Application of image processing for simulation of mechanical response of multi-length scale microstructures of engineering alloys

Microstructures of engineering alloys often contain features at widely diff erent length scales. In this contribution, a digital image processing techn ique is presented to incorporate the effect of features at higher length sc ales on the damage evolution and local fracture processes occurring at lowe r length scales. The method is called M-SLIP: Microstructural Scale Linking by Image Processing. The technique also enables incorporation of the real microstructure at different length scales in the finite element (FE)-based simulations. The practical application of the method is demonstrated via FE analysis on the microstructure of an aluminum cast alloy (A356), where the length scales of micropores and silicon particles differ by two orders of magnitude. The simulation captures the effect of nonuniformly distributed m icropores at length scales of 200 to 500 mu m on the local stresses and str ains around silicon particles that are at the length scales of 3 to 5 mu m. The procedure does not involve any simplifying assumptions regarding the m icrostructural geometry, and therefore, it is useful to model the mechanica l response of the real multi-length scale microstructures of metals and all oys.