CFD-based investigation of turbulent flow behavior in 90-deg pipe bends

Journal of Applied Research in Technology & Engineering Pub Date : 2024-03-21 DOI:10.4995/jarte.2024.20665

Rilwan Kayode Apalowo, C. J. Akisin

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Abstract

This work investigated the influence of bend curvature on the parameters of turbulent flow through a 90° pipe bend using the numerical CFD method, implemented in ANSYS Fluent. The numerical predictions were validated to be in good agreement with existing experimental measurements. The turbulence of the secondary motion was found to be generally stronger at the outer end of the pipe bend, with the most adverse effect recorded at about 45° along the bend. It was also observed that the RMS velocity is larger near the wall, especially at the outer wall region, and it is highest at 45° due to an increase in the circulation of dean vortices, indicating a turbulence generation. In addition, the RMS velocity increases downstream due to an additional mean strain resulting from the creation of secondary flow as the flow travels through the bend. Furthermore, larger static pressure and turbulent viscosity were observed at the outer wall due to the flow deceleration and swirling. Therefore, it can be established that the bend curvature affects the stability of the flow field inside a pipe bend.

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基于 CFD 的 90 度弯管湍流行为研究

本研究采用 ANSYS Fluent 中的 CFD 数值方法，研究了弯管曲率对通过 90° 弯管的湍流参数的影响。经过验证，数值预测结果与现有的实验测量结果十分吻合。研究发现，二次运动的湍流一般在弯管外端较强，在弯管 45° 处的影响最大。同时还观察到，在管壁附近，特别是在外壁区域，均方根速度较大，在 45° 处最高，这是因为笛安涡流循环增加，表明产生了湍流。此外，由于水流通过弯道时产生的二次流导致了额外的平均应变，因此下游的均方根速度会增加。此外，由于流动减速和漩涡，在外壁观察到较大的静压和湍流粘度。因此，可以确定弯管曲率会影响弯管内流场的稳定性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Applied Research in Technology & Engineering

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