Free jets spun from a prilling tower

Stephen Decent; Andrew King; Iain Wallwork

doi:10.1023/A:1016127207992

Free jets spun from a prilling tower

Stephen Decent, Andrew King, Iain Wallwork

Research output: Contribution to journal › Article

50 Citations (Scopus)

Abstract

A mathematical model of the dynamics of an inviscid liquid jet, subjected to both gravity and surface tension, which emerges from rotating drum is derived and analysed using asymptotic and computational methods. The trajectory and linear stability of this jet is determined. By use of the stability results, the break up length of the jet is calculated. Such jets arise in the manufacture of pellets (for example, of fertilizer or magnesium) using the prilling process. Here the drum would contain many thousands of holes, and the molten liquid would be pumped into the rotating drum. After the jet has broken up into droplets, these droplets solidify to form pellets. The jets in this prilling process are curved in space by both gravity and surface tension.

Original language	English
Pages (from-to)	265-282
Number of pages	18
Journal	Journal of Engineering Mathematics
Volume	42
Issue number	3/4
DOIs	https://doi.org/10.1023/A:1016127207992
Publication status	Published - 1 Jan 2002

Keywords

pellets
prilling
rotation
surface tension
jet
gravity

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1023/A:1016127207992

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title = "Free jets spun from a prilling tower",

abstract = "A mathematical model of the dynamics of an inviscid liquid jet, subjected to both gravity and surface tension, which emerges from rotating drum is derived and analysed using asymptotic and computational methods. The trajectory and linear stability of this jet is determined. By use of the stability results, the break up length of the jet is calculated. Such jets arise in the manufacture of pellets (for example, of fertilizer or magnesium) using the prilling process. Here the drum would contain many thousands of holes, and the molten liquid would be pumped into the rotating drum. After the jet has broken up into droplets, these droplets solidify to form pellets. The jets in this prilling process are curved in space by both gravity and surface tension.",

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AB - A mathematical model of the dynamics of an inviscid liquid jet, subjected to both gravity and surface tension, which emerges from rotating drum is derived and analysed using asymptotic and computational methods. The trajectory and linear stability of this jet is determined. By use of the stability results, the break up length of the jet is calculated. Such jets arise in the manufacture of pellets (for example, of fertilizer or magnesium) using the prilling process. Here the drum would contain many thousands of holes, and the molten liquid would be pumped into the rotating drum. After the jet has broken up into droplets, these droplets solidify to form pellets. The jets in this prilling process are curved in space by both gravity and surface tension.

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KW - prilling

KW - rotation

KW - surface tension

KW - jet

KW - gravity

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JO - Journal of Engineering Mathematics

JF - Journal of Engineering Mathematics

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Free jets spun from a prilling tower

Abstract

Keywords

UN SDGs

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