KR101600402B1 - apparatus for automatic angle adjustment of photovoltaic array - Google Patents

Abstract

The present invention relates to an automatic angle adjusting device, and more particularly, to an automatic angle adjusting device capable of automatically adjusting an angle automatically according to a season, and not only can be prevented from dropping off due to firm fixing of a power transmitting element of a driving part for angle adjustment, The present invention relates to a solar array automatic angle adjusting apparatus capable of adjusting an angle by manually operating a driving unit, comprising: an array support on which a solar array is installed; The upper end of which is rotatably mounted on the array support body, and the lower end of which is fixed to the ground; A motor installed on top of the column; A sprocket axially coupled to a rotating shaft of the motor; A chain portion connecting the lower ends of the sprocket and both ends of the array support to change the angle of the array support according to the rotation of the motor; And a controller for controlling the driving of the motor at the lower portion of the fixed post, so that the motor can be easily operated by the controller and the solar array can be adjusted at an accurate angle according to the season.
In addition, according to the present invention, the chain connecting the solar array and the motor is wound in triple to receive the power, thereby preventing the chain from falling off even in an external environment or strong wind, and maintaining an adjusted angle firmly.

Description

An apparatus for automatic angle adjustment of photovoltaic array,

The present invention relates to an automatic angle adjusting device, and more particularly, to an automatic angle adjusting device capable of automatically adjusting an angle automatically according to a season, and not only can be prevented from dropping off due to firm fixing of a power transmitting element of a driving part for angle adjustment, And more particularly, to a solar array automatic angle adjusting device capable of adjusting an angle by manually operating a driving part.

Generally, a solar array refers to a device in which one or a plurality of solar cell modules are connected and installed as a cradle in order to obtain the necessary power.

To optimize power generation efficiency, solar arrays adjust the tilt angle so that sunlight can be projected at 90 degrees. In other words, by adjusting the height of the solar array according to the season, the angle of the solar array with respect to the ground is adjusted so that the sunlight can be received as much as possible.

The angle adjustment of the solar array is mainly performed by the automatic operation of adjusting the angle of the solar array by operating the motor.

However, there is a problem in that the angle manipulation is inaccurate because the angle of the solar array is adjusted while the user directly observes the angle.

In addition, the solar arrays are mounted on the roof or roof of the building in order to receive the maximum amount of sunlight, and the rooftop or roof of the building is strongly windy. Therefore, the driving power for the angle adjustment of the solar array is transmitted There is a problem that element dropout frequently occurs and constant maintenance is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solar array automatic angle adjusting device capable of automatically adjusting the angle of a solar array at an accurate angle according to a season.

It is also an object of the present invention to provide a solar array automatic angle adjusting device which firmly fixes the power transmitting element of the driving part for adjusting the angle of the solar array to prevent dropout and firmly maintain the adjusted angle.

It is another object of the present invention to provide a solar array automatic angle adjusting device capable of adjusting the angle of a solar array by manually operating a driving unit when necessary.

The present invention relates to an apparatus for adjusting the angle of a solar array (10), comprising: an array support (100) on which a solar array (10) is installed; A fixed column 200 at an upper end of which the array support 100 is rotatably installed and a lower end fixed to the ground 1; A motor 300 installed on the fixed column 200; A sprocket 400 axially coupled to the rotation axis 310 of the motor 300; A chain part 500 connecting the sprocket 400 and both ends of the array support 100 so as to change the angle of the array support 100 according to the rotation of the motor 300; And a controller 600 for driving the motor 300 at a lower portion of the fixed column 200. The sprocket 400 includes a pair of spaced apart double sprockets 410, A sprocket shaft 420 connecting between the sprockets 410 and a traveling sprocket 430 reciprocatingly inserted into the sprocket shaft 420 in an inclined form between the double sprockets 410,

The chain part 500 is wound around the moving sprocket 430 and spanned over the double sprocket 410 so that the chain part 500 is wound around the sprocket 400 and the controller 600 The angle of the array support 100 connected to the chain unit 500 is adjusted according to the normal and reverse rotation of the motor 300 by the operation of the chain unit 500.

In addition, a guide plate (not shown) is provided at both ends of the double sprocket 410 of the present invention to cover a part of the periphery of the double sprocket 410 with a larger diameter than the double sprocket 410, (440).

The controller 600 of the present invention may further include a memory 610 to which an adjustment angle is input for each season and an operation button 620 to which each season is indicated, The angle of the array support body 100 is adjusted according to the driving of the motor 300 by loading the adjustment angle inputted to the controller 610.

Further, the fixing post 200 of the present invention includes an angle display unit 210 for displaying the angle of adjustment of the array support 100 on the upper side, and an angle display unit 210 for displaying the angle display unit 210 on the inside And an angle confirmation window 230 for confirming the angle display unit 210 is formed at an end of the sleeping mirror 220 so that the operation button 620 is operated, The angle of the array support 100 connected to the chain unit 500 is adjusted according to the normal and reverse rotation of the chain unit 300.

Meanwhile, at one end of one end of the moving sprocket 430 of the present invention, a part of the circumference of the moving sprocket 430 is covered with a larger diameter than the moving sprocket 430, And a movement guide plate (450) for preventing the rotation of the movable plate (450).

In addition, the guide plate 440 of the present invention is formed with a support body 442 having a circumferential section in the shape of a letter 'A', and the support body 442 supports the chain portion 500 of the moving guide plate 450 is overlapped to prevent the chain part 500 from dropping off, and the moving guide plate 450 is formed with a support body 452 having a cross- The supporting member 452 covers only a portion where the chain unit 500 is engaged with the moving sprocket 430 to prevent the chain unit 500 from falling off.

The present invention has an effect that the motor can be easily operated by the controller, and the solar array can be adjusted at an accurate angle according to the season.

In addition, according to the present invention, the chain connecting the solar array and the motor is wound in triple to receive the power, thereby preventing the chain from falling off even in an external environment or strong wind, and maintaining an adjusted angle firmly.

In addition, the present invention has an advantage that the angle of the solar array can be directly adjusted while the user confirms the angle display unit through the sleeping mirror if necessary.

1 is a front view of a solar array automatic angle control device according to an embodiment of the present invention;
FIG. 2 is a view showing a chain 510 of a chain part 500 wound around a sprocket 400 in a solar array automatic angle adjusting device according to an embodiment of the present invention.
3 is a perspective view illustrating a chain 510 of the chain part 500 wound around the sprocket 400 in the solar array automatic angle adjusting device according to the embodiment of the present invention.
4 is a detailed view of the sleeping part 220 in the solar array automatic angle adjusting device according to the embodiment of the present invention.
5 is a front view showing the operation of the solar array automatic angle adjusting device according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

1 is a front view of a solar array automatic angle control device according to an embodiment of the present invention.

1, the solar array automatic angle adjusting apparatus according to the embodiment of the present invention includes an array support 100 on which a solar array 10 is installed, a support column 100 on which the array support 100 is installed, A sprocket 400 axially coupled to the motor 300 and a sprocket 400 connecting the sprocket 400 and the array support 100 to each other. A chain unit 500, and a controller 600 for driving the motor 300. [

The array support 100 is a rectangular frame in which the solar array 10 is fixedly installed. Here, the solar array 10 refers to one or more solar cell modules connected together.

The center of the array support 100 is rotatably fixed to the upper end of the fixed post 200. The array support 100 is rotated about its axis to be angularly adjusted. At this time, bolts, nuts, fixing pins, etc. are used as fixing elements.

A ring-shaped retaining ring 110 connected to the chain portion 500 is formed at both ends of the array support 100.

The fixed column 200 is a hollow rod-like column for supporting the array support 100. The center of the array support 100 is rotatably fixed to the upper end of the column support 200. The lower end of the column support 200 has a wider The fixing plate 240 is formed.

The fixing plate 240 is fixed to the paper 1 with an anchor bolt. At this time, the fixing plate 240 is embedded in the ground 1 in a state of being fixed to a base formed of concrete or the like. The upper end of the fixing post 200 passes through the roof 2 and is located at the top of the roof 2.

An angle indicator 210 is provided on the upper portion of the fixed column 200 to confirm the angle of the array support 100. The angular display unit 210 has an angle of 15 to 45 degrees on the surface in units of 5 degrees. And angle guide 212, which refers to the angle of the current array support 100. The angle guide 212 is associated with the rotation of the array support 100 at the center of the array support 100 to refer to the current adjustment angle of the array support 100.

Inside the stationary post 200 is installed a sleep lathe 220 which allows the current adjustment angle referred to by the angle guide 212 to be ascertained on the ground. An angle confirmation window 230 is formed at a lower portion of the fixed post 200 so as to allow the user to view the angle guide 212,

The motor 300 is installed on the upper portion of the fixed post 200. The motor 300 serves to provide rotational force to the chain unit 500. The motor 300 may be provided with elements such as bevel gears for switching the direction of rotation according to the installation direction on the fixed post 200.

The sprocket 400 is coupled to the rotating shaft 310 of the motor 300 and includes a pair of double sprockets 410 spaced apart from each other by a predetermined distance and a sprocket shaft 420 connecting between the double sprockets 410, A guide plate 440 installed at both ends of the double sprocket 410 to prevent the chain 510 from falling off from the sprocket shaft 420, And a movement guide plate 450 installed at one end of the chain 430 to prevent the chain 510 from falling off.

At this time, the spacing distance of the double sprockets 410 is set such that the chain 510 of the chain part 500 is smoothly wound on the moving sprocket 430 fitted in the sprocket shaft 420, and the wound chain 510 is smoothly rotated (See Figure 2). ≪ RTI ID = 0.0 >

The chain part 500 is connected to the sprocket 400 and rotated by receiving the rotational force of the motor 300. The chain part 500 comprises a chain 510 engaged with the sprocket 400 and a wire 510 connected to both ends of the chain 510 520). The chain 510 has a length enough to engage with the sprocket 400 at the center to cover the radius of rotation of the array support 100, and wires 520 are connected to both ends. The ends of the wires 520 located at both ends are fixed to the fixing ring 110 of the array support 100.

The controller 600 is electrically connected to the motor 300 to control the forward and backward rotation of the motor 300 and is installed below the stationary post 200. The height of the controller 600 is 80 to 120 cm from the ground so that the user can stand and operate.

The controller 600 includes a memory 610 in which an adjustment angle value of the seasonal array support 100 is stored, an operation button 620 in which the season of the array support 100 is displayed, A display 630, an angle adjustment button 640 for manually raising or lowering the angle of the array support 100, a setting button 650 for storing an adjustment angle value, and a power button 660).

In the memory 610, an adjustment angle is input for each season. For example, 20 degrees in spring, 30 degrees in summer, 40 degrees in autumn, and 45 degrees in winter. Spring, summer, autumn, and winter are displayed on the operation button 620, and each button corresponds to an input value of the memory 610, so that the angle of the array support 100 is adjusted by pressing the corresponding button.

The display 630 displays the current adjustment angle of the array support 100, and FND, LCD, TFT, LED and the like are used.

The angle adjustment button 640 is used to manually adjust the angle of the array support 100. The angle adjustment button 640 is used to increase or decrease the angle of the array support 100 with each button. When the angle adjusting button 640 is used, the angle of the array supporting body 100 can be adjusted while checking the angle of the angle indicating part 210 through the sleeping mirror 220 and the angle checking window 230.

On the other hand, it is possible to set or modify the adjustment angle input value for each season built in the memory 610 through the setting button 650.

FIG. 2 is a view showing a state in which a chain 510 of a chain part 500 is wound on a sprocket 400 in an automatic angle control device for a solar array according to an embodiment of the present invention. In which the chain 510 of the chain part 500 is wound on the sprocket 400 in the automatic angle control device for a solar array according to the present invention.

The sprocket 400 is axially coupled to the rotary shaft 310 of the motor 300 and receives the rotational force of the motor 300. The chain 510 of the chain portion 500 is engaged with the sprocket 400. [

The chain 510 is engaged with a pair of double sprockets 410 located on both sides of the moving sprocket 430 while being wound around the moving sprocket 430. At this time, the chain 510 is firmly fixed so that each link of the chain 510 is engaged with the moving sprocket 430 and the double sprocket 410.

The structure of the chain 510 engaged with the sprocket 400 is firmly maintained even if the chain 510 swings due to the external environment or strong wind and the chain 510 is kept in contact with the sprocket 400, It is prevented from falling off. The angle of the adjusted array support 100 is also maintained firmly.

On the other hand, the moving sprocket 430 takes an inclined shape so that the chain 510 is smoothly wound. At this time, the inclination angle is 20 to 50 degrees with respect to the double sprocket 410. In addition, the diameter of the moving sprocket 430 is smaller than that of the double sprocket 410.

Further, a support plate 432, to which oil or lubricant is applied and loosely fitted to the sprocket shaft 420, protrudes from both ends of the movement sprocket 430 to form a body. The diameter of the support plate 432 is smaller than the movement sprocket 430. The support plate 432 is fitted in the sprocket shaft 420 and rotates left and right linearly while rotating idly. This is because the chain 510 may rotate in a state where the chain 510 is engaged with the double sprocket 410 and the moving sprocket 430 to cause the chain 510 to engage with the moving sprocket 430, 430 rotate in the right and left direction, and thus the chain 510 can be smoothly rotated even if shaking occurs.

A moving guide plate 450 is provided at one end of the moving sprocket 430 to prevent the chain 510 engaged with the moving sprocket 430 from falling off the moving sprocket 430 during the driving process. The moving guide plate 450 is fixed so as not to be affected by the rotation of the sprocket shaft 420 by being loosely fitted to the sprocket shaft 420. [

The moving guide plate 450 is formed to have a diameter larger than that of the moving sprocket 430 and a supporting body 452 extending in a cross section to cover a part of the circumference of the moving sprocket 430 is integrally formed . At this time, the support body 452 is formed in a semicircular shape so as to cover only a portion where the chain is engaged in the moving sprocket 430, and the ends are spaced apart to secure a space for replacing the chain 510.

On both ends of the double sprocket 410, a guide plate 440 is provided to prevent the double sprocket 410 from falling off from the double sprocket 410 during the driving process of the chain 510. The guide plate 440 is formed to have a larger diameter than the double sprocket 410 and is installed on the side surface of the double sprocket 410. The supporting plate 442 is formed integrally with the guide plate 440 so as to extend in the 'A' shape to cover a part of the circumference of the double sprocket 410. At this time, the supporter 442 covers the portion where the chain 510 is engaged, that is, the double sprocket 410 in a semicircular shape, and is positioned in the opposite direction to each other, (410).

Thereby physically blocking the chain 510 from falling out of the travel sprocket 430 and the double sprocket 410.

4 is a detailed view of the sleeping mirror 220 in the solar array automatic angle adjusting device according to the embodiment of the present invention.

The sleeping mirror 220 is installed inside the fixed post 200. The sleeping mirror 220 allows the angle indicator 212 of the angle display unit 210 located on the roof 2 (see FIG. 1) to be confirmed on the ground, using the reflecting property of light.

The upper end of the sleeping mirror 220 is positioned at the angle indicator 210 and the lower end is located at the upper portion of the fixed post 200. The upper part and the lower part are bent at 90 degrees with different directions from each other, and the upper part and the lower part are vertically connected. The first mirror 222 and the second mirror 224 are disposed at a position where the upper end and the lower end of the sleeping mirror 220 are bent by 90 degrees, respectively, and are arranged diagonally with an angle of 45 degrees.

The first mirror 222 firstly illuminates the angle indicator 212 and the angle indicator 212 of the angle indicator 210 and the second mirror 224 disposed below the first mirror 222 illuminates the first mirror 222, And secondarily illuminates the angle indicator 210 and the angle indicator 212 reflected by the mirror 222 to the user. The angle indicator 210 and the angle indicator 212 reflected by the first mirror 222 are changed in the right and left directions but are reflected through the second mirror 224 so that the user can see the original image.

At the position where the second mirror 224 is located, an angle confirmation window 230 is formed in which the user can check the angle. At this time, the height at which the second mirror 224 and the angle confirmation window 230 are formed has a height of about 80 to 120 cm with respect to the ground. Thus, the user can smoothly confirm the angle confirmation window 230. [

In this way, the angle of the array support body 100 can be manually adjusted by the angle adjustment button 640 of the controller 600 while the user directly confirms the angle controlled by the sleeping mirror 220.

On the other hand, reference numeral 3 denotes a moving direction of light.

5 is a front view showing the operation of the solar array automatic angle adjusting device according to the embodiment of the present invention. FIG. 5 shows that the angle of the array support 100 is adjusted to 30 degrees as an example.

First, the automatic operation will be described.

The angle of the array support body 100 is adjusted by pressing the operation button 620 of the controller 600. The operation button 620 displays spring, summer, autumn, and winter, and the season button 620 is pressed. The angle of the array support 100 is adjusted by loading the adjustment angle value input in accordance with the operation button 620 in the memory 610.

That is, when the operation button 620 is pressed, the motor 300 rotates in the forward and reverse directions, and the sprocket 400 axially coupled to the rotary shaft 310 of the motor 300 rotates. The angle of the array support 100 connected to the wires 520 at both ends of the chain 510 is adjusted as the chain 510 of the chain part 500 wound around the sprocket 400 rotates.

At this time, the chain 510 is engaged with the moving sprocket 430 of the sprocket 400 and is also engaged with the double sprocket 410, that is, it has a structure in which the chain 510 is meshed with the moving sprocket 430. Therefore, Thereby maintaining the engagement state. That is, the chain 510 remains firmly engaged with the sprocket 400 and is prevented from falling off, and the adjusted angle of the array support 100 is maintained unchanged.

By adjusting the angle of the array support body 100 by pressing the operation button 620 according to the season, the angle of the array support body 100 can be accurately and automatically adjusted.

Next, the manual operation will be described.

The angle adjustment button 640 of the controller 600 is depressed to adjust the angle of the array support 100. At this time, the angle of the array support 100 is checked by checking the angle confirmation window 230 formed on the fixed column 200. The angle confirmation window 230 allows the angle guide 212 of the angle display unit 210 to be confirmed through the sleep aperture 220.

When the angle adjustment button 640 is operated while viewing the angle confirmation window 230, the motor 300 rotates in the normal or reverse direction and the rotation of the chain unit 500 The chain 510 is moved and the angle of the array support 100 connected to the wire 520 is adjusted.

Thus, the angle of the array support body 100 can be adjusted while manually confirming the angle guide 212 of the angle display unit 210 by manually operating the angle adjustment button 640 manually.

1: Floor 2: Roof 3: Light
10: solar array
100: array support 110: retaining ring
200: Fixed column
210: Angle display unit 212: Angle instruction
220: Sleeping mirror 222: First mirror 224: Second mirror
230: Angle confirmation window 240: Fixed plate
300: motor 310:
400: sprocket
410: Double sprocket 420: Sprocket shaft
430: moving sprocket 432:
440: guide plate 442: support
450: movement guide plate 452: support
500: chain portion
510: chain 520: wire
600: controller
610: Memory 620: Operation button 630: Display
640: angle adjustment button 650: setting button 660: power button

Claims (6)

An apparatus for adjusting the angle of a solar array (10)
An array support 100 on which the solar array 10 is installed;
A fixed column 200 at an upper end of which the array support 100 is rotatably installed and a lower end fixed to the ground 1;
A motor 300 installed on the fixed column 200;
A sprocket 400 axially coupled to the rotation axis 310 of the motor 300;
A chain part 500 connecting the sprocket 400 and both ends of the array support 100 so as to change the angle of the array support 100 according to the rotation of the motor 300; And
And a controller (600) for operating driving of the motor (300) at a lower portion of the fixed column (200)
The sprocket 400 includes a pair of spaced apart double sprockets 410 and a sprocket shaft 420 connecting between the double sprockets 410. The sprocket shaft 420 is sloped between the double sprockets 410 And a moving sprocket (430) inserted in the sprocket shaft (420) and reciprocating, the diameters of the pair of double sprockets (410) being larger than the diameter of the moving sprocket (430)
The chain part 500 is wound around the moving sprocket 430 and spanned over the double sprocket 410 so that the chain part 500 is wound around the sprocket 400 and the controller 600 The angle of the array support 100 connected to the chain unit 500 is adjusted according to the normal and reverse rotation of the motor 300,
The pair of double sprockets 410 are respectively provided at both ends with a wider diameter than the double sprocket 410 to cover part of the circumference of the double sprocket 410 to prevent the chain portion 500 from falling off. (440)
One end of one end of the moving sprocket 430 is covered with a part of the circumference of the moving sprocket 430 at a larger diameter than the moving sprocket 430 to prevent the chain part 500 from falling off A guide plate 450 is provided,
The support plate 442 is formed in a generally semicircular shape and the support plate 442 is formed in the periphery of the double sprocket 410, A pair of double sprockets 410 are provided at opposite positions of the pair of sprockets 410 so as to cover only a portion where the sprockets 500 are engaged to prevent the chain portion 500 from falling off,
The supporting member 452 is formed in a generally semicircular shape with a supporting member 452 extending in the shape of a circle around the moving guide plate 450. The supporting member 452 is disposed on the periphery of the moving sprocket 430, (500) is covered with only the portion where the unit (500) is engaged, thereby preventing the chain part (500) from falling off.
delete delete The method according to claim 1,
The fixed pillars (200)
An angle indicator 210 for indicating the angle of adjustment of the array support 100 is formed on the top and a sleep aperture 220 for viewing the angle indicator 210 on the ground is built in the inside, An angle confirmation window 230 for confirming the angle display unit 210 is formed at an end of the display unit 220,
Wherein the angle of the array support body (100) connected to the chain unit (500) is adjusted according to normal / reverse rotation of the motor (300) by operating the operation button (620).
delete delete

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