Gleeble Simulation of HAZ in S690QL Steel: Microstructural and Mechanical Properties

Damir Tomerlin; Nenad Gubeljak; Dražan Kozak

doi:10.4028/p-HmvK3N

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Gleeble Simulation of HAZ in S690QL Steel: Microstructural and Mechanical Properties
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 966Gleeble Simulation of HAZ in S690QL Steel:...

Gleeble Simulation of HAZ in S690QL Steel: Microstructural and Mechanical Properties

Abstract:

When investigating the heterogeneous properties of welded joints, mechanical testing of certain Heat Affected Zone (HAZ) regions, using standard approach test specimens, is very difficult or sometimes even impossible. Inability to precisely position and extract mechanical test specimens, even ones of the subsize dimensions, from the narrow HAZ regions is a limiting factor in the mechanical testing implementation. Detailed investigation of the HAZ is made possible by the use of thermo-mechanical simulations on the Gleeble welding simulator. In scope of this paper several characteristic HAZ microstructures of S690QL grade High Strength Steel (HSS) are being simulated. Multi-pass welding simulations are done on special 10x10 mm square section bar specimens in order to reproduce thermal gradients and characteristic microstructures at any location in a weld. Such simulated HAZ microstructures are of a sufficiently large volume, with homogeneous and repeatable properties, that standard specimen methods for mechanical testing can be readily implemented. Metallographic optical examinations, as well as hardness measurements were done initially. Mechanical properties are focused on determining stress-strain curves for each characteristic weld region. The paper investigates whether the mechanical properties of Gleeble simulated hard-soft combined HAZ regions are better in comparison to exclusively hard or soft HAZ regions. The obtained results can subsequently be used for the material model development.

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Periodical:

Key Engineering Materials (Volume 966)

Pages:

115-120

DOI:

https://doi.org/10.4028/p-HmvK3N

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Online since:

November 2023

Authors:

Damir Tomerlin*, Nenad Gubeljak, Dražan Kozak

Keywords:

Experimental Testing, Gleeble, High Strength Steel, Thermo-Mechanical Simulations, Welded Joint Heterogeneity

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* - Corresponding Author

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