A Solar Automatic Tracking System that Generates Power for Lighting Greenhouses
Abstract
:1. Introduction
2. Results and Discussion
Solar Tracking System Tests
3. Material and Methods
3.1. Solar Tracking System Design
- (1)
- Structure of the automatic solar tracking system
- (a)
- Component strength: Component should have sufficient strength; the so-called strength is defined as the ability to resist damage under load.
- (b)
- Component stiffness: Component should have sufficient rigidity. Certain structural deformations cannot exceed the permissible limits of normal operation.
- (c)
- Component stability: Member should have sufficient stability; the requirements of the original straight shape remain unchanged.
- (d)
- Angle range: In the mechanical transmission part of the solar tracking system, the orientation axis angle should be at least 270°, and the corner of the pitch axis should be 90°.
- (e)
- Tracking accuracy: At a 12° angle, the system followed the sun once in every forty-eight minutes.
- (2)
- Motion Simulation using COSMOS Motion Analysis
3.2. Solar Tracking System: Experimental Methods
Maximum Power | Operating Voltage | Operating Current | Open Circuit Voltage | Open Circuit Current | Dimensions | Weight |
---|---|---|---|---|---|---|
10 W | 17.2 V | 0.59 A | 21.3 V | 0.63 A | 385 × 290 × 25 mm | 1.4 kg |
Sensitivity | Resistance | Inertia |
---|---|---|
7.2–14.3 μv/wm−2 | 35 ± 5 | 40 s |
Temperature | Relative Humidity | Dimensions | Weight |
---|---|---|---|
−45–+45 °C | ≤95% rh | 180 × 270 mm | 3.2 kg |
4. Conclusions
- (1)
- A new solar tracking system was designed using COSMOS Motion, which performed a simulation analysis and demonstrated the expected motion trail in the absence of an interference phenomenon.
- (2)
- In this study, we successfully implemented a tracking solar power system. In northeast China, during the winter season, the days are relatively short. As a result, northeast China receives sunlight for a shorter duration of time. Therefore, very little power is generated by fixed solar panels during winter. However, with the newly designed solar auto tracking system, the power generation increased by 20% to 25% in winter. This novel system produced power rapidly and effectively.
- (3)
- A regression analysis was conducted to assess the power produced by the solar auto tracking system and fixed solar panels. The experimental results showed a positive relationship between the power generated by both the methods and the amount of solar irradiance. The higher ratio of power generated by both the solar methods was also positively associated with the average solar irradiance. The results of this study would serve to enhance solar power research throughout China.
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Zhang, Q.-X.; Yu, H.-Y.; Zhang, Q.-Y.; Zhang, Z.-Y.; Shao, C.-H.; Yang, D. A Solar Automatic Tracking System that Generates Power for Lighting Greenhouses. Energies 2015, 8, 7367-7380. https://doi.org/10.3390/en8077367
Zhang Q-X, Yu H-Y, Zhang Q-Y, Zhang Z-Y, Shao C-H, Yang D. A Solar Automatic Tracking System that Generates Power for Lighting Greenhouses. Energies. 2015; 8(7):7367-7380. https://doi.org/10.3390/en8077367
Chicago/Turabian StyleZhang, Qi-Xun, Hai-Ye Yu, Qiu-Yuan Zhang, Zhong-Yuan Zhang, Cheng-Hui Shao, and Di Yang. 2015. "A Solar Automatic Tracking System that Generates Power for Lighting Greenhouses" Energies 8, no. 7: 7367-7380. https://doi.org/10.3390/en8077367
APA StyleZhang, Q. -X., Yu, H. -Y., Zhang, Q. -Y., Zhang, Z. -Y., Shao, C. -H., & Yang, D. (2015). A Solar Automatic Tracking System that Generates Power for Lighting Greenhouses. Energies, 8(7), 7367-7380. https://doi.org/10.3390/en8077367