Superplastic Deformation Behavior of Spray Formed High Speed Tool Steel at 820°C

Can Dong Zhou; Jun Fei Fan; Hai Rong Le; Jing Guo Zhang

doi:10.4028/www.scientific.net/MSF.561-565.91

Paper Titles

Slab Method Analysis and FEM Simulation on Rotating Compression Forming of Cylinder Considering Coulomb Friction
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Effects of Ti and Nb Stabilization on the Recrystallization and the Pitting Potential in Fe-21%Cr Ferritic Stainless Steels
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Effect of Intermittent Heating on Creep Behaviour of Advanced 9-12%Cr Power Plant Steels
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Optimization of Residual Manganese in Molten Metal in Basic Oxygen Furnace (BOF)
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Superplastic Deformation Behavior of Spray Formed High Speed Tool Steel at 820°C
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Effects of Addition of V and Nb on Ω in High Cr Ferritic Steels
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Microstructural Characterization of Oxide Scale Formed by Early Stage of Oxidation of 17%Cr-Mn-Ni Austenitic Stainless Steel
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Study on Susceptibility of Hydrogen Embrittlement in a Tool Steel
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High Speed Deformation of Ultrafine Grained TWIP Steel
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HomeMaterials Science ForumMaterials Science Forum Vols. 561-565Superplastic Deformation Behavior of Spray Formed...

Superplastic Deformation Behavior of Spray Formed High Speed Tool Steel at 820°C

Abstract:

Being examined by tensile tests at 820°C with initial strain rates of 2.5×10-4 s-1, 5.0×10-3 s-1and 1.0×10-1 s-1, the hot-rolled spay formed high speed steel (SF-HSS) had superplastic properties. With έ=2.5×10-4 s-1and 5.0×10-3 s-1, the σ-ε curves indicate that there has occurred dynamic recrystallization at the later stage of deformation.The tensile elongation decreases monotonously with strain rate increasing. The strain rate sensitivity m =dlogσ/dlog έ is about 0.23. In the sub-surface of fractured SF-HSS samples with έ=2.5×10-4 s-1,, most of holes on the subsurface are observed to distribute near the carbides and arranged along the tensile axis direction. The interface between coarse carbides and matrix is very weak sites where the holes are easy to nucleate and connect to cracks during deformation. In the necked region, fine carbide particles on the grain boundary have pinned the slip of dislocations and formed dislocation wall inside the grain. Dynamic recrystallization and some climb of dislocations has occurred. The superplastic deformation mechanism with έ=2.5×10-4 s-1 was dislocation creep mechanism controlled by dynamic recrystallization. During deformation, the role of some carbide in the materials was to retard the grain growth and keep SF-HSS having fine equiaxed grain size and remain stable.