ISSN 1812-3368. Вестник МГТУ им. Н.Э. Баумана. Сер. Естественные науки. 2017. № 5

19

DOI: 10.18698/1812-3368-2017-5-19-34

MODIFICATION OF THE LS-STAG IMMERSED BOUNDARY METHOD

FOR SIMULATING TURBULENT FLOWS

I.K. Marchevsky

iliamarchevsky@bmstu.ru

V.V. Puzikova

vvp@dms-at.ru

Bauman Moscow State Technical University, Moscow, Russian Federation

Abstract

Keywords

We constructed the LS-STAG discretisation for 2D Reynolds-

averaged Navier — Stokes equations, filtered Navier — Stokes

equations (as used for large eddy simulation and detached eddy

simulation) and equations employed in the Smagorinsky,

Spalart — Allmaras,

 

,

k

 

k

and

 

k

Menter’s Shear

Stress Transport turbulence models. We added a fourth grid to

the LS-STAG mesh consisting of three staggered grids.

We computed the following parameters at the centres of the

additional mesh cells: turbulent shear stress and, depending on

the turbulence model used, turbulence kinetic energy, turbu-

lent viscosity, and turbulent kinetic energy dissipation rate. We

verified the developed numerical method by solving the prob-

lem of flow around a circular airfoil when the flow has a high

Reynolds number (



2

7

10 10

). The obtained results are in

good agreement with published experimental data and nume-

rical results of other researchers. Our modification of the

LS-STAG immersed boundary method made it possible to

model the so-called "drag crisis" phenomenon for a circular

airfoil when



5

6

Re =10 10

Immersed boundary method,

LS-STAG method, turbulence

models, Reynolds-averaged

Navier — Stokes equations,

large eddy simulation, deta-

ched eddy simulation, airfoil

Received 23.01.2017

© BMSTU, 2017

The research is supported by Russian Ministry of Education and Science (proj. 9.2422.2017/PP),

Russian Federation President grant for young Russian PhD scientists (proj. MK-7431.2016.8),

Russian Foundation for Basic Research (proj. 17-08-01468a)

Introduction.

In number of engineering applications, for example in flow simulation

around wind turbine rotors, heat exchanger pipes, overhead and underwater cables

and pipes, building structures, marine infrastructure elements, etc., it is necessary to

solve coupled hydroelastic problems. Such problems are enough difficult for the

numerical solution and require high-precision numerical methods usage. There is a

special class of numerical methods — the immersed boundary methods — in which

the mesh is not connected to the body boundary and is not modified during the entire

computation, despite the immersed body movement [1]. These methods involve the

rectangular meshes usage. Cells of irregular shape, called the ''cut-cells'', are formed at

the intersection of a rectangular mesh with the immersed boundary. One of the most

effective methods in this class is the LS-STAG method [2]. This method has not been

implemented in both commercial and free software packages.