Numerical Study of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (GDQM)

Eldesoky, Islam M.; Kamel, Mohamed Hassan; Hussien, Reda M; Abumandour, Ramzy M.

doi:10.7763/ijmmm.2013.v1.43

Cited by 8 publications

(7 citation statements)

References 23 publications

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“…Numerical results of the unsteady pulsatile blood flow through porous medium in the presence of magnetic field with periodic body acceleration and slip condition through a rigid straight circular tube (artery) have been studied. It is of interest to note est to note that the result of the present model includes results of different mathematical models such as:  The results of Eldesoky [32] have been recovered,  The results of Eldesoky, Kamel, Reda, and Abumandour [39] have been recovered by taking Knudsen number k n = 0.0 (no slip condition),  The results of Megahed et al [45], have been recovered by taking Knudsen number kn = 0.0 (no slip condition),  the results of Kamel and El-Tawil [43] have been recovered by taking Knudsen number kn = 0.0 (no slip condition), the permeability of porous medium k → ∞ without stochastic and nobody acceleration,  The results of El-Shahed [44] have been recovered by taking Knudsen number kn = 0.0 (no slip condition) and Hartmann number Ha = 0.0 (no magnetic field),  The results of Chaturani and Palanisamy [42] have been recovered by taking Knudsen number kn = 0.0 (no slip condition), the permeability of porous medium k → ∞ and Hartmann number Ha = 0.0 (no magnetic field). It is possible that a proper understanding of interactions of body acceleration with blood flow may lead to a therapeutic use of controlled body acceleration.…”

Section: Discussionmentioning

confidence: 72%

Numerical Study of Slip Effect of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (Comparative Study)

Eldesoky¹,

Kamel²,

Abumandour³

2014

WJET

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How to cite this paper: Eldesoky, I.M., Kamel, M.H. and Abumandour, R.M. (2014) Numerical Study of Slip Effect of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (Comparative Study). World Journal of Engineering and Technology, 2, 131-148. http://dx. AbstractThe unsteady pulsatile flow of blood through porous medium in an artery has been studied under the influence of periodic body acceleration and slip condition by considering blood as incompressible Newtonian electrically conducting fluid in the presence of magnetic field. In this paper, a new technique of differential quadrature method is introduced to find numerical solution of nonlinear partial differential equations such as the equation of motion of this problem "Navier-Stokes equation". The presence of the nonlinearity in the problem leads to severe difficulties in the solution approximation. In construction of the numerical scheme "a new algorithm" a generalized differential quadrature method (GDQM) is to use for derivatives with respect to space variables of differential equations and for the time derivative applying fourth order Runge-Kutta Method (RKM). The GDQM changed the nonlinear partial differential equations into a system of nonlinear ordinary differential equations (ODEs). The obtained system of ODEs is solved by 4 th order RKM. This combination of DQM and 4 th order RKM gives a very good numerical technique for solving time dependent problems. The algorithm is coded in Matlab 7.14.0.739 and the simulations are run on a Pentium 4 CPU 900 MHz with 1 GB memory capacity. The effects of slip condition, magnetic field, porous medium, and body acceleration have been discussed. The numerical results show that the proposed method is more accurate and convergent than other numerical methods in literature. The method is illustrated and compared with the exact and analytical solutions and it is found that the proposed method gives a better accuracy and is quite easy to implement.

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Section: Discussionmentioning

confidence: 72%

Numerical Study of Slip Effect of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (Comparative Study)

Eldesoky¹,

Kamel²,

Abumandour³

2014

WJET

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“…e proposed technique presented is based on the GDQM to solve the nonlinear problems. e GDQ method has been applied successfully in our team work for solutions of a variety of problems such as in fluid mechanics [27,28] and structural analysis [18,21]. In addition, several researchers are interested in other various problems such as Chen and Cheung [29], Fung [30,31], Shu et al [32], and Liu and Wang [33].…”

Section: Introductionmentioning

confidence: 99%

Joint Effect of the Nonlinearity of Elastic Foundations and the Variation of the Inertia Ratio on Buckling Behavior of Prismatic and Nonprismatic Columns Using a GDQ Method

Abumandour

Abdelmgeed

Elrefaey

2020

Mathematical Problems in Engineering

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In this paper, we present a simple, powerful, yet efficient and easily applicable technique based on the GDQ method for solving nonlinear problems. The proposed technique is implemented to some nonlinear engineering problems in structure analysis. The results reveal that the proposed technique is effective. Then, the proposed technique is used to explain the effects of the variation of cross section area on the nondimensional critical buckling loads for columns with and without elastic foundation for three sets of boundary conditions. Finally, the proposed technique is used to investigate the effect of the nonlinearity term of Winkler elastic foundation on the nondimensional critical buckling loads of nonuniform columns resting on elastic foundations. The effectiveness of the proposed technique is validated through comparing the present results with exact solutions and other numerical results available in references. The proposed method benefits the optimum design of columns against buckling in engineering applications. The most important conclusions from this paper can be summarized as follows. When the inertia ratio varies parabolically, the nondimensional critical buckling loads increase in comparison with varying linearly. Moreover, the nondimensional critical buckling loads increase in the presence of the elastic foundation.

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“…Ikbal et al [36] investigated *For correspondence mathematical model on non-Newtonian flow of blood through a stenosed artery in the presence of a transverse magnetic field by treating blood as a power-law fluid. The unsteady nature of blood flow has been further studied by Mustapha et al [37] and Eldesoky et al [38].…”

Section: Introductionmentioning

confidence: 99%

Computational model on pulsatile flow of blood through a tapered arterial stenosis with radially variable viscosity and magnetic field

Priyadharshini

Ponalagusamy

2017

Sādhanā

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An unsteady two-fluid model of blood flow through a tapered arterial stenosis with variable viscosity in the presence of variable magnetic field has been analysed in the present paper. In this article, blood in the core region is assumed to obey the law of Jeffrey fluid and plasma in the peripheral layer is assumed to be Newtonian. The values for velocity, wall shear stress, flow rate and flow resistance are numerically computed by employing finite-difference method in solving the governing equations. A comparison study between the velocity profiles obtained by the present study and the experimental data represented graphically shows that that the rheology of blood obeys the law of Jeffrey fluid rather than that of Newtonian fluid. The effects of parameters such as taper angle, radially variable viscosity, hematocrit, Jeffrey parameter, magnetic field and plasma layer thickness on physiologically important parameters such as wall shear stress distribution and flow resistance have been investigated. The results in the case of radially variable magnetic field and constant magnetic field are compared to observe the effect of magnetic field in driving the blood flow. It is observed that increase in hematocrit increases the wall shear stress. The values of wall shear stress and flow resistance are obtained at various time instances and compared. It is pertinent to note that the magnitudes of flow resistance are higher in the case of converging tapered than non-tapered and diverging tapered artery.

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Numerical Study of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (GDQM)

Cited by 8 publications

References 23 publications

Numerical Study of Slip Effect of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (Comparative Study)

Numerical Study of Slip Effect of Unsteady MHD Pulsatile Flow through Porous Medium in an Artery Using Generalized Differential Quadrature Method (Comparative Study)

Joint Effect of the Nonlinearity of Elastic Foundations and the Variation of the Inertia Ratio on Buckling Behavior of Prismatic and Nonprismatic Columns Using a GDQ Method

Computational model on pulsatile flow of blood through a tapered arterial stenosis with radially variable viscosity and magnetic field

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