Design and optimization of LNG cold energy utilization scheme for dual fuel main engine of 37000DWT asphalt ship

References

• Bao, J., Y. Lin, R. Zhang, N. Zhang, and G. He. 2017. Effects of stage number of condensing process on the power generation systems for LNG cold energy recovery. Applied Thermal Engineering 126 (5):566–82. doi:10.1016/j.applthermaleng.2017.07.144.
   Google Scholar
• Choi, I., S. Lee, Y. Seo, and D. Chang. 2013. Analysis and optimization of cascade Rankine cycle for liquefied natural gas cold energy recovery. Energy 61 (2013):179–95. doi:10.1016/j.energy.2013.08.047.
   Google Scholar
• Daniarta, S., and A. R. Imre. 2020. Cold energy utilization in lng regasification system using organic rankine cycle and trilateral flash cycle[J]. Periodica Polytechnica Mechanical Engineering 64 (4):342–49. doi:10.3311/PPme.16668.
   Google Scholar
• Desong, Q. 2018. Study on cascade utilization scheme of cold energy for large ocean-going LNG ships [D]. Qingdao University of Science and Technology, Qingdao, Shandong Province, China.
   Google Scholar
• Evans, J. A. 2010. Frozen food science and technology [M]. China Light Industry Press, Beijing, China.
   Google Scholar
• Guiyin, F. 2005. Maintenance manual for refrigeration and air conditioning equipment [M]. China Electric Power Press, Beijing, China.
   Google Scholar
• Han, F., Wang, Z., Ji, Y., Li, W., & Sunden, B. (2019). Energy analysis and multi-objective optimization of waste heat and cold energy recovery process in LNG-fueled vessels based on a triple organic Rankine cycle. Energy Conversion and Management, 195, 561-572.
   Google Scholar
• He, T., Lv, H., Shao, Z., Zhang, J., Xing, X., & Ma, H. (2020). Cascade utilization of LNG cold energy by integrating cryogenic energy storage, organic Rankine cycle and direct cooling. Applied Energy, 277, 115570
   Web of Science ®Google Scholar
• Jiying, W., and M. Yimin. 2012. System configuration and secondary refrigerant selection of cold store using lng cascade cold energy [J]. Journal of Jimei University (Natural Science) 17 (2):126–30.
   Google Scholar
• Koo, J., S.-R. Oh, Y.-U. Choi, J.-H. Jung, and K. Park. 2019. Optimization of an organic rankine cycle system for an LNG-powered ship. Energies 12 (10):1933. doi:10.3390/en12101933.
   Web of Science ®Google Scholar
• Lee, S., and B. C. Choi. 2016. Thermodynamic assessment of integrated heat recovery system combining exhaust-gas heat and cold energy for LNG revaporization process in FSRU vessel[J]. Journal of Mechanical Science and Technology 30 (3):1389–98. doi:10.1007/s12206-016-0246-y.
   Web of Science ®Google Scholar
• Likun, Y. 2020. Study on comprehensive utilization system of LNG revaporization cold energy based on FSRU platform [D]. Jiangsu University of Science and Technology, Zhenjiang, Jiangsu Province, China.
   Google Scholar
• Liu, H., and L. You. 1999. Characteristics and applications of the cold heat exergy of liquefied natural gas. Energy Convers Manage 40:1515e25.
   Web of Science ®Google Scholar
• Mosaffa, A., and L. Garousi Farshi. 2016. Exergoeconomic and environmental analyses of an air conditioning system using thermal energy storage. Applied Energy 162:515–26. doi:10.1016/j.apenergy.2015.10.122.
   Web of Science ®Google Scholar
• Mosaffa, A., N. Mokarram, and L. Farshi. 2017. Thermo-economic analysis of combined different ORCs geothermal power plants and LNG cold energy. Geothermics 65 (2017):113–25. doi:10.1016/j.geothermics.2016.09.004.
   Google Scholar
• Shujie, H. A. N., Z. H. A. N. G. Xiaorong, L. I. Boyang, Q. I. A. N. Desong, and T. I. A. N. Dongfang. 2018. Design and simulation optimization of LNG carrier cold energy utilization scheme based on HYSYS[J]. Ship Engineering 40 (2):12–16,87.
   Google Scholar
• Sun, X., Yao, S., Xu, J., Feng, G., & Yan, L. (2020). Design and Optimization of a Full-Generation System for Marine LNG Cold Energy Cascade Utilization. Journal of Thermal Science, 29(3), 587–596
   Web of Science ®Google Scholar
• Tian, Z., Yue, Y., Zhang, Y., Gu, B., & Gao, W. (2020). Multi-objective thermo-economic optimization of a Combined Organic Rankine Cycle (ORC) system based on waste heat of dual fuel marine engine and LNG cold energy recovery. Energies, 13(6), 1397
   Web of Science ®Google Scholar
• Xiaohua, W., C. Lei, L. Tinyu, Y. Xufei, and Y. Bo. 2017. Latest progress of LNG cold energy utilization technology [J]. Oil & Gas Storage and Transportation 36 (6):624–35.
   Google Scholar
• Xiaokang, L., and W. Yueyuan. 2019. LNG cold energy utilization and its development [J]. Petrochemical Industry Technology 26 (5):27–28.
   Google Scholar
• Xingwang, H., L. Boyang, H. Dedong, C. Lanshu, and Y. Sangyu. 2019. Design and analysis of marine cold storage and air conditioning system using LNG cold energy [J]. Ship Engineering 41 (6):54–57+124.
   Google Scholar
• Yingjie, L., and Z. Shan. 2005. MATLAB genetic algorithm toolbox and its application [M]. Xi’an: Xi’an University of Electronic Science and Technology Press.
   Google Scholar
• Yoon-Ho, L. (2019). Thermo-economic analysis of a novel regasification system with liquefied-natural-gas cold-energy. International Journal of Refrigeration, 101, 218–229
   Web of Science ®Google Scholar
• Yu, H., T. Gundersen, and E. Gençer. 2021. Optimal liquified natural gas (LNG) cold energy utilization in an Allam cycle power plant with carbon capture and storage[J]. Energy Conversion and Management 228:113725. doi:10.1016/j.enconman.2020.113725.
   Web of Science ®Google Scholar
• Yu, P., Liu, H., Zhou, S., & Che, D. (2021). Thermodynamic analysis of a cryogenic power generation system recovering both sensible heat and latent heat of flue gas. Energy Conversion and Management, 227, 113615
   Web of Science ®Google Scholar