Impact damage evolution rules of maize kernel based on FEM.

The main cause of damage to maize during harvesting and processing is impact damage. This study aimed to investigate the evolution of impact damage to maize kernels under different impact velocities and orientations. Based on the damage characteristics observed in impact tests, an elastoplastic model has been established to accurately simulate the damage behaviour of maize kernels. The microscopic impact behaviour of maize kernels was presented by the finite element method. The results indicated that there were differences in the evolution of damage for different damage morphology in maize kernels. The nature of surface damage was the diffusion and reflection of stress waves, while the nature of local breakage was the concentration of tiny cracks and the release of elastic potential energy. The nature of fracture was the combined effect of compressive and tensile stresses. Meanwhile, under the surface damage, the maximum stresses in the contact area of maize kernels subjected to front orientation were 20.08 MPa, 10.71 MPa for side orientation, and 13.56 MPa for bottom orientation. Under the local breakage, the front orientation with the highest number of cracks occurred at a velocity of 27.3 m s−1, while for the side orientation, it occurred at 24.6 m s−1, and for the bottom orientation, it occurred at 26.2 m s−1. The results can be extended to the study of impact damage in irregularly shaped grains, which was beneficial for controlling product quality and optimising the design of relevant mechanical parameters in agricultural engineering and food engineering fields. [Display omitted] • Damage morphology of maize kernels was summarised. • Evolution rules of damage in multi-orientation maize kernels were explored. • Impact dynamic response of multi-orientation maize kernels was obtained. • Differences in impact damage of multi-orientation maize kernels were compared. [ABSTRACT FROM AUTHOR]