(ProQuest: ... denotes non-US-ASCII text omitted.)

Recommended by Ahmet Z. Sahin

Mechanical Engineering Department, Islamic Azad University, Dashtestan Branch, Dashtestan 7561888711, Iran

Received 7 August 2012; Revised 6 November 2012; Accepted 7 November 2012

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

In some convection and conduction heat transfer application, the temperature of boundaries is not constant and is a function of a dimension (X, Y, Z) or time. Some of these functions can be modeled as a periodic function. The mentioned boundary condition is applied in several engineering problems such as the nuclear reactor cooling system design and Stirling-cycle machines heat exchanger. Also in many industrial boilers which the heating up process is done by several burners, the above boundary condition is useful for numerical or analytical simulation.

Barletta et al. [ 1, 2] studied forced convection flow, respectively, with sinusoidal wall heat flux distribution and sinusoidal temperature distribution on the longitudinal boundary in a plane channel. Mentioned studies revealed that temperature distribution in longitudinal direction can be expressed as aperiodic function of the longitudinal coordinate. Also in [ 3] the effect of viscous dissipation on temperature in a circular duct in the case of a sinusoidal axial variation of the wall heat flux is evaluated.

In [ 4, 5] the laminar forced convection with the axial periodic boundary condition is studied by taking into account the axial heat conduction. Barletta et al. [ 6] investigated the effect of conducting wall in a parallel-plane channel. Their study showed that the increase in wall heat conductivity causes the increase in temperature oscillation amplitude off low field.

In addition to the analytical studies, some numerical studies are done on convection heat transfer with periodic boundary condition [ 7- 11]. Periodic forced convection in the thermal entrance region of a porous medium is investigated in [ 12] by using finite element method. In mentioned that study, a two-temperature model employed in order to evaluate the solid and fluid phase temperatures.

In the present paper, the forced convection in a circular duct with the boundary condition given by a temperature distribution which varies axially with sinusoidal law is solved analytically. It should be mentioned the modeling is done by taking into account the heat conduction in the duct wall. The longitudinal heat conduction and the viscous dissipation in the fluid will be neglected. Reference will be made to the hydrodynamically and thermally developed region. The two-dimensional energy balance equations will be solved analytically both for the fluid and the solid region.

The fluid and solid temperature distribution will be obtained analytically by expressing the energy balance equation as a complex-valued hypergeometric confluent equation.

For the analytical solution, [ 2] is used as the main source.

2. Mathematic Model

In this section, the local energy balance equations, written separately for the solid region and for the fluid region, are solved analytically with the mentioned boundary condition.

Let us consider, an infinite circular duct with internal and external radii is, respectively, _{r 0} , _{r 1} . Since the channel has a symmetry with reference to the r =0 , it is possible to study only half of the solution domain ( 0 ...4;r ...4; _{r 1} ). A drawing of the section of the circular duct together with the boundary condition is shown in Figure 1.

Figure 1: The axial section of channel.

[figure omitted; refer to PDF]

With considering the fully developed convection of Newtonian fluid, constant thermophysical property, neglecting of axial heat conduction in both phase and viscose dissipation in the fluid phase, the local energy balance in fluid and solid phases is given by the following.

Fluid phase ( 0 <r < _{r 0} ) : [figure omitted; refer to PDF] Solid phase ( _{r 0} <r < _{r 1} ) : [figure omitted; refer to PDF] where U (r ) is the Poiseuille velocity distribution: [figure omitted; refer to PDF] The equations must be solved together with following boundary conditions: [figure omitted; refer to PDF] With introducing the following dimensionless parameters: [figure omitted; refer to PDF] Equations ( 1), ( 2), and ( 4), respectively, transform to [figure omitted; refer to PDF] where Pe =2 _{r 0} ( u - / _{α f} ) , B = β _{r 0} .

3. Analytical Solution

By assuming the axial position sufficiently far from the inlet section, the solution of ( 6) can be written as [figure omitted; refer to PDF] By replacing ( 8) into ( 6), the _{θ 0} ( η ) , _{θ 1} ( η ) , and _{θ 2} ( η ) can be obtained from the following equations sets: [figure omitted; refer to PDF] And the boundary condition of equations sets ( 9) is given by [figure omitted; refer to PDF] In ( 9) it can be observed _{θ 1} , _{θ 2} are coupled together, and _{θ 0} is independent of _{θ 1} , _{θ 2} . The solution of boundary valued problem ( 9) with considering boundary conditions ( 10) yields _{θ 0} =0 .

For uncoupling the _{θ 1} , _{θ 2} equations, a new function ψ is introduced as [figure omitted; refer to PDF] By employing ( 11), ( 9) can be collapsed into a boundary valued problem, such as ( 12) [figure omitted; refer to PDF] Also boundary conditions ( 10) transform to [figure omitted; refer to PDF] By introducing the new parameters ψ = Φ / η , ω = -iPeB /2 , and z =2 ω ^{η 2} and replacing into ( 12), equation ( 15) is formed as [figure omitted; refer to PDF] The solution of ( 15) which fulfills the condition d ψ /d η _{|" η =0} =0 is given by [ 13] [figure omitted; refer to PDF] where M is confluent hypergeometric function.

ψ function can be expressed as the following power series [ 14]: [figure omitted; refer to PDF] where Γ is the gamma function.

By employing the first- and second-type Bessel functions, respectively, I , K , the solution of ( 13) can be written as: [figure omitted; refer to PDF] Constant _{C 1} , _{C 3} , and _{C 4} are obtained by using the mentioned boundary conditions in ( 14).

The Nusselt number can be obtained by employing ( 19) [figure omitted; refer to PDF] where [straight phi] ( ξ ) is the dimensionless heat flux at solid-fluid interface: [figure omitted; refer to PDF] And _{θ b} ( ξ ) is the dimensionless bulk temperature: [figure omitted; refer to PDF] By using the above equations, the Nusselt number is obtained as [figure omitted; refer to PDF] where _{θ 1b} , _{θ 2b} are, respectively, the real and imaginary part of following integral: [figure omitted; refer to PDF] One-time integration from ( 12) yields, [figure omitted; refer to PDF] On account of ( 24) the Nusselt number can be expressed as [figure omitted; refer to PDF] The average Nusselt number in an axial period is given by [figure omitted; refer to PDF] Above integral has a singularity that is shown in ( 27): [figure omitted; refer to PDF] By employing the complex integral analysis and Residual theorem, the integral ( 26) is calculated as [figure omitted; refer to PDF] The simplified form of ( 28) is given by [figure omitted; refer to PDF] And finally Nu ¯ can be rewritten as [figure omitted; refer to PDF]

4. Result and discussion

In Figure 2three-dimensional plot of dimensionless temperature distribution versus ξ and η is shown, for σ =1.15 , γ =1.5 ,Pe =100 , and B =1 . Figure 2shows by moving from wall to the center of duct the oscillation amplitude of temperature decreases, but in the center of duct the oscillation amplitude is not zero and Figure 3confirms it. In this figure the dimensionless temperature versus ξ , for σ =1.15 , γ =1.5 ,Pe =100 , and B =0.1 that is displayed. In Figure 3it can be observed by closing to the center of duct not only the oscillation amplitude decreases, but also the sensing of wall temperature alteration is done with more longitudinal delay. In Figures 4and 5The dimensionless temperature distribution at the center of duct is reported for σ =1.15 , γ =1.5 ,and Pe =100 and various values of B , Pe, respectively. The Figure 4shows that increasing in B causes a decrease in temperature oscillation amplitude in flow field.

Figure 2: 3D plot of dimensionless temperature distribution versus ξ and η .

[figure omitted; refer to PDF]

Figure 3: Dimensionless temperature distribution at η =0 , 1 , σ versus ξ .

[figure omitted; refer to PDF]

Figure 4: Dimensionless temperature distribution at η =0 for B = 0.3, 0.6, and 0.8 versus ξ .

[figure omitted; refer to PDF]

Figure 5: Dimensionless temperature distribution at η =0 for Pe = 20, 50, 100, and 200 versus ξ .

[figure omitted; refer to PDF]

The reason of this phenomenon is related to the effect of conduction accompanied by convection heat transfer. Because of conduction heat transfer in Y direction, each point of fluid senses wall temperature alteration, immediately and without any longitudinal delay. That means by only taking into account conduction, when the wall temperature is Max at an axial position, for example X₀ , the temperature of all points in fluid with same axial position as X₀ , is Max, but with minus gradient in Y direction. About convection heat transfer, it should be mentioned that convection phenomenon transfers the upstream pointes property to downstream pointes in X direction; as a result of only taking into account convection, when the wall temperature is Max at an axial position, as X₀ , the points with X₀ axial position are affected by upstream point only that has lower temperature in comparison to Max temperature. By increasing in B , frequency of oscillation increases, and it causes more difference between Max temperature; and upstream point temperature, as a result, contrast between convection and conduction increases and amplitude decreases.

In Figure 5it can be observed that Pe number and B have a same effect on oscillation amplitude of dimensionless temperature. According to Figure 5an increase in Pe number causes an amplitude reduction. The reason of this behavior is also related to the difference between conducted and conduction phenomenon. Since Pe number is convection to conduction heat transfer rate ratio, increase in Pe number leads to increase in convection against conduction heat transfer as a result the temperature distribution in the fluid phase is more affected by upstream condition in comparison to wall boundary condition. In Figure 6the dimensionless temperature of solid and fluid phases interface against ξ for different values of σ is displayed.

Figure 6: Dimensionless temperature distribution at solid-fluid interface for σ =1.05 ,1.15 ,1.25 versus ξ .

[figure omitted; refer to PDF]

Figure 6shows since increasing in wall thickness is followed with a decrease in conduction heat transfer, the oscillation amplitude in flow field decreases.

The longitudinal dimensionless temperature distribution is observed in Figure 7for several values of γ . In the Figure 7it is seen that increase in heat conductivity of solid phase is followed with increase in oscillation amplitude, because of lower temperature gradient.

Figure 7: Dimensionless temperature distribution at solid-fluid interface for γ =0.5 ,1.5 ,3.0 versus ξ .

[figure omitted; refer to PDF]

In Table 1, the values of the mean Nusselt number, evaluated through ( 30), are reported versus B .Pe and Pe. The table shows that the mean Nusselt number is an increasing monotonic function of B . Since the temperature gradient in Y direction has a direct relation with B , as a result larger value of B leads to large value of Nusselt number.

Table 1: The values of the mean Nusselt number for σ =1.15 , γ =1.5 .

5. Conclusion

In the present paper, the heat transfer problem has been studied for the laminar forced convection of a fluid in a circular duct. The duct walls have finite width, and the temperature on the external boundaries varies longitudinally with sinusoidal law. The local energy balance equation has been solved analytically, with reference to the thermally developed region. Under this assumption, the temperature distribution is a periodic function of the axial direction, and the period is equal to the period of the wall temperature distribution and the following result is obtained.

(i) The oscillation amplitude of the temperature field decreases by increasing the dimensionless frequency B and Peclet number.

(ii) Increasing in The dimensionless frequency B is followed with increase an average Nusselt number.

Nomenclatures

B :

Dimensionless frequency

C1 ,C2 ,C3 ,C4 :

Constants coefficient

i :

Complex unit

k :

Thermal conductivity

n :

Positive integer

M :

Confluent hypergeometricfunction

Nu:

Local Nusselt number

Nu ¯ :

Mean Nusselt number

r :

Radial coordinate

_{r 0} :

Internal radios

_{r 1} :

External radios

T :

Temperature

u :

Fluid velocity

u ¯ :

Mean fluid velocity

x :

Axial coordinate.

Greek Symbols

α :

Thermal diffusivity

β :

Frequency

γ :

Dimensionless parameter, defined in ( 5)

ΔT :

Oscillation temperature of external wall

ξ :

Dimensionless axial coordinate

η :

Dimensionless radial coordinate

θ :

Dimensionless temperature

_{θ 0} , _{θ 1} , _{θ 2} :

Dimensionless function, defined in ( 8)

Φ :

Dimensionless function, defined in ( 15)

_{[straight phi] 1} , _{[straight phi] 2} :

Dimensionless function, defined in ( 21)

σ :

Dimension radios of duct

ψ :

Dimensionless complex function, defined in ( 11).

Subscripts

b :

Bulk quantity

f :

Fluid

s :

Solid.