Open Access
E3S Web Conf.
Volume 288, 2021
International Symposium “Sustainable Energy and Power Engineering 2021” (SUSE-2021)
Article Number 01068
Number of page(s) 6
Published online 14 July 2021
  1. A. Ivanko, A. Kalinechenko, and N. Shmat “Solar Vegetation” Kiev. 2004;312 [Google Scholar]
  2. D.I. Karas, S.T. Mosin Ispol'zovanie teploty uhodyashchih gazov kotlov dlya teplosnabzheniya teplic. Promyshlennaya energetika, 1988, N°5 [Google Scholar]
  3. V.A. Kubis Proektirovanie i opyt ekspluatacii energoeffektivnyh teplic (na primere Penzenskoj oblasti) (Monografiya) Penza: PGUAS, 2014. - 128 s [Google Scholar]
  4. Banik P., Gangult A. Performance and economic analysis of a flori cultural greenhouse with distributed fan-pad evaporative cooling coupled with solar desiccation. SolEnergy 2017;147:439–47. [Google Scholar]
  5. Ahmed Solimon, Jerome Adams, and Chris Reidl, Senior Design project: Hybrid Energy Integrator, Drexel University, 2013. [Google Scholar]
  6. Taki M., Ajabshirchi Y., Ranjbar SF, Rohani A., Matloobi M. Heat transfer and MLP neural network models to predict inside environment variables and energy lost in a semi-solargreenhouse. Energy Build 2016;110:314–29. [Google Scholar]
  7. Kindelam M. Dynamic modeling of greenhouse environment. Trans ASAE 1980;23(5):1232–6. [Google Scholar]
  8. Arinze EA, Schoenau GJ, Besant RW. A dynamic thermal performance simulation model of energy conserving greenhouse with thermal storage. Trans ASAE 1984;27:508–19. [Google Scholar]
  9. Tiwari G.N. Analysis of winter greenhouse. Int J Sol Energy 1984;3:19–24. [Google Scholar]
  10. Gupta MJ, Chandra P. Effect of greenhouse design parameters on conservation of energy for greenhouse environmental control. Energy 2002;27:777–94. [Google Scholar]
  11. Their Future Is Green: The Clean-Energy Economy Promises An Engineering Jobs Bounty - Training Graduates With Right Skills, American Society for Engineering Education PRISM, pp. 38–41, 4/2010. [Google Scholar]
  12. Cossu M., Murgia L., Ledda L., Deligios PA, Sirigu A., Chessa F., et al. Solar radiation distribution inside a greenhouse with south-oriented photovoltaic roofs and effects on crop productivity. Appl Energy 2014;133:89–100. [Google Scholar]
  13. Hassan GE, Salah A.H., Fath, H., Elhelw, M., Hassan, A., Saqr K.M. Optimum operational performance of a new stand-alone agricultural greenhouse with integrated-TPV solar panels. Sol Energy 2016;136:303–16. [Google Scholar]
  14. Richard ChiouDr., Drexel University, Dr. Radian G Belu, Drexel University (Tech.) Prototype Design of a Solar Greenhouse Incorporating Clean Energy Manufacturing Concept/121 st ASEE Annual Conference & Exposition/ Indianapolis, IN June 1518, 2014 [Google Scholar]
  15. K. Saryyev, M. Orazberdiyeva, J. Batmanov, Selfcontained energy saving solar greenhouse. Science and technology journal of Turkmenistan, 2020, N°3. [Google Scholar]
  16. Ahmed Solimon, Jerome Adams, and Chris Reidl, Senior Design project: Hybrid Energy Integrator, Drexel University, 2013. [Google Scholar]
  17. P. Jennings, New directions in renewable energy education. International Journal of Renewable Energy, 34, 435–439, 2009. [Google Scholar]
  18. [Google Scholar]

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