Publication detail
Water spray cooling of stainlees and C-Mn steel
OLDEN, V.RAUDENSKÝ, M.ONSRUND, K. HUMMEL, W.
English title
Water spray cooling of stainlees and C-Mn steel
Type
journal article in Web of Science
Language
en
Original abstract
This paper describes laboratory cooling experiments of C-Mn and stainless steel with a water/air nozzle. Experiments included use of both the steady state and the transient experimental method. The heat transfer coefficient was calculated both analytically and by a numerical method. The heat transfer coefficient was evaluated as a function of steel surface temperature, water flux, material and water/air flow. It was found that by increasing the water flux the heat transfer coefficient also increased. The Leidenfrost point was shifted to higher temperatures. Increasing air flow was also found to increase the heat transfer coefficient. Maximum heat transfer coefficient was twice as large for the C-Mn steel as for the stainless steel. Comparison of the steady state and transient experimental method showed good agreement in the temperature range 200 – 500°C, and with a water flux of 2 l/m2 s. Above 500°C it was difficult to obtain stable conditions for the steady state experiments.
English abstract
This paper describes laboratory cooling experiments of C-Mn and stainless steel with a water/air nozzle. Experiments included use of both the steady state and the transient experimental method. The heat transfer coefficient was calculated both analytically and by a numerical method. The heat transfer coefficient was evaluated as a function of steel surface temperature, water flux, material and water/air flow. It was found that by increasing the water flux the heat transfer coefficient also increased. The Leidenfrost point was shifted to higher temperatures. Increasing air flow was also found to increase the heat transfer coefficient. Maximum heat transfer coefficient was twice as large for the C-Mn steel as for the stainless steel. Comparison of the steady state and transient experimental method showed good agreement in the temperature range 200 – 500°C, and with a water flux of 2 l/m2 s. Above 500°C it was difficult to obtain stable conditions for the steady state experiments.
Keywords in English
Engineering controlled terms: Cooling; Functions; Heat flux; Heat transfer coefficients; Numerical methods; Spraying Engineering uncontrolled terms: Leidenfrost point; Water spray cooling Engineering main heading: Stainless steel
RIV year
1998
Released
01.06.1998
ISSN
0177-4832
Journal
Steel Research
Volume
69
Number
6
Pages from–to
240–246
Pages count
6
BIBTEX
@article{BUT38824,
author="Miroslav {Raudenský},
title="Water spray cooling of stainlees and C-Mn steel",
journal="Steel Research",
year="1998",
volume="69",
number="6",
month="June",
pages="240--246",
issn="0177-4832"
}