Integrated 1D-chemical kinetics model of a diesel and biodiesel fuelled light-duty diesel engine

2017 3rd International Conference on Power Generation Systems and Renewable Energy Technologies (PGSRET) Pub Date : 2017-04-01 DOI:10.1109/PGSRET.2017.8251807

J. Ng, Kang Yao Wong, C. Chong, S. Rajoo

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Abstract

In recent years, advances in numerical modelling of engines have led to the integration of 3-dimensional computational fluid dynamics with chemistry to calculate both the physical flow field and complex chemical reactions. However, it is only feasible to simulate the combustion chamber, but not the entire engine due to simulation runtime limitations. Onedimensional (1D) simulations of an entire engine are rapid yet comprehensive, but focus only on the applied thermodynamics with rudimentary global reaction chemistry. In this study, a compact combined biodiesel-diesel chemical kinetics reaction mechanism is integrated into the 1D modelling of a complete engine. Entire engine cycle from air intake to exhaust product is simulated using commercial software, AVL Boost. This allows for rapid system-level simulation which takes into account applied thermodynamics with complex chemical kinetics to account for combustion and pollutant formation. The integrated 1D-chemical kinetics model is successfully validated against experimental data with both the diesel and palm biodiesel fuel for key combustion parameters. The model would be able to simulate any dieselbiodiesel mixture of any blend levels and also biodiesel produced from different feedstock. This is due to the reaction mechanism comprising of n-Heptane, methyl butanoate and methyl crotonate which are the surrogate fuel models of straight chain hydrocarbon, saturated fatty acid methyl ester (FAME) and unsaturated FAME, respectively. Thus, CME, PME, and SME, are selected for blending due to their innate FAME proportions to represent the high, medium, and low saturated:unsaturated biodiesel, respectively. In all, through 100 simulated cases, this study demonstrated the feasibility of integrating chemical kinetics into 1D numerical model for a complete engine. Ultimately, the use of an integrated 1D-chemical kinetics model for engine simulations can greatly reduce optimisation time for emissions reduction.

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以柴油和生物柴油为燃料的轻型柴油机的集成一维化学动力学模型

近年来，发动机数值模拟的进步使得三维计算流体力学与化学相结合，既可以计算物理流场，也可以计算复杂的化学反应。但是，由于模拟运行时间的限制，只能模拟燃烧室，而不能模拟整个发动机。整个发动机的一维(1D)模拟快速而全面，但只关注应用热力学和基本的全局反应化学。在这项研究中，一个紧凑的组合生物柴油-柴油化学动力学反应机制被集成到一个完整的发动机的一维建模。使用商用软件AVL Boost模拟了从进气到排气产品的整个发动机循环。这允许快速的系统级模拟，考虑到应用热力学与复杂的化学动力学，以解释燃烧和污染物的形成。结合柴油和棕榈生物柴油的实验数据，成功验证了集成的一维化学动力学模型的关键燃烧参数。该模型将能够模拟任何混合水平的柴油-生物柴油混合物，也可以模拟由不同原料生产的生物柴油。这是由于反应机理由正庚烷、丁酸甲酯和巴豆酸甲酯组成，而正庚烷、丁酸甲酯和巴豆酸甲酯分别是直链烃、饱和脂肪酸甲酯和不饱和脂肪酸甲酯的替代燃料模型。因此，选择CME、PME和SME进行混合，因为它们固有的FAME比例分别代表高、中、低饱和:不饱和生物柴油。总而言之，通过100个模拟案例，本研究证明了将化学动力学集成到一个完整发动机的一维数值模型中的可行性。最终，使用集成的一维化学动力学模型进行发动机模拟可以大大减少减排的优化时间。

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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2017 3rd International Conference on Power Generation Systems and Renewable Energy Technologies (PGSRET)

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