Litcius/Paper detail

Hierarchical cubic lattice structures with bending- and stretching-dominated cellular designs for enhanced buckling resistance

Asha Viswanath, Mohamad Khalil, Muhammad Khizer Ali Khan, W.J. Cantwell, Kamran A. Khan

2025International Journal of Lightweight Materials and Manufacture13 citationsDOIOpen Access PDF

Abstract

Buckling is a common failure mode in low-density strut lattices, limiting their mechanical strength and stability. This work presents a novel methodology to design and manufacture lightweight, buckling-resistant strut-based lattice structures by reinforcing buckling-prone members with hierarchical lattice unit cells—either stretching- or bending-dominated—without changing the strut lattice's relative density. Four types of lattice unit cells were examined: plate, honeycomb, strut, and TPMS solids and sheets. These were tested on single-cell cubic lattice columns with square cross-sectional struts. The resulting hierarchical structures were additively manufactured and experimentally evaluated, demonstrating significantly enhanced buckling performance. Design for additive manufacturing principles were applied, and structures with stretching and bending-dominated unit cells achieved higher critical buckling loads, with the square honeycomb cell lattice showing the highest improvement at 179 % over the baseline. This approach broadens opportunities for enhancing low-density strut lattices and developing novel buckling-resistant designs.

Topics & Concepts

BendingMaterials scienceLattice (music)BucklingNanotechnologyChemical physicsCrystallographyComposite materialChemistryPhysicsAcousticsCellular and Composite StructuresAdvanced Materials and MechanicsStructural Analysis and Optimization