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Abstract

Time-resolved visualisation of shock wave motion within a powered resonant tube (PRT) is presented for the regurgitant mode of operation. Shock position and velocity are measured as functions of both time and space from ultra-high-speed schlieren visualisations. The shock wave velocity is seen to vary across the resonator length for both the incident and reflected waves. Three mechanisms are explored as explanations for the variation in velocity: change in local fluid velocity, variation in shock strength and variations in local temperature. For the incident wave, local fluid velocity and shock strength are extracted from the data and both are demonstrated to contribute to the observed variation, with a non-trivial remainder likely explained by variation in temperature.

Keywords

Hartmann-Sprenger tube cavity resonance powered resonance tube shock wave velocity jet regurgitant mode

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References

Hartmann

LXXVII. On the production of acoustic waves by means of an air-jet of a velocity exceeding that of sound. London Edinburgh Dublin Philos Magaz J Sci 1931; 11: 926–948.

Narayanan

Srinivasan

Sundararajan

et al . Acoustic characteristics of chamfered Hartmann whistles. J Sound Vibr 2011; 330: 2470–2496.

Raman

Srinivasan

The powered resonance tube: from Hartmann’s discovery to current active flow control applications. Progr Aerosp Sci 2009; 45: 97–123.

Raman

Kibens

Active flow control using integrated powered resonance tube actuators. In: 15th AIAA computational fluid dynamics conference, 2001, Anaheim, CA, USA, p. 3024.

Raman

Khanafseh

Cain

et al . Development of high bandwidth powered resonance tube actuators with feedback control. J Sound Vibr 2004; 269: 1031–1062.

Stanek

Raman

Kibens

et al . Suppression of cavity resonance using high frequency forcing-the characteristic signature of effective devices. In: 7th AIAA/CEAS aeroacoustics conference and exhibit, 2001, Maastricht, The Netherlands, p. 2128.

Przirembel

Fletcher

Aerothermodynamics of a simple resonance tube. AIAA J 1977; 15: 101–104.

Conrad

Pavli

AJ.

A resonance-tube igniter for hydrogen-oxygen rocket engines. NASA Technical Report 1967; TM X-1460.

Raman

Khanafseh

Cain

Development of high bandwidth actuators for aeroacoustic control. In: 40th AIAA aerospace sciences meeting & exhibit, 2002, Reno, NV, USA, p. 664.

10.

Hartmann

Om en ny Metode til Frembringelse af Lydsvingninger. Denmark: Kongelige Danske Videnskabernes Selskab, 1919.

11.

Hartmann

On a new method for the generation of sound-waves. Phys Rev 1922; 20: 719.

12.

Hartmann

Trolle

New investigation on the air jet generator for acoustic waves. Denmark: Kongelige Danske Videnskabernes Selskab, 1926.

13.

Sprenger

Uber thermische effekte in resonanzrohren. Mitteilungen Aus Dem Institut Für Aerodynamik, Eidgen Tech Hochschule Zürich. 1954; 21: 18.

14.

Brocher

Heating rate of the driven gas in a Hartmann-Sprenger tube. AIAA J 1975; 13: 1265–1266.

15.

Smith

Powell

Experiments concerning the Hartmann whistle. Technical report, California Univ, Los Angeles, 1964.

16.

Hartmann

Trolle

A new acoustic generator: the air-jet-generator. J Sci Instrum 1927; 4: 101.

17.

Sarohia

Back

LH.

Experimental investigation of flow and heating in a resonance tube. J Fluid Mech 1979; 94: 649–672.

18.

Hartmann

Construction, performance and design of the acoustic air-jet generator. J Sci Instrum 1939; 16: 140.

19.

Murugappan

Gutmark

Parametric study of the Hartmann–Sprenger tube. Exp Fluids 2005; 38: 813–823.

20.

Kawahashi

Bobone

Brocher

Oscillation modes in single-step Hartmann–Sprenger tubes. J Acoust Soc Am 1984; 75: 780–784.

21.

Kastner

Samimy

Development and characterization of Hartmann tube fluidic actuators for high-speed flow control. AIAA J 2002; 40: 1926–1934.

22.

Thompson

PA.

Jet-driven resonance tube. AIAA J 1964; 2: 1230–1233.

23.

Edgington-Mitchell

Honnery

Soria

Staging behaviour in screeching elliptical jets. Int J Aeroacoust 2015; 14: 1005–1024.

24.

Settles

GS.

Schlieren and shadowgraph techniques: visualizing phenomena in transparent media. Germany: Springer Science & Business Media, 2012.

25.

Mitchell

Honnery

Soria

The visualization of the acoustic feedback loop in impinging underexpanded supersonic jet flows using ultra-high frame rate schlieren. J Vis 2012; 15: 333–341.

26.

Raman

Advances in understanding supersonic jet screech: review and perspective. Progr Aerosp Sci 1998; 34: 45–106.

27.

Weightman

Amili

Honnery

et al . An explanation for the phase lag in supersonic jet impingement. J Fluid Mech. 2017; 815. DOI: 10.1017/jfm.2017.37

28.

Iwamoto

Deckker

A study of the Hartmann-Sprenger tube using the hydraulic analogy. Exp Fluids 1985; 3: 245–252.

29.

Vollmer

Möllmann

KP.

High speed and slow motion: the technology of modern high speed cameras. Phys Educ 2011; 46: 191.

30.

Gaydon

Hurle

IR.

The shock tube in high-temperature chemical physics. London: Chapman and Hall, 1963.

31.

Jonassen

Settles

Tronosky

MD.

Schlieren “PIV” for turbulent flows. Optics Lasers Eng 2006; 44: 190–207.

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Mechanics of the influx phase in the jet regurgitant mode of a powered resonance tube

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