燃油近嘴区初始射流破碎及影响因素试验研究*

doi:10.19562/j.chinasae.qcgc.2020.01.014

摘要/Abstract

摘要： 搭建了燃油喷射雾化的可视化试验台架,采用数码相机和高放大倍数、高分辨率的长距离显微成像技术,以及纳秒级闪光灯作为相机曝光光源,对燃油近嘴区射流表面初始扰动微观结构进行可视化捕捉,结合图像后处理技术对射流表面结构参数和喷射参数进行定量测量和分析。研究发现,近嘴区初始射流表面波、液丝和液滴等产生、变形和破碎与喷油压力、空化以及环境背压密切相关。喷油压力增加,初始射流受到扰动增大,射流表面出现“坑洼”和“凸起”结构越靠近孔口;空化促进射流初始扰动、液丝和液滴的形成,致使喷雾锥角显著增加;环境背压增加,射流与环境介质之间剪切作用增大,可有效促进射流初始破碎,射流周围液丝进一步破碎形成液滴,有效地改善了雾化质量。

关键词: 射流破碎机理, 多相流, 显微成像, 可视化实验

Abstract: A visual test platform for the fuel injection atomization process is designed and built. With a nanosecond level flash lamp as the exposure light source, the digital camera and the long-distance micro imaging technology with high magnification and high resolution are used to visually capture the microstructure of the initial disturbance of the jet surface near the fuel nozzle area. Combined with the image post-processing technology, the jet surface structure parameters and injection parameters are measured and analyzed quantitatively. The study shows that the generation, deformation and breakup of the initial jet surface wave, liquid wire and liquid drop near the nozzle are closely related to the injection pressure, cavitation and environmental backpressure. With the increase of the injection pressure, the initial jet disturbance increases, and the “potholes” and “bulges” structures on the jet surface are more close to the nozzle. Cavitation promotes the formation of the initial jet disturbance, liquid wire and liquid drop, resulting in increase of the spray cone angle. With the increase of the environmental back pressure, the shear effect between the jet and the environmental medium increases and the initial breakup of the jet can be effectively promoted, and the liquid wire around the jet can be further broken to form droplet, which effectively improves the atomization quality

Key words: jet breakup mechanism, multiphase flow, microscopic imaging, visual experiment

高永强, 钟兵, 陶莉莉, 刘永辉, 王希波, 常静. 燃油近嘴区初始射流破碎及影响因素试验研究^*[J]. 汽车工程, 2020, 42(1): 94-99.

Gao Yongqiang, Zhong Bing, Tao Lili, Liu Yonghui, Wang Xibo, Chang Jing. Experimental Study on Initial Jet Breakup and InfluencingFactors Near Nozzle Area in Diesel Engine[J]. Automotive Engineering, 2020, 42(1): 94-99.

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燃油近嘴区初始射流破碎及影响因素试验研究^*

Experimental Study on Initial Jet Breakup and InfluencingFactors Near Nozzle Area in Diesel Engine

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