Modeling the temperature, crystallization, and residual stress for selective laser sintering of polymeric powder

A thermomechanical model is developed to predict the temperature, degree of crystallization, residual stress, and strain in the selective laser sintering process for polymeric powder. Especially, a transient heat transfer model is used to calculate the temperature evolution. An elastic-viscoplastic model is developed to describe the temperature- and time-dependent stress-strain behavior of polymeric materials with crystallization-induced strain being included. A crystallization model is used to predict the relative crystallization degree during the cooling process. The sintering process and cooling process of polyamide 12 are simulated using the developed model. The melt pool depth and the deformation of the printed parts are validated by the experimental results. The evolutions of the temperature, relative degree of crystallization, strain, and stress are evaluated. The effects of the cooling rate on the strain and stress evolutions are discussed.

Automated summary

A thermomechanical model was developed to predict temperature, crystallization, stress, and strain in the selective laser sintering process for polymeric powder. The model successfully simulated the sintering and cooling process of polyamide 12, validating the melt pool depth and part deformation. The study also discussed the effects of cooling rate on strain and stress evolution.