KR101035388B1 - A solar structure possible angle-adjustment - Google Patents

Abstract

PURPOSE: An angle-adjustable solar structure is provided to enhance the efficiency of solar generation since the structure is controlled to have optimal angles depending on solar altitude. CONSTITUTION: An angle-adjustable solar structure comprises fixed frames(110), inclined frames(120), support frames(150) and angle control members(160). The solar structure further comprises rotating bars(170) and a plurality of solar cell modules(140). The fixed frames are fixed to the ground surface at regular intervals. The fixed frame supports an upper part. The inclined frames are fixed to the upper ends of the fixed frames. The inclined frames have given curvatures at regular intervals and are fixed in a round shape. The support frames have given intervals perpendicularly to the inclined frames. The angle control member is formed on the support frame. The angle control member can be angle-controlled to a plurality of steps.

Description

Solar structure possible angle-adjustment

The present invention relates to a solar structure, and more particularly to a solar structure capable of adjusting the angle to improve the efficiency of photovoltaic power generation.

In general, widely used fossil energy is limited in amount, and sometime it is exhausted and emits various pollutants, so most countries are developing alternative energy that can be used instead.

There are many kinds of energy that can replace fossil energy, tidal wave to generate energy using tidal difference, wave power to generate energy using waves, wind power to generate energy using wind power, And there is geothermal heat that generates energy using heat in the ground, and there is solar energy that is the source of these energy.

The use of these various alternative energy has been practically used, and one of them is the use of solar energy for power generation and heating.

The method of using solar energy is largely divided into a method using solar heat and a method using solar light. The method of using solar heat is to heat and generate electricity using water heated by the sun, and the method of using solar power generates electricity using the light of the sun so that various kinds of machines and appliances can be operated by this electricity. It is called solar power.

Among them, photovoltaic power generation is to convert the light energy of the sun directly into electrical energy using a photoelectric converter called a solar cell. It is a system-connected type that connects the generated electricity to the power grid and sends it to the power supply company, and sells the surplus electricity to the power company. It is distinguished, and it can be used even on a cloudy day because it uses light in part, so the use efficiency of solar energy is higher than that of solar power generation.

Since the solar power generation uses unlimited, non-polluting solar energy, fuel costs are unnecessary, there is no air pollution or waste generation, and since the power generation part is a semiconductor device and the control unit is an electronic component, there is no mechanical vibration and noise.

In addition, the solar cell has a long life of at least 20 years, easy to automate the power generation system, and has the advantage of minimizing the cost of operation and maintenance.

The solar cell used for the photovoltaic power generation, as described above, serves to convert the solar energy into electrical energy, usually silicon and a composite material is used. Specifically, the solar cell is used by bonding a P-type semiconductor and an N-type semiconductor to use a photoelectric effect of producing electricity by receiving sunlight.

Most solar cells consist of a large area P-N junction diode, and the electromotive force generated at the anode end of the P-N junction diode is connected to an external circuit.

The minimum unit of such a solar cell is called a cell, and in practice, the solar cell is rarely used as it is. Since the voltage required for actual use is more than a few tens or hundreds of volts, the voltage from one cell is about 0.5V, which is very small. Therefore, multiple unit solar cells can be connected in series or in parallel to the required unit capacity. Doing.

In addition, when the solar cell is used outdoors, it may be subjected to various harsh environments, so that a plurality of cells may be packaged as a solar cell module in order to protect a plurality of cells connected to a required unit capacity in a harsh environment. Configure and use.

However, since the solar cell module has to be used in large quantities to obtain a constant power, there is a limitation in the installation place. That is, the solar cell module does not have any problem when installed on the roof of the building or outdoor facilities, but when installed in a multi-unit housing that occupies a large number of houses, there is a problem that individual installation in the household is difficult.

In addition, due to the characteristics of the photovoltaic power generation system having a change in efficiency according to the angle of solar light, the solar cell module should be installed on the roof of a building, a roof, or a separately set prop.

However, the above-described solar cell structure according to the prior art has a structure in which a frame and another frame are coupled to each other by using a bracket, so that when a strong wind is blown or a large impact is applied, the screw fixing the bracket is loosened or the bracket is bent. As a result, the frame structure is distorted, and there is a problem in that the frame is severely dropped out of the solar cell module.

In addition, it has a change in power generation efficiency according to the angle of sunlight, because it is fixed type, it does not effectively cope with the domestic situation where the four seasons are distinct and there are altitude differences by region.

The present invention is to solve the conventional problems as described above to provide a photovoltaic structure capable of adjusting the angle to improve the efficiency of photovoltaic power generation by arbitrarily adjusting the angle of the solar cell module according to the altitude difference by region. have.

Solar structure capable of adjusting the angle according to the present invention for achieving the above object is fixed to the ground and fixed to the ground at a constant interval, and is fixed while having a constant interval on the top of the fixed frame An inclination frame, a support frame connected to an upper end of the inclination frame at regular intervals in a direction perpendicular to the inclination frame, an angle adjustment member configured on the support frame and capable of angle adjustment in a plurality of steps; Rotating bar coupled to the angle adjusting member is rotated, and comprises a plurality of solar cell modules arranged at regular intervals on the rotating bar, the angle adjusting member is configured to have a rotation hole corresponding to each other with a constant interval A first fixing plate and a second fixing plate, and a plurality of adjacent fixing plates A movable plate having a positive hole, a fixing slot formed in a predetermined region of the second fixing plate, and a fixing member inserted into and fixed between the fixing slot of the second fixing plate and the fixing hole of the movable plate. Characterized in that the made up.

Photovoltaic structure capable of adjusting the angle according to the present invention has the following effects.

First, it is possible to maximize the efficiency of photovoltaic power generation by adjusting the optimum angle of solar radiation and the optimal angle according to the season and installation location by allowing the optimum angle to be adjusted according to the altitude of sunlight.

Second, by constructing a structure supporting the solar cell module in a round shape it can give a visual beauty with a stable structure.

Third, the base frame on which the solar cell module is mounted is formed in a round structure to reduce the weight of the entire structure by 40% so that it has a light weight structure. Can reduce the construction period.

1 to 3 is a side view, a front view and a rear view schematically showing a solar structure capable of adjusting the angle according to the present invention
Figure 4 is a perspective view showing the outer shape before the solar cell module is installed in the angle adjustable solar structure according to the present invention
5 is an enlarged view of a portion “A” of FIG. 1;
6 and 7 are enlarged views of portions “B” and “C” of FIG. 4.
8 is an enlarged view of a portion “D” of FIG. 1;

Hereinafter, with reference to the accompanying drawings will be described in more detail a solar structure capable of adjusting the angle according to the present invention.

1 to 3 is a side view, a front view and a rear view schematically showing a solar structure capable of adjusting the angle according to the present invention, Figure 4 is a solar cell module installed in the angle adjustable solar structure according to the present invention 5 is an enlarged view of portion "A" of FIG. 1, and FIGS. 6 and 7 are enlarged views of portions "B" and "C" of FIG. 4, and FIG. 8. Is an enlarged view of a portion “D” of FIG. 1.

1 to 8, the angle adjustable solar structure according to the present invention, the fixed frame 110, the inclined frame 120, the strength reinforcement frame 130, the solar cell module 140, support It is configured to include a frame 150, the angle adjustment member 160 and the rotation bar 170.

The fixing frame 110 is formed in a cylindrical structure at regular intervals in one direction to be fixed to the ground and to support the upper portion.

Meanwhile, although the configuration of the fixing frame 110 in a cylindrical shape is described, the present invention is not limited thereto and may be formed in various shapes such as a rectangular structure.

A first support plate 111 having a rectangular plate shape is formed at an end portion of the fixing frame 110 fixed to the ground of the fixing frame 110 to be wider than the cross-sectional area of the fixing frame 110.

A plurality of ribs 112 are integrally formed on the upper surface of the first support plate 111 at regular intervals so that the fixing frame 110 can be more firmly fixed to the ground.

The fixed frame 110 has a different length of the front end and the rear end, that is, the fixed frame 110 of the front end is lower than the fixed frame 110 of the rear end so that the solar cell module 140 receives more sunlight. Is formed to have a predetermined inclination angle when the solar cell module 140 is installed.

Here, the first support plate 111 is described in a rectangular plate shape, but the present invention is not limited thereto, and the first support plate 111 may be integrally formed in the fixed frame 110 in a disc or polygonal shape.

Meanwhile, a second support plate 113 having a rectangular plate shape is formed at an end portion of the fixed frame 110 connected to the inclined frame 120 to have a larger cross-sectional area of the fixed frame 110. Here, the second support plate 113 is configured to have a constant inclination.

The fixing plate 114 is formed on the second support plate 113 to protrude upward and at regular intervals and the inclined frame 120 is fixed thereon.

Here, a groove is formed on the upper surface of the fixing plate 114 while having a predetermined curvature, and the inclined frame 120 is inserted between the grooves to fix it more securely.

The inclined frame 120 is fixed to the upper end of the fixed frame 110 is fixed to the ground, each is fixed, and has a constant curvature is formed in a round shape.

Here, the inclined frame 120 may be formed in a round shape to reduce about 40% of the weight of the entire structure. Therefore, by making the structure to have a light weight structure as a whole, it is possible to reduce the construction cost due to installation cost and installation without requiring structural reinforcement by own weight when installing on the roof.

In addition, the inclined frame 120 may be used by connecting a plurality of frames in series to produce more energy. In other words, the standardized structure can be assembled in two stages, three stages in series or in parallel to produce more energy.

The strength reinforcing frame 130 serves to fix while connecting between the fixing frame 110 adjacent to the lower side than the inclined frame 120.

That is, while one side of the strength reinforcing frame 130 is connected to the upper end of the fixing frame 110, the other side is connected to the lower end of the neighboring fixing frame 110 while supporting between the fixing frame 110.

On the other hand, the strength reinforcement frame 130 is connected to the fixed frame 110 of the neighboring both sides and is also connected to the front and rear fixed frame 110.

Both ends of the auxiliary frame 130 are connected and fixed to the upper or lower end of the fixing member 110 through a link plate means 131, respectively.

The support frame 150 is formed to protrude at a predetermined interval on the upper side of the inclined frame 120, the first, second fixing the angle adjusting member 160 on the upper side of the support frame 150 Two coupling plates 151 and 152 are formed to have a wider width than the support frame 150.

Here, the first coupling plate 151 is formed on the support frame 150, the second coupling plate 152 is formed under the angle adjustment member 160. Although not shown in the drawing, the first and second coupling plates 151 and 152 are fixed by bolt nut fastening.

The angle adjusting member 160 is fixed to a plurality of first and second fixing plates 161 and 162 and the second fixing plate 162 adjacent to the second fixing plate 162 and the rotating holes 163 to correspond to each other at regular intervals. The movable plate 164 which has the hole 165 is formed.

The second fixing plate 162 has a fixing slot 166 is formed to correspond to the plurality of fixing holes 165 formed in the movable plate 164. Here, the position of the fixing hole 165 corresponding to the fixing slot 166 is changed by the operation of the movable plate 164.

When the fixing slot 166 of the second fixing plate 162 and the fixing hole 165 of the movable plate 164 correspond to each other, a fixing member (not shown) is inserted and fixed therebetween.

A rotation bar 170 is formed in one direction with a rotation shaft 171 inserted and rotated between the rotation holes 163.

A plurality of module support bars 172 are formed on the rotation bar 170 at a predetermined interval in a direction perpendicular to the rotation bar 170, and the solar cell module 140 on the module support bar 172. Is seated and fixed.

Here, when installing the plurality of solar cell module 140 has a stable structure by installing a space for use as a wind passage and foreign matter dropping passage having a predetermined interval between the solar cell module 140 and the solar cell module 140. In addition, the foreign matter can be easily removed.

Including at least one communication means (not shown), solar radiation sensor (not shown), CO ₂ measuring sensor (not shown), temperature and humidity sensor (not shown), including the solar cell module 140 (Not shown) and a wind direction wind speed sensor (not shown) are provided, and the communication means delivers the information measured from each sensor to the outside in real time.

In addition, by installing at least one GPS receiver (not shown) in the angle-adjustable solar structure according to the present invention to quickly determine the exact position of the solar structure in the region where the defect occurs outside quickly It can respond.

On the other hand, although not shown in the drawing, by forming at least one lightning rod on the upper side of the solar structure can prevent accidents such as lightning strike in advance.

The solar controllable angle structure according to the present invention configured as described above can facilitate the adjustment of the optimal angle according to the season and the installation site 33 degrees solar radiation optimal angle in any season or any region.

That is, the angle adjustable solar structure according to the present invention constitutes an angle adjusting member 160, the angle adjusting member 160 is possible to adjust the angle in 15 steps from 12 degrees to 43 degrees, the movable plate ( The angle can be freely adjusted through the fixing hole 165 formed in the 164 and the fixing slot 166 formed in the second fixing plate 162.

Here, one fixing slot 166 is formed, and 15 fixing holes 165 are formed, so that the angle can be adjusted up to 15 steps in total.

When the movable plate 164 is arbitrarily rotated, the position of the fixing hole 165 corresponding to the fixing slot 166 is changed. Accordingly, the rotation bar 170 rotates at a predetermined angle, thereby supporting the module support bar 172. The angle of the solar cell module 140 fixed to the will be changed.

Meanwhile, although the fixing hole 165 is formed in the movable plate 164 and the fixing slot 166 is formed in the second fixing plate 162 in the embodiment of the present invention, the second fixing is not limited thereto. A plurality of fixing holes may be formed in the plate 162 and a fixing slot may be formed in the movable plate 164.

Therefore, the angle adjustable photovoltaic structure according to the present invention can maximize the power generation efficiency of photovoltaic power while maintaining the optimum angle according to the region, season, location to be installed.

On the other hand, the present invention described above is not limited to the above-described embodiment and the accompanying drawings, it is possible that various substitutions, modifications and changes within the scope without departing from the technical spirit of the present invention It will be apparent to those skilled in the art.

110: fixed frame 120: inclined frame
130: strength reinforcement frame 140: solar cell module
150: support frame 160: angle adjustment member
170: rotating bar

Claims (10)

A fixed frame which is fixed to the ground at regular intervals and supports the top,
An inclined frame fixed at a round shape with a predetermined curvature while having a predetermined gap on an upper end of the fixed frame;
A support frame configured to be connected to the upper end of the inclined frame at regular intervals in a direction perpendicular to the inclined frame;
An angle adjustment member configured on the support frame and capable of angle adjustment in a plurality of steps;
A rotation bar coupled to the angle adjusting member to rotate;
Comprising a plurality of solar cell modules arranged at regular intervals on the rotation bar,
The angle adjusting member may include first and second fixing plates configured to have rotation holes corresponding to each other at regular intervals, a movable plate having a plurality of fixing holes adjacent to the second fixing plate, and the second fixing plate. The fixed slot formed in a predetermined region of the, and the fixed slot of the second fixing plate and the fixing hole of the movable plate, the fixing member is inserted between them to fix the aspect, characterized in that made of Optical structures. According to claim 1, Angle adjustable solar structure further comprises a strength reinforcement frame for connecting and fixing between the fixing frame adjacent to the lower side than the inclined frame. According to claim 1, wherein the fixed frame is an angle adjustable solar structure, characterized in that the length of the front end and the rear end is configured differently. The support frame of claim 1, wherein the support frame is formed to protrude at regular intervals on an upper side of the inclined frame, and the first and second coupling plates for fixing the angle adjusting member are supported on the upper side of the support frame. Adjustable angle photovoltaic structure, characterized in that formed with a wider width than the frame. The method of claim 4, wherein the first coupling plate is formed on the support frame, the second coupling plate is formed on the lower portion of the angle adjustment member, the first, second coupling plate is bolt nut fastening method Adjustable angle photovoltaic structure, characterized in that is fixed through. delete According to claim 1, wherein the rotation bar is an angle-adjustable solar structure, characterized in that it is formed in one direction with a rotation axis that is inserted between the rotation hole to rotate. The angle adjustment method of claim 1, wherein a plurality of module support bars are formed on the pivot bar at regular intervals and perpendicular to the pivot bar, and the solar cell module is seated and fixed on the module support bar. 2 solar structures available. According to claim 1, wherein the angle adjusting member is a first and a second fixing plate configured to have a rotation hole corresponding to each other at a constant interval and a movable plate having a fixing slot adjacent to the second fixing plate, and And a plurality of fixing holes formed in the second fixing plate at regular intervals, and a fixing member inserted into and fixed between the fixing holes of the second fixing plate and the fixing slot of the movable plate. Photovoltaic structure with adjustable angle. delete

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