Nature Inspires Additive Manufacturing Research

Inspired by the tiny, circular vessels in the trunks of palm trees that allow the iconic plants to bend but not snap in strong winds, an assistant professor of aerospace engineering is researching how to recreate Mother Nature's handiwork in additive manufacturing.

Mirmilad Mirsayar received a three-year, $200,627 research grant from the National Science Foundation's highly competitive CMMI-Mechanics of Materials and Structures program to study the mechanics and physics of crack propagation in functionally graded cellular structures made by additive manufacturing. That's the process of creating an object by building it one layer at a time.

Mirsayar is the sole principal investigator of the project, titled, "Understanding Mixed-Mode Fracture Mechanics in Additively Manufacturable Functionally Graded Microcellular Solids."

"While having broad engineering applications, the mathematics and physics behind this work are so complex and at the fundamental level, which is one of the reasons that the NSF was interested in this project," he said. "I need to come up with how the topology and morphology, which is the cell configuration, the geometry of the cell, across the space can functionally change to get the optimized property for maximizing the fracture resistance." he said.

Materials with cellular structures, such as aircraft wings and artificial bones, are widely used in industries such as aerospace and biomedical. As additive manufacturing has advanced, materials with cellular structures and increasingly complex geometrical patterns can be precisely manufactured.

Mirsayar is looking at ways to optimize these strong and light cellular structures made by additive manufacturing to achieve the highest resistance against failure under complex operational loading conditions, such as bending tension, compression and torsion.

His research is inspired by cellular patterns seen in nature like palm trees and butterfly wings. For example, unlike oak trees and some others, the palm tree's center contains those vessels, distributed non-uniformly throughout the trunk, that help it survive in Florida's windy environment. Other biological systems, such as bone, honeycombs and marine sponges, also serve as natural inspirations.

"I'm enjoying this research because I'm learning from nature and I'm applying fundamentals of physics and mathematics to solve a very important engineering problem while training the next generation of engineers and researchers," he said.

Provided by Florida Institute of Technology