Study on mixture formation for a direct injection lean-burn LPG engine

2011 Second International Conference on Mechanic Automation and Control Engineering Pub Date : 2011-07-15 DOI:10.1109/MACE.2011.5987994

B. Xu, Y. Qi, Juan Xu, S. Cai

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Abstract

Currently, commercial gasoline direct injection engines mainly use wall-guided combustion system to prepare stratified mixture. In this system, the fuel droplets injected from one cylinder side usually tend to wall wet on the piston crown and the other side of the cylinder, which causing an increases of the HC emission. The liquid phase LPG has a lower boiling point and a higher vapor pressure than gasoline. When it is injected with the pressure more than 5MPa, flashing will occur, which speeds up the mixture formation and reduces wall wet. In this paper the mixture formation of direct injection LPG engine at part load and full load were investigated by numerical simulation. The results showed that, compared with gasoline spray using a swirl injector at part load, the LPG spray employing a single-hole injector burst fast once injected, and spray tip penetration was reduced. This resulted that rich mixture was still not guided to the spark plug area, even near the end of compression stroke. Therefore, it is necessary to advance the fuel injection timing of 5∼10°CA for LPG than gasoline at part load using single-hole injector at the same injection pressure. However, at high load, the injection advance could remain the same as that of gasoline.

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直喷稀燃LPG发动机混合气形成研究

目前，商用汽油直喷发动机主要采用壁面导向燃烧系统制备分层混合气。在该系统中，从气缸一侧喷射的燃料液滴通常在活塞顶和气缸另一侧呈壁湿状，从而导致HC排放增加。液态液化石油气的沸点比汽油低，蒸气压比汽油高。当注入压力大于5MPa时，会发生闪蒸，加速了混合物的形成，减少了壁湿。本文采用数值模拟方法研究了LPG直喷发动机在部分负荷和满载状态下的混合气形成。结果表明，在部分负荷下，与采用旋流喷射器的汽油喷雾相比，采用单孔喷射器的LPG喷雾在喷射后爆裂速度快，喷嘴穿透量减小;这导致丰富的混合物仍然没有被引导到火花塞区域，甚至接近压缩冲程的结束。因此，在相同的喷射压力下，使用单孔喷油器，在部分负荷下，LPG比汽油提前5 ~ 10°CA的喷射时间是必要的。然而，在高负荷时，喷射速度可以保持与汽油相同。

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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2011 Second International Conference on Mechanic Automation and Control Engineering

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