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LNG carrier two-stroke propulsion systems: A comparative study of state of the art reliquefaction technologies

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  • George, Dimopoulos G.
  • Eleftherios, Koukoulopoulos D.
  • Chariklia, Georgopoulou A.

Abstract

Transportation of Liquefied Natural Gas (LNG) by sea has been intensified in the current shipping environment, opening new markets and trade routes. LNG carriers are inherently complex vessels, featuring a high degree of integration of their energy conversion systems, all operating under time and load varying mission profiles, making design decisions non-trivial. To this end, DNVGL COSSMOS (Complex Ship Systems Modelling and Simulation) in-house process modelling framework is used to build digital twins of the propulsion and cargo module of LNG carriers, modelling the entire energy conversion process from cargo tanks to useful energy required for propulsion, electricity and heat. Emphasis is given on reliquefaction systems and the improvement they provide in performance, comparing the currently available technologies and giving deeper insight for the Joule-Thomson systems. The overall ship system performance is improved by 5–15% along the low vessel speed range and 25–40% for the anchorage loaded port condition, when partial reliquefaction systems are considered, depending on the configuration they are compared to. Engine technology also plays an important role, with high-pressure engines exhibiting 3–10% better performance, depending on the reliquefaction technology coupled with, along the high vessel speed range, mainly because of their inherent better performance.

Suggested Citation

  • George, Dimopoulos G. & Eleftherios, Koukoulopoulos D. & Chariklia, Georgopoulou A., 2020. "LNG carrier two-stroke propulsion systems: A comparative study of state of the art reliquefaction technologies," Energy, Elsevier, vol. 195(C).
    • Handle: RePEc:eee:energy:v:195:y:2020:i:c:s0360544220301043
    DOI: 10.1016/j.energy.2020.116997
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    References listed on IDEAS

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    1. Yin, L. & Ju, Y.L., 2019. "Comparison and analysis of two nitrogen expansion cycles for BOG Re-liquefaction systems for small LNG ships," Energy, Elsevier, vol. 172(C), pages 769-776.
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    2. Zhen Tian & Yingying Yue & Yuan Zhang & Bo Gu & Wenzhong Gao, 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, MDPI, vol. 13(6), pages 1-23, March.
    3. Lin, Zhen-hao & Li, Jun-ye & Jin, Zhi-jiang & Qian, Jin-yuan, 2021. "Fluid dynamic analysis of liquefied natural gas flow through a cryogenic ball valve in liquefied natural gas receiving stations," Energy, Elsevier, vol. 226(C).
    4. Dai, Rui & Tian, Ran & Zheng, Siyu & Wei, Mingshan & Shi, GuoHua, 2022. "Dynamic performance evaluation of LNG vaporization system integrated with solar-assisted heat pump," Renewable Energy, Elsevier, vol. 188(C), pages 561-572.
    5. Yin, Liang & Ju, Yonglin, 2022. "Review on the design and optimization of BOG re-liquefaction process in LNG ship," Energy, Elsevier, vol. 244(PB).
    6. Yin, Liang & Ju, Yonglin, 2020. "Conceptual design and analysis of a novel process for BOG re-liquefaction combined with absorption refrigeration cycle," Energy, Elsevier, vol. 205(C).
    7. Lee, Jaejun & Son, Heechang & Yu, Taejong & Oh, Juyoung & Park, Min Gyun & Lim, Youngsub, 2023. "Process design of advanced LNG subcooling system combined with a mixed refrigerant cycle," Energy, Elsevier, vol. 278(PA).

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