Inhomogeneous Deformation of Multilayered Roll-Bonded Brass/Cu Composites

doi:10.1007/s40195-015-0237-5

Abstract

Abstract:

The deformation gradients in multilayered hot roll-bonded composite materials incorporating two dissimilar face-centered cubic metals, i.e., brass and Cu, were investigated by characterizing the deformation microstructure, hardness and texture at different thickness positions of the composites. For the constitutive metals, the center part of each metal sheet forms the substructure containing coarse grains, while the ultrafine grains and significant shear banding form in the outer part. As deformation increases, the cross-interface shear occurs in the Cu sheet of the composites. Then, grain fragmentation, shear banding and dynamic recovery become the main factors that influence hardness of the metal. Moreover, in the co-deformed composites, the interface between brass and Cu plays a role in texture developments of the individual metals.

Key words: Deformation, Multilayers, Brass/Cu composites, Texture

Nan Jia, Ming-Wei Zhu, Yi-Ran Zheng, Tong He, Xiang Zhao. Inhomogeneous Deformation of Multilayered Roll-Bonded Brass/Cu Composites[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(5): 600-607.

Figures/Tables 7

Fig. 1 Optical micrographs on the longitudinal section containing RD and ND of brass a, Cu b at the initial state

Fig. 2 Schematic of a roll-bonded brass/Cu specimen

Fig. 3 CLSM micrographs observed on the longitudinal sections of the brass/Cu specimens after different rolling reductions: a 52%; b 57%; c 66%; d 73%

Fig. 4 CLSM micrograph observed on the longitudinal sections of the 73% rolled brass/Cu specimen a and the magnified images of the selected regions in a of Cu b and brass c areas

Fig. 5 Vickers hardness (HV) obtained at different thicknesses of the 52% a, 57% b, 66% c and 73% d rolled brass/Cu specimens. In the plots, the x-axis indicates the distances from "surface" layer of the outer Cu sheet to positions where the hardness indentations locate

Fig. 6 Textures at different thickness positions of brass in the 73% deformed specimen, using α and τ fiber representation: a α fiber with constant Euler angles Φ = 45° and φ 2 = 0°; b β fiber with local maximum texture intensity along a skeleton line (with variable coordinates); c τ fiber with constant Euler angles φ 1 = 90° and φ 2 = 45°

Fig. 7 Textures at different thickness positions of Cu in the 73% deformed specimen, using α and τ fiber representation: a α fiber with constant Euler angles Φ = 45° and φ 2 = 0°; b β fiber with local maximum texture intensity along a skeleton line (with variable coordinates); c τ fiber with constant Euler angles φ 1 = 90° and φ 2 = 45°

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