Progress and Issues in Thermomechanical Simulation: Experience in Tata Steel (Europe)

A.A. Howe; S.V. Parker; R. Beaverstock; W.M.  van Haaften

doi:10.4028/www.scientific.net/MSF.706-709.43

Paper Titles

On the Microstructure of Plate Steels for API-5L X120 Applications
p.17

Shaping of Nanostructured Materials or Coatings through Spark Plasma Sintering
p.24

Development of NiMnGa/Polymer Composite Materials
p.31

Empirical Relationships for the Impact of Nb and C Content on the Mechanical Properties of Hot Rolled Microalloyed Steels
p.37

Progress and Issues in Thermomechanical Simulation: Experience in Tata Steel (Europe)
p.43

Transformation of Deformed Austenite at Temperatures above the Ae₃
p.49

Strategy for Achieving High Strength in Al-Mg-Sc Alloys by Intense Plastic Straining
p.55

Orientation Relationships between Directionally Grown Precipitates and their Parent Phases in Steels
p.61

Magnesium Alloy Development for Automotive Applications
p.69

HomeMaterials Science ForumMaterials Science Forum Vols. 706-709Progress and Issues in Thermomechanical...

Progress and Issues in Thermomechanical Simulation: Experience in Tata Steel (Europe)

Abstract:

Thermomechanical simulation serves to simulate industrial conditions under closer control and much more cheaply than through works trials, and also under ideal conditions (e.g. constant temperature and strain rate) more suitable for input to metallurgical models which can then be applied to real cases. It is remarkable how much effort in Industry and Academia, and how many conferences, are devoted to this issue. Moreover, many of the questions being addressed do not appear to change very much over the years [1]. The continuing stream of new rolled grades requires new experimental quantification and adjustment to models, because we do not as yet have a physically-based model powerful enough to extrapolate safely to substantially different compositions and process conditions. But that is only part of the story. Quantitatively sufficient simulation of the existing grade portfolio is a surprisingly complex, multi-facetted problem. An example is presented in Fig.1 [2] of the model in routine use for Tata Steel’s plate mill at Scunthorpe, UK. Many variables are involved in the prediction of the optimum rolling schedule in terms of productivity, plate geometry, and final properties, each of which will be associated with its own errors. Its configuration around the microstructural development during rolling brings in a range of variables which are very difficult to measure on plant, and are usually implied from laboratory studies. Extensive plant data exist but are seldom transferable to other mills owing to the individual set-up of each mill and its associated data measurement facilities. Similarly, great care has to be taken to avoid systematic differences between laboratory simulation, pilot rolling, and results on plant, owing to subtleties of the set conditions and accuracy of measurement. An overview of such experience in Tata Steel’s European plate and strip mills is given here.

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Materials Science Forum (Volumes 706-709)

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43-48

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https://doi.org/10.4028/www.scientific.net/MSF.706-709.43

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January 2012

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A.A. Howe, S.V. Parker, R. Beaverstock, W.M. van Haaften

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Modeling, Thermomechanical Simulation, Validation

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