Flow characteristics of silicon oil in nanochannels  被引量:2

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作  者:Yong Wang Fu-quan Song Kai Ji Ye-heng Sun Wei-yao Zhu Xiao-hong Wang 

机构地区:[1]School of Engineering Science,University of Science and Technology of China,Hefei 230026,China [2]School of Petrochemical and Energy Engineering,Zhejiang Ocean University,Zhoushan 316022,China [3]Exploration and development scientific research institute of Shengli oil field branch of Sinopec,Dongying 257015,China [4]Civil and Resource Engineering School,University of Science and Technology Beijing,Beijing 100083,China

出  处:《Journal of Hydrodynamics》2021年第6期1282-1290,共9页水动力学研究与进展B辑(英文版)

基  金:Projects supported by the National Major Project of China(Grant No.2017ZX05072005);the National Natural Science Foundation of China(Grant No.11472246).

摘  要:The nonlinear flow of liquids through nanoscale channels play an important role in the separation and purification properties of porous membranes,the manufacture of biofilm ionic channels and microfluidic chips,the production of micro electro-mechanical systems.Silicon oil flow experiments were conducted through anodic alumina films with pore sizes of 26,67,89,and 124 nm,in which flow mechanism and characteristics of the oil through the nanoscale channels were analyzed.Four nanoflow features are revealed:(1)The experimental flow rate is less than the theoretical flow rate through nanochannels,as solid-liquid interaction increasing flow resistance.(2)At small shear rate,the boundary layer is one,indicating existence of a threshold pressure of oil flow through nanochannels.(3)The boundary layer decreases with the increasing of shear rate,and it rapidly decreases as shear rate increases when the value of shear rate is small.(4)The drag coefficient decreases nonlinearly with increasing shear rate,decreasing more slowly when value of shear rate is big,and trending towards 1 in the case of large shear rate.It is shown that the non-linearity of flow is induced by great solid-liquid interaction in nano and microscale,and increasing the driving force can raise the efficiency at the nanometer scale.

关 键 词:Nano and microflow NANOFLUID threshold pressure the boundary layer tight reservoir 

分 类 号:O35[理学—流体力学]

 

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