KR20120084280A - Solar panel tilting mechanism - Google Patents

Abstract

PURPOSE: A solar panel tilting mechanism is provided to maximize power generation efficiency by easily and periodically controlling an angle of a solar panel. CONSTITUTION: A hinge shaft is installed to be parallel to east and west directions in an upright stand(14). A first rotation hinge(24) combined with the hinge shaft is attached to the back side center of a solar panel(20). Angle/date graduation marks in which a date when sunlight meets at right angle is marked are displayed on a first rotation hinge. A second rotation hinge(26) is attached to an upper end portion of the solar panel. A turnbuckle(30) connects the first and second rotation hinges and controls the length between two points.

Description

SOLAR PANEL TILTING MECHANISM

The present invention relates to an angle control device of a solar panel, which is a main part of a solar generator, and more particularly, to easily grasp the angle of a solar panel that can maximize power generation efficiency in response to an altitude change according to the season of the sun. And it relates to a solar panel angle control device that can be quickly adjusted.

Photovoltaic power generation is a power generation system that produces electricity by converting photovoltaic energy into electric current using panels attached with solar cells. The characteristic of this power generation is that it uses semi-permanent solar cells for easy maintenance and repair, and it uses a pollution-free solar energy source. However, photovoltaic power generation uses solar light as an energy source, so maintaining the angle at which the solar panel is orthogonal to the irradiation direction of the solar light, that is, the maximum amount of light received by the solar light can maximize the amount of power generated. As a result, techniques and ideas for achieving this have been constantly developed and proposed.

The patent US 8,042,337 B2 proposes to maximize the generation of energy by sunlight by tracking the sun in real time using the power of a turbine driven by steam generated by the solar heat collecting device, another patent US 7,705,277 B2 proposes to maximize the generation of electricity by tracking the sun in real time using the rotational drive with the sun's position pre-programmed using the electricity generated by the solar cell as the driving force.

Nevertheless, most of the devices that automatically track sunlight in real time are very complicated in structure, so the cost of manufacturing, operating and repairing the device is higher than the cost of installing additional fixed solar panels. Since it is not adopted during the construction of the solar power plant, there is a problem that cannot further improve the power generation of the solar panel.

The present invention is to solve the above problems, an embodiment of the present invention, by easily adjusting the angle of the solar panel periodically to be orthogonal to the direction of irradiation of the sun, which changes according to the season, the latitude of the region Compared to the stationary solar panel set to be, the task is to increase the annual power generation by about 3.0%.

According to an embodiment of the present invention for solving the above problems, the hinge shaft is installed horizontally in the east-west direction and upright to the ground; A rotating hinge coupled to the hinge axis is attached to the center of the rear surface, and the rotation hinge is marked with an angle / date grid that displays the date of the solar light orthogonally considering the angle of the solar panel and the latitude of the region. A solar panel having a rotating hinge for connecting with a turnbuckle capable of adjusting a length of the ground; The ground and the solar panel is connected to the turnbuckle or sliding device that can adjust the length between the two points, or an electric actuator is installed, characterized in that the angle of inclination of the solar panel can be adjusted from time to time or periodically.

According to the preferred embodiment of the present invention as described above, first, since the rotary hinge is installed at the center of the rear surface corresponding to the center of gravity of the solar panel, the rotational reciprocating motion for adjusting the inclination angle of the solar panel is very easy. Therefore, when the turnbuckle connecting the solar panel and the ground, the sliding device or the electric actuator is operated, accurate and easy length adjustment is possible, and as a result, the tilt angle of the solar panel can be precisely and easily adjusted.

Second, using the angle / date grid marked on the rotating hinge can immediately check and change the solar altitude and the angle of inclination orthogonal to the date without a separate measuring device, that is, a level meter and a protractor.

Third, when the angle of inclination of the solar panel is adjusted once a day by using the angle / date grid, the annual power generation amount is increased by about 3.0% compared to the fixed solar panel, and the inclination angle of the solar panel is increased in the same manner. Even if adjusted once a month, the annual output increases by about 2.7%.

Fourth, since the angle of the solar panel approaches the vertical direction in winter, for example, in the case of Seoul, the perpendicular angle of the solar panel increases by 61 degrees in December. In addition, the natural snow-removal function of the snow accumulated on the solar panel is greatly improved, and the amount of sunlight received is increased by up to 9%, which also improves the function of thawing it in the case of frost or snow accumulated on the solar panel. do. As a result, compared to the fixed solar panel, the possibility of winter power generation increases as the installation location of the solar panel moves away from the equator toward the south and north poles, thereby increasing the amount of winter power generation.

1 is a perspective view according to an embodiment of the present invention
FIG. 2 is a perspective view of FIG. 1 rotated 90 degrees counterclockwise;
3 is an exploded view of FIG.
4 is a right side view according to an embodiment of the present invention;
5 is a detail view of 100 portion of FIG.
6 is a perspective view of the electric actuator is mounted
7 is a perspective view of the sliding device is mounted
FIG. 8 is a detailed view of 200 portion of FIG. 7
Figure 9a is a simplified side view when not
9B is a side view of the vernal equinox at the time of the vernal equinox
Figure 9c is a simplified side view at winter solstice
10 shows data table A
11 is a data table B

Hereinafter, a preferred embodiment of the solar panel angle adjustment device according to the present invention will be described with the accompanying drawings. In this process, the lines or components shown in the drawings may be exaggerated or omitted for clarity or convenience of description.

1 is a perspective view of a preferred embodiment of the solar panel angle adjustment device according to the present invention, Figure 2 is a view rotated 90 degrees counterclockwise, Figure 3 is an exploded view of FIG.

As illustrated in FIG. 3, the solar cell angle adjusting device according to the present invention includes an upright support 12 mounted with a hinge shaft 10 horizontally in an affective direction and an solar cell module in which a plurality of solar cell modules are combined. The battery panel 20 is coupled to the hinge shaft 10 by two rotary hinges 22 installed at the lower center thereof, and is installed at the rotary hinge 26 and the base portion installed at the lower upper portion of the solar panel 20. Rotating hinge 14 is connected to the turnbuckle 30 is adjustable in length and is configured in a mutually coupled form.

According to FIG. 4, the length of the turnbuckle 30 increases or decreases according to the direction of rotation, so that the inclination angle of the combined solar cell panel 20 can be arbitrarily adjusted and fixed.

FIG. 5 is a detailed view of the dotted line 100 of FIG. 4, in which a horizontal indicator line 16 is displayed at one side of the rotary shaft 10 and a solar cell panel 30 is provided at the side of the rotary hinge 22. An angle / date grid 24 is shown which indicates the angle of inclination of and the orthogonal angle of sunlight by date in the region. Therefore, when the length of the horizontal indicator line 16 is rotated by turning the turnbuckle 30 to horizontally indicate the corresponding date of the angle / date grid 24, the solar panel 20 noon of the corresponding date. For example, it is possible to maintain a state in which the light receiving amount of sunlight is at a maximum by being adjusted at an angle perpendicular to the sun.

The angle / date grid 24 of FIG. 5 may be displayed in the appropriate range and interval taking into account the latitude of the region from -23.5 degrees to 90 degrees in the case of angles, and in the case of dates, the same date as June 21 It is possible to adjust the angle of the solar panel at a desired period by displaying the month 22, monthly or weekly divided by 22 days.

6 is a solar panel angle adjustment device, characterized in that to operate the solar panel 20 by mounting the electric actuator 40 in place of the manual turnbuckle (30). By doing so, it is possible to remotely control the solar panel angle control device, or to control more than one solar panel angle control device at the same time.

FIG. 7 is a solar cell in which a sliding structure is composed of two square steel pipes 50 capable of reciprocating in an inserted form and a latch 54 and a hole 53 for the latch 53 instead of the turnbuckle 30. The panel angle adjustment device is shown. The sliding structure described above only illustrates the square steel pipe 50, and there is no limitation in the shape as long as it can perform a function of adjusting the length by combining with the solar cell panel.

In FIG. 8, in the inner square steel pipe 51 of the square steel pipe 50, a total of seven latch holes 53 are disposed at positions corresponding to the solar irradiation direction and the orthogonal angle on the 21st or 22nd of every month. Formed, the outer square steel pipe 52 is characterized by being able to adjust and fix the angle once a month by forming a hole through which the latch 54 can penetrate.

In the date notation 56 of the lower or upper portion of the seven clamp holes 53, the corresponding date of the monthly orthogonal angle is indicated. The first hole from the top is 6/21 days, and the second is 5/21 and 7 / 21, the third is 4/21 and 8/22, the fourth is 3/21 and 9/22, the fifth is 2/21 and 10/22, the sixth is 1/21 and 11/22, the seventh is Writing 12/22 is an example of a preferred implementation.

As illustrated in FIGS. 7 and 8, the angle of the solar panel angle adjusting device combined with the sliding structure is faster and faster than the turnbuckle 30 described with reference to FIGS. 2 and 3 and 5. It may be suitable for applications that require more structural strength, such as once-monthly adjustments or areas where strong winds or tornadoes occur frequently.

FIG. 9A is a side view of a solar panel orthogonal to the altitude of the sun at midday (June 21) around Seoul as a reference drawing, and the solar panel tilt angle P3 at this time is the latitude of the region (37.5 degrees). Is 14 degrees minus the Earth's axis of rotation (23.5 degrees).

FIG. 9B is a side view illustrating the altitude of the sun and solar panels orthogonally intersecting the spring equinox (March 21) and Chuchu (September 22) at noon around Seoul as a reference drawing, and the inclination angle of the solar panel at this time P2 is the latitude of 23.5 degrees.

FIG. 9C is a side view illustrating solar altitudes orthogonal to the altitude of the sun at 12 noon (December 22), and the solar panel inclination angle P1 at the local latitude (37.5 degrees) as a reference drawing. This is 61 degrees plus the Earth's rotation axis angle (23.5 degrees).

10 is a data table A, in which the inclination angle of the solar panel 20 is adjusted to be orthogonal to the solar irradiation direction once a day, and the universal fixed solar panel is installed with the inclination angle fixed at the latitude of the region. Compared to the method, the difference in the amount of received light was compared between September 22, which is the autumnal season, and December 22, which is the winter solstice, and the sum divided by 91 days is 2.98% (about 3%). That is the difference in annual power generation.

In FIG. 10, the formula of the difference in received light amount is {1 / COS (difference angle of the corresponding date) −1} × 100%.

11 is a data table B, in which the inclination angle of the solar panel 20 is orthogonal to the solar irradiation direction only once every 21 or 22 days of the month, and the inclination angle of the corresponding region is set and installed. Compared to the conventional fixed solar panel method, the difference in the amount of received light is compared between September 22 and December 22, which is the autumnal sum, and the sum divided by 91 days is 2.67% (about 2.7%). This is the difference in annual power generation.

In FIG. 11, the formula of the difference in the received light amount is {1 / COS (difference angle of the corresponding date)-1 / COS (23.5 degrees-difference angle of the corresponding date)} X 100%.

The definition of the difference angle in FIG. 10 and FIG. 11 means the difference between the inclination angle of the fixed solar panel and the inclination angle of the solar panel, which changes daily according to the present invention.

The reason for comparing only from September 22, which is the autumnal period in FIG. 10 and FIG. 11, to December 22, which is the winter solstice. This is because it is repeated four times as a unit.

10: hinge axis 12: upright support
14: Rotating Hinge 16: Horizontal Leader
18: hinge stopper 20: solar panel
22: Angle / date grid 24: Rotating hinge
26: rotating hinge 30: turnbuckle
40: electric actuator 50: square steel pipe
51: inner square steel pipe 52: outer square steel pipe
53: brace hole 54: brace
56: date notation 100: detail of FIG. 5 in the range
200: range of FIG. 8 in detail

Claims (3)

Hinge shaft 10 is installed horizontally in the east-west direction, the upright support 14 perpendicular to the ground;
A rotating hinge 24 coupled to the hinge shaft 10 is attached to the center of the rear surface, and the rotating hinge 24 has solar light orthogonal in view of the angle of the solar panel 20 and the latitude of the region. A solar panel 20 having a rotating hinge 26 for connecting with a turnbuckle 30 capable of adjusting a length with the ground, and an angle / date scale table 22 having a date displayed thereon;
Solar panel angle adjustment device is characterized in that the turn hinge 30 is connected to the rotating hinge 14 of the ground base portion and the rotating hinge 26 of the solar panel 20 and adjust the length between the two points . The method of claim 1,
In place of the turnbuckle (30), by installing an electric actuator (40), the solar panel angle adjustment device, characterized in that at least one solar panel angle control device can be remotely controlled at the same time. The method of claim 1,
In place of the turnbuckle 30, a sliding structure consisting of two square steel pipes 50, an brace 54, a brace hole 53, and a date mark 56, which can be reciprocated in an inserted form, Solar panel angle adjustment device characterized in that coupled.

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