KR102246583B1 - Support structure of photovoltaic module - Google Patents

Abstract

Disclosed is a support structure for a solar module. The support structure of the photovoltaic module according to the present embodiment includes a plurality of frames that are installed perpendicular to the ground and are arranged in parallel at the front and rear sides, respectively; A girder connected to the upper end of the plurality of frames to support the solar module; A bridge connecting adjacent frames among a plurality of frames; And a plurality of fastening portions that allow rotation of the frame while connecting the frame with the girder and the bridge, respectively, wherein each fastening portion includes a clamp provided at one end of the girder and the bridge to support the frame, and the upper and lower sides of the clamp It may be provided, including a pair of separation preventing members protruding to the outside of the frame.

Description

Support structure of solar module{SUPPORT STRUCTURE OF PHOTOVOLTAIC MODULE}

The present invention relates to a support structure for a solar module, and more particularly, a foundation can be buried in a state in which some of the support structures are pre-assembled, thereby shortening the construction period, reducing construction errors, and improving structural performance. It is a supporting structure for a solar module.

In recent years, solar power generation is rapidly decreasing the power generation cost per unit power generation capacity along with the improvement of the productivity of the solar module, which is a major material, and the market is also rapidly expanding.

In order to maximize the efficiency of solar modules for photovoltaic power generation, it is most advantageous to install the photovoltaic module vertically with the photovoltaic power, and accordingly, the power generation efficiency due to the shade and the south-central altitude of the sun for each season according to the installation area can be reduced. The installation angle is determined in consideration. In domestic solar power facilities, solar modules are mainly installed with an inclination of around 20 degrees. The supporting structure of the solar module is installed for the purpose of maintaining such an installation angle, maintenance of the solar module, preventing damage, etc. At this time, a metal material such as steel or aluminum is mainly used.

In the supporting structure of the existing solar module, the frame, which serves as a pillar of the structure, is erected vertically on the ground, and a girder is fastened to the upper part of the frame to secure space to install the solar module. After fastening the girder, a plurality of perlins are installed on the upper part of the girder in a direction orthogonal to the girder, and a photovoltaic module is installed on the upper part of the perlin, so that the load of the solar module is transmitted to the frame through the perlin and the girder.

As for the frame, various types of foundations are applied, such as a method of installing the frame directly in the ground, such as a rotary penetration type foundation and a direct penetration type foundation, and a method of placing a separate foundation on-site (Reinforced Concrete) or pre-cast concrete (Pre-cast concrete). I can. However, unlike general structures, the supporting structure of the photovoltaic module does not have a large required load, so a rotational or direct penetration type foundation is mainly used for cost reduction.

When the frame is constructed using the above-described rotary penetration type or direct penetration type foundation, construction errors such as an irregular height of each frame may occur during the process of installing and embedding the frame on the ground. In addition, as the construction error of the support structure is corrected, the construction period may be delayed, and the support performance of the support structure may be deteriorated.

Republic of Korea Patent Publication No. 10-2016-0118440 (published on October 12, 2016)

The present embodiment is to provide a support structure for a solar module that reduces errors that occur when the foundation of the support structure is buried, and reduces construction errors through precision improvement.

This embodiment is to provide a support structure for a solar module capable of shortening the construction period by simultaneously installing a plurality of frames.

The present embodiment is to provide a support structure for a photovoltaic module capable of securing excellent structural stability by improving the pull-out force and bearing capacity of the support structure.

According to an aspect of the present embodiment, a plurality of frames that are installed perpendicular to the ground and arranged in parallel to the front and rear, respectively; A girder connected to an upper end of the plurality of frames to support a solar module; A bridge connecting adjacent frames among the plurality of frames; And a plurality of fastening parts that allow rotation of the frame while connecting the frame to the girder and the bridge, respectively, wherein each of the fastening parts is provided at one end of the girder and the bridge to support the frame. A support structure for a solar module including a clamp and a pair of separation preventing members protruding outwardly of the frame on upper and lower sides of the clamp may be provided.

The clamp may be provided with a support structure for a solar module including a pair of fastening members surrounding the frame at a predetermined distance and a bolt for fastening the pair of fastening members.

The clamp may be provided with a support structure for a solar module including a hinge member for hinge-connecting the pair of fastening members.

The bridge may be provided with a support structure for a solar module having a wedge portion at the lower side.

The bridge may be provided with a supporting structure of a solar module buried below the ground.

The frame may be provided with a supporting structure for a solar module having a spiral protrusion on an outer circumferential surface of the lower end.

The support structure of the photovoltaic module according to the present embodiment has the effect of reducing errors that occur when the foundation of the support structure is buried, and reducing construction errors by improving precision.

The support structure of the solar module according to the present embodiment has the effect of shortening the construction period by simultaneously installing a plurality of frames.

The support structure of the photovoltaic module according to the present embodiment has an effect of securing excellent structural stability by improving the pulling force and bearing capacity of the support structure.

1 is a schematic cross-sectional view showing a support structure of a solar module according to the present embodiment.
FIG. 2 is a cross-sectional view illustrating a portion A-A' of FIG. 1.
3 is a perspective view showing the shape of the bridge according to the present embodiment.
4 is a cross-sectional view showing a state in which the supporting structure of the solar module according to the present embodiment is buried.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. The following examples are presented in order to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains, and may be embodied in other forms without being limited thereto. In the drawings, in order to clarify the present invention, the illustration of parts not related to the description may be omitted, and the size of the constituent elements may be somewhat exaggerated to help understanding.

The most common shape and construction order of the support structure 100 of the existing solar module starts with the installation of the frame 110 serving as a pillar of the structure perpendicular to the ground. The frame 110 performs the mechanics of transmitting the compressive force to the foundation, and various types of members such as H-beam, rectangular steel pipe, and circular steel pipe are applied.

Subsequently, after the frame 110 is installed, the girder 120 is fastened to the upper end of the frame 110. The girder 120 serves to transmit the load of the upper perlin (not shown) to the frame 110, and members such as a square steel pipe and a C-beam are mainly applied.

Next, after the girder 120 is fastened, perlin (not shown) is installed on the top of the girder 120 in a direction perpendicular to the girder 120. Perlin (not shown) is a member that directly mounts a photovoltaic module (not shown) and transfers the load of the module to the lower girder 120. Considering the fastening with the upper photovoltaic module (not shown), C-beam and Z-beam members are mainly applied.

As for the frame 110, various types of foundations such as a method of directly installing the frame 110 on the ground, such as a rotational penetration type foundation and a direct penetration type foundation, and a method of placing a separate foundation on-site or pre-casting may be applied, but general Unlike the structure, the support structure 100 of the solar module does not have a large required load, and therefore, a rotational penetration type or a direct penetration type foundation is mainly used for cost reduction.

When the frame 110 is constructed using a rotational penetration type or a direct penetration type foundation, construction errors such as an inconsistent height of each frame 110 may occur in the process of installing and embedding the frame 110 on the ground. have. This may cause a delay in the construction period of the entire structure, such as the installation of the above-described girder 120 and perlin (not shown), and deterioration of support performance.

Accordingly, the present invention proposes a support structure 100 for a solar module capable of installing and embedding the integrated support structure 100 by pre-assembling a part.

1 is a schematic cross-sectional view showing a support structure 100 of a solar module according to the present embodiment, FIG. 2 is a cross-sectional view showing a portion A-A' of FIG. 1, and FIG. 3 is a view of a bridge according to the present embodiment. It is a perspective view showing the shape, and FIG. 4 is a cross-sectional view showing a state in which the support structure 100 of the solar module according to the present embodiment is embedded.

1 to 4, the support structure 100 of the photovoltaic module is installed vertically with respect to the ground, and a plurality of frames 110 and a plurality of frames 110 are disposed in parallel at the front and rear, respectively. A girder 120 connected to the top to support the solar module, a bridge 130 connecting adjacent frames 110 among a plurality of frames 110, and a girder 120 and a bridge 130 ) And may include a plurality of fastening parts 140 that allow rotation of the frame 110 while being connected to each other, and each fastening part 140 has a girder 120 and a bridge ( It may include a clamp 141 provided at one end of the 130, and a pair of separation preventing members 142 protruding to the outside of the frame 110 on upper and lower sides of the clamp 141.

The frame 110 is installed perpendicular to the ground, and is arranged side by side at the front and rear sides, respectively. In more detail, the plurality of frames 110 are arranged in parallel in a straight line at the front and the rear, respectively, and are installed perpendicular to the ground, and a pearlin (not shown) or a photovoltaic module (not shown) is placed on the top of the frame 110. The supporting girder 120 is combined.

In addition, among the plurality of frames 110, the frame 110 located at the front and the frame 110 located at the rear may have different lengths, and accordingly, the girder 120 coupled to the upper end of the frame 110 may be inclined. Can be formed.

The plurality of frames 110 may be connected to adjacent frames 110 by a bridge 130. In more detail, the plurality of frames 110 may be connected to lower ends of adjacent frames 110 by bridges 130 in order to improve structural stability. After assembling the frame 110 and the bridge 130, the frame ( If 110) is penetrated into the ground, the bridge 130 can be buried together under the ground, and structural stability and bearing capacity can be further improved.

Each frame 110 may have a spiral protrusion 111 on the outer circumferential surface of the lower end. The frame 110 is formed in a cylindrical shape and can be directly penetrated under the ground. In order to easily penetrate under the ground, the frame 110 has a spiral protrusion 111 on the outer circumferential surface of the lower end so that the frame 110 rotates and goes below the ground. Rotational penetration may also occur. Further, if the helical protrusion 111 is provided on the outer circumferential surface of the frame 110, it is easy to intrude to the bottom of the ground, and the bearing capacity after embedding is improved, so that excellent structural stability can be secured.

In addition, the frame 110 is provided to be rotatable while being connected by the girder 120 and the bridge 130 and the fastening part 140, the ground in a pre-assembled state with the girder 120 and the bridge 130 Can be installed on In more detail, the frame 110 may be erected on the ground in a state assembled with the girder 120 and the bridge 130 as shown in FIG. 1, and in a state in which the pre-assembled structure 100 as shown in FIG. 4 is erected on the ground. The frame 110 may be directly penetrated or rotated under the ground.

The girder 120 may be connected to the upper end of the plurality of frames 110 to support a solar module (not shown). In more detail, the girder 120 may be formed in the shape of a square plate coupled to the upper end of the plurality of frames 110, and a perlin (not shown) is installed in the orthogonal direction on the upper portion of the girder 120, a plurality of A photovoltaic module is mounted on the upper part of Perlin (not shown) to generate energy from sunlight.

A first bracket 121 is provided at one end of the girder 120 and may be connected to the frame 110 by a fastening part 140 to be described later.

The bridge 130 may connect adjacent frames 110 among the plurality of frames 110. In more detail, second brackets 131 coupled to the fastening portions 140 are provided at both ends of each bridge 130 and connected to the frame 110 by the fastening portions 140.

Bridge 130 is provided with a wedge portion (130a) on the lower side, it is possible to easily embed the bridge 130 below the ground, and secures excellent bearing capacity after embedding. In more detail, the bridge 130 has a wedge portion 130a having a cross section formed in an inverted triangle or a'V' shape and protruding sharply at the lower side, so that when the frame 110 is penetrated below the ground, the bridge 130 Also, it should be easily buried together. In other words, as shown in Fig. 1, the frame 110, the girder 120, and the structure 100 in which the bridge 130 are pre-assembled are erected on the ground, and the frame 110 is embedded below the ground through direct penetration or rotational penetration. However, by providing a wedge portion 130a on the lower side of the bridge 130, it is easy to embed, and it is possible to secure excellent bearing capacity even after embedding.

A plurality of fastening parts 140 may be provided to allow rotation of the frame 110 while connecting the frame 110 to the girder 120 and the bridge 130, respectively, and each fastening part 140 may be provided with a frame ( To support 110), a clamp 141 provided at one end of the girder 120 and the bridge 130, and a pair of protruding to the outside of the frame 110 on the upper and lower sides of the clamp 141 to prevent separation It may include a member 142.

The clamp 141 includes a pair of fastening members 141a surrounding the frame 110 at a predetermined distance, a bolt 141b for binding the pair of fastening members 141a, and a pair of fastening members ( It may include a hinge member (141c) for hinge-coupled to the 141a).

Each of the pair of fastening members 141a may form a semicircular inner circumferential surface, and when the pair is coupled, a circular inner circumferential surface may be formed to surround the cylindrical frame 110. In addition, the inner diameter of the fastening member 141a is formed larger than the outer diameter of the frame 110 so that a predetermined gap is formed between the fastening member 141a and the frame 110 when a pair of fastening members 141a are coupled. Can be.

A pair of fastening members (141a) is provided with a hinge member (141c) hinged to one side, the other side is provided to be able to bind and release, and a pair of fastening members (141a) is wrapped around the frame (110) In the bolt (141b) can be bound. In addition, the bolt 141b may pass through the bracket of the pair of fastening members 141a and the bridge 130 or the girder 120 together to connect the frame 110 and the bridge 130 or the girder 120 .

A pair of separation preventing members 142 may be formed to protrude to the outside of the frame 110 on the upper and lower sides of the clamp 141. In more detail, the separation preventing member 142 is formed to protrude from the upper and lower sides of the clamp 141 to restrict the clamp 141 from moving in the longitudinal direction of the frame 110.

As described above, the fastening part 140 prevents movement of the frame 110 while securing structural stability of the frame 110 by connecting the girder 120 and the bridge 130 and the frame 110, but the frame ( 110) makes it possible to rotate in place. That is, in order to easily embed the integrated support structure 100 in the ground by pre-assembling the support structure 100 of the photovoltaic module, the girder 120 and the bridge 130 and the frame 110 are connected to the fastening part 140 ) In a state connected to the ground, the frame 110 and the bridge 130 can be penetrated under the ground.

If the pre-assembled support structure 100 is embedded in this way, construction errors that may occur in the process of separately embedding each frame 110 can be reduced, and since a plurality of frames 110 can be simultaneously embedded, the construction period is shortened. You can plan. In addition, the structural stability may be improved through the connection of the bridge 130, and the bearing capacity may be increased even after embedding.

Preferably, if the plurality of frames 110 are simultaneously rotated and penetrated while the supporting structure 100 of the solar module is erected on the ground, construction errors and construction periods can be reduced.

Until now, specific embodiments of the support structure 100 of the solar module of the present invention have been described, but it is obvious that various implementation modifications are possible within the limit not departing from the scope of the present invention.

Therefore, the scope of the present invention is limited to the described embodiments and should not be transmitted, and should be determined not only by the claims for patent registration to be described later, but also by those equivalents to the claims for patent registration.

That is, it should be understood that the above-described embodiments are illustrative in all respects and not limiting, and the scope of the present invention is indicated by the patent registration claims to be described later rather than the detailed description, and the meaning of the patent registration claims and It should be construed that all changes or modifications derived from the scope and equivalent concepts are included in the scope of the present invention.

100: support structure of the solar module 110: frame
111: protrusion 120: girder
121: first bracket 130: bridge
130a: wedge part 131: second bracket
140: fastening part 141: clamp
141a: fastening member 141b: bolt
141c: hinge member 142: separation preventing member

Claims (6)

A plurality of frames installed perpendicular to the ground and disposed in parallel at the front and rear sides, respectively;
A girder connected to an upper end of the plurality of frames to support a solar module;
A bridge connecting adjacent frames among the plurality of frames; And
Including; a plurality of fastening portions that allow the frame to rotate relative to the girder and the bridge while connecting the frame to the girder and the bridge, respectively,
Each of the fastening parts
A clamp provided at one end of the girder and the bridge to support the frame, and surrounding the frame at a predetermined distance,
A support structure for a solar module comprising a pair of separation preventing members protruding outward of the frame to support upper and lower sides of the clamp to prevent vertical movement of the clamp. The method of claim 1,
The clamp is
A support structure for a photovoltaic module comprising a pair of fastening members surrounding the frame at a predetermined distance and a bolt for fastening the pair of fastening members. The method of claim 2,
The clamp is
A support structure for a solar module comprising a hinge member for hinge-coupled to the pair of fastening members. The method of claim 3,
The bridge is
A supporting structure for a solar module having a wedge on the lower side. The method of claim 4,
The bridge is
Support structure for solar modules buried under the ground. The method of claim 5,
The frame is
A supporting structure for a solar module having a spiral protrusion on the outer circumferential surface of the lower end.

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