Effect of the Heat Transfer Coefficient Reference Temperatures on Validating Numerical Models of Supercritical CO2

IF 0.5 Q4 ENGINEERING, MECHANICAL Journal of Verification, Validation and Uncertainty Quantification Pub Date : 2021-12-01 DOI:10.1115/1.4051637
Ya-tsʻêng d. Chao, Nicholas C. Lopes, Mark A. Ricklick, S. Boetcher
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引用次数: 4

Abstract

Validating turbulence models for cooling supercritical carbon dioxide (sCO2) in a horizontal pipe is challenging due to the lack of experimental data with spatially resolved local temperature measurements. Although many variables may be present to cause discrepancies between numerical and experimental data, this study focuses on how the choice of reference temperatures (both wall reference temperature and fluid bulk reference temperature) when calculating the heat transfer coefficient influences turbulence-model validation results. While it may seem straightforward to simply use the same parameters as the experimental setup, this has not been observed in practice. In this work, numerical simulations are performed for cooling sCO2 in a horizontal pipe for p = 8 MPa, d = 6 mm, G = 200, and 400 kg/(m2s), and qw = 12, 24, and 33 kW/m2. Local and average heat transfer coefficients with different reference temperatures, found to be frequently used in the literature, are presented and compared with commonly used experimental data. It was found that the choice of reference temperatures has a significant influence on the results of the numerical validation. Historically, the higher heat flux cases have been more difficult to validate, theorized due to using reference temperatures differing from the experiment; however, good agreement was found here using the reference temperatures that most closely matched the experiment. This not only highlights the need for careful selection of reference temperatures in simulations, but also the importance of clearly defining the reference temperature employed when reporting experimental results.
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传热系数参考温度对超临界CO2数值模型验证的影响
由于缺乏具有空间分辨率的局部温度测量的实验数据,验证水平管道中冷却超临界二氧化碳(sCO2)的湍流模型具有挑战性。虽然可能存在许多变量导致数值和实验数据之间的差异,但本研究的重点是计算传热系数时参考温度(壁面参考温度和流体体参考温度)的选择如何影响湍流模型验证结果。虽然简单地使用与实验设置相同的参数似乎很简单,但在实践中并未观察到这一点。在这项工作中,数值模拟了在p = 8 MPa, d = 6 mm, G = 200和400 kg/(m2s), qw = 12, 24和33 kW/m2的水平管道中冷却sCO2的情况。本文给出了文献中常用的不同参考温度下的局部传热系数和平均传热系数,并与常用的实验数据进行了比较。结果表明,参考温度的选择对数值验证结果有显著影响。从历史上看,由于使用与实验不同的参考温度,较高的热通量情况更难以验证;然而,使用与实验最接近的参考温度,这里发现了很好的一致性。这不仅强调了在模拟中仔细选择参考温度的必要性,而且还强调了在报告实验结果时明确定义参考温度的重要性。
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CiteScore
1.60
自引率
16.70%
发文量
12
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