SIMULATION OF THREE-DIMENSIONAL UNSTEADY
MHD NANOFLUID FLOW OVER A
PERMEABLE ROTATING EXPANDING DISK
WITH CONVECTIVE BOUNDARY INFLUENCE
Tapas Datta1, Arindam Das2, Arijit Mandal3
1Department of Mathematics, Aghore Kamini Prakash Chandra Mahavidyalaya, Bengai, Hooghly, West Bengal - 712611
2Assistant Teacher of Mathematics, Bhubanmayee Jr. High School, Pandapara Kalibari, Jalpaiguri,735132, West Bengal, India
3Assistant Teacher, Buridaha Primary School, Buridaha, Dighalbar, Gazole, Malda, West Bengal -732138

Abstract

Here we are going to research heat and mass exchange capacity of unsteady Magneto hydrodynamic nanofluid stream streaming over a porous spinning and rotating disk. Different convective conditions are mulled over at the limit of the stream. The usage of similarity transformation has been considered to change over the suit of partial differential equations in the numerical model portraying the stream into a bunch of ordinary differential equations alongside the appropriate boundary conditions. The authors considered the revolution and extending of the disk and portrayed the outcomes acquired in two conditions like extending and no extending disk through proper graphs. After the exhausting examination of the stream it is discovered that the presence of expanding plate lifts the impacts of heat convection factor, nanoparticle volume fraction convection factor, Prandtl number and stretching disk factor on the heat and mass exchange qualities of the stream proficiently. As needs be, the heat and mass exchange pace of the stream at the stream surface are essentially expanded in presence of suction and no suction in the flow.

Citation details of the article



Journal: International Journal of Applied Mathematics
Journal ISSN (Print): ISSN 1311-1728
Journal ISSN (Electronic): ISSN 1314-8060
Volume: 36
Issue: 2
Year: 2023

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References

  1. [1] Choi SU, Eastman JA. Enhancing thermal conductivity of fluids with nanoparticles. Argonne National Lab., IL (United States); 1995 Oct 1.
  2. [2] Buongiorno J, Convective transport in nanofluids, ASME Journal of Heat Transfer, 2006; 128: 240–250 .
  3. [3] Hayat T, Muhammad T, Alsaedi A, Alhuthali MS. Magnetohydrodynamic three-dimensional flow of viscoelastic nanofluid in the presence of nonlinear thermal radiation. Journal of Magnetism and Magnetic Materials. 2015;385:222-9.
  4. [4] I. V. Shevchuk, Modelling of convective heat and mass transfer in rotating flows, Springer; 2016, DOI:10.1007/978-3-319-20961-6
  5. [5] Von Karman T. Uber laminare und turbulente reibung. Z Angew Math Mech. 1921;1:233–52.
  6. [6] Millsaps K, Pohlhausen K. Heat transfer by laminar flow from a rotating plate. Journal of the Aeronautical Sciences. 1952;19(2):120-6.
  7. [7] Stuart JT. On the effects of uniform suction on the steady flow due to a rotating disk. The Quarterly Journal of Mechanics and Applied Mathematics. 1954;7(4):446-57..
  8. [8] Riley N. The heat transfer from a rotating disk. The Quarterly Journal of Mechanics and Applied Mathematics. 1964 Aug 1;17(3):331-49.
  9. [9] Benton ER. On the flow due to a rotating disk. Journal of Fluid Mechanics. 1966 Apr;24(4):781-800.
  10. [10] Kuiken HK. The effect of normal blowing on the flow near a rotating disk of infinite extent. Journal of Fluid Mechanics. 1971 Jun;47(4):789-98.
  11. [11] Watson LT, Wang CY. Deceleration of a rotating disk in a viscous fluid. The Physics of Fluids. 1979 Dec;22(12):2267-9.
  12. [12] Fang T, Tao H. Unsteady viscous flow over a rotating stretchable disk with deceleration. Communications in Nonlinear Science and Numerical Simulation. 2012 Dec 1;17(12):5064-72.
  13. [13] Türkyılmazoglu M, Uygun N. Basic compressible flow over a rotating disk. Hacettepe Journal of Mathematics and Statistics. 2004;33:1-0.
  14. [14] Miklavčič M, Wang CY. The flow due to a rough rotating disk. Zeitschrift für angewandte Mathematik und Physik ZAMP. 2004 Mar 1;55(2):235-46.
  15. [15] Turkyilmazoglu M. The MHD boundary layer flow due to a rough rotating disk. Z Angew Math Mech. 2010;90:72–82.
  16. [16] Turkyilmazoglu M. MHD fluid flow and heat transfer due to a stretching rotating disk. International Journal of Thermal Sciences. 2012 Jan 1;51:195-201.
  17. [17] Bachok N, Ishak A, Pop I. Flow and heat transfer over a rotating porous disk in a nanofluid. Physica B: Condensed Matter. 2011 Apr 15;406(9):1767-72.
  18. [18] Turkyilmazoglu M. Nanofluid flow and heat transfer due to a rotating disk. Computers & Fluids. 2014 May 1;94:139-46.
  19. [19] Doh DH, Muthtamilselvan M. Thermophoretic particle deposition on magnetohydrodynamic flow of micropolar fluid due to a rotating disk. International Journal of Mechanical Sciences. 2017 Sep 1;130:350-9.
  20. [20] Tabassum M, Mustafa M. A numerical treatment for partial slip flow and heat transfer of non-Newtonian Reiner-Rivlin fluid due to rotating disk. International Journal of Heat and Mass Transfer. 2018 Aug 1;123:979-87.
  21. [21] Appelquist E, Schlatter P, Alfredsson PH, Lingwood RJ. Turbulence in the rotating-disk boundary layer investigated through direct numerical simulations. European Journal of Mechanics-B/Fluids. 2018 Jul 1;70:6-18.
  22. [22] Wen D, Ding Y. Formulation of nanofluids for natural convective heat transfer applications. International Journal of Heat and Fluid Flow. 2005 Dec 1;26(6):855-64.
  23. [23] Liao Z, Poh CK, Huang Z, Hardy PA, Clark WR, Gao D. A numerical and experimental study of mass transfer in the artificial kidney. J. Biomech. Eng.. 2003 Aug 1;125(4):472-80.
  24. [24] Kooijman HA, Taylor R. Modelling mass transfer in multicomponent distillation. The Chemical Engineering Journal and the Biochemical Engineering Journal. 1995 Apr 1;57(2):177-88.
  25. [25] Saif RS, Hayat T, Ellahi R, Muhammad T, Alsaedi A. Darcy–Forchheimer flow of nanofluid due to a curved stretching surface. International Journal of Numerical Methods for Heat & Fluid Flow. 2019 Jan 7.
  26. [26] Mehmood Z, Iqbal Z, Azhar E, Maraj EN. Nanofluidic transport over a curved surface with viscous dissipation and convective mass flux. Zeitschrift für Naturforschung A. 2017 Mar 1;72(3):223-9.
  27. [27] Hayat T, Aziz A, Muhammad T, Alsaedi A. Numerical study for nanofluid flow due to a nonlinear curved stretching surface with convective heat and mass conditions. Results in physics. 2017 Jan 1;7:3100-6.
  28. [28] Imtiaz M, Hayat T, Alsaedi A. MHD convective flow of Jeffrey fluid due to a curved stretching surface with homogeneous-heterogeneous reactions. Plos one. 2016 Sep 1;11(9):e0161641.
  29. [29] Acharya N, Das K, Kundu PK. Outlining the impact of second-order slip and multiple convective condition on nanofluid flow: a new statistical layout. Canadian Journal of Physics. 2018;96(1):104-11.
  30. [30] Chakraborty T, Das K, Kundu PK. Multiple convection‐driven Falkner‐Skan flow of Carreau nanofluid along a permeable wedge: An analytical approach. Heat Transfer—Asian Research. 2019 May;48(3):914-37.