THROUGH PROCESS MODELING OF ALUMINUM ALLOY CASTINGS RELATING CASTING DEFECTS TO FATIGUE PERFORMANCE

摘要

There continues to be increasing interest in using cast aluminum alloy components in automotive applications with cyclic in-service loads. Predicting fatigue performance is a key issue in the design of these components and must consider the entire manufacturing route which typically involves casting, heat treatment and machining. A through process modeling methodology was used to predict fatigue life of one such component, an A356 automotive wheel. The technique tracks the microstructure and defect formation during the casting process as well as the residual stresses that arise due to heat treatment and subsequent finish machining. The microstructural features and the final residual stress state are used as input parameters to calculate the final cyclic stress state and in-service fatigue life. The pore size distribution and secondary dendrite arm spacing formed during casting were predicted using model-based constitutive equations run within a validated macroscopic heat flow model of the process. These constitutive equations were developed by regression fitting to results from an in-house mesoscale solidification model. The residual stresses formed during the quench stage of heat treatment and released during finish machining were simulated in a two-stage thermal stress model. A final stress/displacement model was developed to calculate the variation of the multi-axial stress state and the expected fatigue life of the wheel during cyclic in-service loading. Each of the model results shows good agreement to measurements taken at various stages of the manufacturing process. In particular, excellent agreement was attained for in-service strain. The fatigue performance was compared with full-scale fatigue test results to validate the suitability of the through process modeling for application to aluminum alloy wheels.