Development of a Predictive Pressure Waves Model for High-Pressure Common Rail Injection Systems

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY SAE International Journal of Engines Pub Date : 2021-12-29 DOI:10.4271/03-15-05-0039
G. Silvagni, V. Ravaglioli, F. Ponti, E. Corti, Lorenzo Raggini, G. Scocozza, Federico Stola, Matteo De Cesare
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引用次数: 4

Abstract

Over the last years, automotive industries drove a great amount of research in the field of advanced combustion techniques minimizing carbon dioxide emissions. The so-called Low-Temperature Combustions (LTC), characterized by the self-ignition of highly premixed air-fuel mixtures, represent a promising solution to achieving high efficiency and ultralow emissions of nitrogen oxides (NOx) and particulate matter. Among these, gasoline Partially Premixed Combustion (PPC), obtained through the high-pressure direct injections of gasoline, showed a good potential for the simultaneous reduction of pollutants and emissions in compression ignited engines. However, when multiple injections per cycle are performed (with hydraulic-assisted needle opening), combustion stability might be compromised by the wave effects in the hydraulic system, which produce incoherence between the requested and injected fuel. This work presents a model-based pressure waves reconstruction strategy, based on a control-oriented model of the high-pressure common rail injection system fueled with gasoline. To determine the hydraulic system’s behavior during the injection process, a specifically designed flushing bench with a high-frequency acquisition system has been developed. Experimental activities have been carried out to highlight fuel pressure fluctuations with single and double injection patterns. Through the analysis of the acquired data, the key parameters (characteristic of the system) have been identified and the accuracy of pressure waves reconstruction has been evaluated, always returning errors lower than 2% between measured and estimated instantaneous pressures. Different fuel types, injectors, and rail positions have been tested to highlight the robustness of the approach. Based on the instantaneous pressure trace estimated with the control-oriented model, a fuel quantity Fluctuation Correction Strategy (FQC), implementable on a standard engine Electronic Control Unit (ECU), has been developed. The obtained results confirm the potential to reduce fuel quantity oscillations in multiple-injections systems.
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高压共轨喷射系统压力波预测模型的建立
在过去的几年里,汽车工业在先进的燃烧技术领域推动了大量的研究,以减少二氧化碳的排放。所谓的低温燃烧(LTC),其特点是高度预混的空气燃料混合物自燃,代表了一种很有前途的解决方案,可以实现高效率和超低排放的氮氧化物(NOx)和颗粒物。其中,通过高压直喷汽油获得的汽油部分预混燃烧(PPC)在压缩点火发动机中显示出良好的同时减少污染物和排放的潜力。然而,当一个循环进行多次喷射时(液压辅助开针),燃烧稳定性可能会受到液压系统中的波动效应的影响,从而导致所需燃料和喷射燃料之间的不一致性。本文提出了一种基于模型的压力波重建策略,该策略基于以汽油为燃料的高压共轨喷射系统的面向控制模型。为了确定液压系统在注入过程中的行为,开发了一个专门设计的带有高频采集系统的冲洗工作台。已经进行了实验活动,以突出单次和双次喷射模式下的燃油压力波动。通过对采集数据的分析,确定了关键参数(系统特性),并对压力波重建的精度进行了评价,瞬时压力测量值与估算值之间的误差始终小于2%。测试了不同的燃料类型、喷油器和导轨位置,以突出该方法的稳健性。基于控制导向模型估计的瞬时压力轨迹,提出了一种可在标准发动机电控单元(ECU)上实现的燃油量波动校正策略(FQC)。所得结果证实了在多次喷射系统中减少燃油量振荡的潜力。
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来源期刊
SAE International Journal of Engines
SAE International Journal of Engines TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
2.70
自引率
8.30%
发文量
38
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