Heat Transfers Coefficients of Directly and Indirectly Cooled Component Areas during Air-Water Spray Cooling

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Titel in ÜbersetzungWärmeübergangskoeffizienten von direkt und indirekt gekühlten Bauteilbereichen bei der Luft-Wasser-Spraykühlung
OriginalspracheMehrere Sprachen
Seiten (von - bis)64-75
Seitenumfang12
FachzeitschriftHTM - Journal of Heat Treatment and Materials
Jahrgang76
Ausgabenummer1
PublikationsstatusVeröffentlicht - 18 Feb. 2020

Abstract

For the determination of heat transfer coefficients in air-water spray cooling, two methods are presented that are capable of characterizing multi-nozzle cooling set-ups. The methods are based on the quenching of thin-walled tubes or massive cylinders on which cooling curves are recorded at given positions with thermocouples. The temperature dependent heat transfer coefficients were calculated by an inverse calculation and the measured temperature-time-curves could be reproduced with these data in numerical cooling simulations. Next, the determined heat transfer coefficients were used for the calculation of an air-water-spray quenching process of a forging part with more challenging geometry. The calculated results were compared with thermocouple measurements. Different calculation variants for the heat transfer on component surfaces not directly exposed to the air-water spray are shown and discussed.

Schlagwörter

    Air-Water Spray Cooling, Hardening, Heat Transfer Coefficient, Heat Treatment, Numerical Simulation, Quenching

ASJC Scopus Sachgebiete

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Heat Transfers Coefficients of Directly and Indirectly Cooled Component Areas during Air-Water Spray Cooling. / Kahra, C.; Nürnberger, F.; Maier, H. J. et al.
in: HTM - Journal of Heat Treatment and Materials, Jahrgang 76, Nr. 1, 18.02.2020, S. 64-75.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Kahra C, Nürnberger F, Maier HJ, Herbst S. Heat Transfers Coefficients of Directly and Indirectly Cooled Component Areas during Air-Water Spray Cooling. HTM - Journal of Heat Treatment and Materials. 2020 Feb 18;76(1):64-75. doi: 10.1515/htm-2020-0005
Kahra, C. ; Nürnberger, F. ; Maier, H. J. et al. / Heat Transfers Coefficients of Directly and Indirectly Cooled Component Areas during Air-Water Spray Cooling. in: HTM - Journal of Heat Treatment and Materials. 2020 ; Jahrgang 76, Nr. 1. S. 64-75.
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abstract = "For the determination of heat transfer coefficients in air-water spray cooling, two methods are presented that are capable of characterizing multi-nozzle cooling set-ups. The methods are based on the quenching of thin-walled tubes or massive cylinders on which cooling curves are recorded at given positions with thermocouples. The temperature dependent heat transfer coefficients were calculated by an inverse calculation and the measured temperature-time-curves could be reproduced with these data in numerical cooling simulations. Next, the determined heat transfer coefficients were used for the calculation of an air-water-spray quenching process of a forging part with more challenging geometry. The calculated results were compared with thermocouple measurements. Different calculation variants for the heat transfer on component surfaces not directly exposed to the air-water spray are shown and discussed.",
keywords = "Air-Water Spray Cooling, Hardening, Heat Transfer Coefficient, Heat Treatment, Numerical Simulation, Quenching",
author = "C. Kahra and F. N{\"u}rnberger and Maier, {H. J.} and S. Herbst",
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Download

TY - JOUR

T1 - Heat Transfers Coefficients of Directly and Indirectly Cooled Component Areas during Air-Water Spray Cooling

AU - Kahra, C.

AU - Nürnberger, F.

AU - Maier, H. J.

AU - Herbst, S.

N1 - Funding Information: Funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) – Project-ID 252662854 – SFB 1153.

PY - 2020/2/18

Y1 - 2020/2/18

N2 - For the determination of heat transfer coefficients in air-water spray cooling, two methods are presented that are capable of characterizing multi-nozzle cooling set-ups. The methods are based on the quenching of thin-walled tubes or massive cylinders on which cooling curves are recorded at given positions with thermocouples. The temperature dependent heat transfer coefficients were calculated by an inverse calculation and the measured temperature-time-curves could be reproduced with these data in numerical cooling simulations. Next, the determined heat transfer coefficients were used for the calculation of an air-water-spray quenching process of a forging part with more challenging geometry. The calculated results were compared with thermocouple measurements. Different calculation variants for the heat transfer on component surfaces not directly exposed to the air-water spray are shown and discussed.

AB - For the determination of heat transfer coefficients in air-water spray cooling, two methods are presented that are capable of characterizing multi-nozzle cooling set-ups. The methods are based on the quenching of thin-walled tubes or massive cylinders on which cooling curves are recorded at given positions with thermocouples. The temperature dependent heat transfer coefficients were calculated by an inverse calculation and the measured temperature-time-curves could be reproduced with these data in numerical cooling simulations. Next, the determined heat transfer coefficients were used for the calculation of an air-water-spray quenching process of a forging part with more challenging geometry. The calculated results were compared with thermocouple measurements. Different calculation variants for the heat transfer on component surfaces not directly exposed to the air-water spray are shown and discussed.

KW - Air-Water Spray Cooling

KW - Hardening

KW - Heat Transfer Coefficient

KW - Heat Treatment

KW - Numerical Simulation

KW - Quenching

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U2 - 10.1515/htm-2020-0005

DO - 10.1515/htm-2020-0005

M3 - Article

AN - SCOPUS:85101563917

VL - 76

SP - 64

EP - 75

JO - HTM - Journal of Heat Treatment and Materials

JF - HTM - Journal of Heat Treatment and Materials

SN - 1867-2493

IS - 1

ER -

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