Experimental determination of the recovery factor on cylindrically flow-around temperature sensors Part 1: Determination of the recovery factor for different Reynolds- and Mach-Numbers

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY Applications in engineering science Pub Date : 2023-10-18 DOI:10.1016/j.apples.2023.100157
Andreas Huster, Simon Paymal
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Abstract

It is known in the literature that in the case of compressible fluids, higher values than the fluid temperature are displayed on temperature sensors, partly due to the accumulation point flow. Depending on the operating point, this can be several degrees Celsius. One possibility of consideration is the so-called recovery factor. There are various theoretical approaches and models that have been transferred on the basis of measurement on the flat plate. In some cases, the recovery factor is only defined as a function of the Prandtl number. A test bench has been developed that can be used to determine the recovery factor of cylindrical, quere-flowed temperature sensors. Up to Ma numbers of about 0.5, sensors with different diameters, and thus different Reynolds numbers, were measured and the recovery factors were calculated. There is a pronounced dependence on both the Ma number and the Re number and the recovery factor is not constant. An empirical equation based on the measurement results is given, with which the recovery factor can be determined as a function of the fluid, the Mach- and Reynolds-numbers and thus a more accurate calculation of the real fluid temperature is possible.

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圆柱绕流温度传感器恢复系数的实验测定。第1部分:不同雷诺数和马赫数恢复系数的测定
据文献所知,在可压缩流体的情况下,温度传感器上显示的值高于流体温度,部分原因是积累点流动。根据工作点的不同,这可能是几摄氏度。一种可能的考虑是所谓的恢复因素。在平板测量的基础上,有各种各样的理论方法和模型被转移。在某些情况下,恢复因子仅定义为普朗特数的函数。研制了一种可用于测定柱状、直流式温度传感器采收率的试验台。在Ma数约为0.5的情况下,测量了不同直径的传感器,从而计算了不同的雷诺数,并计算了采收率。对Ma数和Re数都有明显的依赖性,恢复系数不是恒定的。根据实测结果,给出了一个经验公式,利用该公式可以确定采收率系数是流体、马赫数和雷诺数的函数,从而可以更准确地计算实际流体温度。
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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
发文量
0
审稿时长
68 days
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