Analysis of multi-mode combustion and performance in a marine diesel/natural gas dual-fuel engine based on an irreversible equivalent combustion cycle theory

IF 9 1区工程技术 Q1 ENERGY & FUELS

Energy Pub Date : 2025-04-19 DOI:10.1016/j.energy.2025.136248

Liping Yang , Shuaizhuang Ji , Jacek Hunicz , Rui Wang , Ali Zare , Yuqi Su , Deyang Ji

{"title":"Analysis of multi-mode combustion and performance in a marine diesel/natural gas dual-fuel engine based on an irreversible equivalent combustion cycle theory","authors":"Liping Yang , Shuaizhuang Ji , Jacek Hunicz , Rui Wang , Ali Zare , Yuqi Su , Deyang Ji","doi":"10.1016/j.energy.2025.136248","DOIUrl":null,"url":null,"abstract":"<div><div>Diesel/natural gas dual-fuel engines offer the advantages of higher thermal efficiency and lower carbon dioxide emission while breaking the NOx-PM trade-off caused by diffusion-dominated combustion in diesel engines. However, the large reactivity gradient between diesel and natural gas leads to more complex ignition and multi-stage heat release process. Traditional pressure and heat release rate-based analyses, as well as the ideal thermodynamic cycle theory, are insufficient to identify multi-stage heat release under different combustion modes, and especially cannot estimate the correlation of specific thermodynamic processes with engine performance and emissions. In this paper, an irreversible equivalent combustion cycle theory is proposed to reveal the effects of natural gas thermal substitution ratio (NG-TSR) and high reactivity diesel injection strategies on the multi-mode combustion and performance under a typical ship propulsion condition of the engine speed of 1134 rpm and load of 25 %. The results show that as NG-TSR decreases, the heat release ratio of constant volume combustion (Q-CVC) and constant pressure combustion processes (Q-CPC) increases, while the reduction in late combustion (LC) leads to a higher indicated thermal efficiency (ITE is up to 41.4 %). At the same time, total hydrocarbon (THC) emission can be reduced by more than 70 %, while NOx emission increases. Under the single-injection strategy, CO<sub>2</sub> emission is dominated by NG-TSR, while the ratio of Q-CVC in the whole combustion cycle has the most important effect on NOx and THC emissions, with effect significances of +63 % and -72 %, respectively. The split-injection strategy effectively converts the LC stage to the CVC and CPC stages, and pre-injection ratio (PR) shows a strong negative correlation with THC and CO emissions, as well as brake specific energy consumption. Moreover, CO<sub>2</sub> and NOx emissions can be further controlled by optimizing the contributions of these three combustion stages.</div></div>","PeriodicalId":11647,"journal":{"name":"Energy","volume":"326 ","pages":"Article 136248"},"PeriodicalIF":9.0000,"publicationDate":"2025-04-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Energy","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0360544225018900","RegionNum":1,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENERGY & FUELS","Score":null,"Total":0}

引用次数: 0

Abstract

Diesel/natural gas dual-fuel engines offer the advantages of higher thermal efficiency and lower carbon dioxide emission while breaking the NOx-PM trade-off caused by diffusion-dominated combustion in diesel engines. However, the large reactivity gradient between diesel and natural gas leads to more complex ignition and multi-stage heat release process. Traditional pressure and heat release rate-based analyses, as well as the ideal thermodynamic cycle theory, are insufficient to identify multi-stage heat release under different combustion modes, and especially cannot estimate the correlation of specific thermodynamic processes with engine performance and emissions. In this paper, an irreversible equivalent combustion cycle theory is proposed to reveal the effects of natural gas thermal substitution ratio (NG-TSR) and high reactivity diesel injection strategies on the multi-mode combustion and performance under a typical ship propulsion condition of the engine speed of 1134 rpm and load of 25 %. The results show that as NG-TSR decreases, the heat release ratio of constant volume combustion (Q-CVC) and constant pressure combustion processes (Q-CPC) increases, while the reduction in late combustion (LC) leads to a higher indicated thermal efficiency (ITE is up to 41.4 %). At the same time, total hydrocarbon (THC) emission can be reduced by more than 70 %, while NOx emission increases. Under the single-injection strategy, CO₂ emission is dominated by NG-TSR, while the ratio of Q-CVC in the whole combustion cycle has the most important effect on NOx and THC emissions, with effect significances of +63 % and -72 %, respectively. The split-injection strategy effectively converts the LC stage to the CVC and CPC stages, and pre-injection ratio (PR) shows a strong negative correlation with THC and CO emissions, as well as brake specific energy consumption. Moreover, CO₂ and NOx emissions can be further controlled by optimizing the contributions of these three combustion stages.

查看原文本刊更多论文

基于不可逆等效燃烧循环理论的船用柴油/天然气双燃料发动机多模式燃烧及性能分析

柴油/天然气双燃料发动机具有更高的热效率和更低的二氧化碳排放的优点，同时打破了柴油发动机由扩散主导燃烧造成的NOx-PM权衡。然而，柴油与天然气之间的反应性梯度较大，导致其点火和多段放热过程更为复杂。传统的基于压力和放热率的分析，以及理想的热力学循环理论，都不足以识别不同燃烧模式下的多阶段放热，特别是无法估计特定热力学过程与发动机性能和排放的相关性。本文提出了不可逆等效燃烧循环理论，揭示了天然气热替代比（NG-TSR）和高反应性柴油喷射策略对发动机转速为1134 rpm、负荷为25%的典型船舶推进工况下多模式燃烧和性能的影响。结果表明，随着NG-TSR的降低，定容燃烧（Q-CVC）和定压燃烧（Q-CPC）过程的放热比增加，而燃烧后期（LC）的降低导致了更高的指示热效率（ITE高达41.4%）。同时，总碳氢化合物（THC）排放量可减少70%以上，而NOx排放量增加。在单喷策略下，CO2排放以NG-TSR为主，而Q-CVC在整个燃烧循环中的比例对NOx和THC排放的影响最为重要，影响显著度分别为+ 63%和- 72%。分注策略有效地将LC阶段转化为CVC和CPC阶段，预注比（PR）与THC和CO排放量以及制动比能耗呈较强的负相关。此外，通过优化这三个燃烧阶段的贡献，可以进一步控制CO2和NOx的排放。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Energy 工程技术-能源与燃料

CiteScore

15.30

自引率

14.40%

发文量

审稿时长

14.2 weeks

期刊介绍： Energy is a multidisciplinary, international journal that publishes research and analysis in the field of energy engineering. Our aim is to become a leading peer-reviewed platform and a trusted source of information for energy-related topics. The journal covers a range of areas including mechanical engineering, thermal sciences, and energy analysis. We are particularly interested in research on energy modelling, prediction, integrated energy systems, planning, and management. Additionally, we welcome papers on energy conservation, efficiency, biomass and bioenergy, renewable energy, electricity supply and demand, energy storage, buildings, and economic and policy issues. These topics should align with our broader multidisciplinary focus.