Development of Data-Driven Models for the Prediction of Fuel Effects on Diesel Engine Performance and Emissions

IF 1 Q4 TRANSPORTATION SCIENCE & TECHNOLOGY SAE International Journal of Fuels and Lubricants Pub Date : 2023-04-20 DOI:10.4271/04-16-03-0020

P. Schaberg, T. Harms

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Abstract

A modelling tool has been developed for the prediction of fuel effects on the performance and exhaust emissions of a heavy-duty diesel engine. Recurrent neural network models with duty-cycle, engine control, and fuel property parameters as inputs were trained with transient test data from a 15-liter heavy-duty diesel engine equipped with a common-rail fuel injection system and a variable geometry turbocharger. The test fuels were formulated by blending market diesel fuels, refinery components, and biodiesel to provide variations in preselected fuel properties, namely, hydrogen-to-carbon (H/C) ratio, oxygen-to-carbon (O/C) ratio, derived cetane number (CN), viscosity, and mid- and end-point distillation parameters. Care was taken to ensure that the correlation between these fuel properties in the test fuel matrix was minimized to avoid confounding model input variables. The test engine was exercised over a wide variety of transient test cycles during which fuel rail pressure, injection timing, airflow, and recirculated exhaust gas flow were systematically varied. The resulting models could predict the transient engine torque and fuel consumption, and nitrogen oxide (NOx), soot, carbon monoxide (CO), total hydrocarbon (THC), and carbon dioxide (CO2) exhaust emissions with good accuracy, indicating that the limited number of fuel property parameters selected as model inputs was sufficient to capture the fuel-related effects. The modelling tool can also be used to estimate the relative contributions from changes in the individual fuel inputs to changes in exhaust emissions, and this is illustrated by means of an example blending study with crude-derived diesel fuel, biodiesel, and paraffinic gas-to-liquid (GTL) diesel fuel. This type of novel numerical analysis provides insights into fuel effects which are very difficult to achieve experimentally due to the high degree of intercorrelation between fuel properties that is usually present.

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数据驱动模型对柴油发动机性能和排放影响的预测

已经开发了一种建模工具，用于预测燃料对重型柴油发动机性能和废气排放的影响。以占空比、发动机控制和燃料特性参数为输入的递归神经网络模型使用来自配备共轨燃料喷射系统和可变几何涡轮增压器的15升重型柴油发动机的瞬态测试数据进行训练。试验燃料是通过混合市场柴油、炼油厂成分和生物柴油来配制的，以提供预选燃料特性的变化，即氢碳比、氧碳比、衍生十六烷值、粘度以及中终点蒸馏参数。注意确保测试燃料矩阵中这些燃料特性之间的相关性最小化，以避免混淆模型输入变量。试验发动机在各种瞬态试验循环中进行了试验，在这些试验循环中，燃油轨压力、喷射正时、气流和再循环废气流量都发生了系统性变化。由此产生的模型可以很好地预测瞬态发动机扭矩和燃料消耗，以及氮氧化物（NOx）、烟灰、一氧化碳（CO）、总碳氢化合物（THC）和二氧化碳（CO2）废气排放，这表明作为模型输入选择的有限数量的燃料特性参数足以捕捉燃料相关的影响。该建模工具还可用于估计单个燃料输入的变化对废气排放变化的相对贡献，这可通过与原油衍生柴油、生物柴油和链烷烃气-液（GTL）柴油的混合研究来说明。这种新型的数值分析提供了对燃料效应的深入了解，由于通常存在的燃料特性之间的高度相互关联，燃料效应很难通过实验实现。

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来源期刊

SAE International Journal of Fuels and Lubricants TRANSPORTATION SCIENCE & TECHNOLOGY-

CiteScore

2.20

自引率

10.00%

发文量