Abstracts

INTRODUCTION

Over the last forty years much effort has been placed on understanding the dynamical processes through which turbulence is created and maintained in boundary layers. The implications are evident. Provided a clear picture of the turbulence structure is developed, the basis for the construction of statistical-structural turbulence models is immediately laid down.

Wall-layer models for the innermost portions of the boundary layer are of particular interest. The extreme thinness of the viscous sublayer naturally demands the use of exceptionally fine meshes in the numerical computation of flows. To overcome this difficulty, an elegant method resides on the specification of local analytical solutions that can then be used to represent the properties of the flow throughout the wall layer. This type of approach was originally described in Patankar and Spalding (1967)Patankar SV and Spalding DB. 1967. Heat and Mass Transfer in Boundary Layers. (Morgan-Grampian Press, London. and is normally referred to as the wall function method.

Most of the research on wall models is historically related to Reynolds averaged Navier-Stokes (RANS) methods; however, this approach has also appropriately served large eddy simulations (LES) of turbulent flows. Piomelli and Ballaras (2002) have reviewed the applicability of some available methodologies to LES, discussing their assets and drawbacks. In hybrid RANS/LES approaches – whether zonal or non-zonal approaches – wall functions have also been extensively used (see, e.g., Hsieh et al. (2010)Hsieh K-J, Lien F-S and Yee E. 2010. Towards a unified turbulence simulation approach for wall-bounded flows. Flow Turbulence Combustion 84: 193-218.) to specify the lower boundary conditions.

Attempts to incorporate the structure of organized motions into near-wall analytical models persist today, but were given particularly interesting contributions through the works of Bark (1975)Bark FH. 1975. On the wave structure of the wall region of a turbulent boundary layer. J Fluid Mech 70: 229-250., Hatziavramidis and Hanratty (1979)Hatziavramidis DT and Hanratty TJ. 1979. The representation of the viscous wall region by a regular eddy pattern. J Fluid Mech 95: 655-679., Chapman and Kuhn (1986)Chapman DR and Kuhn GD. 1986. The limiting behaviour of turbulence near a wall. J Fluid Mech 170: 265-292., Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. and Landahl (1990)Landahl MY. 1990. On sublayer streaks. J Fluid Mech 212: 593-614.. These authors followed modeling routes that were completely original at the time they were proposed, but to some extent the works did not receive the attention they probably deserved. Here, we concentrate on the analysis of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149..

The model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is set on premises that differ somewhat from all the mentioned above; it strives to develop an analytical solution for the time-dependent velocity profile from asymptotic arguments and similarity solutions of a non-homogeneous diffusion equation. The other models, briefly reviewed below, are treated computationally.

Bark (1975)Bark FH. 1975. On the wave structure of the wall region of a turbulent boundary layer. J Fluid Mech 70: 229-250. evaluates the fluctuating velocity field with simplified models for the mean velocity distribution and the intermittent Reynolds stress during bursting periods. The model considers how a turbulent boundary layer responds to excitation caused by bursting motions which occur randomly. The length and time scales are considered larger than those typically associated with the bursting phenomenon. The energy spectra of the fluctuating large-scale motions in the wall layer region are resolved by the model.

Hatziavramidis and Hanratty (1979)Hatziavramidis DT and Hanratty TJ. 1979. The representation of the viscous wall region by a regular eddy pattern. J Fluid Mech 95: 655-679. discuss the numerical solution of the unsteady Navier-Stokes equations in the viscous wall region with simplications resulting from the “slender body” assumption. Their model evaluates the cross-flow velocity field for a flow that is periodic in time and in the direction transverse to the direction of the mean flow. An eddy time-varying model that incorporates observed wavelengths and bursting frequency of the wall eddies is used to formulate the boundary conditions. The near wall flow is driven by the fluctuating pressures originating from the outer flow.

Three distinct models are presented in Chapman and Kuhn (1986)Chapman DR and Kuhn GD. 1986. The limiting behaviour of turbulence near a wall. J Fluid Mech 170: 265-292.. They embody more complex space- and time-dependent boundary conditions at the outer edge of the viscous boundary layer, so as to reflect, as much as possible, the flow structure observed in experiments. Eight physical modeling guidelines are used to characterize the organized quasi-periodic eddy motion near the wall. A comparison between computed turbulence quantities and experiments is presented. The limiting behavior of turbulence near the wall is discussed in terms of power-law expressions.

In Landahl (1990)Landahl MY. 1990. On sublayer streaks. J Fluid Mech 212: 593-614., local intermittent streaks are considered to act locally and for a very short time, setting up the initial conditions for the evolution of three-dimensional perturbations that are considered linear and inviscid. The prescribed model for the initial nonlinear perturbation results in an eddy that is observed to grow linearly in time. The associated Reynolds shear stress is expressed in terms of the lift-up of fluid elements.

The theory of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. was given a first glimpse in Walker and Abbott (1976)Walker JDA and Abbott DE. 1976. Implications of the structure of the viscous wall layer, in Turbulence in Internal Flows. Edited by. Murthy SNB (West Lafayette, 1976), p. 131.. In fact, some results had previously appeared in reports difficult to find. However, Figure 1 of Walker and Abbott (1976)Walker JDA and Abbott DE. 1976. Implications of the structure of the viscous wall layer, in Turbulence in Internal Flows. Edited by. Murthy SNB (West Lafayette, 1976), p. 131. is exactly Figure 2 of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. Therefore, it is clear that, at least for a zero-pressure gradient flow, a time-dependent solution for the instantaneous longitudinal velocity was available as early as 1976. The model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is formulated in terms of the dynamics of the time-dependent wall-layer flow. A simplified set of the Navier-Stokes (N.-S.) equations is obtained to describe the unsteady flow in the wall layer during a quiescent period. Following the general description commonly found in literature, the flow dynamics is considered to be dominated by two features: wall layer streaks and the bursting phenomenon. The streaks are elongated in the flow direction, typically have a length of the order of 1000v/u_τ and can be observed over a large characteristic time, the quiescent period (Kline et al. 1967Kline SJ, Reynolds WC, Schraub FA and Rundstadler PW. 1967. The structure of turbulent boundary layers. J Fluid Mech 30: 741-773.). To determine the mean velocity profile in the wall layer, a time-average of the leading order instantaneous velocity is performed over the average period between bursts, which is considered to be approximately equal to the duration of the quiescent period.

Figure 1
Mean (thick line) and instantaneous velocity profiles for .

Figure 2
Characteristic behavior of A₀.

The present work studies, in great detail, the feasible domain of the model proposed by Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. The definitions of the instantaneous and mean velocity profiles, as preconceived by Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149., depend on the determination of four unknowns, the average period between bursts (), the origin of time (), a constant of integration of the time dependent equation (A₀) and the local pressure gradient (p⁺). Once p⁺ is specified, a set of three non-linear equations must be solved to reveal , and A₀. These parameters must be real and satisfy . In Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. no comments are made regarding any possible limitation on the value of p⁺. Our attempts to find a feasible domain from the expressions shown in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. failed.

Here, all expressions introduced in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. are verified through the Mathematica^TM (Wolfram 2008Wolfram Research. 2008. Mathematica, Technical and Scientific Software, http://www.wolfram.com.
http://www.wolfram.com... ) software system. In fact, it was later discovered that two terms are missing in equation (63) of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. The resulting non-linear set of equations for parameters , and A₀ is thus correctly presented and the feasible domain is determined. To find the numerical solution, the system of non-linear algebraic equations was transformed onto a system of ordinary differential equations with initial conditions. The system was then solved by NDSolve to generate a solution in terms of interpolation functions.

As it turns out, the model developed by Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is mathematically feasible in the domain p⁺ ∈ [-0.025, 41.886]. To find this interval, the model was only required to provide real values for the parameters computed from the governing system of non-linear equations and to satisfy the condition ; no further stringency to physical validity was required. However, if the model is required to furnish only positive derivatives at the wall for the instantaneous velocity, the feasible domain is reduced to p⁺ ∈ [-0.025, 0.104996].

The present work derives in detail all similarity solutions for the homogeneous diffusion differential partial equation presented in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. In doing so, a new treatment is introduced whereby the pressure term is included as a non-homogeneous contribution. To permit fast computations, interpolation functions were generated from initial and boundary value problems, to represent some complex special functions, including Ξ. The special function Ξ (Walker et al. 1989Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.) and its derivatives are given exact expressions (see Mikhailov and Silva Freire 2012), based on original identities for the hypergeometric functions ₁F₁ and _pF_p.

The analysis of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is specially developed for attached flow. The dominance of the error and logarithmic functions over the solution must clearly prevent its use in regions of separated flows since solutions of the type y² and y^1/2 cannot occur as predicted by Goldstein (1930Goldstein S. 1930. Concerning some solutions of the boundary layer equations in Hydrodynamics. Proc Cambridge Phil Soc 26: 1-18., 1948)Goldstein S. 1948. On laminar boundary-layer flow near a position of separation. Q J Mech Appl Maths 1: 43-69. and Stratford (1959)Stratford BS. 1959. The prediction of separation of the turbulent boundary Layer. J Fluid Mech 5: 1-16.. This aspect of their analysis is further discussed here.

For the first time, an explicit parameterization is presented for , and A₀ in terms of p⁺. These expressions make abundantly clear that p⁺ and cannot be independently specified for computations of the instantaneous velocity profile. They show that once the near wall flow dynamics is accepted to be driven by dominating diffusion effects, is determined uniquely by p⁺.

MODEL FORMULATION

Some relevant features of the model proposed by Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. are briefly reviewed to set the necessary background for discussion. Only the main aspects of the theory are presented. The properties of turbulent flows are known to experiment a complex behavior in the near wall region, with very steep changes in mean-velocity profiles and higher-order statistics. Early studies (Prandtl (1925)Prandtl L. 1925. Über die ausgebildete Turbulenz. ZAMM 5: 136-139., von Karman (1930), Coles (1956)Coles D. 1956. The law of the wake in turbulent boundary layers. J Fluid Mech 1: 191-226.) of the attached turbulent boundary layer have successfully split the boundary layer into two typical regions, a viscous (inner) sublayer where turbulent and laminar stresses are of comparable magnitude and a defect (outer) layer where the turbulent stresses provoke a small perturbation to the inertia dominated external flow solution.

The identification of the pertinent length scale δ⁺ (= v/u_τ, v = kinematic viscosity, u_τ = friction velocity) for the wall region permitted authors to develop local analysis, that naturally lead to analytical solutions (Prandtl (1925)Prandtl L. 1925. Über die ausgebildete Turbulenz. ZAMM 5: 136-139., Millikan (1939)Millikan CB. 1939. A critical discussion of turbulent flow in channels and tubes. in Proc. 5th Int. Congress on Applied Mechanics (J Wiley, N.Y, 1939).) and the advance of proper dimensional arguments. For example, authors have identified the peak production of turbulent kinetic energy to occur at wall distances of the order of 12δ⁺ (Laufer (1954)Laufer J. 1954. The structure of turbulence in fully developed pipe flow. (NACA Report no. 1174, 1954)., Gad-el-Hak and Bandyopadhyay (1994)Gad-El-Hak M and Bandyopadhyay PR. 1994. Reynolds number effects in wall-bounded turbulent flows. Appl Mech Review 47: 307-365.).

Time-Mean Structure

The time-mean structure of the flow in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is based on the classical two-layered asymptotic analyses (Yajnik (1970)Yajnik KS. 1970. Asymptotic theory of turbulent shear flow. J Fluid Mech 42: 411-427., Bush and Fendell (1972)Bush WB and Fendell FE. 1972. Asymptotic analysis of turbulent channel flow and boundary-layer flow. J Fluid Mech 56: 657., Mellor (1972)Mellor GL. 1972. The large Reynolds number, asymptotic theory of turbulent boundary layers. Int J Eng Sci 10: 851-873.) of large Reynolds number turbulent boundary layer flow. Solutions are then developed in terms of two small parameters, R^–1 and u*, where R denotes the Reynolds number based on representative external flow scales and u* = u_τ / u_e, u_e = mainstream velocity.

Because the analysis is restricted to the inner layer, the local variables are scaled with u_τ and v (kinematic viscosity).

The leading-order governing equation of the mean wall flow is set to be (Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.; see also: Loureiro and Silva Freire (2011), Sychev and Sychev (1987)Sychev VV and Sychev VV. 1987. On turbulent boundary layer structure. P.M.M. U.S.S.R 51: 462-467., Cruz and Silva Freire (1998)),

The salient aspect of Eq. (2) is that it becomes undetermined at a point of flow separation, x_s, since u_τ = 0. Also note that, at this point, pressure changes greatly across the boundary layer, implying that p_e is not an appropriate reference parameter at the wall (Stratford (1959)Stratford BS. 1959. The prediction of separation of the turbulent boundary Layer. J Fluid Mech 5: 1-16., Loureiro and Silva Freire (2009, 2011), Loureiro et al. (2008)Loureiro JBR, Monteiro AS, Pinho FT and Silva Freire AP. 2008. Water tank studies of separating flow over rough hills”, Boundary-Layer Meteorol 129: 289-308.).

In the outer limit of the wall region, the mean velocity profile, U⁺, is required to follow a logarithmic behavior, implying that the dominant effect in Eq. (1) is the Reynolds stress effect.

In the outer region of the wall layer, U⁺ must satisfy

Time-Instantaneous Structure

To obtain the governing equations of the unsteady flow in the wall layer during a quiescent period, Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. introduced the following non-dimensional variables,

u⁺ = u / u_τ,v⁺= v / u_τ,w⁺= w / u_τ(4)

and

In accordance with experiments, Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. consider

L_x >> v / u_τ,(6)

and pick a time scale determined from the condition that the unsteady term is balanced by the viscous term in the N.-S. equations (see, Eq. (5)).

Substitution of Eqs. (4) through (6) into the N.-S. equations together with an appropriate expansion for the pressure distribution in the wall layer and collection of the terms of leading order, furnishes the approximate governing equations.

Hypothesis (6) implies that the x-momentum equation develops independently from the other equations of motion. The flow evolution in a cross-flow plane (y⁺, z⁺) is determined from conditions that are representative of the motions during a typical quiescent state. Solutions are then considered to be given in terms of the periodic flow development between a pair of streaks, so that the cross-flow velocity field (v⁺, w⁺) is represented by Fourier series; appropriate wall and outer conditions are specified to reproduce the wall-layer structure. The longitudinal velocity u⁺ is determined from conditions imposed by the outer flow and effects of the evolving flow in the cross-plane.

Solution for u⁺ is also written as a Fourier series with coefficients u_n; substitution of the Fourier expressions for u⁺, v⁺ and w⁺into the approximate equations of motion, yields

The leading-order velocity solution, u₀, is to be found from

Equation (8) is shown in Walker et al. 1989Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. (as Eq. 27) with an obvious typographical mistake. The term ∂u₀ / ∂t⁺ was mistyped as ∂u₀ / ∂y⁺. In fact, the time dependency on Walker et al.'s model is only accounted for by the term ∂u₀ / ∂t⁺.

The set of Eqs. (7) to (9) is a coupled system of non-linear equations that has to be solved numerically. The forcing function M depends on a pressure term that must be determined from the time-dependent motions in the outer layer and on further terms arising from the evolution of the other modes. Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. remark that numerical computations for large R_λ (Reynolds number based on the mean streak spacing, λ) show the coupling between Eqs. (7) and (8) to be weak, so that contributions to the solution of Eq. (8) from Eq. (9) may be neglected. Since this term is not considered in Walker et al.'s solution, it will not be further considered here.

Similarity Solutions

Clearly, signicant contributions to the mean-velocity profile during the quiescent time are due to u₀, which is now solely determined from Eq. (8). The implication is that Walker et al.'s theory of wall-turbulence can be expressed in terms of a one-dimensional diffusion equation with a source term.

The solution presented in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. considers first the homogeneous time-dependent heat transfer equation. Classical similarity methods for the homogeneous heat conduction equation consider one similarity variable and initial conditions. Equation (8) is non-homogeneous and is subject to boundary conditions. To extend the semi-similarity solution developed in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. to the non-homogeneous case, a new term is considered here, p⁺τF(η) that is

u₀ = p⁺ τF(η) + G(η) + g(η)h(τ),(10)

with

Substitution of Eq. (10) into Eq. (8) yields

F″(η) + 2ηF′(η) − 4F(η) + 4 = 0(13)

The terms that are independent of p⁺furnish

2ηG′(η) + G″(η) = 4τg(η)h′(τ) − h(τ)(2 ηg′(η) + g″(η))(14)

In classical similarity methods, separable solutions are easily obtained. The case of Eq. (14) is more complicated since two separation constants are required. Divide both sides of Eq. (14) by g(η) and use a separation constant, a, to get

2ηG′(η) + G″(η) − ag(η) = 0(15)

4τg(η)h′(τ) − h(τ) (2 ηg′(η) + g″(η)) − ag(η) = 0(16)

Next, divide Eq. (16) by h(τ)g(η) and use a separation constant 2α to obtain

2 ηg′(η) + g″(η) − 2αg(η) = 0(17)

4τh′(τ) − 2αh(τ) − a = 0(18)

An analysis of the role of α on the problem solution is presented in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. Only solutions of Eqs. (17) and (18) for α = 0 are presented. The separation constant a is set equal to a₀ and is related to the asymptotic behavior of the time-mean profile for large η.

The solution of Eqs. (13) with conditions F(0) = 0 and F(∞) → 1, is given by

The above solution is shown in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. with a different representation (Eq. 48); however, both forms have been verified and were found to be exactly the same.

Equation (17) is solved with conditions g(0) = 0 and g(∞) → 1, to give

g(η) = erf(η)(20)

To solve Eq. (18), we make a = a₀ and integrate directly to find

h(τ) = a₀lnτ + A₀(21)

where A₀ is the constant of integration.

The solution of Eq. (15) is obtained with conditions G(0) = 0 and G′(0) = 0, and is expressed in terms of a special function, Ξ(η), that behaves logarithmically for large values of the argument. This function has been extensively studied in Mikhailov and Silva Freire (2012) and for this reason is not further discussed here. We may then write,

The preceding solutions are substituted into Eq. (10) to give the instantaneous velocity profile,

This expression depends on four unknown parameters – a₀, A₀, and – which must be specified for prescribed pressure gradients, p⁺. Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. proposed to determine these parameters by computing the time-average of u₀ and forcing the asymptotic form of the resulting expression in the limit of high y⁺ to follow a logarithmic behavior.

Mean Velocity Profile

The time-mean averaged profile (U⁺) is evaluated by an integration of Eq. (23) over the average time between burts, . Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. show that this can be made analytically. The resulting expression is very long and for this reason is not repeated here. All expressions used here in the definition of U⁺ were checked against Eqs. (53) through (59) of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.; all results coincided.

The mean velocity profile is required to satisfy conditions

Condition (3) immediately gives

The first condition in Eq. (24) gives

The second condition is satisfied identically. The third condition gives

Equations (26), (27) and (28) can be solved to yield A₀, and . They specify a system of transcendental non-linear algebraic equations that needs to be solved numerically.

In Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. two terms were missing in their Eq. (63), they are

The solution of a system of algebraic non-linear equations is normally carried out in the software Mathematica^TM through FindRoot. Here, the system of Eqs. (26) to (28) was transformed onto a system of differential equations with initial conditions, and solved through NDSolve. The special features of NDSolve resulted in a very fast computational procedure and in a very convenient solution expressed in terms of interpolation functions. This particular aspect of the present work will be discussed in detail elsewhere.

For the computations, the parameter C_i in Eq. (26) was set constant and equal to 5. For flows under a variable longitudinal pressure gradient this certainly is not true. However, Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. performed their computations with this restrictive assumption (C_i = 5). So that the present results can be compared with those of the original reference, the same hypothesis was adopted here. In any case, provided C_i is parameterized in terms of p⁺, the system of Eqs. (26) to (28) can be easily solved to determine new values of A₀, and . See, e.g., the parameterizations presented in Mellor (1966)Mellor GL. 1966. The effects of pressure gradients on turbulent flow near a smooth wall. J Fluid Mech 24: 255-274. and Nickels (2004)Nickels TB. 2004. Inner scaling for wall-bounded flows subject to large pressure Gradients. J Fluid Mech 521: 217-239..

MATHEMATICAL AND PHYSICAL FEASIBLE DOMAINS

The validity of the model proposed by Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. depends on the resolution of the system of Eqs. (26), (27) and (28) and on the satisfaction of some mathematical and physical conditions. One evident condition, is that parameters A₀, and , be real numbers. Another condition is that .

Following is a brief explanation for the last condition. The cycle is considered to begin in the final stages of sweep. Parameter gives the initial distribution of u₀ at the beginning of the cycle, at t⁺ = 0. Since is the dominant time scale of the cycle, . According to Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149., typical common values of and are respectively ord(10^–3) and ord(10³).

The mean and instantaneous velocity profiles for p⁺ = 0 are shown in Fig. 1. The logarithmic behavior of all profiles for large y⁺ must be observed. Since all instantaneous profiles are required to tend to the same steady solution for large y⁺, their average is objectively that solution. For small values of y⁺ solutions are dominated by the error function, erf, for large y⁺ solutions are dominated by the special function, Ξ.

To find parameters A₀, and the software Mathematica^TM was used. Solutions were found with 25 precision digits. Given the above four constrains, the feasible domain of Walker et al.'s model was found to be p⁺ ∈ [-0.025, 41.886]. The behavior of A₀, and is shown in Figs. 2 and 3.

Figure 3
Characteristic behavior of and .

The behavior of A₀ was not disclosed in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.. This parameter appears in the integration of Eq. (18). Basically, A₀ controls the level of function erf. The process is non-linear and difficult to explain, but generally as p⁺ increases, the last term in Eq. (23) becomes large and negative. The other terms of the equation must then counterbalance this effeect to keep the global level of the external logarithmic solution in accordance with the classical law of the wall. The discussion is further aggravated by the realization that the relative magnitude of the terms in Eq. (23) vary with time during a cycle. Consider then the situation at the end of a cycle, . For p⁺ about three, the negative term achieves its maximum absolute value. Also at about this value A₀ achieves a maximum (Fig. 2). The contribution of the erf-term in Eq. (23) to counterbalance the pressure term reaches its maximum, with about 2/3 of the total contribution. The Ξ-term becomes prevalent for p⁺ > 20.

The characteristic behavior of and at the extremes of the interval [-0.025, 41.886] where , are devoid of physical meaning. Let alone the fact that these two time scales should be at least two orders of magnitude different, on the left extreme is too high (= 29.54 s); on the opposite end, is too low (= 0.029 s). To this clear stringency on the validity of the physical model, a second condition can be added; this is discussed below. The lowest value of is obtained for p⁺ = 2.9 (= 0.000058).

In the physical model formulation, the instantaneous and mean velocity profiles are always required to approach a logarithmic solution in the outer region. Velocity logarithmic profiles are typical of attached flows. Once separation occurs, a different velocity profile of the type y^1/2 sets in (Stratford (1959)Stratford BS. 1959. The prediction of separation of the turbulent boundary Layer. J Fluid Mech 5: 1-16., Loureiro and Silva Freire (2009, 2011), Loureiro et al. (2008)Loureiro JBR, Monteiro AS, Pinho FT and Silva Freire AP. 2008. Water tank studies of separating flow over rough hills”, Boundary-Layer Meteorol 129: 289-308.). Even over rough surfaces a y^1/2-profile is observed for the mean velocity profile at a separation point (Loureiro et al. 2009Loureiro JBR, Monteiro AS, Pinho FT and Silva Freire AP. 2009. The effect of roughness on separating flow over two-dimensional hills. Exp Fluids 46: 577-596.).

In Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149., instantaneous and averaged velocity profiles are presented for four combinations of p⁺ and in accordance with typically measured values. For constant pressure flow (p⁺ = 0.0, ) the canonical boundary layer structure is well reproduced. Under a favorable pressure gradient (p⁺ = − 0.098, ), the instantaneous profiles are accelerated as expected. For adverse pressure gradients (p⁺= 0.11, ; p⁺ = 0.5, ), decreases and, for the latter case, reverse instantaneous flow is observed over the latter portion of the cycle.

In our computations, the second set of conditions (p⁺ = − 0.098) could not be reproduced since some of the flow parameters were rendered imaginary numbers. All other flows were well reproduced, including the instantaneous reverse flow for condition p⁺ = 0.5 (Fig. 4). However, for p⁺= 0, Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149.found (, ), whereas we have found (, ).

Figure 4
Mean (thick line) and instantaneous velocity profiles for .

In the instantaneous motion equations, scale velocities were introduced in terms of the friction velocity, Eq. (4). As defined in Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149., u_τ is obtained from the time-mean structure, which is never allowed to admit a y^1/2behavior for the mean-velocity profile irrespective of the value of p⁺; as a corollary, u_τ is also never admitted to be negative or zero. However, in an unsteady flow computation, if at two distinct instants of time the instantaneous velocity derivatives at the wall change sign, there must be a third instant where it is identical to zero. At this instant, the wall scaling variables need to be expressed in terms of the local pressure gradient at the wall. In fact, close to a separation point the relevant velocity scale in the wall region is u_pv(= (v/p) (∂p_w/∂x)^1/3, p_w = wall pressure). The conclusion is that in a same cycle, positive and negative velocity derivatives at the wall must not be allowed to occur.

To determine the pressure gradient value where flow separation is first observed, consider the extreme situation, , that is, the end of the cycles. Figure (5) shows that du₀ / dy⁺= 0 at p⁺ = 0.104996. Therefore, if as a further requirement, the model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. is asked to furnish only positive derivatives at the wall for the instantaneous velocity, the feasible domain is reduced to p⁺ ∈ [-0.025, 0.104996]. The behavior of parameters A₀, and can then be better observed in Figs. 6 and 7.

Figure 5
First derivative of Eq. (23) at the wall and at as a function of p⁺.

Figure 6
Characteristic behavior of A₀ with the extra condition u′₀(y = 0) > 0.

Figure 7
Characteristic behavior of and with the extra condition u′₀(y = 0) > 0.

Figure (7) shows that if a fourth condition is considered, that is, , the feasible domain is reduced further to p⁺ ∈ [-0.005, 0.104996]. Of course, this is an arbitrary condition based on experimental information. However, it does illustrate how Fig. (7) can be used to determine a domain of validity to the model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. that is physically meaningful.

FINAL REMARKS

The present work has discussed for the first time the domain of validity of the unsteady wall-layer model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. for the velocity profile in turbulent flows.

The model is formulated in terms of some very general considerations on the observed coherent motions in the wall region. However, after many simplifications, the flow features are expected to be represented by a nonhomogeneous time-dependent, one-dimensional, diffusion equation. Effects due to the structure of the organized motions are then restricted to the specification of the duration of a cycle and to the prescription of the external pressure gradient. Despite a claim from the original authors, the model is not appropriate to describe transient reverse flows.

To develop the solutions, a special numerical procedure was implemented. The computation of the special function Ξ is particularly time consuming, therefore a special evaluation scheme was proposed (Mikhailov and Silva Freire 2012). Real time simulators for the velocity profile were implemented and can be obtained from either authors.

Provided a flow representation is required in the interval p⁺ ∈ [-0.010, 0.104496], the following parameterization can be used:

A₀ = A₀₃(p⁺)3 + A₀₂(p⁺)2 + A₀₁p⁺ + A₀₀(30)

with A₀₃ = 260.0, A₀₂ = -177.7, A₀₁= 51.3, A₀₀ = 6.0 and a maximum relative error of 0.5% (Figure 8);

Figure 8
Parameterization of A₀ in the interval p⁺ ∈ [-0.010, 0.104496], (Eq. 30). Error % stands for 100(A_0numerical− A_0approximate)/A_0numerical.

Figure 9
Parameterization of in the interval p⁺ ∈ [-0.010, 0.104496], (Eq. 30). Error % stands for (T_Bnumerical − T_Bapproximate)/T_Bnumerical.

Because the values of span three orders of magnitude, and in view of the low values that this parameter attains as p⁺ → 0.104496, it was difficult to find a simple fit that furnished good results for the whole interval. At the extreme right, the relative error given by Eq. (32) is about 30% (Figure 10). However, over much of the interval, p⁺ ∈ [-0.010, 0.075], the relative error is below 5%. In any case, equations (11) and (23) show that the impact of a large relative error in on the evaluation of u₀ is very small.

Figure 10
Parameterization of in the interval p⁺ ∈ [-0.010, 0.104496], (Eq. 30). Error % stands for 100(T_0numerical− T_0approximate)/T_0numerical.

The set of Eqs. (23) and (30) through (32) permits a straightforward implementation of the model of Walker et al. (1989)Walker JDA, Abbott DE, Scharnhorst RK and Weigandg G. 1989. Wall-layer model for the velocity profile in turbulent flow. AIAA J 27: 140-149. in a domain that has physical meaning.

ACKNOWLEDGMENTS

MDM is thankful to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and the Instituto Nacional de Metrologia, Qualidade e Tecnologia (INMETRO) for their financial support of this research through a CNPq Research Fellowship - Edital MCT/CNPq/Inmetro no 059/2010 - PROMETRO, process No 563061/2010-3. APSF is grateful to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the award of a Research Fellowship (Grant No 303982/2009-8). The work was financially supported by the Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ) through Grant E-26/102.937/2011.

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