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Abstract

Hydroentangling technique uses extremely fine nozzles to direct high-energy water jets against a loose fiber web. This study investigates the effect of nozzle geometry on the flow dynamics of hydroentangling jet by simulating water-jet formation from cone-up, streamline, and cone-down geometries. The simulation results reveal that water contacts with the nozzle wall all the way when it goes through the cone-up and streamline nozzles. In contrast, the cone-down geometry can form a constricted water-jet because of a sharp turning angle at the nozzle entrance. Consequently, the cone-down nozzle has higher velocity coefficient and the water-jet discharged from the nozzle has a longer intact length than the two others because of the absence of cavitation and wall friction. Part of the results is in excellent agreement with earlier experimental studies.

Keywords

hydroentangling nozzle geometry flow dynamics simulation.

References

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Effect of Nozzle Geometry on the Flow Dynamics of Hydroentangling Jet

Abstract

Keywords

References