Studies on convective cooling of cryogenic fluids towards superconducting applications

WIT transactions on engineering sciences Pub Date : 2017-09-20 DOI:10.2495/CMEM170101

K. Satpathy, C. Dubois, A. Duchesne, J. Fagnard, H. Caps, P. Vanderbemden, B. Vanderheyden

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引用次数: 3

Abstract

To understand the cooling aspect through natural convection in a cryogenic fluid interacting with a constant heat source, numerical simulations are carried out in a parallelepiped enclosure. The 3D form of N-S equations is solved to obtain the detailed flow features through path line profiles, isotherm contours and velocity vectors. The effect of heater aspect ratio (x/L) on the rate of heat transfer is studied in terms of the average Nusselt number (Nuave). The results indicate that effective heat transfer enhancement occurs for a small heater length, resulting in an efficient cooling. Increasing the heater length will favor heat transfer through conduction over convection. The maximum temperature difference across the fluid and the velocity magnitude are found to decrease with heater length. 3D and 2D results are in agreement for short heater lengths, but vary for higher heater lengths, presumably due to the essential effect of the heater width. Further analysis on different types of coolant reveals a constant correlation between Nuave and the Rayleigh number (Ra), with Nuave ~ Ra0.374. Benchmark validation for natural convection in a square enclosure is found to be satisfactory against the reported results.

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低温流体对流冷却在超导应用中的研究

为了了解低温流体与恒定热源相互作用时的自然对流冷却问题，在平行六面体中进行了数值模拟。求解N-S方程的三维形式，通过路径线轮廓、等温线轮廓和速度矢量获得详细的流动特征。根据平均努塞尔数(Nuave)研究了加热器长径比(x/L)对传热速率的影响。结果表明，较短的加热器长度可以有效地增强传热，从而实现高效的冷却。增加加热器的长度将有利于传热通过传导而不是对流。流体的最大温差和速度大小随加热器长度的增加而减小。对于较短的加热器长度，3D和2D结果是一致的，但对于较长的加热器长度，结果会有所不同，这可能是由于加热器宽度的基本影响。对不同类型冷却剂的进一步分析表明，Nuave与瑞利数(Ra)之间具有恒定的相关性，Nuave ~ Ra0.374。对方形围护结构中自然对流的基准验证与所报告的结果相比是令人满意的。

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

WIT transactions on engineering sciences

CiteScore

1.20

自引率

0.00%

发文量