Impact-Dissipating Capacity of Fiber-Reinforced Polymer Samples, Fabricated by Fused Filament Fabrication

Abstract: The use of additive manufacturing for the fabrication of sacrificial cladding is becoming increasingly popular as it facilitates the production of complex yet space-saving protective structures. Despite this, the effect of several structural parameters on their capacity to mitigate high-velocity impacts remains elusive. Toward this end, the shock-mitigating capacity of various short fiber-reinforced polymer samples was evaluated regarding impact velocity and mass (raging from 1 to 8.3 m/s and 5.5 to 7.5 Kg, re… Show more

“…PLA performs best at 0.1 mm/60 min/90 °C, while PETG and PETGCF achieve optimal strength [3]. To improve the mechanical properties and surface quality of PLA FFF parts, enhancing surface and forming quality [4] expanding additive manufacturing for sacrificial cladding affects structural parameters, causing higher peak forces [5]. Impact on metal-polymer composites, finding optimal processing variables, and revealing 20 % aluminum enhances tensile strength, yield, and ductility [6].…”

Optimizing mechanical properties of virgin and recycled PLA components using Anova and neural networks

“…PLA performs best at 0.1 mm/60 min/90 °C, while PETG and PETGCF achieve optimal strength [3]. To improve the mechanical properties and surface quality of PLA FFF parts, enhancing surface and forming quality [4] expanding additive manufacturing for sacrificial cladding affects structural parameters, causing higher peak forces [5]. Impact on metal-polymer composites, finding optimal processing variables, and revealing 20 % aluminum enhances tensile strength, yield, and ductility [6].…”

Optimizing mechanical properties of virgin and recycled PLA components using Anova and neural networks