Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation

N. Legrand; D. Weisz-Patrault; J. Horsky; T. Luks; N. Labbe; M. Picard; A. Ehrlacher

doi:10.4028/www.scientific.net/KEM.554-557.1555

Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation

N. Legrand, D. Weisz-Patrault, J. Horsky, T. Luks, N. Labbe, M. Picard, A. Ehrlacher

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

A temperature sensor with a thermocouple placed at ~0.5 mm from roll surface is used in hot rolling conditions to evaluate by inverse calculation heat transfers in the roll bite. Simulation analysis under industrial hot rolling conditions with short contact lengths (e.g. short contact times) and high rolling speeds (7 m./s) show that the temperature sensor + inverse analysis with a high acquisition frequency (> 1000 Hz) is capable to predict accurately (5 to 10% error) the roll bite peak of temperature. However as heat flux is more sensitive to noise measurement, the peak of heat flux in the bite is under-estimated (20% error) by the inverse calculation and thus the average roll bite heat flux is also interesting information from the sensor (these simulation results will be verified with an industrial trial that is being prepared). Rolling tests on a pilot mill with low rolling speeds (from 0.3 to 1.5 m./s) and strip reductions varying from 10 to 40% have been performed with the temperature sensor. Analysis of the tests by inverse calculation show that at low speed (<0.5 m./sec.) and large contact lengths (reduction: 30 to 40%), the roll bite peak of heat flux reconstructed by inverse calculation is correct. At higher speeds (1.5 m./sec.) and smaller contact lengths (reduction : 10-20%), the reconstruction is incorrect: heat flux peak in the bite is under-estimated by the inverse calculation though its average value is correct. The analysis reveals also that the Heat Transfer Coefficient HTC _roll-bite (characterizing heat transfers between roll and strip in the bite) is not uniform along the roll bite but is proportional to the local rolling pressure. Finally, based on the above results, simulations with a roll thermal fatigue degradation model under industrial hot rolling conditions show that the non-uniform roll bite Heat Transfer Coefficient HTC_roll-bite may have under certain rolling conditions a stronger influence on roll thermal fatigue degradation than the equivalent (e.g. same average) HTC _roll-bite taken uniform along the bite. Consequently, to be realistic the roll thermal fatigue degradation model has to incorporate this nonuniform HTCroll-bite.

Original language	English
Title of host publication	The Current State-of-the-Art on Material Forming
Subtitle of host publication	Numerical and Experimental Approaches at Different Length-Scales
Publisher	Trans Tech Publications Ltd
Pages	1555-1569
Number of pages	15
ISBN (Print)	9783037857199
DOIs	https://doi.org/10.4028/www.scientific.net/KEM.554-557.1555
Publication status	Published - 1 Jan 2013
Externally published	Yes
Event	16th ESAFORM Conference on Material Forming, ESAFORM 2013 - Aveiro, Portugal Duration: 22 Apr 2013 → 24 Apr 2013

Publication series

Name	Key Engineering Materials
Volume	554-557
ISSN (Print)	1013-9826
ISSN (Electronic)	1662-9795

Conference

Conference	16th ESAFORM Conference on Material Forming, ESAFORM 2013
Country/Territory	Portugal
City	Aveiro
Period	22/04/13 → 24/04/13

Keywords

Hot strip rolling
Inverse thermal analysis
Roll bite heat transfer
Steel
Thermal fatigue

Access to Document

10.4028/www.scientific.net/KEM.554-557.1555

Cite this

Legrand, N., Weisz-Patrault, D., Horsky, J., Luks, T., Labbe, N., Picard, M., & Ehrlacher, A. (2013). Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation. In The Current State-of-the-Art on Material Forming: Numerical and Experimental Approaches at Different Length-Scales (pp. 1555-1569). (Key Engineering Materials; Vol. 554-557). Trans Tech Publications Ltd. https://doi.org/10.4028/www.scientific.net/KEM.554-557.1555

Legrand, N. ; Weisz-Patrault, D. ; Horsky, J. et al. / Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation. The Current State-of-the-Art on Material Forming: Numerical and Experimental Approaches at Different Length-Scales. Trans Tech Publications Ltd, 2013. pp. 1555-1569 (Key Engineering Materials).

@inproceedings{41941c59a4e34fbe960d956525f81330,

title = "Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation",

abstract = "A temperature sensor with a thermocouple placed at \textasciitilde{}0.5 mm from roll surface is used in hot rolling conditions to evaluate by inverse calculation heat transfers in the roll bite. Simulation analysis under industrial hot rolling conditions with short contact lengths (e.g. short contact times) and high rolling speeds (7 m./s) show that the temperature sensor + inverse analysis with a high acquisition frequency (> 1000 Hz) is capable to predict accurately (5 to 10\% error) the roll bite peak of temperature. However as heat flux is more sensitive to noise measurement, the peak of heat flux in the bite is under-estimated (20\% error) by the inverse calculation and thus the average roll bite heat flux is also interesting information from the sensor (these simulation results will be verified with an industrial trial that is being prepared). Rolling tests on a pilot mill with low rolling speeds (from 0.3 to 1.5 m./s) and strip reductions varying from 10 to 40\% have been performed with the temperature sensor. Analysis of the tests by inverse calculation show that at low speed (<0.5 m./sec.) and large contact lengths (reduction: 30 to 40\%), the roll bite peak of heat flux reconstructed by inverse calculation is correct. At higher speeds (1.5 m./sec.) and smaller contact lengths (reduction : 10-20\%), the reconstruction is incorrect: heat flux peak in the bite is under-estimated by the inverse calculation though its average value is correct. The analysis reveals also that the Heat Transfer Coefficient HTC roll-bite (characterizing heat transfers between roll and strip in the bite) is not uniform along the roll bite but is proportional to the local rolling pressure. Finally, based on the above results, simulations with a roll thermal fatigue degradation model under industrial hot rolling conditions show that the non-uniform roll bite Heat Transfer Coefficient HTCroll-bite may have under certain rolling conditions a stronger influence on roll thermal fatigue degradation than the equivalent (e.g. same average) HTC roll-bite taken uniform along the bite. Consequently, to be realistic the roll thermal fatigue degradation model has to incorporate this nonuniform HTCroll-bite.",

keywords = "Hot strip rolling, Inverse thermal analysis, Roll bite heat transfer, Steel, Thermal fatigue",

author = "N. Legrand and D. Weisz-Patrault and J. Horsky and T. Luks and N. Labbe and M. Picard and A. Ehrlacher",

year = "2013",

month = jan,

day = "1",

doi = "10.4028/www.scientific.net/KEM.554-557.1555",

language = "English",

isbn = "9783037857199",

series = "Key Engineering Materials",

publisher = "Trans Tech Publications Ltd",

pages = "1555--1569",

booktitle = "The Current State-of-the-Art on Material Forming",

note = "16th ESAFORM Conference on Material Forming, ESAFORM 2013 ; Conference date: 22-04-2013 Through 24-04-2013",

}

Legrand, N, Weisz-Patrault, D, Horsky, J, Luks, T, Labbe, N, Picard, M & Ehrlacher, A 2013, Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation. in The Current State-of-the-Art on Material Forming: Numerical and Experimental Approaches at Different Length-Scales. Key Engineering Materials, vol. 554-557, Trans Tech Publications Ltd, pp. 1555-1569, 16th ESAFORM Conference on Material Forming, ESAFORM 2013, Aveiro, Portugal, 22/04/13. https://doi.org/10.4028/www.scientific.net/KEM.554-557.1555

Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation. / Legrand, N.; Weisz-Patrault, D.; Horsky, J. et al.
The Current State-of-the-Art on Material Forming: Numerical and Experimental Approaches at Different Length-Scales. Trans Tech Publications Ltd, 2013. p. 1555-1569 (Key Engineering Materials; Vol. 554-557).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation

AU - Legrand, N.

AU - Weisz-Patrault, D.

AU - Horsky, J.

AU - Luks, T.

AU - Labbe, N.

AU - Picard, M.

AU - Ehrlacher, A.

PY - 2013/1/1

Y1 - 2013/1/1

N2 - A temperature sensor with a thermocouple placed at ~0.5 mm from roll surface is used in hot rolling conditions to evaluate by inverse calculation heat transfers in the roll bite. Simulation analysis under industrial hot rolling conditions with short contact lengths (e.g. short contact times) and high rolling speeds (7 m./s) show that the temperature sensor + inverse analysis with a high acquisition frequency (> 1000 Hz) is capable to predict accurately (5 to 10% error) the roll bite peak of temperature. However as heat flux is more sensitive to noise measurement, the peak of heat flux in the bite is under-estimated (20% error) by the inverse calculation and thus the average roll bite heat flux is also interesting information from the sensor (these simulation results will be verified with an industrial trial that is being prepared). Rolling tests on a pilot mill with low rolling speeds (from 0.3 to 1.5 m./s) and strip reductions varying from 10 to 40% have been performed with the temperature sensor. Analysis of the tests by inverse calculation show that at low speed (<0.5 m./sec.) and large contact lengths (reduction: 30 to 40%), the roll bite peak of heat flux reconstructed by inverse calculation is correct. At higher speeds (1.5 m./sec.) and smaller contact lengths (reduction : 10-20%), the reconstruction is incorrect: heat flux peak in the bite is under-estimated by the inverse calculation though its average value is correct. The analysis reveals also that the Heat Transfer Coefficient HTC roll-bite (characterizing heat transfers between roll and strip in the bite) is not uniform along the roll bite but is proportional to the local rolling pressure. Finally, based on the above results, simulations with a roll thermal fatigue degradation model under industrial hot rolling conditions show that the non-uniform roll bite Heat Transfer Coefficient HTCroll-bite may have under certain rolling conditions a stronger influence on roll thermal fatigue degradation than the equivalent (e.g. same average) HTC roll-bite taken uniform along the bite. Consequently, to be realistic the roll thermal fatigue degradation model has to incorporate this nonuniform HTCroll-bite.

AB - A temperature sensor with a thermocouple placed at ~0.5 mm from roll surface is used in hot rolling conditions to evaluate by inverse calculation heat transfers in the roll bite. Simulation analysis under industrial hot rolling conditions with short contact lengths (e.g. short contact times) and high rolling speeds (7 m./s) show that the temperature sensor + inverse analysis with a high acquisition frequency (> 1000 Hz) is capable to predict accurately (5 to 10% error) the roll bite peak of temperature. However as heat flux is more sensitive to noise measurement, the peak of heat flux in the bite is under-estimated (20% error) by the inverse calculation and thus the average roll bite heat flux is also interesting information from the sensor (these simulation results will be verified with an industrial trial that is being prepared). Rolling tests on a pilot mill with low rolling speeds (from 0.3 to 1.5 m./s) and strip reductions varying from 10 to 40% have been performed with the temperature sensor. Analysis of the tests by inverse calculation show that at low speed (<0.5 m./sec.) and large contact lengths (reduction: 30 to 40%), the roll bite peak of heat flux reconstructed by inverse calculation is correct. At higher speeds (1.5 m./sec.) and smaller contact lengths (reduction : 10-20%), the reconstruction is incorrect: heat flux peak in the bite is under-estimated by the inverse calculation though its average value is correct. The analysis reveals also that the Heat Transfer Coefficient HTC roll-bite (characterizing heat transfers between roll and strip in the bite) is not uniform along the roll bite but is proportional to the local rolling pressure. Finally, based on the above results, simulations with a roll thermal fatigue degradation model under industrial hot rolling conditions show that the non-uniform roll bite Heat Transfer Coefficient HTCroll-bite may have under certain rolling conditions a stronger influence on roll thermal fatigue degradation than the equivalent (e.g. same average) HTC roll-bite taken uniform along the bite. Consequently, to be realistic the roll thermal fatigue degradation model has to incorporate this nonuniform HTCroll-bite.

KW - Hot strip rolling

KW - Inverse thermal analysis

KW - Roll bite heat transfer

KW - Steel

KW - Thermal fatigue

U2 - 10.4028/www.scientific.net/KEM.554-557.1555

DO - 10.4028/www.scientific.net/KEM.554-557.1555

M3 - Conference contribution

AN - SCOPUS:84880553304

SN - 9783037857199

T3 - Key Engineering Materials

SP - 1555

EP - 1569

BT - The Current State-of-the-Art on Material Forming

PB - Trans Tech Publications Ltd

T2 - 16th ESAFORM Conference on Material Forming, ESAFORM 2013

Y2 - 22 April 2013 through 24 April 2013

ER -

Legrand N, Weisz-Patrault D, Horsky J, Luks T, Labbe N, Picard M et al. Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation. In The Current State-of-the-Art on Material Forming: Numerical and Experimental Approaches at Different Length-Scales. Trans Tech Publications Ltd. 2013. p. 1555-1569. (Key Engineering Materials). doi: 10.4028/www.scientific.net/KEM.554-557.1555

Characterization of roll bite heat transfers in hot steel strip rolling and their influence on roll thermal fatigue degradation

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Conference

Keywords

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