UConn assistant professor Julian Norato is part of an exclusive group pf 34 scientists nationwide that have been selected to receive The Office of Naval Research Young Investigator Award, which supports early career academic scientists and engineers that “show exceptional promise for doing creative research.”
Prof. Norato’s project, titled “Computational Synthesis of Composable-Material Structures from Manufacturing-Friendly Primitives”, will advance topology optimization methods for the design of structures made with composite materials with consideration for their manufacturing. Topology optimization is a computational technique that determines the optimal distribution of material within a given space to, for example, design the lightest structure that will not mechanically fail under applied loads. Existing topology optimization methods excel at exploring designs made of homogeneous, isotropic materials—that is, materials that have uniform, direction-independent properties throughout the structure. However, there is a substantial need to advance topology optimization techniques that render designs that are made of heterogeneous, anisotropic materials, such as composite materials, and that take into consideration the geometric requirements of existing composite manufacturing processes. By exploring designs that take advantage of the unique properties of composite materials and that can be more readily translated to fabrication, the techniques advanced by this project have the potential to render significant weight savings and improve the mission performance of Naval aircraft and ship structures.
Prof. Norato leads UConn’s Structural Optimization Laboratory where he and his graduate students develop computational state-of-the-art computational approaches to:
- Incorporate realistic failure mode criteria
- Render designs that are cost-effective and/or close-to-fabrication for a given manufacturing process
- Simultaneously consider the design of a structure and a material system
These capabilities will expand the role of computational design of structures and material systems in the early concept design and advance our ability to push the limits of physical performance (including multifunctional systems), lightweight, and cost effectiveness beyond what is possible today.