KR20230032635A - Solar power system using grid frames - Google Patents

Abstract

The present invention relates to an angle-adjustable solar power generation system using a grid frame in which an upper support bar and a lower support bar, in which an upper end and a lower end of a solar panel are connected to an upper rail and a lower rail of the rectangular-shaped grid frame installed on an exterior wall of a building, are connected in parallel with each other such that solar power generation efficiency can be maximized by freely setting an installation angle of the solar panel. According to the present invention, the angle-adjustable solar power generation system using the grid frame comprises: the grid frame composed of a pair of the upper rails provided parallel to each other, a pair of the lower rails provided parallel to each other in a lower part of the upper rails, and a support frame interconnecting the ends of the upper rail and the lower rail to form a rectangular parallelepiped; the upper support bar each coupled to the upper rail at which the both ends face each other; the lower support bar each coupled to the lower rail at which the both ends face each other and provided in parallel with the upper support bar; and the solar panel in which the upper end and the lower end are mounted and fixed on the upper support bar and the lower support bar, respectively. According to the present invention, a horizontal or vertical angle of the solar panel can be easily and conveniently adjusted.

Description

Angle control solar power generation system using grid frame {Solar power system using grid frames}

In the present invention, the upper and lower support bars to which the upper and lower ends of the solar panels are coupled to each other are coupled in parallel to the upper and lower rails of a rectangular parallelepiped grid frame installed on the outer wall of the building, thereby freely setting the installation angle of the solar panels to increase the solar power generation efficiency. It is about an angle control solar power generation system using a grid frame that can be maximized.

Since thermal power generation mainly uses fossil fuels, environmental pollution caused by exhaust gas is serious. In addition, nuclear power generation requires large costs for nuclear waste disposal, there is a concern about environmental pollution, and the scale of damage in the event of a power plant accident is very large.

In recent years, as interest and demand for renewable energy have increased, technologies related to power generation using solar light have been steadily increasing.

For example, there is an increasing trend to install a photovoltaic power generation system in an apartment building and use it as public electricity in the apartment building.

Patent Registration No. 10-1857739 discloses a technique of installing solar panels around windows to avoid interference with windows and doors.

However, the living room is mainly placed in a direction with high solar radiation, and the veranda side of the living room occupies a large portion of the window area. Accordingly, the area of the wall surface excluding windows and doors is narrow, making it impossible to secure a sufficient installation area for the solar panel. In addition, in the case of the lower floor, there is a limit in that power generation efficiency is lowered due to lack of sunlight.

Therefore, it is advantageous to install the photovoltaic power generation system on the sidewall of the main building without windows in order to avoid interference with windows and doors and to increase power generation efficiency by intensively arranging solar panels at appropriate heights.

In addition, Utility Model Registration No. 20-0403768 discloses a technology for installing a solar panel on the outer wall of a building.

Unlike conventional photovoltaic power generation systems that are installed on top of the ground and free to set the direction, the location of the outer wall of the building is determined considering not only the amount of sunlight but also the shape of the site and the circulation, so the direction of the outer wall of the building may not be suitable for maximizing the solar power generation efficiency. can

However, in the prior art, since the angle of the solar panel is fixed, there is a large difference in solar radiation depending on the arrangement of the building, and the power generation efficiency decreases because it cannot cope with the change in solar altitude according to the season.

In addition, a conventional angle-adjustable photovoltaic power generation system such as Utility Model Publication No. 20-2010-0002091 can adjust the angle only in the vertical direction. Accordingly, when the horizontal direction angle is already determined and fixed, such as in the case of an apartment building, power generation efficiency is inevitably lowered.

In order to solve the above problems, the present invention is to provide an angle-adjustable solar power generation system using a grid frame capable of maximizing solar power generation efficiency by freely setting the installation angle of solar panels installed on the outer wall of a building. .

The present invention according to a preferred embodiment is composed of a pair of upper rails provided parallel to each other, a pair of lower rails provided parallel to each other below the upper rails, and a support frame interconnecting the ends of the upper and lower rails, A grid frame forming a rectangular parallelepiped; Upper support bars coupled to upper rails facing each other at both ends; a lower support bar that is coupled to lower rails facing each other at both ends and provided in parallel with the upper support bar; And a solar panel having upper and lower ends mounted on and fixed to the upper support bar and the lower support bar, respectively; It provides an angle control solar power generation system using a grid frame, characterized in that consisting of.

The present invention according to another preferred embodiment provides an angle control solar power generation system using a grid frame, characterized in that the upper support bar and the lower support bar are slidably coupled to the upper rail and the lower rail, respectively.

In the present invention according to another preferred embodiment, one end of the solar panel is provided with a fixed mount rotatably coupled to either one of the upper support bar and the lower support bar, and the other end of the solar panel is provided with an upper support bar and a lower support bar. It provides an angle-adjustable photovoltaic power generation system using a grid frame, characterized in that a movable mount coupled to the other support bar is provided so as to be slidably movable in a direction orthogonal to the other support bar.

In the present invention according to another preferred embodiment, the movable mount is provided at a panel fixing part to which one end of the solar panel is coupled and fixed, and a lower portion of the panel fixing part, and a support bar having slots formed in a direction orthogonal to the other support bar. It provides an angle-adjustable photovoltaic power generation system using a grid frame, characterized in that it is composed of a slider fixed to the coupling portion and the other support bar and slidably coupled to the slot of the support bar coupling portion.

According to the present invention, by coupling both ends of the upper support bar and the lower support bar, to which the upper and lower ends of the solar panel are coupled, respectively, to a pair of parallel upper rails and a pair of lower rails of a grid frame having a rectangular parallelepiped shape, It is possible to provide an angle-adjustable photovoltaic power generation system using a grid frame capable of maximizing photovoltaic power generation efficiency by freely setting an installation angle of a light panel.

In particular, the horizontal or vertical angle of the solar panel can be easily and conveniently adjusted by adjusting the relative positions of both ends of the upper and lower support bars coupled to neighboring upper and lower rails or by adjusting the relative positions of the upper and lower support bars.

1 is a perspective view showing a photovoltaic power generation system of the present invention installed on an outer wall of a building.
2 is a perspective view showing a grid frame in which upper and lower support bars are coupled;
Figure 3 is a perspective view showing a grid frame equipped with a solar panel.
Fig. 4 is a perspective view showing a state in which a plurality of grid frames are connected;
Figure 5 is a perspective view showing a method for adjusting the vertical direction angle of the solar panel.
6 is a perspective view illustrating a method for adjusting the angle of a solar panel in a horizontal direction;
7 is a cross-sectional view illustrating a solar panel when adjusting an angle in a vertical direction.
8 is a perspective view showing an embodiment of a movable mount;

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

1 is a perspective view showing a photovoltaic power generation system of the present invention installed on an outer wall of a building, FIG. 2 is a perspective view showing a grid frame in which upper and lower support bars are coupled, and FIG. 3 is a perspective view showing a grid frame equipped with solar panels. am. And Figure 4 is a perspective view showing a state in which a plurality of grid frames are connected.

As shown in FIGS. 1 to 4, the angle control photovoltaic power generation system using the grid frame of the present invention includes a pair of upper rails 21 provided parallel to each other, and a lower portion of the upper rails 21 that are parallel to each other. a grid frame 2 composed of a pair of lower rails 22 and a support frame 23 interconnecting ends of the upper and lower rails 21 and 22 to form a rectangular parallelepiped; Upper support bars 3 each coupled to the upper rails 21 facing each other at both ends; Lower support bars 4 coupled to lower rails 22 facing each other at both ends and provided in parallel with the upper support bars 3; And a solar panel (5) whose upper and lower ends are mounted on and fixed to the upper support bar (3) and the lower support bar (4), respectively; It is characterized by consisting of.

The present invention is to provide an angle-adjustable photovoltaic power generation system using a grid frame capable of maximizing photovoltaic power generation efficiency by freely setting the installation angle of the solar panel 5 installed on the outer wall of the building (B).

The photovoltaic power generation system 1 includes an upper support bar 3 and a lower support bar 4 inside a grid frame 2 having a rectangular parallelepiped shape, and the upper support bar 3 and the lower support bar 4 The upper and lower ends of the solar panel 5 are respectively mounted and fixed.

The grid frame 2 is installed on the outer wall of a building B such as an apartment house.

The grid frame 2 includes a pair of upper rails 21 disposed in parallel, a pair of lower rails 22 disposed in parallel, adjacent upper rails 21, adjacent lower rails 22, upper and lower It consists of eight support frames 23 interconnecting the ends of the upper and lower rails 21 and 22 adjacent to each other to form a rectangular parallelepiped shape.

Both ends of the upper support bar 3 are coupled to a pair of upper rails 21 facing each other, and both ends of the lower support bar 4 are coupled to a pair of lower rails 22 facing each other.

The upper support bar 3 and the lower support bar 4 are provided parallel to each other so that the solar panel 5 in the form of a flat plate can be mounted and fixed.

The ends of the upper support bar 3 and the lower support bar 4 can be coupled to an arbitrary position of the upper rail 21 and the lower rail 22, respectively.

The upper and lower ends of the solar panel 5 are mounted on and fixed to the upper support bar 3 and the lower support bar 4, respectively.

At this time, the direction of the solar panel 5 is determined according to the relative position where both ends of the upper and lower support bars 3 and 4 are coupled to the upper and lower rails 21 and 22 adjacent to each other.

For example, when the outer wall of the building B faces southwest, the western ends of the upper and lower support bars 3 and 4 are on the outside (south side) of the upper and lower rails 21 and 22, and the eastern ends are on the upper and lower rails 21 and 22. ) By coupling to the inner side (north side) of the solar panel 5 can be configured to be disposed in the south direction.

In addition, the vertical angle of the solar panel 5 may be adjusted by adjusting the relative positions of the upper support bar 3 and the lower support bar 4 .

For example, when the upper support bar 3 is placed on the inside of the lower support bar 4, that is, when the solar panel 5 is disposed in the south direction, the upper support bar 3 is moved to the north side than the lower support bar 4. By disposing at a spaced position, the solar panel 5 can be configured to be inclined upward.

In this way, the upper support bar 3 and the lower support bar 4 are coupled to the upper and lower ends of the solar panel 5, respectively, and the upper and lower support bars 3 and 4 are attached to the grid frame 2 of the rectangular parallelepiped. By combining, the angle of the solar panel 5 can be easily and freely adjusted in both horizontal and vertical directions.

Accordingly, since the solar panel 5 can be disposed facing south, the amount of solar radiation incident on the solar panel 5 can be maximized.

As shown in FIGS. 1 and 4 , a plurality of grid frames 2 may be continuously installed vertically and horizontally according to the number of solar panels 5 .

5 is a perspective view illustrating a method for adjusting an angle of a solar panel in a vertical direction, and FIG. 6 is a perspective view illustrating a method for adjusting an angle in a horizontal direction of a solar panel.

As shown in FIGS. 5 and 6 , the upper support bar 3 and the lower support bar 4 may be slidably coupled to the upper rail 21 and the lower rail 22 , respectively.

The upper support bar 3 and the lower support bar 4 may be fixed at arbitrary positions on the upper rail 21 and the lower rail 22, respectively, depending on the installation angle of the solar panel 5. However, in this case, the seasonal There is a limit to maximizing power generation efficiency because it is difficult to respond to changes in solar altitude.

Therefore, the end of the upper support bar 3 can be slidably coupled along the upper rail 21, and the end of the lower support bar 4 can be slidably coupled along the lower rail 22.

To this end, rail grooves 211 and 221 may be formed in the upper rail 21 and the lower rail 22 along the longitudinal direction, respectively.

Further, at the ends of the upper support bar 3 and the lower support bar 4, guide members 31 and 41 that are inserted into the respective rail grooves 211 and 221 and slide, may be respectively provided.

Therefore, by sliding and parallel moving the upper support bar 3 or the lower support bar 4 on the upper rail 21 or the lower rail 22 according to the change of the season, the angle in the vertical direction of the solar panel 5 can be adjusted. adjustable (Fig. 5).

Alternatively, by moving the other ends of the upper and lower support bars 3 and 4 in a state in which one end of the upper and lower support bars 3 and 4 is fixed according to the direction of the building B, the angle in the horizontal direction of the solar panel 5 is adjusted. adjustable (Fig. 6).

Since both ends of the upper support bar 3 and the lower support bar 4 are coupled to a pair of upper rails 21 and lower rails 22 that are parallel to each other and slide independently, the upper support bar 3 And the lower support bar (4) must be able to change the length.

To this end, the upper support bar 3 and the lower support bar 4 may be configured to be adjustable in length.

The upper support bar 3 and the lower support bar 4 may be configured to slide manually or electrically along the upper rail 21 and the lower rail 22, respectively.

In this case, a working ladder (not shown) for angle adjustment and maintenance of the solar panel 5 may be placed inside the grid frame 2 .

7 is a cross-sectional view illustrating a solar panel when adjusting an angle in a vertical direction.

As shown in FIG. 7, one end of the solar panel 5 is provided with a fixed mount 6 rotatably coupled to either one of the upper support bar 3 and the lower support bar 4, At the other end of the solar panel 5, a movable mount 7 coupled to the other support bar to be slidably movable in a direction orthogonal to the other support bar of the upper support bar 3 and the lower support bar 4 may be provided.

A fixed mount 6 and a movable mount 7 may be provided at one end and the other end of the solar panel 5 .

At this time, the fixed mount 6 is rotatably coupled to any one side support bar of the upper support bar 3 and the lower support bar 4.

And the movable mount 7 is coupled to the other support bar to be able to slide in a direction orthogonal to the other support bar of the upper support bar 3 and the lower support bar 4.

In FIG. 7, one side support bar is shown as a lower support bar 4, and the other side support bar is shown as an upper support bar 3, and will be described based on this.

The upper support bar 3 and the lower support bar 4 are horizontally moved on the X-Y plane, respectively. Therefore, when adjusting the vertical angle of the solar panel 5 by changing the relative positions of the upper and lower support bars 3 and 4, the distance between the upper support bar 3 and the lower support bar 4 must be changed.

Therefore, even when the distance between the upper and lower support bars 3 and 4 is changed to change the vertical angle of the solar panel 5, the solar panel 5 is mounted on the upper and lower support bars 3 and 4 to fix the position. A fixed mount 6 rotatably coupled to the lower support bar 4 may be installed at the lower end of the solar panel 5 so as to be able to do so. In addition, a movable mount 7 coupled to be slidably movable in a direction orthogonal to the upper support bar 3 may be installed at an upper end of the solar panel 5 .

If you want to increase the vertical direction angle of the solar panel 5, that is, if you want to erect the solar panel 5, the distance between the upper support bar 3 and the lower support bar 4 should be narrowed .

In this case, the fixed mount (6) at the bottom of the solar panel (5) rotates upward relative to the lower support bar (4), and the movable mount (7) at the top of the solar panel (5) is slide to the top.

Conversely, if you want to decrease the vertical angle of the solar panel 5, that is, if you want to lay the solar panel 5 down, the distance between the upper support bar 3 and the lower support bar 4 must be increased .

In this case, the fixed mount (6) at the bottom of the solar panel (5) rotates downward with respect to the lower support bar (4), and the movable mount (7) at the top of the solar panel (5) is slide to the bottom.

8 is a perspective view showing an embodiment of a movable mount.

As shown in FIG. 8, the movable mount 7 is provided on the lower part of the panel fixing part 71 to which one end of the solar panel 5 is coupled and fixed, and the panel fixing part 71 on the other side. A support bar coupling part 72 having a slot 721 formed in a direction orthogonal to the support bar and a slider 73 fixed to the other support bar and slidably coupled to the slot 721 of the support bar coupling part 72. can be configured.

The movable mount 7 may be composed of a panel fixing part 71, a support bar coupling part 72, and a slider 73.

The panel fixing part 71 is a part to which one end of the solar panel 5 is coupled.

As shown in FIGS. 7 and 8 , the panel fixing part 71 has a U-shaped cross section with one side open, so that the upper end of the solar panel 5 can be inserted and fixed.

A lower part of the panel fixing part 71 may be provided with a support bar coupling part 72 formed in an L shape.

A long slot 721 is formed in the support bar coupling part 72 in the vertical direction, which is a direction orthogonal to the other support bar.

In the embodiment of FIG. 8, the other support bar is the upper support bar 3, and will be described based on this.

A slider 73 is coupled to the upper support bar 3, which is the other support bar.

The slider 73 is coupled through the slot 721 of the support bar coupling part 72, so that it can slide vertically along the guide of the slot 721.

Accordingly, the movable mount 7 can slide in the vertical direction of the upper support bar 3 .

1: solar power system 2: grid frame
21: upper rail 211: rail groove
22: lower rail 221: rail groove
23: support frame 3: upper support bar
31: guide tool 4: lower support bar
41: guide sphere 5: solar panel
6: fixed mount 7: movable mount
71: panel fixing part 72: support bar coupling part
721: slot 73: slider
B: building

Claims (4)

A pair of upper rails 21 provided parallel to each other, a pair of lower rails 22 provided parallel to each other under the upper rails 21, and ends of the upper and lower rails 21 and 22 are interconnected. A grid frame 2 composed of a support frame 23 to form a rectangular parallelepiped;
Upper support bars 3 coupled to the upper rails 21 facing each other at both ends;
Lower support bars 4, which are coupled to lower rails 22 facing each other at both ends, provided in parallel with the upper support bars 3; and
A solar panel 5 having upper and lower ends mounted on and fixed to the upper support bar 3 and the lower support bar 4, respectively; An angle control solar power generation system using a grid frame, characterized in that consisting of.
In paragraph 1,
The upper support bar 3 and the lower support bar 4 are slidably coupled to the upper rail 21 and the lower rail 22, respectively.
In paragraph 2,
One end of the solar panel 5 is provided with a fixed mount 6 rotatably coupled to either one of the upper support bar 3 and the lower support bar 4, and the other end of the solar panel 5 Angle adjustment using a grid frame, characterized in that a movable mount 7 coupled to the other support bar so as to be slidably movable in a direction orthogonal to the other support bar of the upper support bar 3 and the lower support bar 4 is provided photovoltaic system.
In paragraph 3,
The movable mount 7 is provided at the bottom of the panel fixing part 71 to which one end of the solar panel 5 is coupled and fixed, and the panel fixing part 71, and a slot in a direction orthogonal to the other support bar ( 721) is formed on the support bar coupling part 72 and the slider 73 fixed to the other support bar and slidably coupled to the slot 721 of the support bar coupling part 72 Angle-adjustable solar power generation system using .

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