Experimental determination of convective heat transfer coefficients of synthetic oil using wilson plot technique

U. Srivastva, R. Malhotra, K. R. Kumar, S. Kaushik
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Abstract

This paper describes the experiments to determine the convective heat transfer coefficients on a synthetic heat transfer fluid flowing in a Shell-and-Tube heat exchanger. The analysis of results is carried out by application of the Wilson plot Technique, on the basis of which, the convective heat transfer coefficients were experimentally obtained for the fluid flowing inside the tube. The convective heat transfer coefficient of oil derived through Wilson plot is then compared with the convective heat transfer coefficients obtained using the classical thermal resistance equation. An empirical correlation between the convective heat transfer coefficient of oil with respect to its mean velocity of flow in the tube and the bulk oil temperature has been proposed. A correction factor of 2.3 and exploration of the exponent value of 0.2 pertaining to the velocity of oil was obtained. The values of convective heat transfer coefficients obtained after applying the correction factor are consistent with the values reported in the literature for oil-water heat transfers. The variation of the heat transfer coefficients at different temperatures is attributed to factors like vapor blanketing effect, surface temperature measurement difficulty as well as dependence of convection phenomenon on surface geometry and physical conditions of the fluids. Experimental results obtained for a temperature range of 50-200°C are extrapolated upto 400°C, the actual upper operational fluid temperatures used in concentrated solar parabolic trough power plant. The test method proposed in this paper can be useful for the development of oil as heat transfer fluids, where already established or commercialized oil is compared with the oil under development, in the same test setup and under similar test conditions.
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威尔逊图法测定合成油对流换热系数的实验研究
本文介绍了在管壳式换热器中测定合成换热流体对流换热系数的实验。应用威尔逊图技术对结果进行了分析,在此基础上,实验得到了管内流动流体的对流换热系数。通过Wilson图得到了油的对流换热系数,并与经典热阻方程得到的对流换热系数进行了比较。提出了油的对流换热系数相对于管内平均流速与油体温度之间的经验关系式。结果表明,修正系数为2.3,油流速度指数为0.2。应用修正系数后得到的对流换热系数值与文献报道的油水换热系数值一致。不同温度下换热系数的变化主要受蒸汽覆盖效应、表面测温难度以及对流现象与流体表面几何和物理条件的依赖等因素的影响。在50-200°C温度范围内获得的实验结果外推至400°C,即集中式太阳能抛物面槽式发电厂使用的实际最高运行流体温度。本文提出的测试方法可用于开发作为传热流体的油,在相同的测试装置和类似的测试条件下,将已经建立或商业化的油与正在开发的油进行比较。
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