文摘
流激振动(fip)工厂安全仍然是一个重要现象。值得注意的是,FIV的理解产生的多相流仍不成熟,和各种事故和问题报告工厂组件包括一个蒸汽发生器,天然气,管道系统,等等。这是因为FIV复杂是预测在核电站的设计阶段,通常是第一次注意到在操作阶段。因此,新型的实用解决方案FIV通过后处理进行了实验室规模的实验模拟原型。计算流体动力学(CFD)已成为一个强大的工具来评估FIV,但多相流的方法仍处于开发阶段。这部分是由于缺乏实验数据,不完整的界面转移条款包含在双流体模型,以及难以两两相流的动力学和结构动力学仿真阶段。此外,不足FIV数据库模拟基准也需要解决CFD的发展和有限元法(FEM)模型。现在回顾总结FIV基础由于气液两相流,和最近FIV研究活动从实验模拟。
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2021年1月08
本文���最先进的植物组件流激振动(fip)���Shuichiro Miwa Takashi科诺,写的是电子出版的出版商���年代互联网门户网站(目前SpringerLink) 2019年8月20日不开放。beplay登入出版后卷2,问题1、页面1���12,作者(年代)决定选择开放的选择,使本文成为开放获取出版。因此,文章的版权已经改为��本文作者(年代)2020和立即分布根据创作共用署名4.0国际许可证(http://creativecommons.org/licenses/by/4.0/),它允许使用、复制、改编、分发和复制在任何媒介或格式,只要你给予适当的信贷原始作者(年代)和来源,提供一个链接到Creative Commons许可,并指出如果变化。
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古板的,年代。,Hibiki, T. State-of-the-art in plant component flow-induced vibration (FIV).Exp。第一版。Multiph。流2,1 - 12 (2020)。https://doi.org/10.1007/s42757 - 019 - 0030 - 1
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关键字
- 流激振动(fip)
- 固耦合
- 两相流
- 弹状流