KR101839352B1 - Binding structure of solar module and structure - Google Patents

Abstract

The present invention discloses the binding structure of a solar module and a binding method. It is possible to quickly and easily bind a solar module and a structure by using a fixing pin and a wire. Especially, it is possible to prevent the solar module from being separated from the structure due to the separation of a fastener such as a bolt and a nut and being broken down to the ground and the problem of corrosion of the fastener, by not connecting the solar module and the structure with the fastener. The binding structure further includes a solar cell module, a wire, and a tension control unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar module,

The present invention relates to a joining structure and a binding method of a solar module and a structure, and more particularly, to a joining structure of a solar module and a structure, A structure including a fixed frame having a cross section fixedly connected at regular intervals and having a first fastening hole formed at a predetermined interval along an upper surface thereof; A solar cell module including a solar cell module, a solar cell module, a solar cell module, and a solar cell module, the solar module module including: A photovoltaic module including a support frame formed with two fastening holes; The first and second fastening holes are inserted into the support frame sequentially so as to penetrate through the first fastening holes and the second fastening holes sequentially. When the fastening holes pass through the second fastening holes, A fixing pin which collapses and is in close contact with an inner circumferential surface of the lower plate so as to stay inside the support frame without being released to the outside; A wire having a predetermined length fixed at one end thereof to the fixing pin; And a plurality of fixing pins each having a wire wound and fixed to one side thereof, the fixing pins being inserted into the first and second fastening holes from the bottoms of both sides of the structure in order so as to sequentially pass through the first and second fastening holes, And the other end of each of the wires is connected to the tension adjusting means to adjust the tension so as to increase the binding force between the solar cell module and the structure.

As well known, the development and commercialization of new and renewable energy is accelerating due to the limitations of conventional fossil fuel-based power generation due to the growing demand for electric power and electric power peak system.

Especially, the power generation using solar light can be used variously from general household to industrial use depending on the installation scale, and it is advantageous that it can produce infinite energy without generating environmental pollution by using clean solar energy Is growing at a faster pace in light of other renewable energy sources.

The solar power generation device using solar light is mostly installed outdoors due to the use of the sun, and the solar power is installed on an outer wall, a roof, a roof, or a floor of the building.

In order to increase solar light receiving efficiency, a certain inclination angle is also installed in such a solar power generation apparatus. In the conventional solar power generation apparatus, the solar module and the support frame are fixedly mounted on the horizontal and vertical support rods.

However, as a solar module installed and fixed with such a structure has a certain period of time, the clip fixing portion is loosened and a strong wind such as a typhoon blows and the fixing portion is loosened, As the solar module is broken due to frequent vibration and impact, the power generation efficiency is lowered due to short-circuiting of the electrical connection part, and the solar module itself blows away from the wind, there is a possibility of causing more economic damage. need.

In addition, in order to compensate for the disadvantage that the fixing force is lowered by fixing with a simple clip or the like in the prior art, there are cases where various types of fixed structures are used. However, since the number of components is increased, the production cost is increased, .

Due to such an economic problem, a solar module and a structure are coupled through a bolt and a nut. However, as time passes, the coupling force between the bolt and the nut is lowered and the solar module is detached from the structure A problem has occurred. The reason for the loosening of the nut is that the contact pressure is small due to the short length of the nut and momentarily decreases due to the vibration or impact around it. The slip phenomenon repeatedly occurs at the screw joint, This is caused by the phenomenon that the screw is contracted and expanded and the screw joint is weakened.

Korean Registered Patent No. 10-1218237 (inclined roof fixed solar power generation device) Korean Patent Laid-Open Publication No. 10-2014-0132863 (Photovoltaic module fixing device)

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a solar module and a structure thereof which can be easily and quickly bound together, and in particular, a solar module and a structure are not fastened with fasteners such as bolts and nuts, The present invention provides a solar module and a method of bonding the solar module to the solar module, which can solve the problem that the solar module is detached from the structure due to the detachment and is broken down to the ground and the corrosion of the fastener is caused.

In order to achieve the above-mentioned object, the present invention provides a vertical frame, comprising: a vertical frame vertically installed on a ground; a horizontal frame coupled to an upper portion of the vertical frame; And a fixing frame having a first fastening hole formed at regular intervals along an upper surface thereof; A solar cell module including a solar cell module, a solar cell module, a solar cell module, and a solar cell module, the solar module module including: A photovoltaic module including a support frame formed with two fastening holes; The first and second fastening holes are inserted into the support frame sequentially so as to penetrate through the first fastening holes and the second fastening holes sequentially. When the fastening holes pass through the second fastening holes, A fixing pin which collapses and is in close contact with an inner circumferential surface of the lower plate so as to stay inside the support frame without being released to the outside; A wire having a predetermined length fixed at one end thereof to the fixing pin; And a plurality of fixing pins each having a wire wound and fixed to one side thereof, the fixing pins being inserted into the first and second fastening holes from the bottoms of both sides of the structure in order so as to sequentially pass through the first and second fastening holes, And the other end of each wire is connected to the tension adjusting means to adjust the tension to increase the binding force.

Also, in the present invention, the wire is formed of a carbon fiber material.

In the present invention, the tension adjusting means is a turnbuckle.

In addition, in the present invention, the wire has an elastic force to disperse a concentrated load generated in the structure and the solar module during the tensioning operation of the wire, at a portion corresponding to the inlet portion of the first fastening hole, And a concentrated load distribution member made of a material is inserted.

According to another aspect of the present invention, there is provided a method of manufacturing a solar module, comprising: forming a first fastening hole at a predetermined interval on a top surface of a stationary frame for supporting a solar module formed on a structure fixed on the ground; Forming a second fastening hole of the same diameter at a position corresponding to the first fastening hole on a support frame provided in the solar module; Preparing two fixing pins on one side of which a wire is wound and fixed; Inserting the two fixing pins into the inside of the supporting frame so as to sequentially pass through the first and second fastening holes in the lower portions of both side edges of the structure; And connecting the other end of each wire to the tension adjusting means and adjusting the tension to fix the solar module and the structure firmly.

According to the present invention as described above, the solar module and the structure can be quickly and easily coupled using the fixing pin and the wire. In particular, since the solar module and the structure are not fastened to fasteners such as bolts and nuts, There is a remarkable effect that the solar module is detached from the structure and broken down to the ground and the problem of the corrosion of the fastener is prevented.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a photovoltaic power generation system according to an embodiment of the present invention; FIG.
3 is a schematic illustration for explaining a state in which a solar module and a structure are connected according to an embodiment of the present invention;
Fig. 4 is a schematic illustration for explaining a concentrated load avoiding member according to the present invention; Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

The present invention can quickly and easily bind a solar module and a structure, and in particular, a solar module and a structure are not fastened to fasteners such as bolts and nuts, so that the solar module is separated from the structure The present invention relates to a solar module, a structure for coupling the structure, and a tie-up method.

Referring to FIGS. 1 and 2, the structure 10 separates the solar module 20 from the ground by a predetermined height to facilitate the collection of sunlight. The solar module 20 includes a vertical frame 11 vertically installed on the ground, A horizontal frame 12 coupled to an upper portion of the vertical frame, and a fixed frame 13 having a "C" shape in cross section fixedly connected to the upper portion of the horizontal frame at regular intervals.

Although not shown in the drawing, the horizontal frame 12 can be adjusted to adjust the angle from the vertical frame 11 so as to increase the condensing efficiency of sunlight by adjusting the angle according to season, temperature, and the like.

The fixed frame 13 has a plurality of first fastening holes 14 formed at regular intervals along the upper surface thereof.

The solar module 20 is mounted on the structure and is coupled to the solar panel 21 for condensing sunlight and a supporting frame 22 of a " C "shape joined along each corner of the solar panel ).

The support frame 22 includes an upper plate 23 coupled to the outside in parallel from the respective corners of the solar panel, a side plate 24 bent vertically downward from the end of the upper plate, And a lower plate 25 which is vertically bent and has a second fastening hole 26 of the same diameter at a position corresponding to the first fastening hole 14, and is formed as a whole in a "C" shape.

When the solar module 20 is mounted on the stationary frame 13, the first fastening hole 14 and the second fastening hole 26 are positioned so as to mate with each other, So as to be introduced into the frame 22.

The fixing pin 30 is a rod or a cylindrical shape having a predetermined length which is shorter than the first and second fastening holes. The fastening pin 30 is inserted into the first fastening hole 14 and the second fastening hole 26 in order, And is naturally collapsed when it passes through the second fastening hole and is brought into close contact with the inner circumferential surface of the lower plate 25 to stay inside the support frame without being released to the outside.

A wire 40 having a predetermined length is wound around the fixing pin 30 and a tension adjusting means 50 is attached to an end of the wire to adjust the tension of the wire.

3, the two fixing pins 30 having a wire wound and fixed on one side thereof are sequentially inserted through the first and second fastening holes 14 and 26 from the bottoms of both sides of the structure, 22, the other end of each wire is connected to the tension adjusting means, and the tension is adjusted to bind the solar module and the structure.

Since the support frame 22 has a "C" shape with one side open, the position of the fixing pin 30 inserted into the support frame is adjusted so as not to be detached from the lower plate 25, and then the other end of the wire is held The wire can be made in a tight state while the holding pin is supported by the lower plate.

In the present invention, the wire 40 may be formed of a carbon fiber material. Conventionally, the method of using metal fasteners such as bolts and nuts has been directly influenced by temperature or weather. Especially, in case of corrosion, the first fastening hole of the fastening frame causes corrosion, And the durability is lowered. The present invention uses a wire formed of a carbon fiber material having excellent heat resistance, abrasion resistance, and corrosion resistance to prevent the above problems, thereby preventing durability or binding force from being deteriorated due to external factors such as temperature or weather have. In addition, since carbon fiber is a material having excellent electrical conductivity, it can serve as a ground that is essential for a photovoltaic power generation device, so that an electric accident such as an electric shock can be prevented and an antistatic effect can be expected.

In the present invention, the tension adjusting means 50 may use a turnbuckle.

The turnbuckle is formed by threadedly engaging a threaded rod formed with a fastening portion at each end thereof on a female threaded portion formed at both ends of the body, a male threaded portion formed on one threaded rod is formed of a right thread, and a male threaded portion formed on the threaded rod on the other side, So that when the body is rotated, the screw rods on both sides approach each other or rotate away from each other. When the steel rope or the wire of the structure is pulled tightly, the turnbuckle is inserted in the middle and the body of the turnbuckle is turned, Wire or the like is tightly fastened and fixed. The fastening part may be formed in an annular shape or a circular shape. In the present invention, it is preferable to use a turnbuckle having a circular fastening part to prevent the wire from coming off. When the end of the wire exposed to the outside after inserting the fixing pin into the support frame is connected to the turnbuckle and tightened, the two side wires are pulled more tightly, and the bonding force between the solar module and the structure is remarkably improved.

In the present invention, the wire 40 is formed with a center through which the wire 10 can be inserted in a portion corresponding to the inlet of the first fastening hole 14 to which the structure 10 and the wire 40 are closely attached And a concentrated load avoiding member 60 of a predetermined length formed of a material having an elastic force.

When a tensile force is applied by pulling the wire 40 through the tension adjusting means 50, a concentrated load is generated at a portion where the wire meets the structure, that is, at the entrance portion of the first fastening hole 14, And the structure may be subjected to an impact.

A concentrated load avoiding member 60 made of an elastic material such as rubber is fitted on the entrance side of the first fastening hole 14 of the wire 40 so that the wire 40 is fixed to the structure 10, It is preferable to secure the durability of the wire and the structure by distributing the load.

Next, a binding method of the solar module and the structure according to the present invention will be described as follows.

First, a first fastening hole 14 is formed at an upper surface of a fixed frame 13 for supporting a solar module 20 formed on a structure fixed on the ground, A second fastening hole 26 of the same diameter is formed in the support frame 22 at a position corresponding to the first fastening hole. In the case of a photovoltaic power generation apparatus constructed by bundling a solar module and a structure with a bolt and a nut, it is possible to omit forming the first and second fastening holes.

Next, two fixing pins 30 having a wire wound and fixed on one side are prepared, and then the first and second fastening holes are sequentially inserted through the bottoms of both sides of the structure, and inserted into the support frame.

When the fixing pin 30 completely escapes through the second fastening hole 26, it naturally collapses and is seated on the lower plate 25 of the support frame. In this state, the respective wires are pulled to be in a tight state.

Here, when the wire 40 is wound around the fixing pin 30, it is preferable that the wire 40 is fixed at the center of the fixing pin 30. If the wire 40 is fixed at a position adjacent to the end or end of the fixing pin 30, the fixing pin 30 may come out of the fixing hole 30 when the wire is pulled.

Then, the end of each wire is connected to the tension adjusting means 50, and the tension is adjusted to firmly fix the solar module and the structure.

The binding method is a method of binding one photovoltaic module 20 to the structure 10 via two stranded wires 40 and one tension adjusting means 50. [

In the present invention, a turnbuckle can be used as the tension adjusting means 50. Since the turnbuckle is expensive compared to a bolt and a nut, the length of the wire can be made long to save costs.

For example, if you can bind a solar module 2m to a structure through two wires of 0.8m and a turnbuckle, you can connect three solar modules with two wires of about 2.5m to 3m and one turnbuckle . Assuming that three solar modules (hereinafter referred to as a first solar module, a second solar module, and a third solar module) are placed side by side along the longitudinal direction on the structure, One end of the wire is fixed to the inner circumferential surface of the lower plate of the support frame formed at the corner via the fixing pin and then the other end is positioned on the bottom surface of the second solar module by passing through the second fastening hole and the first fastening hole at the right corner.

The wires are sequentially bound from the right edge of the third solar module in the same manner to place the other end on the bottom surface of the second solar module and then the ends of both wires are fixed to the turnbuckle to adjust the tension of the turnbuckle Three solar modules can be tightly coupled and the two turnbuckles need not be used through this method, so that cost reduction and ease of construction can be expected.

10: Structure
11: Vertical frame
12: Horizontal frame
13: Fixed frame
14: first fastening hole
20: Photovoltaic module
21: Solar panel
22: Support frame
23: top plate
24: shroud
25: Lower plate
26: second fastening hole
30: Fixing pin
40: wire
50: tension adjusting means
60: concentrated load dispersing member

Claims (5)

A vertical frame 11 vertically installed on the ground, a horizontal frame 12 coupled to the upper part of the vertical frame, and a cross section fixedly connected to the upper part of the horizontal frame at regular intervals, And a stationary frame (13) having a first fastening hole (14) formed at regular intervals along the first fastening hole (14);
A solar cell plate 21 that is seated on and bonded to the structure and condenses sunlight; and a solar cell module 21 that is coupled along each corner of the solar cell panel and has a cross- A solar module (20) including a support frame (22) having a second fastening hole (26) formed therein;
The first and second fastening holes are inserted into the support frame sequentially so as to penetrate through the first fastening holes and the second fastening holes sequentially. When the fastening holes pass through the second fastening holes, A fixing pin (30) which collapses and is brought into close contact with the inner circumferential surface of the lower plate and is not released to the outside but stays in the support frame;
A wire (40) having a predetermined length to which one end of the fixing pin is wound and fixed; And
And a tension adjusting means (50) for binding to the other end of the wire,
The two fixing pins, which are wound and fixed on one side, are inserted into the supporting frame sequentially through the first and second fastening holes from below the both side edges of the structure, and then the other end of each wire is connected to the tension adjusting means And the connecting force is increased to increase the bonding force.
The structure of claim 1, wherein the wire is formed of a carbon fiber material.
The structure of claim 1, wherein the tension adjusting means is a turnbuckle.
[2] The method of claim 1, wherein the wire is provided with an elastic force to disperse a concentrated load generated in the structure and the solar module during tensioning of the wire, in a portion corresponding to an inlet portion of the first fastening hole, And a concentrated load distribution member (60) made of a material having a predetermined thickness is inserted.
Forming a first fastening hole (14) at a predetermined interval on an upper surface of a fixed frame for supporting a solar module formed on a structure fixed on the ground;
Forming a second fastening hole (26) of the same diameter at a position corresponding to the first fastening hole on a supporting frame provided in the solar module;
Preparing two fixing pins 30 on one side of which a wire is wound and fixed;
Inserting the two fixing pins into the inside of the supporting frame so as to sequentially pass through the first and second fastening holes (14, 26) in the lower part of both side edges of the structure;
Connecting the other end of each wire to the tension adjusting means (50) and adjusting the tension to securely fix the solar module and the structure;
And a solar cell module connected to the solar cell module.

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