船舶甲醇燃料动力系统研究与应用关键技术综述

王凯; 梁宏志; 李中伟; 迟艳坡; 王亚棚; 曹建林; 黄连忠

doi:10.19818/j.cnki.1671-1637.2026.055

船舶甲醇燃料动力系统研究与应用关键技术综述

doi: 10.19818/j.cnki.1671-1637.2026.055

王凯^{1, 2, ,},
梁宏志¹,
李中伟¹,
迟艳坡¹,
王亚棚¹,
曹建林¹,
黄连忠^{1, 2}

1.
大连海事大学轮机工程学院, 辽宁大连 116026
2.
大连海事大学水路交通控制全国重点实验室，辽宁大连 116026

基金项目:

国家重点研发计划 2022YFB4300803

国家自然科学基金项目 52271305

中央高校基本科研业务费专项资金项目 3132023525

详细信息

作者简介:
王凯(1990-)，男，吉林公主岭人，副教授，工学博士，E-mail: kwang@dlmu.edu.cn

中图分类号: U677.2
计量
- 文章访问数: 28
- HTML全文浏览量: 9
- PDF下载量: 5
- 被引次数: 0
出版历程
- 收稿日期: 2025-08-08
- 录用日期: 2025-09-26
- 修回日期: 2025-09-13
- 刊出日期: 2026-01-28

Review on research and application technology of marine methanol fuel power system

1.
Marine Engineering College, Dalian Maritime University, Dalian 116026, Liaoning, China
2.
State Key Laboratory of Maritime Technology and Safety, Dalian Maritime University, Dalian 116026, Liaoning, China

Funds:

National Key R&D Program of China 2022YFB4300803

National Natural Science Foundation of China 52271305

Fundamental Research Funds for the Central Universities 3132023525

More Information

Corresponding author: WANG Kai, associate professor, PhD, E-mail: kwang@dlmu.edu.cn

Article Text (Baidu Translation)

摘要

摘要: 为解决现有船舶甲醇燃料应用研究内容分散、缺乏全链条技术体系的系统性分析等问题, 在船舶碳排放控制法规及政策分析的基础上, 综合分析了甲醇燃料特性与制备技术、甲醇燃料存储运输及加注技术、甲醇动力系统设计优化技术、甲醇/柴油双燃料发动机运行特性、甲醇燃料电池技术以及甲醇燃料风险分析与操作安全要求的研究与发展现状, 总结了船舶甲醇燃料动力系统应用技术存在的不足和挑战, 并对船舶甲醇燃料动力系统应用技术的发展趋势进行了总结和展望, 为船舶甲醇燃料动力系统关键技术的研究与应用提供重要参考。分析结果表明: 甲醇燃料的应用是实现船舶脱碳目标的重要选择之一, 然而, 在经济性、安全性及全生命周期碳排放等方面有待开展进一步论证分析; 未来需在绿色甲醇制备、燃料安全存储运输、燃料泄漏与防腐、续航力提升、发动机性能优化与控制等技术方面不断突破, 从而促进航运业的低碳化发展, 满足日益严格的船舶碳排放法规的要求。
- 船舶工程 /
- 低碳航运 /
- 综述 /
- 替代燃料 /
- 甲醇燃料发动机 /
- 甲醇燃料电池 /
- 燃料操作安全 /
- 绿色甲醇
Abstract: To address the problems of fragmented research contents and the lack of systematic analysis of a full-chain technical system in existing studies on marine methanol fuel application, a comprehensive analysis was conducted based on the analysis of ship carbon emission control regulations and policies. The research and development status of methanol fuel characteristics and production technologies, methanol fuel storage, transportation, and refueling technologies, methanol power system design optimization technologies, methanol/diesel dual-fuel engine operating characteristics, methanol fuel cell technologies, and methanol fuel risk analysis and operation safety requirements was comprehensively analysed. The shortcomings and challenges in the application technologies of marine methanol fuel power systems were summarized. The future development trends of application technologies of marine methanol fuel power systems were summarized and prospected. Important references were provided for the research and application of key technologies of marine methanol fuel power systems. Analysis results indicate that the methanol fuel application is one of the important options for achieving ship decarbonization targets. Further demonstration and analysis are still required in terms of economy, safety, and full life-cycle carbon emissions. In the future, continuous breakthroughs are required in technologies including green methanol production, safe fuel storage and transportation, fuel leakage and corrosion prevention, endurance improvement, and engine performance optimization and control, thus promoting the low-carbon development of the shipping industry and meeting the requirements of increasingly stringent ship carbon emission regulations.
- ship engineering /
- low-carbon shipping /
- review /
- alternative fuel /
- methanol-fueled engine /
- methanol fuel cell /
- fuel operational safety /
- green methanol

HTML全文

图 1 IMO脱碳路径^[17]

Figure 1. IMO decarbonization pathway^[17]

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图 2 基于天然气重整的甲醇制备流程^[26]

Figure 2. Methanol production processes based on natural gas reforming^[26]

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图 3 船舶甲醇燃料储存加注系统

Figure 3. Storage and refueling system of marine methanol fuel

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图 4 船舶甲醇动力系统设计^[34]

Figure 4. Design of marine methanol power system^[34]

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图 5 MSEC系统^[40]

Figure 5. MSEC system^[40]

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图 6 双燃料发动机CFD模型^[56]

Figure 6. CFD model of a dual-fuel engine^[56]

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图 7 采用甲醇燃料的SOFC/发动机/电池集成动力系统^[77]

Figure 7. Integrated power system of SOFC/engine/battery using methanol fuel^[77]

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图 8 部分甲醇燃料船舶应用实例

Figure 8. Partial application cases of methanol fueled ships

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表 1 甲醇燃料特性

Table 1. Characteristics of methanol fuel

特性	参数信息
外观与气味	无色透明液体，具有刺激性气味
熔点/℃	97.7
沸点/℃	64.7
闪点/℃	12
热值/(MJ·kg^-1)	19.9
能量密度/(MJ·L^-1)	15.7
与轻柴油能量密度比值	2.5
燃烧时CO₂排放量/ [kg·(kW·h)^-1]	0.248 6
溶解性	与水或多种有机溶剂(如乙醇)以任意比例互溶
引燃温度/℃	464
蒸气压	常温下蒸气压较高，易形成可燃蒸气

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表 2 甲醇/柴油双燃料发动机特性分析

Table 2. Characterization analysis of the methanol/diesel dual-fuel engine

文献	发动机参数或优化方法	结果
[43]	甲醇替代率、初始气缸参数、柴油喷射参数	通过优化可有效降低发动机在低负荷时的排放性能
[44]	MSP、EGR、EB	MSP增加，NO₂排放量先增后降；EGR可降低NO₂排放；EB增加导致NO_x排放增大
[45]	发动机负荷、进气温度、冷却水温度、甲醇温度	较高的进气温度、甲醇温度和冷却水温度有利于提高效率
[50]	进气道喷射、缸内直喷	采用缸内直喷方式时，可减少85%的NO_x排放
[51]	后喷柴油策略	可降低NO_x排放12.9%
[52]	D/M、M/D、M/D/M	M/D是最经济、排放最少的模式
[53]	D/M、M/D、M/D/M	M/D/M模式的热力学性能较佳
[54]	SR	可有效提高燃油经济性
[55]	ESR、柴油喷射定时	甲醇直喷策略具有更好的燃烧特性，从而可有效降低污染物排放
[56]	预喷甲醇策略	提高了ITE，并显著减少CO₂排放量
[57]	优化喷射策略	指示燃油消耗率降低3.95%
[58]	双燃料直喷模式	ESR最高可达52.4%
[59]	DDFS模式	可以提高热效率，降低碳排放
[61]	DMDF模式	可以降低NO_x和Soot的排放
[62]	喷油器喷孔数	喷孔数为9时，指示热效率较原柴油机提升了2.73%
[63]	VCR	压缩比为19时热效率最高
[69]	遗传算法	基于该算法进行喷油器安装优化，可有效提高发动机的热力学性能
[70]	CFD方法	基于该方法分析发现单侧孔喷嘴可促进甲醇燃烧
[71]	RMDF模式	基于该方法可以实现更加清洁、高效的燃烧效果
[72]	GWO算法、熵权逼近理想解排序法	基于该方法可降低NO_x排放26.22%，指示燃油消耗率降低13.39%

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表 3 甲醇燃料操作安全要求

Table 3. Methanol fuel operational safety requirements

相关文件	主要内容
《船舶应用甲醇/乙醇燃料指南》	涵盖了船舶布置、燃料储存、加注、通风、消防、电气系统、监控以及人员保护等多个方面的安全内容，适用于20 m及以上使用甲醇/乙醇为燃料的钢质或等效金属材料船舶
《船舶甲醇燃料加注作业指南》	加注车和受注船需满足相关标准和法规要求，人员需具备资质并配备防护装备，作业现场需严格管控热工作业和静电风险
《甲醇燃料动力船舶技术与检验暂行规则》	船舶的布置、轮机、电气、控制、监测和安全系统、消防以及甲醇燃料储存等方面的技术规范。明确了规则的目的与适用范围，规定了甲醇燃料动力船舶的检验种类、检验项目以及发证的操作性要求
Guidelines on methanol fueled vessels	涉及船舶设计、燃料储存、加注、通风、消防、电气系统、监控以及人员保护等多方面的安全要求
Methanol safe bandling manual	关于甲醇的物理化学特性、环境和健康安全风险、安全操作规程、应急响应程序等

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表 4 甲醇燃料船舶减排效果

Table 4. Emission reduction effect of methanol-fueled ships

船舶	效果	动力类型
“Stena Germanica”号	减少CO₂排放量70%	甲醇/柴油
“Stena Pro Patria”号	分别降低CO₂和NO_x排放量75%和15%	甲醇/柴油
中远海运集装箱船	降低碳排放约8.9%	甲醇
“领先1”号	降低CO₂排放量11.25%	甲醇/柴油
“Island Sky”号	与传统燃料相比，CO₂、NO_x和SO_x排放量分别降低25.70%、38.46%和45.00%	甲醇/柴油
“ECO LEVANT”号	EEDI可以达到5.94	燃料电池混合动力

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