Weighted integral methods for fluid force diagnostics in incompressible flows

TL;DR

This paper introduces a novel weighted-integral framework for fluid force diagnostics in incompressible flows, providing deeper physical insights, improved accuracy, and new force expressions applicable to experimental data.

Contribution

The work develops a second-order tensor weight function approach, establishing new connections between flow fields and forces, and generalizes derivative moment transformation methods for enhanced flow analysis.

Findings

Enhanced force expressions with improved numerical accuracy.

New connections between surface-stress distribution and flow field.

Force estimation method relying only on velocity and acceleration data.

Abstract

Whilst surface-stress integration remains the standard approach for fluid force evaluation, control-volume integral methods provide deeper physical insights through functional relationships between the flow field and the resultant force. In this work, by introducing a second-order tensor weight function into the Navier-Stokes equations, we develop a novel weighted-integral framework that offers greater flexibility and enhanced capability for fluid force diagnostics in incompressible flows. Firstly, in addition to the total force and moment, the weighted integral methods establish, for the first time, rigorous quantitative connections between the surface-stress distribution and the flow field, providing potential advantages for flexible body analyses. Secondly, the weighted integral methods offer alternative perspectives on force mechanisms, through vorticity dynamics or pressure view, when the weight function is set as divergence-free or curl-free, respectively. Thirdly, the derivative moment transformation (DMT)-based integral methods (Wu et al., J. Fluid Mech. vol. 576, 2007, 265-286) are generalised to weighted formulations, by which the interconnections among the three DMT methods are clarified. In the canonical problem of uniform flow past a circular cylinder, weighted integral methods demonstrate advantages in yielding new force expressions, improving numerical accuracy over original DMT methods, and enhancing surface-stress analysis. Finally, a force expression is derived that relies solely on velocity and acceleration at discrete points, without spatial derivatives, offering significant value for experimental force estimation. This weighted integral framework holds significant promise for flow diagnostics in fundamentals and applications.