用不同湍流模型模拟非对称扩散器湍流的直角切割槽技术

IF 2.9 2区数学 Q1 MATHEMATICS, APPLIED

Computers & Mathematics with Applications Pub Date : 2025-01-21 DOI:10.1016/j.camwa.2025.01.015

A.S. Dawood, A.S. Amer, R.M. Abumandour, W.A. El-Askary

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引用次数: 0

摘要

无论是选择合适的计算网格还是使用合适的湍流模型，准确预测分离湍流的行为都需要付出巨大的努力。本文介绍了一种预测非对称扩散器中湍流分离流动特性的比较数值研究方法。本文在自行开发的FORTRAN代码中使用有限体积方法对具有三种湍流模型（标准k−ε， Chen-kim和修改的Chen-kim）的不可压缩Reynolds平均Navier Stokes方程（RANS）进行了数值模拟。由于不对称扩散器复杂的流动特性和几何形状，对其处理提出了挑战。为了解决这个问题，采用了一种发达的笛卡尔切割单元技术，它提供了与固体边界的兼容性，并有效地处理复杂的几何形状。这种发展的切割单元技术进行了检查，以处理其预测具有强压力梯度的复杂湍流的正确性和收敛性的能力，以及测试所提出的湍流模型的性能。因此，通过将现有的非对称扩散器流动特性计算结果与现有的实验数据和LES数据进行比较，进行验证。所提出的模型在大多数情况下都显示出可接受的一致性，特别是改进的Chen-kim模型，在所有流动特性上都与实验和LES结果非常吻合。在大多数比较中，标准k-ε模型不能很好地预测流动分离。利用改进的Chen-kim湍流模型，进一步研究了扩散角（4 ~ 15°）和面积比（2.4 ~ 7）对扩散器流动特性的影响。参数化研究表明，压力恢复系数、表面摩擦系数和分离气泡尺寸对扩压器性能有较大影响。

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Simulation of cartesian cut-cell technique for modeling turbulent flow in asymmetric diffusers using various turbulence models

The process of accurately predicting the behavior of the separated turbulent flow requires extraordinary efforts, whether it is choosing the appropriate computational mesh or using the appropriate turbulence model for that. The present study introduces a comparative numerical investigation for predicting the behavior of turbulent-separated flow in asymmetric diffusers. Numerical simulation using a finite volume approach of incompressible Reynolds Averaged Navier Stokes equations (RANS) with three turbulence models (Standard k−ε, Chen-kim, and modified Chen-kim) is here performed in a self-developed FORTRAN code. The treatment of asymmetric diffusers poses challenges due to the complex flow behavior and geometry. To address this, a developed cartesian cut-cell technique is employed, which provides compatibility with solid boundaries and efficiently handles complex geometries This developed cut-cell technique is checked to treat its ability to predict complex turbulent flow with the presence of strong pressure gradient for correctness and convergence, as well as testing the proposed turbulence-models performance. So, verifications are performed by comparing the present computational results of asymmetric-diffuser flow characteristics with available experimental and LES data. The proposed models reveal acceptable agreements in most cases, especially the modified Chen-kim model, which shows a great match with the experimental and LES results for all flow characteristics. The standard k-ε model fails to predict the flow-separation well in most comparisons. Extended computational studies are also introduced to investigate the effects of diffuser cant angles (4 to 15°) and area ratio (2.4 to 7) on the diffuser flow behavior using the successfully modified Chen-kim turbulence model. The parametric study reveals that these two factors strongly affect the diffuser performance, where the pressure recovery, skin friction coefficients, and separation bubble size are provided.

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来源期刊

Computers & Mathematics with Applications 工程技术-计算机：跨学科应用

CiteScore

5.10

自引率

10.30%

发文量

396

审稿时长

9.9 weeks

期刊介绍： Computers & Mathematics with Applications provides a medium of exchange for those engaged in fields contributing to building successful simulations for science and engineering using Partial Differential Equations (PDEs).