KR101895586B1 - Seismic isolation assembly for photovoltaic module - Google Patents

Abstract

The present invention relates to an antiseismic joint assembly for a solar cell module, capable of stably supplying electric energy by preventing seismic force induced from an earthquake from being transmitted to the solar cell module by separating the solar cell module from the ground. The present invention relates to the antiseismic joint assembly for a solar cell module, which fixes a solar cell module to a support and comprises: an upper module including an upper fixing portion fixed to a lower portion of the solar cell module, a first vertical support plate provided below the upper fixing portion, and a first coupling plate horizontally bent from a lower end of the first vertical support plate; a lower module including a lower fixing portion fixed to an upper end of the support fixed to the ground, a second vertical support plate provided on an upper portion of the lower fixing portion, and a second coupling plate horizontally bent in the direction from an upper end of the second vertical support plate toward the first vertical support plate of the upper module; and a first antiseismic member provided between the first coupling plate and the second coupling plate wherein the upper fixing portion, the second coupling plate, the lower fixing portion, and the first coupling plate are disposed to be spaced apart from each other.

Description

{Seismic isolation assembly for photovoltaic module}

The present invention relates to an optical joint assembly for a solar cell module capable of stably supplying electric energy by preventing the seismic force induced by an earthquake from being transmitted to the solar cell module by separating the solar cell module from the ground.

Recently, the amount of solar energy that can be continuously used as renewable energy is increasing.

There have been many generations of technologies related to solar cells that convert the light energy of sunlight into infinite, pollution-free solar energy into electric energy.

Generally, a solar cell is constituted by fixing a solar cell module, which is a thin panel type, to a support. In order to improve the power generation efficiency due to the inclination angle of the solar panel depending on the angle of incidence of the sunlight, And the inclination angle of the battery plate is adjusted.

However, when a lateral load is generated due to an earthquake or the like, damage may be concentrated on a joint portion between the solar cell module and the support. And if the joint is damaged, the jointed solar cell module may also be damaged.

Accordingly, it is desired to provide a joint assembly for a solar cell module which can withstand a lateral load due to an earthquake or the like, because stable electrical energy supply may become difficult.

KR 10-1511585 B1

In order to solve the above problems, it is an object of the present invention to provide a seismic isolation joint assembly for a solar cell module capable of securing stable electric energy by preventing the seismic force from being transmitted to the solar cell module by separating the solar cell module and the ground.

According to a preferred embodiment of the present invention, there is provided an angle joint assembly for a solar cell module for fixing a solar cell module to a support, comprising: an upper fixing part fixed to a lower portion of the solar cell module; An upper module comprising a vertical support plate and a first engaging plate horizontally bent at a lower end of the first vertical support plate; A second vertical support plate provided on the upper portion of the lower fixing portion, and a horizontal bent portion in the direction of the first vertical support plate of the upper module at an upper end of the second vertical support plate, A lower module comprising a second coupling plate; And a first facing member provided between the first engaging plate and the second engaging plate; Wherein the upper fixing part, the second coupling plate, the lower fixing part, and the first coupling plate are spaced apart from each other.

According to another preferred embodiment of the present invention, the second joint member is provided between the upper fixing portion and the second joint plate and between the lower joint portion and the first joint plate. Lt; / RTI >

According to another preferred embodiment of the present invention, the upper and lower ends of the second seam member are respectively coupled with coupling openings formed with enlarged locking portions, and the lower surface of the upper fixing portion, the upper surface of the second coupling plate, And an engaging groove is formed on a lower surface of the first coupling plate to engage with the enlargement engaging portion in a sliding manner on a side surface thereof.

According to another preferred embodiment of the present invention, a third face-to-face member is provided between the first vertical support plate and the second engagement plate, and between the second vertical support plate and the first engagement plate. And provides a braced joint assembly.

According to another preferred embodiment of the present invention, a coupling member having an enlarged locking portion is coupled to both ends of the third pair of facing members, and an inner side surface of the first vertical supporting plate and an end portion of the second coupling plate, Wherein an inner side surface of the plate and an end portion of the first coupling plate are formed with a latching groove for slidingly engaging the enlarged latching portion at a side surface thereof.

The seismic force can be prevented from being transmitted to the solar cell module by separating the solar cell module from the ground by placing the seismic joint assembly for the solar cell module at the junction between the column and the solar cell module fixed to the ground.

Specifically, since the first base member constituting the joint assembly is provided between the first coupling plate of the upper module fixed to the lower portion of the solar cell module and the second coupling plate of the lower module fixed to the upper end of the support, The horizontal displacement of the solar cell module can be prevented.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing an embodiment of an angle joint assembly for a solar cell module according to the present invention. Fig.
Fig. 2 is a front view showing a state in which an angle joint assembly for a solar cell module of the present invention is installed. Fig.
3 is a perspective view showing another embodiment of an seam joint assembly for a solar cell module according to the present invention.
4 is a cross-sectional view showing another embodiment of the joint member for a solar cell module in which the upper module and the lower module are separated from each other.
5 is a perspective view showing a coupling relationship of the second facing member.
6 is a perspective view showing still another embodiment of an optical joint assembly for a solar cell module according to the present invention.
7 is a cross-sectional view showing another embodiment of the face-to-face joint assembly for the solar cell module of the present invention in which the upper module and the lower module are separated.
8 is a perspective view showing a coupling relationship of the third pair of facing members.

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

FIG. 1 is a perspective view showing an embodiment of an optical joint assembly for a solar cell module according to the present invention, and FIG. 2 is a front view showing a state in which an optical joint assembly for a solar cell module according to the present invention is installed.

1 and 2, the present invention relates to an outer joint assembly 3 for a solar cell module for fixing a solar cell module 1 to a strut 2, A first vertical supporting plate 312 provided at a lower portion of the upper fixing portion 311 and a first vertical coupling portion 312 formed at the lower end of the first vertical supporting plate 312, An upper module 31 composed of a plate 313; A second vertical support plate 322 provided on the upper portion of the lower fixing portion 321 and a second vertical support plate 322 provided on the upper portion of the column 2 fixed to the ground, A lower module 32 consisting of a second coupling plate 323 horizontally bent in the direction of the first vertical support plate 312 of the upper module 31 at the upper end of the lower module 32; And a first yoke (33) provided between the first engaging plate (313) and the second engaging plate (323); The upper fixing part 311, the second coupling plate 323, the lower fixing part 321 and the first coupling plate 313 are spaced apart from each other.

The present invention is to prevent the seismic force from being directly transmitted to the solar cell module 1 by separating the solar cell module 1 from the ground.

The seismic isolation joint assembly 3 for a solar cell module of the present invention is for fixing the solar cell module 1 to the column 2 and is provided at a junction between the solar cell module 1 and the column 2. [

The base isolation joint assembly (3) for a solar cell module of the present invention comprises an upper module (31), a lower module (32) and a first face member (33).

The upper module 31 includes an upper fixing part 311 fixed to the lower part of the solar cell module 1, a first vertical supporting plate 312 provided below the upper fixing part 311, And a first engaging plate 313 horizontally bent at the lower end of the supporting plate 312.

The upper fixing part 311, the first vertical support plate 312, and the first coupling plate 313 may be formed in a U-shape as a whole.

The upper fixing part 311 can be bolted to the solar cell module 1. For this, a pair of bolt coupling plates are formed on the upper fixing part 311, and a through hole for bolt penetration may be formed on the bolt coupling plate.

The upper fixing part 311 may be formed in various shapes corresponding to the lower shape of the solar cell module 1.

The lower module 32 includes a lower fixing part 321 fixed to the upper end of the column 2 fixed to the ground, a second vertical supporting plate 322 provided on the upper part of the lower fixing part 321, And a second engaging plate 323 horizontally bent from the upper end of the two vertical supporting plates 322 toward the first vertical supporting plate 312 of the upper module 31. [

The lower fixing part 321, the second vertical support plate 322, and the second coupling plate 323 may be formed in a U-shape as a whole.

The lower fixing part 321 is bolt-engaged with the support 2. For this purpose, a pair of bolt coupling plates are formed below the lower fixing part 321, and through holes for bolt penetration may be formed in the bolt coupling plate.

The lower fixing part 321 can be formed in various shapes corresponding to the shape of the support 2 and the like.

The upper module 31 and the lower module 32 may be fabricated using a metal material.

The first facing member 33 is provided between the first engaging plate 313 of the upper module 31 and the second engaging plate 323 of the lower module 32.

The first seam member 33 may be a highly damped rubber, silicone, or the like, which is deformable in the vertical and horizontal directions and has elasticity of a predetermined size or more.

When a lateral displacement occurs in the column 2 due to the occurrence of an earthquake, the lower module 32 moves like the column 2. However, the horizontal displacement of the lower module 32 is not transmitted to the upper module 31 due to the lateral shear deformation of the first base member 33. [ Accordingly, the horizontal displacement of the solar cell module 1 can be prevented.

The first yoke 33 is provided between the first engaging plate 313 and the second engaging plate 323 so that the first engaging plate 313 is positioned inside the lower module 32, (323) are arranged to be located inside the upper module (31).

At this time, the upper fixing part 311 of the adjacent upper module 31 and the second coupling plate 323 of the lower module 32 can be closely contacted or spaced apart from each other. Likewise, the lower fixing portion 321 of the lower module 32 and the first coupling plate 313 of the upper module 31 can be closely contacted or spaced apart from each other.

If the adjacent upper fixing part 311 and the second coupling plate 323 and the lower fixing part 321 and the first coupling plate 313 are arranged to be in close contact with each other, The damping effect due to the frictional force of the close contact surface can be expected in addition to the lateral shear deformation.

In this case, in order to prevent the lower module 32 and the upper module 31 from acting together due to the frictional force of the close contact surface, that is, to increase the seismic effect, a lubricant may be applied to the close contact surface.

However, the earthquake energy may be attenuated by the frictional force of the contact surface in consideration of the size of the design load, the weight of the solar cell module 1, and the like.

When the neighboring upper fixing part 311 and the second coupling plate 323 and the lower fixing part 321 and the first coupling plate 313 are spaced apart from each other, The load of the solar cell module 1 can be supported by the tensile rigidity.

That is, the vertical load of the solar cell module 1 can be supported by the axial rigidity of the first base member 33 and the flexural rigidity of the first coupling plate 313 and the second coupling plate 323.

The second engaging plate 323 of the lower module 32 is preferably configured such that the end portion thereof is spaced apart from the inner surface of the first vertical supporting plate 312 of the upper module 31 by a predetermined distance. This is to allow lateral relative displacement of the upper module 31 and the lower module 32.

The first coupling plate 313 of the upper module 31 is also preferably spaced apart from the inner surface of the second vertical support plate 322 of the lower module 32 by a predetermined distance.

Since the relative displacement of the upper module 31 and the lower module 32 is allowed freely also in the width direction, bidirectional isolation performance can be ensured.

FIG. 3 is a perspective view showing another embodiment of the base joint assembly for a solar cell module of the present invention, and FIG. 4 is a sectional view showing another embodiment of the base joint assembly for the solar cell module of the present invention in which the upper module and the lower module are separated to be.

3, a second facing member 34 is interposed between the upper fixing portion 311 and the second fitting plate 323 and between the lower fixing portion 321 and the first fitting plate 313, May be provided.

When the weight of the solar cell module 1 is large or the tensile rigidity of the first yoke 33 is small, it may be difficult to support the upper load only by the first facing member 33. [

The second yoke member 34 is coupled between the upper fixing portion 311 and the second coupling plate 323 and between the lower fixing portion 321 and the first coupling plate 313, And the vertical load of the vehicle.

The second facing member (34) can be manufactured using the same material as the first facing member (33).

As shown in FIG. 3, when the second seam member 34 is installed directly below the first vertical support plate 312 or directly above the second vertical support plate 322, The vertical load can be transferred directly to the ground.

In this case, the first seam member 33 does not bear a vertical load, but resists through shear deformation only in the horizontal direction.

The second facing member 34 may be provided on both sides of the joint assembly 3 in the width direction between the upper fixing part 311 and the second coupling plate 323.

The second facing member 34 may be provided on both sides of the joint assembly 3 in the width direction between the lower fixing part 321 and the first coupling plate 313.

As shown in FIG. 4, the first face-to-face member 33 can be bolted to the second engagement plate 323 and the first engagement plate 313, respectively.

In this case, it may be difficult to fasten the bolts due to the interference between the upper fixing part 311 and the lower fixing part 321. Therefore, a part or all of the upper fixing part 311 and the lower fixing part 321 may be fixed to the first vertical supporting plate 312 And the second vertical support plate 322, respectively.

The upper and lower portions of the first facing member 33 are bolted to the second and third connecting plates 323 and 313 respectively and then the upper and lower fixing portions 311 and 321 Can be coupled to the first vertical support plate 312 and the second vertical support plate 322 by bolt tightening or the like.

5 is a perspective view showing a coupling relationship of the second facing member.

5, an engaging hole 36 having an enlarged latching portion 361 is coupled to the upper and lower ends of the second facing member 34, 2 engaging grooves 314 and 324 are formed on the upper surface of the engaging plate 323 and on the upper surface of the lower fixing portion 321 and on the lower surface of the first engaging plate 313 so that the enlarging engaging portion 361 is slidably engaged with the side surface . ≪ / RTI >

In this case, when the joint assembly 3 is manufactured, the upper and lower modules 31 and 32 are joined together, and then the second seam member 34 is slidably inserted from the side.

The enlarged latching portion 361 may be formed in a T-shape or a Dovetail shape in cross section.

The latching grooves 314 and 324 can be formed in a shape corresponding to the enlarged latching portion 361.

FIG. 6 is a perspective view showing still another embodiment of an optical joint assembly for a solar cell module of the present invention, and FIG. 7 is a perspective view showing another embodiment of an optical joint assembly for a solar cell module of the present invention in which upper and lower modules are separated Fig.

6, between the first vertical support plate 312 and the second engagement plate 323 and between the second vertical support plate 322 and the first engagement plate 313, A member 35 may be provided.

The third facing member (35) can be manufactured using the same material as the first facing member (33).

When the relative displacement between the upper module 31 and the lower module 32 occurs in the horizontal direction, seismic performance can be secured by the elastic deformation in the axial direction of the third facing member 35, that is, in the horizontal direction.

Since the third seam member 35 is formed in a direction orthogonal to the first facing member 33, seismic performance can be ensured in both the vertical and horizontal directions.

It is also possible to deal with the occurrence of rotational displacement of the joint assembly 3.

In addition, the vertical load can be supported by the shearing rigidity of the third yoke 35.

4, the first face-to-face member 33 has the upper and lower portions thereof connected to the second engaging plate 323 and the first engaging plate 313, respectively, in the case where the third face- To be fixed with a bolt.

In this case, it may be difficult to fasten the bolts due to the interference between the upper fixing part 311 and the lower fixing part 321. Therefore, a part or all of the upper fixing part 311 and the lower fixing part 321 may be fixed to the first vertical supporting plate 312 And the second vertical support plate 322, respectively.

The upper and lower portions of the first facing member 33 are bolted to the second engaging plate 323 and the first engaging plate 313 and then the upper and lower fixing portions 311 and 321 Can be coupled to the first vertical support plate 312 and the second vertical support plate 322 by bolt tightening or the like.

The third facing member 35 may be installed before or after the separated upper fixing part 311 and the lower fixing part 321 are coupled.

8 is a perspective view showing a coupling relationship of the third pair of facing members.

8, a coupling member 37 having an enlarged latching portion 371 is coupled to both ends of the third face-to-face member 35, and an inner side face of the first vertical support plate 312 An end of the second engaging plate 323 and an end of the first engaging plate 313 of the second vertical supporting plate 322 and the end of the first engaging plate 313 are engaged with the engaging groove 315, and 325 may be formed.

In this case, when the joint assembly 3 is manufactured, the upper module 31 and the lower module 32 are combined, and then the third yoke 35 is laterally slidably inserted.

The enlarged latching portion 371 may be formed in a T-shape, a Dovetail shape, or the like.

The engaging grooves 315 and 325 are formed in a shape corresponding to the enlarged engaging portion 371.

1: solar cell module 2: holding
3: Joint assembly 31: Upper module
311: upper fixing part 312: first vertical supporting plate
313: first engaging plate 314: engaging groove
315: latching groove 32: lower module
321: lower fixing part 322: second vertical supporting plate
323: second engaging plate 324: engaging groove
325: latching groove 33: first facing member
34: second facing member 35: third facing member
36: Coupling port 361:
37: coupling port 371:
B: Bolt

Claims (5)

(3) for a solar cell module for fixing a solar cell module (1) to a support (2)
A first vertical supporting plate 312 provided at a lower portion of the upper fixing portion 311 and an upper fixing portion 311 fixed to a lower portion of the solar cell module 1, An upper module 31 composed of a first coupling plate 313 horizontally bent at a lower end thereof;
A second vertical support plate 322 provided on the upper portion of the lower fixing portion 321 and a second vertical support plate 322 provided on the upper portion of the column 2 fixed to the ground, A lower module 32 consisting of a second coupling plate 323 horizontally bent in the direction of the first vertical support plate 312 of the upper module 31 at the upper end of the lower module 32; And
A first facing member 33 provided between the first coupling plate 313 and the second coupling plate 323; Respectively,
Wherein the upper fixing part (311), the second coupling plate (323), the lower fixing part (321), and the first coupling plate (313) are spaced apart from each other.
The method of claim 1,
And a second facing member 34 is provided between the upper fixing portion 311 and the second coupling plate 323 and between the lower fixing portion 321 and the first coupling plate 313. [ Seismic joint assembly for battery module.
3. The method of claim 2,
An engaging hole 36 having an enlarged engaging portion 361 is coupled to the upper and lower ends of the second facing member 34,
The enlarged latching portion 361 is slid on the lower surface of the lower surface of the upper fixing portion 311, the upper surface of the second coupling plate 323 and the upper surface of the lower fixing portion 321, And an engaging groove (314, 324) which is engaged with the engaging groove (314, 324) is formed.
The method of claim 1,
A third facing member 35 is provided between the first vertical supporting plate 312 and the second engaging plate 323 and between the second vertical supporting plate 322 and the first engaging plate 313 Characterized in that the joint is an optical fiber.
5. The method of claim 4,
Coupling ports 37 each having an enlarged latching portion 371 are coupled to both ends of the third facing member 35,
The inner surface of the first vertical support plate 312, the end of the second engagement plate 323, the inner surface of the second vertical support plate 322, and the end of the first engagement plate 313, (315, 325) for slidingly engaging with the side wall (371) on the side surface are formed.

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