Abstract
The fractional step method is a technique that results in a computationally-efficient implementation of Navier–Stokes solvers. In the finite element-based models, it is often applied in conjunction with implicit time integration schemes. On the other hand, in the framework of finite difference and finite volume methods, the fractional step method had been successfully applied to obtain predictor-corrector semi-explicit methods. In the present work, we derive a scheme based on using the fractional step technique in conjunction with explicit multi-step time integration within the framework of Galerkin-type stabilized finite element methods. We show that under certain assumptions, a Runge–Kutta scheme equipped with the fractional step leads to an efficient semi-explicit method, where the pressure Poisson equation is solved only once per time step. Thus, the computational cost of the implicit step of the scheme is minimized. The numerical example solved validates the resulting scheme and provides the insights regarding its accuracy and computational efficiency.
Highlights
The solution of incompressible flow problems arising in real-life engineering applications calls for developing accurate, yet efficient schemes, as the associated computational time becomes a decisive factor for their use
We show that a certain assumption regarding the intermediate step pressures results in an efficient semi-explicit scheme that requires solving the pressure Poisson equation only once per time step
This paper has shown how an efficient semi-explicit strategy can be derived in the framework of the stabilized Galerkin finite element methods
Summary
Centre Internacional de Mètodes Numèrics en Enginyeria (CIMNE), Edifici C1 Campus Nord. Received: 19 December 2017; Accepted: 14 January 2018; Published: 16 January 2018
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