Rheological properties of vicoelastic fluid based nanofluid

doi:10.3969/j.issn.0438-1157.2014.z1.032

CIESC Journal ›› 2014, Vol. 65 ›› Issue (S1): 199-205.DOI: 10.3969/j.issn.0438-1157.2014.z1.032

Previous Articles Next Articles

Rheological properties of vicoelastic fluid based nanofluid

YANG Juancheng, XU Hongpeng, LI Fengchen

School of Science and Engineering, Harbin Institute of Technology, Harbin 150001, Heilongjiang, China

Received:2014-02-10 Revised:2014-02-24 Online:2014-05-30 Published:2014-05-30
Supported by:
supported by the National Natural Science Foundation of China (51076036), the Foundation for Innovative Research Groups of the National Natural Science Foundation of China (51121004) and the Fundamental Research Funds for the Central Universities (HIT.BRET1.2010008).

黏弹性流体基纳米流体流变学特性

阳倦成, 徐鸿鹏, 李凤臣

哈尔滨工业大学能源科学与工程学院, 黑龙江哈尔滨 150001

通讯作者: 李凤臣
基金资助:
国家自然科学基金项目（51076036）；国家自然科学基金委创新研究群体（51121004）；哈尔滨工业大学基础研究杰出人才培育计划项目（HIT.BRET1.2010008）。

Abstract

Abstract: Viscoelastic fluid based nanofluid (VFBN) takes the advantages of turbulent drag reduction and convective heat transfer enhancement. Rheological properties of viscoelastic fluid are related with the mechanism of turbulent drag reduction. In order to get the rheology properties of VFBN, the VFBN with aqueous solution of cetyltrimethylammonium chloride/sodium salicylate as viscoelastic base fluid and copper nanoparticles as suspended nanoparticles was prepared. The mass fraction of viscoelastic fluids are 2.5×10^-3, 5×10^-3and 1×10^-2, and the corresponding volume fraction of copper (spherical) nanoparticles are 0.1%, 0.25%, 0.5% and 1.0%, respectively. Experimental results indicate that VFBN shows obvious shear-thinning characteristics, the suspended nanoparticles can increase the zero-shear viscosity and enhance the viscoelasticity of base fluid. Based on the Giesekus constitutive equation, fitted correlations for the measured shear viscosity of VFBN have been obtained by modifying some experimental parameters.

Key words: nanofluid, viscoelastic fluid, interfacial rheology, experimental correlations of shear viscosity, nanoparticles, viscosity

摘要： 黏弹性流体基纳米流体（viscoelastic fluid based nanofluid，VFBN）是一种具有湍流减阻和对流换热相对强化特性的新型换热工质，其湍流减阻机理与流变学特性关系密切。通过对以2.5×10^-3、5×10^-3、1×10^-2三种质量分数的十六烷基三甲基氯化铵/水杨酸钠水溶液为基液，粒子体积分数为0.1%、0.25%、0.5%、1.0%的铜纳米流体的剪切黏度、零剪切黏度以及松弛时间的测量，实验结果表明VFBN有明显的剪切稀变特性，同时纳米粒子的添加增大了基液的零剪切黏度，并导致基液黏弹性增强。以Giesekus本构模型为理论基础，利用实验参数得到了描述VFBN剪切黏度的实验关联式。

关键词: 纳米流体, 黏弹性流体, 界面流变学, 剪切黏度实验关联式, 纳米粒子, 黏度

CLC Number:

O373

YANG Juancheng, XU Hongpeng, LI Fengchen. Rheological properties of vicoelastic fluid based nanofluid[J]. CIESC Journal, 2014, 65(S1): 199-205.

阳倦成, 徐鸿鹏, 李凤臣. 黏弹性流体基纳米流体流变学特性[J]. 化工学报, 2014, 65(S1): 199-205.

References 21

[1]	Yang J C, Li F C, Zhou W W, He Y R, Jiang B C. Experimental investigation on the thermal conductivity and shear viscosity of viscoelastic-fluid-based nanofluids[J]. International Journal of Heat and Mass Transfer, 2012(55): 3160-3166
[2]	Li F C, Yang J C, Zhou W W, He Y R, Huang Y M, Jiang B C. Experimental study on the characteristics of thermal conductivity and shear viscosity of viscoelastic-fluid-based nanofluids containing multiwalled carbon nanotubes[J]. Thermochimica Acta, 2013, 556: 47-53
[3]	Yang J C, Li F C, He Y R, Huang Y M, Jiang B C. Experimental study on the characteristics of heat transfer and flow resistance in turbulent pipe flows of viscoelastic-fluid-based Cu nanofluid[J]. International Journal of Heat and Mass Transfer, 2013, 62: 303-313
[4]	Yang J C, Li F C, Xu H P, He Y R, Huang Y M, Jiang B C. Heat transfer performance of viscoelastic-fluid-based nanofluid pipe flow at entrance region[J]. Experimental Heat Transfer, 2013.DOI:10.1080/08916152.2013.821545
[5]	Ferry J D. Viscoelastic Properties of Polymers[M]. New York: Wiley, 1980
[6]	Li F C, Yu B, Wei J J, Kawaguchi Y. Turbulent Drag Reduction by Surfactant Additives[M]. Beijing: Higher Eeducation Press, 2011
[7]	Cates M E. Reptation of living polymers: dynamics of entangled polymers in the presence of reversible chain-scission reactions[J]. Macromolecules, 1987, 20(9): 2289-2296
[8]	White A. Flow characteristics of complex soap system[J]. Nature, 1967(214): 323-330
[9]	Qi Y Y, Zakin J L. Chemical and rheological characterization of drag-reducing cationic surfactant systems[J]. Industrial and Engineering Chemistry Research, 2002, 41: 6326-6336
[10]	Kawaguchi Y, Yu B, Feng Z. Rheological characteristics and turbulent friction drag and heat transfer reductions of a very dilute cationic surfactant solution[J]. Journal of Heat Transfer, 2006, 128: 977-983
[11]	Giesekus H. A simple constitutive equation for polymer fluids based on the concept of deformation-dependent tensorial mobility[J]. Journal of Non-Newtonian Fluid Mechanics, 1982, 11(1): 69-109
[12]	Nettesheim F, Liberatore M W, Hodgdon T K, Wagner N J, Kaler E W, Vethamuthu M. Influence of nanoparticle addition on the properties of wormlike micellar solutions[J]. Langmuir, 2008, 24(15): 7718-7726
[13]	Gebhard Schramm. A Practical Approach to Rheology and Rheometry (实用流变测量学: 修订版)[M]. Zhu Huaijiang(朱怀江), trans. Beijing: Petroleum Industry Press, 2009: 45
[14]	Yang Juancheng(阳倦成). Study on the turbulent flow and heat transfer characteristics of viscoelasitic fluid based nanofluid[D]. Harbin: Harbin Institute of Technology, 2013: 56-58
[15]	Xuan Y, Li Q. Heat transfer enhancement of nanofluids[J]. International Journal of Heat and Fluid Flow, 2000, 21(1): 58-64
[16]	Li Q, Xuan Y, Wang J. Investigation on convective heat transfer and flow features of nanofluids[J]. Journal of Heat Transfer, 2003, 125: 151-155
[17]	Wei J J, Kawaguchi Y, Yu B, et al. Rheological Characteristics and turbulent friction drag and heat transfer reductions of a very dilute cationic surfactant solution[J]. Journal of Fluids Engineering, 2006, 128: 977-983
[18]	Bjrck . Least squares methods[J]. Handbook of Numerical Analysis, 1990, 1: 465-652.3
[19]	Yu B, Kawaguchi Y. Direct numerical simulation of the viscoelastic drag-reducing flow: a faithful finite-difference method[J]. Journal of Non-Newtonian Fluid Mechanics, 2004, 116: 431-466
[20]	Yu B, Kawaguchi Y. DNS of fully developed turbulent heat transfer of a viscoelastic drag-reducing flow[J]. International Journal of Heat and Mass Transfer, 2005, 48: 4569-4578
[21]	Yu Bo(宇波),Wang Yi(王艺),Hou Lei(侯磊),Zhang Jinjun(张劲军). Direct numerical simulation on the drag-reducing flow by surfactant additives at various rheological properties[J]. Journal of Engineering Thermophysics(工程热物理学报), 2007, 28(3): 469-471

Rheological properties of vicoelastic fluid based nanofluid

黏弹性流体基纳米流体流变学特性

PDF (PC)

Knowledge

Cited

Abstract

Cite this article

share this article

References 21

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Jiajia ZHAO, Shixiang TIAN, Peng LI, Honggao XIE. Microscopic mechanism of SiO₂-H₂O nanofluids to enhance the wettability of coal dust [J]. CIESC Journal, 2023, 74(9): 3931-3945.
[2]	Shuang LIU, Linzhou ZHANG, Zhiming XU, Suoqi ZHAO. Study on molecular level composition correlation of viscosity of residual oil and its components [J]. CIESC Journal, 2023, 74(8): 3226-3241.
[3]	Rubin ZENG, Zhongjie SHEN, Qinfeng LIANG, Jianliang XU, Zhenghua DAI, Haifeng LIU. Study of the sintering mechanism of Fe₂O₃ nanoparticles based on molecular dynamics simulation [J]. CIESC Journal, 2023, 74(8): 3353-3365.
[4]	Yong LI, Jiaqi GAO, Chao DU, Yali ZHAO, Boqiong LI, Qianqian SHEN, Husheng JIA, Jinbo XUE. Construction of Ni@C@TiO₂ core-shell dual-heterojunctions for advanced photo-thermal catalytic hydrogen generation [J]. CIESC Journal, 2023, 74(6): 2458-2467.
[5]	Juhui CHEN, Qian ZHANG, Lingfeng SHU, Dan LI, Xin XU, Xiaogang LIU, Chenxi ZHAO, Xifeng CAO. Study on flow characteristics of nanoparticles in a rotating fluidized bed based on DEM method [J]. CIESC Journal, 2023, 74(6): 2374-2381.
[6]	Bowen LEI, Jianhua WU, Qihang WU. Research on high injection superheat cycle for R290 low pressure ratio heat pump [J]. CIESC Journal, 2023, 74(5): 1875-1883.
[7]	Bimao ZHOU, Shisen XU, Xiaoxiao WANG, Gang LIU, Xiaoyu LI, Yongqiang REN, Houzhang TAN. Effect of burner bias angle on distribution characteristics of gasifier slag layer [J]. CIESC Journal, 2023, 74(5): 1939-1949.
[8]	Yongquan ZHANG, Weiwei XUAN. Mechanism of alkali metal/(FeO+CaO+MgO) influence on the structure and viscosity of silicate ash slag [J]. CIESC Journal, 2023, 74(4): 1764-1771.
[9]	Zhiyuan JIN, Guorong SHAN, Pengju PAN. Preparation and heat and salt resistance of AM/AMPS/SSS terpolymer [J]. CIESC Journal, 2023, 74(2): 916-923.
[10]	Jiaqing ZHANG, Rongpei JIANG, Weikang SHI, Boxiang WU, Chao YANG, Zhaohui LIU. Study on viscosity-temperature characteristics and component characteristics of rocket kerosene [J]. CIESC Journal, 2023, 74(2): 653-665.
[11]	Xintong HUANG, Yuhao GENG, Hengyuan LIU, Zhuo CHEN, Jianhong XU. Research progress on new functional nanoparticles prepared by microfluidic technology [J]. CIESC Journal, 2023, 74(1): 355-364.
[12]	Guojuan QU, Tao JIANG, Tao LIU, Xiang MA. Modulating luminescent behaviors of Au nanoclusters via supramolecular strategies [J]. CIESC Journal, 2023, 74(1): 397-407.
[13]	Wei ZHANG, Haoyang LI, Chungang XU, Xiaosen LI. Research progress on the microscopic mechanism and analytical methods of gas hydrate formation [J]. CIESC Journal, 2022, 73(9): 3815-3827.
[14]	Xin ZHANG, Rui XU, Xinyu LU, Yong'an NIU. Synthesis and photocatalysis of SiO₂@BiOCl-Bi₂₄O₃₁Cl₁₀ core-shell microspheres [J]. CIESC Journal, 2022, 73(8): 3636-3646.
[15]	Chengyi AI, Jinshuo QIAO, Zhenhuan WANG, Wang SUN, Kening SUN. Investigation on PrBaFe₂O_6-_δ anode material with in-situ FeNi nanoparticle in direct carbon solid oxide fuel cell [J]. CIESC Journal, 2022, 73(8): 3708-3719.