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Applied Mathematics and Mechanics >

2020 , Vol. 41 >Issue 5: 681 - 698

DOI: https://doi.org/10.1007/s10483-020-2607-8

Articles

Homotopy Coiflets wavelet solution of electrohydrodynamic flows in a circular cylindrical conduit

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  • 1. State Key Lab of Ocean Engineering, School of Naval Architecture, Ocean and Civil Engineering, Shanghai Jiao Tong University, Shanghai 200240, China;
    2. College of Ocean Science and Engineering, Shanghai Maritime University, Shanghai 201306, China

Received date: 2020-01-19

  Revised date: 2020-02-23

  Online published: 2020-04-20

Supported by

Project supported by the National Natural Science Foundation of China (No. 11872241)

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Abstract

In previous studies, the nonlinear problem of electrohydrodynamic (EHD) ion drag flows in a circular cylindrical conduit has been studied by several authors. However, those studies seldom involve the computation for large physical parameters such as the electrical Hartmann number and the magnitude parameter for the strength of the nonlinearity due to the existence of strong nonlinearity in these extreme cases. To overcome this faultiness, the newly-developed homotopy Coiflets wavelet method is extended to solve this EHD flow problem with strong nonlinearity. The validity and reliability of the proposed technique are verified. Particularly, the highly accurate homotopy-wavelet solution is obtained for extreme large parameters, which seems to be overlooked before. Discussion about the effects of related physical parameters on the axial velocity field is presented.

Key words: homotopy-wavelet method; Coiflets; electrohydrodynamic (EHD) flow; nonlinear boundary value problem (BVP)

Cite this article

Anyang WANG, Hang XU, Qiang YU . Homotopy Coiflets wavelet solution of electrohydrodynamic flows in a circular cylindrical conduit[J]. Applied Mathematics and Mechanics, 2020 , 41(5) : 681 -698 . DOI: 10.1007/s10483-020-2607-8

References

[1] CLOUPEAU, M. and PRUNET-FOCH, B. Electrostatic spraying of liquids in cone-jet mode. Journal of Electrostatics, 22(2), 135-159 (1989)
[2] BAI, Y., YANG, G., HU, Y., and QU, M. Physical and sensory properties of electrohydrodynamic (EHD) dried scallop muscle. Journal of Aquatic Food Product Technology, 21, 238-247 (2012)
[3] ESEHAGHBEYGI, A. and BASIRY, M. Electrohydrodynamic (EHD) drying of tomato slices (lycopersicon esculentum). Journal of Food Engineering, 104, 628-631 (2011)
[4] SUGIYAMA, H., OGURA, H., and OTSUBO, Y. Fluid devices by the use of electrohydrodynamic effects of water. Journal of Applied Fluid Mechanics, 4(1), 27-33 (2011)
[5] MCClUSKEY, F. M. J., ATTEN, P., and PEREZ, A. T. Heat transfer enhancement by electroconvection resulting from an injected space charge between parallel plates. International Journal of Heat and Mass Transfer, 34, 2237-2250 (1991)
[6] ARTANA, G., D'ADAMO, J., LÉGER, L., MOREAU, E., and TOUCHARD, G. Flow control with electrohydrodynamic actuators. AIAA Journal, 40(9), 1773 (2002)
[7] SEYED-YAGOOBI, J. Electrohydrodynamic pumping of dielectric liquids. Journal of Electrostatics, 63(6), 861-869 (2005)
[8] BEG, O. A., HAMEED, M., and BEG, T. A. Chebyshev spectral collocation simulation of nonlinear boundary value problems in electrohydrodynamics. International Journal for Computational Methods in Engineering Science and Mechanics, 14(2), 104-115 (2013)
[9] MCKEE, S., WATSON, R., CUMINATO, J. A., CALDWELL, J., and CHEN, M. S. Calculation of electrohydrodynamic flow in a circular cylindrical conduit. Zeitschrift für Angewandte Mathematik und Mechanik, 77, 457-465 (1997)
[10] PAULLET, J. E. On the solutions of electrohydrodynamic flow in a circular cylindrical conduit. Zeitschrift für Angewandte Mathematik und Mechanik, 79, 357-360 (1999)
[11] ANTONIO, M. Homotopy analysis method applied to electrohydrodynamic flow. Communications in Nonlinear Science and Numerical Simulation, 16(7), 2730-2736 (2001)
[12] MOHSEN, M., HASSAN, S. N., and SAEID, A. A spectral method for the electrohydrodynamic flow in a circular cylindrical conduit. Chinese Annals of Mathematics, Series B, 36(2), 307-322 (2015)
[13] GHASEMI, S. E., HATAMI, M., MEHDIZADEH-AHANGAR, G. R., and GANJI, D. D. Electrohydrodynamic flow analysis in a circular cylindrical conduit using least square method. Journal of Electrostatics, 72(1), 47-52 (2014)
[14] HASANKHANI, G. R., ABBASI, M., GANJI, D. D., RAHIMIPETROUDI, I., and BOZORGI, A. Application of Galerkin and collocation method to the electrohydrodynamic flow analysis in a circular cylindrical conduit. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 38(8), 2327-2332 (2016)
[15] ALOMARI, A., ERTURK, V., MOMANI, S., and ALSAEDI, A. An approximate solution method for the fractional version of a singular BVP occurring in the electrohydrodynamic flow in a circular cylindrical conduit. European Physical Journal Plus, 134(4), 1-11 (2019)
[16] PRADIP, R., HARSHITA, M., and KLAUS, K. A sixth-order numerical method for a strongly nonlinear singular boundary value problem governing electrohydrodynamic flow in a circular cylindrical conduit. Applied Mathematics and Computation, 350, 416-433 (2019)
[17] YANG, Z. C. and LIAO, S. J. A HAM-based wavelet approach for nonlinear ordinary differential equations. Communications in Nonlinear Science and Numerical Simulation, 48, 439-453 (2017)
[18] YANG, Z. C. and LIAO, S. J. A HAM-based wavelet approach for nonlinear partial differential equations: two dimensional Bratu problem as an application. Communications in Nonlinear Science and Numerical Simulation, 53, 249-262 (2017)
[19] LIAO, S. J. Homotopy Analysis Method in Nonlinear Differential Equations, Springer-Verlag, New York (2011)
[20] NIAZI, M. D. K. and XU, H. Modelling two-layer nanofluid flow in a microchannel with electro-osmotic effects by means of Buongioro's mode. Applied Mathematics and Mechanics (English Edition), 41(1), 83-104 (2020) https://doi.org/10.1007/s10483-020-2558-7
[21] WANG, J., CHEN, J. K., and LIAO, S. J. An explicit solution of the large deformation of a cantilever beam under point load at the free tip. Journal of Computational and Applied Mathematics, 212, 320-330 (2008)
[22] LI, Y. J., NOHARA, B. T., and LIAO, S. J. Series solutions of coupled Van der Pol equation by means of homotopy analysis method. Journal of Mathematical Physics, 51, 063517 (2010)
[23] FAROOQ, U. and XU, H. Free convection nanofluid flow in the stagnation-point region of a three-dimensional body. The Scientific World Journal, 2014, 158269 (2014)
[24] CHENG, J., ZHU, S. P., and LIAO, S. J. An explicit series approximation to the optimal exercise boundary of American put options. Communications in Nonlinear Science and Numerical Simulation, 15, 1148-1158 (2010)
[25] WANG, J. Z. Generalized Theory and Arithmetic of Orthogonal Wavelets and Applications to Researches of Mechanics Including Piezoelectric Smart Structures, Ph.D. dissertation, Lanzhou University (2001)
[26] ZHOU, Y. H., WANG, X. M., WANG, J. Z., and LIU, X. J. A wavelet numerical method for solving nonlinear fractional vibration, diffusion and wave equations. Computer Modeling in Engineering and Sciences, 77(2), 137-160 (2011)
[27] LIU, X. J. A Wavelet Method for Uniformly Solving Nonlinear Problems and Its Application to Quantitative Research on Flexible Structures with Large Deformation, Ph.D. dissertation, Lanzhou University (2014)
[28] YU, Q. and XU, H. Novel wavelet-homotopy Galerkin technique for analysis of lid-driven cavity flow and heat transfer with non-uniform boundary conditions. Applied Mathematics and Mechanics (English Edition), 39(12), 1691-1718 (2018) https://doi.org/10.1007/s10483-018-2397-9
[29] YU, Q., XU, H., LIAO, S. J., and YANG, Z. C. A novel homotopy-wavelet approach for solving stream function-vorticity formulation of Navier-Stokes equations. Communications in Nonlinear Science and Numerical Simulation, 67, 124-151 (2019)
[30] YU, Q., XU, H., and LIAO, S. J. Analysis of mixed convection flow in an inclined lid-driven enclosure with Buongiorno's nanofluid model. International Journal of Heat and Mass Transfer, 126, 221-236 (2018)
[31] YU, Q., XU, H., and LIAO, S. J. Coiflets solutions for Foppl-von Karman equations governing large deflection of a thin flat plate by a novel wavelet-homotopy approach. Numerical Algorithms, 79(4), 993-1020 (2018)
[32] YU, Q., XU, H., and LIAO, S. J. Nonlinear analysis for extreme large bending deflection of a rectangular plate on non-uniform elastic foundations. Applied Mathematical Modelling, 61, 316-340 (2018)
[33] YU, Q. A HAM-Based Wavelet Approach and Its Applications in Nonlinear Mechanics and Ocean Engineering, Ph.D. dissertation, Shanghai Jiao Tong University (2018)
[34] YANG, Z. C. The Wavelet Homotopy Analysis Method for Nonlinear Boundary Value Problems and Its Applications, M. Sc. dissertation, Shanghai Jiao Tong University (2017)
[35] PUJOL, M. J., PUJOL, F. A., AZNAR, F., PUJOL, M., and RIZO, R. Numerical resolution of Emden's equation using Adomian polynomials. International Journal of Numerical Methods for Heat and Fluid Flow, 23(6), 1012-1022 (2013)
[36] RIAZI, N. and MOHAMMADI, M. Composite Lane-Emden equation as a nonlinear Poisson equation. International Journal of Theoretical Physics, 51(4), 1276-1283 (2012)
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