外部流量的伽马和 BC 转换模型的评估和比较

IF 0.4 4区 工程技术 Q4 ENGINEERING, MECHANICAL
Sami KARABAY, Özgür Ugras BARAN
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引用次数: 0

摘要

由于近年来可再生能源、无人机技术和类似航空航天应用的发展,层流到湍流过渡的建模成为一个热门话题。从层流到湍流的过渡是CFD分析中一个具有挑战性的问题。如果在CFD解决方案中假设流动是完全紊流而忽略过渡,则会高估阻力。这就导致了流的基本特征的缺失和流场预测的不准确。最常用的转换模式是应用于海温湍流模式的Menter模式和应用于Spalart-Almaras模式的baul -Çakmakçıoğlu (BC)转换模式。我们专注于Menter的更简单但更受欢迎的γ模型和baek Çakmakçıoğlu模型。γ模型依赖于局部湍流强度,这使得该模型在外部流动中的应用具有挑战性。这种困难源于湍流衰减和跃迁开始之间的复杂关系。BC转捩模型利用了自由流湍流强度。两种模型都使用k黎巴嫩夫和ERCOFTAC平板情况和几个二维外部流动情况进行了验证。皮肤摩擦系数计算结果与实验数据进行了比较。结果表明,两种模型对跃迁的预测非常相似。与γ模型相比,BC模型在计算上更便宜,更容易实现。此外,γ模型还存在边界条件模糊的问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
GAMMA VE BC GEÇİŞ MODELLERİNİN DIŞ AKIŞLAR İÇİN DEĞERLENDİRİLMESİ VE KARŞILAŞTIRILMASI
Modelling of transition from the laminar to turbulent flow became a hot topic due to recent developments in renewable energy, UAV technologies and similar aerospace applications. The transition from laminar flow to turbulence is challenging to model in CFD analysis. The drag is overestimated if the transition is neglected in CFD solutions by assuming the flow is fully turbulent. This results in missing the fundamental characteristics of the flow and inaccurate predictions of the flow field. The most popular transition models are Menter's models applied to the SST turbulence model and the Baş-Çakmakçıoğlu (BC) transition model applied to the Spalart-Almaras model. We have focused on Menter's simpler but more popular γ model and Baş Çakmakçıoğlu models. The γ model relies on the local turbulence intensity, which makes applying the model challenging in external flows. This difficulty stems from the complex relationship between turbulence decay and transition onset. BC transition model utilizes the free stream turbulence intensity. Both models are verified using the Klebanoff and ERCOFTAC flat plate cases and several 2D external flow cases. Skin friction coefficient results are compared to experimental data. Results show that both models predict transition very similarly. BC model is computationally cheaper and easier to implement than the γ model. Also, γ model suffers from boundary conditions ambiguity.
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来源期刊
CiteScore
1.00
自引率
0.00%
发文量
19
审稿时长
>12 weeks
期刊介绍: The “Journal of Thermal Sciences and Technology”, which started its publication in 1977 with the aim of encouraging the development of heat science and technology and enabling the publication of original, theoretical, numerical and experimental papers in its field, is published twice a year in April and October. Original and compilation articles on the subject of heat science and technology are included and each article is evaluated by at least two referees who are experts in their field.
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