Estimation of the local convective heat transfer coefficients of low frequency two-phase pulsating impingement jets using the IHCP

IF 2.5 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Ali Amiri-Gheisvandi, F. Kowsary, M. Layeghi
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引用次数: 5

Abstract

ABSTRACT In this paper, a numerical-experimental investigation was performed for estimation of the local convective heat transfer coefficients of a two-phase pulsating heated jet impinging a cold disk-shaped mass. By solving the energy equation, temperature history of thermocouples was obtained and then using the “temperatures measured” at locations of the sensors and the “temperatures calculated” from the numerical solution of heat equation and then minimizing the sum of squared errors by the conjugate gradient method (CGM), the convective heat transfer coefficients are estimated using the nonlinear inverse heat conduction procedure (IHCP). To compare the heat transfer characteristics of the pulsating, steady, bubbly, and liquid-only jets, the heat transfer coefficients were estimated with respect to the square pulse frequency produced by a solenoid valve in the range of and the gas volume fraction in the range of . In the case of single-phase jet, results show that flow pulsation increases Nusselt number up to at the stagnation point and for farther radial distances as compared to the steady jet. Also, for steady jet, increasing Reynolds number resulted in a increase in the stagnation point Nusselt number and a increase at farther radial distances.
用IHCP估计低频两相脉动冲击射流局部对流换热系数
本文采用数值-实验方法研究了两相脉动加热射流撞击冷圆盘状质量时的局部对流换热系数。通过求解能量方程,得到热电偶的温度历史,然后利用传感器位置的“测量温度”和热方程数值解的“计算温度”,然后利用共轭梯度法(CGM)最小化误差平方和,利用非线性反热传导程序(IHCP)估计对流换热系数。为了比较脉动射流、稳态射流、气泡射流和纯液体射流的传热特性,计算了电磁阀产生的平方脉冲频率范围内的传热系数和气体体积分数范围内的传热系数。结果表明,在单相射流中,与稳定射流相比,流动脉动使努塞尔数增加到滞止点处,并在更远的径向距离处增加。对于稳定射流,雷诺数的增加会导致滞止点努塞尔数的增加,并在更远的径向距离处增加。
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
Experimental Heat Transfer
Experimental Heat Transfer 工程技术-工程:机械
CiteScore
6.30
自引率
37.10%
发文量
61
审稿时长
>12 weeks
期刊介绍: Experimental Heat Transfer provides a forum for experimentally based high quality research articles and communications in the general area of heat-mass transfer and the related energy fields. In addition to the established multifaceted areas of heat transfer and the associated thermal energy conversion, transport, and storage, the journal also communicates contributions from new and emerging areas of research such as micro- and nanoscale science and technology, life sciences and biomedical engineering, manufacturing processes, materials science, and engineering. Heat transfer plays an important role in all of these areas, particularly in the form of innovative experiments and systems for direct measurements and analysis, as well as to verify or complement theoretical models. All submitted manuscripts are subject to initial appraisal by the Editor, and, if found suitable for further consideration, to peer review by independent, anonymous expert referees. All peer reviews are single blind and submission is online via ScholarOne Manuscripts. Original, normal size articles, as well as technical notes are considered. Review articles require previous communication and approval by the Editor before submission for further consideration.
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