CN215581020U - Photovoltaic solar tracking system - Google Patents

Abstract

The utility model provides a photovoltaic solar tracking system which comprises a solar panel, a fixed frame, a rotating shaft, a first driving rod, a second driving rod and a supporting rod, wherein the solar panel is arranged on the fixed frame, the fixed frame is arranged on the rotating shaft, one end of the rotating shaft is rotatably connected with the supporting rod, the other end of the rotating shaft is rotatably connected with the first driving rod, the first driving rod and the supporting rod are positioned on the same plane, one end of the second driving rod is rotatably connected with the supporting rod, and the other end of the second driving rod is rotatably connected with the fixed frame positioned on one side of the rotating shaft. The utility model realizes the effect of double-shaft tracking by utilizing the first driving rod and the second driving rod, avoids the use of an alternating current motor and a rotary support drive, and has the advantages of low cost and easy maintenance.

Description

Photovoltaic solar tracking system

Technical Field

The utility model relates to a photovoltaic solar tracking system, and belongs to the field of solar power generation.

Background

When the angle between the photovoltaic power generation panel and the solar ray is deviated from 25 degrees, the output power of the photovoltaic array is reduced by about 20 percent because the radiation energy of the vertical incidence is reduced. To solve this problem, ray auto-tracing technology is often used. The existing photovoltaic tracking system on the market mainly comprises three types of flat single-axis tracking, inclined single-axis tracking and double-axis tracking. The power output of the flat single-axis tracking system is increased by 20-25% compared with that of the fixed single-axis tracking system, the power output of the inclined single-axis tracking system is increased by 30-35% compared with that of the fixed single-axis tracking system, and the power output of the double-axis tracking system is increased by 40-45% compared with that of the fixed single-axis tracking system, so that the strong advantages of the photovoltaic double-axis tracking system in the aspect of improving the power generation power are seen.

Some photovoltaic double-shaft tracking systems in the current market mostly adopt an alternating current motor and a rotary support for driving, but have the defects of failure of a rotating system, misalignment of the motor and a controller, slipping of a bearing and the like, the cost is overhigh, the technical problem exists in after-sale maintenance, and the application of double-shaft tracking is limited.

SUMMERY OF THE UTILITY MODEL

The utility model provides a photovoltaic solar tracking system, which at least solves the problems that in the prior art, double-shaft tracking cost is too high and maintenance is not easy.

The utility model provides a photovoltaic solar tracking system which comprises a solar panel, a fixed frame, a rotating shaft, a first driving rod, a second driving rod and a supporting rod, wherein the solar panel is arranged on the fixed frame, the fixed frame is arranged on the rotating shaft, one end of the rotating shaft is rotatably connected with the supporting rod, the other end of the rotating shaft is rotatably connected with the first driving rod, the first driving rod and the supporting rod are positioned on the same plane, one end of the second driving rod is rotatably connected with the supporting rod, and the other end of the second driving rod is rotatably connected with the fixed frame positioned on one side of the rotating shaft.

Further, the first driving rod and the second driving rod can be selected as a hydraulic driving rod or a motor driving rod.

Furthermore, photovoltaic solar tracking system still includes GPS locator, controller, the controller links to each other with GPS locator, first actuating lever, second actuating lever electrical property respectively.

Furthermore, a rotating arm is further arranged on the fixed frame, and the second driving rod is in transmission connection with the fixed frame through the rotating arm.

Furthermore, the photovoltaic solar tracking system further comprises a gyroscope, wherein the gyroscope is installed on the solar panel or the fixed frame, and the gyroscope is connected with the controller.

Furthermore, the photovoltaic solar tracking system further comprises a solar angle detection device, the solar angle detection device comprises a shell, a base and a plurality of light sensing mechanisms, the shell is a light-transmitting hemisphere, the shell is mounted on the solar panel through the base, each light sensing mechanism comprises a light receiving end, a light guide piece and a light sensor, the light receiving ends form a light transmission path through the light guide pieces and the light sensors, the light receiving ends of the light sensing mechanisms are mounted in the shell, the receiving direction of the light receiving ends faces the center of the sphere of the shell, the plurality of light sensing mechanisms comprise a central optical fiber sensing mechanism and a plurality of lateral optical fiber sensing mechanisms, the receiving direction of the light receiving end of the central optical fiber sensing mechanism is perpendicular to the solar panel, and the light receiving ends of the lateral optical fiber sensing mechanisms use the light receiving end of the central optical fiber sensing mechanism as the center, are uniformly arranged in the shell.

Furthermore, the sun angle detection device further comprises a first convex lens, the first convex lens is arranged above the shell, and the main optical axis of the first convex lens coincides with the receiving direction of the light receiving end of the central optical fiber sensing mechanism.

Further, the light guide is an optical fiber.

Furthermore, a second convex lens is arranged in the light receiving end.

Furthermore, the casing still is equipped with a plurality of annular concave lens in side direction optical fiber response mechanism's light receiving end department, the center department of annular concave lens is equipped with circular plano mirror portion, just the primary optical axis of annular concave lens coincides with the primary optical axis of second convex lens, the area of circular plano mirror portion is not less than the area of second convex lens.

Compared with the prior art, the double-shaft tracking device has the advantages that the effect of double-shaft tracking is realized by utilizing the first driving rod and the second driving rod, the use of an alternating current motor and a rotary support drive is avoided, and the double-shaft tracking device is low in cost and easy to maintain.

Drawings

FIG. 1 is a side view of an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of an embodiment of the present invention at a second drive rod;

FIG. 3 is a schematic cross-sectional view of a photovoltaic solar tracking system according to an embodiment of the present invention;

FIG. 4 is a front view of a ring-shaped concave lens according to an embodiment of the present invention;

fig. 5 is a schematic cross-sectional view of a light receiving end according to an embodiment of the utility model.

1. A solar panel; 2. a fixed frame; 21. a rotating arm; 3. a rotating shaft; 41. a first drive lever; 42. a second drive lever; 43. a support bar; 51. a GPS locator; 52. a controller; 53. a gyroscope; 6. a sun angle detection device; 61. a housing; 62. a base; 63. a light sensing mechanism; 631. a light receiving end; 6311. a second convex lens; 632. a light guide; 633. a light sensor; 64. a first convex lens; 65. a ring-shaped concave lens.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.

The embodiment of the utility model discloses a photovoltaic solar tracking system, which comprises a solar panel 1, a fixed frame 2, a rotating shaft 3, a first driving rod 41, a second driving rod 42 and a supporting rod 43, wherein the solar panel 1 is installed on the fixed frame 2, the fixed frame 2 is installed on the rotating shaft 3, one end of the rotating shaft 3 is rotatably connected with the supporting rod 43, the other end of the rotating shaft 3 is rotatably connected with the first driving rod 41, the first driving rod 41 and the supporting rod 43 are positioned on the same plane, one end of the second driving rod 42 is rotatably connected with the supporting rod 43, and the other end of the second driving rod 42 is rotatably connected with the fixed frame 2 positioned on one side of the rotating shaft 3.

As shown in fig. 1-2, the support rod 43 and the first driving rod 41 are installed on the ground. The two ends of the second driving rod 42 are both provided with universal joints, and the two ends of the second driving rod 42 are connected with the fixed frame 2 and the supporting rod 43 through the universal joints.

In actual installation, the rotating shaft 3 may be installed in the east-west direction or in the north-south direction. The embodiment of the present invention takes the case where the rotary shaft 3 is installed in the north-south direction. The supporting rod 43 is vertically installed on the ground, one end of the first driving rod 41 is rotatably installed on the ground, and the orientation of the solar panel 1 in the north-south direction can be adjusted through the telescopic length of the first driving rod 41 in the using process; and the extension and contraction of the second driving rod 42 can drive the fixed frame 2 to rotate in the east-west direction by taking the rotating shaft 3 as an axis, thereby realizing the angle adjustment in the east-west direction.

The embodiment of the utility model realizes the effect of double-shaft tracking by utilizing the first driving rod 41 and the second driving rod 42, avoids the use of an alternating current motor and a rotary support drive, and has the advantages of low cost and easy maintenance. The embodiment of the utility model has a simple structure, and a user can determine the change of the illumination angle along with time according to the longitude and latitude of the photovoltaic solar tracking system, and further, through the setting of a fixed program, the telescopic degrees of the first driving rod 41 and the second driving rod 42 in different time periods are utilized to ensure that the solar panel 1 changes along with time and is matched with illumination to carry out angle adjustment, so that the surface of the solar panel 1 is ensured to be vertical to the sunlight irradiation direction, and the photoelectric conversion power is improved.

Alternatively, as shown in fig. 1-2, the first driving rod 41 and the second driving rod 42 may be hydraulic driving rods or electric motor driving rods.

The first driving rod 41 and the second driving rod 42 are driven by a motor driving rod to extend and retract.

Optionally, as shown in fig. 1-2, the photovoltaic solar tracking system further includes a GPS locator 51 and a controller 52, and the controller 52 is electrically connected to the GPS locator 51, the first driving rod 41, and the second driving rod 42, respectively.

As shown in fig. 1-2, the GPS locator 51 and the controller 52 are both mounted on the support rod 43. The controller 52 can control the operation of the first and second driving levers 41 and 42.

According to the embodiment of the utility model, the GPS positioner 51 is adopted, so that the photovoltaic solar tracking system has a positioning function, a user can effectively position address information of the photovoltaic solar tracking system through the GPS positioner 51, the sunlight irradiation angle can be determined through inquiry, the user can conveniently determine the deflection angle of the solar panel 1 according to the sunlight irradiation angle, the sunlight can be ensured to vertically irradiate the solar panel 1, and the photoelectric conversion efficiency of the solar panel 1 is improved.

Optionally, as shown in fig. 1-2, the fixed frame 2 is further provided with a rotating arm 21, and the second driving rod 42 is in transmission connection with the fixed frame 2 through the rotating arm 21.

Wherein the rotary arm 21 is mounted on the fixed frame 2 and the second driving lever 42 is rotatably connected to the rotary arm 21, as shown in fig. 1-2.

In particular, the photovoltaic solar tracking system further comprises a gyroscope 53, wherein the gyroscope 53 is mounted on the solar panel 1 or the fixed frame 2, and the gyroscope 53 is connected with the controller 52.

Wherein the gyroscope 53 is mounted on the solar panel 1.

According to the embodiment of the utility model, the gyroscope 53 is adopted, so that the accurate angle of the solar panel 1 can be obtained in real time, and the angle of the solar panel 1 can be conveniently and effectively adjusted.

Optionally, as shown in fig. 3, the photovoltaic solar tracking system further includes a sun angle detection device 6, the sun angle detection device 6 includes a housing 61, a base 62, a plurality of light sensing mechanisms 63, the housing 61 is a light-transmitting hemisphere, the housing 61 is installed on the solar panel 1 through the base 62, the light sensing mechanisms 63 include a light receiving end 631, a light guide member 632, and a light sensor 633, the light receiving end 631 forms a light transmission path through the light guide member 632 and the light sensor 633, each of the light receiving end 631 of the light sensing mechanism 63 is installed in the housing 61, and a receiving direction of the light receiving end 631 faces a spherical center of the housing 61, the light sensing mechanism 63 is composed of a central optical fiber sensing mechanism and a plurality of lateral optical fiber sensing mechanisms, a receiving direction of the light receiving end 631 of the central optical fiber sensing mechanism is perpendicular to the solar panel 1, the light receiving end 631 of each lateral optical fiber sensing mechanism is centered on the light receiving end 631 of the central optical fiber sensing mechanism and is uniformly installed in the housing 61.

As shown in fig. 3, the light receiving end 631 of each lateral optical fiber sensing mechanism is centered on the light receiving end 631 of the central optical fiber sensing mechanism, and the light receiving ends 631 and the housing 61 are uniformly installed in the housing 61 at equal intervals, and are connected and fixed by a connecting member. The sun angle detection device 6 is connected to the controller 52.

When the device works, the controller 52 may obtain the illumination intensity collected by each of the lateral optical fiber sensing mechanisms and the central optical fiber sensing mechanism, and if the intensity detected by one of the lateral optical fiber sensing mechanisms is greater than the illumination intensity of the other lateral optical fiber sensing mechanisms, it indicates that the detection angle of the lateral optical fiber sensing mechanism is closer to the sunlight irradiation angle.

In actual work, sunlight can cause deviation of an actual illumination angle and a theoretical illumination angle due to the influence of local water vapor, black clouds and other factors, and by adopting the light sensing mechanism 63, the sunlight illumination angle can be effectively detected at the solar panel 1, so that the detection precision of the sunlight illumination angle is improved, and further the photoelectric conversion power of the solar panel 1 is improved.

Specifically, as shown in fig. 3, the sun angle detecting device 6 further includes a first convex lens 64, which is installed above the housing 61, and a main optical axis of the first convex lens 64 coincides with a receiving direction of a light receiving end 631 of the central optical fiber sensing mechanism.

The surface area of one side of the first convex lens 64 is more than 2 times of the cross-sectional area of the light guide 632. The light receiving end 631 of the central fiber sensing mechanism is located at the focus of the first convex lens 64.

According to the embodiment of the utility model, the first convex lens 64 is adopted, so that the light collection area of the central optical fiber sensing mechanism can be increased, the light intensity collected by the central optical fiber sensing mechanism is further increased, the light intensity amplification effect is achieved, when the first convex lens 64 deflects with the sunlight angle, the light intensity collected by the optical fiber sensing mechanism can be obviously changed, and the sensitivity of the central optical fiber sensing mechanism for detecting the light intensity change can be effectively improved.

In particular, the light guide 632 is an optical fiber.

Specifically, as shown in fig. 5, a second convex lens 6311 is disposed in the light receiving end 631.

One end of the light guide 632 is located on the main optical axis of the second convex lens 6311.

By adopting the second convex lens 6311, the embodiment of the utility model can effectively increase the light receiving area of the light receiving end 631, thereby increasing the light collection amount of the light receiving end 631 in the collection direction thereof.

Specifically, as shown in fig. 3 and 4, the housing 61 is further provided with a plurality of annular concave lenses 65 at the light receiving end 631 of the lateral optical fiber sensing mechanism, a circular flat mirror portion is provided at the center of the annular concave lens 65, a main optical axis of the annular concave lens 65 coincides with a main optical axis of the second convex lens 6311, and an area of the circular flat mirror portion is not smaller than an area of the second convex lens 6311.

The annular concave lens 65 has a circular lens structure and has a circular flat lens portion.

By adopting the annular concave lens 65, the embodiment of the utility model can refract the light of other angles except the direction collected by the light receiving end 631, thereby avoiding the influence of the light of other angles on the light receiving end 631 and improving the light collection amount precision of the light receiving end 631 to the collection direction.

Finally, it should be noted that the above-mentioned embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the same, and although the present invention is described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the modifications and equivalents of the specific embodiments of the present invention can be made by those skilled in the art after reading the present specification, but these modifications and variations do not depart from the scope of the claims of the present application.

Claims (10)

1. The utility model provides a photovoltaic solar tracking system, its characterized in that, photovoltaic solar tracking system includes solar panel, fixed frame, rotation axis, first actuating lever, second actuating lever, bracing piece, solar panel installs on fixed frame, fixed frame installs on the rotation axis, the one end and the bracing piece of rotation axis are rotatable to be linked to each other, the other end and the first actuating lever of rotation axis are rotatable to be linked to each other, first actuating lever, bracing piece are located the coplanar, second actuating lever one end and the bracing piece are rotatable to be linked to each other, the other end of second actuating lever and the fixed frame that is located rotation axis one side are rotatable to be linked to each other.

2. The photovoltaic solar tracking system of claim 1, wherein the first and second drive rods are selected from hydraulic drive rods and motor drive rods.

3. The photovoltaic solar tracking system of claim 1, further comprising a GPS locator and a controller, wherein the controller is electrically connected to the GPS locator, the first drive rod, and the second drive rod, respectively.

4. The photovoltaic solar tracking system of claim 1, wherein the fixed frame further comprises a pivot arm, and the second driving rod is in driving connection with the fixed frame through the pivot arm.

5. The photovoltaic solar tracking system of claim 3, further comprising a gyroscope mounted on the solar panel or the fixed frame, the gyroscope being connected to the controller.

6. The photovoltaic solar tracking system according to claim 1, further comprising a solar angle detection device, wherein the solar angle detection device comprises a housing, a base, and a plurality of light sensing mechanisms, the housing is a transparent hemisphere, the housing is mounted on the solar panel via the base, the light sensing mechanisms comprise a light receiving end, a light guide member, and a light sensor, the light receiving end forms a light transmission path with the light sensor via the light guide member, the light receiving end of each light sensing mechanism is mounted in the housing, the receiving direction of the light receiving end faces the center of the housing, the plurality of light sensing mechanisms comprise a central optical fiber sensing mechanism and a plurality of lateral optical fiber sensing mechanisms, the receiving direction of the light receiving end of the central optical fiber sensing mechanism is perpendicular to the solar panel, and the light receiving ends of the lateral optical fiber sensing mechanisms are uniformly arranged in the shell by taking the light receiving end of the central optical fiber sensing mechanism as the center.

7. The photovoltaic solar tracking system of claim 6, wherein the sun angle detection device further comprises a first convex lens, the first convex lens is mounted above the housing, and a main optical axis of the first convex lens coincides with a receiving direction of a light receiving end of the central optical fiber sensing mechanism.

8. The photovoltaic solar tracking system of claim 6, wherein the light guide is an optical fiber.

9. The photovoltaic solar tracking system of claim 6, wherein a second convex lens is disposed within the light receiving end.

10. The photovoltaic solar tracking system of claim 9, wherein the housing further has a plurality of annular concave lenses at the light receiving end of the lateral optical fiber sensing mechanism, a circular flat lens portion is disposed at the center of the annular concave lens, and the main optical axis of the annular concave lens coincides with the main optical axis of the second convex lens, and the area of the circular flat lens portion is not smaller than the area of the second convex lens.

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