Analytical Study of the Convection Heat Transfer From an Isothermal Wedge Surface to Fluids

Bachiri, Mohamed; Bouabdallah, A.

doi:10.1115/1.4006030

Cited by 3 publications

(5 citation statements)

References 11 publications

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“…= 1. Figure 3 shows comparison of the asymptotic model with n = 3, and 6 as suggested in the present paper, and by Lin and Lin [24], respectively, with the exact solutions of Evans [8,10], Cheng and Lin [27] correlation, and Bachiri and Bouabdallah [30] correla tion, Eq. (7), for isothermal wedges (ft = 0) and the wide fluids (10 4 < Pr < 104).…”

Section: Forced Laminar Flow Past a Uniform-flux Wedgementioning

confidence: 75%

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Heat Transfer From a Wedge to Fluids at Any Prandtl Number Using the Asymptotic Model

Awad

2014

Journal of Heat Transfer

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Heat transfer from a wedge to fluids at any Prandtl number can be predicted using the asymptotic model. In the asymptotic model, the dependent parameter N uJReJ12 has two asymptotes. The first asymptote is NuxIRex112/>,->o that corresponds to very small value of the independent parameter Pr. The second asymptote is NuJReJ'2 Pr^oo, that corresponds to very large value o f the inde pendent parameter Pr. The proposed model uses a concave down ward asymptotic correlation method to develop a robust compact model. The solution has two general cases. The first case is P -0.198838. The second case is the special case of separated wedge flow (fl = -0.198838) where the surface shear stress is zero, but the heat transfer rate is not zero. The reason for this division is Nux/Rex112 ~ Pr1'3 for Pr 1 in the first case while NuJReJ12 ~ Pr1'4 for Pr > 1 in the second case. In the first case, there are only two common examples o f the wedge flow in prac tice. The first common example is the flow over aflat plate at zero incidence with constant external velocity, known as Blasius flow and corresponds to f = 0. The second common example is the two-dimensional stagnation flow, known as Hiemenez flow and corresponds to f = l (wedge half-angle 90deg). Using the meth ods discussed by Churchill

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Section: Forced Laminar Flow Past a Uniform-flux Wedgementioning

confidence: 75%

“…Bachiri and Bouabdallah [30] attempted to establish a general analytical approximation of the convection heat transfer from an isothermal wedge surface to fluids for all Prandtl numbers. They Andersson [25] considered the heat transfer in Falkner-Skan similarity boundary layers.…”

Section: Literature Reviewmentioning

confidence: 99%

Heat Transfer From a Wedge to Fluids at Any Prandtl Number Using the Asymptotic Model

Awad

2014

Journal of Heat Transfer

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“…Equation (3.3) admits numerical solutions and analytical approaches with a high order of approximation. In our study given in [17], an accurate analytical approach is proposed using a dimensionless velocity profile formula ( )…”

Section: Case Of Convective Flow (Stmentioning

confidence: 99%

“…The principal result concerned the evolution of the skin friction coefficient in two regime flows from initial to steady solutions. They also [17] studied the steady state momentum and energy equations over an isothermal wedge surface and gave a new expression of the Nusselt number valid for all Prandtl numbers and for different wedge surface positions. So, as a complementary investigation given in [17], we investigate the unsteady dynamic boundary layer over a wedge surface to establish an analytical formulation of the velocity profile as a function of Strouhal numbers over all time values.…”

Section: Introductionmentioning

confidence: 99%

“…They also [17] studied the steady state momentum and energy equations over an isothermal wedge surface and gave a new expression of the Nusselt number valid for all Prandtl numbers and for different wedge surface positions. So, as a complementary investigation given in [17], we investigate the unsteady dynamic boundary layer over a wedge surface to establish an analytical formulation of the velocity profile as a function of Strouhal numbers over all time values. In addition, in this paper, an analytical expression of the velocity is proposed by superposition method, which must consider the boundary conditions, the solutions of Rayleigh, Blasius and Falkner-Skan, and the equilibrium of the unsteady momentum equation.…”

Section: Introductionmentioning

confidence: 99%

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Strouhal Number Effects on Dynamic Boundary Layer Evolution Over a Wedge Surface from Initial Flow to Steady Flow: Analytical Approach

Bachiri

Bouabdallah

2022

International Journal of Applied Mechanics and Engineering

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The present work studies the effects of the physical parameter characterizing the laminar flow regime, namely the Strouhal number, on the evolution of the unsteady dynamic boundary-layer developed along a wedge surface. Similarity method is used to transform unsteady momentum equation to dimensionless form. Using superposition method between diffusion and convective flows solutions, an ad hoc velocity profile formula is proposed. The obtained results confirm perfectly the numerical data given by Blasius, Falkner-Skan and Williams-Rhyne for all Strouhal numbers. A new accurate analytical function of the local skin friction is established for all time values and for different wedge surface directions. In order to give further clarification on the flows evolutions from diffusion flow to convective flow, in the whole space domain, new skin friction coefficient curves are plotted for all Strouhal numbers and for different wedge surface directions.

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Heat and mass transfer from an isothermal wedge in nanofluids with Soret effect

et al. 2014

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Analytical Study of the Convection Heat Transfer From an Isothermal Wedge Surface to Fluids

Cited by 3 publications

References 11 publications

Heat Transfer From a Wedge to Fluids at Any Prandtl Number Using the Asymptotic Model

Heat Transfer From a Wedge to Fluids at Any Prandtl Number Using the Asymptotic Model

Strouhal Number Effects on Dynamic Boundary Layer Evolution Over a Wedge Surface from Initial Flow to Steady Flow: Analytical Approach

Heat and mass transfer from an isothermal wedge in nanofluids with Soret effect

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