乙醇喷雾稳定自燃所需环境条件的数值研究

IF 1.5 Q3 ENGINEERING, CHEMICAL Journal of Combustion Pub Date : 2019-10-17 DOI:10.1155/2019/1329389
H. Saitoh, K. Uchida, Norihiko Watanabe
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引用次数: 0

摘要

本文研究了高性能压缩点火酒精发动机控制点火技术的发展。在酒精燃料中,我们重点关注乙醇,因为它是一个有前途的替代燃料替代石油。本研究的目的是揭示乙醇喷雾自燃前混合物形成过程中的物理和化学现象。在我们之前的数值研究中,我们以空间过剩空气比和喷雾内温度分布的形式展示了汽油和乙醇喷雾的混合形成过程以及燃油喷射的时间历史。结果与基于喷淋动量理论的理论分析结果吻合较好。通过与实验结果的对比,验证了计算的合理性。通过一系列的实验和数值研究,揭示了乙醇喷雾自燃质量差的原因,即与传统柴油相比,乙醇喷雾的燃料和热性质,其化学计量空燃比小,蒸发热大,难以同时达到喷雾混合物的自燃适宜浓度和温度。然而,无论是实验还是数值分析,都没有得到乙醇喷雾的自燃现象。下一步,我们数值测试了几种周围气体压力和温度条件,以明确周围气体条件足以获得稳定的自燃。计算中使用了商业CFD代码之一CONVERGE,考虑了湍流、雾化、蒸发和详细的化学反应。本文讨论了乙醇喷雾在可接受的点火延迟条件下稳定自燃所需的周围气体压力和温度,以及研制高性能压缩点火酒精发动机的可行性。
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Numerical Study on the Required Surrounding Gas Conditions for Stable Autoignition of an Ethanol Spray
This study deals with the development of controlled-ignition technology for high-performance compression ignition alcohol engines. Among the alcohol fuels, we focus on ethanol as it is a promising candidate of alternative fuels replacing petroleum. The objective of this study is to reveal the physical and chemical phenomena in the mixture formation process up to autoignition of an ethanol spray. In our previous numerical study, we showed the mixture formation process for gas oil and ethanol sprays in the form of spatial excess air ratio and temperature distributions inside a spray and their temporal histories from fuel injection. The results showed a good agreement with those of theoretical analysis based on the momentum theory of spray penetration. Calculation was also confirmed as reasonable by comparing to the experimental results. Through the series of our experimental and numerical studies, the reason for poor autoignition quality of an ethanol spray was revealed, that is, difficulty in simultaneous attainments of autoignition-suitable concentration and temperature in the spray mixture formation due to its fuel and thermal properties of smaller stoichiometric air-fuel ratio and much greater heat of evaporation compared to conventional diesel fuels. However, autoignition of an ethanol spray has not been obtained yet in either experiments or numerical analysis. As the next step, we numerically examined several surrounding gas pressure and temperature conditions to make clear the surrounding gas conditions enough to obtain stable autoignition. One of the commercial CFD codes CONVERGE was used in the computational calculation with the considerations of turbulence, atomization, evaporation, and detailed chemical reaction. Required surrounding gas pressure and temperature for stable autoignition with acceptable ignition delay of an ethanol spray and feasibility of the development of high-performance compression ignition alcohol engines are discussed in this paper.
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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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