Nano Fluid Flow Analysis in the Presence of Slip Effects and Wall Properties by Means of Contraction and Expansion
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摘要
The present article is a study of mixed convective peristaltic flow of Cu-blood nanofluid confined in a non-uniform tube along with the velocity slip conditions and wall properties. Endoscopic or catheterized special effects are also taken into description. Upon utilization of the large wavelength and small reynolds number approximation, the non-dimensional governing differential equation took a more simplified form, which is then solved for the exact solutions.Afterwards, these outcomes are offered graphically and are debated in detail. Velocity profile for pure blood as well as Cu-blood and no-slip and slip effects are also discussed separately. Streamlines pattern is also discussed for different physical parameters.
The present article is a study of mixed convective peristaltic flow of Cu-blood nanofluid confined in a non-uniform tube along with the velocity slip conditions and wall properties. Endoscopic or catheterized special effects are also taken into description. Upon utilization of the large wavelength and small reynolds number approximation, the non-dimensional governing differential equation took a more simplified form, which is then solved for the exact solutions.Afterwards, these outcomes are offered graphically and are debated in detail. Velocity profile for pure blood as well as Cu-blood and no-slip and slip effects are also discussed separately. Streamlines pattern is also discussed for different physical parameters.
The present article is a study of mixed convective peristaltic flow of Cu-blood nanofluid confined in a non-uniform tube along with the velocity slip conditions and wall properties. Endoscopic or catheterized special effects are also taken into description. Upon utilization of the large wavelength and small reynolds number approximation, the non-dimensional governing differential equation took a more simplified form, which is then solved for the exact solutions.Afterwards, these outcomes are offered graphically and are debated in detail. Velocity profile for pure blood as well as Cu-blood and no-slip and slip effects are also discussed separately. Streamlines pattern is also discussed for different physical parameters.
引文
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[3]H Shapiro,M.Y.Jaffrin,and S.L.Weinberg,J.Fluid Mech.37(1969)799.
[4]S.I.Abdelsalam and K.Vafai,Eur.J.Mech.B/Fluids65(2017)398.
[5]H.V.Moradi,S.Zandi,and J.M.Floryan,Comput.Fluids 147(2017)72.
[6]R.Ellahi,M.M.Bhatti,and C.M.Khalique,J.Mol.Liq.241(2017)1059.
[7]N.Iftikhar and A.Rehman,Int.J.Heat Mass Transf.111(2017)667.
[8]J.K.Grabski,J.A,Ko lodziej,and M.Mierzwiczak,Eng.Anal.Bound.Elem.63(2016)125.
[9]Z.Poursharifi and K.Sadeghy,J.Non-Newton.Fluid Mech.243(2017)1.
[10]N.S.Akbar and S.Nadeem,Alexandria Eng.J.53(2014)449.
[11]S.Choi,Devel.Applic.Non-New.Flows 23(1995)66,99.
[12]M.Amani,P.Amani,and A.Kasaeian,Chem.Eng.Sci.167(2017)135.
[13]S.Dinarvand and I.Pop,Adv.Powder Technol.28(2017)900.
[14]H.Sadaf and S.Nadeem,Comput.Methods Programs Biomed.131(2016)169.
[15]T.Elnaqeeb,K.S.Mekheimer,and F.Alghamdi,Math.Biosci.282(2016)135.
[16]A.Ahmed and S.Nadeem,Res.Phys.7(2017)677.
[17]D Tripathi and O.A.B′eg,Int.J.Heat Mass Transf.70(2014)61.
[18]M.A.Zeid,Res.Phys.6(2016)481.
[19]S.Sreenadh,A.N.Srinivas,and C.K.Selvi,Alexandria Eng.J.55(2016)1085.
[20]M.G.Reddy and O.D.Makinde,J.Mol.Liq.223(2016)1242.
[21]S.E.Ghasemi,J.Mol.Liq.238(2017)115.
[22]G.Sucharitha,P.Lakshminarayana,and N.Sandeep,Int.J.Mech.Sci.52(2017)131.
[23]I.Shahzadi,H.Sadaf,S.Nadeem,and A.Saleem,Comput.Methods Programs Biomed.139(2017)137.
[24]C.L.M.H.Navierand,Men.Acad.R.Sci.Inst.Fr.6(1827)389.
[25]C.H.Choi,J.A.Westin,and K.S.Breuer,To slip or not to slip water flows in hydrophilic and hydrophobic microchannels,In:Proceedings of IMECE,New Orleans,LA,(2002)Paper No.2002-33707.
[26]M.T.Matthews and J.M.Hill,J.Math.Anal.Appl.333(2007)381.
[27]M.T.Matthews and J.M.Hill,Appl.Math.Lett.21(2008)810.
[28]S.Sreenadh,A.N.S.Srinivas,and C.K.Selvi,Alexandria Eng.J.55(2016)1085.
[29]H.M.Sayed,E.H.Aly,and K.Vajravelu,Alexandria Eng.J.55(2016)2209.
[30]T.Hayat,M.Shafique,A.Tanveer,and A.Alsaedi,Int.J.Heat Mass Transf.112(2017)559.
[31]M.Khan,T.Hayat,and M.Ayub,Comp.Math.Appl.53(2007)1088.
[32]C.Derek,D.C.Tretheway,and C.D.Meinhart,Phys.Fluids 16(2004)1509.
[33]M.Renksizbulut,H.Niazmand,and G.Tercan,Inter.J.Therm.Sci.45(2006)870.
[34]Z.Yongbin,J.Balkan Trib.Ass.22(2016)3292.
[35]Z.Yongbin,J.Balkan Trib.Ass.20(2014)522.
[36]T.Hayat,Z.Nisar,B.Ahmad,and H.Yasmin,J.Mag.Mag.Mat.394(2015)48.
[37]F.M.Abbasi,T.Hayat,B.Ahmad,and G.Q.Chen,PLo S one 9(2014)e105440.doi:10.1371/journal.pone.0105440.