KR101571050B1 - Apparatus for fixing solar energy generation - Google Patents

Abstract

The present invention provides a device for fixing a solar power generating module which comprises: a plurality of main frames having cavities respectively; coupling units for coupling adjacent main frames each other wherein the coupling units are located in inner cavities of the adjacent main frames among the main frames; and support units connected to the main frames and coupled with an installation target object wherein the support units are arranged in a direction which crosses a plane mad by the main frames.

Description

[0001] APPARATUS FOR FIXING SOLAR ENERGY GENERATION [0002]

The present invention relates to an apparatus for fixing a solar module to an installation object.

Generally, a photovoltaic module is a module that generates electricity by receiving sunlight. These solar modules must be mounted in a position suitable for receiving the sun's light.

The mounting device therefor has a generally lattice-like frame structure. To create such a frame structure, a plurality of frames are welded to form a single module.

However, such a welding method inconveniences the installation site because the power supply equipment must be prepared. Especially, in the underdeveloped countries where electricity is poor, even if there is a power supply facility, it is difficult to work because the power supply is unstable.

In addition, since the PV module must be mounted on the roof, the existing steel structure has a problem that an excessive load is applied to the roof.

It is an object of the present invention to provide a solar cell module fixing device that is easy to combine and disassemble by a simple operation out of the conventional welding method.

Another object of the present invention is to provide a solar PV module fixing device which can achieve the required strength while being made of a lightweight material.

According to an aspect of the present invention, there is provided a solar cell module fixing apparatus comprising: a plurality of main frames each having an inner cavity; A binding unit located in an inner cavity of an adjacent main frame among the plurality of main frames and binding the adjacent main frames to each other; And a support unit connected to the main frame and arranged along a direction intersecting the plane defined by the plurality of main frames and coupled to the installation object.

Here, the main frame may include a closed loop-shaped rim forming the inner cavity.

Here, the main frame may include: a main reinforcing portion that defines an inner cavity of the rim portion; And a sub-reinforcement portion that defines a space between the main reinforcement portion and the frame portion and is arranged along a direction intersecting the main reinforcement portion.

Here, the binding unit may include: a first branch portion inserted into an inner cavity of one of the adjacent main frames; And a second branch portion inserted in the inner cavity of the other of the adjacent main frames and arranged along a direction crossing the longitudinal direction of the first branch portion.

Here, the binding unit may further include a locking protrusion provided on at least one of the first branch portion and the second branch portion and elastically protruding.

The main frame may further include a lock groove communicating with the internal cavity at a position corresponding to the lock projection and receiving the lock projection.

Here, the first branch portion and the second branch portion may be formed as separate members, and the binding unit may further include a fastening piece for fastening the first branch portion and the second branch portion.

Here, the binding unit may include: an extension plate bent and extended corresponding to the adjacent main frame; And an attachment piece for attaching the extension plate to the adjacent main frame.

Here, the support unit may include: a first coupling unit coupled to the main frame; And a second coupling portion extending from the first coupling portion so as to be bent and coupled to the installation object.

The main frame may further include a rail formed on an outer surface of the rim portion, wherein the rail includes: a pair of ridges projecting from opposite ends of one side of the rim portion; And a pair of latching portions extending toward each other in the pair of projecting portions to latch the slider. The first coupling portion may include a slider slidably inserted into the rail.

Here, the rim forms a quadrangle, the rails are formed on three sides of the rim, and the first rim includes three sliders corresponding to three sides of the rim.

Here, the second coupling unit may include a coupling block having a through hole; And a coupling piece passing through the mounting object and the through hole to allow the second coupling portion to be coupled to the installation object.

According to the solar power generating module fixing apparatus of the present invention configured as described above, it is convenient to merge and disassemble by a simple operation out of the existing welding method.

In addition, it is possible to achieve the required strength for supporting the solar cell module while making the fixing device lightweight.

1 is an exploded perspective view of a solar cell module fixing apparatus 100 according to an embodiment of the present invention, which corresponds to a solar cell module S. FIG.
2 is a perspective view for explaining the main frame 110 of FIG.
3 is a perspective view for explaining connection between the upper frame 131 and the first connection unit 151 of FIG.
4 is a perspective view illustrating the connection between the lower frame 141 and the second connection unit 161 of FIG.
5 is a perspective view for explaining binding between the adjacent main frame 110 and the binding unit 170 of FIG.
6 is a perspective view for explaining coupling between the main frame 110 and the support unit 190 of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a photovoltaic module fixing apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is an exploded perspective view of a solar cell module fixing apparatus 100 according to an embodiment of the present invention, which corresponds to a solar cell module S. FIG.

Referring to the drawings, a solar cell module fixing apparatus 100 includes a main frame 110, a reinforcing frame 130, a connecting unit 150, a binding unit 170, and a support unit 190 have.

The main frame 110 is a part where the solar power generation module S is placed. The plurality of main frames 110 may be connected to each other. In the present embodiment, the main frame 110 is composed of four parts, that is, up, down, left, and right. The mainframe 110 may have rails 119 and 121 (see FIG. 2) extending along its lengthwise direction. In addition, the main frame 110 may have an internal cavity C (FIG. 2). The main frame 110 is made of an aluminum alloy and may be lighter than conventional iron.

The reinforcing frame 130 reinforces the main frame 110 to support the solar power generation module S together with the reinforcing frame 130. The reinforcing frame 130 may be arranged along a direction crossing the extending direction of the main frame 110. [ In addition, the reinforcing frame 130 may be located within the rectangle formed by the main frame 110. The reinforcing frame 130 may also be made of an aluminum alloy, such as the main frame 110.

Further, the reinforcing frame 130 may cross the upper frame 131 and the lower frame 141 to form a cross. Both ends of the upper frame 131 are connected to the side surface 111a of the main frame 110 and both ends of the lower frame 141 are connected to the bottom surface 111b of the main frame 110, ). ≪ / RTI > Thereby, the upper frame 131 can be positioned on the upper side of the lower frame 141.

 The connecting unit 150 is a medium for connecting the reinforcing frame 130 to the main frame 110. The connection unit 150 may have a first connection unit 151 and a second connection unit 161. The first connection unit 151 connects the upper frame 131 to the side surface of the main frame 110 while the second connection unit 161 connects the lower frame 141 to the bottom surface of the main frame 110 .

The binding unit 170 is configured to bind adjacent main frames 110 to each other. The binding unit 170 is disposed so as to be inserted into the internal cavity C of the main frame 110 (Fig. 2).

The support unit 190 is configured to engage the main frame 110 with respect to the object to be installed. To this end, the support unit 190 is connected to the main frame 110 and may be arranged along the direction intersecting the plane formed by the main frame 110. [

Hereinafter, the main frame 110, the reinforcing frame 130 and the connecting unit 150, the binding unit 170, and the supporting unit 190 will be described in order.

2 is a perspective view for explaining the main frame 110 of FIG.

Referring to the drawings, the main frame 110 may have a closed-loop-shaped rim portion 111 forming an inner cavity C. [ In this embodiment, the rim 111 has a rectangular shape. In this case, the rim portion 111 has two side surfaces 111a, one bottom surface 111b, and one top surface 111c.

In order to reinforce the strength of the rim portion 111, a reinforcing portion may be provided in the inner cavity C of the rim portion 111. The reinforcing portion increases the strength of the rim 111, which is an aluminum alloy, to enable strong support for the solar module S.

The reinforcing portion may have a main reinforcing portion 112 and further a sub-reinforcing portion 113. The main reinforcing portion 112 can divide the internal cavity C into two spaces. On the other hand, the sub-reinforcement portion 113 can be opened so as to separate again any one of the above two spaces. At this time, the sub-reinforcing portion 113 may be in a direction intersecting the arrangement direction of the main reinforcing portion 112.

The main frame 110 may further have a support plate 115. The support plate 115 is configured to support the solar power generation module S together with the rim 111. Specifically, the support plate 115 protrudes from one side of the upper surface 111c. In this case, the support plate 115 may be arranged perpendicular to the upper surface 111c.

The mainframe 110 may also have a receiving unit 116 for receiving electrical wires. Here, the electric wire may be connected to the solar power generation module S. The housing unit 116 may have a first accommodating body 117 and a second accommodating body 118. [ The first accommodating body 117 is provided on the rim 111 and has an arcuate cross section. The second accommodating body 118 also has an arc-shaped cross section. Here, the curvature of the second accommodating body 118 is smaller than the curvature of the first accommodating body 117, so that the second accommodating body 118 can be fitted in the first accommodating body 117. In this state, the second accommodating body 118 can be rotated to switch the first accommodating body 117 and the second accommodating body 118 to form a closed space or to form an open space.

The mainframe 110 may have rails extending along its lengthwise direction. The rail is a structure in which a slider of the connection unit 150 is slidably inserted.

The rail may be divided into a side rail (119) and a bottom rail (121). The side rail 119 is formed on the side surface 111a of the rim portion 111 and the bottom rail 121 is formed on the bottom surface 111b of the rim portion 111. [

The side rail 119 may have a protruding portion 119a and a locking portion 119b. The protruding portions 119a may be provided as a pair protruding from both ends of the side surface 111a. The protrusions 119a may be provided as a pair extending from the pair of protrusions 119a toward each other.

The bottom rail 121 may have the same configuration as the side rail 119.

The side rails 119 may be formed on two sides 111a of the rim 111 and the bottom rails 121 may be formed on the bottom 111b. Then, three sides of the four sides of the rim 111 are wrapped by the rails 119 and 121.

3 is a perspective view for explaining connection between the upper frame 131 and the first connection unit 151 of FIG.

Referring to this figure, the upper frame 131 has a rim 133 having an inner cavity UC similar to the main frame 110. [ The rim 133 may have a rectangular cross section.

The first connection unit 151 may have a body 152, a slider 153, a screw 154, and a nut 155.

The body 152 may be a substantially rectangular parallelepiped block. The body 152 may also have an inner cavity, and the inner cavity may have a reinforcement.

The slider 153 is coupled to the free end of the body 152. The slider 153 may be a first retaining plate having a larger size than the cross section of the body 152.

 The screw 154 and the nut 155 are configured to fasten the upper frame 131 and the body 152.

According to this configuration, the body 152 of the first connection unit 151 is inserted into the inner cavity UC of the upper frame 131. In this state, the screw 154 passes through the rim 133 and the body 152 and is fastened to the nut 155.

The slider 153 is slidably inserted into the side rail 119 (Fig. 2) of the main frame 110 in a state where the first connection unit 151 is engaged with the upper frame 131. [ At this time, both opposite ends of the slider 153 are caught by the latching portion 119b of the side rail 119, so that they are not separated from the side rail 119.

4 is a perspective view illustrating the connection between the lower frame 141 and the second connection unit 161 of FIG.

Referring to this figure, the lower frame 141 has a rim portion 143 having an inner cavity DC similar to the main frame 110. The rim 143 may have a rectangular cross section.

The second connection unit 161 may have a body 162, a slider 166, a screw 169, and a nut 170.

The body 162 may have an insertion portion 163 and a mounting portion 164. The insertion portion 163 may be a substantially rectangular parallelepiped block. The mounting portion 164 may extend from the insertion portion 163 and may have a protruding surface 164a protruding from the insertion portion 163 and an arcuate supporting surface 164b supporting the protruding surface 164a . The supporting surface 164b exhibits a strong supporting force against the protruding surface 164a while reducing the amount of the material as compared with the case where the mounting portion 164 is formed as a rectangular parallelepiped corresponding to the protruding surface 164a .

The slider 166 may have a pillar portion 167 and a second latching plate 168. The column portion 167 is a portion projecting in the direction intersecting with the projecting surface 164a. The second latching plate 168 is provided on the column portion 167. The second engaging plate 168 has a larger size than the column portion 167.

The screw 169 and the nut 170 are configured to fasten the lower frame 141 and the body 162.

According to this configuration, the body 162 of the second connection unit 161 is inserted into the inner cavity DC of the lower frame 141. In this state, the screw 169 passes through the rim 143 and the body 162 and is fastened to the nut 170.

The slider 166 is slidably inserted into the lower rail 121 (Fig. 2) of the main frame 110 in a state where the second connection unit 161 is coupled to the lower frame 141. [ At this time, both opposite end portions of the slider 166 are caught by the latching portion of the lower rail 121, and are not separated from the lower rail 121.

5 is a perspective view for explaining binding between the adjacent main frame 110 and the binding unit 170 of FIG.

Referring to this figure, the binding unit 170 may have a first branch portion 171 and a second branch portion 177.

The first branch portion 171 is inserted into the inner cavity C of one of the adjacent main frames 110. Specifically, the main reinforcing portion 112, the sub-reinforcing portion 113, and the rim portion 111 can be inserted into a space defined by the main reinforcing portion 112, the sub-reinforcing portion 113, and the rim portion 111.

And the second branch portion 177 is inserted into the inner cavity C of the other of the adjacent main frames 110. [ The second branch portion 177 may be arranged in a direction intersecting the first branch portion 171, for example, in a vertical direction.

The first branch portion 171 and the second branch portion 177 may be provided with locking protrusions 172 and 177, respectively. The locking protrusions 172 and 177 are resiliently supported by a spring and can be inserted into the lock hole 123 while being inserted into the inner cavity C. [

The first branch portion 171 and the second branch portion 177 may be a single piece or individual pieces separated from each other. In the latter case, they can be fastened to each other by fastening pieces 179.

The binding unit 170 may further have an extension plate 181 and an attachment piece 183.

The extension plate 181 extends over the adjacent main frame 110. In this embodiment, the extension plate 181 may be a plate that is bent approximately 90 degrees. Further, the extension plate 181 may have a height and a width to be fitted to the bottom rail 121.

The attachment piece 183 is an element for fixing the extension plate 181 to the main frame 110. [ The attachment piece 183 may be, for example, a screw.

6 is a perspective view for explaining coupling between the main frame 110 and the support unit 190 of FIG.

Referring to this figure, the support unit 190 is configured to engage the main frame 110 with an object to be installed.

The support unit 190 may have a first engaging portion 191 and a second engaging portion 197.

The first coupling portion 191 is a portion coupled to the main frame 110. The first coupling portion 191 has a slider 193 slidably inserted into the rails 119 and 121 of the main frame 110. The slider 193 may be provided in three corresponding to three sides (two sides and one bottom) of the main frame 110.

The second coupling portion 197 is a portion coupled to the installation object. The second coupling portion 197 may have a coupling block 197 and a coupling piece 199.

The coupling block 197 bends and extends at the first coupling portion 191. A through hole 198 may be formed in the coupling block 197.

The coupling piece 199 passes through the through hole 198 and the object to be mounted so that the second coupling part 197 is coupled to the object to be installed. The coupling block 197 may have a screw 199a and a nut 199b.

According to this configuration, the solar module S can be supported at an inclination with respect to the object to be installed through the support unit 190. In addition, the angle of the solar power generation module S (and the main frame 110 and the reinforcing frame 130) to the installation object can be easily controlled by operating the coupling piece 199.

The solar cell module fixing device as described above is not limited to the configuration and operation of the embodiments described above. The above embodiments may be configured so that all or some of the embodiments may be selectively combined to make various modifications.

100: PV module fixing device 110: Main frame
130: reinforcing frame 150: connecting unit
170: binding unit 190: support unit

Claims (12)

A plurality of main frames each having an inner cavity; A binding unit located in an inner cavity of an adjacent main frame among the plurality of main frames and binding the adjacent main frames to each other; And a support unit connected to the main frame and arranged along a direction intersecting a plane defined by the plurality of main frames and coupled to an object to be installed,
The support unit includes: a first coupling unit coupled to the main frame; And a second engaging portion bent and extending from the first engaging portion and coupled to the mounting object.
The method according to claim 1,
The main frame includes:
And a closed loop-shaped rim forming the inner cavity.
3. The method of claim 2,
The main frame includes:
A main reinforcing portion for defining an inner cavity of the rim portion; And
Further comprising a sub-reinforcement portion that defines a space formed by the main reinforcement portion and the rim portion and is arranged along a direction intersecting the main reinforcement portion.
3. The method of claim 2,
The binding unit includes:
A first branch portion inserted into an inner cavity of any one of the adjacent main frames; And
And a second branch portion which is inserted into the inner cavity of the other one of the adjacent main frames and arranged along a direction crossing the longitudinal direction of the first branch portion.
5. The method of claim 4,
The binding unit includes:
Further comprising locking protrusions provided on at least one of the first branch portion and the second branch portion and elastically protruding from the first branch portion and the second branch portion.
6. The method of claim 5,
The main frame includes:
Further comprising a lock groove communicating with the internal cavity at a position corresponding to the lock projection and receiving the lock projection.
5. The method of claim 4,
Wherein the first branch portion and the second branch portion are formed as separate members,
The binding unit includes:
And a fastening piece for fastening the first branch portion and the second branch portion.
5. The method of claim 4,
The binding unit includes:
An extension plate that is bent and extended corresponding to the adjacent main frame; And
Further comprising a mounting piece for attaching said extension plate to said adjacent main frame.
delete 3. The method of claim 2,
The main frame includes:
And a rail formed on an outer surface of the rim portion,
The rail
A pair of protrusions protruding from both ends of one side of the rim; And
And a pair of latching portions extending toward each other at the pair of projecting portions to catch the slider,
Wherein the first coupling portion includes:
And a slider slidably inserted into the rail.
11. The method of claim 10,
The rim forms a quadrangle,
The rails being formed on three sides of the rim,
Wherein the first coupling portion includes:
And three sliders corresponding to three sides of the rim portion.
11. The method of claim 10,
And the second engagement portion includes:
A coupling block having a through hole; And
And a coupling piece passing through the installation object and the through hole to allow the second coupling portion to be coupled to the installation object.

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