Heat transfer enhancement in annulus cooling channel subjected to constant heat flux by using Nano-fluid

2015 International Mediterranean Gas and Oil Conference (MedGO) Pub Date : 2015-04-16 DOI:10.1109/MEDGO.2015.7330331

Akram W. Ahmed Ezzat, I. Hasan

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Abstract

The research investigates experimentally and theoretically the thermal behavior of Nano-fluid in annulus channel under forced convection at steady state condition. The Nano-fluid which flows in the test section is consisted from alumina Nano powder of 10nm mixed in distilled water as the cooling media. Heat flux density of (q"=20693W/m2, q"=27752W/m2) was subjected to the flowing fluid at different Nano particle volume fraction (0.13, 0.24,1, and 1.7%) during the experiments. Preparing the Nano-fluid is ensured by using ultrasonic probe (750W, 20 kHz) and magnetic stirrer for 6hours. The thermal conductivity of Nano-fluid was measured by Decagon KD2-sensor at the average operation temperature (37.87°C, and 44.23°C) at different Nano particle volume fraction. The thermal behavior of the Nano-fluid based on the heat transfer coefficient, thermal conductivity, pressure drop, safety boiling factor, and effectiveness of system with different Nano particle volume fractions, were recorded. The enhancement in the ratio of heat transfer coefficient and thermal conductivity were evaluated and showed an enhancement of about (1.2 - 4.7%) and (0.3 - 4.5%) respectively.

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纳米流体增强恒热流密度环空冷却通道的换热性能

实验和理论研究了稳态条件下强制对流条件下纳米流体在环空通道中的热行为。在试验段内流动的纳米流体是由10nm的氧化铝纳米粉混合蒸馏水作为冷却介质组成的。实验过程中，不同纳米颗粒体积分数(0.13、0.24、1、1.7%)下流动流体的热流密度为(q”=20693W/m2, q”=27752W/m2)。采用超声探头(750W, 20 kHz)和磁力搅拌6小时制备纳米流体。采用Decagon kd2传感器测量了不同纳米颗粒体积分数下，平均工作温度(37.87℃)和平均工作温度(44.23℃)下纳米流体的导热系数。记录了纳米流体在不同纳米颗粒体积分数下的传热系数、导热系数、压降、安全沸腾系数和体系有效性。对传热系数和导热系数比值的提高进行了评估，结果表明，传热系数和导热系数分别提高了约(1.2 ~ 4.7%)和(0.3 ~ 4.5%)。

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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2015 International Mediterranean Gas and Oil Conference (MedGO)

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