A Computational Study of Hydrogen Direct Injection Using a Pre-Chamber in an Opposed-Piston Engine

Rafael Menaca, Kevin Moreno Cabezas, Mohammad Raghib Shakeel, Giovanni Vorraro, James W. G. Turner, Hong G. Im
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Abstract

Combustion characteristics of a hydrogen (H2) direct-injected (DI) pre-chamber (PC)-assisted opposed piston two-stroke (OP2S) engine are investigated by 3D computational fluid dynamics (CFD) simulations. The architecture of the OP2S engine has potential features for reducing wall heat losses, as the DI H2 jets are not directed towards the piston face. To overcome the high resistance to autoignition of H2, a PC technology was implemented in order to enhance the ignition of the mixture by the multiple hot reactive jets. To further investigate the interaction between the H2 plume and the chamber walls, three different piston bowl designs were evaluated and ranked based on a merit function. For the cases under study, the flat piston design was found to be most favorable (compared to the narrow and wide pistons) due to its reduced surface area for lower wall heat losses. The results also showcase that a co-optimization approach considering various parameters is an effective strategy to minimize the flame-wall interaction. The analysis showed that the PC jet must guarantee ignition and also a high-momentum exchange to support mixing-controlled and late combustion stages, while keeping safety limits from being exceeded. Finally, the results highlight that DI-PC H2 combustion exhibits Diesel-like behavior, which can be exploited to achieve high efficiency and low emissions. Similar to conventional Diesel combustion (CDC), DI-PC H2 combustion can provide the control of combustion phasing by adjusting the timing of the hot jet injection. While more work is needed to achieve the same level of efficiency as CDC, the present study demonstrated additional benefits of DI-PC concept as a robust carbon-free engine operation option. Finally, the analysis with respect to the fuel energy distribution and the DI-PC H2 combustion phases shows that it is possible to further optimize combustion, especially in mixing-controlled and late stages.
对置活塞发动机中使用预腔的氢气直喷计算研究
通过三维计算流体动力学(CFD)模拟研究了氢气(H2)直喷(DI)前室(PC)辅助对置活塞二冲程(OP2S)发动机的燃烧特性。OP2S 发动机的结构具有减少活塞壁热量损失的潜在特点,因为 DI H2 喷射不直接对着活塞面。为了克服 H2 自燃阻力大的问题,我们采用了 PC 技术,以增强多个热反应喷流对混合气的点燃作用。为了进一步研究 H2 烟流与燃烧室壁之间的相互作用,我们对三种不同的活塞碗设计进行了评估,并根据优点函数进行了排序。在研究的案例中,发现扁平活塞设计最为有利(与窄活塞和宽活塞相比),因为它的表面积减少了,从而降低了壁面热损失。结果还表明,考虑各种参数的共同优化方法是将焰壁相互作用降至最低的有效策略。分析表明,PC 喷射必须保证点火和高动量交换,以支持混合控制和后期燃烧阶段,同时保持不超过安全限制。最后,研究结果突出表明,DI-PC H2 燃烧表现出类似柴油机的特性,可以利用这种特性实现高效率和低排放。与传统柴油燃烧(CDC)类似,DI-PC H2 燃烧可通过调整热喷射的时间来控制燃烧阶段。虽然要达到与 CDC 相同的效率水平还需要做更多的工作,但本研究证明了 DI-PC 概念作为一种强大的无碳发动机运行方案的额外优势。最后,对燃料能量分布和 DI-PC H2 燃烧阶段的分析表明,有可能进一步优化燃烧,特别是在混合控制和后期阶段。
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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