论文信息 - Effect of Nozzle Geometry on Hydroentangling Water Jets: Experimental Observations

Effect of Nozzle Geometry on Hydroentangling Water Jets: Experimental Observations

This paper reports on the role of nozzle geometry on the characteristics of hydroen tangling water jets, specifically the behavior of three different conventional nozzle geometries under pressures below 3500 psi. Profiles of the water jets are digitized with a Nikon Dlx digital camera from which we extract the water-jet breakup lengths and spray angles under different operating conditions. Our preliminary data indicate that the cone-up nozzle produces water jets with considerably shorter intact lengths and slightly larger spray angles and a higher coefficient of discharge compared to the two other geometries considered. We attribute this distinct behavior to friction-induced and cavitation-induced turbulence inside the cone-up nozzles; a constricted water jet is formed by cone-down or cylindrical nozzles. Our results are in excellent agreement with previous experimental and computational data.

[1] H. Tafreshi,et al. Simulating and Characterizing Water Flows Inside Hydroentangling Orifices , 2003 .

[2] Simulating the Flow Dynamics in Hydroentangling Nozzles: Effect of Cone Angle and Nozzle Aspect Ratio , 2003 .

[3] H. Hiroyasu,et al. Break-up Length of a Liquid Jet and Internal Flow in a Nozzle , 1991 .

[4] R. Reitz,et al. DROP AND SPRAY FORMATION FROM A LIQUID JET , 1998 .

[5] K. Ramamurthi,et al. Influence of periodic disturbances on inception of cavitation in sharp-edged orifices , 2002 .

[6] Arthur H. Lefebvre,et al. GEOMETRICAL EFFECTS ON DISCHARGE COEFFICIENTS FOR PLAIN-ORIFICE ATOMIZERS , 1991 .

[7] Stephen D. Heister,et al. CAVITATING INJECTOR FLOWS: VALIDATION OF NUMERICAL MODELS AND SIMULATIONS OF PRESSURE ATOMIZERS , 1999 .

[8] B. Pourdeyhimi,et al. The effects of nozzle geometry on waterjet breakup at high Reynolds numbers , 2003 .

[9] M. J. McCarthy,et al. Review of stability of liquid jets and the influence of nozzle design , 1974 .

[10] R. Grose. Orifice Contraction Coefficient for Inviscid Incompressible Flow , 1985 .

[11] Christopher J. Rutland,et al. Cavitation in Two-Dimensional Asymmetric Nozzles , 1999 .