Evaluation of a Semiempirical, Zero-Dimensional, Multizone Model to Predict Nitric Oxide Emissions in DI Diesel Engines’ Combustion Chamber

IF 1.5 Q3 ENGINEERING, CHEMICAL Journal of Combustion Pub Date : 2016-03-16 DOI:10.1155/2016/6202438
N. Savva, D. Hountalas
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引用次数: 2

Abstract

In the present study, a semiempirical, zero-dimensional multizone model, developed by the authors, is implemented on two automotive diesel engines, a heavy-duty truck engine and a light-duty passenger car engine with pilot fuel injection, for various operating conditions including variation of power/speed, EGR rate, fuel injection timing, fuel injection pressure, and boost pressure, to verify its capability for Nitric Oxide (NO) emission prediction. The model utilizes cylinder’s basic geometry and engine operating data and measured cylinder pressure to estimate the apparent combustion rate which is then discretized into burning zones according to the calculation step used. The requisite unburnt charge for the combustion in the zones is calculated using the zone equivalence ratio provided from a new empirical formula involving parameters derived from the processing of the measured cylinder pressure and typical engine operating parameters. For the calculation of NO formation, the extended Zeldovich mechanism is used. From this approach, the model is able to provide the evolution of NO formation inside each burned zone and, cumulatively, the cylinder’s NO formation history. As proven from the investigation conducted herein, the proposed model adequately predicts NO emissions and NO trends when the engine settings vary, with low computational cost. These encourage its use for engine control optimization regarding NOx abatement and real-time/model-based NOx control applications.
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半经验的评估,零维,多区域模型预测一氧化氮排放在直喷式柴油发动机的燃烧室
在本研究中,作者建立了一种半经验的零维多区域模型,对两台带有先导燃油喷射的汽车柴油发动机(重型卡车发动机和轻型乘用车发动机)在功率/转速、EGR速率、燃油喷射正时、燃油喷射压力和增压压力等不同工况进行了仿真,验证了该模型对一氧化氮(NO)排放的预测能力。该模型利用汽缸的基本几何形状和发动机运行数据以及实测汽缸压力来估计表观燃烧速率,然后根据计算步骤将表观燃烧速率离散到燃烧区域。区域燃烧所需的未燃药量由区域等效比计算得到,该公式由处理实测气缸压力和典型发动机工作参数得到的参数组成。对于NO形成的计算,使用扩展的Zeldovich机制。通过这种方法,该模型能够提供每个燃烧区域内NO地层的演化情况,并累计提供柱体NO地层的历史。本文的研究表明,该模型能够较好地预测发动机设置变化时NO排放和NO趋势,且计算成本较低。这鼓励了它在发动机控制优化方面的应用,包括氮氧化物减排和实时/基于模型的氮氧化物控制应用。
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
Journal of Combustion
Journal of Combustion ENGINEERING, CHEMICAL-
CiteScore
2.00
自引率
28.60%
发文量
8
审稿时长
20 weeks
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