KR102566402B1 - Photovoltaic power generation facility - Google Patents

Abstract

According to the present invention, the foundation structure; a support cable installed to extend along the transverse direction to the foundation structure; a plurality of pillars sequentially disposed along the extending direction of the support cable and supported by the support cable; Solar cell modules installed to be fixed to each of the plurality of pillars; There is provided a photovoltaic power generation facility including a plurality of pillar rotation supports for supporting each of the plurality of pillars with respect to the ground so as to be axially rotated from below.

Description

Solar power facility {PHOTOVOLTAIC POWER GENERATION FACILITY}

The present invention relates to photovoltaic power generation, and more particularly, to a photovoltaic power generation facility having a structure in which a plurality of solar cell modules are installed using cables.

Fossil fuel, which is mainly used to produce electricity today, is a kind of resource with limited reserves on the earth. It is used indiscriminately in accordance with the rapidly increased acceptance of electric energy due to industrial development, causing serious environmental pollution, as well as destroying the resource in the near future. As it is expected to be depleted, the development of so-called clean energy that can replace fossil fuels is actively promoted all over the world, and a representative example is solar power generation.

Solar power generation, along with wind power generation, is attracting great attention because it is non-polluting and can be used infinitely among alternative energies. In particular, photovoltaic power generation is composed of semiconductor devices and control parts having a very long lifespan, and there is no generation of mechanical vibration or noise, and the operation life span of several decades is guaranteed.

As a prior art related to the present invention, Patent Registration No. 10-2112354 discloses a support structure having a hanging cable and a fixing cable located under the hanging cable, a solar cell module is installed, and the hanging cable and A configuration of a solar cell module device having a module installation structure coupled to the fixing cable is described. However, the structure of installing a plurality of solar cell modules using such a conventional cable is difficult to apply in practice due to the complexity of the structure.

Republic of Korea Registered Patent Registration No. 10-2112354 "Solar cell module device and photovoltaic power generation facility having the same" (2020.05.15)

An object of the present invention is to provide a photovoltaic power generation facility in which a plurality of solar cell modules can be easily installed using a cable, and its operation is also easy.

In order to achieve the above object of the present invention, according to one aspect of the present invention, the foundation structure; a support cable installed to extend along the transverse direction to the foundation structure; a plurality of pillars sequentially disposed along the extending direction of the support cable and supported by the support cable; Solar cell modules installed to be fixed to each of the plurality of pillars; There is provided a photovoltaic power generation facility including a plurality of pillar rotation supports supporting each of the plurality of pillars to be axially rotated with respect to the ground from below.

According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, in the photovoltaic power generation facility of the present invention, since a pillar on which a plurality of solar cell modules are installed is supported on a support cable extending in the lateral direction to maintain an upright state, and the pillar is axially rotated on the ground, Simple structure makes installation and operation easy.

1 is a perspective view showing a photovoltaic power generation facility according to an embodiment of the present invention.
FIG. 2 is a view showing a support structure in the photovoltaic power plant shown in FIG. 1 .
FIG. 3 is a perspective view showing an enlarged main part of the photovoltaic power generation facility shown in FIG. 1 .
Figure 4 is a view showing a column rotation support in Figure 3;
5 is a view showing another embodiment of the pillar rotation support shown in FIG.
Figure 6 is a view showing another embodiment of the pillar rotation support shown in Figure 4;
Figure 7 is a view showing another embodiment of the pillar rotation support shown in Figure 4;

1 shows a photovoltaic facility 100 according to an embodiment of the present invention as a perspective view. Referring to FIG. 1, a photovoltaic power generation facility 100 according to an embodiment of the present invention includes a foundation structure 110, a cable structure 113 installed on the foundation structure 110, and a cable structure 113. A cable height adjusting means 115 for adjusting the height, a plurality of power generation units 120 supported by the cable structure 113, and a plurality of suspended solar cell modules 170 installed on the cable structure 113 ), and a module direction adjusting means 180 for adjusting the direction of the plurality of power generation units 120.

1 and 2, the foundation structure 110 includes a first foundation 111a and a second foundation 111b spaced apart from the first foundation 111a by a predetermined distance.

The first foundation 111a is fixed to the ground E and has a columnar shape extending upward from the ground S. A cable height adjusting means 115 is installed on the first foundation 111a. In this embodiment, the first foundation (111a) is described as having a columnar shape, however, it may have a different shape such as a wall shape, which also falls within the scope of the present invention.

The second foundation 111b is located at a predetermined distance from the first foundation 111a. The 2nd base (111b) is fixed to the ground (E) and is a pillar shape extending upward from the ground (S). A cable height adjusting means 115 is installed on the second foundation 111b. In this embodiment, the second base (111b) is described as having a columnar shape, however, it may have a different shape such as a wall shape, which also falls within the scope of the present invention.

The cable structure 113 is coupled to the base structure 110 so that the height can be adjusted by the cable height adjusting means 115.

The cable structure 113 is coupled to the base structure 110 so that the height can be adjusted by means of the cable height adjusting means 115 . The cable structure 113 includes a first support cable 113a and a second support cable 113b. A plurality of power generation units 120 are coupled to and supported by the first support cable 113a and the second support cable 113b.

The first support cable 113a extends substantially horizontally along the transverse direction between the first foundation 111a and the second foundation 111b of the foundation structure 110 . Both ends of the first support cable 113a are coupled to the first foundation 111a and the second foundation 111b to be height-adjustable via a cable height adjusting unit 115. A plurality of suspended solar cell modules 170 are installed in a suspended manner on the first support cable 113a. The second support cable 113b is positioned under the first support cable 113a.

The second support cable 113b is spaced apart from the bottom of the first support cable 113a. The second support cable 113b extends substantially horizontally along the transverse direction between the first foundation 111a and the second foundation 111b of the foundation structure 110 . Both ends of the second support cable 113b are coupled to the first foundation 111a and the second foundation 111b to be height-adjustable via a cable height adjusting unit 115. A plurality of suspended solar cell modules 170 are installed in a suspended manner on the second support cable 113b.

In this embodiment, the cable structure 113 is described as having two support cables 113a and 113b, but, unlike this, the support cables may be one or three or more, which also falls within the scope of the present invention.

The support cables 113a and 113b may stretch due to various causes such as snow or rain. The photovoltaic power plant 100 may further include a tension maintaining device for preventing the support cables 113a and 113b from being stretched or returning the stretched support cables 113a and 113b to their original tensioned state.

The cable height adjusting means 115 is for adjusting the height of the cable structure 113. The cable height adjusting means 115 includes a first guide 116a installed on the first foundation 111a, two first movable members 118a movably coupled to the first guide 116a, It includes a second guide 116b installed on the second base 111b and two second moving members 118b movably coupled to the second guide 116b. When installing the photovoltaic power generation facility 100, the height of the cable structure 113 may be appropriately adjusted using the cable height adjusting means 115 in consideration of the height of the power generation unit 120.

The first guide 116a is installed on the first base 111a so as to elongate along the height direction. The first guide 116a has a rail shape and is disposed toward the second base 111b. Two first moving members 118a are movably coupled to the first guide 116a.

Each of the two first movable members 118a is independently movably coupled to the first guide 116a. Each of the two first movable members 118a may move up and down in the height direction along the first guide 116a. The first support cable 113a is coupled to the upper one of the two first moving members 118a, and the second support cable 113b is coupled to the lower one. Although not shown, the cable height adjusting means 115 further includes a position fixing means for fixing the height of the first moving member 118a and a moving means such as a rope for moving the first moving member 118a. can do. In this embodiment, the first movable member 118a is described as two, but it may be one or three or more, which also falls within the scope of the present invention.

The second guide 116b is installed on the second foundation 111b so as to elongate along the height direction. The second guide 116b has a rail shape and is disposed toward the first foundation 111a. Two second moving members 118b are movably coupled to the second guide 116b.

Each of the two second movable members 118b is independently movably coupled to the second guide 116b. Each of the two second movable members 118b can move up and down in the height direction along the second guide 116b. The first support cable 113a is coupled to the upper one of the two second moving members 118b, and the second support cable 113b is coupled to the lower one. Although not shown, the cable height adjusting means 115 further includes a position fixing means for fixing the height of the second moving member 118b and a moving means such as a rope for moving the second moving member 118b. can do. In this embodiment, it is described that the second moving member 118b is two, but it may be one or three or more, which also falls within the scope of the present invention.

The plurality of power generation units 120 are sequentially spaced apart and disposed between the first foundation 111a and the second foundation 111b. A plurality of power generation units 120 are coupled to the first support cable 113a and the second support cable 113b.

1 and 3, each of the plurality of power generation units 120 includes a pole 121, a plurality of solar cell modules 160 installed on the pole 121, and the pole 121 in the ground ( E) is provided with a pillar rotation support 150 that supports shaft rotation.

The pillar 121 is fixed to the ground (E) and extends upward from the ground (S). The lower end of the pillar 121 is supported by the pillar rotation support 150 so that it can pivot. The pillar 121 is coupled to the first support cable 113a and the second support cable 113b to maintain a vertically erected state. The pillar 121 and each of the two support cables 113a and 113b are coupled by a coupler 122 at an intersection point. A plurality of solar cell modules 160 are coupled and fixed to the pillar 121 . The pillar 121 is rotated by the module direction adjusting means 180 to adjust the direction of the plurality of solar cell modules 160 . The pillar 121 may be configured by connecting a plurality of rod members.

A plurality of solar cell modules 160 are installed on the pillar 121 . A plurality of solar cell modules 160 are sequentially spaced apart from each other along the height direction. A plurality of solar cell modules 160 are all fixed to the pillar 121 facing the same direction. Accordingly, as the pillar 121 pivots, the plurality of solar cell modules 160 all rotate together and face the same direction. Not only the solar cell modules 160 installed in one power generation unit 120, but also all the solar cell modules 160 installed in the plurality of power generation units 120 face the same direction. In this embodiment, the solar cell module 160 will be described as having a flat plate shape elongated along the height direction. Although the number of solar cell modules 160 is described as two in this embodiment, it may be three or more, which also falls within the scope of the present invention. Also, only one solar cell module 160 may be provided, which also falls within the scope of the present invention. Since the solar cell module 160, also called a solar module, has a conventional configuration, a detailed description thereof is omitted here.

The pillar rotation support part 150 supports the pillar 121 so as to be able to pivot on the ground (E). Referring to FIG. 4 , the pillar rotation support 121 includes a contact washer 158 in contact with the lower end of the pillar 121 and an anchor 151 fixing the contact washer 158 to the ground S.

The contact washer 158 is fixed to the ground S by an anchor 151. The upper surface of the contact washer 158 and the lower end of the column 121 are in contact.

The anchor 151 fixes the contact washer 158 to the ground (S). The anchor 151 includes an anchor bolt 152 partially embedded in the ground E and fixed to the ground E, and an anchor nut 155 coupled with the anchor bolt 152 to fix the contact washer 158 provide

The anchor bolt 152 includes a bolt body 154 in which a male thread is formed, and a bolt head 153 positioned at one end of the bolt body 154. The bolt body 154 is fixed to the ground (E) so that a part is embedded in the ground (E) and the rest protrudes above the ground (S) of the ground (E). The part protruding above the ground (S) in the bolt body 154 is accommodated in the inner space of the hollow pillar 121. A contact washer 158 is inserted into a portion of the bolt body 154 protruding above the ground S. The bolt head 153 is entirely buried in the ground (E).

The anchor nut 155 is coupled to the bolt body 154 of the anchor bolt 152 to fix the contact washer 158 inserted into the bolt body 154 on the ground (S).

5 shows another embodiment of the pillar rotation support. Referring to FIG. 5 , the pillar rotation support 250 includes a pillar receiving member 251 that is embedded and fixed to the ground E. A pillar receiving groove 253 with an open top is formed inside the pillar receiving member 251 . The lower end of the pillar 121 is rotatably accommodated in the pillar receiving groove 253 .

6 shows another embodiment of the pillar rotation support. Referring to FIG. 6 , the pillar rotation support 350 includes a body 351 fixed to the ground E and a protrusion 353 protruding upward from the body 351 .

A part of the body 351 is fixed by being buried in the ground (E), and the rest is exposed by protruding above the ground (S). The protrusion 353 is located in the center of the flat upper surface 352 of the body 351. The flat upper surface 352 of the body 351 is in contact with the lower end of the pillar 121.

The protruding portion 353 is formed by protruding upward from the center of the upper surface 352 of the body 351 . The lower end of the pillar 121 is inserted into the protrusion 353 .

7 shows another embodiment of the pillar rotation support. Referring to FIG. 7, the pillar rotation support 450 includes a pillar flange 422 formed at the lower end of the pillar 121, a pillar support member 456 supporting the pillar flange 422 from below, and a pillar support member An anchor 151 fixing the 456 to the ground S, and a lubricating oil 459 reducing friction between the pillar flange 422 and the pillar supporting member 456 are provided.

The pillar flange 422 extends outward from the lower end of the pillar 121 and is integrally formed with the pillar 121 . The pillar flange 422 reduces friction with the pillar support member 456 by the lubricating oil 459 .

The pillar support member 456 is fixed to the ground (S) by an anchor 151 . The pillar support member 456 has a seating groove 457 with an open top formed therein. The pillar flange 422 is seated in the seating groove 457. The bottom 458 of the seating groove 457 faces the pillar flange 422.

The anchor 151 fixes the pillar support member 456 to the ground (S). The anchor 151 includes an anchor bolt 152 partially embedded in the ground E and fixed to the ground E, and an anchor nut 155 coupled with the anchor bolt 152 to fix the pillar support member 456 to provide

The anchor bolt 152 includes a bolt body 154 in which a male thread is formed, and a bolt head 153 positioned at one end of the bolt body 154. The bolt body 154 is fixed to the ground (E) so that a part is embedded in the ground (E) and the rest protrudes above the ground (S) of the ground (E). The bolt body 154 passes through the pillar support member 456. The part protruding above the ground (S) in the bolt body 154 is accommodated in the inner space of the hollow pillar 121. The bolt head 153 is entirely buried in the ground (E).

The anchor nut 155 is coupled to the bolt body 154 of the anchor bolt 152 to fix the pillar support member 456 inserted into the bolt body 154 on the ground (S).

The lubricating oil 459 reduces friction by preventing direct contact between the pillar flange 422 and the pillar supporting member 456 in the seating groove 457 of the pillar supporting member 456 .

Although not shown, the pillar rotation support may be composed of a conventional bearing device, which also falls within the scope of the present invention. One of the two relative rotating parts of the bearing device is fixed to the ground (S), and the other rotating part is fixed to the column (121).

Referring to FIGS. 1 and 3 , a plurality of suspended solar cell modules 170 are installed in such a way as to be suspended from a first support cable 113a and a second support cable 113b. Since the suspended solar cell module 170 is a solar cell module having a typical configuration, a detailed description thereof is omitted here. A hook 175 hooked to the first support cable 113a or the second support cable 113b is installed at the upper end of the suspended solar cell module 170 .

The module direction adjusting means 180 is for adjusting the direction of a plurality of solar cell modules 160 . The manager of the photovoltaic power generation facility 100 can adjust the direction of the plurality of solar cell modules 160 by simultaneously pivoting the pillars 121 at the same angle using the module direction adjusting unit 180 . The module direction adjusting means 180 is connected to a plurality of pillar arm parts 182 formed by protruding from each of the plurality of pillars 121 and coupled to each of the plurality of pillar arm parts 182 to be relatively rotatable. A member 185 and a direction adjusting arm 195 fixed to any one of the plurality of pillars 121 are provided.

Each of the plurality of pillar arm parts 182 protrudes from each of the plurality of pillars 121 and is integrally formed. The post arm portion 182 extends radially outward from the corresponding post 121 . All of the plurality of pillar arm parts 182 are located at substantially the same height. Each of the plurality of pillar arm parts 182 is rotatably hinged to the connecting member 185 .

The connecting member 185 has a rod shape extending in a straight line and is disposed to extend parallel to the extending direction of the first and second support cables 113a and 113b. The connecting member 185 is hinge-coupled with each of the plurality of pillar arm parts 182 to be relatively rotatable. The plurality of pillars 121 are rotated in the same direction and angle by the connecting member 185 .

The direction adjusting arm 195 is fixed to any one of the plurality of poles 121 . The direction adjusting arm 195 extends radially outwardly from the pillar 121 to which it is fixed. Rotational force is transmitted to the pillar 121 integrally fixed through the direction adjusting arm 195 .

Although not shown, the photovoltaic power generation facility 100 may further include a driving unit for automatically pivoting one of the plurality of pillars 121 with external power. The drive unit (not shown) includes a drive motor (not shown) that produces rotational force and a power transmission unit that transmits the rotational force produced by the drive motor (not shown) to one of the plurality of pillars 121 (121) ( (not shown) and a controller (not shown) loaded with a program for controlling the operation of a drive motor (not shown). The power transmission unit (not shown) may disconnect the mechanical connection between the driving motor (not shown) and the pole 121, and this state is referred to as a neutral state in this embodiment. In a neutral state, the pillar 121 can rotate freely, so that the photovoltaic power generation facility 100 can be prevented from being damaged by strong winds. A controller (not shown) may operate a driving motor (not shown) to change the direction of the plurality of solar cell modules 160 in response to the changing position of the sun during the day. For example, in the morning, the solar cell modules 160 face southeast, at noon, the solar cell modules 160 face south, and in the afternoon, the solar cell modules 160 face southwest, so that the controller (not shown) is driven by a driving motor (not shown) can be controlled.

Although not shown, the photovoltaic facility 100 may further include a wind direction and wind speed gauge. The wind direction and speed meter measures the direction and speed of the wind blowing through the photovoltaic power generation facility 100, converts the measured wind direction and speed into electrical signals, and transmits them to a controller (not shown). The controller (not shown) may prevent the photovoltaic power generation facility 100 from being damaged by strong winds by using wind direction and wind speed information. For example, when the wind speed is higher than a set wind speed, the controller (not shown) may rotate the poles 121 so that the solar cell module 160 is disposed parallel to the wind direction.

Some of the electricity generated by the suspended solar cell modules 170 may be used as self-power for the operation of the photovoltaic power generation facility 100 including a drive motor (not shown).

Although the present invention has been described through the above examples, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100: solar power plant 110: foundation structure
111a: first foundation 111b: second foundation
113: cable structure 113a: first support cable
113b: second support cable 115: height adjustment means
116a: first guide 116b: second guide
118a: first moving member 118b: second moving member
120: power generation unit 121: column
160: solar cell module 150: pillar rotation support
151: anchor 152: anchor bolt
153: bolt head 154: bolt body
155: anchor nut 158: contact washer
170: suspended solar cell module 180: module direction adjustment means
250: pillar rotation support 251: pillar receiving member
253: column receiving groove 350: column rotation support
351: body 353: protrusion
450: column rotation support 422: column flange
456: column supporting member 457: seating groove
459 Lubricating oil

Claims (17)

foundation structures;
a support cable installed to extend along the transverse direction to the foundation structure;
a plurality of pillars sequentially disposed along the extending direction of the support cable and supported by the support cable;
Solar cell modules installed to be fixed to each of the plurality of pillars;
Including a plurality of pillar rotation supports for supporting each of the plurality of pillars to be axially rotated with respect to the ground from below,
The pillar rotation support includes a washer contacting the lower end of the pillar and an anchor fixing the contact washer,
The anchor includes an anchor bolt and an anchor nut coupled to the anchor bolt,
A part of the anchor bolt is buried in the ground and the rest protrudes from the ground while passing through the contact washer,
The anchor nut is coupled to a portion of the anchor bolt protruding from the ground to fix the contact washer to the ground,
In a state in which the lower end of the pillar and the contact washer are in contact, the anchor bolt protruding from the ground and the anchor nut are received inside the pillar,
A plurality of solar cell modules are sequentially located on one pillar along the height direction,
solar power plant. delete delete delete delete delete foundation structures;
a support cable installed to extend along the transverse direction to the foundation structure;
a plurality of pillars sequentially disposed along the extending direction of the support cable and supported by the support cable;
Solar cell modules installed to be fixed to each of the plurality of pillars;
Including a plurality of pillar rotation supports for supporting each of the plurality of pillars to be axially rotated with respect to the ground from below,
The pillar rotation support unit comprises a pillar flange formed by extending outward from the lower end of the pillar, a pillar support member having a seating groove in which the pillar flange is seated and installed on the ground to support the pillar, and the pillar support member An anchor for fixing and a lubricating oil for reducing friction between the pillar flange and the pillar supporting member in the seating groove,
The anchor includes an anchor bolt and an anchor nut coupled to the anchor bolt,
A part of the anchor bolt is buried in the ground and the rest protrudes from the ground while passing through the pillar support member,
The anchor nut is coupled to a portion of the anchor bolt protruding from the ground to fix the pillar support member to the ground,
In a state in which the pillar flange is seated in the seating groove, the anchor bolt protruding from the ground and the anchor nut are received inside the pillar,
A plurality of solar cell modules are sequentially located on one pillar along the height direction,
solar power plant. According to claim 1 or claim 7,
Further comprising module direction adjusting means for adjusting the rotation direction of the plurality of pillars,
solar power plant. The method of claim 8,
The module direction adjusting means includes a plurality of pillar arms formed by extending radially outwardly from each of the plurality of pillars, and a connecting member rotatably hinged to each of the plurality of pillar arms,
solar power plant. The method of claim 9,
The module direction adjusting means further comprises a direction adjusting arm fixed to any one of the plurality of pillars,
solar power plant. The method of claim 8,
Further comprising a driving unit having a drive motor for producing rotational force and a power transmission unit for transmitting the rotational force to any one of the plurality of pillars,
solar power plant. The method of claim 11,
Further comprising a controller for controlling the operation of the drive motor,
solar power plant. The method of claim 12,
Further comprising a wind direction and wind speed instrument for measuring wind direction and speed,
When the wind speed is equal to or greater than the set wind speed, the controller controls the operation of the drive motor so that the solar cell module is disposed parallel to the wind speed.
solar power plant. According to claim 1 or claim 7,
Further comprising a cable height adjusting means for adjusting the height of the support cable,
solar power plant The method of claim 14,
The cable height adjusting means includes a first guide extending along the height direction and fixed to the foundation structure, and a second guide positioned apart from the first guide by a predetermined distance and extending along the height direction and fixed to the foundation structure. And, a first moving member movably coupled to the first guide along the height direction and coupled to one end of the support cable, and movably coupled to the second guide along the height direction and coupled to the other end of the support cable Equipped with a second moving member to which is coupled,
solar power plant. delete According to claim 1 or claim 7,
Further comprising a plurality of suspended solar cell modules installed in a hanging form on the support cable,
solar power plant.

Images