Detail publikace

Hydraulic Descaling Improvement - Findings of Jet Structure on Water Hammer Effect

RAUDENSKÝ, M. HORÁK, A. HORSKÝ, J. POHANKA, M. KOTRBÁČEK, P.

Originální název

Hydraulic Descaling Improvement - Findings of Jet Structure on Water Hammer Effect

Anglický název

Hydraulic Descaling Improvement - Findings of Jet Structure on Water Hammer Effect

Jazyk

en

Originální abstrakt

The latest research in descaling brought new findings about dynamic features of the process. The continuous water jet formed by a descaling nozzle has complicated and variable qualities not visible to the naked eye. A water jet is formed by clusters of droplets moving at high velocity. The theory of the "water hammer" must be used when the descaling process is studied. Results show that in the impact area, one can observe pressure peaks of several hundred Mpa's, lasting microseconds per peak.

Anglický abstrakt

The latest research in descaling brought new findings about dynamic features of the process. The continuous water jet formed by a descaling nozzle has complicated and variable qualities not visible to the naked eye. A water jet is formed by clusters of droplets moving at high velocity. The theory of the "water hammer" must be used when the descaling process is studied. Results show that in the impact area, one can observe pressure peaks of several hundred Mpa's, lasting microseconds per peak.

Dokumenty

BibTex


@misc{BUT63485,
  author="Miroslav {Raudenský} and Aleš {Horák} and Jaroslav {Horský} and Michal {Pohanka} and Petr {Kotrbáček}",
  title="Hydraulic Descaling Improvement - Findings of Jet Structure on Water Hammer Effect",
  annote="The latest research in descaling brought new findings about dynamic features of the process. The continuous water jet formed by a descaling nozzle has complicated and variable qualities not visible to the naked eye. A water jet is formed by clusters of droplets moving at high velocity. The theory of the "water hammer" must be used when the descaling process is studied. Results show that in the impact area, one can observe pressure peaks of several hundred Mpa's, lasting microseconds per peak.",
  address="ATS",
  booktitle="La Revue de Mettallurgie",
  chapter="63485",
  edition="neuvedeno",
  institution="ATS",
  year="2006",
  month="december",
  pages="34--35",
  publisher="ATS",
  type="presentation"
}