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Setareh, Milad, Assari, Mohammad Reza. (1403). Mathematical study on performance enhancement of solar updraft tower power plant by hot gas injection from an external source. نشریه مهندسی عمران امیرکبیر, 7(3), 241-260. doi: 10.22060/ajme.2024.22382.6064
Milad Setareh; Mohammad Reza Assari. "Mathematical study on performance enhancement of solar updraft tower power plant by hot gas injection from an external source". نشریه مهندسی عمران امیرکبیر, 7, 3, 1403, 241-260. doi: 10.22060/ajme.2024.22382.6064
Setareh, Milad, Assari, Mohammad Reza. (1403). 'Mathematical study on performance enhancement of solar updraft tower power plant by hot gas injection from an external source', نشریه مهندسی عمران امیرکبیر, 7(3), pp. 241-260. doi: 10.22060/ajme.2024.22382.6064
Setareh, Milad, Assari, Mohammad Reza. Mathematical study on performance enhancement of solar updraft tower power plant by hot gas injection from an external source. نشریه مهندسی عمران امیرکبیر, 1403; 7(3): 241-260. doi: 10.22060/ajme.2024.22382.6064

Mathematical study on performance enhancement of solar updraft tower power plant by hot gas injection from an external source

AUT Journal of Mechanical Engineering
دوره 7، شماره 3، 2023، صفحه 241-260    اصل مقاله (2.55 M)
نوع مقاله: Research Article
شناسه دیجیتال (DOI): 10.22060/ajme.2024.22382.6064
نویسندگان
Milad Setareh* ؛ Mohammad Reza Assari
Jundi-Shapur Research Institute, Jundi-Shapur University of Technology, Dezful, Iran- Department of Mechanical Engineering, Jundi-Shapur University of Technology, Dezful, Iran
چکیده
 In this paper, a theoretical model for simulation of a solar updraft tower power plant with the assumption of axisymmetric condition is developed to study the impact of hot gas injection at the chimney base as well as extraction of a portion of hot gas after the turbine and re-entered it at the collector inlet. A new computational code is written by Matlab software and the effects of operational parameters are studied. Results show that the maximum power output is increased by 49.9% by increasing the extraction fraction from 0% to 40% at a wind velocity of 10 m/s. Besides, the obtained results show that the power output is enhanced as the mass flow rate of hot gas increases. As a result, the maximum power output at a hot gas mass flow rate of 30 kg/s is approximately 37% higher than the one at a hot gas mass flow rate of 10 kg/s. Results reveal that the optimum performance of SUTPP takes place at the ratio of pressure drop across the turbine to driving pressure potential in the range from 0.83 to 0.87. Furthermore, the power output in the presence of wind is investigated and the positive influence of wind is illustrated. Results indicate that by increasing the wind velocity from 10 m/s to 30 m/s, the maximum power output is increased by 386.1%
کلیدواژه‌ها
Theoretical model؛ Solar updraft tower power plant؛ Hot gas injection؛ Driving pressure potential؛ Wind
مراجع
  1. Cabanyes, Las Chimeneassolares (Solar Chimneys), La Ernergiaeléctr., (1903).
  2. Zuo, L. Ding, Y. Yuan, Z. Liu, N. Qu, P. Dai, Research progress on integrated solar chimney system for freshwater production, Global Energy Interconnection, 2(3) (2019) 214-223.
  3. Haaf, Solar Chimneys, International Journal of Solar Energy, 2(2) (1984) 141-161.
  4. Haaf, K. Friedrich, G. Mayr, J. Schlaich, Solar Chimneys Part I: Principle and Construction of the Pilot Plant in Manzanares, International Journal of Solar Energy, 2(1) (1983) 3-20.
  5. Balijepalli, V.P. Chandramohan, K. Kirankumar, A complete design data and performance parameter evaluation of a pilot scale solar updraft tower, Heat Transfer Engineering, 41(6-7) (2020) 562-575.
  6. Das, V.P. Chandramohan, 3D numerical study on estimating flow and performance parameters of solar updraft tower (SUT) plant: Impact of divergent angle of chimney, ambient temperature, solar flux and turbine efficiency, Journal of Cleaner Production, 256 (2020) 120353.
  7. Semai, A. Bouhdjar, S. Larbi, Canopy slope effect on the performance of the solar chimney power plant, International Journal of Green Energy, 14(3) (2017) 229238.
  8. Guo, Y. Zhou, D. Zhang, B. Xu, J. Li, Numerical investigation and multi-objective thermo-economic optimization of a solar chimney power plant, International Journal of Energy Research, 45(7) (2021) 10317-10331.
  9. Nizetic, B. Klarin, A simplified analytical approach for evaluation of the optimal ratio of pressure drop across the turbine in solar chimney power plants, Applied Energy, 87(2) (2010) 587-591.
  10. M. Padki, S.A. Sherif, A mathematical model for solar chimneys, in: Renewable energy, University of Joardn, 1992, pp. 289-294.
  11. Pasumarthi, S.A. Sherif, Experimental and theoretical performance of a demonstration solar chimney model— Part II: experimental and theoretical results and economic analysis, International Journal of Energy Research, 22(5) (1998) 443-461.
  12. Koonsrisuk, T. Chitsomboon, Dynamic similarity in solar chimney modeling, Solar Energy, 81(12) (2007) 1439-1446.
  13. Koonsrisuk, T. Chitsomboon, A single dimensionless variable for solar chimney power plant modeling, Solar Energy, 83(12) (2009) 2136-2143.
  14. Koonsrisuk, Mathematical modeling of sloped solar chimney power plants, Energy, 47(1) (2012) 582-589.
  15. Sangi, M. Amidpour, B. Hosseinizadeh, Modeling and numerical simulation of solar chimney power plants, Solar Energy, 85(5) (2011) 829-838.
  16. Sangi, Performance evaluation of solar chimney power plants in Iran, Renewable and Sustainable Energy Reviews, 16(1) (2012) 704-710.
  17. Balijepalli, V.P. Chandramohan, K. Kirankumar, Performance parameter evaluation, materials selection, solar radiation with energy losses, energy storage and turbine design procedure for a pilot scale solar updraft tower, Energy Conversion and Management, 150 (2017) 451-462.
  18. H. Ali, Z. Kurjak, J. Beke, Modelling and simulation of solar chimney power plants in hot and arid regions using experimental weather conditions, International Journal of Thermofluids, 20 (2023) 100434.
  19. P. Singh, J. Singh, A. Kumar, O.P. Singh, Vertical limit reduction of chimney in solar power plant, Renewable Energy, 217 (2023) 119118.
  20. Toghraie, A. Karami, M. Afrand, A. Karimipour, Effects of geometric parameters on the performance of solar chimney power plants, Energy, 162 (2018) 10521061.
  21. Nasraoui, Z. Driss, A. Ayedi, H. Kchaou, Numerical and Experimental Study of the Aerothermal Characteristics in Solar Chimney Power Plant with Hyperbolic Chimney Shape, Arabian Journal for Science and Engineering, 44(9) (2019) 7491-7504.
  22. Nasraoui, Z. Driss, H. Kchaou, Novel collector design for enhancing the performance of solar chimney power plant, Renewable Energy, 145 (2020) 1658-1671.
  23. Asnaghi, S.M. Ladjevardi, Solar chimney power plant performance in Iran, Renewable and Sustainable Energy Reviews, 16(5) (2012) 3383-3390.
  24. A. Sedighi, Z. Deldoost, B.M. Karambasti, Effect of thermal energy storage layer porosity on performance of solar chimney power plant considering turbine pressure drop, Energy, 194 (2020) 116859.
  25. RahimiLarki, R.H. Abardeh, H. Rahimzadeh, H. Sarlak, Performance analysis of a laboratory-scale tilted solar chimney system exposed to ambient crosswind, Renewable Energy, 164 (2021) 1156-1170.
  26. Bagheri, M. Ghodsi Hassanabad, Numerical and experimental investigation of a novel vertical solar chimney power plant for renewable energy production in urban areas, Sustainable Cities and Society, 96 (2023) 104700.
  27. Kumar Mandal, N. Biswas, N.K. Manna, A.C. Benim, Impact of chimney divergence and sloped absorber on energy efficacy of a solar chimney power plant (SCPP), Ain Shams Engineering Journal, 15(2) (2024) 102390.
  28. J. Saleh, F.S. Atallah, S. Algburi, O.K. Ahmed, Enhancement methods of the performance of a solar chimney power plant: Review, Results in Engineering, 19 (2023) 101375.
  29. Koonsrisuk, T. Chitsomboon, Mathematical modeling of solar chimney power plants, Energy, 51 (2013) 314-322.
  30. P. Pretorius, D.G. Kröger, Solar Chimney Power Plant Performance, Journal of Solar Energy Engineering, 128(3) (2006) 302-311.
  31. Setareh, Comprehensive mathematical study on solar chimney powerplant, Renewable Energy, 175 (2021) 470-485.
  32. A. Kalogirou, Solar thermal collectors and applications, Progress in Energy and Combustion Science, 30(3) (2004) 231-295.
  33. J. Maghrebi, R. Masoudi Nejad, S. Masoudi, Performance analysis of sloped solar chimney power plants in the southwestern region of Iran, International Journal of Ambient Energy, 38(6) (2017) 542-549.
  34. Rahbar, A. Riasi, Performance enhancement and optimization of solar chimney power plant integrated with transparent photovoltaic cells and desalination method, Sustainable Cities and Society, 46 (2019) 101441.
  35. B. Hanna, T.A.-M. Mekhail, O.M. Dahab, M.F.C. Esmail, A.R. Abdel-Rahman, Performance Investigation of the Solar Chimney Power Plants Heater Case Study in Aswan, Egypt, Journal of Power and Energy Engineering, Vol.04No.10 (2016) 22.
  36. Zhou, M.A.d.S. Bernardes, R.M. Ochieng, Influence of atmospheric cross flow on solar updraft tower inflow, Energy, 42(1) (2012) 393-400.
  37. Zhou, Y. Xu, Pressure Losses in Solar Chimney Power Plant, Journal of Solar Energy Engineering, 140(2) (2018).
  38. E. Haaland, Simple and Explicit Formulas for the Friction Factor in Turbulent Pipe Flow, Journal of Fluids Engineering, 105(1) (1983) 89-90.
  39. r. Schlaich , R. Bergermann , W. Schiel , G. Weinrebe, Design of Commercial Solar Updraft Tower Systems— Utilization of Solar Induced Convective Flows for Power Generation, Journal of Solar Energy Engineering, 127(1) (2005) 117-124.
  40. -h. Guo, J.-y. Li, Y. Wang, Numerical simulations of solar chimney power plant with radiation model, Renewable Energy, 62 (2014) 24-30.
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