KR101688493B1 - Structure for solar generator - Google Patents

Abstract

A photovoltaic structure of the present invention comprises: a solar module; a support unit installed in the ground, and supporting the solar module provided in an upper side while separating the solar module from the ground; a connection unit of which one side and the other side are coupled to a pair of the support units, respectively; and a tilting means for enabling the solar module to rotate from the support unit. The solar module includes a plurality of dispersal panels arranged to form two or more rows and columns. The support unit includes a supporting plate for supporting each of the dispersal panels.

Description

{STRUCTURE FOR SOLAR GENERATOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a solar collective power generating structure having a connecting portion interconnecting a plurality of solar modules and minimizing damage such as natural disasters.

More specifically, since the supporting portion for allowing the solar module to be installed on the ground is mutually connected by the connecting portion, the solar module and the supporting portion, which are provided with the other solar modules, can share and disperse the impact, The present invention relates to a photovoltaic power generation structure capable of minimizing damage and damage due to external factors such as natural disasters and the like.

The method of using solar energy is classified into a method using solar heat and a method using sunlight.

The method of using solar heat is a method of supplying hot water and heating by using water heated by sunlight.

In addition, the method using sunlight is called solar power generation by generating electricity using sunlight, and using such electricity to operate various machines and apparatuses.

This solar power generation is a technology that can change the sunlight of direct sunlight to direct electricity without Wuhan, and the power generation using solar energy uses infinite clean energy and requires no additional energy or driving source, This has several simple advantages.

The technology of converting the energy of sunlight into electricity is to use a solar cell, which is provided on a plate-shaped panel for collecting solar energy, and the panel receives the energy to be converged, do.

Recently, a variety of energy generating devices using sunlight have been developed. In particular, tilting means are provided so that the position of the sun, that is, the sun and the panel are kept perpendicular to each other, A technique has been developed that can improve the light collection efficiency of sunlight.

As one of such photovoltaic power generation devices, a photovoltaic power generation device is disclosed in Patent Publication No. 10-1609540.

FIG. 1 is a perspective view of a conventional photovoltaic power generating apparatus, which includes a solar module; A module mounting unit for mounting the solar cell module while supporting both sides of the solar cell module so that the solar cell module is floated; And an external force supporting unit installed at one or more places below the module installation unit inserted in the ground to support the module installation unit from an external force acting in a vertical direction and a horizontal direction of the module installation unit, A pair of module supporting frames spaced apart from each other and supporting both sides of the solar module; A pair of vertical frames having lower ends embedded in the ground and upper ends connected to respective central portions of the pair of module support frames; And a pair of bottom frames connected to a center portion of the vertical frame so as to be perpendicular to each other at a lower end of the vertical frame, Wherein the external force supporting unit comprises a horizontal resistance member of a net structure which is installed vertically between the pair of vertical frames to resist an external force acting along a horizontal direction of the vertical frame; And a vertical resistance member of a net structure installed between the pair of bottom frames so as to be in contact with a ground surface of the ground to resist an external force acting along a vertical direction of the vertical frame; Wherein the horizontal resistance member and the vertical resistance member are formed in the form of a panel in which a plurality of permeable holes are formed and are fastened with bolts, and a reinforcing frame in the form of a lattice is installed so that the overall rigidity is secured.

Such a conventional photovoltaic device can be installed firmly on the ground GM of the ground G while being protected from external force through the external force supporting unit 30 composed of the horizontal resistance member 31 and the vertical resistance member 32 .

However, in the conventional photovoltaic device, since the solar module 10 is formed in a single plate shape and the area contacted with the wind is formed as shown in FIG. 1B, the solar module is severely affected by the wind.

Thus, there is a problem that the solar module 10 supported by the module installation unit 20 to be spaced apart from the ground is shaken due to the influence of the wind, or the supported portion is damaged.

Also, as shown in FIG. 1C, when snow accumulates on the solar module 10 having a wide plate shape, the solar module 10 may fall to the ground due to the load as the amount of accumulated snow increases. There is a problem.

Further, when the solar module 10 has a tilting structure, the coupling force of the mutually coupled portions of the module installation unit 20 and the solar module 10 due to the tilting structure is weaker than the fixed solar module 10 Therefore, as mentioned above, there is a problem that breakage easily occurs due to various natural disasters.

Further, the conventional photovoltaic power generation apparatus has a structure in which the support unit is embedded in the underground, so that it is possible to firmly support one photovoltaic module 10, but in order to install a plurality of photovoltaic modules 10 When the solar modules 10 of the plurality of solar modules 10 collapse due to a natural disaster such as wind or the like, The solar cell module 10 lacks an organic coupling relationship to be held by each other and is not suitable for installing a plurality of solar modules 10.

Patent Registration No. 10-1609540 (Mar. 31, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a solar module and a solar cell module, The present invention is to provide a photovoltaic power generation structure capable of minimizing damage and damage due to external factors such as natural disasters due to an organic coupling relationship such that the support portion shares and disperses the impact and the solar module is more firmly supported .

Another problem to be solved by the present invention is to provide a solar cell module in which a plurality of solar modules are composed of a composite of a dispersion type panel and a support stand for supporting each of the dispersion type panels is separately provided, And more particularly, to a photovoltaic power generation structure capable of minimizing the damage caused by natural disasters.

Another object of the present invention is to provide a photovoltaic power generation structure having a structure in which a plurality of dispersed panels are each lifted and lowered and an inclination angle of each of the dispersion type panels can be adjusted to improve power generation efficiency There is.

According to an aspect of the present invention, there is provided a photovoltaic power generation system comprising: a solar module; A supporting unit installed on the ground to support the solar module provided on the upper side in a state spaced apart from the ground; A connecting portion having one side and the other side coupled to each of the pair of supports; And a tilting means for allowing the solar module to pivot from the support, wherein the solar module comprises a plurality of scattering panels arranged in two or more rows and two or more rows, The present invention provides a solar power generation structure including a support for supporting a solar cell.

The present invention is configured such that the supporting part for allowing the solar module to be installed on the ground is mutually connected by the connecting part so that the solar module and the supporting part provided with the other solar modules share and disperse the impact, , Which has a remarkable effect of minimizing damage and damage due to external factors such as natural disasters and the like.

The present invention is made up of a composite of a plurality of dispersed type solar panels each having a plurality of solar modules and a support stand for supporting each of the dispersed type panels is separately provided so that the areas where the wind contact and the snow accumulate are dispersed and installed more stably It has a remarkable effect that can minimize damage caused by natural disasters.

The present invention has a structure in which a plurality of dispersed type panels are each lifted and lowered, and the inclination angle of each of the dispersion type panels can be adjusted to have a remarkable effect of improving power generation efficiency.

1A is a perspective view showing a conventional photovoltaic device.
FIG. 1B is a view showing an example in which the wind is applied according to FIG. 1A.
Fig. 1C is a view showing an example in which snow is stacked according to Fig. 1A.
2 is a perspective view of a photovoltaic power generation structure according to the present invention.
3 is an exploded perspective view showing a structure of a connection part in a solar cell structure according to the present invention.
4 is an exploded perspective view showing one dispersion type panel in the solar power generation structure according to the present invention.
5 is a view showing an example of the operation of the photovoltaic power generation structure according to the present invention.
6A is a view illustrating an example in which wind is applied to the solar power generating structure according to the present invention.
6B is a view showing an example in which snow is accumulated in the solar power generating structure according to the present invention.
7 is a side view of a photovoltaic power generation structure according to the present invention.
8 is a view showing an example in which the rotation guide is operated in the solar power generating structure according to the present invention.

Advantages and features of embodiments of the present invention and methods of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions in the embodiments of the present invention, which may vary depending on the intention of the user, the intention or the custom of the operator. Therefore, the definition should be based on the contents throughout this specification.

The solar power generating structure according to the present invention is configured such that the supporting part for mounting the solar module on the ground is mutually connected by the connection part so that the solar module and the supporting part provided with the other solar modules share and disperse impact, The present invention relates to a photovoltaic power generation structure capable of minimizing damage and damage due to external factors such as natural disasters and the like.

Hereinafter, a photovoltaic power generation structure according to the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a perspective view of a photovoltaic power generation structure according to the present invention, FIG. 3 is an exploded perspective view illustrating a structure of a connection part in the photovoltaic power generation structure according to the present invention, FIG. FIG. 5 is a view showing an example of the operation of the photovoltaic power generation structure according to the present invention. FIG.

The photovoltaic power generation structure according to the present invention is installed on the ground to generate electric energy by sunlight and includes a solar module 100, a support unit 200, a connection unit 300, and a tilting unit 400 .

The solar module 100 comprises a plurality of dispersion type panels 110 and cells are provided in the respective dispersion type panels 110 to receive sunlight through the cells and convert the power into electric power do.

At this time, each of the dispersion type panels 110 may be fabricated as a dual panel structure or a single-layer panel structure which are stacked in layers.

The dispersive panel 110 is composed of a composite arranged to form two or more rows and two or more rows in one solar module 100, as shown in the accompanying drawings.

Preferably, since conventional solar modules are mainly rectangular in shape, one rectangle may be formed in a dispersed form.

For example, as shown in FIG. 2, one solar module 100 may be composed of nine scattering panels 110, and by dividing the area of the solar module in one plate form, The spaced spaces are formed between the dispersion type panels 110 to reduce wind resistance and to minimize the snow accumulation area so as to reduce the load applied as the snow accumulates so that the dispersion type panel 110 is damaged Can be prevented in advance.

The supporting unit 200 includes a supporting table 210, a plate 220, and a rotating unit 230. The supporting unit 200 supports the solar module 100 installed on the ground and is spaced apart from the ground.

The support 210 supports each of the plurality of dispersion type panels 110 provided in one solar module 100 and is provided on the upper surface of the plate 220 to be described later, Type panel 110 is installed.

At this time, the dispersion type panel 110 provided on the support table 210 is installed in a state in which the dispersion type panel 110 is rotatable by the tilting means 400, which will be described later.

The supports 210 may be formed by coupling a plurality of poles having different sizes in a telescopic manner.

According to the design conditions, the structure of the pole in the photovoltaic power generation structure according to the present invention may be configured in two or more stages according to the purpose of use.

Further, it is needless to say that the height can be adjusted by using a power such as a motor, hydraulic pressure or air.

In addition, the support 210 having a plurality of poles having different sizes may have a larger size of the pole provided on the upper side than the pole provided on the lower side.

That is, the pole may be configured to surround a part of a pole provided on the lower side of the pole, and the length may be varied by a telescopic method.

Accordingly, it is possible to minimize the upward exposure of the gap formed between the pole provided on the upper side and the pole provided on the lower side, and the inflow of foreign matter into the gap can be minimized.

The plate 220 is installed on the ground to support a supporter 210 provided on the upper side and one end or the other end of a connection part 300 to be described later is coupled to the outer side to connect a plurality of plates 220 to each other .

As shown in the accompanying drawings, the plate 220 has a double layer composed of a base plate 221 and a rotation plate 222, and the base plate provided on the lower side is fixed on the ground, The rotary plate 222 provided on the upper side is rotatably connected to the base plate 221 provided on the lower side by the base plate 221 provided on the lower side of the support part 200 and the connection part 300 described later, .

The rotation unit 230 rotates the plate 220 so that the rotation plate 222 provided at the upper side from the foundation plate 221 provided at the lower side is rotated.

It is needless to say that the rotation unit 230 may have any structure as long as the support unit 200 provided on the upper side of the rotation plate 222 can rotate.

The connection unit 300 connects the plurality of solar modules 100 to each other and improves durability by organically connecting the plurality of solar modules 100. The connection unit 300 includes a bracket 310, (320) and a cable (300).

The bracket 310 is connected to the side surface of the base plate 221 by a bolt fastening structure and is formed of a letter "C" having a cross section opened to the outside. The bracket 310 has a coupling hole 311 and a rotary member 312 .

Here, the brackets 310 are provided on both sides of the pair of foundation plates 221, respectively, and are engaged with the respective side ends of the protection guard 320 described later.

At this time, the pair of brackets 310 are formed with coupling holes 311, and the selected one bracket 310 of the pair of brackets 310 may be provided with the rotary member 312.

One bracket 310 of the pair of brackets 310 is provided with a coupling hole 324a formed on the other side of the protective guard 320 to be described later, The other bracket 310 of the pair of brackets 310 without the rotary member 312 is coupled to the protective guards 320 to be described later, And a fastening protrusion 324b formed on the other side is fitted and rotatably coupled.

As shown in the accompanying drawings, when the protective guards 320 are installed, the protective guards 320 are installed between a pair of plates 220, that is, a pair of brackets 310 An intermediate portion of the first protection guard 320a formed of the protection guards 320 is provided in a protruded form and a middle portion of the second protection guard 320b formed of the other pair of the protection guards 320 is provided As shown in Fig.

Thus, a rhombic inner space (not shown) is formed between the first and second protective guards 320a and 320b.

The first protection guard 320a and the second protection guard 320b are coupled to each other by the same coupling structure as the bracket 310 between the pair of brackets 310. As described above, One side of each of the pair of protection guards 320 provided in the protection guard 320a is formed with a fastening hole 324a to be described later and a fastening protrusion 324b is formed on one side thereof, The coupling protrusions 324b formed on the other guard guard 320 are fitted in the coupling holes 324a formed on the other side of the other guard guard 320 so that the pair of guard protrusions 320 are coupled so as to be rotatable relative to each other, The rotation guard 312 is coupled to the coupling hole 311 formed in one bracket 310 and the coupling hole 324a formed on the other side of the protection guard 320, The fastening protrusion 324b is fitted in the coupling hole 311 formed in the other bracket 310, Combine to function.

The first protection guard 320a and the second protection guard 320b formed of a pair of the protection guards 320 are disposed between the pair of plates 220, that is, the pair of the brackets 310, So as to be rotatable.

The protection guard 320 includes a shock absorbing cover 321, a partition wall 322, a fixing protrusion 323, and an auxiliary cover 324, which will be described in detail with reference to the accompanying drawings.

The shock absorbing cover 321 is provided on the outer side of the protective guard 320 and is provided to surround the auxiliary cover 324 to be described later.

As shown in the accompanying drawings, the shock absorbing cover 321 is formed to have a 'C' -shaped cross-section to form a coupling space portion 321a, and the coupling space portion 321a The auxiliary cover 324 to be described later is fitted inside the impact absorbing cover 321.

The partition wall 322 is provided inside the shock absorbing cover 321 and spaced apart from the inner side surface of the shock absorbing cover 321 by a predetermined distance,

The partition wall 322 is formed by dividing a part of the coupling space part 321a formed in the impact absorbing cover 321 and forming a space between the coupling space part 321a and the partition space 322 The space formed by the coupling space portion 321a formed by the two layers and the space formed by the buffer space 322a formed by the two layers, The impact can be absorbed more efficiently by the portion 322a.

Although the rib 322 is illustrated as being spaced apart from the inner surface of the impact absorbing cover 321 in the accompanying drawings, it is also possible to use ribs or ribs connecting the inner side surface of the engagement space 321a and the rib 322 Joints (not shown in the drawings), and the like.

The partition wall 322 is connected to only part of the inner side surface of the shock absorbing cover 321 by the structure of the coupling space 321a and the rib or joint and the remaining part is spaced apart, (322b).

The fixing protrusion 323 is formed at the outer end of the shock absorbing cover 321 and extends to the side facing each other. An auxiliary cover 324 to be described later is inserted into the coupling space portion 321a formed in the impact absorbing cover 321 When fitted, the auxiliary cover 324 is engaged with the fixing protrusion 323 to prevent the auxiliary cover 324 from being released.

The auxiliary cover 324 is provided on the inner side of the protective guard 320 and functions to close the opened portion of the shock absorbing cover 321 by being fitted into the impact absorbing cover 321.

One side of the auxiliary cover 324 is formed with a fastening protrusion 324b to be fitted into the coupling hole 311 formed in the bracket 310 and the other side is formed in a shape corresponding to the coupling hole 311 formed in the bracket 310 And is coupled to the coupling hole 311 by a rotary member 312 fitted to the coupling hole 324a so that the coupling hole 324a is mutually rotatable.

The cable 300 is provided in the coupling space portion 321a formed between the shock absorbing cover 321 and the auxiliary cover 324, that is, in the impact absorbing cover 321, and electrically connects the plurality of supports 200 So that the electric energy generated from the plurality of solar modules 100 is transferred by the cable 300 to be transferred to and stored in a separate electric energy storage device.

Accordingly, the cable 300 for transferring the electric energy is located inside the protection guard 320, minimizing damage due to various external environmental factors, and protecting the life of the cable 300 can be minimized.

The connection part 300 electrically connects the plurality of solar modules 100 and connects the support parts 200 to each other so that the solar modules 100 are installed more firmly than when the plurality of solar modules 100 are installed. The first protection guard 320a and the second protection guard 320b are installed in a rhombic shape and are provided in a rotatable joint shape, so that the effect of relieving impact is excellent.

Thus, damage caused by a safety accident can be minimized.

The tilting means 400 is provided on each of the support rods 210 so that the dispersion type panel 110 provided on the support rods 210 is rotatable and includes the rotation bracket 410, the first cylinder 420, 2 cylinder 430 as shown in FIG.

The rotation bracket 410 allows the dispersion type panel 110 provided on the upper side of the support table 210 to be rotatable. As shown in the accompanying drawings, the rotation type bracket 410 can be formed as a bracket rotatable with respect to each other.

The first cylinder 420 has a variable length so that the dispersion type panel 110 provided on the upper side of the support table 210 is rotatable so that one side of the first cylinder 420 is rotatably coupled to the support table 210, And is rotatably coupled to one side of the panel 110.

The second cylinder 430 performs the same function as the first cylinder 420. One end of the second cylinder 430 is rotatably coupled to the support 210 and the other end of the second cylinder 430 is rotatably coupled to one side of the dispersion panel 110 .

As the lengths of the first cylinder 420 and the second cylinder 430 are changed, the dispersion type panel 110 is rotated around the rotation bracket 410 as an axis.

5, each of the dispersion type panels 110 is movable up and down by a support 210 in which poles having different sizes are telescopically coupled, and the tilting means 400 Each of the dispersion type panels 110 installed above the support table 210 is rotatably provided.

That is, each of the plurality of dispersion type panels 110 arranged so as to form two or more rows and two or more rows may be moved upward and downward to change the position, and may be rotated by the tilting means 400, Favorable conditions can be satisfied.

Further, the plurality of distributed panels 110 will be described in detail through comparison between FIG. 1B and FIG. 6A.

FIG. 1B is a view showing an example in which wind is applied to a conventional photovoltaic device, and FIG. 6A is a view showing an example in which wind is applied to a photovoltaic power generation structure according to the present invention.

As shown in FIG. 1B, since the conventional solar photovoltaic device has a single solar cell module 10, the area of contact with the wind is wide, and the solar cell module 10 is applied to the solar cell module 10 The impact of losing wind is transmitted entirely through the wider area formed.

In other words, the impact of the entire solar module 10 having a single plate shape is limited, and there is a limitation in minimizing the influence of the wind, and the solar module 10 and the module installation unit 20 may be broken.

6A, the photovoltaic power generation structure according to the present invention is formed of a composite of a plurality of dispersed panels 110 having a plurality of solar modules 100 in a plate form, 110, it is possible to disperse an area where the wind is in contact with the dispersion type panel 110, thereby minimizing the impact caused by wind.

Accordingly, the dispersion type panel 110 can be installed more stably on the upper side of the support table 210.

1C, the conventional photovoltaic device includes a solar cell module 10 having a single plate shape, and a solar cell module 10 having a plurality of solar cells, The amount of snow accumulated on the upper side of the solar module 10 is increased, and the load applied to the solar module 10 is increased to cause breakage.

On the other hand, as shown in FIG. 6B, the photovoltaic power generation structure according to the present invention is formed of a composite of the dispersion type panel 110 having a plurality of the solar cell modules 100, The amount of snow accumulated in the optical module 100 can be minimized, so that breakage due to the load applied by the snow can be minimized and more stable installation can be achieved.

Meanwhile, the plurality of dispersion type panels 110 arranged to form two or more rows and two or more rows can be configured to be rotated through the tilting means 400, respectively. However, the plurality of dispersion type panels 110 And the tilting means 400 (see FIG. 4) of the dispersion type panel 110 arranged to form a plurality of rows are arranged in the tilting direction of the tilting means 400 It is possible to minimize the waste of electrical energy for controlling the tilting means 400 of each of the dispersion type panels 110 by rotating the other dispersion type panels 110 together.

Here, the adjacent dispersed panel 110 refers to the dispersed panel 110 disposed adjacent to one side and the other side of the plurality of dispersion type panels 110 arranged to form two or more rows.

Hereinafter, the configuration and operation of the adjacent distributed panel 110 will be described in detail with reference to FIGS. 6 and 7. FIG.

First, it should be noted that overlapping portions of the contents already described in Figs. 2 to 6 have not been described.

FIG. 7 is a side view of a photovoltaic power generation structure according to the present invention, and FIG. 8 is a view illustrating an example in which a rotation guide is operated in the photovoltaic power generation structure according to the present invention.

The rotation guide 500 performs a function of interconnecting the adjacent dispersion type panels 110 among the plurality of dispersion type panels 110 arranged to form two or more rows. The rotation type guide 500 includes the outer side projection 510, the housing 520, And a load 530.

When the dispersion type panel 110 provided on the other side of the adjacent dispersion type panels 110 is rotated and tilted, the rotation type guide 500 may be provided with a dispersion type panel 110 provided on one side of the adjacent dispersion type panels 110, So that it tilts together.

At this time, the dispersion type panel 110 provided on one side of the adjacent dispersion type panels 110 is rotated and tilted, and is lifted by varying the length of the support table 210.

Accordingly, the plurality of dispersion type panels 110 arranged so as to form two or more rows are rotated and inclined so as to have the same angle, and as the dispersion type panel 110 disposed on one side is elevated, It is possible to satisfy the condition of development, and the efficiency is excellent.

The outer protrusion 510 protrudes outward from one side of the dispersion type panel 110 provided at one side of the adjacent dispersion type panel 110 and is formed to be slidable by being inserted into the housing 520 described later.

The housing 520 has a sliding groove 521 and an intermittent hole 522 to guide the outer protrusion 510 to be slidable.

The housing 520 may be configured such that the outer protrusion 510 is fitted, but the fitted outer protrusion 510 is not easily separated, as shown in the accompanying drawings.

For example, the outer diameter of the outer protrusion 510 may be gradually increased toward the housing 520, or the outer end of the outer protrusion 510 may be formed to be larger than the outer diameter of the other portion except for the end, 520, and the intermittent hole 522, so as not to be separated from each other.

The sliding groove 521 provides a space in which the outer protrusion 510 is slid and is provided in the longitudinal direction of the housing 520, that is, on the other side of the adjacent dispersion type panel 110 And has a horizontal direction to the horizontal direction of the dispersion type panel 110.

The intermittent hole 522 communicates with the sliding groove 521 to provide a space in which the outer protrusion 510 is moved through the sliding groove 521 and is seated in the intermittent hole 522. In the figure, The sliding groove 521 is formed at the lower end and the upper end of the other end, respectively.

The rod 530 is extended to the other side of the housing 520 and is fixedly coupled to one side of the dispersion type panel 110 provided on the other side of the adjacent dispersion type panels 110 on the other side.

The solar power generation structure according to the present invention having such a structure is configured such that a plurality of dispersion type panels 110 arranged to form a plurality of rows by the structure of the rotation guide 500 is rotated by the tilting means 400 It can be shared, and there is an advantage that it can be operated efficiently.

For example, referring to FIG. 8, when nine solar modules 100 are provided to have three rows and three rows in the distributed panel 110, The panels 110 are connected to each other by a rotation guide 500.

At this time, when the dispersion type panel 110 provided on the other side of the adjacent dispersion type panels 110 is rotated and tilted, the outer side projection 510 inserted in the housing 520 is moved along the sliding groove 521, The lower side surface of the dispersion panel 110 presses the outer protrusion 510 upward to generate a force for rotating the dispersion type panel 110 provided at one side of the dispersion type panel 110 together.

Accordingly, the dispersion type panel 110 provided on one side of the adjacent dispersion type panels 110 is rotated together, and gradually increases due to the variable length of the support platform 210.

Thereafter, the outer protrusion 510 is guided by the intermittent hole 522 formed at the lower side of one side of the sliding groove 521, and the rotation of the dispersion type panel 110 is stopped.

At this time, the angle formed by the solar module 100 including the plurality of dispersion type panels 110 may be configured to be tilted to about 30 degrees.

This is due to the fact that when the inclination angle of the panel at 30 ° is compared with the angle of the module installation angle and the array spacing in the photovoltaic power generation system of the academic paper (Comparative Researches for Installation of the Module Angles and Array Spacing on Photovoltaic Power System) It is needless to say that the present invention can be configured to have various inclination angles depending on design conditions with reference to a study result that photovoltaic generation is most efficient.

Accordingly, as shown in FIG. 8, the dispersion type panel 110 provided on the other side of the adjacent dispersion type panels 110 is rotated and raised to the upper side, so that the plurality of dispersion type panels 110 are rotated and tilted The power generation efficiency can be improved by making the wide plate shape horizontal.

On the other hand, when the dispersion type panel 110 provided at the other side of the adjacent dispersion type panels 110 is tilted so as to be rotated in the opposite direction and is flattened, the variable type panel 110 is seated in the intermittent hole 522 formed at the lower side of one side of the sliding groove 521 The outer protrusion 510 which has been removed from the intermittent hole 522 moves along the sliding groove 521 so that the upper surface of the sliding groove 521 presses the outer protrusion 510 downward, A force for rotating the dispersion type panel 110 provided at one side of the panel 110 is generated.

Accordingly, the dispersion type panels 110 provided on one side of the adjacent dispersion type panels 110 are rotated together in the horizontal direction, and gradually lowered due to the variable length of the support platform 210.

The outer protrusion 510 is guided by the intermittent hole 522 formed on the upper side of the other side of the sliding groove 521 to stop the rotation of the dispersion type panel 110, Direction.

According to this configuration, the solar power generation structure according to the present invention has a structure in which a plurality of the dispersion type panels 110 are lifted and lowered, and the inclination angle of each of the dispersion type panels 110 can be adjusted, So that it is possible to perform tracking-type power generation for the sun, and the power generation efficiency can be improved.

In addition, since the remaining dispersion type panels 110 are also rotated through the rotation of one dispersion type panel 110 of the plurality of rows of dispersion type panels 110, waste of electric energy can be minimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It can be seen that branch substitution, modification and modification are possible.

100: solar module 110: distributed panel
200: Support part 210: Support part
220: plate 221: base plate
222: rotation plate 230:
300: connection part 310: bracket
311: engaging hole 312: rotating member
320: Protection guard 320a: 1st protection guard
320b: second protection guard 321: shock-absorbing cover
321a: coupling space part 322: partition wall
322a: buffer space part 322b: passage space part
323: fixing protrusion 324: auxiliary cover
324a: fastening hole 324b: fastening projection
330: cable 400: tilting means
410: Rotation bracket 420: First cylinder
430: second cylinder 500: rotation guide
510: outer protrusion 520: housing
521: Sliding groove 522: Intermittent hole
530: Load

Claims (10)

A solar module 100;
A support part 200 installed on the ground to support the solar cell module 100 provided on the upper side in a state spaced apart from the ground;
A connection part 300 having one side and the other side coupled to the pair of support parts 200; And
And a tilting means (400) for allowing the solar module (100) to rotate from the support portion (200)
The photovoltaic module (100)
A plurality of distributed panels (110) arranged to form two or more rows and two or more rows,
The support portion 200
And a support table (210) for supporting each of the dispersion type panels (110)
The connection part 300
A bracket 310 which is formed on the outer side of the support part 200 in a transverse direction and has a cross-sectional shape opened to the outside and has a coupling hole 311;
A protection guard 320 having one side and the other side coupled to a bracket 310 provided on each of the pair of supports 200; And
And a cable (300) provided in a space formed inside the protective guards and electrically connecting the plurality of solar modules (100).
The method according to claim 1,
The support portion 200
A support table 210 supporting each of the dispersion type panels 110;
A plate 220 installed on the ground to support a supporter 210 provided on the upper side; And
And a rotation unit (230) for rotating the plate (220).
The method according to claim 1,
The support base 210
Characterized in that the poles of different sizes are coupled in a telescopic manner.
delete The method according to claim 1,
An intermediate portion of the first protection guard 320a made of a pair of the protection guards 320 is installed between the pair of brackets 310 so as to protrude to one side and the other pair of the protection guards 320 A middle portion of the second protection guard 320b is protruded to the other side so that a rhombic inner space is formed between the first protection guard 320a and the second protection guard 320b Photovoltaic structures.
The method of claim 5,
One side of each of the pair of protection guards 320 provided in the first protection guard 320a is formed with a coupling hole 324a and a side of which is formed with a coupling protrusion 324b, And a pair of protection guards 320 are coupled to each other so as to be rotatable between the pair of protection guards 324a formed on the other side of the one protection guard 320. The one protection guard 320 The rotary member 312 is fitted to the coupling hole 311 formed in one of the pair of brackets 310 and is rotatably engaged with the coupling hole 314 formed on the other side of the bracket 310, A fastening protrusion 324b formed at one side of the guard 320 is inserted into a coupling hole 311 formed in the other bracket 310 and is coupled so as to be rotatable,
The second protective guard 320b
Is coupled to the bracket (310) by the same coupling structure as the first protective guard (320a).
The method according to claim 1,
The protective guard 320
A shock absorbing cover 321 formed on the outer side of the protective guard 320 and having a U-shaped cross section with a side opened to form a coupling space 321a;
A partition wall 322 provided inside the shock absorbing cover 321;
A fixing protrusion 323 extending from the outer end of the shock-absorbing cover 321 to the side opposite to the fixing protrusion 323; And
Is formed on the inner side of the protective guard 320 and has a U-shaped cross-section having a side opened. The shock absorbing cover 321 is inserted into the coupling space portion 321a formed in the impact absorbing cover 321, And an auxiliary cover (324) for finishing the opened portion of the first cover (321)
The shock-absorbing cover 321
The partition wall 322 is formed on the inner side surface of the partition wall 322 so as to be spaced apart from the partition wall 322 by a space defined by the coupling space portion 321a and the space 321a and the partition wall 322. [ A space formed by the cushioning space portion 322a is formed,
And a passage space part (322b) communicating between the space formed by the coupling space part (321a) and the space formed by the buffer space part (322a) is formed.
The method according to claim 1,
The tilting means (400)
A rotating bracket 410 for rotating the dispersion type panel 110 provided on the upper side of the support table 210;
A first cylinder 420 rotatably coupled to the supporter 210 at one side and coupled to one side of the dispersion panel 110 at the other side; And
And a second cylinder 430 coupled to the supporter 210 to be rotatable on one side and coupled to the other side of the dispersion panel 110,
Wherein the dispersion type panel (110) is pivoted about the pivot bracket (410) as the lengths of the first cylinder (420) and the second cylinder (430) are changed.
The method according to claim 1,
And a rotation guide (500) for interconnecting adjacent dispersion type panels (110) among the plurality of dispersion type panels (110) arranged to form two or more rows,
The rotation guide 500
An outer protrusion 510 protruding outward at one side of the dispersion type panel 110 provided at one side of the adjacent dispersion type panels 110;
A housing 520 to which the outer protrusion 510 is slidably fitted; And
And a rod 530 extending from the other side of the housing 520 and coupled to one side of the dispersion type panel 110 provided on the other side of the adjacent dispersion type panels 110 on the other side Wherein the solar cell structure is a solar cell.
The method of claim 9,
The housing 520
A sliding groove 521 for providing a space in which the outer protrusion 510 is slidable; And
And an intermittent hole (522) communicating with the sliding groove (521) and formed on one lower side and the other side upper side of the sliding groove (521), respectively.

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