An analysis has been carried out to study the flow and heat transfer in a liquid film over a permeable stretching sheet. Using similarity transformations,
the time-dependent boundary layer equations are reduced to a set of nonlinear ordinary differential equations. The resulting parameter problem and velocity as well as temperature fields are solved using the homotopy analysis method (HAM). Analytic series solutions are given, and numerical results for velocity and the temperature profiles are presented through graphs of different values for pertinent parameter. The effects of unsteadiness parameter and permeability parameter on the velocity and temperature profiles are explored for different values of blowing or suction parameter.
1. Introduction
The study of flow and heat transfer in a thin liquid film is often encountered in industrial and engineering applications. Such processes are wire and fibre coating, cooling of metallic plates, drawing of a polymer sheet, aerodynamic extrusion of plastic sheets, and thinning of copper wires. In polymer processing application, the flow over a permeable stretching sheet has received considerable attention from researchers because of its widespread applications. Therefore, the analysis of momentum and thermal transport within thin liquid film on a continuously stretching surface is important for gaining some fundamental understanding of such processes. Crane [1] studied the Newtonian fluid flow induced by the stretching of an elastic sheet. The boundary layer equation is considered, and the boundary conditions are prescribed at the sheet and on the fluid at infinity. Nonetheless, in real physical application involving coating processes, the consideration of the fluid adhering to the finite liquid film is important. The hydrodynamics of a flow in a thin liquid film driven by an unsteady stretching surface was first investigated by Wang [2]. Andersson et al. [3] explored the heat transfer characteristics of the hydrodynamical problem. Wang [4] investigated the same problem of Andersson et al. [3], presenting analytic solutions. Several researchers extended Wang’s [2] classical problem in non-Newtonian problems [5–8], thermocapillarity effects [9–12], and magnetic effects [13, 14].
Wang [4] was probably the first to analyze the flow and heat transfer in a thin liquid film on an unsteady stretching surface using homotopy analysis method (HAM). The HAM is a general analytic method to obtain series solutions for various types of nonlinear equations [15, 16]. Several studies have successfully applied HAM to various nonlinear problems in science and engineering such as in heat transfer [17], upper-convected Maxwell fluid [18], Kawahara equation [19], diffusion and reaction in porous catalyst [20], micropolar fluid flow [21, 22], and MHD flow [23, 24].
The purpose of the present study is to give a numerical analysis of the flow and heat transfer in a thin liquid film over a porous stretching sheet, and the effects of unsteadiness parameter on the film thickness are explored for different values of blowing or suction parameter. Here the momentum and energy equations are highly nonlinear; hence a similarity transformation is used to transform the nonlinear partial differential equations into nonlinear ordinary differential equations. The resulting parameter problem and velocity as well as temperature fields are solved using the homotopy analysis method (HAM). The analytical solutions reached using HAM are presented and implications discussed.
2. Mathematical Model
Consider that the Newtonian fluid flow in a thin liquid film of uniform thickness h(t) on a horizontal thin elastic sheet emerges from a narrow slot at the origin of a Cartesian coordinate system. The fluid motion and heat transfer are due to the stretching of a permeable elastic sheet parallel to the x-axis at y=0. Two equal and opposite forces are applied along the x-axis, keeping the origin fixed. Under these assumptions, the governing conservation equations of mass, momentum, and energy at unsteady state can be expressed as
(1)∂u∂x+∂v∂y=0,(2)∂u∂t+u∂u∂x+v∂u∂y=ν∂2u∂y2,(3)ρCp(∂T∂t+u∂T∂x+v∂T∂y)=κ∂2T∂y2,
where u is the velocity component of the fluid in the x direction is defined as U=bx/(1-αt), vs is the mass transfer velocity at the surface of the sheet with vs>0 for blowing (injection) and vs<0 for suction, and vs=0 corresponding to an impermeable sheet. Further, T is the temperature, ν is the kinematic viscosity, ρ is the density, Cp is the specific heat at constant pressure, and κ is the thermal diffusivity. It is assumed that the surface of the planar liquid film is smooth and free of surface waves, and the viscous shear stress as well as the heat flux vanishes at the adiabatic free surface. Thus the boundary conditions are
(4)u=U,v=vs,T=Tsaty=0,∂u∂y=∂T∂y=0,v=dhdtaty=h.
The elastic sheet’s temperature is assumed to vary both along the sheet and with time in accordance with
(5)Ts=To-Trefbx2ν(1-αt)-3/2,
where To is the temperature at the slit, Tref is the constant reference temperature for all t<1/α, and d is the positive constant of proportionality with dimension (length2-rtime-1).
Consider employing the similarity transformations which are given as
(6)ψ=βx[νb1-αt]1/2f(η),T=To-Tref[bx2ν(1-αt)-3/2]θ(η),η=1β[bν(1-αt)]1/2y,
where β is the dimensionless film thickness and ψ(x,y) is the stream function defined by
(7)u=∂ψ∂y=bx1-αtf′(η),v=-∂ψ∂x=-(νb1-αt)1/2βf(η),
where a prime denotes differentiation with respect to η. Apparently, (7) has already satisfied the continuity equation, (1). Consequently, (1)–(4) are transformed to the following nonlinear boundary-value problem:
(8)f′′′+γ(ff′′-12Sηf′′-(f′)2-Sf′)=0,(9)1Prθ′′+γ(fθ′-2f′θ-12Sηθ′-32Sθ)=0,
subject to
(10)f(0)=K,f′(0)=1,f(1)=12S,f′′(1)=0,(11)θ(0)=1,θ′(1)=0,
where S=α/b is a dimensionless measure of the unsteadiness, γ=β2 is an unknown constant which must be determined as a part of the boundary value problem, Pr=ν/κ is Prandtl number, and K=vs/β(νb)1/2 is permeability parameter. It is worth mentioning that the momentum boundary layer problem defined by the ODE (8) subject to the relevant boundary conditions (10) is decoupled from the thermal boundary layer problem, while the temperature field θ(η) is on the other hand coupled to the velocity field. The most important characteristics of flow and heat transfer are the shear stress τs and the heat flux qs on the stretching sheet that are defined as
(12)τs=μ(∂u∂y)y=0,qs=-κ(∂T∂y)y=0,
where μ is the fluid dynamic viscosity. The local skin-friction coefficient Cf and the local Nusselt number Nux can be defined as
(13)Cf=τsρu2/2,Nux=-xqsκTref.
Thus, the skin friction and the rate of heat transfer for fluid flow in a thin film can be expressed as
(14)12CfRex1/2=1βf′′(0),NuxRex-1/2=bx2βν(1-αt)1/2θ′(0),
where Rex=Ux/ν is the local Reynolds number.
3. Analytical Approach
In this section we apply HAM to solve systems (8)–(11). We assume that the solutions of f(η) and θ(η) can be expressed by a set of base functions {ηm∣m=0,1,2,…} with the following forms:
(15)f(η)=∑m=0+∞amηm,(16)θ(η)=∑m=0+∞cmηm,
where am and cm are constants. Under the rule of solution expression given by (8) and (9), subject to the boundary conditions (10) and (11), it is straightforward to choose
(17)f0(η)=(-S4+K2+12)η3+(3S4-3K2-32)η2+η+K,(18)θ0(η)=1
as the initial guesses of f(η) and θ(η). The auxiliary linear operators Lf=∂3/∂η3 and Lθ=∂2/∂η2 are chosen with the following properties:
(19)Lf[C1+C2η+C3η2]=0,Lθ[C4+C5η]=0,
where C1, C2, C3, C4, and C5 are constants of integration. From (8) and (9), the nonlinear operators are defined as
(20)Nf[F(η,q),Γ(q)]=F′′′+Γ[FF′′-12SηF′′-(F′)2-SF′],Nθ[F(η,q),Θ(η,q),Γ(q)]=1PrΘ′′+Γ[FΘ′-2F′Θ-12SηΘ′-32SΘ],
where F(η,q) and Θ(η,q) are both unknown functions of η and q while Γ is a function dependent on the embedding parameter q. Let ℏf and ℏθ denote the non-zero auxiliary parameters whereas Hf and Hθ denote nonzero auxiliary functions, respectively. The zero-order deformation equation can be constructed as
(21)(1-q)Lf[F(η,q)-f0(η)]=qℏfHfNf[F(η,q),Γ(q)],(1-q)Lθ[Θ(η,q)-θ0(η)]=qℏθHθNθ[F(η,q),Θ(η,q),Γ(q)],
subject to the boundary conditions
(22)F(0,q)=K,F′(0,q)=1,Θ(0,q)=1,F(1,q)=12S,F′′(1,q)=0,Θ′(1,q)=0.
From (17) and (18), it is straightforward to show that when q=0, the solutions of (21)-(22) are
(23)F(η,0)=f0(η),Θ(η,0)=θ0(η).
Since ℏf,ℏθ≠0 and Hf, Hθ≠0 when q=1, (21)-(22) are equivalent to (8)–(11), respectively, provided that
(24)F(η,1)=f(η),Θ(η,1)=θ(η),Γ(1)=γ.
Thus, as q increases from 0 to 1, F(η,q) and Θ(η,q) vary from the initial guesses f0(η) and θ0(η) to the solutions f(η) and θ(η) in (8)–(11). In addition, Γ also varies from the initial guess
(25)Γ(0)=γ0
to γ. Applying the Taylor series to (23) and (25), F(η,q), Θ(η,q), and Γ(q) can be expanded as series of q(26)F(η,q)=f0(η)+∑m=1+∞fm(η)qm,Θ(η,q)=Θ0(η)+∑m=1+∞θm(η)qm,Γ(q)=γ0+∑m=1+∞γmqm,
where
(27)fm(η)=1m![∂mF(η,q)∂qm]q=0,θm(η)=1m![∂mΘ(η,q)∂qm]q=0,γm=1m![∂mΓ(q)∂qm]q=0.
Thus, using (24), we have
(28)f(η)=f0(η)+∑m=1+∞fm(η),θ(η)=θ0(η)+∑m=1+∞θm(η),γ=γ0+∑m=1+∞γm.
By differentiating (21) m times with respect to q, then setting q=0, and finally dividing by m!, the mth-order deformation equations are obtained:
(29)Lf[fm(η)-χmfm-1(η)]=ℏfHf(η)R1,m(η),Lθ[θm(η)-χmθm-1(η)]=ℏθHθ(η)R2,m(η),
subject to the boundary conditions
(30)fm(0)=K,fm′(0)=0,θm(0)=0,fm(1)=0,fm′′(1)=0,θm′(1)=0,
for m≥1, where
(31)R1,m(η)=fm-1′′′+∑n=0m-1γm-1-n∑i=0n(fifn-i′′-fi′fn-i′)-12Sη∑n=0m-1γnfm-1-n′′-S∑n=0m-1γnfm-1-n′,R2,m(η)=1Prθm-1′′+∑n=0m-1γm-1-n∑i=0n(fiθn-i′-2fn-i′θi)-12Sη∑n=0m-1γnθm-1-n′-32S∑n=0m-1γnθm-1-n,χm={1m>1,0m=1.
Let fm* and θm* denote the particular solutions of (29) as
(32)fm*=∫0η∫0η∫0ηℏfHf(s)R1,m(s)dsdηdη+χmfm-1,θm*=∫0η∫0ηℏθHθ(s)R2,m(s)dsdη+χmθm-1.
The general solutions for (19) are
(33)fm(η)=fm*+C1+C2η+C3η2,θm(η)=θm*+C4+C5η.
Hence, the mth-order approximations of f(η), θ(η), and γ are given, respectively, by
(34)f(η)≈∑n=0mfn(η),θ(η)≈∑n=0mθn(η),γ≈∑n=0m-1γn.
4. Results and Discussion
We solve (29)-(30) with the aid of Maple, a symbolic computation software. The auxiliary functions ℏf and ℏθ in (29) were set to be equal to 1 in all calculations reported in this paper. The solution of (29)-(30) can be expressed as
(35)fm(η)=∑k=24m+3am,k(η)ηk,θm(η)=∑k=14mcm,k(η)ηk,
for m≥1, where am,k and cm,k are the coefficients, which can be obtained recursively for m=1,2,3,… using
(36)a0,1=1,a0,2=3S4-3K2-32,a0,3=-S4+K2+12,b0,0=1,
given by (16) and (17). When m=1, we have the analytic solutions as follows:
(37)f1(η)=∑k=27a1,k(η)ηk,θ1(η)=∑k=14c1,k(η)ηk,γ0=105(2-S+2K-2K/ℏf)R,
where
(38)a1,2=-38R(152KℏfS+76ℏfK2S-94ℏfKS2-112K+24ℏfa1,2=-38R-504K2+72ℏfK+76ℏfS+112KS-94ℏfS2a1,2=-38R+24ℏfK3-238KS2+812K2S+72ℏfK2a1,2=-38R+25S3ℏf-672K3),a1,3=-12R(-210K3-210K2-70K+96ℏfS+144ℏfKa1,3=-12R-70KS-132ℏfS2K+96K2ℏfS+48ℏfa1,3=-12R+144K2ℏf+48K3ℏf-132ℏfS2+36ℏfS3a1,3=-12R+105K2S+192SℏfK),a1,4=10532R(2ℏf-ℏfS+2ℏfK-2K)a1,4=×(4K2+8K-3S2+4S+4KS+4),a1,5=-2132R(2ℏf-ℏfS+2ℏfK-2K)a1,5=×(24K+12K2-4S-S2-4KS+12),a1,6=2132R(2ℏf-ℏfS+2ℏfK-2K)a1,5=×(4K2+8K+S2-4S+4-4KS),a1,7=-332R(2ℏf-ℏfS+2ℏfK-2K)a1,7=×(4K2+8K+S2-4S+4-4KS),c1,1=-1052Rℏθℏf(2ℏf-ℏfS+2ℏfK-2K)(4K-5S),c1,2=-1054Rℏθℏf(2ℏf-ℏfS+2ℏfK-2K)(4+3S),c1,3=1052Rℏθℏf(2ℏf-ℏfS+2ℏfK-2K)(2K-S+2),c1,4=-1058Rℏθℏf(2ℏf-ℏfS+2ℏfK-2K)(2K-S+2),
where R=162K2-225KS+114K+72S2-50S+22. Note that (37) will be simplified to the expression γ0 of Wang [4] when K=0.
We noted that the HAM analytic solutions contain two nonzero auxiliary parameters ℏf and ℏθ that can be used to adjust and control the convergence of the series solutions. Liao [15, 25] indicates that the analytic solutions given by HAM contain an auxiliary parameter ℏ which could be chosen by means of what he calls the ℏ-curve.
Figures 1(a) and 1(b) show the variation of γ with ℏf using 10th-order HAM approximation when S=0.8 for suction and S=1.4 for blowing, respectively. For suction case, it is shown that the convergence region can be obtained by choosing a value of ℏf in the ranges -1.8≤ℏf≤-0.1 for K=-0.3, -2.5≤ℏf≤0.3 for K=-0.5, -2.3≤ℏf≤-0.2 for K=-1, -2.3≤ℏf≤-0.5 for K=-1.5, and -2.3≤ℏf≤-0.5 for K=-2.
The ℏf curve of γ=β2 using 10th-order HAM approximation for the cases S=0.8 and Pr=1.
Suction
Blowing
For blowing case, the appropriate ranges of the auxiliary parameter ℏf to maintain the convergent rate and region of γ are -2≤ℏf≤-0.5 for K=0.1, -1.75≤ℏf≤0 for K=0.2, -1.4≤ℏf≤-0.1 for K=0.3, -1.2≤ℏf≤-0.1 for K=0.4, and -0.65≤ℏf≤-0.5 for K=0.5.
The ℏf curves of f′′(0) are graphed in Figures 2(a) and 2(b) for suction and blowing, respectively. For suction case, it is shown that the convergence region can be obtained by choosing a value of ℏf in the ranges -1.5≤ℏf≤-0.4 for K=-0.3, -1.8≤ℏf≤0 for K=-0.5, -1.9≤ℏf≤-0.1 for K=-1, -1.7≤ℏf≤-0.3 for K=-1.5, and -1.5≤ℏf≤-0.5 for K=-2.
The ℏf curve of f′′(0) using 10th-order HAM approximation for the cases S=0.8 and Pr=1.
Suction
Blowing
For blowing case, the appropriate ranges of the auxiliary parameter ℏf to maintain the convergent rate and region of f′′(0) are -1.5≤ℏf≤-0.25 for K=0.1, -1.4≤ℏf≤-0.4 for K=0.2, -1.2≤ℏf≤-0.5 for K=0.3, -1≤ℏf≤-0.5 for K=0.4, and -0.55≤ℏf≤-0.45 for K=0.5.
In order to retain the convergent rate and region of θ′(0), Figures 3(a) and 3(b) show the appropriate ranges of ℏθ for both suction and blowing. For suction case, the appropriate value of ℏθ is in the ranges -0.8≤ℏθ≤-0.6 for K=-0.3, -1.4≤ℏθ≤-0.4 for K=-0.5, -1.75≤ℏθ≤-0.75 for K=-0.8, and -1.5≤ℏθ≤-1.5 for K=-1.
The ℏθ curve of θ′(0) using 10th-order HAM approximation for the cases S=0.8, Pr=1, and ℏf=-0.8.
Suction
Blowing
For blowing case, the appropriate value of ℏθ is in the ranges -1≤ℏθ≤-0.4 for K=0.1, -0.75≤ℏθ≤-0.5 for K=0.2, -0.6≤ℏθ≤-0.4 for K=0.3, -0.5≤ℏθ≤-0.45 for K=0.4, and -0.55≤ℏθ≤-0.5 for K=0.5.
To demonstrate the accuracy of the present findings, results for dimensionless film thickness and the skin friction are compared with the available results obtained by Wang [4]. It is found that all the numerical results in Table 1 agree with the values of β and -f′′(0) in Wang [4]. As the unsteadiness parameter S increases, the skin friction -f′′(0) increases and thereby the film thickness reduces.
Variations of the dimensionless film thickness β=γ1/2 and the skin friction -f′′(0) with respect to the unsteadiness parameter when Pr=1 and K=0 using 10th-order HAM approximation.
Present work
Wang [4]
S
ℏf
β
-f′′(0)
β
-f′′(0)
0.8
−0.6
2.151994
2.680943
2.15199
2.68094
1.0
−0.8
1.543616
1.972384
1.54362
1.97238
1.2
−1.0
1.127780
1.442625
1.127780
1.442631
1.4
−1.0
0.821032
1.012784
0.821032
1.012784
1.6
−0.6
0.576173
0.642397
0.567173
0.642397
1.8
−1.0
0.356389
0.309137
0.356389
0.309137
The effects of permeability parameter K on the velocity distribution f′(η) are presented in Figures 4(a) and 4(b) for suction and blowing, respectively. It is found that, as permeability parameter K increases, the flow velocity of the thin film increases for suction case, while for blowing case, the flow velocity decreases.
The effect of permeability parameter K on the velocity distributions f′(η) using 10th-order HAM approximation when Pr=1.
Suction
Blowing
Figures 5(a) and 5(b) reveal that by increasing the values of unsteadiness parameter, the velocity of thin film flow increases for both cases of suction (K<0) and blowing (K>0).
The effect of unsteadiness parameter S on the velocity distributions f′(η) using 10th-order HAM approximation when Pr=1.
Suction (K=-0.2)
Blowing (K=0.3)
The temperature profiles for different values of suction and blowing are demonstrated in Figures 6(a) and 6(b). It is seen that the temperature of the fluid flow increases with the increase in suction whereas blowing (K>0) has quite the opposite effect on the temperature of the flow.
The effect of permeability parameter K on the temperature distributions θ(η) using 10th-order HAM approximation when Pr=1.
Suction
Blowing
The effects of the unsteadiness parameter on the temperature profile are shown graphically in Figures 7(a) and 7(b). It is observed that by increasing the value of unsteadiness parameter, the temperature profiles decrease for both cases of suction and blowing.
The effect of unsteadiness parameter S on the temperature distributions θ(η) using 10th-order HAM approximation when Pr=1.
Suction (K=-0.2)
Blowing (K=0.3)
5. Concluding Remarks
In this paper an analysis has been carried out to study the effects of porous stretching sheet for both cases of suction and blowing. Analytical and numerical solutions are obtained for momentum and heat transfer over a permeable stretching sheet. The effect of permeability parameter K is to increase the flow velocity f′(η) for suction case and to decrease the flow velocity for the blowing case. Besides, we found that the permeability parameter K has significant effects on the temperature distribution. When K increases, the temperature of the fluid flow θ(η) increases for suction case and decreases for blowing case. When the unsteadiness parameter increases, the velocity of thin film flow increases for both cases of suction (K<0) and blowing (K>0); thereby the film thickness reduces.
Acknowledgment
The authors would like to acknowledge the financial support received from the Grant UKM-ST-07-FRGS0028-2009.
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