Timescale Behavior of the Wall Shear Stress in Unsteady Laminar Pipe Flows.

Based on two-dimensional (2D) flow model simulations, the effects of the radial structure of the flow (e.g., the nonuniformity of the velocity profile) on the pipe wall shear stress, τ_w, are determined in terms of bulk parameters such as to allow improved 1D modeling of unsteady contribution of τ_w. An unsteady generalization, for both laminar and turbulent flows, of the quasi-stationary relationship between τ_w and the friction slope, J, decomposes the additional unsteady contribution into an instantaneous energy dissipation term and an inertial term (that is, based on the local average acceleration-deceleration effects). The relative importance of these two effects is investigated in a transient laminar flow and an analysis of the range of applicability of this kind of approach of representing unsteady friction is presented. Finally, the relation between the additional inertial term and Boussinesq momentum coefficient, is clarified. Although laminar pipe flows are a special case in engineering practice, solutions in this flow regime can provide some insight into the behavior of the transient wall shear stress, and serve as a preliminary step to the solutions of unsteady turbulent pipe flows. [ABSTRACT FROM AUTHOR]