Development of a Model and Experimental Study of Thermal Processes in a Ferrofluid Sealer

IF 0.3 Q4 ENERGY & FUELS Problemele Energeticii Regionale Pub Date : 2023-05-01 DOI:10.52254/1857-0070.2023.2-58-05
S. Nesterov, V.D. Baklanov
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引用次数: 1

Abstract

The aim of the work is to create an interconnected numerical model of the magnetic, hydrodynamic and temperature fields of a ferrofluid sealer and to analyze thermal processes occurring in highspeed seals. This goal is achieved by selecting the necessary equations, boundary conditions, assumptions and physical properties of the magnetic fluid when building the numerical model of the sealer’s working gap, verification of the developed model by the results of the physical experiment. The important results of the work are the obtained and analyzed data on the influence both of physical properties and the geometry of the working gap of the ferrofluid sealer on the heating of the ferrofluid. With a shaft radius of 140 mm and a linear velocity at the shaft surface of 25 m/s due to viscous heating the ferrofluid temperature exceeding the ambient temperature can reach values up to 80 degrees and higher, it has been shown. The use of the equation proposed by V.E. Fertman to determine the thermal conductivity of ferrofluid and the mixing rule to determine its heat capacity allows us to describe with sufficient accuracy for engineering calculations the thermophysical properties of concentrated ferrofluids, it was shown. The significance of the results consists in the possibility of using the developed numerical model in the study of interrelated physical processes in the working gap of the ferrofluid sealer of rotating shafts. The physical and concentration parameters of the synthetic oil-based magnetic fluid given in the paper and the results of its test operation as part of a ferrofluid seal can be used to verify the results of newly developed models of ferrofluid devices.
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铁磁流体密封机热过程模型的建立及实验研究
这项工作的目的是建立一个铁磁流体密封器的磁场、流体动力和温度场的相互关联的数值模型,并分析高速密封中发生的热过程。在建立密封机工作间隙数值模型时,选择必要的方程、边界条件、假设和磁流体的物理性质,并通过物理实验结果对所建立的模型进行验证,从而达到这一目的。获得并分析了铁磁流体密封器的物理性质和工作间隙的几何形状对铁磁流体加热的影响。结果表明,当轴半径为140 mm,轴表面因粘性加热而线速度为25 m/s时,铁磁流体温度可超过环境温度80度以上。利用V.E. Fertman提出的确定铁磁流体导热系数的方程和确定其热容的混合规则,可以在工程计算中充分准确地描述浓缩铁磁流体的热物理性质。这些结果的意义在于,可以利用所建立的数值模型来研究旋转轴铁磁流体密封器工作间隙内相互关联的物理过程。本文给出的合成油基磁流体的物理参数和浓度参数及其作为铁磁流体密封部分的试运行结果可用于验证新建立的铁磁流体装置模型的结果。
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来源期刊
CiteScore
0.70
自引率
33.30%
发文量
38
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