The Dynamic Response of Dense 3 Dimensionally Printed Polylactic Acid

• Published in: Journal of dynamic behavior of materials Vol. 5; no. 4; pp. 377 - 386
• Main Authors: Agu, H. O., Hameed, A., Appleby-Thomas, G. J., Wood, D. C.
• Format: Journal Article
• Language: English
• Published: Cham Springer International Publishing 01.12.2019; Springer Nature B.V
• Subjects: Chemistry and Materials Science; Dynamic response; Elastic limit; Equations of state; Gauges; Hugoniot equation of state; Impact loads; Manganin; Materials Science; Metallic Materials; Plates (structural members); Polylactic acid; Shear strength; Shock waves; Solid Mechanics; Strain rate; Three dimensional printing; United States > US; Polymer; Hugoniot elastic limit; Equations of state; Polylactic acid
• ISSN: 2199-7446; 2199-7454
• DOI: 10.1007/s40870-019-00198-8

Polylactic acid (PLA) is commonly used as a feedstock material for commercial 3D printing. As components manufactured from such material become more commonplace, it is inevitable that some of the resultant systems will be exposed to high strain-rate/impact events during their design-life (for example, components being dropped or even involved in a high-speed crash). To this end, understanding the shock properties of polylactic acid, in its role as a major raw material for 3D printed components, is of particular importance. In this work, printed samples of PLA were deformed by one-dimensional shock waves generated via the plate impact technique, allowing determination of both the Hugoniot Equation of State (EOS) and shear strength of the material. Both linear and non-linear EOS forms were considered in the U S -Up plane, with the best-fit found to take the general form U S = 1.28 + 3.06 - 1.09 U p 2 in the U s - U p plane, consistent with other polymers. Use of lateral Manganin gauges embedded in the material flow allowed consideration of lateral stress evolution at impact pressures ranging from 0.3 to 4.0 GPa. Shear strength was observed to increase with impact stress, however, with minimal strengthening behind the shock front. Deviation of the measured stress from the predicted elastic measurement (corresponding to the PLA’s Hugoniot Elastic Limit) was observed at longitudinal stress of 0.90 ± 0.05 GPa, within range of polymeric materials of similar characteristics—the first time this important parameter has been measured for PLA. As a result, this material characterisation will allow numerical modellers to accurately predict the structural response of PLA-based components/structures against high strain rates such as impacts or drops.