李大树,仇性启,于磊,郑志伟,马培勇,祁风雷.柴油液滴冲击液膜润湿壁面实验和数值模拟[J].农业机械学报,2014,45(12):9-17.
Li Dashu,Qiu Xingqi,Yu Lei,Zheng Zhiwei,Ma Peiyong,Qi Fenglei.Experiment and Numerical Simulation of Droplet Impacting onto a Wetted Surface[J].Transactions of the Chinese Society for Agricultural Machinery,2014,45(12):9-17.
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柴油液滴冲击液膜润湿壁面实验和数值模拟   [下载全文]
Experiment and Numerical Simulation of Droplet Impacting onto a Wetted Surface   [Download Pdf][in English]
投稿时间:2014-07-09  
DOI:10.6041/j.issn.1000-1298.2014.12.002
中文关键词:  液滴冲击  液膜润湿壁面  皇冠水花  液滴破碎飞溅
基金项目:“十二五”国家科技支撑计划资助项目(2012BAD30B01)、 国家自然科学基金资助项目(51006031)、 中央高校基本科研业务费专项资金资助项目(13CX02078A)和安徽省自然科学基金资助项目(11040606Q40)
作者单位
李大树 中国石油大学 
仇性启 中国石油大学 
于磊 中国石油大学 
郑志伟 中国石油大学 
马培勇 合肥工业大学 
祁风雷 爱荷华州立大学 
中文摘要:从实验和数值模拟两方面研究了液滴碰撞液膜润湿壁面的过程。实验采用高速摄像仪观测并分析了液滴撞壁后的铺展、水花形成和液滴破碎飞溅现象,并定量获得了液滴的铺展系数和铺展速度随时间的变化规律。实验结果表明:液滴的铺展系数和铺展速度的碰撞速度效应明显;碰撞速度越大,液滴的铺展系数越大;液滴撞壁后的铺展速度迅速减小,碰撞速度越大铺展速度越大。数值模拟采用流体体积法,综合考虑液滴与壁面间传热及接触热阻的作用,建立了液滴撞壁数值模型。该模型模拟结果和实验数据吻合较好,证明了数值模型的准确性。数值结果表明:液体内部的压力梯度是液滴铺展、产生皇冠水花和以及液滴破碎飞溅的主要原因;毛细波是水花颈部收缩和液滴破碎飞溅的关键因素。
Li Dashu  Qiu Xingqi  Yu Lei  Zheng Zhiwei  Ma Peiyong  Qi Fenglei
China University of Petroleum;China University of Petroleum;China University of Petroleum;China University of Petroleum;Hefei University of Technology;Iowa State University
Key Words:Droplet impact  Wetted surface  Crown liquid sheet  Droplet breakup and splash
Abstract:In order to explore the mechanism of fuel droplet impacting on a wetted surface in a small-size combustor of diesel engine, experiments and numerical simulation were carried out. High speed camera was used to observe the phenomenon of spreading, liquid sheet formation, breakup and splashing during droplet impact. The results showed that the spreading factor and velocity were closely related to impact velocity. The higher impact velocity droplet had a larger spreading factor, and the intial spreading velocity was the largest, which could be increased by increasing impact velocity. The numerical simulation was developed using volume of fluid method including heat transfer and contact resistance. The mechanism of droplet fluid and heat transfer as well as breakup during impact were obtained according to analysis of results. The numerical results also showed that the pressure gradient inside liquid was the main factor resulting in droplet spreading, liquid sheet formation, breakup and splashing. The capillary wave resulted in the shrink at the neck of the liquid sheet and breakup and splash from the liquid sheet.

Transactions of the Chinese Society for Agriculture Machinery (CSAM), in charged of China Association for Science and Technology (CAST), sponsored by CSAM and Chinese Academy of Agricultural Mechanization Science(CAAMS), started publication in 1957. It is the earliest interdisciplinary journal in Chinese which combines agricultural and engineering. It always closely grasps the development direction of agriculture engineering disciplines and the published papers represent the highest academic level of agriculture engineering in China. Currently, nearly 8,000 papers have been already published. There are around 3,000 papers contributed to the journal each year, but only around 600 of them will be accepted. Transactions of CSAM focuses on a wide range of agricultural machinery, irrigation, electronics, robotics, agro-products engineering, biological energy, agricultural structures and environment and more. Subjects in Transactions of the CSAM have been embodied by many internationally well-known index systems, such as: EI Compendex, CA, CSA, etc.

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