Sage Journals: Discover world-class research

Abstract

Pseudo-shock is often encountered in a variety of internal flows, almost always entailing an increase in total pressure loss, hence leading to deterioration of the flow system performance. This pseudo-shock is a very complex process still requiring a good deal of elucidation. In spite of the recent rapid progress that has been made in numerical computation methods, there is as yet no quantitative prediction of pseudo-shock flow. The present paper describes a simple pseudo-shock flow model using a mass-weighted averaging technique. The flow quantities across pseudo-shock were analysed for different Mach numbers, flow confinements and turbulent boundary layer Reynolds numbers. The analytical results agree well with the previous experimental data. The flow model presented can be used to estimate the important features of pseudo-shocks in engineering practice.

Keywords

pseudo-shock wave Mach number Reynolds number flow confinement compressible flow normal shock wave

Get full access to this article

View all access options for this article.

References

Green

J. E.

Interactions between shock waves and turbulent boundary layers. Prog, in Aerospace Sci., 1970, 101, 235–340.

Crocco

One-dimensional treatment of steady gas dynamics. In Fundamentals of Gas Dynamics (Ed. Emmons

H. W.

), 1958, p. 115 (Princeton).

Matsuo

Miyazato

Kim

H. D.

Shock train and pseudo-shock phenomena in internal gas flows. Prog, in Aerospace Sci, 1999, 35, 33–100.

Hataue

Computational study of the shock-wave/boundary-layer interaction in a duct. Fluid Dynamics Res., 1989, 5, 217–234.

Carroll

B. F.

Dutton

J. C.

Characteristics of multiple shock wave/turbulent boundary layer interactions in rectangular ducts. J. Propulsion and Power, 1990, 6 (2), 186–193.

Yamane

Oshima

Nakamura

Ishii

Numerical simulation of pseudo shock in straight channels. Jap. Soc. Mech Engrs Int. J., Ser. B., 1995, 38 (4), 549–554.

Ikui

Matsuo

Nagai

The mechanism of pseudo-shock waves. Bull. Jap. Soc. Mech. Engrs, 1974 17 (108), 731–739.

Ikui

Matsuo

Sasaguchi

Modified diffusion model of pseudo-shock waves considering upstream boundary layer. Bull. Jap. Soc. Mech. Engrs, 1981, 24 (197), 1920–1927.

Tamaki

Tomita

Yamane

A study of pseudo-shock, I, λ-type pseudo-shock. Bull. Jap. Soc. Mech. Engrs, 1970, 13 (55), 51–58.

10.

Shchetinkov

E. S.

Piecewise-one-dimensional models of supersonic combustion and pseudo-shocks in a duct. Combust. Explos. and Shock Waves, 1975, 9 (4), 409–417.

11.

Zimont

V. L.

Ostras

V. N.

Calculation of pseudo-shocks in a cylindrical duct. Fluid Mech. Sov. Res., 1976, 5 (2), 78–87.

12.

Nagai

Yaga

On the pseudo shock wave relations. ASME FED. 224 Trans, and Turbulent Compressible Flows, 1995, 103–108.

13.

Tyler

R. D.

One-dimensional treatment of non-uniform flow. ARC, R&M 2991, 1957.

14.

Ward-Smith

A. J.

Internal Fluid Flow, 1980, p. 67 (Clarendon Press).

15.

Torizumi

One-dimensional treatment of compressible flow through a duct (in Japanese). Trans. Jap. Soc. Mech. Engrs, Ser. B, 1992, 58 (549), 1650–1653.

16.

Tucker

Approximate turbulent boundary-layer development in plane compressible flow along thermally insulated surfaces with application to supersonic tunnel contour correction. NACATN 2045, 1950.

17.

Tucker

Approximate calculation of turbulent boundary-layer development in compressible flow. NACA TN 2337, 1951.

18.

Shapiro

A. H.

The Dynamics and Thermodynamics of Compressible Fluid Flow, 1953, Vol. 1, p. 1085 (Ronald Press Company).

19.

McLafferty

Theoretical pressure recovery through a normal shock in a duct with initial boundary layer. J. Aeronaut. Sci., 1953, 20 (3), 169–174.

20.

Merkli

P. E.

Pressure recovery in rectangular constant area supersonic diffusers. Am. Inst. Aeronaut. Astronaut. J., 1976, 14 (2), 168–172.

21.

Carroll

B. R

Fernandez

P. A.L.

Dutton

J. C.

Computations and experiments for a multiple normal shock/ boundary-layer interaction. J. Propulsion and Power, 1993, 9 (3), 405–411.

22.

McCormick

D. C.

Shock/boundary-layer interaction control with vortex generators and passive cavity. Am. Inst. Aeronaut. Astronaut. J, 1993, 31 (1), 91–96.

23.

Waltrup

P. J.

Cameron

J. M.

Wall shear and boundary-layer measurements in shock separated flow. Am. Inst. Aeronaut. Astronaut. J, 1974, 12 (6), 878–880.

24.

Childs

M. E.

Multiple transonic shock-wave/ turbulent boundary-layer interaction in a circular duct. Am. Inst. Aeronaut. Astronaut. J., 1985, 23 (10), 1506–1511.

Mass-averaging pseudo-shock model in a straight flow passage

Abstract

Abstract

Keywords

Get full access to this article

References