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dc.contributor.author | Shakil, Md. Reduan Afroj | |
dc.date.accessioned | 2024-04-25T05:57:53Z | |
dc.date.available | 2024-04-25T05:57:53Z | |
dc.date.issued | 2023-05-30 | |
dc.identifier.citation | 1. Turchi, C., Ma, Z., and Dyreby, J., 2012, “Supercritical CO2 for Application in Concentrating Solar Power Systems,” Proceedings of ASME Turbo Expo 2012, Copenhagen, Denmark, June 11–15. 2. Ma, Z., and Turchi, C., 2011, “Advanced Supercritical Carbon Dioxide Power Cycle Configurations for Use in Concentrating Solar Power Systems,” Proceedings of Supercritical CO2 Power Cycle Symposium 2011, Boulder, CO, May 24–25. 3. Wright, S. A., 2012, “Mighty Mite,” Mechanical Engineering, ASME, New York, pp. 40– 43. 4. Pasch, J., Conboy, T., Fleming, D., and Rochau, G., 2012, “Supercritical CO2 Recompression Brayton Cycle: Completed Assembly Description,” Sandia National Laboratories, SAND2012-9546. 5. Robb, D., 2012, “Supercritical CO2—The Next Big Step?,” Turbomachinery International, Business Journals, Inc., Norwalk, CT, pp. 22–28. 6. NREL, U.S. Dept. of Energy, “10-Megawatt Supercritical Carbon Dioxide Turbine,” project factsheet available at: http://www1.eere.energy.gov/solar/sunshot/ csp_sunshotrnd_nrel_turbine.html 7. Dostal, V., Hejzlar, P., and Driscoll, M. J., 2006, “High-Performance Supercritical NextGeneration Nuclear Reactors,” Nucl. Technol., 154, pp. 265–282. 8. Dostal, V., Hejzlar, P., and Driscoll, M. J., 2006, “The Supercritical Carbon Dioxide Power Cycle: Comparison to Other Advanced Power Cycles,” Nucl. Technol., 154, pp. 283–282. 50 9. Argonne National Laboratory, 2007, “Performance Improvement Options for the Supercritical Carbon Dioxide Brayton Cycle,” ANL-GenIV-103. 10. Kulha´nek, M., and Dostal, V., 2011, “Thermodynamic Analysis and Comparison of Supercritical Carbon Dioxide Cycles,” Proceedings of Supercritical CO2 Power Cycle Symposium 2011, Boulder, CO, May 24–25. 11. Johnson, G., and McDowell, M., 2009, “Issues Associated With Coupling Supercritical CO2 Power Cycles to Nuclear, Solar and Fossil Fuel Heat Sources,” Proceedings of Supercritical CO2 Power Cycle Symposium 2009, RPI, Troy, NY, April 29–30. 12. Chacartegui, R., Mun˜oz de Escalona, J. M., Sa´nchez, D., Monje, B., and Sa´nchez, T., 2011, “Alternative Cycles Based on Carbon Dioxide for Central Receiver Solar Power Plants,” Appl. Thermal Eng., 31, pp. 872–879. 13. Moisseytsev, A., and Sienicki, J. J., 2010, “Extension of the Supercritical Carbon Dioxide Brayton Cycle for Application to the Very High Temperature Reactor,” Proceedings of ICAPP’10, San Diego, CA, June 13–17, Paper No. 10070. 14. Seidel, W., 2010, “Model Development and Annual Simulation of the Supercritical Carbon Dioxide Brayton Cycle for Concentrating Solar Power Applications,” University of Wisconsin–Madison, Madison, WI. 15. Klein, S. A., 2012, “EES—Engineering Equation Solver,” F-Chart Software, http://www.fchart.com 16. Dostal, V., Driscoll, M. J., and Hejzlar, P., 2004, “A Supercritical Carbon Dioxide Cycle for Next Generation Nuclear Reactors,” Design MIT-ANP-TR-100, Advanced Nuclear Power Technology Program, MIT. 51 17. Nellis, G., and Klein, S. A., 2008, Heat Transfer, Cambridge University Press, Cambridge, MA, Chap. 8. 18. Wright, S. A., Radel, R. F., Vernon, M. E., Rochau, G. E., and Pickard, P. S., 2010, “Operation and Analysis of a Supercritical CO2 Brayton Cycle,” Sandia Report, No. SAND2010-0171. 19. Fuller, R. L., and Batton, W., 2009, “Practical Considerations in Scaling Supercritical Carbon Dioxide Closed Brayton Cycle Power Systems,” Proceedings of Supercritical CO2 Power Cycle Symposium 2009, RPI, Troy, NY, April 29–30. 20. Wright, S., Conboy, A. T., Parma, E., Rochau, G., and Suo-Anttila, A. J., 2011, “Summary of the Sandia Supercritical CO2 Development Program,” Proceedings of Supercritical CO2 Power Cycle Symposium 2011, Boulder, CO, May 24–25. 21. Dyreby, J., Klein, S., Nellis, G., and Reindl, D., 2011, “Development of Advanced Models for Supercritical Carbon Dioxide Power Cycles for Use in Concentrating Solar Power Systems,” Report to Subcontract No. AXL-0- 40301-1, National Renewable Energy Laboratory, Golden, CO. 22. Dostal, V., and Kulhanek, M., 2009, “Research on the Supercritical Carbon Dioxide Cycles in the Czech Republic,” Proceedings of Supercritical CO2 Power Cycle Symposium, RPI, Troy, NY, April 29–30. 23. Gong, Y., Carstens, N. A., Driscoll, M. J., and Matthews, I. A., 2006, “Analysis of Radial Compressor Options for Supercritical CO2 Power Conversion Cycles,” MIT-GFR-034. 24. Kolb, G. J., Ho, C. K., Mancini, T. R., and Gary, J. A., 2011, “Power Tower Technology Roadmap and Cost Reduction Plan,” SAND2011-2419, Sandia National Laboratories, Albuquerque, NM. 52 25. Wagner, M. J., and Kutscher, C., 2010, “The Impact of Hybrid Wet/Dry Cooling on Concentrating Solar Power Plant Performance,” Proceedings of the 4th International Conference on Energy Sustainability. 26. IPSEpro software, http://www.simtechnology.com/IPSEpro/english/IPSEpro.php 27. Southall, D., 2011, “Diffusion Bonding in Compact Heat Exchangers,” Proceedings of Supercritical CO2 Power Cycle Symposium 2011, Boulder, CO, May 24–25. 28. Feher, E. G., 1967, “Supercritical Thermodynamic Power Cycle,” Proceeding of the IECEC, Miami Beach, FL, August 13–17. 29. Angelino, G., 1967, “Perspectives for the Liquid Phase Compression Gas Turbine,” ASME J. Eng. Power, 89, pp. 229–237. 30. Angelino, G., 1968, “Carbon Dioxide Condensation Cycles for Power Production,” ASME J. Eng. Power, 90, pp. 287–295. 31. Angelino, G., 1969, “Real Gas Effects in Carbon Dioxide Cycles,” ASME Paper No. 69- GT-103. 32. Dostal, V., Hejzlar, P., and Driscoll, M. J., 2006, “The Supercritical Carbon Dioxide Power Cycle: Comparison to Other Advanced Power Cycles,” Nucl. Technol., 154(3), pp. 283– 301. 33. Sarkar, J., 2009, “Second Law Analysis of Supercritical CO2 Recompression Brayton Cycle,” Energy, 34(9), pp. 1172–1178. 34. Sarkar, J., and Bhattacharyya, S., 2009, “Optimization of Recompression S-CO2 Power Cycle With Reheating,” Energy Convers. Manage., 50(8), pp. 1939–1945. 53 35. Moisseytsev, A., and Sienicki, J. J., 2009, “Investigation of Alternative Layouts for the Supercritical Carbon Dioxide Brayton Cycle for a Sodium-Cooled Fast Reactor,” Nucl. Eng. Des., 239(7), pp. 1362–1371. 36. Jeong, W. S., Lee, J. I., and Jeong, Y. H., 2011, “Potential Improvements of Supercritical Recompression CO2 Brayton Cycle by Mixing Other Gases for Power Conversion System of a SFR,” Nucl. Eng. Des., 241(6), pp. 2128–2137. 37. Turchi, C. S., 2009, “Supercritical CO2 for Application in Concentrating Solar Power Systems,” Proceedings of SCCO2 Power Cycle Symposium, Troy, NY, April 29–30. 38. Turchi, C. S., Ma, Z., Neises, T., and Wagner, M., 2012, “Thermodynamic Study of Advanced Supercritical Carbon Dioxide Power Cycles for High Performance Concentrating Solar Power Systems,” ASME 2012 6th International Conference on Energy Sustainability (ES2012), San Diego, CA, July 23–26, ASME Paper No. ES2012-91179. 39. “SunShot Initiative,” 2013, U.S. Department of Energy, www1.eere.energy. gov/solar/sunshot/ 40. Hung, T. C., Shai, T. Y., Wang, S. K., 1997, “A Review of Organic Rankie Cycles (ORCs) for the Recovery of Low-Grade Waste Heat,” Energy, 22(7), pp. 661–667. 41. Chacartegui, R., Mu~ noz de Escalona, J. M., S anchez, D., Monje, B., and S anchez, T., 2011, “Alternative Cycles Based on Carbon Dioxide for Central Receiver Solar Power Plants,” Appl. Therm. Eng., 31(5), pp. 872–879. 42. S anchez, D., Brenes, B. M., de Escalona, J. M. M., and Chacartegui, R., 2012, “NonConventional Combined Cycle for Intermediate Temperature Systems,” Int. J. Energy Res., 37(5), pp. 403–411. 54 43. Kulh anek, M., and Dostal, V., 2011, “Supercritical Carbon Dioxide Cycles Thermodynamic Analysis and Comparison,” Supercritical CO2 Power Cycle Symposium, Boulder, CO, May 24–25. 44. Lemmon, E. W., McLinden, M. O., and Huber, M. L., “NIST Reference Fluid Thermodynamic and Transport Properties—REFPROP,” National Institute of Standards and Technology, Gaithersburg, MD, NIST Standard Reference Database 23. 45. McDonald, C. F., 2003, “Recuperator Considerations for Future Higher Efficiency Microturbines,” Appl. Therm. Eng., 23(12), pp. 1463–1487. 46. Demirkaya, G., Besarati, S., Vasquez Padilla, R., Ramos Archibold, A., Goswami, D. Y., Rahman, M. M., and Stefanakos, E. L., 2012, “Multi-Objective Optimization of a Combined Power and Cooling Cycle for Low-Grade and Midgrade Heat Sources,” ASME J. Energy Resour. Technol., 134(3), p. 032002. 47. Chen, H., Goswami, D. Y., and Stefanakos, E. K., 2010, “A Review of Thermodynamic Cycles and Working Fluids for the Conversion of Low-Grade Heat,” Renewable Sustainable Energy Rev., 14(9), pp. 3059–3067. 48. Rayegan, R., and Tao, Y. X., 2011, “A Procedure to Select Working Fluids for Solar Organic Rankine Cycles (ORCs),” Renewable Energy, 36(2), pp. 659–670. | en_US |
dc.identifier.uri | http://hdl.handle.net/123456789/2096 | |
dc.description | Supervised by Dr. Mohammad Monjurul Ehsan, Associate Professor, Department of Mechanical and Production Engineering (MPE), Islamic University of Technology (IUT), Board Bazar, Gazipur-1704. Bangladesh | en_US |
dc.description.abstract | This paper presents an innovative approach for increasing the thermal efficiency of supercritical CO2 (SCO2) power cycles by incorporating partial cooling with a two-bottom organic rankine cycles (ORC). The SCO2 power cycles have gained significant attention in recent years as a promising alternative to traditional power cycles due to their high thermal efficiency, but there is still room for improvement. The proposed approach aims to achieve this by utilizing the heat rejected by the SCO2 cycle to generate additional power through an ORC, and by using multiple working fluids with different temperature and pressure ranges in the ORC. The review explores the fundamental concepts, advantages, limitations, and recent advancements related to this integrated approach. By examining a range of studies and publications, this review offers valuable insights into the performance, feasibility, and potential applications of the partial cooling cycle integrated with ORCs in different settings. In conclusion, the proposed approach of combining partial cooling with a two-bottom ORC has the potential to improve the thermal efficiency of SCO2 power cycles. The results of this study demonstrate that this approach is a promising solution for increasing the performance of SCO2 power cycles. More research is needed, however, to fully evaluate the feasibility of implementing this method in real-world applications. | en_US |
dc.language.iso | en | en_US |
dc.publisher | Department of Mechanical and Production Engineering(MPE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh | en_US |
dc.subject | Supercritical CO2 , Partial cooling, Two-bottom ORC , Waste heat management , Efficiency improvement | en_US |
dc.title | Thermodynamic analysis of Supercritical CO2 Partial Cooling Cycle integrated with two Organic Rankine Cycles | en_US |
dc.type | Thesis | en_US |