About the project
Delicate, high-value objects such as museum artefacts or medical goods warrant bespoke packaging solutions for protection against shock and vibration damage during transit. This project will develop the capability to design and 3D print packaging from metamaterials that derive their mechanical properties in-part from the geometry of their porous architecture.
Delicate objects must be packaged to mitigate against damage due to shock and vibration exposure during transit. Many standard solutions are available for high-volume, comparatively low-value goods. However, some transported objects, such as museum artefacts, instrumentation, or medical goods, are unique, particularly fragile and irreplaceable, warranting bespoke packaging solutions. This project will develop the capability to design and 3D print packaging from so-called metamaterials that derive their mechanical properties in-part from the intricate geometry of their porous architecture.
Metamaterials have the potential to achieve high performance cushioning and restraint that can be tailored across different directions and orientations, and 3D printing enables their manufacture and conformity to an object’s unique and complex geometry. Computational models will be developed to help understand and design metamaterial packaging solutions that can accommodate the shape and weight of example objects whilst optimising shock and vibration isolation performance. The models will be validated through the use of state-of-the-art material testing facilities, whilst both laboratory and field trials will be undertaken to quantify the cushioning provided against typical shock and vibration stimuli.
You will join the Engineering Materials research group in the Department of Mechanical Engineering whilst also being affiliated to the Dynamics research group in the Institute of Sound and Vibration Research.
