Subcooled water jet quenching phenomena for a high temperature rotating cylinder

Quenching characteristics of a rotating hollow steel cylinder with 15mm water jet having flow rate of 6–10L/min has been experimentally investigated. The jet with 60–80K subcooling was impinged on the horizontally rotating (0, 15, 30 and 60rpm) 460–560°C hot cylinder. A developed inverse solution es...

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Veröffentlicht in:	International journal of heat and mass transfer 2014-01, Vol.68, p.466-478
Hauptverfasser:	Mozumder, Aloke Kumar, Mitsutake, Yuichi, Monde, Masanori
Format:	Artikel
Sprache:	eng
Schlagworte:	Boiling Boiling heat transfer Cooling Cylinders Heat conduction Heat flux Heat transfer Inverse solution Jet quenching Quenching Rotating Surface temperature
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container_title	International journal of heat and mass transfer
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creator	Mozumder, Aloke Kumar Mitsutake, Yuichi Monde, Masanori
description	Quenching characteristics of a rotating hollow steel cylinder with 15mm water jet having flow rate of 6–10L/min has been experimentally investigated. The jet with 60–80K subcooling was impinged on the horizontally rotating (0, 15, 30 and 60rpm) 460–560°C hot cylinder. A developed inverse solution estimated surface temperature and heat flux from measured temperatures during quenching. Surface rotation created a non-uniform cooling which resulted in a non-uniform distribution of wetting front (leading edge of visible vigorous boiling region). Surface velocity (rotation) strongly influenced relative velocity between solid and liquid which affected the surface heat transfer during cooling. As the cylinder rotated and the jet was fixed, the surface heat flux fluctuated which was followed by the surface temperature. Heat transfer from a relatively faster moving surface was smaller but due to periodic cooling, bulk temperature reduced more. The estimated heat flux agreed reasonable with static surface critical heat flux in literature especially for the trend with radial position. The produced boiling curves were well compatible with some of the compared correlations in nucleate boiling region.
doi_str_mv	10.1016/j.ijheatmasstransfer.2013.09.059
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The jet with 60–80K subcooling was impinged on the horizontally rotating (0, 15, 30 and 60rpm) 460–560°C hot cylinder. A developed inverse solution estimated surface temperature and heat flux from measured temperatures during quenching. Surface rotation created a non-uniform cooling which resulted in a non-uniform distribution of wetting front (leading edge of visible vigorous boiling region). Surface velocity (rotation) strongly influenced relative velocity between solid and liquid which affected the surface heat transfer during cooling. As the cylinder rotated and the jet was fixed, the surface heat flux fluctuated which was followed by the surface temperature. Heat transfer from a relatively faster moving surface was smaller but due to periodic cooling, bulk temperature reduced more. The estimated heat flux agreed reasonable with static surface critical heat flux in literature especially for the trend with radial position. 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subjects	Boiling Boiling heat transfer Cooling Cylinders Heat conduction Heat flux Heat transfer Inverse solution Jet quenching Quenching Rotating Surface temperature
title	Subcooled water jet quenching phenomena for a high temperature rotating cylinder
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