Publication detail

Comparison of water and oil nozzle cooling intensity

RAUDENSKÝ, M. HORSKÝ, J.

Original Title

Comparison of water and oil nozzle cooling intensity

English Title

Comparison of water and oil nozzle cooling intensity

Type

conference paper

Language

en

Original Abstract

Experimental program for studying influence of coolant on cooling intensity. Identical experiments conducting water and oil as coolants. The goal of the program is to compare cooling intensity for both media.Heta transfer is represented by heat transfer coefficient distribution. The knowledge of boundary conditions allowed the application of numerical models for the computation of material temperature fields during cooling, the computation of heat losses and thermal stresses caused by spraying.

English abstract

Experimental program for studying influence of coolant on cooling intensity. Identical experiments conducting water and oil as coolants. The goal of the program is to compare cooling intensity for both media.Heta transfer is represented by heat transfer coefficient distribution. The knowledge of boundary conditions allowed the application of numerical models for the computation of material temperature fields during cooling, the computation of heat losses and thermal stresses caused by spraying.

Keywords

cooling, heat trasnfer, numerical model

RIV year

2004

Released

23.06.2003

Publisher

HEFAT

Location

Livingstone, Victoria Falls, Zambia

ISBN

0-620-30503-7

Book

HEFAT 2003 - Heat Transfer, Fluid Mechanics and Thermodynamics

Pages from

27

Pages to

30

Pages count

4

URL

BibTex


@inproceedings{BUT13496,
  author="Miroslav {Raudenský} and Jaroslav {Horský}",
  title="Comparison of water and oil nozzle cooling intensity",
  annote="Experimental program for studying influence of coolant on cooling intensity. Identical experiments conducting water and oil as coolants. The goal of the program is to compare cooling intensity for both media.Heta transfer is represented by heat transfer coefficient distribution. The knowledge of boundary conditions allowed the application of numerical models for the computation of material temperature fields during cooling, the computation of heat losses and thermal stresses caused by spraying.",
  address="HEFAT",
  booktitle="HEFAT 2003 - Heat Transfer, Fluid Mechanics and Thermodynamics",
  chapter="13496",
  howpublished="electronic, physical medium",
  institution="HEFAT",
  year="2003",
  month="june",
  pages="27--30",
  publisher="HEFAT",
  type="conference paper"
}