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Roll-formability of cryo-rolled ultrafine aluminium sheet
Highlights 30% Higher tensile strength with cryo-rolling compared to room temperature rolling. Ultrafine material with very low uniform elongation but large fracture strains. Minimum profile radius of 6mm in roll forming. Stress distribution more homogeneous in roll forming compared to V-die bending. Material is successfully roll formed into simple longitudinal sections.
Abstract Ultrafine-grain aluminium sheet was produced by rolling at cryogenic (CR) and at room temperature (RTR). Commercial purity aluminium plate was reduced in 30 passes from an initial material thickness of 10mm to a final thickness of 2mm (80% reduction). Tensile stress and strength were significantly increased while total elongation was drastically reduced. It was found that despite the low tensile elongation both materials are able to accommodate high localised strains in the neck leading to a high reduction in area. The formability of the material was further investigated in bending operations. A minimum bending radius of 6mm (CR) and 5mm (RTR) was found and pure bending tests showed homogeneous forming behaviour for both materials. In V-die bending the cryo-rolled material showed strain localisations across the final radius and kinking of the sample. It has been found that even if the total elongation in tension is close to zero leading to early failure in V-die bending, ultra-fine grained and low ductile sheet metals can be roll formed to simple section shapes with small radii using commercial roll forming equipment.
Roll-formability of cryo-rolled ultrafine aluminium sheet
Highlights 30% Higher tensile strength with cryo-rolling compared to room temperature rolling. Ultrafine material with very low uniform elongation but large fracture strains. Minimum profile radius of 6mm in roll forming. Stress distribution more homogeneous in roll forming compared to V-die bending. Material is successfully roll formed into simple longitudinal sections.
Abstract Ultrafine-grain aluminium sheet was produced by rolling at cryogenic (CR) and at room temperature (RTR). Commercial purity aluminium plate was reduced in 30 passes from an initial material thickness of 10mm to a final thickness of 2mm (80% reduction). Tensile stress and strength were significantly increased while total elongation was drastically reduced. It was found that despite the low tensile elongation both materials are able to accommodate high localised strains in the neck leading to a high reduction in area. The formability of the material was further investigated in bending operations. A minimum bending radius of 6mm (CR) and 5mm (RTR) was found and pure bending tests showed homogeneous forming behaviour for both materials. In V-die bending the cryo-rolled material showed strain localisations across the final radius and kinking of the sample. It has been found that even if the total elongation in tension is close to zero leading to early failure in V-die bending, ultra-fine grained and low ductile sheet metals can be roll formed to simple section shapes with small radii using commercial roll forming equipment.
Roll-formability of cryo-rolled ultrafine aluminium sheet
Marnette, J. (author) / Weiss, M. (author) / Hodgson, P.D. (author)
2014-06-15
8 pages
Article (Journal)
Electronic Resource
English
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