KR101973145B1 - Photoviltaic power generation facility easy moving of photoviltaic modoule - Google Patents

Abstract

The present invention provides a photovoltaic power generation facility capable of facilitating installation and maintenance of the photovoltaic power generation facility in an environment where access of a manager is difficult. According to the present invention, the photovoltaic power generation facility comprises: a cable structure having a cable extending to be cyclically movable and a drive roller circulating and moving the cable; and a plurality of solar cell module devices coupled to the cable so as to be sequentially disposed along an extension direction of the cable. The cable has a first extension unit and a second extension unit positioned above the first extension unit. The solar cell module device has a support structure coupled to the cable and a solar cell module coupled to the support structure. The support structure has a first coupling shaft coupled to the first extension unit to be slidably movable and a second coupling shaft fixed to the second extension unit.

Description

[0001] PHOTOVILTAIC POWER GENERATION FACILITY EASY MOVING OF PHOTOVILTAIC MODULE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photovoltaic power generation facility, and more particularly, to a photovoltaic power generation facility capable of easily moving a solar cell module to facilitate installation and maintenance.

Fossil fuels, which are mainly used to produce electricity today, are a kind of resource with limited reserves on the earth. They are used indiscriminately due to the rapid increase in electric energy due to industrial development, causing serious environmental pollution. As depletion is anticipated, the development of so-called clean energy that can replace fossil fuels is being actively promoted around the world, and a representative example is solar power generation.

In addition to wind power generation, photovoltaic power generation has attracted a great deal of attention because it is pollution-free and can be used infinitely. In particular, photovoltaic power generation is composed of semiconductor elements in the power generation part and electronic parts in which the control part has a long life span. There is no occurrence of mechanical vibration or noise, and operation life of several decades is guaranteed.

It is possible to control the operation and control of the power generation system by remote or unmanned control through semi-automatic or automated program. Therefore, aggressive utilization of solar power generation system is an alternative power generation system that should actively develop in the environment like ours where energy resources are absolutely lacking.

The solar panels are designed in various sizes ranging from a large size to a small size. In order to produce a large amount of electricity, it is necessary to provide a large-sized space because dozens or hundreds of solar panels of a large size are required.

In Korea, however, most of the land is composed of mountainous areas. In the relatively less plains, people are not able to utilize as residential, agricultural and industrial areas. Therefore, large area It is not easy to secure ground space.

Accordingly, recently, technologies for constructing solar power generation facilities in mountainous areas have been developed. Due to the nature of the mountainous regions, it is not easy for an administrator to access the area where the solar cell module is located. · There is a problem that maintenance work is difficult and inconvenient.

Korean Registered Patent Publication No. 10-0721002 "Photovoltaic Generator" (2007.05.28.)

An object of the present invention is to provide a photovoltaic power generation facility capable of facilitating installation, maintenance and repair work of a photovoltaic power generation facility in an environment where a manager is unable to access the photovoltaic module, such as a mountainous region.

According to an aspect of the present invention, there is provided a cable structure comprising: a cable extending to be circulatively moved; and a driving roller for circulating and moving the cable; And a plurality of solar cell module devices coupled to the cable such that the cables are disposed in order along the extension direction of the cable, the cable having a first extension and a second extension positioned above the first extension, The solar cell module includes a support structure coupled to the cable and a solar cell module coupled to the support structure. The support structure includes a first coupling shaft And a second coupling shaft fixed to the second extension portion.

The support structure may further include at least one support for connecting the first engagement shaft and the second engagement shaft.

The drive roller can move along the extending direction of the cable.

The first engagement shaft may include a semicircular lower member that surrounds the first extension portion and a semicircular upper member coupled to the lower member and surrounding the first extension portion.

According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, a plurality of solar cell module devices are coupled in a line so as to be arranged in a line along an extending direction on a cable extending to circulate, and the solar cell module device is slidably coupled to a first extension portion of the cable The first joining shaft and the second joining shaft fixed to the second extending portion of the cable located above the first extending portion are provided so that the plurality of solar cell module devices are connected to one end of the cable in the extending direction So that the facility manager can easily access the solar cell module, making maintenance and management easier.

1 is a perspective view illustrating a main configuration of a photovoltaic power generation facility according to an embodiment of the present invention.
FIG. 2 is a plan view of a portion corresponding to one solar cell module assembly in the solar power generation facility shown in FIG. 1; FIG.
3 is a view showing a state in which the solar cell module devices are moved in the solar power generation facility of FIG.
FIG. 4 is a view showing a state in which the solar cell module devices are all moved to one side in the solar power generation facility of FIG. 1;
5 is a cross-sectional view of the lower coupling shaft of the solar cell module apparatus in FIG.
6 to 10 are views showing another embodiment of the solar cell panel shown in FIG.
11 is a view showing another example in which the solar cell assembly is fixed.

FIG. 1 is a perspective view showing a main configuration of a photovoltaic power generation system according to an embodiment of the present invention. 1, a photovoltaic power generation system 100 according to an embodiment of the present invention includes a cable structure 110 and a plurality of solar cell module devices 150 supported by a cable structure 110 do.

The cable structure 110 is a structure for supporting and moving the plurality of solar cell module devices 150. The cable structure 110 includes a cable 120 extending in the form of a closed curve, a drive roller 130a circulatingly moving the cable 120, A driven roller 130b which is rotated depending on the circulation movement of the cable 120 and a plurality of support rollers 140 for supporting the cable 120. [

The cable 120 extends in the form of a closed curve and includes a first extension portion 121 and a second extension portion 123 positioned above the first extension portion 121 and extending parallel to the first extension portion 121, A first connection part 125 connecting the two extension parts 121 and 123 at one end in the longitudinal direction of the first extension part 121 and the second extension part 123, And a second connection part 127 connecting the two extension parts 121 and 123 at the other end in the longitudinal direction of the extension part 123. A plurality of solar cell module devices 150 are coupled to and supported by the first extension part 121 and the second extension part 123. A drive roller 130a is coupled to an end of the first connection part 125 and a hill roll 130b is coupled to an end of the second connection part 127. [ The support roller 140 is positioned at a portion where the first connection portion 125 and the two extension portions 121 and 123 are connected and a portion where the second connection portion 127 and the two extension portions 121 and 123 are connected. The cable 120 can be circularly moved by the driving roller 130a and the plurality of solar cell module devices 150 can be reciprocated along the longitudinal direction of the cable 120 by the circular movement of the cable 120 .

The driving roller 130a is coupled to the end of the first connection part 125 of the cable 120 to circulate the cable 120. [ Although not shown, the rotating shaft of the driving roller 130a is driven by the driving motor to rotate. Although not shown, the driving roller 130a may move along the longitudinal direction of the cable 120 in order to maintain the tension of the cable 120. [

The driven roller 130b is coupled to the end of the second connection part 127 of the cable 120 and is dependent on the rotation of the cable 120 and rotates. In this embodiment, the drive roller 130a is described as moving for maintaining tension, but the driven roller 130b may move, which is also within the scope of the present invention.

Each of the plurality of support rollers 140 is connected to a portion where the first connection portion 125 and the two extension portions 121 and 123 are connected and a portion where the second connection portion 127 and the two extension portions 121 and 123 are connected And supports the cable 120.

A plurality of solar cell module devices 150 are sequentially arranged in a line along the extending direction of the cable 120 and are coupled to and supported by the cable 110. The cable 120 is rotated by the rotation of the cable 120 120 in the longitudinal direction. 1 and 2, a solar cell module device 150 includes a support structure 160 coupled to a cable 120, two solar cell modules 180 supported by a support structure 160, First and second rotary winding wires 191a and 191b for connecting the supporting structure 160 and the two solar cell modules 180, first and first B folding winding wires 192a and 192b, 2A, and second B folding winding wires 194a, 194b.

The support structure 160 is coupled to the cable 120 to support the two solar cell modules 180. The support structure 160 is fixedly coupled to the first extension 121 of the cable 120 and to the second extension 123 of the cable 120, A second coupling shaft 170 and two supports 179 connecting the first coupling shaft 161 and the second coupling shaft 170. [

The first coupling shaft 161 is a hollow shaft and passes through the coupling shaft 161 so that the first extension portion 121 of the cable 120 can slide. 5 is a cross-sectional view of the first coupling shaft 161. As shown in Fig. 5, the first engaging shaft 161 includes a semicircular lower member 162 and a semicircular upper member 163 fitted to the lower member 162 in a fitting manner. The wires 128 electrically connected to the solar cell module 180 together with the first extension portion 121 of the cable 120 are accommodated in the inner space of the first coupling shaft 161. Although the wires 128 are described as being received in the internal space of the first coupling shaft 161 in the present embodiment, they may be located outside the first coupling shaft 161, . The lower ends of the two support rods 179 are connected to both ends of the first coupling shaft 161. Two solar cell modules 180 are rotatably coupled to both sides of the first coupling shaft 161.

The second engagement shaft 170 is a hollow shaft and the second extension portion 123 of the cable 120 passes the second engagement shaft 170. The second coupling shaft 170 and the second extension portion 123 are fixed to prevent the slide movement from occurring between the second coupling shaft 170 and the second cable 123. The upper ends of the two supports 179 are connected to both ends of the second coupling shaft 170. The second engagement shaft 170 has a rotation take-up roller 171 and two folding take-up rollers 175 and 177.

The take-up reel roller 171 is generally located in the longitudinal center portion of the second engaging shaft 170. The first rotation dedicated winding wire 191a and the second rotation dedicated winding wire 191b are wound around the rotation take-up roller 171. [ The second engaging shaft 170 is provided with a first motor 171a for rotating the take-up winding roller 171. [

The two folding-up take-up roller portions 175 and 177 are provided with a first folding take-up roller portion 175 and a second folding take-up roller portion 177 which are respectively located at both longitudinal ends of the second engaging shaft 170, Respectively. The first folding take-up roller portion 175 includes a first A folding take-up roller 175a for winding the first A folding take-up rewinding wire 192a and a first B folding rewinding reel 175b for winding the first B folding rewinding wire 192b And a roller 175b. The second folding take-up roller portion 177 is wound around the second A folding take-up roller 177a around which the second A folding take-up wire 194a is wound and the second B folding take- And a roller 177b. The second engaging shaft 170 is provided with a second motor 175c for rotating the first and first B folding-up winding rollers 175a and 175b and a second motor 175c for rotating the second A- and B-folding-up winding rollers 177a and 177b 3 motor 177c.

Each of the two supports 179 extends along the height direction and is disposed at both longitudinal ends of the first engagement shaft 161 and the second engagement shaft 170, respectively. The lower ends of the two supports 179 are fixedly connected to the first coupling shaft 161 and the upper ends of the two supports 179 are connected to and fixed to the second coupling shaft 170. Accordingly, the first engaging shaft 161, the second engaging shaft 170, and the two supports 179 form a rectangular frame.

Each of the two solar cell modules 180 is rotatably coupled to the first coupling shaft 161 on both sides of the first coupling shaft 161.

The first and second spinning rewinding wires 191a and 191b are wound around a rotation take-up roller 171 and connected to the two solar cell modules 180, respectively. One of the two-times-dedicated winding wire 191a and 191b is elongated and the other is shortened by the rotation of the rotation-purpose winding roller 171, so that the two solar cell modules 180 rotate according to the sun's position .

The first A folding rewinding wire 192a is wound around a first A folding takeup roller 175a and the first B folding takeup wire 192b is wound around a first B folding takeup roller 175b. The first A folding rewinding wire 192a and the first B folding rewinding wire 192b are connected to each of the two solar cell modules 180 one by one.

The second A folding winding wire 194a is wound around the second A folding winding roller 177a and the second B folding winding wire 194b is wound around the second B folding winding roller 177b. The second A folding winding wire 194a and the second B folding winding wire 194b are connected to each of the two solar cell modules 180 one by one.

As the winding rollers 175a, 175b, 177a and 177b for folding 1A, 1B, 2A, and 2B rotate, the first, second, and second folding winding wires 192a, 192b and 194a , 194b are lengthened or shortened so that the two solar cell modules 180 can be folded or unfolded. When the winding wires 192a, 192b, 194a and 194b for the first 1A, first B, second 2A and second b folding are elongated, the two solar cell modules 180 are unfolded and the first, second, When the folding winding wires 192a, 192b, 194a, and 194b are shortened, the two solar cell modules 180 are folded. The state in which the two solar battery modules 180 are unfolded is a case where solar power generation is normally performed and the state in which the two solar battery modules 180 are folded is a state in which the damage of the solar battery module 150 And to prevent breakage.

Now, a photovoltaic power generation facility according to one embodiment of the present invention, which has been described above with reference to the configuration, will be described with respect to characteristic operation.

As shown in FIG. 1, in a state where a plurality of solar cell module devices 150 are arranged in order along the extending direction of the cable 120 and apart from the end of the cable 120 by a considerable distance, When the maintenance and repair of the battery module devices 150 is required, as shown in FIG. 2, as the drive roller 130a rotates, the cable 120 circulates, The first extended portion 121 moves away from the driving roller 130a and the second extended portion 123 of the cable 120 moves toward the driving roller 130a. The first coupling shaft 161 of the solar cell module device 150 is slidable with the first extension portion 121 of the cable 120 and the second coupling shaft 170 of the solar cell module device 150 is slidable, The second extending portion 123 of the cable 120 is moved toward the driving roller 130a so that the plurality of solar battery modules 120 are not moved relative to the second extending portion 123 of the cable 120. Therefore, The devices 150 are also moved toward the driving roller 130a. FIG. 4 shows a state where a plurality of solar cell module devices 150 are all moved toward the driving roller 130a. 4, a worker performs maintenance and repair work on the solar cell module device 150, and after the operation is completed, the drive roller 130a is rotated in the opposite direction, Thereby bringing the module devices 150 back into place.

6 to 10 show another embodiment of the solar cell panel shown in Fig. 6 to 10, the solar cell module 350 includes a module frame 360, a plurality of solar cell assemblies 370, and a plurality of solar cell assemblies 370 fixed to a lower portion of the module frame 360, And a plurality of securing means 390 for securing each of the plurality of solar cell assemblies 370 to the backing web 380 individually.

The module frame 360 is a frame member having an opening 361 opened at the center thereof, and is described as being a rectangular shape in the present embodiment, but the present invention is not limited thereto. A plurality of solar cell assemblies 370 are disposed in an opening 361 of the module frame 360 and a supporting net 380 is fixed to a lower portion of the module frame 360 to form a plurality of cell assemblies 370 I support. Although not shown, a wiring structure that is electrically connected to the plurality of solar cell assemblies 370 is formed in the module frame 360.

In the present embodiment, the first, second and third motors 171a, 175c and 177c are provided on the second coupling shaft 170. Alternatively, the first, second and third motors 171a, 175c and 177c may be provided on the module frame 360 together with the control unit , Which are also within the scope of the present invention.

The plurality of solar cell assemblies 370 are disposed apart from each other in the opening 361 region of the module frame 360. The plurality of solar cell assemblies 370 are supported by the support nets 380 without falling down. Each of the plurality of solar cell assemblies 370 is fixed by the fixing means 390 so as not to move. 8, a solar cell assembly 370 is shown as a perspective view, and a solar cell assembly 370 is shown as a cross-sectional view in FIG. 8 and 9, the solar cell assembly 370 includes a solar cell 371 and a cell frame 375 surrounding the rim of the solar cell 371.

The solar cell 371 is a commonly used solar cell, and a protective film 372 is disposed on an upper surface of the solar cell 371. A support plate 373 of a resin material, which is a supporting structure, is located on the lower surface.

The cell frame 375 is a frame member that encloses the rim of the solar cell 371 and includes a flange portion 376 for supporting the solar cell 371 from below and a flange portion 376 extending upward from the flange portion 376, And a sidewall portion 378 surrounding the rim. Although not shown, a terminal located on the lower surface of the solar cell 371 and a wire extending from the terminal can be exposed through the opening 377 formed in the flange portion 376. [ The height of the sidewall portion 378 is set such that the upper end of the sidewall portion 378 protrudes further than the upper surface of the solar cell 371 in a state where the cell frame 375 and the solar cell 371 are coupled, (371). Thereby, the protective film 372 of the solar cell 371 is prevented from being damaged by the fixing means 390. A plurality of drain holes 379 are formed in a portion of the side wall portion 378 protruding above the solar cell 371. So that water can be quickly drained in the sera frame 375 through the drains 379 without accumulation of water.

The support net 180 is fixedly coupled to the lower surface of the module frame 360 to support a plurality of solar cell assemblies 370 from below. The size of the hole of the support net 380 is smaller than the sun stop cell assembly 370. The support net 380 preferably has sufficient strength to support a plurality of solar cell assemblies 370.

Each of the plurality of fixing means 390 is in the form of a net and is combined with the supporting net 380 while covering the plurality of solar cell assemblies 370 one by one to fix the solar cell assembly 370. FIG. 7 shows a state in which the solar cell assembly 370 is fixed by the fixing means 390. FIG. 7, the overall size of the securing means 390 is larger than the solar cell assembly 370 so that the lateral outer portions of the securing means 390 extend further laterally than the solar cell assembly 370 And this extended portion is joined to the supporting net 380 by a wire so that the fixing means 190 fixes the solar cell assembly 370. The size of the eye of the fixing means 390 is formed smaller than the size of the solar cell assembly 370. It is preferable that the dimension of the fixing means 390 is such that two or three horizontal lines and vertical lines pass over the solar cell assembly 370. It is also preferable that the average size of the eyes of the fixing means 390 is larger than the average size of the eyes of the backing screen 380. The fixing means 390 is in contact with the upper end of the side wall portion 378 of the cell frame 375 of the solar cell assembly 370 to be separated from the protective film 372 of the solar cell 371, The protection film 372 of the solar cell 371 is prevented from being damaged by the protection film 390. [

10, a plurality of fixed lines 290, such as a fishing line, may be provided on the solar cell assembly 370, as shown in FIG. 10, And both ends thereof are tied and fixed to the support net 380. At this time, it is preferable that the fixed lines 290 pass over one solar cell assembly 370 by two or three, respectively in the horizontal and vertical directions.

11 shows another embodiment in which the solar cell assembly 370 is secured to the backing net 380. [ 11, the rear side of the solar cell assembly 370 is seen to be seen. 11, a lower surface of the flange portion 376 of the cell frame 375 of the solar cell assembly 370 is provided with a plurality of ribs 372 for engagement with each of a plurality of horizontal and vertical lines constituting the support net 180 Coupling means 379 are coupled. The fittings 379 may be fixed to the cell frame 375 by fastening means such as screws as one embodiment of the coupling means of the present invention.

As described above, since the plurality of solar cell assemblies 170 are stably fixed and disposed apart from each other, the air circulates and passes through the cell assemblies 170, so that heat radiation, drainage, wind load avoidance, And ease of cell exchange.

Although the present invention has been described with reference to the above embodiments, the present invention is not limited thereto. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

100: Solar power generation facility 110: Cable structure
120: cable 121: first extension
123: second extension part 125: first connection part
127: second connecting portion 130a: driving roller
130b: driven roller 140: support roller
150: solar cell module device 160: support structure
161: first coupling shaft 162: lower member
163: upper member 170: second engagement shaft
179: Support frame 180: Solar cell module

Claims (5)

A cable structure having a cable extending to be cyclically movable and a drive roller for circulating the cable; And
And a plurality of solar cell module devices coupled to the cable so as to be sequentially disposed along an extension direction of the cable,
The cable having a first extension and a second extension positioned above the first extension,
The solar cell module device includes a support structure coupled to the cable and a solar cell module coupled to the support structure,
The supporting structure may include a first engaging shaft through which the first extending portion can slide so as to be slidable, a second engaging shaft through which the second extending portion is fixed, and a second engaging portion that engages the first engaging shaft and the second engaging shaft And at least one support fixed to both of the coupling shafts,
Both the first engaging shaft and the second engaging shaft move in the same direction along the moving direction of the second extending portion by the circular movement of the cable,
Wherein the first coupling shaft receives an electric wire electrically connected to the solar cell module,
Wherein the first coupling shaft includes a semicircular lower member for wrapping the first extension and the electric wire thereunder and a semicircular upper member coupled to the lower member and surrounding the first extension and the electric wire , Photovoltaic power generation facilities. delete The method according to claim 1,
Wherein the driving roller is movable along an extending direction of the cable. delete delete

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