Modification of the LS-STAG Immersed Boundary Method for Simulating Turbulent Flows

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

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In 2D case, the cut-cells can be classified into trapezoidal, triangular and

pentagonal cells. Examples of each type cut-cells are shown on Fig. 4.

To preserve the five-point structure of the stencil of the MAC method, which can

be considered as some kind of ''predecessor'' of the LS-STAG method, we need

to make distinction between the discretization of the normal and shear stresses [2]

(Fig. 4). It is conveniently to sample the eddy viscosity

,

t



the turbulent kinetic

energy

,

k

the dissipation rate of the kinetic energy,



and the specific dissipation rate

of kinetic energy



at the same points as the shear stresses. Thus, in case of the

LS-STAG method usage for RANS-based models the fourth mesh (

xy

-mesh) with cells

1

,

1

=( ,

) ( ,

)

xy

c c

c c

i

i

i j

j

j

x x

y y









is needed. The faces of these cells are

,

xy

i j



(Fig. 2) and their

areas are

,

.

xy

i j

M

If

i

and

j

take values from ranges

1,...,

N

and

1,..., ,

M

respectively,

the base mesh contains

=

E NM

cells,

x

-mesh contains

=( 1)

x

E N M



cells,

y

-mesh

contains

= ( 1)

y

E N M



cells and

xy

-mesh contains

=( 1)( 1)

xy

E N M

 

cells.

It is possible to assign a weight

,

i j



to each cell

,

i j



of the base mesh:

 

 

 



,

,

,

0,

if

is the solid cell;

= 1/ 3, if

is the triangular cell;

1/ 4, otherwise.

i j

i j

i j

Fig. 4.

Location of the variables discretization points in case of base types cells of the LS-STAG

mesh:

a —

Cartesian Fluid Cell;

b —

North Trapezoidal Cell;

c —

Northwest Pentagonal Cell;

d —

Northwest

Triangle Cell