KR101941436B1 - Solar power apparatus for slope - Google Patents

Abstract

The inclined plane photovoltaic device according to the present invention includes an upper support portion provided on an upper part of an inclined surface; A lower support portion provided below the inclined surface; A sliding wire portion connected to the upper support portion and the lower support portion and having a plurality of wires supported so as to be spaced apart from the inclined surface; And a plurality of solar cell modules connected to each other and slidable along the plurality of wires.

Description

 [0001] SOLAR POWER APPARATUS FOR SLOPE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an inclined solar power generator installed on an inclined surface using a wire.

Recently, the importance of alternative energy has been emphasized due to depletion of petroleum energy and various energy, increase of production cost, global warming, and environmental pollution. Interest and investment in solar energy, which has various advantages as one of renewable energy, .

Generally, the term "solar power generation" refers to a method in which plate-shaped light collecting panels arranged in a longitudinal direction are laid out in a certain space, and sunlight incident thereon is condensed to obtain electric energy. Such a photovoltaic device generally includes a solar cell condensing panel in which a solar panel is connected in series or in parallel to supply necessary power, a storage battery for storing the condensed power, a power regulator for regulating the power, And the like. Photovoltaic power generation is advantageous in that it uses infinite energy of the sun, does not cause pollution, can only be developed as needed for the required place, and is easy to maintain. However, There is a disadvantage that the initial investment cost and the power generation unit cost are high.

Meanwhile, solar power determines the total amount of energy produced by how large a solar cell can be installed than the amount of light energy from the sun. In addition, it is necessary to secure an inexpensive site or topography . In particular, since the slope site has low utility value in terms of real estate and the cost of securing the site is low, it is advantageous to install a photovoltaic power generation facility on a slope site, and it is advantageous to have high power generation efficiency at a lower cost. There is a need for an effective photovoltaic device.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a sloping solar photovoltaic device having a simple and more stable structure on an inclined surface with a somewhat lower land use degree and having improved power generation efficiency at a lower cost have.

According to an aspect of the present invention, there is provided a solar photovoltaic device including: an upper supporting part provided on an upper surface of an inclined surface; A lower support portion provided below the inclined surface; A sliding wire portion connected to the upper support portion and the lower support portion and having a plurality of wires supported so as to be spaced apart from the inclined surface; And a plurality of solar cell modules connected to each other and slidable along the plurality of wires.

Further, in the photovoltaic device according to the present invention, the solar cell module part may include: a plate-shaped body plate having a solar cell on an upper surface thereof; A sliding guide provided on a lower surface of the body plate and guiding the sliding member along the plurality of wires; An upper connection part provided at an upper end of the body plate and connected to another solar cell module part; And a lower connection part provided at a lower end of the body plate and connected to another solar cell module part.

The photovoltaic apparatus according to the present invention may further include an intermediate supporting portion provided on an inclined surface between the upper supporting portion and the lower supporting portion, which supports the plurality of wires so as to be spaced apart from the inclined surface.

Further, in the photovoltaic device according to the present invention, the sliding wire portion may further include an extending wire portion extending from the upper supporting portion to an opposite inclined surface of the inclined surface, and the extending wire portion may include a weight .

In the photovoltaic device according to the present invention, a part of the wire extending from the extending wire portion to the opposite inclined surface of the inclined surface through the upper supporting portion is buried.

Further, in the photovoltaic device according to the present invention, the solar cell module part may include: a plate-shaped body plate having a solar cell on an upper surface thereof; A slope plate fixedly coupled to one side of the body plate at a predetermined angle; A sliding guide provided on the lower surface of the body plate and the swash plate for guiding the plurality of wires to slide; An upper connection part provided at an upper end of the body plate and connected to another solar cell module part; And a lower connection part provided at a lower end of the swash plate and connected to another solar cell module part.

Further, in the photovoltaic device according to the present invention, a reflection mirror is attached to the swash plate, the inclination angle of the solar cell is adjusted by the predetermined angle formed by the swash plate and the body plate, And the reflected light is projected to the another solar cell module part.

Further, in the photovoltaic device according to the present invention, the solar cell module part may include: a plate-shaped body plate having a solar cell on an upper surface thereof; A swash plate rotatably coupled to one side of the body plate; A rotation fixing bar for fixing a rotation of the body plate and the swash plate;

A sliding guide provided on the lower surface of the body plate and the swash plate and guiding the plurality of wires to be slidably loaded; An upper connection part provided at an upper end of the body plate and connected to another solar cell module part; And a bottom connection part provided at a lower end of the swash plate and connected to another solar cell module part.

In the photovoltaic device according to the present invention, a reflection mirror is attached to the swash plate, the inclination angle of the solar cell is adjusted by a predetermined angle formed by the swash plate and the body plate, Light is projected to another solar cell module section.

The sloping solar photovoltaic device according to the present invention can be easily installed or demounted by connecting a plurality of connected solar cell modules slidable along the wire with low cost and simple structure using wires on the sloped surface.

In addition, even when the upper surface of the slope is weak, the wire is extended to the opposite surface of the slope, and the weight is provided at the end of the slope so that the wire itself can balance the load by itself, A photovoltaic device may be provided. On the other hand, since a part of the extending wire is buried in the upper part of the inclined surface, space utilization of the upper part of the inclined surface can be increased.

In addition, since the solar cell module can have a specific angle based on the inclined plane, the inclination angle of the solar cell module can be arbitrarily adjusted, and the inclination angle that can optimize the solar power generation efficiency can be obtained regardless of the angle of the inclined plane . On the other hand, a reflection mirror may be further provided to change the incidence direction of sunlight to further improve solar power generation efficiency.

1A is a perspective view of a sloping solar photovoltaic apparatus according to an embodiment of the present invention.
FIG. 1B is a side view of a sloping solar photovoltaic apparatus according to an embodiment of the present invention.
1C is a perspective view of a solar cell module part of an inclined-surface solar power generation apparatus according to an embodiment of the present invention.
FIG. 1D is a cross-sectional view of an intermediate supporting portion of an inclined plane solar power generator according to an embodiment of the present invention.
2 is a side view of a sloping solar photovoltaic device according to another embodiment of the present invention.
FIG. 3A is a side view of a sloping solar photovoltaic device according to another embodiment of the present invention.
FIG. 3B is a cross-sectional view of an extension wire portion buried in a sloping solar photovoltaic device according to another embodiment of the present invention. FIG.
4A is a perspective view illustrating another embodiment of the solar cell module unit of the inclined plane solar power generator according to the present invention.
FIG. 4B is a perspective view showing still another embodiment of the solar cell module unit of the inclined plane solar power generator according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a slope photovoltaic apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The following embodiments are merely provided to understand the contents of the present invention, and those skilled in the art will be able to make many modifications within the technical scope of the present invention. Therefore, the scope of the present invention should not be construed as being limited to these embodiments. In addition, when a part is referred to as being "connected" to another part, it may include not only a case where it is directly connected, but also a case where it is indirectly connected with another component in between have. Also, to include or " comprise " any element may mean that it may include other elements, rather than excluding elements other than the element, unless specifically stated otherwise.

1A is a perspective view of a sloping solar photovoltaic apparatus according to an embodiment of the present invention. FIG. 1B is a side view of a sloping solar photovoltaic apparatus according to an embodiment of the present invention. 1C is a perspective view of a solar cell module part of an inclined-surface solar power generation apparatus according to an embodiment of the present invention. FIG. 1D is a cross-sectional view of an intermediate supporting portion of an inclined plane solar power generator according to an embodiment of the present invention.

1A to 1D, an inclined-surface solar power generation apparatus according to an embodiment of the present invention includes an upper support unit 100, a lower support unit 200, a sliding wire unit 300, a plurality of solar cell module units 400, Respectively.

The upper support part 100 is provided on the upper side of the slope 10 and supports the sliding wire part 300 so that the sliding wire part 300 is spaced apart from the ground surface of the slope 10 by a predetermined distance . The upper support part 100 typically has a column shape, and the sliding wiper part 300 may be connected to the upper end of the column.

The lower support part 200 is provided at a lower portion of the inclined surface 10 and supports the sliding wire part 300 together with the upper supporting part 100 so that the sliding wire part 300 contacts the upper surface of the inclined surface 10 So as to be spaced apart from each other by a predetermined distance. The lower support part 200 typically has a column shape, and the sliding door 300 can be coupled to the upper end of the column.

The sliding wire portion 300 includes a plurality of wires connected to the upper support portion 100 and the lower support portion 200 and spaced apart from the slope 10, respectively. The two wires of the sliding wire 300 may be connected to the upper end of the column of the upper support 100 and the upper end of the column of the lower support 200, And may be spaced apart from the slope 10 by a predetermined distance.

The plurality of solar cell module units 400 are connected to each other with a plurality of solar cell module units having a flat plate shape capable of sliding along the plurality of wires of the sliding wire unit 300. Each of the plurality of solar cell modules 400 slides along the plurality of wires and can move along the slopes 10 to thereby install or dismount the plurality of solar cell modules 400. [ There is a very simple and convenient advantage.

Referring to FIG. 1C, the individual solar cell module units of the plurality of solar cell module units 400 include a solar cell 410, a body plate 420, a sliding guide 450, an upper connecting unit 470, (480).

The body plate 420 has a flat plate shape having the solar cell 410 on its upper surface. A sliding guide 450 is provided on a lower surface of the body plate 420 to guide the sliding wire 300 to slip along the plurality of wires (typically two wires). More specifically, the sliding guide 450 has a semicircular shape at the lower surface of the body plate 420, and the wire is inserted and moved in the semicircular shape, so that the sliding guide 450 does not come off the wire , And can stably slide and move along the wire.

The upper end of the body plate 420 is provided with an upper connecting part 470 connected to another solar cell module part and the lower connecting part 470 connected to another solar cell module part is provided at a lower end of the opposite side of the body plate 420 480 may be provided. The upper end connecting portion 470 and the lower end connecting portion 480 can be connected to each other from the different solar cell module units. In short, each of the upper end connecting portion 470 and the lower end connecting portion 480 can be connected to each other through a through- Can be connected to each other. In addition, they may be connected to each other through a through hole and a ring shape, and a general technician may have various connecting means without any particular limitation.

In some cases, the sloping solar photovoltaic apparatus according to an embodiment of the present invention may include an intermediate supporting unit 500 for supporting the plurality of wires so as to be spaced apart from the inclined surface, And the inclined surface 10 may be provided on the inclined surface 10 between. The intermediate support part 500 prevents the plurality of wires from touching the sloped surface 10 due to its own load between the upper support part 100 and the lower support part 200 and supports the plurality of wires.

The middle support part 500 includes a column-shaped support base 510 for supporting the slant surface and a support base 520 for supporting the wire of the sliding wire part 300 from the slant surface. The support base 520 has a structure in which the center is flat and both side faces are each bent upward and the wire of the sliding wire unit 300 is placed on the center plane of the support base 520. Due to the bent structure of both sides, The wire of the support base 300 can not escape from the support pedestal 520.

As described above, the sloping solar photovoltaic device according to one embodiment of the present invention may be supported by the upper support part 100 and the lower support part 200 and additionally by the intermediate support part 500, A plurality of solar cell module units 400 connected to each other by the sliding wire unit 300 having the plurality of wires spaced from the inclined plane slides along the sloped surface and is installed or removed while being easily moved A sloping solar photovoltaic device having a very simple structure which can be easily installed or demounted on an inexpensive and unused slope, can be provided.

2 is a side view of a sloping solar photovoltaic device according to another embodiment of the present invention.

Referring to FIG. 2, the inclined plane photovoltaic device according to another embodiment of the present invention is the same as the individual components having the same name of the inclined plane photovoltaic device according to the above-described embodiment of the present invention, Hereinafter, only differences or additions will be described.

The sliding wire portion 1300 may further include the extension wire portion 1350 extending from the wire after the wire is connected to the upper support portion 1100 to the opposite slope 20 of the slope surface 10. The wire of the sliding wire portion 1300 extends to the opposite inclined surface 20 with the wire extending beyond the upper supporting portion 1100 and the weight 1360 is provided at the end of the extended wire portion 1350 do.

Since the load received along the inclined surface 10 with respect to the upper support portion 1100 and the load received along the opposite inclined surface 20 by the weight 1360 are balanced to some extent, The sliding wire portion 1300 can be stably supported from the inclined surface 10 in a stable manner even when the sliding wire portion 1300 is not firmly supported by the weak ground on the upper surface of the sloping surface 10.

FIG. 3A is a side view of a sloping solar photovoltaic device according to another embodiment of the present invention.

FIG. 3B is a cross-sectional view of an extension wire portion buried in a sloping solar photovoltaic device according to another embodiment of the present invention. FIG.

3A and 3B, the inclined plane photovoltaic device according to another embodiment of the present invention is the same as the individual component having the same name of the inclined plane photovoltaic device according to another embodiment of the present invention described above, The description will be omitted, and only differences or added configurations will be described.

The sliding wire portion 2300 may further include the extension wire portion 2350 extending from the wire after the wire is connected to the upper support portion 2100 to the opposite slope 20 of the slope surface 10. The wire of the sliding wire portion 2300 extends through the upper support portion 2100 to the opposite inclined surface 20 and the weight portion 2360 is provided at the end of the extended wire portion 2350 A part of the wire of the extension wire portion 2350 may be buried through a pipe or the like forming a through hole below the ground surface of the upper surface of the slope 10. 3B, the buried wire of the extension wire portion 2350 is connected to the opposite inclined surface 2052 through a connection hole 2352 having a through hole in the embedded concrete 2351, which is concrete embedded under the ground surface. ).

Since the load received along the inclined surface 10 with respect to the upper support portion 2100 and the load received along the opposite inclined surface 20 by the weight 2360 are balanced to some extent, The sliding wire portion 2300 can be stably supported on the inclined surface 10 in a stable manner even when the ground wire 2100 is not firmly supported on the weak ground on the upper surface of the inclined surface 10. A portion of the extended wire portion 2350 is buried in the upper portion of the sloped surface 10 so that the wire exposed at the upper portion of the sloped surface 10 is eliminated to improve the upper space utilization of the sloped surface 10 .

4A is a perspective view illustrating another embodiment of the solar cell module unit in the inclined plane solar power generation apparatus according to the present invention.

FIG. 4B is a perspective view showing still another embodiment of the solar cell module unit of the inclined plane solar power generator according to the present invention.

4A, a solar cell module unit 1400 according to another embodiment of the solar cell module unit of FIG. 1C in the inclined plane solar power generating apparatus according to the present invention includes a solar cell 1410, a body plate 1420, A sliding guide 1450, an upper end connecting portion 1470, and a lower end connecting portion 1480. As shown in FIG.

The body plate 1420 has a flat plate shape having the solar cell 1410 on its upper surface. The swash plate 1430 in the form of a flat plate having a predetermined angle is fixedly coupled to one side of the body plate 1420. The sliding guide 1450 is provided on the lower surfaces of the body plate 1420 and the swash plate 1430 so that the sliding wires 1450 are slid along the plurality of wires (typically two wires) Guide. More specifically, the sliding guide 1450 has a semicircular shape on the lower surfaces of the body plate 1420 and the swash plate 1430, and the wire is inserted and moved in the semicircular shape. Therefore, the sliding guide 1450 Can stably slide and move along the wire without leaving the wire. Accordingly, the solar cell module unit 1400 can arbitrarily adjust the inclination angle of the solar cell module unit 1400 with respect to the inclined plane 10, Can be found.

The upper end of the body plate 1420 is provided with an upper connecting portion 1470 connected to another solar cell module portion and the lower connecting portion 1480 connected to another solar cell module portion is provided at the lower end of the swash plate 1430, May be provided. The upper end connecting portion 1470 and the lower end connecting portion 1480 may be connected to each other from the other solar cell module units. In short, the upper end connecting portion 1470 and the lower end connecting portion 1480 may include means that are connected to each other through one through- , And the ordinary technician can have various connecting means without any particular limitation. A reflective mirror may be provided on the outer surface of the swash plate 1430, and the solar cell module may be provided with light reflected by the reflection mirror to help improve energy efficiency.

Referring to FIG. 4B, a solar cell module unit 2400 according to another embodiment of the solar cell module unit of FIG. 1C in the inclined plane solar power generation apparatus according to the present invention includes a solar cell 2410, a body plate 2420, A rotation guide bar 2440, a sliding guide 2450, an upper end connection 2470, and a lower end connection 2480.

The body plate 2420 has a flat plate shape having the solar cell 2410 on its upper surface. The swash plate 2430 in the form of a flat plate is rotatably coupled to one side of the body plate 2420 by a hinge structure 2435. The rotation fixing bar 2440 fixes the rotation of the body plate 2420 and the swash plate 2430. The rotation fixing bar 2440 may be a rod for fixing the body plate 2420 and the side surface of the swash plate 2430 to each other, As shown in FIG. The sliding guide 2450 is provided on the lower surface of the body plate 2420 and the swash plate 2430 so that the sliding guide 2450 is slid along the plurality of wires (typically two wires) Guide. More specifically, the sliding guide 2450 has a semicircular shape on the lower surfaces of the body plate 2420 and the swash plate 2430, and the wire is inserted and moved in the semicircular shape. Therefore, the sliding guide 2450 Can stably slide and move along the wire without leaving the wire. The inclination angle of the solar cell module part 2400 can be arbitrarily adjusted with respect to the inclined plane 10 so that the solar cell module part 2400 can be provided with the solar power generation efficiency regardless of the angle of the inclined plane 10. [ Can be found.

The upper end of the body plate 2420 is provided with an upper connecting portion 2470 connected to another solar cell module portion and the lower connecting portion 2480 connected to another solar cell module portion is provided at the lower end of the swash plate 2430, May be provided. The upper end connecting portion 2470 and the lower end connecting portion 2480 may be connected to each other from the different solar cell module units. In short, the upper end connecting portion 2470 and the lower end connecting portion 2480 may include means for connecting each other through one through- , And the ordinary technician can have various connecting means without any particular limitation. Meanwhile, the outer surface of the swash plate 2430 may be provided with a reflection mirror, and may be directed to another solar cell module portion provided with light reflected by the reflection mirror to help enhance energy efficiency.

As described above, the sloping solar photovoltaic device according to the present invention has a simple structure at low cost by using a wire on an inclined surface, and a plurality of connected solar cell modules slidable along the wire can be easily installed or removed.

In addition, even when the upper surface of the slope is weak, the wire is extended to the opposite surface of the slope, and the weight is provided at the end of the slope so that the wire itself can balance the load by itself, A photovoltaic device may be provided. On the other hand, since a part of the extending wire is buried in the upper part of the inclined surface, space utilization of the upper part of the inclined surface can be increased.

In addition, since the solar cell module can have a specific angle based on the inclined plane, the inclination angle of the solar cell module can be arbitrarily adjusted, and the inclination angle that can optimize the solar power generation efficiency can be obtained regardless of the angle of the inclined plane . On the other hand, a reflection mirror may be further provided to change the incidence direction of sunlight to further improve solar power generation efficiency.

10: slope 20: opposite slope
100: upper support part 200: lower support part 300: sliding wire part
400, 1400, 2400: Solar cell module part

Claims (9)

An upper support provided on an upper portion of the inclined surface;
A lower support portion provided below the inclined surface;
A sliding wire portion connected to the upper support portion and the lower support portion and having a plurality of wires supported so as to be spaced apart from the inclined surface; And
And a plurality of solar cell modules connected to each other and slidable along the plurality of wires,
The solar cell module unit includes:
A plate-shaped body plate having a solar cell on an upper surface thereof;
A slope plate fixedly coupled to one side of the body plate at a predetermined angle;
A sliding guide provided on the bottom surface of the body plate and the swash plate, respectively, for guiding sliding along the plurality of wires;
An upper connection part provided at an upper end of the body plate and connected to another solar cell module part; And
And a lower connection part provided at a lower end of the swash plate and connected to another solar cell module part,
A reflection mirror is attached to the swash plate,
The angle of inclination of the solar cell is adjusted by the predetermined angle formed by the swash plate and the body plate, and light reflected by the reflection mirror is projected to the another solar cell module portion
Inclined plane photovoltaic device. delete The method according to claim 1,
Further comprising an intermediate supporting portion provided on an inclined surface between the upper supporting portion and the lower supporting portion, for supporting the plurality of wires so as to be spaced apart from the inclined surface. The method according to claim 1,
Wherein the sliding wire portion further includes an extension wire portion extending from the wire through the upper support portion to an opposite inclined surface of the inclined surface, and the extension wire portion has a weight at an end thereof. The method of claim 4, wherein
Wherein a portion of the wire extending from the extending wire portion to the opposite inclined surface of the inclined surface through the upper supporting portion is buried. delete delete An upper support provided on an upper portion of the inclined surface;
A lower support portion provided below the inclined surface;
A sliding wire portion connected to the upper support portion and the lower support portion and having a plurality of wires supported so as to be spaced apart from the inclined surface; And
And a plurality of solar cell modules connected to each other and slidable along the plurality of wires,
The solar cell module unit includes:
A plate-shaped body plate having a solar cell on an upper surface thereof;
A swash plate rotatably coupled to one side of the body plate;
A rotation fixing bar for fixing a rotation of the body plate and the swash plate;
A sliding guide provided on the bottom surface of the body plate and the swash plate, respectively, for guiding sliding along the plurality of wires;
An upper connection part provided at an upper end of the body plate and connected to another solar cell module part; And
And a lower connection part provided at a lower end of the swash plate and connected to another solar cell module part,
A reflection mirror is attached to the swash plate,
Wherein a tilt angle of the solar cell is adjusted by a predetermined angle formed between the swash plate and the body plate, and light reflected by the reflection mirror is projected to the another solar cell module portion
Inclined plane photovoltaic device. delete

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