The impact of exhaust gas recirculation calibration on emissions and efficiency with GTL and GTLB30 fuels on a heavy-duty diesel engine

IF 6.7 1区工程技术 Q2 ENERGY & FUELS

Fuel Pub Date : 2024-11-12 DOI:10.1016/j.fuel.2024.133709

Zhongcheng Sun , Benjamin Haefele , Michel Cuijpers , Noud Maes , Bart Somers

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引用次数: 0

Abstract

A gas-to-liquid (GTL) fuel and its blend with 30% fatty acid methyl esters (GTLB30), as well as reference diesel have been investigated on a modified single-cylinder heavy-duty compression-ignition engine over a large part of the engine operation map. The experimental results indicate that GTL and GTLB30 demonstrate comparable in-cylinder pressure and rates of heat release (ROHR) trends to diesel throughout the operating map. In general, the ROHR of GTL is close to diesel, albeit with a heightened sensitivity to exhaust gas recirculation (EGR) variations. In this work, these variations were 15% above and below baseline values. Meanwhile, the ROHR of GTLB30 is less sensitive to EGR variations because of its inherent higher oxygen content, but this comes at a small penalty in fuel injection duration due to its reduced LHV. Generally, Both GTL and GTLB30 exhibit shorter ignition delay and burn duration compared to diesel. Additionally, GTL achieves higher gross indicated efficiency (GIE) with a weighted average increase of 2.04% over diesel across all baseline engine operation map, while GTLB30 has slightly lower GIE than diesel in most cases, with a weighted average decrease of 0.99%. In terms of emissions, GTL and GTLB30 follow a similar trend with remarkable low particulate matter (PM) emissions, especially at higher EGR ratios (above 35%). Using baseline EGR rates, both GTL and GTLB30 demonstrate significant reductions in engine-out PM emissions, with a weighted average reduction of 34.5% for GTL and 71.5% for GTLB30 compared to diesel across the entire engine operation map. Moreover, GTL illustrates significant potential in breaking the PM-NO_x trade-off relationship, with a 16.1% weighted average reduction in NO_x emissions compared to diesel at the baseline EGR calibration. Conversely, the NO_x emissions of GTLB30 show a weighted average increase of 8.3% (again at the baseline EGR calibration), which can be reduced with increasing EGR. Furthermore, GTLB30 exhibits minimal CO emissions, without any sensitivity to changes in EGR, while both GTL and GTLB30 benefit from a THC emission reduction. Notably, the CO and THC emissions of GTL and GTLB30 show possible compliance in most operating points with Euro V regulation without after-treatment. Finally, NO_x reduction across all operating points is possible while respecting Euro VI PM limits for both GTL and GTLB30 by utilizing higher EGR levels at A30, A50, B50, and B70 versus lower EGR values for B30 and C30. The exact magnitude of these EGR levels per operating point are given in a bar-chart based on a non-linear curve fitting procedure, resulting in a weighted average NO_x reduction of 38.3% and 68.7% across the tested speed-load range for GTL and GTLB30, respectively.

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重型柴油发动机使用 GTL 和 GTLB30 燃料时废气再循环标定对排放和效率的影响

在一台改装的单缸重型压燃式发动机上，对一种气变液（GTL）燃料及其与 30% 脂肪酸甲酯的混合燃料（GTLB30）以及参考柴油进行了研究，研究范围覆盖了发动机运行图的大部分区域。实验结果表明，GTL 和 GTLB30 在整个运行曲线图上表现出与柴油相当的缸内压力和热释放率（ROHR）趋势。总体而言，GTL 的 ROHR 接近柴油，但对废气再循环（EGR）变化的敏感性更高。在这项工作中，这些变化比基准值高出或低出 15%。同时，由于 GTLB30 本身含氧量较高，因此其 ROHR 对 EGR 变化的敏感性较低，但由于其 LHV 较低，因此在燃料喷射持续时间方面会略有损失。一般来说，与柴油相比，GTL 和 GTLB30 的点火延迟和燃烧持续时间都更短。此外，在所有基线发动机运行图中，GTL 实现了更高的总指示效率（GIE），比柴油加权平均提高了 2.04%，而 GTLB30 在大多数情况下的 GIE 比柴油略低，加权平均降低了 0.99%。在排放方面，GTL 和 GTLB30 的趋势相似，颗粒物（PM）排放量都很低，尤其是在 EGR 比率较高（35% 以上）的情况下。使用基准 EGR 率时，GTL 和 GTLB30 都能显著减少发动机排放的 PM，在整个发动机运行图中，GTL 和 GTLB30 与柴油相比，加权平均减少 34.5%，GTLB30 减少 71.5%。此外，GTL 在打破 PM-NOx 权衡关系方面具有巨大潜力，在基准 EGR 标定时，与柴油相比，NOx 排放加权平均减少了 16.1%。相反，GTLB30 的氮氧化物排放量加权平均增加了 8.3%（同样是在基准 EGR 校准时），这可以通过增加 EGR 来减少。此外，GTLB30 的一氧化碳排放量最小，对 EGR 的变化不敏感，而 GTL 和 GTLB30 都受益于 THC 排放量的减少。值得注意的是，GTL 和 GTLB30 的一氧化碳和四氢大麻酚排放量表明，在大多数工作点，无需后处理就能符合欧 V 法规。最后，通过在 A30、A50、B50 和 B70 采用较高的 EGR 水平，而在 B30 和 C30 采用较低的 EGR 值，GTL 和 GTLB30 可以在所有运行点减少氮氧化物，同时遵守欧 VI PM 限制。基于非线性曲线拟合程序的条形图给出了每个工作点 EGR 水平的确切大小，结果是 GTL 和 GTLB30 在测试的速度-负荷范围内的加权平均氮氧化物减排量分别为 38.3% 和 68.7%。

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

Fuel 工程技术-工程：化工

CiteScore

12.80

自引率

20.30%

发文量

3506

审稿时长

64 days

期刊介绍： The exploration of energy sources remains a critical matter of study. For the past nine decades, fuel has consistently held the forefront in primary research efforts within the field of energy science. This area of investigation encompasses a wide range of subjects, with a particular emphasis on emerging concerns like environmental factors and pollution.