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机构地区:[1]西安交通大学能源与动力工程学院,西安710049
出 处:《西安交通大学学报》2012年第7期115-121,共7页Journal of Xi'an Jiaotong University
基 金:国家自然科学基金资助项目(51106125);高等学校博士学科点专项科研基金资助项目(20090201110059);中央高校基本科研业务费专项资金资助项目
摘 要:通过优化极值点位置,对表面自由能模型进行了研究和改进,改进后的模型解决了原模型中表面粒子聚集和液滴形状畸变的问题.采用移动粒子半隐式法(MPS)结合改进后的表面自由能模型,对受表面张力作用的自由面运动问题进行了研究和分析.研究了包括气液、固液和不互溶液液界面在内的表面张力收缩和液滴浸润过程,并提取了接触角及浸润面积等特征量进行分析.数值计算结果与理论分析结果吻合较好,从结果中可以明显观察到固液浸润过程的3个发展阶段,浸润速度随时间递减且与浸润接触角成反比.研究结果验证了MPS方法结合改进后的表面自由能模型可以更加有效、准确地模拟多界面张力的作用.An improved surface tension model was obtained by optimizing the position of the ex- treme point. The particle clustering and shape distortion problems were solved by the model im- proved. The moving particle semi-implicit (MPS) method combined with the improved model was adopted to simulate the wetting phenomenon with large deformation of the free surface. The shrinkage and wetting effect, due to the surface tension, between different substances (gas- liquid, solid-liquid or liquid-liquid) was examined and analyzed. The wetting angle and wetting area were extracted for analysis. The numerical result agrees well with the analytical one. Three sections could be observed in the liquid-solid wetting process. The wetting speed decreases with an increase in time and varies inversely with the wetting angle. Our results indicate that the MPS method combined with the improved surface tension model can simulate the interface tension force between different substances effectively and precisely.
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