Stabilization of a smoothed finite element semi-implicit coupling scheme for viscoelastic fluid-structure interaction

We propose in this work a stabilization approach for semi-implicit coupling of viscoelastic fluid-structure interaction (VFSI) using the cell-based smoothed finite element method (CS-FEM). The viscoelastic fluid and nonlinear solid equations are spatially discretized by the CS-FEM and then are semi-implicitly coupled via a partitioned solution strategy. The current semi-implicit coupling framework depends on a second-order characteristic-based split (CBS(B)) scheme that solves the Navier-Stokes equations together with the Oldroyd-B constitutive model in the fractional-step manner. To enhance the stability of the semi-implicit coupling algorithm, the discrete elastic-viscous split stress-gradient (DEVSS-G) procedure is introduced into the explicit stage while the stabilized pressure gradient projection (SPGP) is earmarked for the implicit stage. Moreover, the iterated end-of-step velocity begins with the intermediate velocity during the subiterations. The DEVSSG/CBS(B)-SPGP technique is readily applied to the CBS-based partitioned semi-implicit coupling algorithm for VFSI. Visible improvements in stabilization and efficiency are revealed in a benchmark test.

Automated summary

This paper introduces a semi-implicit stabilization approach for VFSI using CS-FEM, coupling viscoelastic fluid and nonlinear solid equations through a partitioned solution strategy for improved stability and efficiency.