论文信息 - Experimental Investigation of a Flapping-Jet Nozzle with a Flexible Film at Exit

Experimental Investigation of a Flapping-Jet Nozzle with a Flexible Film at Exit

This study investigates a new type of the flapping jets ‘selfexcited’ by a thin FEP film fixed at the leading edge axially and centrally to the jet nozzle exit. Hot-wire anemometer and flow visualization are used to measure the flapping-jet flows induced by different-length films and also the non-flapping counterpart, i.e., the free jet without any film involving. The rectangular film length (L) is varied for L/D = 0.5 ~ 2.0 at the constant width W = D while the jet Reynolds number Re  UoD/ is taken between 10,000 and 50,000; here, Uo and D are the jet-exit velocity and diameter while  is the fluid viscosity. It is found that the effective length of a rectangular film for the flapping to occur depends upon the exit velocity. The flapping frequency fF reduces as L is increased and rises with increasing Uo. For the present nozzle integrating with a rectangular FEP film of L/D = 0.5 ~ 2.0 and , the flapping Strouhal number StF ranges in 0.05  StF  0.23. These Strouhal numbers are substantially lower than that ( 0.65) for the primary vortex shedding in the free jet, but one to two orders of magnitude higher than those from the self-exciting fluidic devices. Results also show that the flapping jet decays and spreads far more rapidly than the free jet. The decaying and spreading rates vary with L and Re.

J. Mi | M. Xu | M. Wu

[1] J. Mi,et al. Large Eddy Simulation of an Initially-Confined Triangular Oscillating Jet , 2012 .

[2] J. Mi,et al. Statistical Properties of Turbulent Free Jets Issuing from Nine Differently-Shaped Nozzles , 2010 .

[3] Zeyad T. Alwahabi,et al. Impacts of a jet's exit flow pattern on mixing and combustion performance , 2006 .

[4] J. Mi,et al. Self-excited jet-precession Strouhal number and its influence on downstream mixing field , 2004 .

[5] J. Mi,et al. Mixing Characteristics of a Flapping Jet from a Self-Exciting Nozzle , 2001 .

[6] Ganesh Raman,et al. Jet mixing control using excitation from miniature oscillating jets , 1995 .

[7] Michael R. Davis,et al. Variable control of jet decay , 1982 .

[8] M. Favre-Marinet,et al. Generation of Oscillating Jets , 1981 .

[9] W. G. Hill,et al. Increased Turbulent Jet Mixing Rates Obtained by Self-Excited Acoustic Oscillations , 1977 .

[10] Hermann Viets,et al. Flip-Flop Jet Nozzle , 1975 .

[11] S. Crow,et al. Orderly structure in jet turbulence , 1971, Journal of Fluid Mechanics.

[12] J. Mi,et al. Scalar mixing characteristics of a self-excited flip-flop jet nozzle , 2001 .

[13] G. Nathan,et al. The precessing jet gas burner: a low NOx burner providing process efficiency and product quality improvements , 1993 .

[14] G. Nathan. The enhanced mixing burner , 1988 .

[15] M. Platzer,et al. Jet excitation by an oscillating vane , 1981 .