A dynamic mixed nonlinear subgrid‐scale model for large‐eddy simulation
Abstract
Purpose
Large eddy simulation (LES) is widely used in prediction of turbulent flow. The purpose of this paper is to propose a new dynamic mixed nonlinear subgrid‐scale (SGS) model (DMNM), in order to improve LES precision of complex turbulent flow, such as flow including separation or rotation.
Design/methodology/approach
The SGS stress in DMNM consists of scale‐similarity part and eddy‐viscosity part. The scale‐similarity part is used to describe the energy transfer of scales that are close to the cut‐off explicitly. The eddy‐viscosity part represents energy transfer of the other scales between smaller than grid‐filter size and larger than grid‐filter size. The model is demonstrated through two examples; one is channel flow and another is surface‐mounted cube flow. The computed results are compared with prior experimental data, and the behavior of DMNM is analyzed.
Findings
The proposed model has the following characteristics. First, DMNM exhibits significant flexibility in self‐calibration of the model coefficients. Second, it does not require alignment of the principal axes of the SGS stress tensor and the resolved strain rate tensor. Third, since both the rotating part and scale‐similarity part are considered in the new model, flow with rotation and separation is easily simulated. Compared with the prior experimental data, DMNM gives more accurate results in both examples.
Originality/value
The SGS model DMNM proposed in the paper could capture the detail vortex characteristics more accurately. It has the advantage in simulation of complex flow, including more separations.
Keywords
Citation
Zhengjun, Y. and Fujun, W. (2012), "A dynamic mixed nonlinear subgrid‐scale model for large‐eddy simulation", Engineering Computations, Vol. 29 No. 7, pp. 778-791. https://doi.org/10.1108/02644401211257263
Publisher
:Emerald Group Publishing Limited
Copyright © 2012, Emerald Group Publishing Limited