气体雾化过程中涉及颗粒形貌和空心颗粒形成的金属液滴变形和破碎数值模拟  

作　　者：汪鹏 黎兴刚 周香林[1] 陈志培 王淼辉 甘萍 任晓娜 余志勇 Peng WANG;Xing-gang LI;Xiang-lin ZHOU;Zhi-pei CHEN;Miao-hui WANG;Ping GAN;Xiao-na REN;Zhi-yong YU(State Key Laboratory for Advanced Metals and Materials,University of Science and Technology Beijing,Beijing 100083,China;China Machinery Institute of Advanced Materials(Zhengzhou)Co.,Ltd.,Zhengzhou 450001,China;Department of Materials Science and Engineering,Southern University of Science and Technology,Shenzhen 518055,China;School of Materials Science and Engineering,University of Science and Technology Beijing,Beijing 100083,China;China United Gas Turbine Technology Co.,Ltd.,Beijing 100016,China)

机构地区：[1]北京科技大学新金属材料国家重点实验,北京100083 [2]中机新材料研究院(郑州)有限公司,郑州450001 [3]南方科技大学材料科学与工程系,深圳518055 [4]北京科技大学材料科学与工程学院,北京100083 [5]中国联合重型燃气轮机技术有限公司,北京100016

出　　处：《Transactions of Nonferrous Metals Society of China》2024年第7期2074-2094,共21页中国有色金属学报（英文版）

基　　金：financially supported by the National Natural Science Foundation of China(Nos.51975240,52074157,51271034);the National Key Research and Development Program of China(No.2018YFB0703400);Department of Education of Guangdong Province,China(No.2023KTSCX121);Shenzhen Science and Technology Program,China(Nos.JSGG20210802154210032,JCYJ20210324104608023)。

摘　　要：采用考虑液滴冷却和凝固的流体体积(VOF)方法模拟金属液滴在气体雾化过程中的变形和破碎。建立典型粉末形貌和液滴破碎行为之间的相关性,以指导球形粉末颗粒的制备。结果显示,当增加液滴的气动力与黏性力的比值时,球形颗粒的形成得到加强;然而,当减小这个比值时,预期的液滴破碎模型将被改变或仅仅只发生液滴的变形。从空心颗粒的形成和演变过程的数值模拟中观察到几种典型的情况,例如,开放的空心液膜的形成、液膜封闭、气泡的离心和气泡的脱离。通过提高气体速度或液滴温度,实现较高的非平衡拉普拉斯压力或较低的粘性力,促使气泡从液滴内部分离。The deformation and breakup of metallic droplets during gas atomization were simulated using a volume of fluid(VOF)approach that considered droplet cooling and solidification.The correlation between the typical powder morphology and droplet breakup behavior was established to guide the preparation of spherical powder particles.The results showed that upon increasing the ratio of aerodynamic to viscous force of the droplet,the formation of spherical particles was enhanced,while upon decreasing this ratio,the expected droplet breakup mode changed or only droplet deformation occurred.Several typical scenarios were observed from the numerical simulations of the hollow particle formation and evolution process,e.g.,open hollow film formation,film closure,bubble centrifugation,and bubble detachment.By increasing the gas velocity or droplet temperature,a higher non-equilibrium Laplace pressure or lower viscous forces was achieved,which separated the bubbles from the interior of the droplet.

关 键 词：液滴破碎 空心颗粒 颗粒形貌 黏性力 金属粉末 气体雾化 

分 类 号：TF123.112[冶金工程—粉末冶金]