Numerical Investigation on Flow and Heat Transfer Performance of Supercritical Carbon Dioxide Based on Variable Turbulent Prandtlnumber Model

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摘要 Flow and heat transfer characteristic of supercritical carbon dioxide(SCO_(2))are numerically investigated in the horizontal and vertical tubes.TWL turbulent Prandtl number model could well describe the behavior of SCO_(2) affected by the buoyancy.Under the cooling condition,the heat transfer performance of SCO_(2) along the upward direction is best and that along the downward direction is worst when bulk fluid temperatures are below the pseudocritical temperature.Reducing the ratio of heat flux to mass flux could decrease the difference of convective heat transfer coefficient in three flow directions.Under the heating condition,heat transfer deterioration only occurs in vertical upward and horizontal flow directions.Heat transfer deterioration of SCO_(2) could be delayed by increasing the mass flux and the deterioration degree is weakened in the second half of tube along the vertical upward flow direction.Compared with the straight tube,the corrugated tube shows better comprehensive thermal performance.

作者 Xiaokai LIU Haiyan ZHANG Keyong CHENG Xiulan HUAI Haiyan LIAO Zhongmei ZHANG

机构地区 Institute of Engineering Thermophysics University of Chinese Academy of Sciences Nanjing Institute of Future Energy System CHN Energy New Energy Technology Research Institute CO.

出处《Mechanical Engineering Science》 2021年第2期1-8,共8页 机械工程（英文）

关键词 Supercritical carbon dioxide Turbulent Prandtl number Flow and heat transfer Field synergy principle Numerical investigation

分类号 O35 [理学—流体力学]

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参考文献4

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Mechanical Engineering Science

2021年第2期

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Numerical Investigation on Flow and Heat Transfer Performance of Supercritical Carbon Dioxide Based on Variable Turbulent Prandtlnumber Model

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