Effect of a drag-reducing polymer solution ejection on tip vortex cavitation

Autor:	P. Cerrutti, T. Pichon, D. H. Fruman
Rok vydání:	1995
Předmět:	Lift coefficient animal structures Materials science business.industry Mechanical Engineering Reynolds number Ocean Engineering Mechanics Oceanography Vortex Volumetric flow rate Physics::Fluid Dynamics Lift (force) symbols.namesake Optics Mechanics of Materials Drag Cavitation Physics::Space Physics symbols business Body orifice
Zdroj:	Journal of Marine Science and Technology. 1:13-23
ISSN:	1437-8213 0948-4280
DOI:	10.1007/bf01240009
Popis:	Experiments regarding the modification of the foil geometry and/or active or passive mass injection in the vortex core have been performed to investigate the possibility of inhibiting tip vortex cavitation. The ejection at very low flow rates of drag-reducing polymer solutions at the tip of hydrofoils and propeller blades has demonstrated effectiveness as a tip vortex cavitation inhibitor. This paper reports the results obtained with an elliptical hydrofoil, of 8cm maximum chord and 12cm haif-span, operating at Reynolds numbers, of =106, much larger than those previously reported in the literature. Lift coefficients and critical cavitation numbers were determined for a variety of flow and polymer solution ejection conditions. Tangential and axial components of the mean velocity as well as velocity fluctuations along the vortex path were also measured. At 12.5 m/s free stream velocity and a variety of angles of attack, the ejection of a 500 ppm aqueous solution of a drag-reducing polymer at a flow rate of about 5 cm3/s leads to a decrease of up to 30% in the cavitation number. This occurs without modification of the lift coefficient and, hence, of the midspan bound circulation of the foil. Moreover, water injection does not cause any appreciable change in the cavitation numbers. The tangential velocity profiles along the vortex path during polymer ejection indicate that the potential region remains the same, while the viscous core dimension increases, and the maximum tangential velocity decreases substantially as compared to the no ejection or water ejection experiments. Thus, the pressure coefficients at the vortex axis are smaller than for the no ejection or water ejection cases and cause the reduction of the critical cavitation numbers. It is speculated that this inhibition effect is due only to swelling of the polymer solution when exiting the ejection orifice.
Databáze:	OpenAIRE
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