Assessment of CO2 capture and storage onboard LNG vessels driven by energy recovery from engine exhaust

IF 5.3 Q2 ENGINEERING, ENVIRONMENTAL
Jaafar Ballout , Ma'moun Al-Rawashdeh , Dhabia Al-Mohannadi , Joseph Rousseau , Gareth Burton , Patrick Linke
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Abstract

The pressing need to significantly reduce global CO2 emissions requires the decarbonization of the shipping industry. Currently, shipping relies on fossil fuels with a shift from heavy oil to liquefied natural gas. The main engine is the primary energy user onboard vessels, and its exhaust is the main CO2 emission source. A potential path to reduce emissions onboard vessels is the capture, compression, and storage of CO2 from the exhaust gases. This requires effective integration across the engine, the capture technology, the CO2 compression, cooling, and storage. The integration of four alternative capture technology options is conceptually explored and assessed: chemical absorption, membranes, temperature swing adsorption, and cryogenic distillation. Integration schemes are developed for each of the four technologies that achieve carbon capture, compression, and storage driven by the exhaust gas waste heat as the only energy source. Heat and power requirements are met through heat integration and heat-to-power conversions using organic Rankine cycles (ORCs). The study was performed on an LNG vessel using LNG fuel in its main engine. Thermal capture technologies (absorption and adsorption) are observed to significantly outperform their alternatives (membranes and cryogenic distillation) and capture, compress, and store more than twice the amount of CO2 emissions from the engine exhaust stream. Finally, the proposed integration schemes resulted in self-sustainable onboard capture systems without combusting additional fuel.

Abstract Image

评估由发动机废气能量回收驱动的液化天然气船上二氧化碳捕集与封存技术
大幅减少全球二氧化碳排放量的迫切需要要求航运业去碳化。目前,航运业依赖化石燃料,从重油转向液化天然气。主机是船上的主要能源消耗者,其废气是主要的二氧化碳排放源。从废气中捕捉、压缩和储存二氧化碳是减少船上排放的一条潜在途径。这需要对发动机、捕集技术、二氧化碳压缩、冷却和储存进行有效整合。我们从概念上探索和评估了四种可选捕集技术方案的整合:化学吸收、膜、变温吸附和低温蒸馏。为四种技术中的每一种制定了集成方案,以废气余热作为唯一能源,实现碳捕集、压缩和储存。通过热集成和使用有机郎肯循环 (ORC) 进行热电转换,可满足热能和电能需求。这项研究是在一艘使用液化天然气燃料的液化天然气船上进行的。据观察,热捕获技术(吸收和吸附)明显优于替代技术(膜和低温蒸馏),从发动机废气流中捕获、压缩和储存的二氧化碳排放量是替代技术的两倍多。最后,所提出的集成方案产生了可自我维持的车载捕获系统,而无需燃烧额外的燃料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Cleaner Engineering and Technology
Cleaner Engineering and Technology Engineering-Engineering (miscellaneous)
CiteScore
9.80
自引率
0.00%
发文量
218
审稿时长
21 weeks
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