CFD Study of Cooking Liquor Blow for Piping Thrust Force and Risk of Condensation Hydraulic Shock

Andrew Carlson, C. Narayanan, D. Lakehal, Timo Hermonen, Noora Jokinen, J. Ikävalko
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Abstract

This study is an interesting industrial case study for the application of a validated flashing and hydraulic shock modelling approach to the safety and design of a reactor blow line. The maximum flow rate is important for sizing of downstream components. The high pressure of the blow and flashing of the liquid can result in significant forces on pipe bends and other geometrical features. Analysis and prediction of such forces are of importance for the structural design and anchoring of the piping. Another concern for a liquid blow under high pressure is the potential for condensation-induced hydraulic shock. The collapse of the flashed vapor to the liquid phase creating shock waves of large amplitudes is a serious safety concern. The CFD model used the homogeneous mixture model with a flashing model for phase change of the fluid. The properties of the fluid were defined by a custom function which interpolated between tabulated values of the thermodynamic and transport properties. The CFD simulations confirmed the risk of condensation hydraulic shock when the blow down is initiated with empty pipes and also demonstrated that a hydraulic shock could be prevented with liquid-filled condition. The pipework geometry was also optimized to reduce the forces acting at the junctions. The vapour quality at the outlet as a result of flashing was estimated which is necessary for the design of downstream systems.
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蒸煮液吹气对管道推力及冷凝液压冲击危险性的CFD研究
本研究是一个有趣的工业案例研究,用于将经过验证的闪光和液压冲击建模方法应用于反应器吹管的安全性和设计。最大流量对于下游部件的定径非常重要。液体的高压吹打和喷射会对管道弯头和其他几何特征产生显著的作用力。这种力的分析和预测对管道的结构设计和锚固具有重要意义。高压下液体冲击的另一个问题是冷凝引起液压冲击的可能性。闪蒸蒸汽向液相的坍缩产生大振幅的激波是一个严重的安全问题。CFD模型采用均匀混合模型和闪变模型来描述流体的相变。流体的性质由一个自定义函数定义,该函数在热力学和输运性质的表值之间进行插值。CFD模拟证实了在空管道下开始吹气时冷凝液压冲击的风险,也证明了在充满液体的情况下可以防止液压冲击。管道的几何形状也进行了优化,以减少作用在连接处的力。估计了由于闪蒸而导致的出口蒸气质量,这对下游系统的设计是必要的。
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