Abstract
The evolution of texture and grain orientations in a cold-rolled steel of BCC structure was simulated by a reaction stress (RS) model. The results show that cold-rolled texture could be assessed based on a RS model because the stress and strain are considered to remain consistent in the deformation process. The strain consistency is actualized by the cooperation of two plastic strains and an elastic strain. The accumulation range of each reaction stress and different activation abilities of {110}<111> and {112}<111> slip systems strongly affect the calculated deformation textures. The values of reaction stress are influenced by elastic anisotropy; however, the effects are greatly reduced because its corresponding reaction stress accumulation is limited. Typical α-fiber and γ-fiber textures are achieved when the reaction stress accumulation coefficients αijs are chosen suitably. Furthermore, the αij values that are selected based on statistically calculated textures can also be used to simulate the orientation change of multiple orientations. The existence of reaction stress is able to stabilize crystallographically symmetrical orientations under rolling deformation, in which the Schmid factors of several slip systems are identical.
Highlights
Rolling technology is widely used in manufacturing metals and alloys
Regarding the stress and strain consistency during simulation, it is actualized inside grain groups by grain interaction (GIA) and advanced lamel (ALAMEL) models, in which 8 grains and 2 grains are set as a group respectively, and different relaxation is implemented inside the groups [4,5,6,7,11]
This study focuses on the rolling deformation behavior of BCC structured steel via both theoretical simulation and experimental characterization
Summary
Rolling technology is widely used in manufacturing metals and alloys. In general, deformation texture forms during rolling, and the resultant texture will affect the following processes and determine properties of final products [1,2]. Grain interaction (GIA) model, viscoplastic self-consistent (VPSC) model, advanced lamel (ALAMEL) models and others have been proposed With development of these models, the simulated deformation textures have been continuously improved and nicely match experimental observation [4,5,6,7,8,9,10]. The VPSC model considers the stress and strain continuity between every deformed grain and its surrounding matrix statistically [9,10,11]. A RS model is used to investigate the rolling deformation behaviors of a BCC structured steel and the simulated results are compared to the experimental results and results reported in the literature. The study could help to clarify the deformation process of BCC structured steel
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
