in the shape of an upper-lower light, and having engaging ends 211 protruding from left and right ends; and
a support part 220 formed on the upper side and formed by bending an iron plate in a shape protruding upward in an 'a' shape toward the upper side of the insertion part 210; A solar power roof system comprising a. The method according to claim 1
The coated steel plate 300 is
A photovoltaic power generation roof having a plurality of curved portions 310 that are arranged in a stacked form on the upper side to cover the insulating block 100 and the protruding support bracket 200 and are spaced apart at uniform intervals to protrude upward. system. delete 4. The method of claim 3
The support 220 and the coated steel sheet 300 are stacked with each other and have a horizontal surface formed on the upper surface of the solar power generation roof system, which is formed as a rail that moves when the solar panel holder 400 is installed. The method according to claim 1
The solar panel holder 400 is
The support clamping hole 420a in the form of penetrating left and right is formed in the holder support 420, and bolts are inserted in the left and right directions, so that the protruding support bracket 200 and the coated steel plate 300 are laminated. A solar power roof system fastened to clamp both sides of the upper and lower extending sides of the shape.

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