Numerical Study on Renewable and Sustainable Fuels for HPDF Engines

ASME 2020 Power Conference Pub Date : 2020-08-04 DOI:10.1115/power2020-16438

S. Frankl, A. Gelner, S. Gleis, M. Härtl, G. Wachtmeister

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引用次数: 4

Abstract

Renewable and sustainable fuels (based on electricity) will play a key role in future scenarios for power supply. Enabling storage and distribution of local and temporal fluctuations of renewable energies, different e-fuels with varying production processes and characteristics get interesting for different locations. For reconversion of the chemical energy, a fuel-flexible internal combustion engine with a High Pressure Dual Fuel (HPDF) combustion process is suitable for different e-fuels. As the combustion process is the main influence on emissions, combustion behavior of the studied fuels hydrogen, methane, methanol and ammonia, ignited by the pilot fuels Fischer-Tropsch diesel and polyoxymethylene dimethyl ethers (OME), is investigated in varying fuel pairings. In addition, a review of production efficiencies and important characteristics like toxicity and storage method is given. Afterwards, the application of the investigated fuels in HPDF-combustion is investigated. The investigations are conducted with a numerical 3D-CFD model of a large bore high speed single cylinder research engine. The differences in ignition and combustion when using diesel or OME as pilot fuel are shown and a comparison of the emissions for the used main fuels is given.

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HPDF发动机可再生和可持续燃料的数值研究

可再生和可持续燃料(以电力为基础)将在未来的电力供应中发挥关键作用。能够储存和分配可再生能源的当地和时间波动，不同的电子燃料具有不同的生产过程和特性，在不同的地点变得有趣。为了实现化学能的再转化，采用高压双燃料(HPDF)燃烧过程的燃料柔性内燃机适用于不同的电子燃料。由于燃烧过程是影响排放的主要因素，因此研究了实验燃料氢、甲烷、甲醇和氨在不同燃料对下的燃烧行为，分别由中试燃料费托柴油和聚氧亚甲基二甲醚(OME)点燃。此外，还对其生产效率、毒性、储存方法等重要特性进行了综述。然后，研究了所研究的燃料在hpdf燃烧中的应用。利用某大口径高速单缸研究发动机的三维cfd数值模型进行了研究。在使用柴油或OME作为先导燃料时，显示了点火和燃烧的差异，并对使用的主要燃料的排放进行了比较。

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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ASME 2020 Power Conference

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