KR101725038B1 - Structure using Multi-Wire for installing Solar Module - Google Patents

Abstract

The present invention relates to a photovoltaic module installation structure using a plurality of wires. The photovoltaic module installation structure using a plurality of wires comprises: a rod rotary unit including at least four first to fourth rotary units positioned at vertexes to form a virtual rectangular plane, the first and second rotary units and third and fourth rotary units forming short sides respectively, and the first and third rotary units and the second and fourth rotary units disposed to form long sides respectively, and further including at least one additional rotary unit formed at a random position; a support structure supporting so that the first to fourth rotary units and an additional rotary unit of the rod rotary unit are individually installed to be separated from the ground; and a rod wire including a closed curved first rod wire continuously wound around at least the first and third rotary units of the rod rotary unit and a closed curved second rod wire continuously wound around at least second and fourth rotary units and an additional rotary unit of the rod rotary unit, and provided to move a first holding unit of the first rod wire disposed between the first and third rotary units and a second holding unit of the second rod wire disposed between the second and fourth rotary units. Therefore, the photovoltaic module installation structure using wires can be installed in a three-dimensional manner without a spatial constraint by providing a volplaning construction system when the photovoltaic module is installed.

Description

[Background Art] Solar module installation structure using a plurality of wires {Structure using Multi-Wire for installing Solar Module}

The present invention relates to a solar module installation structure using a plurality of wires, and more particularly to a solar module installation structure using a plurality of wires, and more particularly, a rod rotating body including first to fourth rotors is supported by a support structure A first rod wire of a closed curve continuously wound on at least first, third and additional rotors of the rod rotating body, and a second rod wire of a closed curve continuously wound on at least the second, The first load portion of the load wire being held between the first and third rotors and the second load portion of the load wire being interposed between the second and fourth rotors are moved in the same direction And more particularly to a solar module installation structure using a plurality of wires.

Solar power system is the most popular electric energy production facility in the renewable energy field, and solar modules including a number of solar cells are installed in series or parallel to convert sunlight into electric energy .

However, if there is a lack of available idle space, it is necessary to install it in a ground space that is being used for other purposes. Therefore, there is a space restriction, And the maintenance cost is increased.

In particular, in order to secure the structural safety, a massive weight structure is used in the processing type or public type photovoltaic power generation system installed in the parking lot, sewage treatment plant, etc., which is installed at present, , The installation labor cost and the material cost are 1.5 ~ 2.0 times more, and there is a problem that the risk of work of the field installation technician is high.

As a conventional photovoltaic system using a wire, there is a Korean Patent No. 10-1004108 entitled " Photovoltaic panel fixing device using a steel wire " (Registered on Dec. 20, 2010, hereinafter referred to as prior art document 1). In the prior art document 1, there was an effort to secure a ground space by supporting the array using wires, but the solar panels were merely mounted on the wires.

In addition, Japanese Unexamined Patent Publication No. 2013-247237 discloses a photovoltaic panel supporting apparatus (disclosed in Mar. 12, 2012, hereinafter referred to as "Prior Art Document 2") and Japanese Unexamined Patent Application Publication No. 2003-318430 And its installation method '(published on November 7, 2003, hereinafter referred to as' prior art document 3'). Although the prior art documents 2 and 3 disclose a structure for supporting a solar panel by using a plurality of rollers and wires, they are used for changing the angle of the solar panel only by twisting or folding And there was no technical idea of actively moving a solar panel using a wire.

Therefore, when the solar module is installed using the conventional method as in the above-described prior art documents 1 to 3, it is difficult to install the solar module at a desired precise position because the solar module is connected to the wire at a desired position in the air However, there was a problem with the safety of the operator, and there was a problem that it was difficult to install because of a complicated structure in order to prevent the wire from sagging.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the problems described above, and it is an object of the present invention to provide a solar module in which a plurality of wires are wound around a plurality of rotors, (Volplaning Construction System) for installation.

In addition, it is possible to provide a three-dimensional installation by machining a plurality of wires, and it is possible to work only in a specific place without movement of a worker, thereby securing safety, facilitating work, shortening air, It is an object of the present invention to provide a structure for mounting a solar module using a wire that can easily and quickly perform maintenance, and can relieve deflection by applying tension to the wire.

In order to achieve the above object, the first rotating body 100a, the second rotating body 100b, the third rotating body 100c, and the fourth rotating body 100c located at the vertex to form a virtual rectangular plane of the present invention, The first and third rotating bodies 100a and 100b and the third and fourth rotating bodies 100c and 100d form short sides respectively and the first and third rotating bodies 100a and 100b 100b and 100c and the second and fourth rotors 100b and 100d are formed so as to form long sides, respectively, and at least one additional rotating body 100e is formed at an arbitrary position; A supporting structure 200 for supporting the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the load rotating body 100 so as to be installed at positions separated from the ground; And a first load wire (300a) of a closed curve continuously wound on at least a first rotating body (100a), a third rotating body (100c) and an additional rotating body (100e) among the rod rotating bodies (100) And a second rod wire 300b of a closed curve continuously wound on at least the second rotating body 100b, the fourth rotating body 100d and the additional rotating body 100e out of the whole body 100, The first load wire 300a which is placed between the three rotors 100a and 100c is provided with at least one first mounting portion 310 and the first and second load wires 300a and 100b are mounted between the second and fourth rotors 100b and 100c. The second load wire 300b is provided with at least one second mounting portion 320 and the at least one pair of the first and second mounting portions 310 and 320 are connected to a load wire (300).

The first rotating body 100a through the fourth rotating body 100d and the additional rotating body 100e of the load rotating body 100 are rotated such that at least one rotating disk 120 rotates on the rotating shaft 110 And the additional rotating body 100e can be coupled to the plurality of rotating disks 120. [

The support structure 210 includes a support body 210 and a base structure 220 below the support body 210. The support body 210 includes a plate 212 coupled to the post 211, The rod rotating body 100 may be provided on the upper portion of the rotor 100.

The support body 210 has a plate 212 rotatably coupled to the post 211 and a wire loader portion 213 provided at an upper portion of the plate 212. The wire loader portion 213 includes At least a pair of rollers 213b may be spaced apart from each other by a predetermined distance between the pair of support bars 213a so that the rod wire 300 can be guided.

The support 210 may include a first plate 212-1 and a second plate 212-2 to which the plate 212 is coupled to the post 211 and the plate 212 is slid with respect to each other The first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 are respectively attached to the first plate 212-1 and the second plate 212-2, So that the distance can be adjusted.

The base structure 220 includes a post 211 coupled to the base plate 221 and a brazing plate 222 coupled to support the post 211. The bucket unit 222 is coupled to the bucket unit 222, (223) may be integrally formed.

A plurality of wire brackets 400 may be coupled to the first and second mounting portions 310 and 320 of the load wire 300 so that the wire brackets 400 are opposed to each other. have.

The wire bracket 400 is coupled to a pair of first bracket bars 400a and a second bracket bar 400b that are hinged to each other. The first and second bracket bars 400a and 400b The wire seating grooves 410a and 410b are formed on the inner side and the rod wire 300 is coupled to the wire seating hole 410 formed by the wire seating grooves 410a and 410b.

In addition, a wire guide groove 410a (410b) formed in the first and second bracket bars 400a and 400b of the wire bracket 400 is formed with a linear guide surface, can do.

The wire bracket 400 may include a pair of first bracket bars 400a and a second bracket bar 400b which are hinged to the mutually facing surfaces of the bracket body 400c, The first and second bracket bars 400a and 400b have wire seating grooves 410a and 410b formed on the inner surface thereof and wire seating grooves 410c are formed on the opposite surfaces of the bracket body 400c, The wire 300 can be coupled to the wire insertion hole 410 formed by the wire receiving grooves 410a and 410b and the wire receiving groove 410c.

The first mounting part 310 of the rod wire 300 includes a pair of mounting wires 310-1 provided at the top and bottom and a pair of mounting screws 320 provided at the top and bottom of the second mounting part 320 The mounting wires 310-1 and 320-1 are coupled to penetrate the wire bracket 400 and may be provided to intersect between adjacent wire brackets 400 have.

The upper wires 310-2 and 320-2 are provided above the mounting wires 310-1 and 320-1 of the first and second mounting portions 310 and 320 of the rod wire 300 Or lower wires 310-3 and 320-3 may be provided below.

The first mounting portion 310 of the load wire 300 includes a pair of first outer mounting portions 311 and a first inner mounting portion 312 that are different in moving direction from each other, The unit 320 also includes a pair of second outer mounting portions 321 and a first inner mounting portion 322 which are movable in different directions so that the solar modules SM can be installed at different positions at the same time have.

The rod rotating body 100 is provided with two additional rotating bodies 100e and one additional rotating body 100e is located between the first and second rotating bodies 100a and 100b, The rotating body 100e is located between the third and fourth rotating bodies 100c and 100d and is disposed between the first and third rotating bodies 100a and 100c and the two additional rotating bodies 100e, A second rod wire 300b of a closed curve wound on both the first rod wire 300a and the second and fourth rotors 100b and 100d and the two additional rotators 100e, The first and second mounting portions 310 and 320 of the two load wires 300a and 300b are provided with at least one first mounting portion 310 and at least one second mounting portion 320, The first and second mounting portions 310 and 320 may be provided to move in the same direction.

In the solar module installation structure using the plurality of wires of the present invention by the above-described solving means, since the solar module is installed by using the method in which the rod wire of the closed curve is continuously wound on the rod rotating body, It is possible to form a Volplaning Construction System which is installed in both directions or unidirectionally.

Thus, the first and second mounting portions of the rod wire can be moved in the same direction, so that the solar module can be installed in three dimensions without being restricted by the space.

In addition, even if the operator does not move, it is possible to perform the operation of installing the solar module only at a specific place, thereby securing safety.

In addition, since the solar module can be installed easily by simply moving the first and second rod wires, the air can be shortened because the operation can be performed easily, and the advantages .

On the other hand, since the plate having the rotating body is rotatably coupled to the post or the first plate and the second plate constituting the plate are mutually slid so that the distance between the rotating bodies is adjusted, tension is applied to the wire, Can be mitigated.

Furthermore, a plurality of load wires are provided up and down to ensure the structural safety of the installation structure. Further, the plurality of load wires arranged in the upper and lower rows can be arranged in a cross shape so as to have a truss shape, thereby further enhancing safety from self weight and wind load.

In addition, a three-dimensional structure having a curvature can be formed based on a plurality of rod wires arranged in the vertical direction.

On the other hand, even when a wire loader is provided so that the rod wires are guided between the pair of rollers and a plurality of rod wires are provided up and down, the rod wires can be stably moved without detaching from the rotor.

The first and second bracket bars or the bracket formed of the bracket body are coupled to each other to stably provide the solar module, and when the plurality of load wires are provided up and down, they are moved at the same speed.

Particularly, the first and second mount portions of the rod wire have a pair of inner and outer teeth portions which are moved in mutually different directions, and the solar module can be installed at different positions at the same time.

1 is a plan view showing an installation structure according to an embodiment of the present invention;
2 is a side view of an installation structure according to an embodiment of the present invention;
FIGS. 3A and 3B are conceptual diagrams showing an installation method according to an embodiment of the present invention; FIGS.
4A and 4B are conceptual diagrams showing an installation method according to an embodiment in which the first and second load wires of the present invention are wound around an additional rotating body and two rotating bodies.
FIGS. 5A to 5B and 6A to 6B are conceptual diagrams showing an installation method according to an embodiment in which the first and second rod wires of the present invention are wound on an additional rotating body and three or four rotating bodies.
7A to 7C are conceptual diagrams showing an installation method with two additional rotors of the present invention.
8A and 8B are elevational views showing a wire loader section according to various embodiments of the present invention.
Figures 9a-9c are cross-sectional views of a support structure in accordance with an embodiment of the present invention.
10A-10C are elevational views illustrating a support in accordance with various embodiments of the present invention.
11A-11B are elevation and cross-sectional views of a wire bracket according to various embodiments of the present invention.
12A-12B are elevational views illustrating a mounting wire and upper and lower wires according to various embodiments of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, a solar module installation structure using a plurality of wires according to the present invention includes a rod rotating body 100 including a plurality of rotating bodies, a supporting structure 200 supporting the rod rotating body 100, And a rod wire 300 including a first rod wire 300a and a second rod wire 300b which are continuously wound and moved to the rod rotating body 100.

Specifically, the rod rotating body 100 includes at least four first rotating bodies 100a, a second rotating body 100b, a third rotating body 100c, and a fourth rotating body 100c positioned at apexes to form a virtual rectangular plane. And an additional rotating body 100e including the rotating body 100d and formed at an arbitrary position.

The first and second rotating bodies 100a and 100b and the third and fourth rotating bodies 100c and 100d form the short sides of the first and third rotating bodies 100a and 100b, (100c) and the second and fourth rotors (100b) and (100d) are arranged so as to form long sides, respectively.

2, the support structure 200 includes a first rotating body 100a, a fourth rotating body 100d and an additional rotating body 100e of the rod rotating body 100, As shown in Fig. The support structure 200 may be manufactured in various shapes and may support the first rotating body 100a through the fourth rotating body 100d and the additional rotating body 100e individually The first and second rotating bodies 100a and 100b and the additional rotating body 100e are supported by one supporting structure and the third and fourth rotating bodies 100c and 100d The other supporting structure may be supported and may be formed as a single supporting structure to support the first rotating body 100a through the fourth rotating body 100d and the additional rotating body 100e as a whole.

The first rod wire 300a and the second rod wire 300b of the rod wire 300 are formed as a closed curve. In this case, the closed curve means a wire formed continuously so as to have no end portion, and it is arranged so as to intersect when viewing orthogonal projection on a hypothetical plane formed by the rod wire 300 to form a plurality of intersections CP Shape.

The rod wire 300 is connected to the first load wire 300a of the closed curve continuously wound on at least the first rotating body 100a, the third rotating body 100c and the additional rotating body 100e of the load rotating body 100 And a second rod wire 300b of a closed curve continuously wound on at least the second rotating body 100b, the fourth rotating body 100d and the additional rotating body 100e out of the rod rotating body 100 .

At this time, between the first mounting portion 310 of the first rod wire 300a and the second and fourth rotors 100b and 100d which are placed between the first and third rotors 100a and 100c, The second mounting portion 320 of the second load wire 300b is moved in the same direction.

The 'winding' means that the rod wire 300 is coupled to rotate the first rotating body 100a through the fourth rotating body 100d and the additional rotating body 100e, If the rod wire 300 is able to rotate the first to fourth rotors 100a, 100b, 100c, and 100d and the additional rotator 100e by the frictional force, .

3A and 3B, the first rod wire 300a of the rod wire 300 is rotated from the first rotating body 100a through the third rotating body 100c, The second rod wire 300b of the rod wire 300 is returned from the second rotating body 100b to the fourth rotating body 100d via the first rotating body 100e and then returned to the first rotating body 100a, Through the additional rotating body 100e, and then to the rotating bodies to be returned to the first second rotating body 100b.

In this case, the first and second rod wires 300a and 300b are each formed with one intersection CP, and the first and second rod wires 300a and 300b are connected to the first and second rotors 100a and 100c, The second mounting portion 320 of the second rod wire 300b which is placed between the first mounting portion 310 of the first rod 300a and the second and fourth rotors 100b and 100d moves in the same direction .

Therefore, the operator can perform the operation of joining the solar module SM to the load wire 300 only at one end of the installation structure in the lengthwise direction, and it is possible to install three-dimensionally without being restricted by the space, It is possible to install a solar module (SM) only at a specific place, thereby ensuring safety.

In addition, since the solar module SM can be installed simply by moving the load wire 300, the operation can be performed easily, and the air is shortened. In the maintenance of the solar module SM, .

3A and 3B, the first mounting portion 310 of the load wire 300 includes a pair of first outer mounting portions 311 and a second inner mounting portion 311, And the second mounting portion 320 may include a pair of second outer mounting portions 321 and a first inner mounting portion 322 that are different in moving direction from each other.

In the above embodiment, the first outer mounting portion 311 of the first mounting portion 310 and the second inner mounting portion 322 of the second mounting portion 320 have the same moving direction, The first and second outer mounting portions 312 and 321 of the first mounting portion 310 and the second mounting portion 320 of the first mounting portion 320 and the second mounting portion 320 of the second mounting portion 320 are moved in the same direction, (SM) can be installed, so that the working efficiency is increased.

4A, the first outer mounting portion 311 of the first mounting portion 310 and the second outer mounting portion 321 of the second mounting portion 320 are moved in the same direction The first inner mounting portion 312 of the first mounting portion 310 and the second inner mounting portion 322 of the second mounting portion 320 may be formed to have the same moving direction.

4B shows a state in which the load wire 300 is connected to at least one of the first rotating body 100a, the third rotating body 100c and the additional rotating body 100e of the rod rotating body 100, The second load wire 300b of the closed curve continuously wound on at least the second rotating body 100b, the fourth rotating body 100d and the additional rotating body 100e among the rod wire 300a and the rod rotating body 100 3A, 3B and 4A, the winding order is different.

5A and 5B, the load wire 300 is connected to the first rotating body 100a, the second rotating body 100b, the third rotating body 100c, The first load wire 300a of the closed curve continuously wound on the rotating body 100e and the first rod body 100a of the rod rotating body 100, the second rotating body 100b, the fourth rotating body 100d And a second rod wire 300b of a closed curve continuously wound on the additional rotor 100e. As shown in FIGS. 6A and 6B, the rod wire 300 may be formed of a rod- The first load wire 300a of the closed curve continuously wound on the first to third rotors 100a to 100d and the additional rotor 100e and the first load wire 300a of the rod rotating body 100, And a second load wire 300b of a closed curve continuously wound on the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e.

As shown in FIGS. 7A and 7B, it is also possible to design a plurality of additional rotors 100e.

Particularly, FIG. 7C shows a structure in which two additional rotating bodies 100e are provided, one additional rotating body 100e is located between the first and second rotating bodies 100a and 100b, and the other rotating body 100e Is disposed between the third and fourth rotors 100c and 100d and is connected to the first load wire 100c of the closed curve wound on both the first and third rotors 100a and 100c and the two additional rotators 100e, And a second rod wire 300b of a closed curve wound on both the first and second rotating bodies 300a, 100b and 100d and the two additional rotating bodies 100e.

At this time, the first and second mounting portions 310 and 320 of the first rod wire 300a are formed to move in the same direction.

8A to 8B, the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 are respectively connected to the rotating shaft 110 One rotating disk 120 is coupled to rotate, and the additional rotating body 100e may be coupled with a plurality of rotating disks 120. [

The first rotating body 100a to the fourth rotating body 100d are also vertically mounted to form a plurality of mounting wires 310a and 320a, upper wires 310b and 320b and lower wires 310c and 320c The plurality of rotating disks 120 may be independently rotated on one rotating shaft 110. In this case,

8A to 8B, a wire loader portion 213 may be provided on the plate 212. [0040] At least a pair of rollers 213b are spaced apart from each other by a predetermined distance between the pair of support bars 213a so that the rod loader part 213 can be guided.

At this time, if a plurality of the rod wires 300 are formed in the upper and lower portions, a plurality of the rollers 213b may also be provided in the vertical direction.

9A to 9C, the support structure 200 includes a support 210 and a base structure 220 below the support 210. The support 210 supports the plate 212 in the post 211, And the plate 212 may be rotatably coupled to the post 211 so that the rod 212 is coupled to the rod 212. Thus, Tension can be applied to the elastic member 300 to reduce the sagging phenomenon.

The base structure 220 has a post 211 coupled to the base plate 221 and a brazing plate 222 coupled to support the post 211, (223) may be integrally formed. As a result, the structural stability can be secured.

10A to 10C, the support 210 includes a first plate 212-1 to which the plate 212 is coupled to the post 211, a first plate 212-1 to which the plate 212 is slid with respect to the first plate 212-1, 2 plate 212-2 and the first rotating body 100a to the fourth rotating body 100b of the rod rotating body 100 are connected to the first plate 212-1 and the second plate 212-2, At least one of the additional rotating body 100d and the additional rotating body 100e may be provided to adjust the distance.

Therefore, the distance between the rotating bodies of the rod rotating body 100 can be flexibly adjusted, so that tension can be applied to the rod wires 300 to reduce the sagging phenomenon.

At least one pair of wire brackets 400 may be coupled to the first and second mounting portions 310 and 320 of the rod wire 300 in the longitudinal direction so as to face each other, 400 to the top of the solar module SM.

11A, the wire bracket 400 includes a pair of first bracket bars 400a and a second bracket bar 400b which are hinged to each other, and the first and second bracket bars 400a, 400a and 400b are formed with wire seating grooves 410a and 410b on the inner side and the rod wire 300 is coupled to the wire seating hole 410 formed by the wire seating grooves 410a and 410b. .

A plurality of wire seating grooves 410a and 401b may be formed in each of the first and second bracket bars 400a and 400b and a wire guide groove 410b may be formed at one side of the wire seating grooves 410a and 410b. So that the wire can be easily guided in the process of placing the wire in the wire seating grooves 410a and 410b.

In another embodiment, the wire bracket 400 includes a pair of first bracket bars 400a and a pair of second bracket bars 400b, which are hinged to the mutually facing surfaces of the bracket body 400c, The first and second bracket bars 400a and 400b are formed with wire seating grooves 410a and 410b on the inner side of the first and second bracket bars 400a and 400b. The groove 410c may be formed and the rod wire 300 may be formed to be coupled to the wire insertion hole 410 formed by the wire seating grooves 410a and 410b and the wire seating groove 410c.

When the wire bracket 400 is coupled to the rod wire 300 to stably provide the solar module SM and when a plurality of mounting wires 310a and 320a are vertically disposed, .

12A, the first mounting part 310 of the load wire 300 includes a pair of mounting wires 310a provided up and down, and the second mounting part 320 also includes a pair of mounting wires And may include a pair of mounting wires 320a.

The fixing wires 310a and 320a are coupled to penetrate the wire bracket 400 and intersect the adjacent wire brackets 400 to ensure the structural safety of the installation structure and to secure safety from the weight or wind load Can be further increased. Further, a three-dimensional structure having a curvature can be formed based on the mounting wires 310a and 320a arranged up and down.

On the other hand, as shown in FIG. 12B, the upper wires 310b and 320b are provided above the fixing wires 310a and 320a of the first and second mounting portions 310 and 320 of the rod wire 300 And lower wires 310c and 320c may be provided at the lower portion.

The solar module installation structure S using a plurality of wires according to the present invention described above is not limited to the above-described embodiments, and may be constructed without departing from the gist of the present invention claimed in the following claims. It should be understood that the present invention is not limited to the scope of the claims as far as it can be practiced by various persons skilled in the art.

SM: Photovoltaic module 100: Rod rotating body
100a to 100d: first to fourth rotors 100e:
110: rotating shaft 120: rotating disk
200: support structure 210: support
211: post 212: plate
212-1: first plate 212-2: second plate
213: wire loader section 213a: support bar
213b: roller 220: base structure
221: base plate 222: brazing plate
223: Bucket part 300: Load wire
300a: first load wire 300b: second load wire
310: first mounting portion 311, 312: first outside, inner mounting portion
320: second mounting portion 321, 322: second outside, inner mounting portion
310a, 320a: upper and lower mounting wires 310b, 320b: upper wire
310c and 320c:
400: wire bracket 400a: first bracket bar
400b: second bracket bar 400c: bracket body
410a, 410b, 410c: wire seating groove 410:

Claims (14)

The first rotating body 100a, the second rotating body 100b, the third rotating body 100c, and the fourth rotating body 100d positioned at apexes so as to form a virtual rectangular plane, The two rotating bodies 100a and 100b and the third and fourth rotating bodies 100c and 100d form short sides and the first and third rotating bodies 100a and 100c and the second and fourth rotating bodies 100b and 100c ) 100d are arranged so as to form long sides, respectively, and at least one additional rotating body 100e is formed at an arbitrary position;
A supporting structure 200 for supporting the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the load rotating body 100 so as to be installed at positions separated from the ground; And
A first load wire 300a of a closed curve continuously wound on at least the first rotating body 100a, the third rotating body 100c and the additional rotating body 100e of the rod rotating body 100, A second rod wire 300b of a closed curve continuously wound on at least the second rotating body 100b, the fourth rotating body 100d and the additional rotating body 100e among the rotating bodies 100,
The first load wire 300a interposed between the first and third rotors 100a and 100c is provided with at least one first stationary part 310 and the second and fourth rotors 100b and 100d The second load wire 300b is provided with at least one second mounting portion 320 so that the first and second mounting portions 310 and 320 are moved in the same direction And a load wire (300) provided on the solar cell module.
The method according to claim 1,
The first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the load rotating body 100 are coupled to the rotating shaft 110 such that at least one rotating disk 120 rotates , And the additional rotating body (100e) is coupled to the plurality of rotating disks (120).
The method according to claim 1,
The supporting structure 200 includes a supporting body 210 and a base structure 220 disposed below the supporting body 210. The supporting body 210 includes a plate 212 coupled to the post 211, And a rod rotating body (100) is provided on the inner surface of the solar cell module.
The method of claim 3,
The support 210 includes a plate 212 rotatably coupled to the post 211 and a wire loader 213 disposed at an upper portion of the plate 212. The wire loader 213 includes a pair of Wherein at least a pair of rollers (213b) are spaced apart from each other by a predetermined distance between the support bars (213a) of the support rods (213a).
The method of claim 3,
The support 210 includes a first plate 212-1 and a second plate 212-2 to which the plate 212 is coupled to the post 211 and the plate 212 is slid with respect to each other, At least one of the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 is attached to the first plate 212-1 and the second plate 212-2, And the distance is adjusted by one of the plurality of wires.
The method of claim 3,
The base structure 220 has a post 211 coupled to the base plate 221 and a braking plate 222 coupled to support the post 211. The bucket 223 Wherein the plurality of wires are integrally formed.
The method according to claim 1,
A plurality of wire brackets 400 are formed in the longitudinal direction so as to face the wire brackets 400 formed in the first mounting portion 310 and the second mounting portion 320 of the rod wire 300 A solar module installation structure using a plurality of wires.
8. The method of claim 7,
The wire bracket 400 has a pair of first bracket bars 400a and a second bracket bar 400b which are hinged to each other. The first and second bracket bars 400a, Wherein the wire receiving grooves 410a and 410b are formed in the wire receiving grooves 410a and 410b and the rod wire 300 is coupled to the wire receiving hole 410 formed by the wire seating grooves 410a and 410b. Solar module installation structure using.
9. The method of claim 8,
A guide surface is formed at one side of the wire seating grooves 410a and 410b formed in the first and second bracket bars 400a and 400b of the wire bracket 400 to guide the rod wire 300 A solar module installation structure using a plurality of wires.
8. The method of claim 7,
The wire bracket 400 is formed by coupling a pair of first bracket bars 400a and a second bracket bar 400b hinged to mutually facing surfaces of the bracket body 400c, 2 bracket bars 400a and 400b are formed with wire seating grooves 410a and 410b on the inner side and wire seating grooves 410c are formed on the opposite surfaces of the bracket body 400c, ) Is coupled to a wire running hole (410) formed by the wire receiving grooves (410a) (410b) and the wire receiving grooves (410c).
8. The method of claim 7,
The first mounting portion 310 of the load wire 300 includes a pair of mounting wires 310-1 provided up and down and the second mounting portion 320 includes a pair of mounting wires The mounting brackets 310-1 and 320-1 are coupled to penetrate through the wire brackets 400 and intersect each other between adjacent wire brackets 400 A solar module installation structure using a plurality of wires.
12. The method of claim 11,
The upper wires 310-2 and 320-2 are provided above the mounting wires 310-1 and 320-1 of the first and second mounting portions 310 and 320 of the rod wire 300, And the lower wires (310-3) and (320-3) are provided on the upper surface of the solar cell module.
The method according to claim 1,
The first mounting portion 310 of the load wire 300 includes a pair of first outside mounting portions 311 and a first inside mounting portion 312 that are different in moving direction from each other, 320 may also include a pair of second outer mounting portions 321 and a second inner mounting portion 322 which are moved in different directions from each other so that the solar module SM can be installed at different positions at the same time A solar module installation structure using a plurality of wires.
The method according to claim 1,
The load rotating body 100 is provided with two additional rotating bodies 100e and one additional rotating body 100e is located between the first and second rotating bodies 100a and 100b, The whole body 100e is located between the third and fourth rotors 100c and 100d and is formed of a closed curve wound around both the first and third rotors 100a and 100c and the two additional rotors 100e. A second rod wire 300b of a closed curve wound around both the first rod wire 300a and the second and fourth rotors 100b and 100d and the two additional rotors 100e, The first and second mounting portions 310 and 320 of the load wires 300a and 300b are provided with at least one first mounting portion 310 and at least one second mounting portion 320, Wherein the pair of first and second mounts (310, 320) are arranged to move in the same direction with respect to each other.

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