An Overview of Electricity Generation by Solar & its Tracking System
Abstract
Sun-powered vitality is produced by daylight. It may be a renewable vitality source that’s not ecologically neighborly and never vanishes. Each hour, sufficient sun- oriented vitality reaches the soil to meet the world’s vitality needs for one year. Today’s era required to power each hour. This solar energy is generated for mechanical, commercial, residential, and other employment. You’ll be able effortlessly to extricate vitality from direct daylight. So, it is exceptionally proficient and free of encompassing environmental contamination. In this article, we surveyed sun-oriented energy from daylight and talked about its future patterns and aspects. This article too depicts the sorts of sun-oriented boards that work. Highlights the diverse applications and strategies for advancing the benefits of sun-based vitality. This paper bargains with the power era utilizing sun-powered power. The proposed framework guarantees the optimization of the conversion of sun-powered vitality into power by legitimately orienting the board in agreement with the position of the sun. The paper works by having a Stepper engine move a board in accordance with the sun's focused light as sensed by a light sensor. The greatest choice in this situation to boost photovoltaic panel efficiency is a solar tracking device. Throughout the day, solar trackers shift the payload in the direction of the sun. This essay discusses many tracking system varieties, as well as the advantages and disadvantages of each. According to the results of this study, the dual axis azimuth and altitude tracking system is superior than other tracking systems. However, a single axis tracking system is more practical than a dual axis tracking system from a cost and flexibility perspective.
Keywords
Full Text:
PDFReferences
Sharma, S., Jain, K.K. and Sharma, A., 2015. Solar cells: in research and applications—a review. Materials Sciences and Applications, 6(12), p.1145
A book on solar energy by Dr. S. P. Sukhatme, Published by Tata McGraw Hill.
Romero, M., Lemuz, R., Ayaquica-Martinez, I.O. and Saldana- Gonz, G., 2011, November. A calibration algorithm for solar tracking system. In 2011 10th Mexican International Conference on Artificial Intelligence (pp. 139-143). IEEE.
CRC Press book on Wind and Solar Power Plants by Mukund Patel.
Chen, C.J., 2011. Physics of solar energy. John Wiley & Sons.
Askari Mohammad Bagher, Mirzaei Mahmoud Abadi Vahid, Mirhabibi Mohsen. “Types and uses of solar cells”. American Journal of Optics and photonics.Vol. 3, No. 5, 2015, pp. 94-113.
Doi: 10.11648 / j. ajop.20150305.17
Gupta, N., Alapatt, G.F., Podila, R., Singh, R., and Poole, K.F., 2009. Prospects of nanostructure-based solar cells for manufacturing future generations of photovoltaic modules. International Journal of Photoenergy, 2009.
Gaurav A. Maiduguri, S. R. Karale, “High Solar Energy Concentration Using Fresnel Lenses: A Review,” Vol. 2, Issue 3, May-June 2012 pp-1381-1385 ISSN: 2249664
Mashohor, S., Samsudin, K., Noor, A.M., and Rahman, A.R.A., 2008, November. Evaluation of genetic algorithm-based solar tracking system for photovoltaic panels. In 2008 IEEE International Conference on Sustainable Energy Technologies (pp. 269-273). IEEE.
Kassem, A. and Hamad, M., 2011, April. A microcontroller- based multi-function solar tracking system. In 2011 IEEE International Systems Conference (pp. 13-16). IEEE.
Saxena, A.K. and Dutta, V., 1990. A versatile microprocessor- based controller for solar tracking.
Khan, M.T.A., Tanzil, S.S., Rahman, R. and Alam, S.S., 2010, December. Design and construction of an automatic solar tracking system. In International Conference on Electrical & Computer Engineering (ICECE 2010) (pp. 326-329). IEEE.
Koyuncu, B. and Balasubramanian, K., 1991. A microprocessor-controlled automatic sun tracker. IEEE Transactions on Consumer Electronics, 37(4), pp.913-917.
Bingol, O., Altintas, A. and Oner, Y., 2006. Microcontroller- based solar-tracking system and its implementation.
M. F. Khan, R. L. Ali, “Automatic sun tracking system”, IEEE 2005.
Stjepanović, A., Stjepanović, S., Softić, F. and Bundalo, Z., 2009, October. Microcontroller-based solar tracking system. In 2009 9th International Conference on Telecommunication in Modern Satellite, Cable, and Broadcasting Services (pp. 518-521). IEEE.
Oo, L.L. and Hlaing, N.K., 2010, May. Microcontroller-based two-axis solar tracking system. In 2010 second international conference on computer research and development (pp. 436-440). IEEE.
Han, S., Han, Y. and Han, M., 2012, March. Research and Implementation of the Dual Mode Solar Automatic Tracking System. In 2012 Asia-Pacific Power and Energy Engineering Conference (pp. 1-4). IEEE.
Zhao, X., 2011, September. Research on automatic tracking solar power systems. In 2011 International Conference on Electrical and Control Engineering (pp. 296-299). IEEE.
Gies for Wastewater Treatment. I: Oxidation Technologies at Ambient Conditions,” Adv. Environ. Res., 8, pp. 501–551.
Gogate, P.R. and Pandit, A.B., 2004. A review of imperative technologies for wastewater treatment II: hybrid methods. Advances in environmental research, 8(3-4), pp.553-597.
Refbacks
- There are currently no refbacks.
Copyright (c) 2022 Journal of Thermal Engineering and Applications