Enhancing Accuracy of Transition Models for Gas Turbine Applications Through Data-Driven Approaches

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-12 DOI:arxiv-2409.07803

Harshal D. Akolekar

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Abstract

Separated flow transition is a very popular phenomenon in gas turbines, especially low-pressure turbines (LPT). Low-fidelity simulations are often used for gas turbine design. However, they are unable to predict separated flow transition accurately. To improve the separated flow transition prediction for LPTs, the empirical relations that are derived for transition prediction need to be significantly modified. To achieve this, machine learning approaches are used to investigate a large number of functional forms using computational fluid dynamics-driven gene expression programming. These functional forms are investigated using a multi-expression multi-objective algorithm in terms of separation onset, transition onset, separation bubble length, wall shear stress, and pressure coefficient. The models generated after 177 generations show significant improvements over the baseline result in terms of the above parameters. All of the models developed improve the wall shear stress prediction by 40-70\% over the baseline laminar kinetic energy model. This method has immense potential to improve boundary layer transition prediction for gas turbine applications across several geometries and operating conditions.

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通过数据驱动方法提高燃气轮机应用过渡模型的准确性

在燃气轮机，尤其是低压涡轮机（LPT）中，分离流过渡是一种非常普遍的现象。低保真模拟通常用于燃气轮机的设计。然而，它们无法准确预测分离流过渡。为了改进 LPT 的分离流过渡预测，需要对用于过渡预测的经验关系进行重大修改。为此，我们采用机器学习方法，利用计算流体动力学驱动的基因表达编程研究了大量功能形式。利用多表达多目标算法，从分离起始点、过渡起始点、分离气泡长度、壁面剪应力和压力系数等方面对这些函数形式进行了研究。经过 177 代生成的模型在上述参数方面都比基线结果有显著改进。与基线层流动能模型相比，所有开发的模型都将壁面剪应力预测提高了 40-70%。该方法在改进燃气轮机应用的边界层过渡预测方面具有巨大潜力，适用于多种几何形状和工作条件。

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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arXiv - PHYS - Fluid Dynamics

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