This collaborative project, supported by the U.S. Department of Energy, explores an innovative design strategy for a carbon negative building system.

The design and fabrication of a combined compression and tension funicular canopy with periodic anticlastic, diamond surfaces.

Cellular mechanical metamaterials can be systematically architected to demonstrate properties ranging from bending- to stretching-dominated, realize metafluidic behavior, or create novel hybrid shellulars.

This research investigates the possibility of fabricating shell-based cellular structures using knitting techniques.

In the study, we present a new multi-filament 3D printer which makes possible the designing and printing of a continuous toolpath with different materials for different stress conditions.

This research presents a framework for effective room temperature repair of fractured metals using an area-selective nickel electrodeposition process we refer to as electrochemical healing.

This project presents novel research in structural design and analysis of an ultra-transparent bridge made of glass sheets only in a double layer, funicular, compression-only configuration.

The result shows that the sheet-based system has improved performance with the same volume of material and can withstand a wide range of loading scenarios.

This research results in a tension-compression system with a performative geometry and material.

Cellular mechanical metamaterials can be systematically architected to demonstrate properties ranging from bending- to stretching-dominated, realize metafluidic behavior, or create novel hybrid shellulars.

Tortuca is an efficient and innovative structural system constructed by the dry assembly of thirteen hollow glass units.

This research introduces a computational algorithm for translating a Cellular Funicular Structure (CFS) to a Shellular Funicular Structure (SFS) and explores a fabrication method using the origami/kirigami technique.

This research proposes a geometry-based generative design method that utilizes Machine Learning to generate various funicular floor structures with simple sketch input.

The Saltatur demonstrates innovative research in the design and fabrication of a prefab, discrete, spatial composite structure consisting of a spatial, compression-only concrete body, post-tensioning steel rods, and an ultra-thin glass structure on its top in the form of long-span furniture.

The proposed approach introduces a new typology of funicular spatial structures consist of a minimal surface for a given boundary condition.

Graphic Statics and Strut and Tie ModelsAuthors Salma Mozaffari, Masoud Akbarzadeh, Thomas VogelProject Date 2019-2020Related Publications Generation of Strut-and-Tie... Graphic Statics in a Continuum...Description This research investigates procedures for the...

This research explores the structural performance of a funicular polyhedral geometry using experimental testing. The geometry of the physical prototype for the presented study is designed using 3DGS method.