Chapter_6.pdf

Chapter 6 on Round wake (not completed in actual

book)

Classical round wake

Major surveys and theory

NEWMAN 1967

RILEY, J.J. and METCALFE, R.W. 1980 Direct numerical simula-

tions of the turbulent wake of an axisymmetric body. In

Turbulent Shear

Flows 2

(L.J.S. Bradbury et al., eds.), Springer-Verlag, 78–93.

Decay*, fig-

ures 1, 10. Growth*, figure 11. Velocity*, figure 13. Flatness*, figure 18.

SWAIN, L.M. 1929 On the turbulent wake behind a body of revolu-

tion. Proc. Roy. Soc. London

125

, 647–659.

Similarity of round wake by

mixing-length theory.

Experimental data

ATLI, V. 1989 Wakes of four complex bodies of revolution at zero

angle of attack. AIAA J.

, 707–711.

Geometry*, figure 1. Velocity*,

figures 3, 6. Reynolds stresses*, figures 4, 7. This is thesis at Instanbul

Techn. Univ., 1984.

BEVILAQUA, P.M. 1975 Some observations on the mechanism of en-

trainment. In

Turbulent Mixing in Nonreactive and Reactive Flows

(S.N.B.

Murthy, ed.) Proc. SQUID Workshop,Plenum, 323–326.

Entrainment*, fig-

ure 1.

CANNON, S. and CHAMPAGNE, F. 1991 Large-scale structures in

wakes behind axisymmetric bodies. In

Preprints, Eighth Symposium on

Turbulent Shear Flows

, Technical University of Munich, Vol. 1, Paper 6-

Velocity*, figure 3. Reynolds stresses*, figure 5. This is thesis at U.

Arizona, 1991.

CHEVRAY, R. 1968 The turbulent wake of a body of revolution.

Trans. ASME (J. Basic Eng.)

90D

, 275–284.

Velocity*, figures 4, 5.

Reynolds stresses*, figures 9–13.

ILDAY, O., ACAR, H., ELBAY, M.K., and ATLI, V. 1993 Wakes of

three axisymmetric bodies at zero angle of attack. AIAA J.

, 1152–1154.

Geometry*, figure 1. Velocity*, figures 2, 5.

McERLEAN, D.P. and PRZIREMBEL, C.E.G. 1970 The turbulent

near-wake of an axisymmetric body at subsonic speeds. Dept. Mech. and

304

Aerospace. Eng., Rutgers — The State Univ., Rep. RU-TR 132-MAE-F

(AFOSR 70-0449TR).

Velocity*, figure 37.

REICHARDT, H. and ERMSHAUS, R. 1962 Impuls- und W ̈arme-

̈ubertragung in turbulenten Windschatten hinter Rotationsk ̈orpern. Int.

J. Heat Mass Transf.

, 251–265.

Axially-symmetric wake behind various

bodies cantilevered from stagnation chamber of low-speed tunnel. Velocity,

temperature*, figure 3. Growth*, figure 6.

WU, J.-S. and FAETH, G.M. 1993 Sphere wakes in still surroundings

at intermediate Reynolds numbers. AIAA J.

, 1448–1455.

Velocity*,

figures 3, 4, 5, 8. Reynolds stress*, figure 6.

Momentumless round wake

Major surveys or theory

FINSON, M.L. 1975 Similarity behaviour of momentumless turbulent

wakes. J. Fluid Mech.

, 465–479.

HASSID, S. 1980 Similarity and decay laws of momentumless wakes.

Phys. Fluids

, 404–405.

Experimental data

DURAO, D.F.G., KNITTEL, G., PEREIRA, J.C.F., and ROCHA, J.M.P.

1991 Measurements and modelling of the turbulent near wake flow of a

disk with a central jet. In

Preprints, Eighth Symposium on Turbulent Shear

Flows

, Technical University of Munich, Paper 17–5.

HIGUCHI, H. 1977 Experimental investigation on axisymmetric tur-

bulent wakes wih zero momentum deficit. Ph. D. thesis, California Inst.

Technology.

HIGUCHI, H. and KUBOTA, T. 1990 Axisymmetric wakes behind a

slender body including zero-momentum configurations. Phys. Fluids

1615–1623.

Geometry*, figure 1. Velocity*, figures 5, 8.

RIDJANOVIC, M. 1963 Wake with zero change of momentum flux.

Ph. D. thesis, Dept. Mechanics and Hydraulics, State Univ. Iowa.

Student

of Rouse. Naudascher (JFM

, p 627) says correction to hot-wire data for

free-stream turbulence is wrong. Geometry*, figure 1. Velocity, pressure*,

figure 4. Reynolds stresses*, figures 7, 9.

SCHETZ, J.A. and JAKUBOWSKI, A.K. 1975 Experimental studies

of the turbulent wake behind self-propelled slender bodies. AIAA Paper 75-

117.

305

SCHETZ, J.A. and JAKUBOWSKI, A.K. 1975 Experimental studies

of the turbulent wake behind self-propelled slender bodies. AIAA J.

1568–1575.

Velocity*, figures 3, 6, 9. Reynolds stresses*, figures 4, 5, 7, 8,

10. See also Swanson et al.

SWANSON, R.C. Jr., SCHETZ, J.A., and JAKUBOWSKI, A.K. 1974

Turbulent wake behind slender bodies including self-propelled configura-

tions. Aerospace and Ocean Eng. Dept., Virginia Polytechnic Institute and

State Univ., Rep. VPI-Aero-024.

Velocity*, figures 12, 14, 26, 28. Some

data are tabulated.

Miscellaneous round wake

Major surveys and theory

Experimental data

FUCHS, H.V., MERCKER, E., and MICHEL, U. 1979 Mode expan-

sion of coherent structures in the wake of a circular disk. In

Turbulent Shear

Flows 2

, Proc. 2nd Int’l Symp. on Turbulent Shear Flows, Springer-Verlag,

282–296 (also Preprints, Imperial Coll., 7.14–7.19).

HAMA, F.R. and PETERSON, L.F. 1976 Axisymmetric laminar wake

behind a slender body of revolution. J. Fluid Mech.

, 1–15.

KUO, Y.-H. and BALDWIN, L.V. 1967 The formation of elliptical

wakes. J. Fluid Mech.

, 353–360.

Velocity*, figure 2. Reynolds stresses*,

figure 3.

PETERSON, L.F. 1975 An experimental study of instability and tran-

sition in an axisymmetric wake. Ph. D. thesis, Dept. Aerosp. and Mech.

Sciences, Princeton Univ.

PETERSON, L.F. and HAMA, F.R. 1978 Instability and transition

of the axisymmetric wake of a slender body of revolution. J. Fluid Mech.

, 71–96.

Velocity*, figure 5. Flow viz*, figures 22, 23.

ROBERTS, J.B. 1973 Coherence measurements in an axisymmetric

wake. AIAA J.

, 1569–1571.

WATMUFF, J.H. 1979 Phase-averaged large-scale structures in three-

dimensional turbulent wakes. Ph. D. thesis, Univ. Melbourne.

306