Fleet Deployment and Voyage Planning Optimization for Liquefied
 Natural Gas Shipping Under Power of Mixed Boil Off Gas

doi:10.16097/j.cnki.1009-6744.2024.02.030

Abstract

Abstract: Liquefied natural gas ships can use the natural and forced boil off gas from their laden cargo as the propulsion power during navigation. This paper proposes an optimization method of fleet deployment and voyage planning for liquefied natural gas shipping powered by mixed boil off gas. A correlation function between liquefied natural gas ship speed, consumption volumes of boil off gas, and volumes of voyage delivery is constructed to balance the relationship between forced boil off gas of liquefied natural gas and voyage costs. Considering factors of owning and chartering ships, voyage transportation time, and boil off losses, this paper develops a management strategy of mixed boil off gas, and a joint optimization model for fleet deployment, voyage planning and speed of liquefied natural gas shipping is formulated with the goal of minimizing the annual operating cost of liquefied natural gas shipping companies. A nested solution algorithm based on model decomposition is proposed by combining genetic algorithm with optimization software. Using the actual operational data of liquefied natural gas shipping companies as a case study, this paper verified that the management strategy of mixed boil off gas can effectively reduce the operating cost by 7.13% and ship idle rate by 4.8%. The sensitivity analysis results indicate that as the spot price of liquefied natural gas increases, the management strategy of mixed boil off gas to adjust volumes of forced boil off gas has a more significant effect on reducing operating costs for shipping companies.

Key words: waterway transportation, fleet deployment and voyage planning, joint optimization, liquefied natural gas, management of boil off gas

摘要： 液化天然气运输船舶在航行过程中，可利用其装载货物的自然蒸发气与强制蒸发气作为船舶动力燃料。根据这一实际情况，提出混合蒸发气动力模式下液化天然气海运航线配船优化方法。通过构建船舶航速、蒸发气消耗量及航次交付量之间的关联函数，权衡液化天然气强制蒸发量与航次成本间的反馈关系。考虑自有船和定期租船、航次运输时间、蒸发损失等因素，以液化天然气船队年运营成本最低为目标，设计混合蒸发气管理策略，建立液化天然气海上运输航线配船与航速联合优化模型。根据模型特点，将遗传算法与优化软件相结合，提出基于模型分解的嵌套求解算法。最后，以航运企业实际运营数据为背景开展案例分析，计算结果表明，采用混合蒸发气管理策略可使航运企业运营成本降低7.13%，船队闲置率降低4.8%。敏感性分析结果表明，随液化天然气现货价的增高，采用混合蒸发气管理策略调整强制蒸发气用量对企业运营成本的降低效果更加显著。

关键词: 水路运输, 航线配船, 联合优化, 液化天然气, 蒸发气管理

CLC Number:

U692

ZHAORuijia, SUN Yuxuan, NIU Dongxiang, XIE Xinlian. Fleet Deployment and Voyage Planning Optimization for Liquefied Natural Gas Shipping Under Power of Mixed Boil Off Gas[J]. Journal of Transportation Systems Engineering and Information Technology, 2024, 24(2): 304-312.

赵瑞嘉, 孙宇轩, 牛东翔, 谢新连. 混合蒸发气动力下液化天然气海运航线配船优化[J]. 交通运输系统工程与信息, 2024, 24(2): 304-312.

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References

[1] 周军,彭思洲,王楷,等.LNG海运贸易订购策略优化研究[J/OL]. 中国管理科学, (2023-09-11) [2023-12 17]. https://doi.org/ 10.16381/ j.cnki.issn1003 207x.2022.2567. [ZHOU J, PENG S Z, WANG K, et al. Research on ordering strategy optimization of LNG maritime trade[J/OL]. Chinese Journal of Management Science, (2023-09-11) [2023-12-17]. https://doi.org/ 10.16381/j.cnki.issn1003-207x.2022.2567.]

[2]廖诗管,翁金贤,胡甚平.液化天然气船通航模式下的航道通过能力评价方法[J].交通运输系统工程与信息, 2022, 22(2): 290-297. [LIAO S G, WENG J X, HU S P. A capacity estimation approach for waterway traffic under LNG carriers navigation mode[J]. Journal of Transportation Systems Engineering and Information Technology, 2022, 22(2): 290-297.]

[3] KIM D, HWANG C, GUNDERSEN T, et al. Process design and economic optimization of boil-off-gas re-liquefaction systems for LNG carriers[J]. Energy, 2019, 173: 1119-1129.

[4]WANG C, YU S, XU L. Decisions on sailing frequency and ship type in liner shipping with the consideration of carbon dioxide emissions[J]. Regional Studies in Marine Science, 2022, 52: 102371.

[5]牛东翔,高成男,谢新连,等.LNG海运航线配船优化模型[J]. 天然气工业,2015, 35(9): 101-104. [NIU D X, GAO C N, XIE X L, et al. A fleet deployment optimization model for LNG shipping[J]. Natural Gas Industry, 2015, 35(9): 101-104.]

[6] AL-HAIDOUS S, MSAKNI M K, HAOUARI M. Optimal planning of liquefied natural gas deliveries[J]. Transportation Research Part C: Emerging Technologies, 2016, 69: 79-90.

[7]TASKAR B, ANDERSEN P. Benefit of speed reduction for ships in different weather conditions[J]. Transportation Research Part D: Transport and Environment, 2020, 85: 102337.

[8]镇璐,孙晓凡,王帅安.排放控制区限制下邮轮航线及速度优化[J]. 运筹与管理,2019, 28(3): 31-38. [ZHEN L, SUN X F, WANG S A. The optimization of cruise shipping routing and speed with emission control area[J]. Operations Research and Management Science, 2019, 28 (3): 31-38.]

[9] 计明军,胡寒霖,高振迪,等.考虑风浪影响下的船舶节能航线优化[J].交通运输系统工程与信息,2023,23 (6): 274-283. [JI M J, HU H L, GAO Z D, et al. Energy efficient ship route optimization considering wind and wave impacts[J]. Journal of Transportation Systems Engineering and Information Technology, 2023, 23(6): 274-283.]

[10] SHENG D, MENG Q, LI Z C. Optimal vessel speed and fleet size for industrial shipping services under the emission control area regulation[J]. Transportation Research Part C: Emerging Technologies, 2019, 105: 37-53.

[11] 邢玉伟, 杨华龙,郑建风,等.考虑货物时间价值的洲际班轮航线配船与航速优化[J].系统工程学报,2022, 37(6): 796-810. [XING Y W, YANG H L, ZHENG J F, et al. Optimization of fleet deployment and vessel sailing speed for intercontinental liner considering cargo time value[J]. Journal of Systems Engineering, 2022, 37 (6): 796-810.]

[12] KRIKKIS R N. A thermodynamic and heat transfer model for LNG ageing during ship transportation towards an efficient boil-off gas management[J]. Cryogenics, 2018, 92: 76-83.

[13] AL-BREIKI M, BICER Y. Investigating the technical feasibility of various energy carriers for alternative and sustainable overseas energy transport scenarios[J]. Energy Conversion and Management, 2020, 209: 112652.

[14] 宋云婷, 王诺.基于时间不确定的集装箱码头靠泊计划优化[J]. 交通运输系统工程与信息, 2020, 20(4): 224-230. [SONG Y T, WANG N. A simulation-based optimization approach to container terminal berth planning under time uncertainty[J]. Journal of Transportation Systems Engineering and Information Technology, 2020, 20(4): 224-230.]

[15] SUN Y, ZHENG J, HAN J, et al. Allocation and reallocation of ship emission permits for liner shipping [J]. Ocean Engineering, 2022, 266: 112976.

Fleet Deployment and Voyage Planning Optimization for Liquefied Natural Gas Shipping Under Power of Mixed Boil Off Gas

混合蒸发气动力下液化天然气海运航线配船优化

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