Stochastic Process in the Concentrating System of a Solar Power Plant for Greenhouse Agriculture

Abstract

Agricultural greenhouses are usually located in the suburbs or remote areas away from towns, and generally speaking, the cost of transmission and power supply is high, and some remote areas do not even have  electricity  supply. However, traditional greenhouses contain many different electrical equipment and facilities, and a stable power supply is essential for the normal, economical and efficient operation of the greenhouse. Modern agricultural greenhouses also need to be equipped with complete lighting systems, temperature and humidity control systems, ventilation systems, carbon dioxide concentration controlsystems, irrigation sprinkler systems, etc., which are difficult for traditional greenhouses to achievesmoothly. Traditional greenhouses are usually covered with plastic film, which usually needs to be replaced every year, and the discarded plastic film does not meet the requirements of energy conservation and environmental protection. The problem of "thermal insulation" in greenhouses has also been plaguing greenhouse growers. From the perspective of planting cycle, traditional greenhouses are generally onlyplanted twice a year, and the economic benefits are limited.

References

1. Zhang, X., & Cao, R. (2021). Photovoltaic grid-connected power generation and its inverter control. Photovoltaic Grid-Connected Power Generation, (3), 16-17.
2. Ren, X. (2021). Solar photovoltaic power generation engineering technology. Solar Photovoltaic Power Generation, 16(4), 35-37.
3. Zhao, Z. (2020). Solar photovoltaic power generation and its application. Solar Photovoltaic Power Generation Applications, 23(4), 103-105.
4. Yang, G., Qiang, S., Zhang, Y., & Zheng, Y. (2021). Solar photovoltaic power generation system and its application. Solar Photovoltaic Power Generation System, 19(2), 31-38.
5. 5.Wang, D. (2018). Solar photovoltaic power generation technology and system integration. *Solar Photovoltaic Power Generation Technology, (127), 44-48.
6. Li, C., & Yang, X. (2020). Solar and wind energy grid connection technology. *Solar Power System, (8), 76-113.
7. Cui, R., Zhao, C., & Wu, D. (2021). Grid-connected photovoltaic power generation system. *Grid-Connected Photovoltaic Power Generation System Technology, 27*(1), 5.
8. Zhou, Z., & Ji, A. (2019). Design and construction technology of off-grid solar power system. *Solar Power Generation System Design, (8), 22.
9. Lu, M., Cen, H., & Guo, T. (2021). Research on the optimal allocation of greenhouse composite energy supply. *Research on Agricultural Mechanization, (1)(215), 66-69.
10. Liu, K., Feng, L., & Yang, W. (2017). Greenhouse microclimate characteristics and their relationship with macroclimate. Acta Meteorological Society, 24.
11. Liu, Y. (2011). Modeling and simulation of photovoltaic grid-connected power generation system. Power Generation System Modeling, 24.
12. Pugachev, V. S. (2020). Grid-connected control technology for photovoltaic power generation. CNKI, (17), 183–215.
13. i China PV Power Application. (2022, September 26). Retrieved September 26, 2022, from https://take-profit.org/statistics/imports/china/
14. Irwin, D. A. (2021). Operation control strategy of three-phase grid-connected photovoltaic power generation system. World Development, (139), 105-106.
15. Zhou, X., Guo, R., & Ma, Y. (2021). Control technology of photovoltaic grid-connected power generation system. Control Technology, 30(6), 15-27.
16. Wu, C., Zhang, J., & Chen, Y. (2020). Time solar photovoltaic grid-connected power generation and lighting system. Lighting System, (3), 29-36.
17. Wang, Z., Wang, R., Shi, T., & Wu, F. (2018). Modeling and simulation of grid-connected photovoltaic power generation system. Rural Electrification, 8(2), 95–108.
18. Lai, S. (2021). Research on the optimal allocation of greenhouse composite energy supply. Research on Agricultural Mechanization, (7), 16-20.
19. Li, Y. (2017). Greenhouse microclimate characteristics and their relationship with macroclimate. Meteorology, (11), 61-65.