WO2018034403A1 - Structure for installing photovoltaic module by using wire - Google Patents

Abstract

The present invention relates to a structure for installing a photovoltaic module by using a wire. To this end, the present invention comprises: a rod rotation body comprising at least four rotation bodies, a first rotation body, a second rotation body, a third rotation body and a fourth rotation body, which are positioned at vertices so as to form an imaginary rectangular plane, wherein the first and second rotation bodies and the third and fourth rotation bodies are disposed to form short sides, and the first and third rotation bodies and the second and fourth rotation bodies are disposed to form long sides; a support structure for supporting the first to fourth rotation bodies of the rod rotation body such that the first to fourth rotation bodies are installed in positions separated from the ground; and a closed curved rod wire which is consecutively wound around the first to fourth rotation bodies of the rod rotation body, and in which a first holding part of the rod wire, held between the first and third rotation bodies, and a second holding part of the rod wire, held between the second and fourth rotation bodies, are provided so as to be moved in the same direction. Accordingly, a volplaning construction system is provided for installing a photovoltaic module, which enables three-dimensional installation unbound by spatial constraints.

Description

PV module installation structure using wire

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

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 it installs the solar module using a method of winding the wire in a plurality of rotating bodies to install in both directions or unidirectional direction without being restricted by the space in a specific place The purpose is to provide a Volplaning Construction System.

Also, bar installations by processing the wire three-dimensional installation is a feature, and without moving the worker can work only in certain places the safety is secured, it is possible to easily perform the operation air is reduced, and maintenance of solar modules It is an object of the present invention to provide a photovoltaic module installation structure using wires, which can be quickly and easily repaired, and to relieve sag by applying tension to the wires.

In order to achieve the above object, the solar module installation structure using the wire of the present invention includes at least four first rotating bodies 100a and second rotating bodies 100b positioned at vertices to form a virtual rectangular plane. And a third rotating body 100c and a fourth rotating body 100d, wherein the first and second rotating bodies 100a and 100b and the third and fourth rotating bodies 100c and 100d respectively have short sides. A rod rotator 100 formed to form a long side of the first and third rotators 100a and 100c and the second and fourth rotators 100b and 100d, respectively; A supporting structure (200) for supporting the first and fourth rotating bodies (100d) to 100d of the rod rotating body (100) to be installed at positions spaced apart from the ground; And a rod wire which is continuously wound on the first rotating body 100a to the fourth rotating body 100d of the rod rotating body 100 and mounted between the first and third rotating bodies 100a and 100c. 300 is provided with at least one first mounting portion 310, the load wire 300 is mounted between the second, fourth rotating body (100b, 100d) is at least one second mounting portion (320) It is provided, at least a pair of first and second mounting portion 310, 320 is a closed wire rod 300 provided to be moved in the same direction with each other; includes.

In addition, at least one pair of girder units 400 may be coupled to the first mounting portion 310 and the second mounting portion 320 of the load wire 300 in the longitudinal direction so as to face each other.

In addition, a wire clamp 420 is formed on an upper portion of the girder unit 400, and a wire clamp 420 may be coupled to the load wire 300.

In addition, the wire clamp 420 of the girder unit 400 has a support flange 422 for supporting the photovoltaic module SM on the coupling flange 421 coupled to the side of the girder unit 400 is a rotary rod 423 Is rotatably coupled by it may be possible to adjust the angle of the solar module (SM).

In addition, the rolling wire 424 is wound around the rotating rod 423 of the wire clamp 420, so that the support flange 422 may rotate as the rolling wire 424 moves.

In addition, the other side of the auxiliary wire 425 coupled to the photovoltaic module SM is coupled to the rolling wire 424 to prevent the flow of the photovoltaic module SM, and the balance can be maintained.

In addition, the pair of auxiliary wires 425 coupled to the rolling wire 424 are coupled to both ends of the width direction of the photovoltaic module SM, respectively, and the other side is inclined to the rolling wire 424 extended outwards. Can be combined.

In addition, the girder unit 400 is formed of a hollow steel pipe, between the girder unit 400 and the adjacent girder unit 400 so that the connecting socket 500 is inserted into the hollow portion 410 of the girder unit 400. It may be provided.

In addition, the connecting socket 500 is formed of a hollow steel pipe, the truss bracket 600 is provided to be inserted into the hollow portion 510 of the connecting socket 500, the truss bracket 600 is a pair of trusses A guide hole 610 may be formed, and a pair of truss wires 700 may be provided to penetrate the truss guide hole 610.

In addition, a connection bracket 800 formed of a pair of bracket bodies 810 coupled to the girder unit 400 and an adjacent girder unit 400 to enable an angle adjustment may be coupled.

In addition, the bracket body 810 is formed by combining an upper bracket unit 810a having a wire seating groove 811a formed therein with a lower bracket unit 810b having a wire seating groove 811b formed therein, The truss wire 700 may be provided to penetrate the wire seating hole 811 formed by the wire seating grooves 811a and 811b.

In addition, the upper and lower bracket units 810a and 810b of the bracket body 810 are formed with pressure fixing grooves 812a and 812b on one side, respectively, to provide a pressure fixing part 812 and the pressure fixing part 812. ) Is provided with a first iron piece 820, a pair of connecting pieces (813a, 813b) are formed on both sides of the pressure fixing groove (812a, 812b), the upper, lower bracket units (810a, 810b) on the other side The girder seating grooves 814a and 814b are formed to provide girder seating portions 814 on which end portions of the girder units 400 are seated, and second iron pieces 830 are provided on the girder seating portions 814. The connecting rods 840 are coupled to the first and second iron pieces 820 and 830 so that upper and lower bracket units 810a and 810b are pressurized and fixed.

In addition, the pair of connecting pieces 813a and 813b of the upper and lower bracket units 810a and 810b constituting the bracket body 810 may include first connecting pieces 813a-1 and 813b-1 and different lengths, respectively. It is composed of two connecting pieces (813a-2, 813b-2), the upper and lower bracket units (810a, 810b) is a second relatively short length relative to the first long connecting pieces (813a-1, 813b-1) The connecting pieces 813b-2 and 813a-2 may be coupled to contact each other up and down.

In addition, through holes 815a and 815b are formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b constituting the bracket body 810, respectively. 810 may be coupled such that the first connecting pieces 813b-1 and 813a-1 of the other bracket body 810 coupled to the first connecting pieces 813a-1 and 813b-1 abut up and down.

In addition, at least one of the through holes 815a and 815b formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b is formed in a long hole shape to be coupled to enable angle adjustment. Can be.

In addition, the rod wire 300 is wound continuously so that an odd number of intersections CP may be formed between the first and fourth rotating bodies 100a to 100d of the rotating body 100, and thus, at least one pair The first and second mounting portions 310 and 320 may be moved in the same direction.

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.

And a pair of tension brackets 900 are symmetrically coupled to the center of the intersection portion CP of the load wire 300, each tension bracket 900 is a pair of guide plate 910 is a connecting rod ( 920 is coupled to adjust the separation distance to each other, the guide plate 910 is a pair of guide grooves 911 is formed can be applied to the tension by adjusting the distance of the load wire (300).

The solar module installation structure using the wire of the present invention by the above-described solution, because the solar module is installed by using a method of winding the rod wire of the closed curve continuously on the rod rotating body is not limited by the space in a specific place Can be formed in two or one direction have.

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, since the installation of the solar module can be easily performed by simply moving the load wire, the operation can be easily performed, and thus the air is shortened.

On the other hand, the wire clamp for supporting the solar module is rotatably coupled to facilitate the angle adjustment of the solar module.

Furthermore, the connecting socket and the truss bracket are provided inside the girder member, and a pair of truss wires are provided to penetrate the truss bracket, thereby enabling the formation of a three-dimensional structure while ensuring structural safety.

In addition, a plurality of girder members are continuously coupled to each other is provided with a connecting bracket coupled to be able to adjust the angle therebetween to form a three-dimensional structure having a curvature.

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

In addition, a pair of tension brackets are symmetrically coupled around the intersection of the rod wires, thereby adjusting tension of the rod wires, thereby alleviating sag by applying tension to the wires.

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

7 and 8 is a conceptual diagram showing an installation method including a girder unit according to an embodiment of the present invention.

9 and 10 is a conceptual diagram showing an installation method including a girder unit according to another embodiment of the present invention.

11 is a cross-sectional view illustrating a wire clamp according to various embodiments of the present disclosure.

12 and 13 are a cross-sectional view and operation conceptual diagram showing a wire clamp according to an embodiment of the present invention.

14 and 15 are cross-sectional views showing an installation method using a connecting socket and a truss bracket according to an embodiment of the present invention.

16 and 17 are a perspective view and a cross-sectional view showing an installation method using a connection bracket according to an embodiment of the present invention.

18 and 19, 20 and 21 is a conceptual diagram showing an installation method according to various embodiments of the present invention.

22 is a conceptual diagram and a cross-sectional view showing a tension bracket according to an embodiment 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 wire of the present invention, as shown in Figure 1, the rod rotating body 100 including a plurality of rotating body, the support structure 200 for supporting the rod rotating body 100, the It includes a load wire 300 is continuously wound on the rod rotating body 100 to move.

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. Rotor 100d is included.

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 supports the first and fourth rotating bodies 100d and 100d of the rod rotating body 100 to be installed at positions spaced apart from the ground, respectively. The support structure 200 may be manufactured in various shapes, and separate support structures are formed to individually support the first rotating bodies 100a to the fourth rotating bodies 100d of the rod rotating body 100. Alternatively, one supporting structure may support the first and second rotating bodies 100a and 100b, and the other supporting structure may support the third and fourth rotating bodies 100c and 100d. It may be formed as a single support structure to support the whole (100a) to the fourth rotating body (100d) as a whole.

The load wire 300 is 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 continuously wound on the first rotating body 100a to the fourth rotating body 100d of the rod rotating body 100, between the first and third rotating bodies 100a and 100c. The second mounting portion 320 of the load wire 300 mounted between the first mounting portion 310 and the second and fourth rotating bodies 100b and 100d of the loaded wire 300 move in the same direction. It is provided to be.

The meaning of the 'winding' is that the load wire 300 is coupled to rotate the first rotating body (100a) to the fourth rotating body (100d), winding more than one rotation of course winding less than one rotation Even if the load wire 300 can rotate the first to fourth rotating bodies (100a, 100b, 100c, 100d) by the friction force is defined as 'wound'.

3 to 4, the load wire 300 passes through the first rotating body 100a from the first rotating body 100a to the third rotating body 100c. In order to return to the first rotating body 100a from the first rotating body 100a, passing through the second rotating body 100b, passing through the fourth rotating body 100d, and the second rotating body 100b. It can be wound around the rotating bodies.

In this case, three cross portions CP are formed in the load wire 300, and the first mounting portion 310 of the load wire 300 mounted between the first and third rotational bodies 100a and 100c. ) And the second mounting portion 320 of the load wire 300 mounted between the second and fourth rotating bodies 100b and 100d may be moved in the same direction.

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. 5 to 6, 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 addition, in the above embodiment, 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 mutually the same movement direction, the first mounting The first inner mounting portion 312 of the portion 310 and the second inner mounting portion 322 of the second mounting portion 320 also have the same movement direction, so that workers can simultaneously view sunlight at both ends in the longitudinal direction of the installation structure. Since the module (SM) can be installed, the work efficiency is increased.

Meanwhile, as shown in FIGS. 7 to 8, at least one pair of girder units 400 are longitudinally opposed to each other in the first mounting portion 310 and the second mounting portion 320 of the load wire 300. It may be coupled to, and may be coupled to both ends of the solar module (SM) to the upper portion of the girder unit 400.

The girder unit 400 is coupled to only the first and second outer mounting parts 311 and 321 of the load wire 300 or coupled to only the first and second inner mounting parts 312 and 322 of the rod wire 300. The operation may be performed at one end in the longitudinal direction, or as shown in FIGS. 9 to 10, at one side, the girder unit 400 is coupled to the first and second outer mounting portions 311 and 321, and at the other side. The girder unit 400 may be coupled to the first and second inner mounting portions 312 and 322 so that the work may be simultaneously performed at both ends.

On the other hand, a wire clamp 420 is formed on the upper part of the girder unit 400, the wire clamp 420 may be coupled to the load wire 300.

The wire clamp 420 may be formed on the upper part of the girder unit 400 in various shapes, and as shown in FIG. 11, the flange of the iron piece on which the coupling hole is formed is welded to the upper part, or the inner side of the girder unit 400. It may be manufactured to form a separate coupling hole.

At this time, the method of coupling the photovoltaic module (SM) to the upper portion of the girder unit 400 is coupled to the side of the girder unit 400 as shown in FIG. The optical module SM may be seated or the upper surface of the wire clamp 420 may be flat to form the solar module SM.

In addition, the protrusion 430 may be formed on the upper part of the girder unit 400, and the upper surface may be flat to form the solar module SM to be seated therein.

On the other hand, as shown in Figure 12 the wire clamp 420 of the girder unit 400 is a support flange for supporting the photovoltaic module (SM) to the coupling flange 421 is coupled to the side of the girder unit 400 ( 422 is rotatably coupled by the rotating rod 423 may be capable of adjusting the angle of the solar module (SM). In this case, a bearing 426 may be provided on the outer circumferential surface of the rotating rod 423.

In this case, as shown in FIG. 13, the rolling wire 424 is wound around the rotating rod 423 of the wire clamp 420 so that the support flange 422 may rotate as the rolling wire 424 moves.

The angle of the photovoltaic module (SM) should be adjusted in order to secure the optimal power generation efficiency according to the change of the sun angle, and the rotating rod 423 wound on the rolling wire 424 may be moved by the movement of the rolling wire 424. Reaction is rotated, the auxiliary wire 425 coupled to the widthwise end of the solar module (SM) may be coupled to the rolling wire 424 to maintain the balance of the angle adjusted.

Specifically, the other side of the pair of auxiliary wires 425, one side of which is coupled to both ends of the width direction of the photovoltaic module SM, is coupled to the rolling wire 424 to prevent the flow of the photovoltaic module SM. And balance can be maintained. At this time, it is preferable that the auxiliary wires are coupled to each other outwardly inclined.

On the other hand, in one embodiment, as shown in Figure 14, the girder unit 400 is formed of a hollow steel pipe, the connection socket 500 between the adjacent girder unit 400, the hollow portion of the girder unit 400 It may be provided to be inserted into the 410. As a result, the coupling force between the plurality of girder units 400 coupled in the longitudinal direction can be securely secured.

In this case, the connection socket 500 may be formed of a hollow steel pipe, and the truss bracket 600 may be inserted into the hollow part 510 of the connection socket 500. The truss bracket 600 is preferably made of steel.

The truss bracket 600 may be provided with a pair of truss guide holes 610, and a pair of truss wires 700 may pass through the truss guide holes 610.

As shown in FIG. 15, the truss wire 700 is configured to secure a tensile force, thereby ensuring structural safety from its own weight generated by forming a three-dimensional structure.

In another embodiment, as shown in FIGS. 16 to 17, a connecting bracket formed of a pair of bracket bodies 810 coupled to be adjustable in angle between the girder unit 400 and the adjacent girder unit 400. 800 may be combined.

The bracket body 810 is formed by combining an upper bracket unit 810a having a wire seating groove 811a formed therein with a lower bracket unit 810b having a wire seating groove 811b formed therein, and a pair of trusses. The wire 700 may be provided to penetrate the wire seating hole 811 formed by the wire seating grooves 811a and 811b.

Thus, the technical effect that can be produced in a three-dimensional shape so that the girder unit 400 of the installation structure has a certain curvature is exhibited.

As shown in FIGS. 16 to 17, upper and lower bracket units 810a and 810b of the bracket body 810 are provided with pressure fixing grooves 812a and 812b on one side, respectively, to provide a pressure fixing part 812. can do.

In addition, a pair of connecting pieces 813a and 813b are formed at both sides of the pressing fixing grooves 812a and 812b, and the upper and lower bracket units 810a and 810b are respectively provided with girder seating grooves 814a and 814b. A girder seating portion 814 may be provided to be formed so that the end of the girder unit 400 is seated.

In this case, a first iron piece 820 is provided on the pressure fixing part 812, and a second iron piece 830 is provided on the girder seating part 814, and the first and second iron pieces 820 and 830 are provided. The coupling rod 840 is coupled to the upper and lower bracket units 810a and 810b to be pressurized and fixed.

Threads are formed on the first and second iron pieces 820 and 830, and screw threads are formed on the connecting rod 840 to be press-coupled, and the first and second iron pieces 820 and 830 are separately pressed. The nut of may be further provided.

In addition, the pair of connecting pieces 813a and 813b of the upper and lower bracket units 810a and 810b constituting the bracket body 810 may include first connecting pieces 813a-1 and 813b-1 and different lengths, respectively. It is composed of two connecting pieces (813a-2, 813b-2), the upper and lower bracket units (810a, 810b) is a second relatively short length relative to the first long connecting pieces (813a-1, 813b-1) The connecting pieces 813b-2 and 813a-2 may be coupled to contact each other up and down.

Meanwhile, through holes 815a and 815b are formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b constituting the bracket body 810, respectively. 810 may be coupled such that the first connecting pieces 813b-1 and 813a-1 of the other bracket body 810 coupled to the first connecting pieces 813a-1 and 813b-1 abut up and down.

In this case, at least one of the through holes 815a and 815b formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b may be formed in a long hole shape to be coupled to enable angle adjustment. Can be.

In addition, the pair of bracket body 810 may be coupled to each other, and the cover 850 may be coupled to the upper and lower portions. In this case, when the bracket bodies 810 are coupled to each other at a predetermined angle, the cover 850 having a shape corresponding to the angle may be coupled.

On the other hand, the load wire 300 is continuously wound to form an odd number of intersections (CP) between the first rotating body (100a) to the fourth rotating body (100d) of the rotating body 100 is a first mounting portion The 310 and the second holder 320 may be moved in the same direction.

3 and 4 form an intersection CP three times, but form an intersection CP once as shown in FIGS. 18 to 19, or cross as shown in FIGS. 20 to 21. By forming the portion CP five times, the first mounting portion 310 and the second mounting portion 320 may be designed to be moved in the same direction.

In addition, as shown in FIG. 22, a pair of tension brackets 900 may be coupled to be symmetrical about the intersection CP of the load wires 300, and the tension brackets 900 may include a load wire ( The tensile force is applied to the 300 to prevent the rod wire 300 from sagging.

Each tension bracket 900 is coupled to the pair of guide plates 910 to adjust the mutual separation distance by the connecting rod 920, the guide plate 910 is a pair of guide grooves (911) The tension may be applied by adjusting the spacing of the rod wires 300.

The photovoltaic module installation structure (S) using the wire according to the present invention described above is not limited to the above-described embodiment, the technical field to which the present invention belongs without departing from the spirit of the present invention as claimed in the following claims. To those skilled in the art should be considered to fall within the scope of the claims to the extent that anyone can make a variety of changes.

Claims (18)

1. And at least four first rotating bodies 100a, second rotating bodies 100b, third rotating bodies 100c, and fourth rotating bodies 100d positioned at vertices to form a virtual rectangular plane. The first and second rotating bodies 100a and 100b and the third and fourth rotating bodies 100c and 100d respectively form short sides, and the first and third rotating bodies 100a and 100c and the second and fourth times, respectively. A rod rotator 100 disposed such that the entire 100b and 100d respectively form a long side;

   A supporting structure (200) for supporting the first and fourth rotating bodies (100d) to 100d of the rod rotating body (100) to be installed at positions spaced apart from the ground; And

   The rod wire 300 which is continuously wound on the first rotating body 100a to the fourth rotating body 100d of the rod rotating body 100 and is mounted between the first and third rotating bodies 100a and 100c. ) Is provided with at least one first mounting portion 310, the rod wire 300 is mounted between the second, fourth rotating body (100b, 100d) is provided with at least one second mounting portion (320). At least one pair of first and second mounting portions 310 and 320 are disposed in a closed curve to be moved in the same direction;

   Photovoltaic module installation structure using a wire comprising a.
2. The method of claim 1,

   At least one pair of girder units 400 are coupled to the first mounting portion 310 and the second mounting portion 320 of the load wire 300 in a lengthwise direction so as to face each other. Modular mounting structure.
3. The method of claim 2,

   Wire clamp 420 is formed on the upper part of the girder unit 400, the solar module mounting structure using a wire, characterized in that the wire clamp 420 is coupled to the load wire (300).
4. The method of claim 3,

   The wire clamp 420 of the girder unit 400 has a support flange 422 for supporting the photovoltaic module SM on the coupling flange 421 coupled to the side of the girder unit 400 is rotated by the rotary rod 423. The solar module installation structure using a wire that is coupled to be possible to adjust the angle of the solar module (SM).
5. The method of claim 4, wherein

   Rolling wire 424 is wound around the rotating rod 423 of the wire clamp 420, the support flange 422 is rotated in accordance with the movement of the rolling wire 424 solar module installation structure using a wire .
6. The method of claim 5,

   The rolling wire 424 is coupled to the other side of the auxiliary wire 425 coupled to one side of the solar module (SM) to prevent the flow of the solar module (SM), characterized in that the balance is maintained Solar module installation structure using wire.
7. The method of claim 6,

   The pair of auxiliary wires 425 coupled to the rolling wire 424 are coupled to both ends of the width direction of the photovoltaic module SM, respectively, and the other side is coupled to the rolling wire 424 to be inclined to extend outward. Solar module installation structure using a wire, characterized in that.
8. The method of claim 2,

   The girder unit 400 is formed of a hollow steel pipe, the connection socket 500 is provided between the girder unit 400 and the adjacent girder unit 400 to be inserted into the hollow portion 410 of the girder unit 400. Solar module installation structure using a wire.
9. The method of claim 8,

   The connecting socket 500 is formed of a hollow steel tube, the truss bracket 600 is provided to be inserted into the hollow portion 510 of the connecting socket 500, the truss bracket 600 is a pair of truss guide hole ( 610 is formed, a pair of truss wires 700 is provided with a solar module installation structure using a wire, characterized in that provided through the truss guide hole (610).
10. The method of claim 2,

    Between the girder unit 400 and the adjacent girder unit 400, a solar module using a wire, characterized in that the connection bracket 800 formed of a pair of bracket body 810 is coupled to enable the angle adjustment is coupled. Installation structure.
11. The method of claim 10,

    The bracket body 810 is formed by combining an upper bracket unit 810a having a wire seating groove 811a formed therein with a lower bracket unit 810b having a wire seating groove 811b formed therein, and a pair of trusses. Solar module installation structure using a wire, characterized in that the wire 700 is provided to pass through the wire seating hole (811) formed by the wire seating grooves (811a, 811b).
12. The method of claim 11,

    The upper and lower bracket units 810a and 810b of the bracket body 810 are formed with pressure fixing grooves 812a and 812b on one side, respectively, to provide a pressure fixing part 812 and to the pressure fixing part 812. A first iron piece 820 is provided, and a pair of connecting pieces 813a and 813b are formed at both sides of the pressure fixing grooves 812a and 812b, and upper and lower bracket units 810a and 810b are respectively provided on the other side. Seating grooves 814a and 814b are formed to provide a girder seating portion 814 on which an end of the girder unit 400 is seated, and a second iron piece 830 is provided at the girder seating portion 814. The connecting rod 840 is coupled to the first and second iron pieces 820 and 830 so that the upper and lower bracket units 810a and 810b are pressurized and fixed.
13. The method of claim 12,

    The pair of connecting pieces 813a and 813b of the upper and lower bracket units 810a and 810b constituting the bracket body 810 have a first connecting piece 813a-1 and 813b-1 and a second connecting piece having different lengths, respectively. (813a-2, 813b-2), wherein the upper and lower bracket units (810a, 810b) has a relatively short second connection piece (1) relative to the first long connecting piece (813a-1, 813b-1) 813b-2, 813a-2) solar module installation structure using a wire, characterized in that coupled up and down abut.
14. The method of claim 13,

    Through-holes 815a and 815b are formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b constituting the bracket body 810, respectively. Is a photovoltaic module using a wire, characterized in that the first connecting piece 813b-1, 813a-1 of the other bracket body 810 coupled to the first connecting piece 813a-1, 813b-1 abuts up and down abuts Installation structure.
15. The method of claim 14,

    At least one of the through holes 815a and 815b formed in the first connection pieces 813a-1 and 813b-1 of the upper and lower bracket units 810a and 810b is formed in a long hole shape and is coupled to enable angle adjustment. Solar module installation structure using wire.
16. The method of claim 1,

    The load wire 300 is continuously wound to form an odd-numbered intersection portion CP between the first rotating bodies 100a to the fourth rotating bodies 100d of the rotating body 100 to form at least a pair of firsts. , 2 mounting portion 310, 320 is a solar module installation structure using a wire, characterized in that the movement in the same direction.
17. The method of claim 16,

    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 first inner mounting portion 322 to be different from each other in the movement direction, characterized in that the solar module (SM) can be installed at the same time in different positions Solar module installation structure using wire.
18. The method of claim 16,

    A pair of tension brackets 900 are coupled to be symmetrical about the intersection CP of the load wire 300, and each tension bracket 900 has a pair of guide plates 910 connected to the rod 920. Coupled to each other to adjust the separation distance, the guide plate 910 is a pair of guide grooves 911 is formed is a wire that is characterized in that the tension is applied by adjusting the distance of the load wire 300 Solar module installation structure using.

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