WO2019027136A1

WO2019027136A1 - Solar cell module device and photovoltaic power generation facility having same

Info

Publication number: WO2019027136A1
Application number: PCT/KR2018/006561
Authority: WO
Inventors: 강희성; 전형관
Original assignee: (주)아이엔오기술
Priority date: 2017-08-02
Filing date: 2018-06-11
Publication date: 2019-02-07
Also published as: WO2019027135A1; CN111095787A; CN111095787B

Abstract

According to an aspect of the present invention, provided is a solar cell module device, to be installed on a cable, having a first extension part and a second extension part which extend side by side. The solar cell module device comprises: a module installation structure having a central shaft, which has the first extension part coupled thereto, a cable coupling shaft, which is positioned below the central shaft and has the second extension part coupled thereto, and a connection structure part which is coupled between the central shaft and the cable shaft; and at least one solar cell module fixed to the connection structure part, wherein the at least one solar cell module is fixed to the connection structure part so as to be inclined on one side of the central shaft.

Description

Photovoltaic module device and photovoltaic power generation equipment having the same

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photovoltaic power generation system, and more particularly, to a photovoltaic module system and a photovoltaic power generation system having the same.

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.

By installing the solar cell module on the ground, various applications can be done by the geometric structure, and control and operation of the power generation system can be controlled remotely or unattended through semi-automatic or automated programs. Therefore, aggressive utilization of solar power generation system is an alternative power generation system that should actively develop in the environment like Korea where energy resources are absolutely lacking.

No. 10-1356290 discloses a configuration in which the photovoltaic elements fixed to the support rods are disposed on a supporting frame composed of a supporting cable and a supporting adjusting cable. However, such a conventional configuration has a problem that the supporting structure of the solar power plant is complicated, and installation and operation are not easy.

An object of the present invention is to provide a solar cell module device which is easy to install and operate the solar cell module, and a solar power generation facility having the solar cell module device.

According to an aspect of the present invention, there is provided a solar cell module apparatus for installing on a cable having a first extending portion and a second extending portion extending in parallel, A module mounting structure having a center shaft coupled to the center shaft, a cable coupling shaft positioned below the center shaft and coupled with the second extension, and a coupling structure coupled between the center shaft and the cable shaft; And at least one solar cell module fixed to the connection structure, wherein the at least one solar cell module is fixed to the connection structure portion so as to be inclined to one side of the center shaft.

According to another aspect of the present invention, there is provided a method of manufacturing a semiconductor device including two support pillars; A cable structure having a cable installed to extend between the two support posts; And a solar cell module device having a module installation structure coupled to the cable and at least one solar cell module installed in the module installation structure, wherein the cable includes a first extension portion, And a second extension extending below the first extension and extending parallel to the first extension, the module installation structure comprising: a center shaft to which the first extension is coupled; Wherein the at least one solar cell module is disposed between the central shaft and the cable shaft and includes a connection structure in which the solar cell module is fixed, A photovoltaic power generation facility, a module device, is provided

According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, since a plurality of solar cell modules are installed and a module installation structure capable of being coupled to a cable is provided, the installation and operation of the solar cell module becomes easier than in the conventional technology.

In addition, since the module mounting structure can rotate the fixed portion of the solar cell module so that the inclination and direction of the solar cell module can be adjusted, the solar power generation efficiency can be improved.

Further, since the module installation structure in which a plurality of solar cell modules are installed can be moved by the circulation movement of the cable, the facility manager can easily access the solar cell module, and work for maintenance and management can be facilitated.

FIG. 1 is a side view schematically showing a solar power generation facility according to an embodiment of the present invention.

FIG. 2 is a perspective view of the solar cell module apparatus shown in FIG. 1. FIG.

3 is a front view of the solar cell module apparatus shown in FIG.

4 is a view illustrating a state in which the solar cell module devices are moved in the solar power generation facility of FIG.

FIG. 5 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. FIG.

6 is a front view of another embodiment of the solar cell module apparatus shown in Fig.

FIG. 7 is a front view showing another embodiment of the module installation structure in the solar cell module apparatus shown in FIG. 1. FIG.

FIG. 8 is a perspective view showing still another embodiment of the solar cell module apparatus shown in FIG. 1. FIG.

FIG. 9 schematically shows a state in which the direction of the solar cell module is changed in the solar cell module device of FIG. 8. FIG.

FIG. 1 is a side view of a schematic configuration of a photovoltaic power generation facility according to an embodiment of the present invention. Referring to FIG. 1, a photovoltaic power generation system 100 according to an embodiment of the present invention includes two support pillars 110, a cable structure 120 installed on two support pillars 110, a cable structure 120 And a plurality of solar cell modules 150 supported by the plurality of solar cell modules 150. In this embodiment, it is explained that the photovoltaic power generation equipment 100 is installed in a place with little or no difference in height, such as a flat or a reservoir, but the present invention is not limited thereto.

The two support pillars 110 are spaced apart from each other by a predetermined distance, and the cable structure 120 is installed on the two supporting pillars 110.

The cable structure 120 includes a cable 121 extending in the form of a closed curve and a cable 121 installed to connect the two support columns 110 to support and move the plurality of solar cell module devices 150, A driven roller 130b which is rotated in accordance with the circulation movement of the cable 120 and a plurality of support rollers 140 for supporting the cable 121. The drive roller 130a circulates the cable 120,

The cable 121 extends in the form of a single closed curve and includes a first extension portion 122 and a second extension portion 123 located below the first extension portion 122 and extending parallel to the first extension portion 122 A first connection part 125 connecting two

extensions

122 and 123 at one end in the longitudinal direction of the first extension part 122 and the second extension part 123, And a second connection part 127 connecting the two

extensions

122 and 123 at the other end in the longitudinal direction of the second extension part 123. A plurality of solar cell module devices 150 are coupled to and supported by the first extension part 122 and the second extension part 123. A drive roller 130a is coupled to an end of the first connection part 125 and a driven roller 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

122 and 123 are connected and a portion where the second connection portion 127 and the two

extension portions

122 and 123 are connected. The cable 121 can be circulatively moved in both directions by the driving roller 130a and the plurality of solar cell module devices 150 are reciprocated along the longitudinal direction of the cable 121 by the bidirectional circulation movement of the cable 121 .

The driving roller 130a is coupled to the end of the first connection part 125 of the cable 121 to circulate the cable 121 in both directions. Although not shown, the driving roller 130a is driven by a driving motor and rotates. Although not shown, the driving roller 130a may move along the longitudinal direction of the cable 121 in order to maintain the tension of the cable 121. [

The driven roller 130b is coupled to the end of the second connecting portion 127 of the cable 121 and is driven to rotate depending on the circular movement of the cable 121. [ 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

122 and 123 are connected And supports the cable 121.

The plurality of solar cell module devices 150 are sequentially arranged in a line along the extending direction of the cable 121 and are coupled to and supported by the cable 121. The cable 121 is rotated by bidirectional circulation movement of the cable 121, As shown in Fig. The solar cell module device 150 is supported by a cable 121 and produces direct current power using solar light. The solar cell module device 150 is shown as a perspective view in Figure 2 and as a front view in Figure 3. 2 and 3, the solar cell module apparatus 150 includes a module installation structure 160, a plurality of solar cell modules 190 installed in the module installation structure 160, a module installation structure 160, And a balance weight member 195 mounted on the balance weight member 195.

The module mounting structure 160 is a generally truss-like structure and includes a center shaft 161, two first extending link portions 181 coupled to the center shaft 161, A first coupling link portion 170 connecting two first extended link portions 183 and a second coupling link portion 170 connecting two first extended link portions 183, Two linking links 180 connecting the first coupling link 170 and the second coupling link 175 and a cable coupling shaft 185. Two first extending link portions 181, two second extending link portions 183, a first coupling link portion 170, a second coupling link portion 175, A connecting structure for connecting the center shaft 161 and the cable coupling shaft 185 in the structure 160 is formed.

The center shaft 161 is a hollow shaft extending in a straight line and the first extension portion 122 of the cable 121 passes through the center shaft 161 and is inserted into the center shaft 161, 1 extended portion 122 is coupled. An electric wire 111 electrically connected to the plurality of solar cell modules 190 is passed through a clearance space with the first extended portion 122 in the central passage of the central shaft 161. The center shaft 161 and the first extended portion 122 of the cable 121 are fixedly fixed so that the sliding movement does not occur between the center shaft 161 and the first extended portion 122 of the cable 121 . Two first extending link portions 181 and two second extending link portions 183 are rotatably coupled to the center shaft 161 at both ends in the longitudinal direction. The center shaft 161 together with the cable coupling shaft 185 forms the cable coupling of the module mounting structure 160.

Each of the two first extending link portions 181 extends from both ends of the center shaft 161 in the radial direction of the center shaft 161 (arrow direction of the one-dot chain line in Fig. 2) And is coupled to the center shaft 161 rotatably. The two first extending link portions 181 extend obliquely downward from the center shaft 161. A first coupling link portion 170 is rotatably coupled to an end of the two first extending link portions 181. A module fixing base 182 to which the solar cell module 190 is fixed is installed on the two first extending link portions 181.

Each of the two second extending link portions 183 (only one is shown in the figure) extends from both ends of the center shaft 161 in the radial direction of the center shaft 161 (arrow direction of the one-dot chain line in Fig. 2) And is coupled to the center shaft 161 so as to be rotatable about the shaft 161. The two second extending link portions 183 extend obliquely downward from the center shaft 161 (opposite side of the first extending link portion 181). The first extended link portion 181 and the second extended link portion 183 extend downward from the center shaft 161 and are spaced apart from each other along the circumferential direction And the angle between the two extending

link portions

181 and 183 is changed by rotating the two extending

link portions

181 and 183 so as to flare or narrow each other about the center shaft 161 . A second coupling link portion 175 is rotatably coupled to an end of the two second extending link portions 183.

The first coupling link portion 170 extends parallel to the center shaft 161 and both end portions of the first coupling link portion 170 are rotatably engaged with the two first extending link portions 181, respectively. In addition, two connecting link portions 180 are rotatably coupled to the first engaging link portion 170.

The second coupling link portion 175 extends parallel to the center shaft 161 and both ends of the second connecting rod 175 are rotatably coupled to the two second extending link portions 183, respectively. In addition, two connecting link portions 180 are rotatably coupled to the second engaging link portion 175.

Each of the two connecting link portions 180 is rotatably coupled to the first engaging link portion 170 and the second engaging link portion 175 or the first extending link portion 181 and the second extending link portion 183 do. That is, both ends of the connecting link portion 180 are rotatably connected to the first engaging link portion 170 and the second engaging link portion 175 or the first extending link portion 181 and the second extending link portion 183 . The length of the connecting link portion 180 is varied corresponding to the change in angle between the two extending

link portions

181 and 183. To this end, in this embodiment, the connection link portion 180 includes a central tube member 184 and two protruding and retracting

members

186 and 187 which are sleeved and coupled to both ends of the central tube member 184. A cable coupling shaft 185 is fixed to the center tube member 184 and ends of each of the protruding and retracting

members

186 and 187 are rotatably attached to the first engaging link portion 170 and the second engaging link portion 175 . The present invention is described as being configured such that two protruding and retracting

members

186 and 187 are coupled to both ends of a central tube member 184 by being sleeved to be able to protrude and retract to vary the length of the connecting link portion 180. However, However, the present invention is not limited to this, and other structures may be used in which the length of the link portion 180 can be varied, and this also falls within the scope of the present invention.

The cable coupling shaft 185 is a hollow shaft that extends parallel to the center shaft 161 and is fixed to the respective center pipe members 181 of the two connecting link portions 180. [ The second extension portion 123 of the cable 121 passes through the cable coupling shaft 185 and the second extension portion 123 is coupled to the cable coupling shaft 185. [ The second extending portion 123 of the cable 121 is slidably passed through the cable coupling shaft 185 in the present embodiment.

The first extended portion 122 of the cable 121 is fixed to the center shaft 161 and the second extended portion 123 of the cable 121 is slidable with the cable coupling shaft 185 Conversely, conversely, the first extension portion 122 of the cable 121 is slidable with the center shaft 161, and the second extension portion 123 of the cable 121 is fixed to the cable engagement shaft 185 And this is also within the scope of the present invention.

The plurality of solar cell modules 190 are fixed to the module fixing base 182 of the module mounting structure 160. The solar cell module 190, also referred to as a solar module, is a flat plate and has a conventional structure, so that a detailed description thereof will be omitted. The inclination of the solar cell module 190 is substantially the same as the first extending link portion 181 and can be changed in accordance with the rotation of the first extending link portion 181 to cope with the altitude change of the sun. Although two solar cell modules 190 are shown in this embodiment, three or more solar cell modules 190 may be installed, and this is also within the scope of the present invention.

The balance weight member 195 is installed in the module mounting structure 160 so as to be positioned on the opposite side of the solar cell modules 190 with the center shaft 161 therebetween. The balance weight member 195 is balanced to the left and right of the solar cell module unit 150, so that the load is prevented from being imbalanced.

Although not shown, the solar cell module device 150 may further include a driving motor for rotating the first and second

extended link portions

181 and 183 with respect to the center shaft 461. [ Further, although not shown, the solar cell module apparatus 150 further includes a controller for controlling a driving motor for rotating the first and second

extension link portions

181 and 183, The rotation angles of the two

extension link portions

181 and 183 are adjusted so that the solar cell module 190 can maintain the optimum inclination corresponding to the sun altitude. In the present embodiment, it is described that the controller operates to maintain the optimum slope of the solar cell module 190 according to the conditions. The conditions include a season, a time of day, and a month (January, February, etc.).

The solar cell module device 150 is configured such that the first and second

extended link parts

181 and 183 rotate in opposite directions to change the inclination of the solar cell module 190 and the length of the connecting link part 180 is The height difference between the center shaft 161 and the cable coupling shaft 185 (that is, the distance between the center shaft 161 and the cable coupling shaft 185) is changed. The second extended portion 123 of the cable 121 is formed to be longer than the first extended portion 122 in order to cope with a variation in height difference between the center shaft 161 and the cable coupling shaft 185 . Alternatively, the first extending portion 122 may be formed longer than the second extending portion 123, which is also within the scope of the present invention.

As shown in FIG. 1, in a state where a plurality of solar cell module devices 150 are sequentially arranged along the extension direction of the cable 121 and are spaced apart from the end of the cable 121 by a considerable distance, 4, when the drive roller 130a rotates, when the maintenance and repair of the module devices 150 are required, as the cable 121 circulates, the first 121 of the cable 121 The extension portion 122 moves in the direction of approaching the drive roller 130a and the second extension portion 123 of the cable 120 moves in the direction away from the drive roller 130a. The center shaft 161 of the solar cell module device 150 is fixed to the first extension portion 122 of the cable 121 and the cable coupling shaft 185 is fixed to the second extension portion 123 of the cable 120 The first extended portion 122 of the cable 121 moves toward the driving roller 130a so that the plurality of solar cell module devices 150 are moved toward the driving roller 130a together . FIG. 5 shows a state in which a plurality of solar cell module devices 150 are all moved toward the driving roller 130a. 5, 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 is a front view of another embodiment of the solar module apparatus shown in Fig. 6, the photovoltaic module device 250 is substantially similar to the photovoltaic module device 150 according to the embodiment shown in FIGS. 2 and 3 and includes a module mounting structure 260, A plurality of solar cell modules 190 installed in the module installation structure 260 and a balance weight member 195 installed in the module installation structure 260. The module mounting structure 260 includes a center shaft 161, two first extending link portions 181 coupled to the center shaft 161 and two second extending link portions 182 coupled to the center shaft 161 A first engaging link portion 170 connecting two first extending link portions 181 and a second engaging link portion 175 connecting two second extending link portions 183, Two coupling link portions 280 connecting the first coupling link portion 170 and the second coupling link portion 175, and a cable coupling shaft 185. The first extension link portion 181 and the second extension link portion 183 are fixedly coupled so as not to rotate with the center shaft 161 and the first and second

engagement link portions

170 and 175, Is fixedly coupled to the first and second

extension link portions

181 and 183 and the first and second

coupling link portions

170 and 175 so as not to rotate. Accordingly, the solar cell module 190 always maintains the same tilt. Other configurations are the same as the embodiments shown in Figs. 2 and 3. Fig.

6, in the case of a structure in which the first extending link portion 181 and the second extending link portion 183 are fixed so as not to rotate on the center shaft 161, In order to change the inclination, the second extension portion 123 is moved to one side (or the opposite side) as shown by the broken line arrow in the state where the first extension portion 122 is fixed, or the second extension portion The first extension portion 122 can be moved to one side (or the opposite side) as indicated by an alternate long and two short dashed line in a state where the first extension portion 123 is fixed. When the second extension part 123 is moved, the solar module device 250 rotates around the first extension part 122 like a triangle shown by a broken line, and the first extension part 122 is moved The solar module device 250 rotates about the second extension 123 as a triangle shown by the two-dot chain line. To this end, the photovoltaic power generation system may further include a side movement driving unit for moving the first extension unit 122 or the second extension unit 123 to the side. Additionally, the first extension portion 122 and the second extension portion 123 may be moved together in the opposite lateral direction. Alternatively, the same effect may be obtained by rotating the drive roller (130a in FIG. 1), the driven roller (130 in FIG. 1) and the plurality of support rollers (140 in FIG. 1) A driving roller 130a, a driven roller 130, and a plurality of supporting rollers 140. [ It is also within the scope of the present invention that the inclination of the solar cell module 190 does not change because the first extension portion 122 and the second extension portion 123 do not move sideways or rotate in Fig.

7 is a front view of a module installation structure according to another embodiment of the present invention. 7, the module mounting structure 360 includes a center shaft 161, two first extending link portions 181 coupled to the center shaft 161, and two first extending link portions 182 coupled to the center shaft 161. [ A second coupling link portion 170 connecting the first extended link portion 181 and the second extended link portion 183 and a second coupling link portion 170 connecting the two second extended link portions 183, Two coupling link portions 380 connecting the first coupling link portion 170 and the second coupling link portion 175 and a cable coupling shaft 185. The center shaft 161, the first extending link portion 181, the second extending link portion 183, the first coupling link portion 170, the second coupling link portion 175, 3, detailed description thereof will be omitted. The connection link portion 380 is in the shape of an arc centering on the center shaft 161 and both ends of the cable coupling shaft 185 are connected to the first coupling link portion 170 and the second coupling link portion 175, And is coupled to the link portion 181 and the second extension link portion 183. The length of the connecting link portion 380 is varied corresponding to the change in angle between the two extending

link portions

181 and 183. To this end, in this embodiment, the connecting link portion 380 has a central tube member 384 and two protruding and retracting

members

386 and 387 which are sleeved and coupled to both ends of the central tube member 384. A cable coupling shaft 185 is fixed to the center pipe member 384 and the ends of the two protruding and retracting

members

386 and 387 are coupled to the first coupling link 170 and the second coupling link 175, respectively. The present invention is described as being configured such that two protruding and retracting

members

386 and 387 are coupled to both ends of the central tube member 384 by being sleeved to be able to protrude and retract to vary the length of the connecting link unit 380. However, However, the present invention is not limited thereto, and other structures are also possible, such that the length of the connecting link portion 380 can be varied, and this is also within the scope of the present invention. Even when the angle between the two extending

link portions

181 and 183 changes, the connecting link portion 380 is formed in an arc shape about the center shaft 161, The distance can be kept constant and both ends of the connecting link portion 380 need not be rotatable.

8 shows another embodiment of the solar cell module apparatus as a perspective view. 8, the solar cell module device 450 includes a module installation structure 160, a plurality of solar cell modules 190 rotatably installed in the module installation structure 160, (Not shown) installed in the module installation structure 160. The module installation structure 160 is provided with a module direction adjusting unit for adjusting the direction by rotating the modules 190.

The module installation structure 160 is generally a truss-like structure and has substantially the same configuration as the module installation structure 160 shown in FIG. The module mounting structure 160 shown in FIG. 8 further includes a plurality of module support shafts 480 connecting the center shaft 161 and the first coupling link portion 170. The solar cell module 190 is rotatably coupled to the module support shaft 480. [

The solar cell module 190 has the same configuration as the solar cell module 190 of the embodiment shown in FIG. A rotation coupling part 495 rotatably coupled to the module support shaft 480 and fixed to the solar cell module 190 is provided on the back surface of the solar cell module 190. The direction of the solar cell module 190 is controlled by means of the module direction adjusting means by rotating the rotary engaging portion 495 with respect to the module supporting shaft 480.

The module direction adjusting means includes a plurality of protruding bar portions 496 protruding from a rotational engaging portion 495 formed on each of the plurality of solar cell modules 190 and a plurality of protruding bar portions 496 And a wire 499 connected and extending generally along the horizontal direction. The wire 499 reciprocates along the extending direction thereof, so that the solar cell module 190 is rotated and its direction is controlled. The direction of the solar cell module 190 is changed from the east side to the west side along the sun's moving path so as to follow the sun during the day by the module direction adjusting means. Although not shown, the present embodiment further includes a drive motor for moving the wire 499.

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.

Claims

1. A solar cell module apparatus for installing on a cable having a first extending portion and a second extending portion extending in parallel,

A module attachment structure having a center shaft to which the first extension part is coupled, a cable coupling shaft that is located below the center shaft and to which the second extension part is coupled, and a coupling structure that is coupled between the center shaft and the cable shaft; And

And at least one solar cell module fixed to the connection structure,

Wherein the at least one solar cell module is fixed to the connection structure portion so as to be inclined to one side of the center shaft.
The method according to claim 1,

The connecting structure includes a first elongated link portion extending obliquely downwardly from the center shaft in the radial direction, a second elongated link portion extending obliquely downwardly from the center shaft in the radial direction, And a connection link portion connecting the extension link portion and the second extension link portion.
The method of claim 2,

Wherein the first extending link portion and the second extending link portion are rotatably coupled to the center shaft so that the tilt of the solar cell module is adjusted,

Wherein the connecting link portion is rotatably connected to each of the first extending link portion and the second extending link portion, and the length of the connecting link portion is variable.
The method of claim 2,

Wherein the first extending link portion and the second extending link portion are rotatably coupled to the center shaft so that the tilt of the solar cell module is adjusted,

Wherein the connecting link portion has an arc shape centering on the center shaft and the length thereof is variable.
The method according to claim 3 or 4,

Wherein the connecting link portion includes a central tube member and two protruding and retracting members which are sleeved and coupled to both ends of the central tube member.
The method of claim 5,

And the cable coupling shaft is fixed to the center tube member.
The method according to claim 3 or 4,

And a driving motor for rotating the first elongated link portion and the second elongated link portion with respect to the center shaft for adjusting the tilt of the solar cell module.
The method of claim 7,

And a controller for controlling the drive motor to adjust the tilt of the solar cell module.
The method of claim 2,

Wherein the first extending link portion and the second extending link portion are plural,

Wherein the connection structure portion further comprises a first coupling link portion connecting the plurality of first extending link portions and a second coupling link portion connecting the plurality of second extending link portions.
The method of claim 2,

Wherein the first extending link portion and the second extending link portion are fixedly coupled to the center shaft.
The method according to claim 1,

And a balance weight member installed on the module mounting structure so as to be positioned on the opposite side of the at least one solar cell module with the center shaft interposed therebetween.
The method according to claim 1,

Wherein the solar cell module is rotatably coupled to the connection structure such that a direction of the solar cell module is adjusted.
Two support pillars;

A cable structure having a cable installed to extend between the two support posts; And

And a solar cell module device having a module installation structure coupled to the cable and at least one solar cell module installed in the module installation structure,

Said cable having a first extension and a second extension located below said first extension and extending parallel to said first extension,

The module installation structure includes:

A cable coupling shaft which is located below the center shaft and to which the second extending portion is coupled; and a coupling structure coupled between the center shaft and the cable shaft, And,

Wherein the at least one solar cell module is disposed obliquely to one side of the center shaft,

Photovoltaic power generation equipment that is a solar cell module device.
14. The method of claim 13,

Wherein one of the first extension and the second extension is formed longer than the other.
14. The method of claim 13,

Wherein the cable is connected to the first extension and the second extension to form a single closed curve,

The cable structure further comprising a drive roller for circulating the cable,

Wherein one of the first extension and the second extension is slidably coupled to the module installation structure and the other is fixed to the module installation structure.
14. The method of claim 13,

The connecting structure includes a first elongated link portion extending obliquely downwardly from the center shaft in the radial direction, a second elongated link portion extending obliquely downwardly from the center shaft in the radial direction, And a connection link portion connecting the extension link portion and the second extension link portion,

Wherein the first elongated link portion and the second elongated link portion are fixedly coupled to the center shaft,

And the tilt of the solar cell module is adjusted by rotating the module installation structure about the extending direction of the cable.
18. The method of claim 16,

And the slope of the solar cell module is adjusted by moving the first extension portion or the second extension portion to the side.
18. The method of claim 16,

Wherein the cable is rotated around an extending direction of the cable to adjust a tilt of the solar cell module.
14. The method of claim 13,

Wherein the solar cell module is rotatably coupled to the connection structure such that a direction of the solar cell module is adjusted.
The method of claim 19,

Wherein a plurality of the solar cell modules are disposed along an extending direction of the cable,

Further comprising a reciprocating wire for adjusting the direction of the plurality of solar cell modules,

And the wires are coupled in turn to the plurality of solar cell modules.
The method of claim 20,

The connection structure further includes a plurality of support shafts arranged corresponding to each of the plurality of solar cell modules,

The solar cell module has a rotation coupling portion rotatably coupled to the support shaft,

And a protruding bar portion protruding from the rotary coupling portion and coupled with the wire.