Topology Optimization 3D-Printed Mycelium Hydrogels is a M.Tech project topic for Mechanical Engineering. It gives students a clear starting point for research, implementation planning, and documentation.
Topology Optimization 3D-Printed Mycelium Hydrogels Project Details
| Abstract |
This research seeks to create sustainable and resilient bio-composites for 3D printing using specially-designed, fungus-inoculated hydrogels. There is a notable lack of computational models to adequately address and engineer the mechanics of structures made from 3D printed fungi. This research proposes the first computational model for 3D printed mycelium that relates fungal growth to material stiffness. The model simulates fungal growth using a diffusion model, and then converts that model into a distribution of local mycelial density and corresponding local stiffness. This describes how elemental stiffness varies throughout the material. The research presents two topology optimization models, both of which are based on Bayesian optimization, to increase the stiffness of
the structure of cuboid 3D printed parts while decreasing the amount of material used to create the part. One model was developed to maximize the stiffness of a single material, which allows for the bio-derived constituents to be engineered.
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| Reference Paper |
Topology Optimization of 3D-Printed Mycelium Hydrogels |
| Domain |
Mechanical Engineering |
| Sub-Domain |
Design & Manufacturing / Additive Manufacturing / Bioprinting |
| PDF Download |
Download / View PDF |
| Get Help |
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