KR101971726B1 - Sunlight Module Array Mounting System Mounted On Rooftop Provided With Reinforced Part - Google Patents

Abstract

The present invention relates to a roof-installed solar module array installation system with a reinforcing part for preventing railing damage due to an external force, which comprises: a solar module (110) receiving sunlight to generate power; a support plate (120) having the solar module (110) attached thereto; a column (130) mounted on a lower surface of the support plate (120) to rotate; a frame (140) having a lower end of the column (130) fixed thereto; an L-shaped bracket (150) supporting a lower surface of the frame (140) and formed to be attached to the inner surface of a handrail (R); a lateral buffer part (160) fixed to the bracket (150) and supporting the lower surface and a rim of the frame (140); a lower buffering part (170) supporting the lower surface of the frame (140) and mounted on an upper surface of the slab (S); and a reinforcing part preventing breakage of the handrail (R) due to separation of the L-shaped bracket (150) by an external force from the handrail (R). The reinforcing part includes: a first fixing part (164) fixed to a knife block anchor (163) provided in the slab (S) adjacent to a side end of the slab (S), and protruding outward from the side end of the slab (S); a second fixing part (165) fixed through the handrail (R) and the L-shaped bracket (150), and protruding from the outer surface of the handrail (R); and a connection fixing part (166) connecting and fixing the first fixing part (164) and the second fixing part (165). Thus, deterioration of power generation efficiency can be prevented.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar module array mounting system having a reinforced portion for preventing railing damage due to an external force,

The present invention relates to a solar module (110) for receiving sunlight to generate electricity; A support plate 120 to which the solar module 110 is attached; A column 130 mounted to rotate on a lower surface of the support plate 120; A frame 140 to which a lower end of the column 130 is fixed; An L-shaped bracket 150 for supporting the lower surface of the frame 140 and adapted to be attached to an inner surface of the handrail R; A side buffer part 160 fixed to the bracket 150 to support a bottom surface and an edge of the frame 140; A lower cushioning part 170 supporting the lower surface of the frame 140 and resting on the upper surface of the slab S; And a reinforcement portion for preventing breakage of the handrail (R) due to separation of the L-shaped bracket (150) from the handrail (R) by an external force, wherein the reinforcement portion A first fixing part 164 fixed to the knife block anchor 163 provided in the slab S adjacent to the slab S and protruding outward from the side end of the slab S; A second fixing portion 165 fixed through the handrail R and the L-shaped bracket 150 and protruding from the outer surface of the handrail R; And a connection fixing part (166) connecting and fixing the first fixing part (164) and the second fixing part (165) to each other. Module array installation system.

Hereinafter, the background art will be described with reference to the accompanying drawings.

Solar power generation is a power generation system that converts solar energy directly into electric energy using solar cells without the aid of generators.

Such solar power generation is generally constituted by installing a solar panel, which is a solar cell means that condenses sunlight and converts it into electric energy.

The photovoltaic power generation system should arrange a solar panel to concentrate sunlight, but a structure supporting the solar panel is needed.

As shown in FIG. 1, the solar module array installation system according to the related art installed on the roof has a solar module 110 that receives sunlight to generate electricity; A support plate 120 to which the solar module 110 is attached; A column 130 mounted to rotate on a lower surface of the support plate 120; A frame 140 to which a lower end of the column 130 is fixed; An L-shaped bracket 150 for supporting the lower surface of the frame 140 and adapted to be attached to an inner surface of the handrail R; A side buffer part 160 fixed to the bracket 150 to support a bottom surface and an edge of the frame 140; A lower cushioning part 170 supporting the lower surface of the frame 140 and resting on the upper surface of the slab S; And a connection fixing part 190 penetrating through the L-shaped bracket 150 and deeply inserted in the rail R to connect and fix the L-shaped bracket 150 and the rail R, The railing R is usually formed by applying cement to the block so that the connecting fixture 190 is easily separated from the railing R and the railing R is broken and the solar module array The power generation efficiency is lowered due to damage or breakage.

In addition, the solar module array installation system according to the above-described conventional example installed on the roof has a structure in which when the wind is severely blown, the solar module 110 is lifted up by the wind power and is tiled horizontally and vertically The frame 140 may also be lifted up and broken or damaged so that the connecting fixture 190 connected to the frame 140 from the railing R is easily separated so that the railing R is broken and the photovoltaic module array is damaged So that the power generation efficiency is lowered.

Korean Patent No. 10-1797899 (Aug.

A rooftop installed solar module array installation system having a reinforced portion for preventing railing damage by an external force according to the present invention is intended to solve the following problems.

It is an object of the present invention to provide a solar cell module in which a rooftop rail is usually formed by applying cement to a block having a weak strength at the time of occurrence of an earthquake so that the connecting and securing portion is easily separated from the railing and the parcel is broken, The power generation efficiency is lowered.

Another object of the present invention is to provide a solar module in which the solar module is lifted up by the wind force when the wind is blowing so that the horizontally and vertically tiled frame is crushed, The parapet is easily broken and the PV module array is damaged or damaged, thereby lowering the power generation efficiency.

A rooftop installed solar module array installation system having a reinforcement for preventing railway breakage by external force according to the present invention is configured as follows to solve the above problems.

A photovoltaic module 110 that receives sunlight to generate electricity; A support plate 120 to which the solar module 110 is attached; A column 130 mounted to rotate on a lower surface of the support plate 120; A frame 140 to which a lower end of the column 130 is fixed; An L-shaped bracket 150 for supporting the lower surface of the frame 140 and adapted to be attached to an inner surface of the handrail R; A side buffer part 160 fixed to the bracket 150 to support a bottom surface and an edge of the frame 140; A lower cushioning part 170 supporting the lower surface of the frame 140 and resting on the upper surface of the slab S; And a reinforcement portion for preventing breakage of the handrail (R) due to separation of the L-shaped bracket (150) from the handrail (R) by an external force, wherein the reinforcement portion A first fixing part 164 fixed to the knife block anchor 163 provided in the slab S adjacent to the slab S and protruding outward from the side end of the slab S; A second fixing portion 165 fixed through the handrail R and the L-shaped bracket 150 and protruding from the outer surface of the handrail R; And a connection fixing part 166 connecting and fixing the first fixing part 164 and the second fixing part 165.

The first fixing part 164 and the second fixing part 165 form a hole 164H and a hole 165H and are threaded on an outer surface of the fixing part 164H and the hole 165H, The connection fixing part 166 forms a bolt head 166BH at one end and a nut 167, 167 ', 167 "at the other end and the entire outer surface of the body. The first fixing part 164 and the second fixing part 165 are connected to each other by passing through the hole 164H and the hole 165H and the nuts 167 and 167 ' , 167 ").

The holes 164H and 165H of the first fixing part 164 and the second fixing part 165 are formed in the longitudinal direction of the first fixing part 164 and the second fixing part 165 And an elliptical shape having a major axis in a direction perpendicular to the longitudinal direction and a minor axis in the longitudinal direction.

The rooftop installed solar module array installation system having a reinforcement for preventing railing damage by external force according to the present invention can exhibit the following effects by the above solution.

First, when an external force such as an earthquake occurs, the rooftop railing is usually formed by applying cement to a block having a weak strength, so that the connecting and fixing part is easily separated from the railing, and the railing is broken and the solar module array is damaged or broken There is an effect of solving the disadvantage that the power generation efficiency is lowered.

Secondly, when the wind is severely blown, the solar module is lifted up by the wind power, and accordingly, the frame which is tiled horizontally and vertically is lifted up and broken or damaged so that the connecting fixture connected to the frame is easily separated from the rail, There is an effect of solving the disadvantage that the power generation efficiency is lowered because the parapet is broken and the solar cell module array is damaged or broken.

1 is a cross-sectional view of a solar module array installation system according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a rooftop installed solar module array installation system having a reinforcement for preventing railing damage according to an embodiment of the present invention.
3 is an enlarged view of part A of Fig.
Fig. 4 is an exploded view of the components constituting the reinforcing portion in Figs. 2 and 3. Fig.
Fig. 5 is a view showing another embodiment of a reinforcement portion including components different from those of the reinforcement portion of Fig.
6 is a plan view of two frames adjacent to each other among frames provided in a checkered pattern on the roof and blocks arranged between these frames.
7 is a cross-sectional view taken along the line A-A 'in Fig.

Hereinafter, various embodiments of the present document will be described with reference to the accompanying drawings. It should be understood, however, that the techniques described herein are not intended to be limited to any particular embodiment, but rather include various modifications, equivalents, and / or alternatives of the embodiments of this document. In connection with the description of the drawings, like reference numerals may be used for similar components.

Also, the terms "first," "second," and the like used in the present document can be used to denote various components in any order and / or importance, and to distinguish one component from another But is not limited to those components. For example, 'first part' and 'second part' may represent different parts, regardless of order or importance. For example, without departing from the scope of the rights described in this document, the first component may be named as the second component, and similarly the second component may be named as the first component.

It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the other embodiments. The singular expressions may include plural expressions unless the context clearly dictates otherwise. Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by one of ordinary skill in the art. The general predefined terms used in this document may be interpreted in the same or similar sense as the contextual meanings of the related art and, unless expressly defined in this document, include ideally or excessively formal meanings . In some cases, even the terms defined in this document can not be construed as excluding the embodiments of this document.

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

FIG. 1 is a cross-sectional view of a conventional solar module array installation system according to an embodiment of the present invention. FIG. 2 is a perspective view of a roof installation solar module array installation system for preventing railing damage Fig. 3 is an enlarged view of the portion A in Fig. 2, and Fig. 4 is an exploded view of the components constituting the reinforcing portion in Figs.

1 to 4, a rooftop installed solar module array installation system having a reinforcement for preventing railing damage according to the present invention includes a solar module 110, a support plate 120, a column 130, a frame 140 An L-shaped bracket 150, a side cushioning portion 160, a lower cushioning portion 170, and a reinforcing portion.

The solar module 110 receives sunlight to generate electricity, and the structure of the solar module 110 is already well known, and thus a detailed description thereof will be omitted.

The support plate 120 is a plate to which the solar module 110 is attached, and is larger in size than the solar module 110.

The column 130 is mounted on the lower surface of the support plate 120 to support the support plate 120. In the present embodiment, the support plate 120 is configured to be rotatable, but the present invention is not limited thereto But in other embodiments, the support plate 120 may be fixed to the column 13 so as not to be rotatable.

The lower end of the column 130 is fixed to the frame 140.

The L-shaped bracket 150 supports the lower surface of the frame 140 and is formed to be attached to the inner surface of the handrail R. In the present embodiment, the L-shaped bracket 150 is attached to the inner surface of each wall surface of the handrail R .

The side buffer part 160 is fixed to the bracket 150 and supports a bottom surface and an edge of the frame 140. A spring is provided between the bracket 150 and the frame 140, So as to be capable of performing buffering to the side of the main body 140.

The lower cushioning part 170 supports a lower surface of the frame 140 and is seated on the upper surface of the slab S. The lower cushioning part 170 is provided with a plurality of springs between the slab S and the lower surface of the frame 140 So as to perform buffering to the lower side of the frame 140.

The reinforcing portion is configured to prevent the L-shaped bracket 150 from being separated from the railing R by an earthquake and then to prevent breakage of the railing R due to such separation, (164) fixed to a knife block anchor (163) provided in a slab (S) adjacent to a side end of the slab (S) and projecting outward from a side end of the slab (S); A second fixing portion 165 fixed through the handrail R and the L-shaped bracket 150 and protruding from the outer surface of the handrail R; And a connection fixing part 166 for connecting and fixing the first fixing part 164 and the second fixing part 165.

The first fixing part 164 and the second fixing part 165 form a hole 164H and a hole 165H and are threaded on the outer surface and the holes 164H and 165H Is formed on the inner wall surface.

The first fixing part 164 has a bolt head 164BH at one end and a screw forming part 164T at the other end which mates with a screw part formed on the inner surface of the knife block anchor 163 And may be fixed to the knife block anchor 163.

The second fixing portion 165 has a bolt head 165BH at one end and a thread that can be engaged with the nut 165N at the other end.

The connection fixing part 166 has a bolt head 166BH formed at one end thereof and a screw thread capable of mating with the nut 167, 167 ', 167 "at the other end and the entire outer surface of the body, The first fixing portion 164 and the second fixing portion 165 are connected to each other by passing through the hole 164H and the hole 165H and are fastened and fixed with the nuts 167, 167 ', 167 " .

The holes 164H and 165H of the first fixing part 164 and the second fixing part 165 are formed in the longitudinal direction of the first fixing part 164 and the second fixing part 165 And an elliptical shape having a major axis in a direction perpendicular to the longitudinal direction and a minor axis in the longitudinal direction.

The first fixing portion 164 and the second fixing portion 165 are fixed to the L-shaped bracket 150 and the slab S, respectively, in the slab S, which is made of reinforcing steel and concrete and has high strength, The holes 164H and 165H of the first fixing part 164 and the second fixing part 165 are respectively formed as the grooves when the screws are fastened to each other so that the connection fixing part 166 to easily fix the connection fixing portion 166 to the first fixing portion 164 and the second fixing portion 165 so that the impact due to the earthquake can be prevented from being applied to the first fixing portion 164 Can prevent the damage of the handrail R and the damage and breakage of the solar cell module array, thereby improving the power generation efficiency.

Meanwhile, FIG. 5 is a view showing another embodiment of the reinforcement portion including components different from those of the reinforcement portion of FIG.

5, the first fixing part 164 and the second fixing part 165 are formed with a plurality of holes 164H 'and a plurality of holes 165H', respectively, with threads formed on the outer surface thereof A locus connecting the center of the plurality of holes 165H on the outer surface of the first fixing part 164 and the second fixing part 165 forms a spiral trajectory, One of the plurality of holes 165H formed in the first fixing portion 164 and one of the plurality of holes 165H formed in the second fixing portion 165 is passed through the nuts 167, 167 ', 167 " So that the first fixing part 164 and the second fixing part 165 are connected and fixed.

The first fixing portion 164 and the second fixing portion 165 are fixed to the L-shaped bracket 150 and the slab S, respectively, in the slab S, which is made of reinforcing steel and concrete and has high strength, A plurality of holes 164H and holes 165H of the first fixing portion 164 and the second fixing portion 165 are formed along the helical trajectory when the screws are screwed together, It is possible to easily fix the connection fixing portion 166 to the first fixing portion 164 and the second fixing portion 165 by easily passing through the connection fixing portion 166 to one of the plurality of holes 165H, The first fixing part 164 is able to withstand an impact due to an earthquake, thereby preventing breakage of the handrail R and damaging or damaging the solar cell module array, thereby improving power generation efficiency.

According to this construction, it is possible to prevent the rainwater from leaking when the rain comes down, thereby preventing corrosion of the first fixing portion 164 and the second fixing portion 165, and preventing corrosion of the first fixing portion 164 and the It is possible to secure the effect of improving the adhesion to the rail (R) of the fixing part (165).

FIG. 6 is a plan view of two frames adjacent to each other among frames provided in a checkered pattern on the roof, and FIG. 7 is a sectional view taken along the line A-A 'in FIG.

Referring to FIGS. 6 and 7, a frame 140 is provided inside a roof railing R in a checkerboard shape, and a heavy T-shaped block 10 is disposed between two adjacent frames 140 of the frames The T-shaped block 10 is composed of an upper portion 11 and a lower portion 12 and has a T-shape. The lower portion 12 is integrally formed, Respectively. Herein, both side surfaces of the upper portion 11 are placed on the two adjacent frames 140, and the lower portion 12 is protruded down through the two adjacent frames 140 have.

In another embodiment, a 'C' block may be used instead of the T block 10, in which case the 'C' block may have an upper portion and a lower portion And the lower portion of the upper portion is positioned on the two adjacent frames 140 and the two lower portions of the opposite ends of the upper portion are positioned on the lower side of the two adjacent frames 140 Respectively.

In this configuration, since the T-shaped block 10 or the 'C' -shaped block pushes the adjacent two frames 140 downward, even when the wind is heavily blown, So that the raised frame is prevented from being lifted upward, so that the frame is not broken or damaged. As a result, the connecting fixture connected to the frame is easily separated from the rail so that the parapet is broken, Thereby preventing the occurrence of damage or breakage and improving the power generation efficiency.

In the above embodiments, the system for installing a roof-mounted solar photovoltaic module array according to the present invention is provided with the first fixing part 164 and the second fixing part 165 It is also possible to further include a rubber plate 161 and an iron plate 162 which are interposed between the first and second fixing portions 164 and 165 and penetrate by the first fixing portion 164 and the second fixing portion 165 .

A drive unit (not shown) for adjusting the inclination angle a of the support plate 120 is installed on the frame 140 so that the support plate 120 is pulled downward 180). The driving unit 180 includes a servo motor 181 fixed to the frame 140 and a bobbin 183 fixed to the rotating shaft of the servo motor 181. The driving unit 180 is connected to the bobbin 183 And a rope 185 fixed to the support plate 120 is formed. When the power is not supplied, the servo motor 181 is braked so that the rotation shaft is not rotated. When the power is supplied, the braking of the brake is released and the rotation shaft is freely rotated. The servomotor 181 is sold in the market and corresponds to general matters, so a detailed description thereof will be omitted. In another embodiment, the driving unit 180 may be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

10: T-shaped block
11: upper portion
12: Lower part
110: Photovoltaic module
120: Support plate
130: Column
140: frame
150: L-shaped bracket
160: Side buffer
161: Rubber plate
162: Iron plate
163: Knife block anchor
164: first fixing portion
164H, 164H ', 165H, 165H': hole
165: second fixing portion
166:
166BH: Bolt Head
167, 167 ', 167 ": Nuts
170: Lower buffer
180:
181: Servo motor
183: Bobbin
185: Rope
R: Railing
S: Slab

Claims (3)

A photovoltaic module 110 that receives sunlight to generate electricity;
A support plate 120 to which the solar module 110 is attached;
A column 130 mounted to rotate on a lower surface of the support plate 120;
A frame 140 to which a lower end of the column 130 is fixed;
An L-shaped bracket 150 for supporting the lower surface of the frame 140 and adapted to be attached to an inner surface of the handrail R;
A side buffer part 160 fixed to the bracket 150 to support a bottom surface and an edge of the frame 140;
A lower cushioning part 170 supporting the lower surface of the frame 140 and resting on the upper surface of the slab S; And
And a reinforcing portion for preventing breakage of the handrail (R) due to separation of the L-shaped bracket (150) from the handrail (R) by an external force,
The reinforcing portion
A first fixing part 164 fixed to a knife block anchor 163 provided in the slab S adjacent to the side end of the slab S and projecting outward from the side end of the slab S;
A second fixing portion 165 fixed through the handrail R and the L-shaped bracket 150 and protruding from the outer surface of the handrail R; And
And a connection fixing part (166) connecting and fixing the first fixing part (164) and the second fixing part (165). The roof mounting solar module Array installation system. The method according to claim 1,
The first fixing part 164 and the second fixing part 165 form a hole 164H and a hole 165H and are threaded on an outer surface of the fixing part 164H and the hole 165H, The connection fixing part 166 forms a bolt head 166BH at one end and a nut 167, 167 ', 167 "at the other end and the entire outer surface of the body. The first fixing part 164 and the second fixing part 165 are connected to each other by passing through the hole 164H and the hole 165H and the nuts 167 and 167 ' , 167 ") to fix the rooftop installed solar module array system with the reinforced portion for preventing railing damage by external force. 3. The method of claim 2,
The holes 164H and 165H of the first fixing part 164 and the second fixing part 165 are formed in the longitudinal direction of the first fixing part 164 and the second fixing part 165 Wherein the slot comprises an elliptical shape having a major axis in a direction perpendicular to the longitudinal direction and a minor axis in the longitudinal direction.

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