A novel trigeneration system using geothermal heat source and liquefied natural gas cold energy recovery: Energy, exergy and exergoeconomic analysis

Renewable Energy

Volumn 119, Issue , 2018, Pages 513-527

  Ghaebi, Hadi ^a   Parikhani, Towhid ^a   Rostamzadeh, Hadi ^a  

^a UNIVERSITY OF MOHAGHEGH ARDABILI   (Iran)

Author keywords

Energy analysis; Exergoeconomic analysis; Exergy analysis; Geothermal; LNG; Trigeneration

Indexed keywords

ABSORPTION REFRIGERATION; AMMONIA; COLD WORKING; EVAPORATORS; EXERGY; GEOTHERMAL ENERGY; HEATING; LIQUEFIED NATURAL GAS; RANKINE CYCLE; RECOVERY; REFRIGERATORS; THERMOELECTRIC POWER; WASTE HEAT;

COLD ENERGY; ENERGY ANALYSIS; EXERGOECONOMIC ANALYSIS; EXERGY ANALYSIS; EXERGY EFFICIENCIES; GEOTHERMAL; HEAT SOURCES; THERMAL-EFFICIENCY; TRI-GENERATION; TRIGENERATION SYSTEMS;

TEMPERATURE;

ABSORPTION; AMMONIA; COOLING; EXERGY; HEAT SOURCE; HEATING; LIQUEFIED NATURAL GAS; POWER GENERATION; PUMP; SIMULATION;

EID: 85038822628     PISSN: 09601481     EISSN: 18790682     Source Type: Journal    
DOI: 10.1016/j.renene.2017.11.082     Document Type: Article

References (32)

1. Li, H., Zhang, X., Liu, L., Zeng, R., Zhang, G., Exergy and environmental assessments of a novel trigeneration system taking biomass and solar energy as co-feeds. Appl. Therm. Eng. 104 (2016), 697–706.
2. Al Moussawi, H., Fardoun, F., Louahlia, H., Selection based on differences between cogeneration and trigeneration in various prime mover technologies. Renew. Sust. Energy Rev. 74 (2017), 491–511.
3. Rostamzadeh, H., Ghaebi, H., Behnam, F., Energetic and exergetic analyses of modified combined power and ejector refrigeration cycles. Therm. Sci. Eng. Prog. 2 (2017), 119–139.
4. Rostamzadeh, H., Ebadollahi, M., Ghaebi, H., Amidpour, M., Kheiri, R., Energy and exergy analysis of novel combined cooling and power (CCP) cycles. Appl. Therm. Eng. 124 (2017), 152–169.
5. Renewables, Global Status Report., 2016, REN21 Steering Committee.
6. Chicco, G., Mancarella, P., Trigeneration primary energy saving evaluation for energy planning and policy development. Energy Policy 35 (2007), 6132–6144.
7. Yao, E., Wang, H., Wang, L., Xi, G., Marechal, F., Multi-objective optimization and exergoeconomic analysis of a combined cooling, heating and power based compressed air energy storage system. Energy Convers. Manag. 138 (2017), 199–209.
8. Anvari, S., Taghavifar, H., Parvishi, A., Thermo-economical consideration of regenerative organic Rankine cycle coupling with the absorption chiller systems incorporated in the trigeneration system. Energy Convers. Manag. 148 (2017), 317–329.
9. Baghernejad, A., Yaghoubi, M., Jafarpur, K., Exergoeconomic optimization and environmental analysis of a novel solar-trigeneration system for heating, cooling and power production purpose. Sol. Energ 134 (2016), 165–179.
10. Ghaebi, H., Saidi, M.H., Ahmadi, P., Exergoeconomic optimization of a trigeneration system for heating, cooling and power production purpose based on TRR method and using evolutionary algorithm. Appl. Therm. Eng. 36 (2012), 113–125.
11. Kerdan, I.G., Raslan, R., Ruyssevelt, P., Galvez, D.M., ExRET-Opt: an automated exergy/exergoeconomic simulation framework for building energy retrofit analysis and design optimization. Appl. Energy 192 (2017), 33–58.
12. Wang, J.J., Yang, Y., Energy, exergy and environmental analysis of a hybrid combined cooling heating and power system utilizing biomass and solar energy. Energy Convers. Manag. 124 (2016), 566–577.
13. Moradi, M., Mehrpooya, M., Optimal design and economic analysis of a hybrid solid oxide fuel cell and parabolic solar dish collector, combined cooling, heating and power (CCHP) system used for a large commercial tower. Energy 130 (2017), 530–543.
14. Boyaghchi, F.A., Chavoshi, M., Sabeti, V., Optimization of a novel combined cooling, heating and power cycle driven by geothermal and solar energies using the water/Cuo (copper oxide) nanofluid. Energy 91 (2015), 685–699.
15. Najibullah Khan, N.B., Barifcani, A., Tade, M., Pareek, V., A case study: application of energy and exergy analysis for enhancing the process efficiency of a three stage propane pre-cooling cycle of the cascade LNG process. J. Nat. Gas. Sci. Eng. 29 (2016), 125–133.
16. He, Y., Li, R., Chen, G., Wang, Y., A potential auto-cascade absorption refrigeration system for pre-cooling of LNG liquefaction. J. Nat. Gas. Sci. Eng. 24 (2015), 425–430.
17. Zhang, G., Xu, W., Yang, Y., Zhang, D., Utilization of LNG cryogenic energy in a proposed method for inlet air cooling to improve the performance of a combined cycle. Energy Procedia 61 (2014), 2109–2113.
18. Tsatsaronis, G., Morosuk, T., Advanced exergetic analysis of a novel system for generating electricity and vaporizing liquefied natural gas. Energy 35 (2010), 820–829.
19. Kanbur, B.B., Xiang, L., Dubey, S., Choo, F.H., Duan, F., Thermoeconomic assessment of a micro cogeneration system with LNG cold utilization. Energy 129 (2017), 171–184.
20. Zhang, G., Zheng, J., Yang, Y., Liu, W., A novel LNG cryogenic energy utilization method for inlet air cooling to improve the performance of combined cycle. Appl. Energy 179 (2016), 638–649.
21. Zhao, P., Wang, J.F., Dai, Y., Gao, L., Thermodynamic analysis of a hybrid energy system based on CAES system and CO2 transcritical power cycle with LNG cold energy utilization. Appl. Therm. Eng. 91 (2015), 718–730.
22. Zhang, M.G., Zhao, L.J., Liu, C., Cai, Y.L., Xie, X.M., A combined system utilizing LNG and low-temperature waste heat energy. Appl. Therm. Eng. 101 (2016), 525–536.
23. Kim, K.H., Kim, K.C., Thermodynamic performance analysis of a combined power cycle using low grade heat source and LNG cold energy. Appl. Therm. Eng. 70 (2014), 50–60.
24. Taheri, M.H., Mosaffa, A.H., Farshi, L.G., Energy, exergy, and economic assessments of a novel integrated biomass based multigeneration energy system with hydrogen production and LNG regasification cycle. Energy 125 (2017), 162–177.
25. Rostamzadeh H, Mostoufi K, Vosoughi S. Performance enhancement of combined cooling, heating and power (CCHP) system by ejector expanders. 7th International Conference & Workshop REMOO-2017, Energy for Tomorrow, 10–12 May 2017, Venice, Italy.
26. Ghaebi, H., Rostamzadeh, H., Matin, P.S., Performance evaluation of ejector expansion combined cooling and power cycles. Heat. Mass Transf., 2017, 10.1007/s00231-017-2034-.
27. Bejan, A., Advanced Engineering Thermodynamics. 1998, John Wiley & Sons, NY, USA.
28. Bejan, A., Tsataronis, G., Moran, M., Thermal design and Optimization. 1996, John Wiley & Sons, NY, USA.
29. Ghaebi, H., Parikhani, T., Rostamzadeh, H., Farhang, B., Thermodynamic and thermoeconomic analysis and optimization of a novel combined cooling and power (CCP) cycle by integrating of ejector refrigeration and Kalina cycles. Energy 139 (2017), 262–276.
30. Tesha. Absorption refrigeration system as an integrated condenser cooling unit in a geothermal power plant. MSc. Thesis, Department of Mechanical and Industrial Engineering, University of Iceland.
31. Herold, K.E., Radermacher, R., Klein, S.A., Absorption Chillers and Heat Pumps. second ed., 2016, CRC Press, UK.
32. Mosaffa, A.H., Mokarram, N.H., Farshi, L.G., Thermoeconomic analysis of combined different ORCs geothermal power plants and LNG cold energy. Geothermics 65 (2017), 113–125.