Effect of heat flux and mass flux on the heat transfer characteristics of supercritical carbon dioxide for a vertically downward flow using computational fluid dynamics and artificial neural networks

IF 1.1 Q3 Engineering

Journal of Thermal Engineering Pub Date : 2023-10-17 DOI:10.18186/thermal.1376850

Rajendra PRASAD K S, Vijay KRISHNA, Sachin BHARADWAJ

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引用次数: 0

Abstract

Drastic variation in the thermodynamic properties of supercritical fluids near the pseudo critical point hinders the use of commercial computational fluid dynamics (CFD) software. However, with the increase in computational abilities, along with the use of Artificial Neu-ral Networks (ANN), turbulence heat transfer characteristics of supercritical fluids can be very accurately predicted. In the present work, heat transfer characteristics for a vertically downward flow of carbon dioxide in a pipe are studied for a wide range of heat flux and mass flux values. Firstly, six different turbulent models available in the commercial CFD software - Ansys Fluent are validated against the experimental results. The k- ω Standard model with enhanced wall treatment is found to be the best-suited turbulence model. When experimental results were validated in CFD, an average error of 1% in the bulk fluid temperature and 2% in the wall temperature were recorded. Further, K- ω Standard Turbulence Model is used in CFD for parametric analysis to generate the data for ANN studies. Mass flux range of 238 to 1038 kg/m2s, and heat flux range of 26 kW/m2 to 250 kW/m2 are used to generate 81,432 data sam-ples. These samples were fed into the ANN program to develop an equation that can predict the heat transfer coefficient. It was found that ANN can predict the heat transfer coefficient for the considered range of values within the absolute average relative deviation of 2.183 %.

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利用计算流体力学和人工神经网络研究超临界二氧化碳垂直向下流动时热流通量和质量通量对传热特性的影响

超临界流体在伪临界点附近热力学性质的剧烈变化阻碍了商用计算流体动力学(CFD)软件的使用。然而，随着计算能力的提高，以及人工神经网络(ANN)的使用，可以非常准确地预测超临界流体的湍流传热特性。在本工作中，研究了二氧化碳在管道中垂直向下流动时的换热特性，该换热特性适用于大范围的热流密度和质量流密度。首先，对商用CFD软件Ansys Fluent中6种不同的湍流模型与实验结果进行了验证。采用增强壁面处理的k- ω标准模型是最合适的湍流模型。在CFD中对实验结果进行验证时，记录到的总体流体温度平均误差为1%，壁面温度平均误差为2%。此外，在CFD中使用K- ω标准湍流模型进行参数分析，生成用于人工神经网络研究的数据。质量通量238 ~ 1038kg /m2s，热流通量26kw /m2 ~ 250kw /m2，共生成81432个数据样本。这些样本被输入到人工神经网络程序中，以建立一个可以预测传热系数的方程。结果表明，人工神经网络可以在2.183%的绝对平均相对偏差范围内预测出考虑范围内的换热系数。

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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来源期刊

Journal of Thermal Engineering THERMODYNAMICS-

CiteScore

2.40

自引率

18.20%

发文量

审稿时长

4 weeks

期刊介绍： Journal of Thermal Enginering is aimed at giving a recognized platform to students, researchers, research scholars, teachers, authors and other professionals in the field of research in Thermal Engineering subjects, to publish their original and current research work to a wide, international audience. In order to achieve this goal, we will have applied for SCI-Expanded Index in 2021 after having an Impact Factor in 2020. The aim of the journal, published on behalf of Yildiz Technical University in Istanbul-Turkey, is to not only include actual, original and applied studies prepared on the sciences of heat transfer and thermodynamics, and contribute to the literature of engineering sciences on the national and international areas but also help the development of Mechanical Engineering. Engineers and academicians from disciplines of Power Plant Engineering, Energy Engineering, Building Services Engineering, HVAC Engineering, Solar Engineering, Wind Engineering, Nanoengineering, surface engineering, thin film technologies, and Computer Aided Engineering will be expected to benefit from this journal’s outputs.