Dynamic crack propagation and arrest in rapid prototyping material

The purpose of this paper is to find the response of micro‐layered rapid prototyping material under impact loading.

A modified Hopkinson Bar was used to impart impact loading in velocities ranging from 2‐7 m/s. Strain gages and stress wave theory were employed to calculate the load‐point force and displacement. Hence the dynamic crack initiation and propagation energies were calculated.

It was found that the crack deflection and inter layer delamination mechanisms lead to greater absorption of crack propagation energy and hence offer better resistance to crack propagation as compared to monolithic acrylonitrile butadiene styrene (ABS).

The finding will lead to greater confidence for the use of rapid prototypes as direct‐use parts subjected to low velocity impact.

Although the static properties of ABS material used in rapid prototyping are well documented, this paper is one of the first reported researches in measuring the impact response of the micro layered ABS.