KR20200076914A - A kit of 3-axis structure for the solar tracker - Google Patents

Abstract

Disclosed is a three-axis solar tracking structure formed in a kit. The three-axis solar tracking structure formed in a kit, comprises: a base block fixedly installed on the ground; a guide rail block connected to a base pad assembled on an upper part of the base block and having a guide rail coupled to a chain on the outside, and a center pole connected at the center of the base pad; a turntable block installed on an upper part of the guide rail block to be supported by a guide roller installed at the upper part of the guide rail block and reciprocating and rotating around the center pole; a tilter block having both front sides installed on an upper part of the turntable block to rotate up and down by a pivot, and supported by a three-axis adjustment support so that an angle can be adjusted up and down with respect to the turntable block on a rear surface portion; and an array block installed to rotate on an upper part of the tilter block and having a solar panel installed on the upper part thereof.

Description

Kitted 3-axis solar tracking structure {A KIT OF 3-AXIS STRUCTURE FOR THE SOLAR TRACKER}

The present invention relates to a solar tracking structure, and more particularly, to a kitted 3-axis solar tracking structure that can be tracked by changing a 3-axis posture along a sun position while supporting a solar cell block.

In general, photovoltaic power generation is a pollution-free energy source that can obtain energy without generating greenhouse gas emission or environmental destruction factors, unlike other energy sources, and means that solar cells are directly converted to electric power by solar cells. do.

In such photovoltaic power generation, the incident angle at which sunlight enters the solar cell block is directly related to the power generation efficiency. Even if the solar cell block is located in a region having a large amount of sunlight, the solar altitude and orientation change frequently, so the solar cell The block needs to move according to the sun's altitude and position.

In view of this, various tracking devices, ie, solar tracking devices, have been developed to allow the solar cell block to change the posture by tracking the position of the sun.

As an example, in Korean Patent Registration No. 10-1346684, three solar cell blocks are disposed on a first frame, and the solar cell blocks use sunlight by using first and second high-altitude operation parts and rotation control parts made of actuators. The configuration to trace is described.

However, according to the conventional technology, the rotation of the rotation support lever for synchronizing and manipulating a plurality of solar cell blocks is severe, resulting in shaking, such as strong wind, and stability is deteriorated.

In addition, there is a problem in that a large load is generated in the second high-altitude operating unit for angle-adjusting the first frame supporting the solar cell block, thereby increasing the capacity of the driving motor and the like, thereby increasing cost.

In addition, in order to synchronize a plurality of solar cell blocks, a plurality of parts and an interlocking device are required, and thus, the number of parts increases, the weight increases, the stability decreases, and the cost increases.

In addition, in the case of photovoltaic power generation devices, structures have to be installed in various places. Until now, after being brought into the installation place for each part, the working conditions are poor because skilled workers must install it through on-site assembly work. As it takes a long time, the labor cost is excessively spent, and there is a problem that more than 20% of the total facility cost is taken.

Particularly, since a skilled expert needs to assemble and install parts, labor costs are increased, and when installed by a non-skilled person, the reliability of the installed structure decreases due to problems such as mis-assembly, and there is a problem that occurs until reinstallation is required. .

The present invention was devised in view of the above points, and an object thereof is to provide an improved kitted 3-axis solar tracking structure that can be easily assembled and installed through a bolt assembly process in the field by blocking the structure. .

The kit-shaped three-axis solar tracking structure of the present invention for achieving the above object, a base block fixedly installed on the ground; A guide rail block having a guide rail connected to a base pad assembled to an upper portion of the base block and a chain coupled to the outside and a center pole connected at the center of the base pad; A turntable block installed on an upper portion of the guide rail block to be supported by a guide roller installed on an upper portion of the guide rail block, and reciprocating about the center pole; A tilter block on both sides of the front of the turntable block installed pivotably up and down by a pivot, and on the rear part supported by a three-axis adjustment support so that the angle can be adjusted up and down relative to the turntable block; And an array block that is rotatably installed on the upper portion of the tilter block, and the solar cell panel is installed on the upper portion of the tilter block.

As a result, since the components of the entire structure are manufactured at the factory for each block, it can be transported to the site and assembled, so that the overall installation time can be reduced and costs can be reduced.

Here, the foundation block, a corrugated pipe in which concrete is poured inside; A reinforcing bar installed inside the corrugated pipe; A conduit pipe installed inside the corrugated pipe; An anchor bolt is fixed to the inside of the corrugated pipe, the upper end protruding to the top of the corrugated pipe; And a coupling plate having a plurality of anchor coupling holes to which the anchor bolts are coupled.

As a result, after the foundation block is manufactured in the factory, it only needs to be buried in the ground at the site.

In addition, the guide rail block, the base pad having an anchor hole in close contact with the upper portion of the coupling plate and the anchor bolt passes; A guide rail disposed in a ring shape around the base pad and having a chain installed on its outer periphery; A rail arm connecting the base pad and the guide rail; A center pole protruding upward from a center of the base pad; And a locking ring coupled to the upper end of the center pole.

In addition, the turntable block, the center pole is coupled to the center, the turntable frame in which the guide roller is interposed between the guide rail block; A tilter rotating shaft part protruding from both front sides of the upper part of the turntable frame; An azimuth drive motor installed on the front surface of the turntable frame; And it is installed on both sides of the rear of the turntable frame guide portion for guiding the vertical movement of the support for the three-axis adjustment; preferably.

In addition, the tilter block, a tilter frame in which the tilting shaft is coupled to the inside of the first half of the frame with a pin; A plurality of pivots for rotating the array, which are installed to protrude at regular intervals on both sides of the tilter frame; A two-axis driving unit for rotationally driving the array block coupled to the array rotation pivot; And a three-axis adjustment fixing lever protruding downward from the tilter frame and connected to the three-axis adjustment support bar.

In addition, the two-axis driving unit, the slider is installed to be reciprocally sliding on the upper portion of the tilter frame; An elevation angle adjustment motor installed on the upper side of the tilter frame and driving in the forward and reverse directions; And a power transmission unit that transmits the rotational force of the elevation angle adjusting motor to the slider to interlock slidably and reciprocally.

In addition, the array block, the array girder is rotatably connected to the top of each of the array pivot pivot; A girder rotation axis connecting the array girder; An array sagorae installed on the array girder to support a solar cell panel; And a two-axis adjustment lever at which both ends are pivotally connected to each of the array sputum and the slider.

According to the kitted 3-axis solar tracking structure of the present invention, the parts constituting the entire system are blocked by parts, and each block is standardized in the factory and then manufactured, so that only workers can assemble and install it in the field. The time can be shortened, thereby significantly reducing the cost.

In addition, since each block only needs to be assembled in order according to the provided assembly order manual, there is an advantage that even an unskilled person can easily assemble.

In addition, since each blocked part can be separated and replaced for each part in case of failure or damage, maintenance can be facilitated.

1 is a schematic view showing a kitted triaxial solar tracking structure according to an embodiment of the present invention.
2 is a cross-sectional view showing the basic block shown in FIG. 1.
FIG. 3 is a view showing excerpts of main parts of FIG. 2.
4 is a front view showing the guide rail block shown in FIG. 1.
5 is a plan view showing the guide rail block shown in FIG. 4.
6 is a front view showing a state in which the guide rail block and the turntable block shown in FIG. 1 are combined.
7 is a plan view showing the turntable block illustrated in FIG. 6.
8 is a right side view of the turntable block shown in FIG. 7.
9 is a rear view of the turntable block shown in FIG. 7.
FIG. 10 is a front view showing an array block coupled to an upper portion of the turntable block in FIG. 6.
FIG. 11 is a plan view of the turntable block shown in FIG. 10.
12 is a side view of the turntable block shown in FIG. 11.
13 is a front view of the turntable block shown in FIG. 11.
14 is a side view showing a state in which an array block is coupled to a tilter block.
15 is a view showing an array block.
Fig. 16 is a view showing that the array block is divided into two equal parts.

Hereinafter, with reference to the accompanying drawings will be described in detail the kit-shaped three-axis solar tracking structure according to an embodiment of the present invention.

1 to 15, the kit-shaped three-axis solar tracking structure 10 according to an embodiment of the present invention, the base block 100 is fixedly installed on the support surface, the upper portion of the base block 100 Guide rail block 200 coupled, turntable block 300 coupled to the top of guide rail block 200, tilter block 400 coupled to turntable block 300, array block coupled to tilter block 400 (500).

2 and 3, the foundation block 100 is concretely poured and fixedly installed with a predetermined depth inserted from the ground. The foundation block 100 includes a plurality of (six) reinforcing bar 110, a corrugated pipe 120 coupled to the outside of the reinforcing bar 110, and a conduit 130 installed inside the reinforcing bar 110. Includes. The reinforcing bar 110 is fixedly installed by pouring concrete 140 therein while buried at a predetermined depth from the ground. At this time, the inside of the upper end of the reinforcing bar 110 is fixed by the anchor bolt 150 is poured concrete (140), or is fixedly installed inside the reinforcing bar (110). That is, the anchor bolt 150 may be fixedly installed by welding or the like inside the reinforcing bar 110, and the upper end of the anchor bolt 150 is installed to protrude to the upper portion of the reinforcing bar 110 and is all factory Assembled in blocks and assembled in the field.

A coupling plate 160 for coupling the guide rail block 200 to the anchor bolt 150 is coupled. The coupling plate 160 is formed with an anchor coupling hole 161 at a predetermined interval radially based on the center, and the anchor bolt 150 is coupled.

1, 4 and 5, the guide rail block 200 is fixedly coupled to the upper portion of the foundation block 100 in a blocked state. The guide rail block 200 includes a base pad 210 coupled to the coupling plate 160, a ring-shaped guide rail 220, a rail arm 230 connecting the guide rail 220 and the base pad 210. ) And a center pole 240 connected to protrude upward from the center of the base pad 210.

A plurality of anchor holes 211 are drilled in the base pad 210 to be coupled with the anchor bolt 150. Therefore, when the nut is coupled to the anchor bolt 150 that protrudes upward through the anchor hole 211, the guide rail block 200 can be easily assembled and coupled to the base block 100. In the center of the base pad 210, the center pole 240 is connected upright to a predetermined height, and a dry bearing (not shown) and a locking ring 250 are coupled to the upper end of the center pole 240 later.

The guide rail 220 has a circular ring structure, and is connected to the base pad 210 by the plurality of (six) rail arms 230. The outer circumference of the guide rail 220, as shown in Figure 6, the chain 260 is installed along the outer circumference of a predetermined length.

6 to 9, the turntable block 300 is coupled by a center pole 240 and a dry bearing 313 on an upper portion of the guide rail block 200 to be rotated around the center pole 240 Is assembled. The turntable block 300 includes a turntable frame 310, a tilter rotation shaft part 320 installed on both sides of the entire upper part of the turntable frame 310, and an azimuth drive motor installed on the front surface of the turntable frame 310 ( 330).

The turntable frame 310 has a planar structure having a substantially rectangular shape, and may have a structure in which the outer frame 311 and the inner cabinet 312 connecting the outer frame 311 are connected. A dry bearing 313 coupled to the center pole 240 is installed at the center of the central cabinet frame 312. The center pole 240 is coupled to the dry bearing 313, and the locking ring 250 is firmly fixed to the center pole 240 to prevent the upper part of the turntable block 300 from being detached.

In addition, on both sides of the front upper portion of the turntable frame 310, the tilting pivot part 320 is protruded, and on both sides of the turntable frame 310 on the opposite side of the tilting pivot part 320, the three-axis adjustment support to be described later. A guide unit 315 that guides vertical movement of the 460 is installed.

The azimuth drive motor 330 is installed on the front of the turntable frame 310 and has a sprocket 331 connected to a chain 260 installed on the turntable block 200. As the sprocket 331 interlocks with the chain 260 as the azimuth drive motor 330 is driven, the azimuth can be adjusted by rotating the turntable block 300 on the guide rail block 200.

In addition, a plurality of guide rollers 340 are installed between the turntable frame 310 and the guide rail block 200. Accordingly, the azimuth can be adjusted while the turntable block 300 is stably rotated and moved on the guide rail block 200.

The tilter block 400 is assembled and installed on the top of the turntable block 300 as shown in FIGS. 10 to 13, and both sides are rotatably connected to the tilter rotation shaft part 320 of the turntable block 300 It is assembled, and the opposite side is supported by the three-axis adjustment support 460 so as to be rotatably connected up and down. That is, the tilter block 400 is rotated 3 axes up and down about the tilter rotation shaft part 320 to adjust the secondary elevation angle.

The tilter block 400 is installed on the tilter block frame 410, the tilter block frame 410, and the three-axis pivot 420 coupled with the tilter rotation shaft part 320, and both sides of the tilter block frame 410. Three array rotating pivots 430 disposed at regular intervals to protrude upward, and fixed to protrude on both sides of the lower side of the tilter block frame 410 to adjust the three axes to be connected to the three-axis adjustment support 460 The fixed lever 440 and the tilting block frame 410 are installed on the tilting block frame 410 to primarily adjust the array block 500 to rotate the two-axis drive unit 450.

The tilter block frame 410 has a substantially rectangular flat frame structure. The three-axis pivot 420 is installed on both sides of the first half of the tilter block frame 410 to be coupled to the tilting shaft 320 of the turntable block 300 with a pin. On both sides of the tilter block frame 410, six array pivots 430 are arranged at regular intervals. A dry bearing is installed at the upper end of the array rotating pivot 430 so that the array block 500 is rotatably connected.

The three-axis adjustment fixing lever 440 is connected to protrude to the lower portion of the tilter block frame 410, and is coupled by the three-axis adjustment support 460 and a bolt.

A plurality of height adjustment holes 461 are formed on the three-axis adjustment support 460 at regular intervals. The three-axis adjustment support 460 has a fixing hole 317 that couples the three-axis adjustment support 460 to the rear sides of the turntable block 300 while the top is connected to the three-axis adjustment fixed lever 440. Is supported slidably up and down.

Then, the height adjustment hole 461 of the three-axis adjustment support 460 is coupled to the fixing hole 317 formed in the turntable block 300 by a bolt, a fixing pin, or the like, thereby pivoting the tilter block 410 to the three-axis pivot. You can adjust the 3-axis by changing the posture up and down based on (420). Here, three height adjustment holes 461 are formed at regular intervals up and down, and can be used for fixing the lower extremities, fixing the vernal and equinoxes, and fixing the winter solstice from the top to the bottom.

The two-axis driving unit 450 is for synchronizing two-axis driving by rotating three array blocks 500 coupled to the array rotating pivot 430 with each array rotating pivot 430 as a rotation axis. The two-axis driving unit 450 is provided with two sliders 451 that are slidably installed on the tilter block frame 410, an elevation angle adjustment motor 453 installed on the tilter block frame 410, and an elevation angle adjustment motor. A power transmission unit 455 is provided to transmit and rotate the rotational driving force of 453 to the slider 451. The power transmission unit 455 is provided with a chain 455a installed on the slider 451, a sprocket 455b connected to the chain 455a, and a sprocket 355b installed at both ends of the drive shaft 455c to adjust the elevation angle motor. It is provided to be driven to rotate simultaneously by (453).

The slider 451 is provided with a plurality of lever connecting portions 451a at which the lower end of the two-axis adjustment lever 540 connected to the array block 500 is pivotally connected at regular intervals. The slider 451 is slidably supported by the slider holder 457 installed on the tilter block frame 410 and moved reciprocally. The slider 451 is provided with a pair of aluminum quadrangular profiles, and a chain 455a is installed at a predetermined length under the profile to be connected to the sprocket 455b. The elevation angle adjustment motor 453 is installed in the middle between the pair of sliders 451 to rotate and drive the drive shaft 455c in the forward or reverse direction. Therefore, while the drive shaft 455c is rotated, the sprocket 455b installed at the end thereof may reciprocate the slider 451 by interlocking with the chain 455a.

14 and 15, the array block 500 is divided into two by dividing one array into six, and is assembled and installed so as to be rotatable on the pivot 430 for rotating the array. The array block 500 includes an array girder 510, an array drive shaft 520, an array sputum 530 installed on the top of the girder 510, a connecting plate 550 with a girdle, and a two-axis adjustment lever 540. It is provided. The array girder 510 is connected to a dry bearing on top of the array rotating pivot 430.

In the array girder 510, two blocks are connected to one array drive shaft 520, and a plurality of array sputum 530s on which the solar panel 600 is supported are installed on the array girder 510.

The two-axis adjustment lever 540 is pivotally connected to the lower end of the lever connecting portion 451a, and the upper end is pivotally connected to the array sputum 530.

The array block 500 having the above configuration is transported to the field in a blocked state and assembled and installed in the tilter block 400, and may be adjusted in two axes by driving the two-axis driving unit 450.

Here, in the solar tracking system of the present invention, as the turntable block 400 rotates, the solar cell panel 600 is adjusted by one axis by azimuth adjustment, and adjusted by two axes by a two-axis driving unit 450, and the three-axis It is possible to adjust the 3-axis by adjusting the height of the support 460 for adjustment.

In addition, preferably, as illustrated in FIG. 16, the array block 500 may be configured as a kit to be separated and assembled by 1/2 length based on the entire length.

In this case, it is configured to include a pair of 1/2 array blocks 500a that are 1/2-blocked to be assembled and detachable from the central portion based on the entire length of the array drive shaft 520. By using the connecting plate 550 at the connection end of the 1/2 array block 500a, the 1/2 array blocks 500a on both sides can be easily connected and assembled by bolts.

As described above, according to the kit 3-axis solar tracking structure of the present invention, the base block 100, the guide rail block 200, the turntable block 300, the tilter block 400, the array block 500 ), each block can be mass-produced in the factory, and each block that has been mass-produced needs to be transferred to the site and assembled, so installation work is easy, time is shortened, and unskilled people can easily install it. .

In addition, by standardizing by blocking, no separate setting work is required after installation, and even when replacing or replacing due to failure or damage of a specific block, only the blocks to be exchanged must be separated and assembled for replacement. There is an advantage.

That is, as described above, the foundation block 100, as shown in FIG. 2, after digging the pit to a depth of approximately 1.2 m from the ground, lay the gravel with a thickness of approximately 100 mm, and then cover the concrete with a thickness of 100 mm.

Then, after the concrete is poured into the corrugated pipe 120 and fixedly installed, the coupling plate 160 is coupled with the anchor bolt 150.

Then, when the curing of the concrete of the foundation block 100 is completed, the guide rail block 200 is installed to be coupled to the upper portion of the foundation block 100. At this time, the guide rail block 200 is firmly assembled to the anchor bolt 150 by using a nut and a washer.

Next, one guide roller 340 is assembled to the lower portion of each side of the turntable block 300.

Next, the turntable block 300 is put on the upper portion of the guide rail block 200 and assembled. At this time, the locking ring 250 is coupled to the end of the center pole 240 to keep the turntable block 300 firmly assembled and prevent dry bearings from falling out. In addition, the azimuth drive motor 330 is assembled and installed on the front of the turntable frame 310. In addition, the chain 260 may be installed on the side of the guide rail block 200 in the field, or may be moved to a pre-installed state.

In addition, although not shown, by installing a limit switch for detecting the position of the azimuth drive motor 330 in a predetermined position on the lower or side of the guide rail block 200, the azimuth adjustment range by the azimuth drive motor 330 Can be limited.

Next, as shown in FIG. 10, the tilter block 400 is assembled and installed on the top of the turntable block 300. The tilter block 400 is completely assembled at the factory and transported to the field, and the pivot axis 420 for three-axis rotation is coupled to the tilter rotation shaft portion 320 of the turntable block 300 with a pin. In addition, the three-axis adjustment support 460 is assembled with the three-axis adjustment support 440. In addition, according to the season, that is, by adjusting a predetermined position according to autumn, summer, autumn and winter, the height of the three-axis adjustment support 460 is adjusted and fixed.

Next, the array block 500 is divided into three pieces in one set and assembled. In order to save transport space, the array sputum 530 may be transported in a separate state and assembled in the field. The array block 500 is pivotally connected to the top of the array support bar 430 in the field, and six six-axis adjustment levers 540 are connected to the slider 451, respectively.

Finally, when the solar panel 600 is placed on the top of the array block 500 and assembled with bolts, the assembly and installation of the solar tracking system is completed.

As a result, it is possible to assemble the blocked parts through a simple assembly process in the field, thereby saving installation work time, and even an unskilled person can easily assemble, thereby reducing the overall installation cost.

Above, the present invention has been shown and described in connection with a preferred embodiment for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, those skilled in the art will appreciate that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended claims.

100..Basic block 110..Reinforced rebar
120..wrinkle tube 130..wire tube
140.. Concrete 150.. Anchor bolt
160..Combination plate 200..Guide rail block
210..Base pad 220..Guide rail
230..Rail arm 240..Center pole
250..locking ring 300..turntable block
310..Turntable frame 320..Rotating shaft
330..Azimuth drive motor 340..Guide roller
400..Tilt block 410..Tilt frame
420..3-axis pivot 430..array rotation pivot
440..3-axis fixed lever 450..3-axis drive
451..Slider 453..High-angle adjustable motor
455..Power transmission 460..3-axis adjustable support
500..array block 510..array girder
520..girder connecting rod 530..array sakyaerae
540..2-axis adjustable lever 600..Solar panel

Claims (7)

A base block fixedly installed on the ground;
A guide rail block having a guide rail connected to a base pad assembled to an upper portion of the base block and a chain coupled to the outside and a center pole connected at the center of the base pad;
A turntable block installed on an upper portion of the guide rail block to be supported by a guide roller installed on an upper portion of the guide rail block, and reciprocating about the center pole;
A tilter block on both sides of the front of the turntable block installed pivotably up and down by a pivot, and on the rear part supported by a three-axis adjustment support so as to be able to adjust the angle up and down relative to the turntable block; And
Kitted three-axis solar tracking structure, characterized in that it comprises; an array block that is rotatably installed on the upper portion of the tilter block, the solar panel is installed on the upper portion. According to claim 1, The basic block,
A corrugated pipe through which concrete is poured;
A reinforcing bar installed inside the corrugated pipe;
A conduit pipe installed inside the corrugated pipe;
An anchor bolt fixedly installed inside the corrugated pipe and protruding from the upper end of the corrugated pipe; And
Kit the three-axis solar tracking structure comprising a; coupling plate having a plurality of anchor coupling holes to which the anchor bolt is coupled. According to claim 2, The guide rail block,
A base pad closely coupled to the upper portion of the coupling plate and having an anchor hole through which the anchor bolt passes;
A guide rail disposed in a ring shape around the base pad and having a chain installed on its outer periphery;
A rail arm connecting the base pad and the guide rail;
A center pole protruding upward from a center of the base pad; And
Kiting three-axis solar tracking structure comprising a; locking ring coupled to the upper end of the center pole. The turntable block according to claim 2 or 3,
A turntable frame in which the center pole is coupled to the center and the guide roller is interposed between the guide rail block;
A tilter rotating shaft part protruding from both front sides of the upper part of the turntable frame;
An azimuth drive motor installed on the front surface of the turntable frame; And
Kit is provided on both sides of the rear side of the turntable guide section for guiding the vertical movement of the support for the three-axis adjustment; Kitted three-axis solar tracking structure comprising a. The method of claim 4, wherein the tilter block,
A tilter frame in which the tilting shaft is coupled with a pin inside the first half of the frame;
A plurality of pivots for rotating the array, which are installed to protrude at regular intervals on both sides of the tilter frame;
A two-axis driving unit for rotationally driving the array block coupled to the array rotation pivot; And
Kitted three-axis solar tracking structure, characterized in that it comprises; a three-axis adjustable fixed lever protrudingly extended to the lower portion of the tilter frame and connected to the support bar for the three-axis adjustment. According to claim 5, The two-axis driving unit,
A slider installed reciprocally sliding on an upper portion of the tilter frame;
An elevation angle adjustment motor installed on the upper side of the tilter frame and driving in the forward and reverse directions; And
Kitted three-axis solar tracking structure comprising a; power transmission unit for transmitting the rotational force of the elevation angle adjustment motor to the slider to reciprocate slidingly interlocked. The method of claim 6, wherein the array block,
An array girder rotatably connected to an upper end of each of the array rotating pivots;
A girder rotation axis connecting the array girder;
An array sagorae installed on the array girder to support a solar cell panel; And
Kit two-axis solar tracking structure, characterized in that it comprises; a two-axis control lever is pivotally connected to each end of the array sputum and the slider.

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