Local mechanical properties of intercritically reheated coarse grained heat affected zone in low alloy steel

Local mechanical properties of intercritically reheated coarse grained heat affected zone in low alloy steel

•Nanomechanical testing has been performed based on compression of very small pillars (up to 1μm).•Pillars are located at grain boundaries decorated by massive martensite–austenite.•Pillars are also located inside grains in martensite/bainite.•Very high yield strength (>1500MPa) was found in bloc...

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Bibliographic Details
Published in:Materials in engineering Vol. 59; pp. 135 - 140
Main Authors: Haugen, Veronica G., Rogne, Bjørn Rune Sørås, Akselsen, Odd M., Thaulow, Christian, Østby, Erling
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-07-2014
Subjects:
Ductile brittle transition
Grain boundaries
Grains
Heat affected zone
Microstructure
Nanostructure
Phases
Stress-strain relationships
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Summary:•Nanomechanical testing has been performed based on compression of very small pillars (up to 1μm).•Pillars are located at grain boundaries decorated by massive martensite–austenite.•Pillars are also located inside grains in martensite/bainite.•Very high yield strength (>1500MPa) was found in blocky martensite–austenite phases.•The scatter is large, possibly due to different orientations or sampling effects. Steels applied in arctic climates are subjected to low temperature. Since they undergo ductile–brittle transition with falling temperature, their fracture toughness must be addressed, particularly after welding. To predict their behaviour requires knowledge on local properties. Thus, the present study concerns nanomechanical testing of typical microstructures present in the intercritically reheated coarse grained heat affected zone of a 490MPa forging. Such microstructures were achieved by weld thermal simulation of samples with 11mm×11mm cross section and 100mm length, using peak temperature of 1350°C in the first cycle and 780°C in the second cycle. Both cycles used cooling time Δt8/5 of 5 or 10s. This caused formation of M–A phases along prior austenite grain boundaries and mixture of bainite/tempered martensite in the bulk. Nanomechanical testing was performed by compression of nanopillars prepared in grain boundary located M–A phases and in the bulk of the grains. The results achieved showed significant that the grain boundary phase possesses much higher strength than the grain bulk. It is also shown that there is large scatter in the stress–strain data, depending on the actual local microstructure being tested.
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ISSN:0261-3069
DOI:10.1016/j.matdes.2014.02.010