A grid-free Lagrangian approach is applied to simulate the high Reynolds number unsteady flow inside a three-dimensional domain with moving boundaries. For this purpose, the Navier-Stokes equations are expressed in terms of the vorticity transport formulation. The convection and stretch of vorticity are obtained using the Lagrangian vortex method, while diffusion is approximated by the random walk method. The boundary-element method is used to solve a potential flow problem formulated to impose the normal flux condition on the boundary of the domain. The no-slip condition is satisfied by a vortex tile generation mechanism at the solid boundary, which takes into account the time-varying boundary surfaces due to, e.g., a moving piston. The approach is entirely grid-free within the fluid domain, requiring only meshing of the surface boundary, and virtually free of numerical diffusion. The method is applied to study the evolution of the complex vortical structure forming inside the time-varying semi-confined geometry of a cylinder equipped with an eccentric inlet port and a harmonically driven piston. Results show that vortical structures resembling those observed experimentally in similar configurations dominate this unsteady flow. The roll-up of the incoming jet is responsible for the formation of eddies whose axes are nearly parallel to the cylinder axis. These eddies retain their coherence for most of the stroke length. Instabilities resembling conventional vortex ring azimuthal modes are found to be responsible for the breakup of these toroidal eddies near the end of the piston motion. The nondiffusive nature of the numerical approach allows the prediction of these essentially inviscid phenomena without resorting to a turbulence model or the need for extremely fine, adaptive volumetric meshes.

Issue Section:
Research Papers
Topics:
Cylinders, Flow (Dynamics), Pistons, Simulation, Eddies (Fluid dynamics), Vortices, Diffusion (Physics), Unsteady flow, Vorticity, Boundary element methods, Convection, Fluids, Geometry, Navier-Stokes equations, Reynolds number, Tiles, Turbulence
1.
Beale
J. T.
, and
Majda
A.
,
1985
, “
High Order Vortex Methods with Explicit Velocity Kernels
,”
Journal of Computational Physics
, Vol.
58
, pp.
188
208
.
2.
Chorin
A. J.
,
1980
, “
Vortex Models and Boundary Layer Instability
,”
SIAM Journal on Scientific and Statistical Computing
, Vol.
1
, No.
1
, pp.
1
21
.
3.
Cloutman, L.D., Dukowicz, J.K., and Ramshaw, J.D., 1981, “Numerical Simulation of Reactive Flow In Internal Combustion Engines,” Proceedings of the Seventh International Conference on Numerical Methods in Fluid Dynamics, pp. 119–124.
4.
Ekchian, A., and Hoult, D. P., 1979, “Flow Visualization Study of the Intake Process of An Internal Combustion Engine,” SAE Technical Paper No. 790095, pp. 383–400.
5.
Errera, M. P., 1987, “Numerical Prediction of Fluid Motion in the Induction System and the Cylinder in Reciprocating Engines,” SAE Technical Paper No. 870594, pp. 1–11.
6.
Fishelov
D.
,
1990
, “
Vortex Methods for Slightly Viscous Three-Dimensional Flow
,”
SIAM Journal on Scientific and Statistical Computing
, Vol.
11
, No.
3
, pp.
399
424
.
7.
Gharakhani, A., and Ghoniem, A. F., 1996a, “Vortex Simulation of the Three-Dimensional Wake Behind A Cube,” AIAA-96-0170, 34th Aerospace Sciences Meeting, p. 22, Reno, NV.
8.
Gharakhani, A., and Ghoniem, A. F., 1996b, “Massively Parallel Implementation of A 3D Vortex-Boundary-Element Method,” Proceedings of the Second International Workshop on Vortex Flows and Related Numerical Methods, Montreal, Canada, 1995; ESAIM: http://www.emath.frlproclVol.1/, Vol. 1, pp. 213–223.
9.
Gharakhani, A., and Ghoniem, A. F., 1996c, “3D Vortex Simulation of Intake Flow In An Off-Centered Port and Cylinder with A Moving Piston,” Proceedings of the 1996 ASME Fluids Engineering Division Summer Meeting, FED-Vol. 238, Vol. 3, pp. 13–24, San Diego, CA.
10.
Gharakhani
A.
, and
Ghoniem
A. F.
,
1997
a, “
BEM Solution of the 3D Internal Neumann Problem and A Regularized Formulation for the Potential Velocity Gradients
,”
International Journal for Numerical Methods in Fluids
, Vol.
24
, No.
1
, pp.
81
100
.
11.
Gharakhani
A.
, and
Ghoniem
A. F.
,
1997
b, “
Three-Dimensional Vortex Simulation Of Time Dependent Incompressible Internal Viscous Flows
,”
Journal of Computational Physics
, Vol.
134
, pp.
75
95
.
12.
Ghoniem
A. F.
, and
Gagnon
Y.
,
1987
, “
Vortex Simulation of Laminar Recirculating Flow
,”
Journal of Computational Physics
, Vol.
68
, No.
2
, pp.
346
377
.
13.
Gosman
A. D.
,
Meling
A.
,
Watkins
A. P.
, and
Whitelaw
J. H.
,
1978
, “
Axisymmetric Flow in a Motored Reciprocating Engine
,”
Proc. Instn. Mech. Engrs.
, Vol.
192
, pp.
213
223
.
14.
Gosman, A. D., Johns, R. J. R., and Watkins, A.P., 1980, “Development of Prediction Methods for In-Cylinder Process in Reciprocating Engines,” Mattavi, J.N. and Amann, C. A., eds., Combustion Modeling in Reciprocating Engines, Plenum, New York, pp. 69–129.
15.
Khalighi
B.
,
1995
, “
Multidimensional In-Cylinder Flow Calculations and Flow Visualization in a Motored Engine
,”
ASME Journal of Fluids Engineering
, Vol.
117
, No.
2
, pp.
282
288
.
16.
Knio, O.M., and Ghoniem, A.F., 1988, “On the Formation of Streamwise Vorticity In Turbulent Shear Flows,” AIAA-88-0728, 26th Aerospace Sciences Meeting, p. 17, Reno, NV.
17.
Martins
L.-F.
, and
Ghoniem
A. F.
,
1991
, “
Vortex Simulation of the Intake Flow in A Planar Piston-Chamber Device
,”
International Journal for Numerical Methods in Fluids
, Vol.
12
, pp.
237
260
.
18.
Maxworthy
T.
,
1977
, “
Some Experimental Studies of Vortex Rings
,”
Journal of Fluid Mechanics
, Vol.
81
, No.
3
, pp.
465
495
.
19.
Morse
A.
,
Whitelaw
J. H.
, and
Yianneskis
M.
,
1980
, “
The Influence of Swirl on the Flow Characteristics of A Reciprocating Piston-Cylinder Assembly
,”
ASME Journal of Fluids Engineering
, Vol.
102
, No.
4
, pp.
478
480
.
20.
Naitoh, K., Fujii, H., Urushihara, T., Takagi, Y., and Kuwahara, K., 1990, “Numerical Simulation of the Detailed Flow In Engine Ports and Cylinders,” SAE Technical Paper No. 900256, pp. 1–18.
21.
Puckett
E. G.
,
1989
, “
A Study of the Vortex Sheet Method and Its Rate of Convergence
,”
SIAM Journal on Scientific and Statistical Computing
, Vol.
10
, No.
2
, pp.
298
327
.
22.
Saffman
P. G.
,
1978
, “
The Number of Waves On Unstable Vortex Rings
,“
Journal of Fluid Mechanics
, Vol.
84
, No.
4
, pp.
625
639
.
23.
Sullivan
J. P.
,
Widnall
S. E.
, and
Ezekiel
S.
1973
, “
A Study of Vortex Rings Using A Laser-Doppler Velocimeter
,”
AIAA Journal
, Vol.
11
, No.
10
, pp.
1384
1389
.
24.
Taghavi, R., and Dupont, A., 1988, “Multidimensional Flow Simulation in An Inlet Port/Combustion Chamber Assembly Featuring A Moving Valve,” ASME Internal Combustion Div., ICE Vol. 6, pp. 9–15.
25.
Widnall
S. E.
,
Bliss
D. B.
, and
Tsai
C-Y.
,
1974
, “
The Instability of Short Waves on A Vortex Ring
,”
Journal of Fluid Mechanics
, Vol.
66
, pp.
35
47
.
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