Experimental Investigation of Convective Heat Transfer Coefficient of
  Fe3O4/Water Nanofluids in the Presence of the Magnetic Field
 Under the Turbulent Flow Regime Conditions

doi:10.16183/j.cnki.jsjtu.2019.02.002

Abstract

Abstract: The effect of magnetic field on the convective heat transfer of Fe3O4/Water nanofluids was experimentally studied. The Fe3O4/Water nanofluids flowed through a horizontal circular tube under the turbulent flow regime conditions. The pressure drop of Fe3O4/Water nanofluids was measured at volume fraction of 3%. The mechanism of the heat transfer of magnetic nanofluids under the magnetic field was discussed. The experimental results showed that the heat transfer coefficient increased with the increase of the Fe3O4/Water nanofluids concentration, and the maximum averaged enhancement was 4.3%. In the presence of the perpendicular uniform magnetic field, almost no obvious enhancement of the convective heat transfer coefficient of Fe3O4/Water nanofluids was observed in fields up to 23.809 and 39.682kA/m but it was observed in fields of intensity up to 63.492kA/m. The maximum averaged enhancement was 3%. Compared with the pressure drop of the distilled water, 50% enhancement was observed using Fe3O4/Water nanofluids at the volume fraction of 3%. Enhancement was also obtained under the applied magnetic field and the maximum averaged enhancement was 11.3%. The power ratio was less than 1, and thus the utilization of Fe3O4/Water nanofluids in heat transfer could not save energy.

Key words: nanofluids, heat transfer enhancement, magnetic field, pressure drop, energy ratio

CLC Number:

TK 114

SHA Lili,JU Yonglin,ZHANG Hua. Experimental Investigation of Convective Heat Transfer Coefficient of Fe3O4/Water Nanofluids in the Presence of the Magnetic Field Under the Turbulent Flow Regime Conditions[J]. Journal of Shanghai Jiaotong University, 2019, 53(2): 134-139.

References ［12］

［1］	CHOI S U S, EASTMAN J A. Enhancing thermal conductivity of fluids with nanoparticles developments and application of non-newtonian flows［J］. ASME Journal of Heat Transfer, 1995, 66(1): 99-105.
［2］	PRASHER R, SONG D, WANG J, et al. Measurements of nanofluid viscosity and its implications for thermal applications［J］. Applied Physics Letters, 2006, 89(13): 255.
［3］	ZHANG P, LEE K H, LEE C H. Fretting friction and wear characteristics of magnetorheological fluid under different magnetic field strengths［J］. Journal of Magnetism and Magnetic Materials, 2017, 421: 3-18.
［4］	GOHARKHAH M, SALARIAN A, ASHJAEE M, et al. Convective heat transfer characteristics of magnetite nanofluid under the influence of constant and alternating magnetic field ［J］. Power Technology, 2015, 274: 258-267.
［5］	GOHARKHAH M, ASHJAEE M, SHAHADADI M. Experimental investigation on convective heat transfer and hydrodynamic characteristics of magnetite nanofluid under the influence of an alternating magnetic field［J］. International Journal of Thermal Sciences, 2016, 99: 113-124.
［6］	YARAHMADI M, GOUDARZI H M, SHAFII M B. Experimental investigation into laminar forced convective heat transfer of ferrofluids under constant and oscillating magnetic field with different magnetic field arrangements and oscillation modes ［J］. Experimental Thermal and Fluid Science, 2015, 68: 601-611.
［7］	BRINKMAN H C. The viscosity of concentrated suspensions and solutions ［J］. Journal of Chemical Physics, 1952, 20(4): 571.
［8］	EINSTEIN A. Eine neue bestimmung der moleküldimensionen［J］. Annals of Physics, 1906, 324: 289-306.
［9］	GNIELINSKI V V, KARLSRUHE. Neue gleichungen für den wrme-und den stoffübergang in turbulent durchsrtmten Rohren and kanlen［J］. Forschung Im Ingenieurwesen A, 1975, 41(1): 8-16.
［10］	张鸣远. 流体力学［M］. 北京: 高等教育出版社, 2010.
	ZHANG Mingyuan. Fluid mechanics ［M］. Beijing: Higher Education Press, 2010.
［11］	FEYNMAN R P, LEIGHTON R B, SANDS M. The feynman lectures on phycics (2 volume set)［M］. United States: Addison-Wesley, 1964.
［12］	宣益民. 纳米流体能量传递理论与应用［J］. 中国科学: 科学技术, 2014, 44: 269-279.
	XUAN Yimin . An overview on naofluids and applications ［J］. Scientia Sinica (Technologica), 2014, 44: 269-279.

[1]	LU Wu, DING Ranran, ZHAO Wenbin, HUANG Dong, WANG Zheming. “Window Effect” and Protective Measures of Exogenous Pulsed Electromagnetic Field on Implantable Cardiac Pacemaker [J]. Journal of Shanghai Jiao Tong University, 2022, 56(11): 1518-1531.
[2]	LIU Xucheng, GU Bo, ZENG Weijie, DU Zhongxing, TIAN Zhen. Analysis of Frictional Pressure Drop Correlations of Refrigerant Two-Phase Flow in Mini-Channel [J]. Journal of Shanghai Jiao Tong University, 2021, 55(9): 1095-1107.
[3]	WANG Pei (王昢), LIU Hua (刘华), CHENG Xiang (程翔), ZHAO Wanliang (赵万良), LI Shaoliang (李绍良), CHENG Yuxiang (成宇翔). Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation [J]. Journal of Shanghai Jiao Tong University (Science), 2018, 23(6): 740-745.
[4]	LI Chong (李冲), LU Cunyue* (鹿存跃), MA Yixin (马艺馨). Magnetic Field Tuning Characteristics of Bimodal Ultrasonic Motor Stator [J]. Journal of shanghai Jiaotong University (Science), 2017, 22(2): 129-132.
[5]	YANG Yun,RAO Yu. A Numerical Study of Turbulent Flow and Heat Transfer of Dimples at Different Depths [J]. Journal of Shanghai Jiaotong University, 2017, 51(1): 18-.
[6]	LI Pengchenga,SUN Zhijiana，TANG Zhoua，YU Zitaoa,b，HU Yacaia. Laminar Heat Transfer Enhancement of Graphite Tube with Internal FanShaped Fins [J]. Journal of Shanghai Jiaotong University, 2016, 50(04): 557-562.
[7]	DENG Dong (邓冬), XIE Si-wei (谢斯卫), WANG Rong-shun*(汪荣顺). Two-Phase Flow Pressure Drop of Liquid Nitrogen Boiling in the Straight Section Downstream of U-Bend [J]. Journal of shanghai Jiaotong University (Science), 2014, 19(4): 495-501.
[8]	CHEN Peihua，HUANG Pingjie，ZHANG Wubo，TANG Huayi,ZHOU Zekui. Fault Detection by Remote-Field Eddy Current Technique in Ferromagnetic Conductive Plate [J]. Journal of Shanghai Jiaotong University, 2013, 47(12): 1948-1956.
[9]	ZHANG Wei, WANG Xi. Delaminated Buckling near the Surface of Piezoelectric-Piezomagnetic Laminated Shells [J]. Journal of Shanghai Jiaotong University, 2013, 47(02): 198-202.
[10]	ZHANG Yong-jie1 (张永杰), CHEN Guo-jun2 (陈国军), TANG Chen-long3 (唐成龙). Metallurgical Applications of Pulsed Electromagnetic Field [J]. Journal of shanghai Jiaotong University (Science), 2012, 17(3): 282-285.
[11]	HUANG Xiao-Hong-1, ZHOU Qi-Bin-1, DU Ya-Ping-2. An Equivalent Circuit Method for Computing Lightning-Induced Magnetic Fields in Structures with Metallic Plates [J]. Journal of Shanghai Jiaotong University, 2012, 46(07): 1112-1116.
[12]	JIA Zhi-Wei, YAN Guo-Zheng, SHI Yu, ZHU Bing-Quan. Optimization Design of Transmitting Coils in the Wireless Power Transmission Based on Human Tissue Safety [J]. Journal of Shanghai Jiaotong University, 2012, 46(07): 1127-1131.
[13]	HU Hai-Tao-1, HUANG Xiang-Chao-1, DING Guo-Liang-1, DENG Bin-2, ZHENG Yong-Xin-3, GAO Yi-Feng-3, SONG Ji-3. The Influence of Oil on Pressure Drop of R410A Flow Condensation in Small Diameter Microfin Tube [J]. Journal of Shanghai Jiaotong University, 2012, 46(04): 515-519.
[14]	LIAN Li-Ting, XIAO Chang-Han, YANG Ming-Ming, ZHOU Guo-Hua. The Model of Ship’s Magnetic Field Extrapolation Based on Neural Network Improved by Particle Swarm Optimization [J]. Journal of Shanghai Jiaotong University, 2011, 45(06): 809-813.
[15]	LIU Zhen-Hua, YANG Xue-Fei. Boiling Heat Transfer Characteristics of Nanofluids in a Thermosyphon Loop [J]. Journal of Shanghai Jiaotong University, 2011, 45(06): 890-894.

Experimental Investigation of Convective Heat Transfer Coefficient of Fe3O4/Water Nanofluids in the Presence of the Magnetic Field Under the Turbulent Flow Regime Conditions

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References ［12］

Related Articles 15

Recommended Articles

Metrics

Comments