Year 2022,
, 960 - 970, 31.12.2022
Ahmet Elbir
,
Feyza Akarslan Kodaloğlu
,
Mehmet Erhan Şahin
,
İbrahim Üçgül
References
- [1] Lecompte, S., Oyewunmi, O. A., Markides, C. N., Lazova, M., Kaya, A., Van den Broek, M., & De Paepe, M. (2017). Case study of an organic rankine cycle (ORC) for waste heat recovery from an electric arc furnace (EAF). Energies, 10(5), 649.
- [2] Javanshir, A., Sarunac, N., & Razzaghpanah, Z. (2017). Thermodynamic analysis of ORC and its application for waste heat recovery. Sustainability, 9(11), 1974.
- [3] Ahmadi, M. H., Alhuyi Nazari, M., Ghasempour, R., Pourfayaz, F., Rahimzadeh, M., & Ming, T. (2018). A review on solar‐assisted gas turbines. Energy Science & Engineering, 6(6), 658-674.
- [4] Nassar, A., Mehta, N., Rudenko, O., Moroz, L., & Giri, G. (2018). Design of Waste Heat Recovery System based on ORC for a Locomotive Gas Turbine.
- [5] Kaşka, Ö., Onur, B. O. R., Tokgöz, N., & Aksoy, M. M. (2020). First and second law evaluation of combined Brayton-Organic Rankine power cycle. Journal of Thermal Engineering, 6(4), 577-591.
- [6] Ren, J., Cao, Y., Long, Y., Qiang, X., & Dai, Y. (2019). Thermodynamic comparison of gas turbine and ORC combined cycle with pure and mixture working fluids. Journal of Energy Engineering, 145(1), 05018002.
- [7] Kaşka, Ö., Onur, B. O. R., Tokgöz, N., & Aksoy, M. M. (2020). First and second law evaluation of combined Brayton-Organic Rankine power cycle. Journal of Thermal Engineering, 6(4), 577-591.
- [8] Espinel Blanco, E., Valencia Ochoa, G., & Duarte Forero, J. (2020). Thermodynamic, exergy and environmental impact assessment of S-CO2 brayton cycle coupled with ORC as bottoming cycle. Energies, 13(9), 2259.
- [9] Gürgen, S., & Altin, İ. (2022). Novel decision-making strategy for working fluid selection in Organic Rankine Cycle: A case study for waste heat recovery of a marine diesel engine. Energy, 124023.
- [10] Menegazzo, D., Bobbo, S., Fedele, L., De Carli, M., Carnieletto, L., Emmi, G., ... & Bernardi, A. (2021). Thermodynamic Analysis for the Selection of low GWP Refrigerants in Ground Source Heat Pumps.
- [11] James, S. J. (2013). Refrigeration Systems. In Handbook of Food Factory Design (pp. 385-402). Springer, New York, NY.
- [12] Dincer, I., & Rosen, M. A. (2012). Exergy: energy, environment and sustainable development. Newnes.
- [13] Cengel, Y. A., Boles, M. A., & Kanoğlu, M. (2011). Thermodynamics: an engineering approach (Vol. 5, p. 445). New York: McGraw-hill.
- [14] Klein, S. A., & Alvarado, F. L. (2002). Engineering equation solver. F-Chart Software, Madison, WI, 1.
Thermodynamic Analysis of a Combined Gas Turbine ORC Using Some Organic Fluids
Year 2022,
, 960 - 970, 31.12.2022
Ahmet Elbir
,
Feyza Akarslan Kodaloğlu
,
Mehmet Erhan Şahin
,
İbrahim Üçgül
Abstract
The increase in energy and environmental problems from day to day has led us to use sustainable methods of optimizing energy systems. In this study, mass flow rates, pressure ratios, net powers and thermodynamic calculations were performed by adding the integrated organic rankine cycle (ORC) to the waste heat of a gas turbine (GT) on behalf of innovative concepts in industrial competition and operating five different fluids (R123, R245fa, R600a, R236ea and R134a) with a specific heat in this ORC system. The gas turbine integrated with the R123 refrigerant was found to provide the best net power. The mass, energy, and exergy destructions for each component are summarized in tables separately. The energy efficiency of the designed integrated cystream was calculated as 66%, and the exergy efficiency was calculated as 20%. It is seen that the importance of sustainable energy in the optimization of power systems combined with ORC is inevitable.
References
- [1] Lecompte, S., Oyewunmi, O. A., Markides, C. N., Lazova, M., Kaya, A., Van den Broek, M., & De Paepe, M. (2017). Case study of an organic rankine cycle (ORC) for waste heat recovery from an electric arc furnace (EAF). Energies, 10(5), 649.
- [2] Javanshir, A., Sarunac, N., & Razzaghpanah, Z. (2017). Thermodynamic analysis of ORC and its application for waste heat recovery. Sustainability, 9(11), 1974.
- [3] Ahmadi, M. H., Alhuyi Nazari, M., Ghasempour, R., Pourfayaz, F., Rahimzadeh, M., & Ming, T. (2018). A review on solar‐assisted gas turbines. Energy Science & Engineering, 6(6), 658-674.
- [4] Nassar, A., Mehta, N., Rudenko, O., Moroz, L., & Giri, G. (2018). Design of Waste Heat Recovery System based on ORC for a Locomotive Gas Turbine.
- [5] Kaşka, Ö., Onur, B. O. R., Tokgöz, N., & Aksoy, M. M. (2020). First and second law evaluation of combined Brayton-Organic Rankine power cycle. Journal of Thermal Engineering, 6(4), 577-591.
- [6] Ren, J., Cao, Y., Long, Y., Qiang, X., & Dai, Y. (2019). Thermodynamic comparison of gas turbine and ORC combined cycle with pure and mixture working fluids. Journal of Energy Engineering, 145(1), 05018002.
- [7] Kaşka, Ö., Onur, B. O. R., Tokgöz, N., & Aksoy, M. M. (2020). First and second law evaluation of combined Brayton-Organic Rankine power cycle. Journal of Thermal Engineering, 6(4), 577-591.
- [8] Espinel Blanco, E., Valencia Ochoa, G., & Duarte Forero, J. (2020). Thermodynamic, exergy and environmental impact assessment of S-CO2 brayton cycle coupled with ORC as bottoming cycle. Energies, 13(9), 2259.
- [9] Gürgen, S., & Altin, İ. (2022). Novel decision-making strategy for working fluid selection in Organic Rankine Cycle: A case study for waste heat recovery of a marine diesel engine. Energy, 124023.
- [10] Menegazzo, D., Bobbo, S., Fedele, L., De Carli, M., Carnieletto, L., Emmi, G., ... & Bernardi, A. (2021). Thermodynamic Analysis for the Selection of low GWP Refrigerants in Ground Source Heat Pumps.
- [11] James, S. J. (2013). Refrigeration Systems. In Handbook of Food Factory Design (pp. 385-402). Springer, New York, NY.
- [12] Dincer, I., & Rosen, M. A. (2012). Exergy: energy, environment and sustainable development. Newnes.
- [13] Cengel, Y. A., Boles, M. A., & Kanoğlu, M. (2011). Thermodynamics: an engineering approach (Vol. 5, p. 445). New York: McGraw-hill.
- [14] Klein, S. A., & Alvarado, F. L. (2002). Engineering equation solver. F-Chart Software, Madison, WI, 1.