Efficiency Study of a Natural Gas Liquefier Using Precooling Driven by Organic Rankine Cycle
Sofia V. Maslikova , Alexander S. Krotov , Georgii M. Kosenko , Pavel R. Sitnikov , Vsevolod O. Novikov
Refrigeration Technology ›› 2023, Vol. 112 ›› Issue (3) : 139 -148.
Efficiency Study of a Natural Gas Liquefier Using Precooling Driven by Organic Rankine Cycle
Technical and energy analyses of small-scale liquefied natural gas (LNG) plants using a precooling cycle based on the organic Rankine cycle (ORC) were conducted. The first step of the research included modeling and optimization of the natural gas mixed-refrigerant (MR) liquefaction cycle with propane vapor-compression cycle (VCR) precooling. Calculations were used to determine the value of heat and energy flows under various environmental conditions. The second step of the research included a simulation of ORC cycles using values of high-potential heat obtained earlier. The minimum possible cooling temperature was determined as the intersection point between the required cooling capacity and the possible cooling capacity of the ORC–VCR system. Performance data of ORC–VCR-type refrigerators using natural refrigerants were obtained and analyzed, and optimal operational modes were determined. The applicability of the ORC–VCR type refrigerators was considered using obtained data. The potential cost–benefit of the ORC–VCR systems was compared with those of traditional propane VCR systems.
AIMS: Feasibility study of ORC–VCR systems for the preliminary cooling of an autonomous small-scale plant for natural gas liquefaction plants.
MATERIALS AND METHODS: Natural gas liquefaction cycles and ORC–VCR cycles were simulated using the Aspen HYSYS software. Further optimization and parameter selection were performed using the MATLAB module Global Optimization Toolbox.
RESULTS: The cost–benefit value of the ORC–VCR precooling systems compared with the classic propane VCR refrigerators was found to be up to 15%, depending on the type of the Rankine cycle used and the type of working substance.
CONCLUSIONS: The authors analyzed the feasibility of ORC–VCR systems for the preliminary cooling of autonomous small-scale LNG plants. The application of ORC–VCR refrigerators using high-potential heat of exhaust gases from a diesel generator or an electric generator reduced the consumption of natural gas and specific costs of LNG production. The cost–benefit value compared with those of classic propane VCR refrigerators was up to 15%, depending on the type of the Rankine cycle used and the type of working substance.
LNG / ORC / VCR / MR / high-potential heat / cooling
| [1] |
Yin QS, Li HY, Fan QH, Jia LX. Economic Analysis of Mixed refrigerant Cycle and Nitrogen Expander Cycle in Small Scale Natural Gas Liquefier. AIP Conference Proceedings. 2008;985:1159. |
| [2] |
Yin Q.S., Li H.Y., Fan Q.H., Jia L.X. Economic Analysis of Mixed refrigerant Cycle and Nitrogen Expander Cycle in Small Scale Natural Gas Liquefier // AIP Conference Proceedings. 2008. Vol. 985. 1159. |
| [3] |
Pearson SF. Uses of Hydrocarbon Refrigerants. In: Proceedings of the IIR Conference on Applications for Natural Refrigerants. Aarhus: IIF/IIR; 1996:439–446. doi: 10.1063/1.2908467 |
| [4] |
Pearson S.F. Uses of Hydrocarbon Refrigerants. In: Proceedings of the IIR Conference on Applications for Natural Refrigerants. Aarhus: IIF/IIR, 1996. P. 439–446. doi: 10.1063/1.2908467 |
| [5] |
Voronov VA, Leonov VP, Apsit KA. Use of heat-utilizing vehicle refrigerating machine using diesel engine waste heat. Chemical and petroleum engineering. 2022;57:997–1007. doi: 10.1007/s10556-022-01037-9 |
| [6] |
Voronov V.A., Leonov V.P., Apsit K.A. Use of heat-utilizing vehicle refrigerating machine using diesel engine waste heat // Chemical and petroleum engineering. 2022. Vol. 57. P. 997–1007. doi: 10.1007/s10556-022-01037-9 |
| [7] |
Zhao J, Ma X, Grekhov L, Denisov A. Specific features of diesel fuel supply under ultra-high pressure. Applied Thermal Engineering. 2020;179:115699. doi: 10.1016/j.applthermaleng.2020.115699 |
| [8] |
Zhao J., Ma X., Grekhov L., Denisov A. Specific features of diesel fuel supply under ultra-high pressure // Applied Thermal Engineering. 2020. Vol. 179. P. 115699. doi: 10.1016/j.applthermaleng.2020.115699 |
| [9] |
Antanenkova IS, Koroleva AP, Frantsuzov MS, et al. Designing the Main Heat-Transfer Equipment of an ORC-System for the Internal Combustion Engines of Shipboard Installations. Thermal Engineering. 2021;68(1):25–36. doi: 10.1134/S0040601520120010 |
| [10] |
Antanenkova I.S., Koroleva A.P., Frantsuzov M.S., et al. Designing the Main Heat-Transfer Equipment of an ORC-System for the Internal Combustion Engines of Shipboard Installations // Thermal Engineering. 2021. Vol. 68, N. 1. P. 25–36. doi: 10.1134/S0040601520120010 |
| [11] |
Kostenko AA, Leonov VP, Rosenoer TM, et al. Using the Direct and Reverse Rankine Cycles to Create a Water-Cooling Chiller Running on Waste Heat. Chemical and Petroleum Engineering. 2016;51:778–782. doi: 10.1007/s10556-016-0121-9 |
| [12] |
Kostenko A.A., Leonov V.P., Rosenoer T.M., et al. Using the Direct and Reverse Rankine Cycles to Create a Water-Cooling Chiller Running on Waste Heat // Chemical and Petroleum Engineering. 2016. Vol. 51. P. 778–782. doi: 10.1007/s10556-016-0121-9 |
| [13] |
Aphornratana S, Sriveerakul T. Analysis of a combined Rankine–vapour–compression refrigeration cycle. Energy Conversion and Management. 2010;51:2557–2564. doi: 10.33422/5ist.2018.12.111 |
| [14] |
Aphornratana S., Sriveerakul T. Analysis of a combined Rankine–vapour–compression refrigeration cycle // Energy Conversion and Management. 2010. Vol. 51. P. 2557–2564. doi: 10.33422/5ist.2018.12.111 |
| [15] |
Rawat KS, Khulve H, Pratihar AK. Thermodynamic Analysis of Combined ORC-VCR System Using Low Grade Thermal Energy. International Journal for Research in Applied Science & Engineering Technology (IJRASET). 2015;3:515–522. Accessed: 22.05.2024. Available from: https://www.ijraset.com/fileserve.php?FID=3025 |
| [16] |
Rawat K.S., Khulve H., Pratihar A.K. Thermodynamic Analysis of Combined ORC-VCR System Using Low Grade Thermal Energy // International Journal for Research in Applied Science & Engineering Technology (IJRASET). 2015. Vol. 3. 515–522. Дата обращения: 22.05.2024. Доступ по ссылке: https://www.ijraset.com/fileserve.php?FID=3025 |
| [17] |
Bao J. Organic Rankine Cycle for Recovery of Liquefied Natural Gas (LNG) Cold Energy. In: Organic Rankine Cycle Technology for Heat Recovery. Enhua Wang: IntechOpen; 2018. doi: 10.5772/intechopen.77990 |
| [18] |
Bao J. Organic Rankine Cycle for Recovery of Liquefied Natural Gas (LNG) Cold Energy. In: Organic Rankine Cycle Technology for Heat Recovery. Enhua Wang: IntechOpen, 2018. doi: 10.5772/intechopen.77990 |
| [19] |
Astolfi M, Fantolini AM, Valenti G, et al. Cryogenic ORC to Enhance the Efficiency of LNG Regasification Terminals. Energy Procedia. 2017;129:42–49. doi: 10.1016/j.egypro.2017.09.177 |
| [20] |
Astolfi M., Fantolini A.M., Valenti G., et al. Cryogenic ORC to Enhance the Efficiency of LNG Regasification Terminals // Energy Procedia. 2017. Vol. 129. P. 42–49. doi: 10.1016/j.egypro.2017.09.177 |
| [21] |
Krotov A, Kolesnikov A, Samokhvalov Y, et al. Research of mixed refrigerant cycle for liquefaction of natural gas depending on ambient conditions and its regulation. In: Proceedings of the 25th IIR International Congress of Refrigeration, August 24-30, 2019, Montreal, Canada. Montreal; 2019:401–407. doi: 10.18462/iir.icr.2019.0980 |
| [22] |
Krotov A., Kolesnikov A., Samokhvalov Y., et al. Research of mixed refrigerant cycle for liquefaction of natural gas depending on ambient conditions and its regulation. In: Proceedings of the 25th IIR International Congress of Refrigeration, August 24-30, 2019, Montreal, Canada. Montreal, 2019. P. 401–407. doi: 10.18462/iir.icr.2019.0980 |
| [23] |
Narasimhan NL, Venkatarathnam G. A method for estimating the composition of the mixture to be charged to get the desired composition in circulation in a single stage JT refrigerator operating with mixtures. Cryogenics. 2010;50(2):93–101. doi: 10.1016/J.CRYOGENICS.2009.12.004 |
| [24] |
Narasimhan N.L., Venkatarathnam G. A method for estimating the composition of the mixture to be charged to get the desired composition in circulation in a single stage JT refrigerator operating with mixtures // Cryogenics. 2010. Vol. 50, N. 2. P. 93–101. doi: 10.1016/J.CRYOGENICS.2009.12.004 |
| [25] |
Bychkov EG, Makarov BA, Yakovlev VI, et al. Comparative Analysis of Equations of State for Calculating the Thermodynamic Properties of a Vapour-Liquid Multicomponent Refrigerant Blend Comprising the Working Fluid of a Low-Temperature Throttling Refrigeration Unit. Chemical and Petroleum Engineering. 2020;56(5–6):393–402. doi: 10.1007/s10556-020-00786-9 |
| [26] |
Bychkov E.G., Makarov B.A., Yakovlev V.I., et al. Comparative Analysis of Equations of State for Calculating the Thermodynamic Properties of a Vapour-Liquid Multicomponent Refrigerant Blend Comprising the Working Fluid of a Low-Temperature Throttling Refrigeration Unit // Chemical and Petroleum Engineering. 2020. Vol. 56, N. 5–6. P. 393–402. doi: 10.1007/s10556-020-00786-9 |
| [27] |
Zuev OA, Garanov SA, Ivanova EV, Karpukhin AS. Investigation of the efficiency of autocascade and cascade heat pumps in cold climate. Chemical and petroleum engineering. 2020;56:448–455. doi: 10.1007/s10556-020-00793-w |
| [28] |
Zuev O.A., Garanov S.A., Ivanova E.V., Karpukhin A.S. Investigation of the efficiency of autocascade and cascade heat pumps in cold climate // Chemical and petroleum engineering. 2020. Vol. 56. P. 448–455. doi: 10.1007/s10556-020-00793-w |
| [29] |
Krotov A, Samokhvalov Y, Verkhovny A, Vasilyev A. Closed cycle cryosurgical device with phase separator and mixed refrigerant. Refrigeration Science and Technology. 2019;F147717:287–292. doi: 10.18462/iir.cryo.2019.0067 |
| [30] |
Krotov A., Samokhvalov Y., Verkhovny A., Vasilyev A. Closed cycle cryosurgical device with phase separator and mixed refrigerant // Refrigeration Science and Technology. 2019. Part F147717. P. 287–292. doi: 10.18462/iir.cryo.2019.0067 |
Eco-Vector
/
| 〈 |
|
〉 |
PDF
