KR101348734B1 - Support for photovoltaic module - Google Patents

Abstract

The present invention relates to a support structure for photovoltaic power generation module of which the vibration and noise caused by wind loads and the supporting state can be maintained stably at the same time. The present invention comprises multiple of first holdings vertically fixed to the installation location of the photovoltaic module, multiple of second holdings vertically fixed to the rear side of the first holding and is formed longer than the first holding, a plurality of vertical members installed and inclined along to the longitudinal direction of the upper end of the first and second holdings, a plurality of horizontal members disposed laterally on the vertical members, and a plurality of clamps in the beam which is to combine the horizontal members on the photovoltaic module. In particular, the photovoltaic module of the clamp surface in contact with the first uneven portion and a resilient pad is interposed to absorb the vibration and the noise made from between the first uneven portion and the photovoltaic module, wherein the horizontal member of PV in contact with the surface of the photovoltaic module with a module to increase the frictional force between the second part is formed.

Description

Support structure for photovoltaic module {Support for photovoltaic module}

The present invention relates to a support structure for a photovoltaic module, and more particularly, to a support structure for a photovoltaic module that is improved to prevent vibration, noise and slip due to wind load of a photovoltaic module, and to maintain a stable support state. .

As the reserves of fossil fuels are finite and environmental pollution due to the use of fossil fuels is a serious problem, the new energy and renewable energy industries that can actively respond to sustainable energy supply and environmental regulations have recently been spotlighted.

In Korea, three areas of new energy are designated: fuel cells, coal liquefied gasification, and hydrogen energy. Renewable energy includes eight areas: solar, solar, biomass, wind, small hydro, geothermal, marine, and waste energy. A field is designated.

Among them, in the photovoltaic power generation industry related to the present invention, a module (solar panel), which is a collection of solar cells that convert solar energy into electrical energy using a photoelectric effect, and a light collection efficiency, In view of this, it is important to develop a supporting structure that stably supports a plurality of modules in a state suitable for the incident angle of sunlight.

The support structure for a photovoltaic module is known in a number of patent technologies, both domestic and international, and Patent Document 1 and Patent Document 2 in the following prior art documents are given as examples.

The support structure of Patent Literature 1 includes a base having a support frame for supporting a photovoltaic module fixed thereto, a pole fixed to the base while being fixed to the ground, and an inclined support member supporting the base spaced apart from the ground. consist of. Thereby, the support structure of patent document 1 has the characteristic to simplify the operation | work which supports a photovoltaic module on the ground, and to change the position and height of a photovoltaic module by adjusting the length of a pole.

In addition, the supporting structure of Patent Literature 2 includes a plurality of leaflet frames vertically mounted on a rooftop floor of a building, and a plurality of leaflet frames longer in length than the leaflet frame and vertically mounted on a rooftop floor of a building to be spaced apart from the leaflet frame. A plurality of vertical frames connecting the rear support frame, the plurality of leaflet paper frames and the rear support frame, respectively, and a plurality of horizontal frames mounted on top of each vertical frame so as to vertically intersect the vertical frames, And a clamping means for clamping the optical panel to the horizontal frame. The supporting structure of Patent Document 2 focuses on simply fixing the upper portion of the horizontal frame without damaging the solar panel using a clamping means.

On the other hand, the photovoltaic module is a collection of solar cells that are finished in the form of panels by connecting the solar cells to each other, and is subjected to mechanical loads due to strong winds or earthquakes, resulting in deformation of the module and over time Fatigue is caused in the constituent material, and in particular, a material such as a copper wire connecting the solar cell may be easily damaged. Even weak winds cause vibrations in the module, so it is necessary to cope with such vibrations in consideration of the life of the photovoltaic module. In addition, the support structure for supporting the photovoltaic module should be able to maintain a stable state without the module slips due to wind or earthquake and other external force at the time of installation or installation of the module.

By the way, the support structures for the conventional photovoltaic module, including the support structures of the patent documents cited above, lack a means for coping with the vibration applied to the module as well as a means for preventing the slip of the module.

In addition, the electrical energy produced by the solar power module is transmitted to the transformer through a wire, in the conventional solar power module support structure, the wire extending from the module to the transformer, etc. is not arranged on the rear side of the support structure. Due to its neglect, the appearance may be impaired.

[Patent Document 1] Republic of Korea Patent No. 10-1142898 (Name: Photovoltaic module support structure, Patent Holder: Ilkwang Solar Energy Co., Ltd.) [Patent Document 2] Korean Patent Publication No. 10-2013-0097043 (Name: Supporting structure of the solar panel, Applicant: Daeyoung Metal Co., Ltd.)

As described above, the currently known support structure for photovoltaic modules lacks a means to cope with vibrations applied to the module, thereby causing deformation, fatigue and damage of the module due to strong winds or earthquakes. Accordingly, there is a problem in that the lifespan of the solar power module is shortened.

In addition, the conventional support structure for photovoltaic modules lacks a means to stably maintain the module without slipping due to wind or earthquake and other external forces during installation or installation of the module, and thus photovoltaic power generation. Stable installation of the module is difficult, and thus there is a problem that can not guarantee the life of the module.

In addition, the conventional support structure for photovoltaic modules also has a problem that the appearance is impaired because the wires for transmitting the electrical energy produced in the module is left unorganized.

The present invention was developed to improve these conventional problems, the object of which is to prevent the vibration caused by wind or earthquake, etc. applied to the photovoltaic module and to prevent the module from slipping during installation or installation of the module. By providing a means for providing a support structure for a photovoltaic module that can ensure a stable installation and long-term life of the module.

In another aspect, the present invention provides a support structure for a photovoltaic module that has a structure capable of concealing the electric wires for transmitting electrical energy produced by the module, thereby improving the appearance deterioration due to overexposure of the electric wires. There is a purpose.

The support structure for a photovoltaic module of the present invention for achieving the above object is a plurality of first supports vertically fixed to the installation site of the photovoltaic module, and formed longer than the first support is the rear side of the first post A plurality of second supports vertically fixed to the plurality of vertical members, the plurality of vertical members being inclined in the longitudinal direction along the upper sides of the first and second supports, and a plurality of horizontally disposed on the vertical members It includes a member and a plurality of clamps for coupling the photovoltaic module on the horizontal member. Further, in the present invention, the first uneven portion is formed on the surface in contact with the photovoltaic module of the clamp, and the elastic pad for absorbing vibration and noise is interposed between the first uneven portion and the photovoltaic module, the horizontal member The surface in contact with the photovoltaic module is provided with a structure in which a second uneven portion is formed to increase the friction between the photovoltaic module and prevent the detachment and slip of the photovoltaic module.

In the above configuration, each of the first holding and the second holding is provided with an insertion groove that can be inserted into the electric wire for transmitting electricity generated in the solar power module on any one side or more, and coupled to the insertion groove The shielding member may be further provided to hide the wires inserted into the insertion grooves so as not to be exposed.

In the above configuration, a first bracket is assembled to the first holding and the second holding, respectively, and a second bracket coupled to the first bracket is assembled to the bottom of the vertical member, and the bottom of the bottom of the vertical member is assembled. A downwardly protruding flange is formed, and the second bracket has a latching jaw in which the vertical member flange is seated, thereby preventing the second bracket from rotating or shaking in the assembled state of the vertical member and the second bracket. .

In the support structure for a photovoltaic module of the present invention configured as described above, the elastic pad interposed between the photovoltaic module and the clamp absorbs vibrations and generated noise applied to the photovoltaic module by wind or earthquake and so on. To prevent deformation, fatigue and breakage of the module, and the uneven portion of the horizontal member to provide a friction force to the bottom portion and the side portion of the photovoltaic module to prevent the phenomenon that the photovoltaic module is separated and slipped on the horizontal member. Therefore, the support structure for a solar power module of the present invention has the effect of ensuring the stable installation and long-term life of the solar power module.

In addition, the support structure for the photovoltaic module of the present invention is to conceal the wires for transmitting the electrical energy produced in the module inside the first and second holding, thereby improving the appearance beauty due to overexposure of the wire There is.

1 is an assembled state perspective view of an embodiment of a support structure for a photovoltaic module according to the present invention.
Figure 2 is a perspective view showing a state in which the photovoltaic module is installed on the support structure of FIG.
3 is a perspective view showing the installation state of the first column and the second column in the support structure of FIG.
4 is an exploded perspective view of the first column and the first bracket in the support structure of FIG.
5 is an exploded perspective view of the vertical member and the second bracket in the support structure of FIG.
6 is a cross-sectional view illustrating an assembly state of the vertical member and the second bracket of FIG. 5.
FIG. 7 is a perspective view illustrating an assembly relationship between the first column and the vertical member in the supporting structure of FIG. 1.
FIG. 8 is a perspective view illustrating an assembly state of the first column and the second column and the vertical member in the supporting structure of FIG. 1.
9 is a perspective view illustrating an assembly relationship of horizontal members to vertical members in the supporting structure of FIG. 1.
10 is a side view of the support structure of FIG. 1.
FIG. 11 is an enlarged cross-sectional view of part A of FIG. 10.
12 is a perspective view of the first holding (or second holding) provided in the present invention.
FIG. 13 is a perspective view illustrating a state in which an electric wire is inserted into the support of FIG. 12. FIG.
14 is a perspective view illustrating a state in which a covering member is coupled to the support of FIG. 13.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it should be understood that the following embodiments are provided so that those skilled in the art can understand the present invention without departing from the scope and spirit of the present invention. It is not.

First, Figure 1 is an assembled state perspective view of an embodiment of a support structure for a photovoltaic module according to the present invention, Figure 2 is a perspective view showing a state in which the photovoltaic module is installed on the support structure of Figure 1, the support structure The assembly of the first holding 10, the second holding 20, the holding connecting member 30, the vertical member 40, the horizontal member 50 and the photovoltaic module 60 constituting the .

The first holding 10, the second holding 20, the support connecting member 30, the vertical member 40, the horizontal member 50, and the first bracket 70, the second bracket (described below) 80), the components such as the clamp 90 may be made of various materials such as aluminum alloy or plastic, but will be described on the premise that the configuration is made of aluminum alloy.

The first holding 10 and the second holding 20 are members fixed vertically to the installation place (for example, flat, roof, or all flat places) of the photovoltaic module 60, respectively. The first holding 10 and the second holding 20 are fixed. The first holding 10 and the second holding 20 are manufactured to have different lengths so that the photovoltaic module 60 can be installed to be inclined in response to the incident angle of the sunlight, the first holding fixed to the front side The second column 20 fixed to the rear side than the support 10 is formed longer.

Then, between the first holding 10 and the second holding 20, the strut connection member 30 for securing structural stability is inclinedly coupled.

In addition, the plurality of vertical members 40 are installed to be inclined in the vertical direction along the upper sides of the first holding 10 and the second holding 20, the plurality of horizontal members 50 on the vertical members (40) Arranged in the transverse direction at regular intervals, the photovoltaic module 60 is coupled by clamps 90 as shown in FIG. 11 on the horizontal members 50.

3 is a view illustrating an installation state of the first column 10 and the second column 20 in the supporting structure of FIG. 1, wherein the vertical members 10 are respectively formed at upper ends of the first column 10 and the second column 20. The first bracket 70 for assembling 40 is installed.

4 is an exploded perspective view of the first column 10 and the first bracket 70, the interior of the first column 10 is composed of a hollow hollow 10a, the first bracket 70 is hollow By having the insertion end 70a protruding to be inserted into the portion 10a, the bolt (with the insertion end 70a of the first bracket 70 inserted into the hollow portion 10a of the first column 10) 71) and the nut 72 is fixed. Since the second support 20 is assembled with the first bracket 70 similarly to the first support 10, repeated description thereof will be omitted.

Thus, the vertical member 40 is coupled in the state in which the first bracket 70 is assembled to the first support 10 and the second support 20, and for this purpose, the bottom surface of the vertical member 40 is shown in FIG. 5. The second bracket 80 is assembled to the first portion. The second bracket 80 is disposed as a member of the 'c'-shaped cross-section facing down, the upper surface (80a) of the second bracket 80 is in contact with the lower surface of the vertical member (40) On both sides 80b of the second bracket 80, bolt holes 80d corresponding to the bolt holes 70b of the first bracket 70 are formed, as shown in FIG. The bolt hole 80e for assembling with the vertical member 40 is also formed in the upper surface 80a. The first bolt head is inserted into the bottom of the vertical member 40 to insert the head of the bolt 41 to be assembled into the bolt hole 80e provided in the upper surface 80a of the second bracket 80. The groove 40a is formed long along the longitudinal direction of the vertical member 40. Accordingly, in the state where the head of the bolt 41 is inserted into the first bolt head insertion groove 40a of the vertical member 40, the upper surface 80a of the second bracket 80 is abutted to form a bolt hole 80e. The second bracket 80 is assembled to the vertical member 40 by the bolt 41 and the nut 42 are fastened to each other.

Particularly, in the present invention, in order to maintain the state in which the second bracket 80 is stably assembled to the vertical member 40 without rotating or shaking, the bottom surface of the vertical member 40 as shown in FIGS. A flange 40c protruding downward from the lower edge is formed, and a latching jaw in which the flange 40c of the vertical member 40 is seated between the upper surface 80a and both side surfaces 80b of the second bracket 80. 80c) is formed. Accordingly, the second bracket 80 may be prevented from rotating or shaking due to the load applied to the second bracket 80 in a state in which the vertical member 40 and the second bracket 80 are assembled.

FIG. 7 shows a state in which the vertical member 40 having the second bracket 80 assembled thereon is assembled to the first bracket 70 on the first column 10. That is, the nut 74 is inserted by inserting the bolt 73 in a state where the bolt holes 70b of the first bracket 70 are aligned with the bolt holes 80d formed on both sides 80b of the second bracket 80. By fastening, the vertical member 40 and the first column 10 are assembled. Since the assembling relationship between the second support 20 and the vertical member 40 is also the same as the assembling relationship between the first support 10 and the vertical member 40, repeated description thereof will be omitted. FIG. 8 illustrates a state in which the vertical member 40 is assembled on the first and second supports 10 and 20.

Next, Figure 9 shows the assembling relationship of the horizontal member 50 to the vertical member 40 in the support structure of Figure 1, as shown in Figure 5 and Figure 9 in the upper side of the vertical member 40 A second bolt head insertion groove 40b into which the head of the bolt 51 is inserted is formed so that the horizontal member 50 is assembled by the bolt 51 and the nut 52. In addition, a flange surface 50a is formed at a lower portion of the horizontal member 50 in which a bolt hole 50b for fastening the bolt 51 and the nut 52 is formed. Therefore, the flange surface 50a of the horizontal member 50 on the upper side of the vertical member 40 in a state where the head of the bolt 51 is inserted into the second bolt head insertion groove 40b of the vertical member 40. ), The bolt 51 and the nut 52 are fastened through the bolt hole 50b of the flange surface 50a, whereby the horizontal member 50 is assembled on the vertical member 40.

On the other hand, in the upper portion of the horizontal member 50, in order to assemble the photovoltaic module 60, a mounting surface 50c and a vertical surface 50d are formed vertically upward in the center of the mounting surface 50c. A third bolt head insertion groove 50f is formed along the longitudinal direction of the horizontal member 50 so as to bisect the vertical surface 50d. Accordingly, as shown in FIGS. 10 and 11, the clamp (in the state where the bottom portion and the side portion of the photovoltaic module 60 are seated to contact the seating surface 50c and the vertical surface 50d of the horizontal member 50. The assembly is achieved by the 90 and the bolt 53 and the nut 54.

As shown in FIG. 11, the clamp 90 has a cross-sectional structure in which a 'b' shape and an inverted 'a' shape are symmetrically bent so that a pair of photovoltaic modules 60 may be assembled upside down. In the center of the clamp 90, a bolt hole into which the bolt 53 is inserted is formed. In particular, the surface of the clamp 90 in contact with the photovoltaic module 60 is formed with a first uneven portion 90a having a sawtooth shape, and between the first uneven portion 90a and the photovoltaic module 60. There is an elastic pad 100 made of a material such as rubber is interposed.

Accordingly, the pair of photovoltaic modules 60 is seated on the horizontal member 50, and the head portion of the bolt 53 is inserted into the third bolt head insertion groove 50f of the horizontal member 50. In a state where the clamp 90 is disposed between the pair of photovoltaic modules 60 together with the elastic pad 100, the body portion of the bolt 53 is inserted into the bolt hole of the clamp 90 so that the nut ( When the 54 is fastened, the elastic pad 100 is bitten and fixed to the first uneven portion 90a of the clamp 90 due to the fastening force between the bolt 53 and the nut 54. Thus, the elastic pad 100 interposed between the photovoltaic module 60 and the clamp 90 absorbs vibrations and generated noise applied to the photovoltaic module 60 by a strong wind or an earthquake. Deformation, fatigue and breakage of the (60) is prevented.

In addition, as shown in FIGS. 9 and 11, the mounting surface 50c and the vertical surface 50d of the horizontal member 50 are in contact with the bottom portion and the side portion of the photovoltaic module 60. The second concave-convex portion 50e such as the sawtooth shape that increases the frictional force is formed between the first and second portions 60). Therefore, as described above, when the photovoltaic module 60 is seated on the horizontal member 50 and assembled by the clamp 90, the bolt 53, and the nut 54, the second uneven portion 50e is provided. By pressing) provides a frictional force to the bottom and side portions of the photovoltaic module 60 to prevent the photovoltaic module 60 from being separated and slipped on the horizontal member (50).

12 to 14 are diagrams showing the configuration of the first holding (or second holding) provided in the present invention. As shown in FIGS. 12 to 14, the first and second supports 10 and 20 are each of the photovoltaic module 60 on at least one side of the front side, the rear side, the left side, and the right side. An insertion groove 10b or 20b into which an electric wire W for transmitting electricity can be inserted is provided, and the insertion groove 10b or 20b includes an electric wire W inserted into the insertion groove 10b or 20b. The cover member 11 or 21 which hides so that it may not be exposed is combined. That is, the electrical energy produced by the photovoltaic module 60 is transmitted to a transformer through a wire (W), in the support structure for a conventional photovoltaic module, a wire extending from a photovoltaic module to a transformer ( W) is left unarranged on the rear side of the support structure, but the appearance is impaired, but in the present invention, the wires are inserted into the insertion grooves 10b or 20b formed in the first column 10 and the second column 20. Since (W) is concealed by the cover member 11 or 21 in the inserted state, the appearance beauty can be prevented.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, This is possible.

10: first column 10a: hollow portion
10b, 20b: Insertion groove 11.21: Screening member
20: second holding 30: strut connecting member
40: vertical member 40a: the first ball head insertion groove
40b: 2nd bolt head insertion groove 40c: flange
41, 51, 53, 71, 73: Bolt 50: Horizontal member
50a: Flange surface 50b, 70b, 80d, 80e: Bolt hole
50c: seating surface 50d: vertical surface
50e: Uneven portion 50f: Third bolt head insertion groove
52,54,72,74: Nut 60: PV module
70: first bracket 70a: insertion end
80: second bracket 80a: upper side
80b: Both sides 80c: Hanging jaw
90: clamp 90a: uneven portion
100: elastic pad W: electric wire

Claims (3)

A plurality of first supports vertically fixed to the installation location of the photovoltaic module, a plurality of second supports formed longer than the first supports and vertically fixed to the rear side of the first support, and the first and second supports A plurality of vertical members are installed to be inclined in the longitudinal direction along the upper side of the support, a plurality of horizontal members disposed in the transverse direction on the vertical members, and a plurality of coupling of the photovoltaic module on the horizontal member Includes a clamp,
A first uneven portion is formed on a surface of the clamp contacting the photovoltaic module, and an elastic pad is disposed between the first uneven portion and the photovoltaic module to absorb vibration and noise.
A support for a photovoltaic module having a second uneven portion formed on a surface of the horizontal member in contact with the photovoltaic module so as to increase frictional force between the photovoltaic module and prevent slippage and slippage of the photovoltaic module. structure.
The method of claim 1,
Each of the first holding and the second holding is provided with an insertion groove into which an electric wire for transmitting electricity generated by the solar power module is inserted into at least one side thereof, and is coupled to the insertion groove and inserted into the insertion groove. The support structure for a solar power module, characterized in that the shielding member is further provided so as not to expose the wires.
The method of claim 1,
A first bracket is assembled to the first support and the second support, respectively, and a second bracket coupled to the first bracket is assembled to the bottom of the vertical member.
A downwardly protruding flange is formed at the bottom edge of the vertical member, and the second bracket has a locking jaw in which the flange of the vertical member is seated, and the second bracket is assembled with the vertical member and the second bracket. The support structure for a solar power module, characterized in that the rotation or shaking can be prevented.

Images