WO2017175982A1 - Structure for installing solar module using multiple wires - Google Patents

Abstract

The present invention relates to a structure for installing a solar module using a plurality of wires. To this end, the present invention may include: a rod rotating body including a first rotating body, a second rotating body, a third rotating body, and a fourth rotating body, which are disposed at vertices to form a virtual rectangular plane, the rotating bodies arranged such that the first and second rotating bodies form a short side, and the third and fourth rotating bodies form a short side, the first and third rotating bodies form a long side, and the second and fourth rotating bodies form a long side, and at least one additional rotating body is formed at an arbitrary position; a support structure supporting the first to fourth rotating bodies and the additional rotating body of the rod rotating body so that the first to fourth rotating bodies and the additional rotating body of the rod rotating body are each installed at a position spaced apart from the ground; and a rod wire including a first rod wire which is a closed curve and which is consecutively wound on at least the first rotating body, the third rotating body, and the additional rotating body of the rod rotating body, and a second rod wire which is a closed curve and which is consecutively wound on at least the second rotating body, the fourth rotating body, and the additional rotating body of the rod rotating body, wherein a first holding part of the first rod wire, which is held between the first and third rotating bodies, and a second holding part of the second rod wire, which is held between the second and forth rotating bodies, are provided so as to move in the same direction. Accordingly, when the solar module is installed, a volplaning construction system may be provided to enable a three-dimensional installation without being restricted in terms of space.

Description

Solar module installation structure using a plurality of wires

The present invention relates to a photovoltaic module mounting structure using a plurality of wires, and more particularly, a rod rotating body including first to fourth rotating bodies is supported to be installed at a position spaced apart from the ground by a supporting structure, respectively. A first rod wire of a closed curve continuously wound on at least the first, third and additional rotating bodies of the rod rotating body and a closed curve continuously wound on the at least second, fourth and additional rotating bodies of the rod rotating body. 2 the rod wire is wound, but the first mounting portion of the rod wire mounted between the first and third rotating bodies and the second mounting portion of the rod wire mounted between the second and fourth rotating bodies are provided to move in the same direction. It relates to a solar module installation structure using a plurality of wires.

Photovoltaic system is the most popular electric energy production equipment in the field of renewable energy and converts solar light into electrical energy by installing solar modules including solar cells in series or parallel. .

Sufficient installation space is required to install such solar modules to produce electric energy of the desired capacity. However, when there is not enough idle space available, it must be installed in the ground space used for other purposes. And maintenance costs have risen.

In particular, the processed or aerial photovoltaic power generation system installed at the site of a parking lot, sewage treatment plant, etc., which is currently installed, is using a massive weight structure to secure structural safety, and thus, the working time is higher than the ground installation of flat land In addition, the installation labor cost and the material cost are 1.5 ~ 2.0 times higher, and there is a high risk of the field installation technician.

Conventional photovoltaic systems using wires include Korea Patent Registration No. 10-1004108, 'Photovoltaic panel fixing device using steel wire' (December 20, 2010 registration, hereinafter referred to as 'prior art document 1'). In the prior art document 1, there was an effort to secure the ground space by supporting the array using wires, but only the solar panels were mounted on the wires.

In addition, Japanese Patent Application Laid-Open No. 2013-247237, 'Photovoltaic Panel Supporting Device' (published Dec. 9, 2013, hereinafter referred to as Prior Art Document 2) and Japanese Patent Application Laid-open No. 2003-318430 'Solar Cell Module' And its installation method ”(published Nov. 7, 2003, hereinafter referred to as Prior Art Document 3). Prior art documents 2 and 3 disclose a structure for supporting a solar panel by using a plurality of rollers and wires, but are only used to change the angle of the solar panel by a twisting method or a folding method. There was no technical idea of actively moving the solar panels using wires.

Therefore, when installing the photovoltaic module using the conventional method, such as the prior art documents 1 to 3, it is difficult to install the photovoltaic module at the exact position desired because the photovoltaic module must be coupled to the wire at a desired position in the air. In addition, there was a problem in the safety of the worker, there was a problem that is difficult to install due to the complex structure to prevent the sag of the wire.

The present invention has been made in order to solve the above problems, because the solar module is installed by using a method of winding a plurality of wires in a plurality of rotating bodies in both directions or a single direction without being limited by space at a specific place. The purpose is to provide a Volplaning Construction System.

In addition, three-dimensional installation is possible by processing a plurality of wires, it is possible to work only in a specific place without the movement of the operator to ensure safety, can easily perform the work is shortened the air, It is an object of the present invention to provide a photovoltaic module installation structure using a plurality of wires that can be easily and quickly taken during maintenance, and to relieve sag by applying tension to the wires.

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 positioned at vertices to form a virtual rectangular plane of the present invention. Including the (100d), the first and second rotating bodies (100a) (100b) and the third and fourth rotating bodies (100c) (100d) each form a short side, the first and third rotating bodies (100a) ( A rod rotator 100 disposed such that 100c and the second and fourth rotators 100b and 100d respectively form a long side, and at least one additional rotator 100e is formed at an arbitrary position; A support structure 200 for supporting the first and fourth rotating bodies 100d and 100d and the additional rotating body 100e of the rod rotating body 100 at positions spaced from the ground, respectively; And 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 rod rotating body 100 and the rod rotating body. 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 of the whole 100, wherein the first, The first rod wire 300a mounted between the three rotors 100a and 100c is provided with at least one first mounting unit 310 and is mounted between the second and fourth rotors 100b and 100d. The second load wire 300b is provided with at least one second mounting part 320, and at least one pair of first and second mounting parts 310 and 320 are provided to move in the same direction. 300; includes.

In addition, each of the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 so that at least one rotating disk 120 rotates on the rotating shaft 110, respectively. The additional rotating body 100e may be coupled to a plurality of rotating disks 120.

In addition, the support structure 200 is composed of a support 210 and a base structure 220 thereunder, the support 210 is a plate 212 is coupled to the post 211, the plate 212 The rod rotating body 100 may be provided at an upper portion of the rod rotating body 100.

In addition, the support 210 is a plate 212 is rotatably coupled to the post 211, the wire loader 213 is provided on the upper portion of the plate 212, the wire loader 213 is At least one pair of rollers 213b are provided between the pair of support bars 213a so as to be spaced apart from each other at a predetermined interval so that the load wire 300 may be guided therebetween.

In addition, the support 210 is a plate 212 is coupled to the post 211, the plate 212 is composed of a first plate 212-1 and a second plate 212-2, which are mutually slide The first and second rotating bodies 100a to 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. At least one of the provided distance can be adjusted.

In addition, the foundation structure 220, the post 211 is coupled to the base plate 221, the bracing plate 222 is coupled to support the post 211, the bucket portion so that earth or sand is provided 223 may be integrally formed.

In addition, a plurality of wire brackets 400 in which wire seating holes 410 are formed may be coupled to the first mounting part 310 and the second mounting part 320 of the rod wire 300 in the longitudinal direction so as to face each other. have.

In addition, the wire bracket 400 is formed by coupling a pair of first bracket bar 400a and a second bracket bar 400b hinged, wherein the first and second bracket bars 400a and 400b are Wire seating grooves 410a and 410b are formed on the inner side, and the rod wire 300 may be coupled to the wire seating holes 410 formed by the wire seating grooves 410a and 410b.

In addition, an oblique guide surface is formed on 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 load wire 300. can do.

In addition, the wire bracket 400 is formed by coupling a pair of first bracket bar 400a and a second bracket bar 400b hinged to surfaces of the bracket body 400c facing each other. 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 formed on opposite surfaces of the bracket body 400c, respectively. 300 may be coupled to the wire seating hole 410 formed by the wire seating grooves 410a and 410b and the wire seating groove 410c.

In addition, 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 is also provided with a pair of up and down Including a mounting wire 320-1, the mounting wires 310-1, 320-1 are coupled to penetrate the wire bracket 400, may be provided to cross between the adjacent wire bracket 400. have.

In addition, 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 load wire 300. Or lower wires 310-3 and 320-3 may be provided downward.

In addition, the first mounting portion 310 of the load wire 300 includes a pair of the first outer mounting portion 311 and the first inner mounting portion 312 which are different from each other in the moving direction, the second mounting The unit 320 may also be installed at the same time in different positions, including a pair of the second outer mounting portion 321 and the first inner mounting portion 322 to be different from each other in the direction of movement can be installed in the solar module (SM). have.

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

The solar module installation structure using a plurality of wires of the present invention by the above-described solution, since the photovoltaic module is installed using a method in which the rod wire of the closed curve is continuously wound on the rod rotating body, the space is limited in a specific place It is possible to form a Volplaning Construction System that can be installed in both directions or in one direction without receiving any pressure.

As a result, the first and second mounting portions of the load wire may move in the same direction, so that the three-dimensional installation may be performed without being limited by space in installing the solar module.

In addition, even if the worker does not move, it is possible to perform the task of installing the photovoltaic module only in a specific place to ensure safety.

In addition, the solar module can be easily installed by simply moving the first and second load wires, so that the work can be easily performed, and the air can be shortened. There is this.

On the other hand, the plate with the rotating body is rotatably coupled to the post, or the first plate and the second plate constituting the plate is formed so as to slide with each other, the distance between the rotating body is adjusted, so that the tension is applied to the wire I can alleviate it.

Furthermore, a plurality of rod wires may be provided up and down to ensure structural safety of the installation structure, and the plurality of rod wires arranged up and down may be alternately arranged in a truss shape to further increase safety from self weight or wind load.

In addition, it is possible to form a three-dimensional structure having a curvature based on a plurality of rod wires arranged up and down.

On the other hand, even when the wire loader is provided so that the rod wire is guided between the pair of rollers to be provided with a plurality of rod wires up and down, the load wire can be stably moved without departing from the rotating body.

And by combining the wire bracket formed of the first, second bracket bar or the bracket body can be provided with a photovoltaic module stably, when a plurality of rod wires are provided up and down so that they are moved at the same speed.

In particular, the first and second mounting portions of the rod wire may include a pair of inner and outer mounting portions, respectively, which are different from each other in a moving direction, so that the solar modules may be simultaneously installed at different positions.

1 is a plan view showing an installation structure according to an embodiment of the present invention.

Figure 2 is a side view showing the installation structure according to an embodiment of the present invention.

3 and 4 is a conceptual diagram showing an installation method according to an embodiment of the present invention.

5 and 6 are conceptual views illustrating an installation method according to an embodiment in which the first and second rod wires of the present invention are wound around additional rotors and two rotors.

7 to 8 and 9 to 10 is a conceptual diagram showing an installation method according to an embodiment in which the first and second rod wire of the present invention is wound on an additional rotating body and three or four rotating bodies.

11 to 13 is a conceptual diagram showing an installation method having two additional rotating bodies of the present invention.

14 and 15 are elevation views illustrating a wire loader unit according to various embodiments of the present disclosure.

16 to 18 are cross-sectional views showing a support structure according to an embodiment of the present invention.

19 to 21 are elevation views illustrating a support according to various embodiments of the present invention.

22 to 23 are elevation and cross-sectional views illustrating a wire bracket according to various embodiments of the present disclosure.

24 to 25 are elevation views showing the mounting wire and the 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.

Solar module installation structure using a plurality of wires of the present invention is a rod rotating body 100 including a plurality of rotating bodies, a support structure 200 for supporting the rod rotating body 100 as shown in FIG. The rod wire 300 includes a first rod wire 300a and a second rod wire 300b which are continuously wound and moved on the rod rotating body 100.

In detail, the rod rotating body 100 includes at least four first rotating bodies 100a, second rotating bodies 100b, third rotating bodies 100c, and fourth portions positioned at vertices to form a virtual rectangular plane. It includes the rotor 100d and additionally includes an additional rotor 100e formed at an arbitrary position.

At this time, in forming a rectangular plane, the first and second rotors 100a and 100b and the third and fourth rotors 100c and 100d respectively form short sides and the first and third rotors 100a. 100c and the 2nd, 4th rotating bodies 100b and 100d are arrange | positioned so that each may form a long side.

As shown in FIG. 2, the support structure 200 is a position in which the first and fourth rotating bodies 100d and 100d and the additional rotating body 100e of the rod rotating body 100 are separated from the ground, respectively. Support to be installed on The support structure 200 may be manufactured in various shapes, so that the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 are individually supported. Separate support structures are formed, or one support structure supports the first and second rotors 100a and 100b and the additional rotor 100e, and the third and fourth rotors 100c and 100d are supported. Another support structure may be supported, and may be formed as one support structure to support the entire first to fourth rotating bodies 100a to 100d and the additional rotating bodies 100e as a whole.

The first load wire 300a and the second load wire 300b of the load wire 300 are formed in a closed curve. In this case, the closed curve refers to a wire continuously formed so that there is no end portion, and is disposed to intersect when viewed as an orthogonal projection in an imaginary plane formed by the rod wire 300 to form a plurality of intersections CP. It is defined as including a shape.

The load wire 300 is a closed first load wire 300a that is 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. ) And the second rod 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 of the rod rotating body 100. .

At this time, the first mounting portion 310 of the first rod wire 300a mounted between the first and third rotary bodies 100a and 100c and between the second and fourth rotary bodies 100b and 100d The second mounting part 320 of the second load wire 300b is provided to move in the same direction.

The meaning of 'winding' is that the rod wire 300 is coupled so as to rotate the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e, and wound around one or more turns. Of course, even if the winding is less than one rotation, the 'wound' if the load wire 300 can rotate the first to fourth rotating body (100a, 100b, 100c, 100d) and the additional rotating body (100e) by the friction force It is defined as.

3 to 4, the first rod wire 300a of the rod wire 300 passes through the third rotor 100c to the additional rotor 100c in the first rotor 100a. Via (100e), it is returned to the first first rotating body (100a) again, the second load wire (300b) of the load wire 300 is the second rotating body (100d) in the second rotating body (100b) Via the additional rotating body (100e) via, can be wound on the rotating bodies to return to the first second rotating body (100b).

In this case, each of the first and second load wires 300a and 300b is provided with one crossing portion CP, and the first load wire is mounted between the first and third rotating bodies 100a and 100c. The second mounting portions 320 of the second rod wires 300b mounted between the first mounting portion 310 of the 300a and the second and fourth rotating bodies 100b and 100d respectively move in the same direction. Can be.

Therefore, the operator can perform the operation of coupling the solar module (SM) to the load wire 300 only at one end in the longitudinal direction of the installation structure, three-dimensional installation is possible without the constraints of space, the worker moves Even if not, the installation of the photovoltaic module (SM) can be performed only at a specific place, thereby ensuring safety.

In addition, it is possible to install the solar module (SM) simply by moving the load wire 300, so that the operation can be easily performed, the air is shortened, easy and quick measures during maintenance of the solar module (SM) There is a possible advantage.

In this case, as shown in FIGS. 3 to 4, the first mounting part 310 of the rod wire 300 has a pair of first outer mounting parts 311 and first inner mounting parts which are different from each other in a moving direction. 312, the second mounting part 320 may also include a pair of second outer mounting portions 321 and the first inner mounting portions 322 which are different from each other in the moving direction.

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 are mutually the same direction of movement, the first mounting portion The first inner mounting portion 312 of the 310 and the second outer mounting portion 321 of the second mounting portion 320 are also the same in the direction of movement of each other, the operator at the same time both ends in the longitudinal direction of the installation structure (SM) can be installed, the work efficiency is increased.

In another embodiment, as illustrated in FIG. 5, 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 have the same moving 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 also be formed to have the same moving direction.

In addition, FIG. 6 shows that the load wire 300 is the first 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 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 of the load wire 300a and the rod rotating body 100. ), But the winding sequence is different from that of FIGS. 3, 4, and 5.

Further, as shown in FIGS. 7 to 8, the load wire 300 may include the first rotating body 100a, the second rotating body 100b, the third rotating body 100c and the addition of the rod rotating body 100. The first rod wire 300a of the closed curve continuously wound on the rotor 100e and the first rotor 100a, the second rotor 100b, and the fourth rotor 100d of the rod rotor 100. ) And the second rod wire 300b of the closed curve that is continuously wound on the additional rotating body 100e, and as shown in FIGS. 9 to 10, the load wire 300 is the rod rotating body 100. The first rod wire 300a of the closed curve continuously wound on the first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e and the first rotating body among the rod rotating bodies 100. It can also be comprised with the closed 2nd load wire 300b wound continuously by 100a-4th rotating body 100d and the additional rotating body 100e.

In addition, as illustrated in FIGS. 11 and 12, the additional rotating body 100e may be designed to be provided in plural.

In particular, FIG. 13 includes two additional rotors 100e, one additional rotor 100e is located between the first and second rotors 100a and 100b, and the other additional rotor 100e. ) Is located between the third and fourth rotors 100c and 100d, and the first rod wire of the closed curve wound around both the first and third rotors 100a and 100c and the two additional rotors 100e. An embodiment composed of a closed curved second rod wire 300b wound around both 300a and second and fourth rotating bodies 100b and 100d and two additional rotating bodies 100e is shown.

In this case, the first mounting portion 310 and the second mounting portion 320 of the first load wire 300a is formed to move in the same direction.

Meanwhile, as illustrated in FIGS. 14 to 15, the first and fourth rotating bodies 100a to 100d and the additional rotating body 100e of the rod rotating body 100 may each have at least a rotation axis 110. One rotating disk 120 may be coupled to rotate, and the additional rotating body 100e may be coupled to a plurality of rotating disks 120.

In addition, a plurality of first rotating body (100a) to the fourth rotating body (100d) is also mounted up and down to form the mounting wire (310a, 320a), the upper wire (310b, 320b) and the lower wire (310c, 320c) In this case, the plurality of rotating disks 120 may be independently rotated on one rotating shaft 110.

In addition, as illustrated in FIGS. 14 to 15, a wire loader 213 may be provided on the plate 212. The wire loader 213 may be provided such that at least one pair of rollers 213b are spaced apart by a predetermined interval between the pair of support bars 213a so that the load wire 300 may be guided therebetween.

In this case, when a plurality of load wires 300 are formed up and down, a plurality of rollers 213b may also be provided in the up and down direction.

Meanwhile, as illustrated in FIGS. 16 to 18, the support structure 200 includes a support 210 and a base structure 220 below the support 210, and the support 210 has a plate 212 on the post 211. Is coupled, the rod rotating body 100 may be provided on the upper portion of the plate 212, the support 210 may be rotatably coupled to the plate 212 to the post 211, the load wire Tension may be applied to the 300 to mitigate sag.

On the other hand, the base structure 220, the post 211 is coupled to the base plate 221, the bracing plate 222 is coupled to support the post 211, bucket portion so that earth or sand is provided 223 may be integrally formed. Thereby, structural stability can be ensured.

In addition, as shown in FIGS. 19 to 21, the support 210 has a plate 212 coupled to the post 211, and the first plate 212-1 and the first plate 212-1 on which the plates 212 slide together. It consists of two plates 212-2, and the first rotating body 100a to the fourth rotating body of the rod rotating body 100, respectively, on the first plate 212-1 and the second plate 212-2. At least one of the 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 to reduce the deflection phenomenon by applying tension to the rod wire 300.

Meanwhile, at least one pair of wire brackets 400 may be coupled to the first mounting part 310 and the second mounting part 320 of the load wire 300 in a lengthwise direction so as to face each other, and the wire bracket ( The solar module (SM) is coupled to the upper portion of the 400.

At this time, the wire bracket 400 is formed by combining a pair of first bracket bar 400a and a second bracket bar 400b hinged as shown in Figure 22, the first and second bracket bar ( 400a and 400b are wire seating grooves 410a and 410b formed on the inner side thereof, and the rod wire 300 is coupled to the wire seating holes 410 formed by the wire seating grooves 410a and 410b. It may be formed to.

In this case, 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 one side of the wire seating grooves 410a and 410b may be diagonally guided. The surface may be formed so that the wire may be easily guided in the process of being seated in the wire seating grooves 410a and 410b.

In another embodiment, the wire bracket 400 includes a pair of first bracket bar 400a and a second bracket bar 400b which are hinged on surfaces of the bracket body 400c facing each other, as shown in FIG. 23. ) Are coupled to each other, and the first and second bracket bars 400a and 400b have wire seating grooves 410a and 410b formed on the inner side thereof, and the wires are mounted on opposite sides of the bracket body 400c. The groove 410c is formed so that the load wire 300 may be coupled to the wire seating hole 410 formed by the wire seating grooves 410a and 410b and the wire seating groove 410c.

The wire bracket 400 may be coupled to the load wire 300 to stably provide a solar module SM, and in the case where a plurality of mounting wires 310a and 320a are provided up and down, at the same speed. To be moved.

As shown in FIG. 24, the first mounting part 310 of the rod wire 300 includes a pair of mounting wires 310a provided up and down, and the second mounting part 320 is also provided up and down. It may include a pair of mounting wire 320a.

The mounting wires 310a and 320a are coupled to penetrate the wire bracket 400 and provided to intersect between adjacent wire brackets 400 to secure structural safety of the installation structure, and to be safe from own weight or wind load. Can be further increased. In addition, a three-dimensional structure having a curvature may be formed based on the mounting wires 310a and 320a disposed up and down.

Meanwhile, as shown in FIG. 25, upper wires 310b and 320b are provided above the mounting wires 310a and 320a of the first and second mounting portions 310 and 320 of the load wire 300. Lower wires 310c and 320c may be provided below.

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 embodiment, and the present invention belongs without departing from the gist of the present invention as claimed in the following claims. Those skilled in the art should be regarded as belonging to the protection scope of the claims to the extent that any person can make various changes.

Claims (14)

1. A first rotating body 100a, a second rotating body 100b, a third rotating body 100c, and a fourth rotating body 100d positioned at vertices to form an imaginary rectangular plane, wherein the first, The second rotor 100a, 100b and the third and fourth rotors 100c and 100d respectively form short sides, and the first and third rotors 100a and 100c and the second and fourth rotors 100b are respectively formed. A rod rotating body (100), each of which is disposed so as to form a long side, and at least one additional rotating body (100e) is formed at an arbitrary position;

   A support structure 200 for supporting the first and fourth rotating bodies 100d and 100d and the additional rotating body 100e of the rod rotating body 100 at positions spaced from the ground, respectively; And

   The first rod wire 300a and the rod rotator of a closed curve continuously wound on at least a first rotator 100a, a third rotator 100c, and an additional rotator 100e of the rod rotator 100. Consists of 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) of (100),

   The first rod wire 300a mounted between the first and third rotors 100a and 100c is provided with at least one first mounting unit 310 and the second and fourth rotors 100b and 100d. At least one second mounting portion 320 is provided between the second load wires 300b and the at least one pair of first and second mounting portions 310 and 320 are moved in the same direction. A solar module installation structure using a plurality of wires, characterized in that it comprises a load wire (300) provided.
2. The method of claim 1,

   The first rotating body 100a to the fourth rotating body 100d and the additional rotating body 100e of the rod rotating body 100 are coupled to the rotating shaft 110 so that at least one rotating disk 120 rotates. , The additional rotating body (100e) is a solar module installation structure using a plurality of wires, characterized in that the plurality of rotating disks 120 are coupled.
3. The method of claim 1,

   The support structure 200 is composed of a support 210 and a lower base structure 220, the support 210 is a plate 212 is coupled to the post 211, the upper portion of the plate 212 Solar module installation structure using a plurality of wires, characterized in that the rod rotating body 100 is provided.
4. The method of claim 3,

   The support 210 is a plate 212 is rotatably coupled to the post 211, the wire loader 213 is provided on the upper portion of the plate 212, the wire loader 213 is a pair At least one pair of rollers (213b) is provided between the support bars (213a) of the solar module installation structure using a plurality of wires, characterized in that the load wire 300 is guided therebetween.
5. The method of claim 3,

   The support 210 is a plate 212 is coupled to the post 211, the plate 212 is composed of a first plate 212-1 and a second plate 212-2, the slide between 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, respectively, on the first plate 212-1 and the second plate 212-2. Solar module installation structure using a plurality of wires, characterized in that the distance is adjusted to one provided.
6. The method of claim 3,

   The base structure 220 is a post 211 is coupled to the base plate 221, the bracing plate 222 is coupled to support the post 211, bucket portion 223 to be provided with earth or sand Solar module installation structure using a plurality of wires, characterized in that is formed integrally.
7. The method of claim 1,

   A plurality of wire brackets 400 in which wire seating holes 410 are formed are coupled to the first mounting portion 310 and the second mounting portion 320 of the rod wire 300 in the longitudinal direction so as to face each other. Solar module installation structure using a plurality of wires.
8. The method of claim 7, wherein

   The wire bracket 400 is formed by coupling a pair of first bracket bar 400a and a second bracket bar 400b hinged, and the first and second bracket bars 400a and 400b have an inner surface. The wire seating grooves 410a and 410b are formed in the plurality of wires, and the rod wire 300 is coupled to the wire seating holes 410 formed by the wire seating grooves 410a and 410b. Solar module installation structure using.
9. The method of claim 8,

   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 is formed to guide the load wire 300 by forming a diagonal guide surface. Solar module installation structure using a plurality of wires characterized in.
10. The method of claim 7, wherein

    The wire bracket 400 is formed by coupling a pair of first bracket bar 400a and a second bracket bar 400b hinged to the surfaces of the bracket body 400c facing each other, respectively, wherein the first, 2, the bracket bars 400a and 400b have wire seating grooves 410a and 410b formed on the inner side thereof, and wire seating grooves 410c formed on the opposite sides of the bracket body 400c, respectively. ) Is a solar module installation structure using a plurality of wires, characterized in that coupled to the wire seating hole (410) formed by the wire seating groove (410a) (410b) and the wire seating groove (410c).
11. The method of claim 7, wherein

    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 also includes a pair of mounting wires provided up and down. Including a (320-1), the mounting wires 310-1, 320-1 are coupled to penetrate through the wire bracket 400, characterized in that provided to cross each other between the adjacent wire bracket 400 Solar module installation structure using a plurality of wires.
12. The method of claim 11,

    Upper wires 310-2 and 320-2 are provided above or below the mounting wires 310-1 and 320-1 of the first and second mounting portions 310 and 320 of the load wire 300. Row lower wire 310-3 (320-3) is provided with a solar module installation structure using a plurality of wires.
13. The method of claim 1,

    The first mounting portion 310 of the rod wire 300 includes a pair of first outer mounting portion 311 and the first inner mounting portion 312 to be different from each other in the moving direction, the second mounting portion ( 320 also includes a pair of second outer mounting portion 321 and the second inner mounting portion 322 different from each other in the direction of movement can be installed at the same time at different locations the solar module (SM) Solar module installation structure using a plurality of wires.
14. The method of claim 1,

    The rod rotating body 100 includes two additional rotating bodies 100e, one additional rotating body 100e is located between the first and second rotating bodies 100a and 100b and the other additional rotating body 100e. The whole 100e is located between the third and fourth rotating bodies 100c and 100d and is formed of a closed curve wound around both the first and third rotating bodies 100a and 100c and the two additional rotating bodies 100e. It consists of the 1st load wire 300a, the 2nd, 4th rotation body 100b (100d), and the 2nd load wire 300b of the closed curve wound by both the additional rotation bodies 100e, The said 1st, 2nd Each of the first and second mounting portions 310 and 320 of the load wires 300a and 300b is provided with at least one first mounting portion 310 and at least one second mounting portion 320, respectively. Solar module installation structure using a plurality of wires, characterized in that the pair of first and second mounting portion 310, 320 is provided to move in the same direction.

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