I studied soft-matter mechanics of instabilities in soft shells, and laid some basic principles for designing structures with controlled 'snaps'. These controlled instabilities can be used to make fast and reliable soft-actuators.
This work was part of a large NSF/ AFRL program that aspired to apply principles from origami to get unique mechanical response.
- PhD Thesis: Non-Euclidean Shells: A Study of Growth-Induced Fabrication and Mechanical Multi-Stability
- All academic works: Google Scholar
Designing shell instabilities for soft actuators
- Geometrically controlled snapping transitions in shells with curved creases
- Journal: Proceedings of the National Academy of Sciences
- Authors : Nakul P. Bende, Arthur A. Evans, Sarah Innes-Gold, Luis A. Marin, Itai Cohen, Ryan C. Hayward, Christian D. Santangelo
- Abstract:
Curvature and mechanics are intimately connected for thin materials, and this coupling between geometry and physical properties is readily seen in folded structures from intestinal villi and pollen grains to wrinkled membranes and programmable metamaterials. While the well-known rules and mechanisms behind folding a flat surface have been used to create deployable structures and shape transformable materials, folding of curved shells is still not fundamentally understood. Shells naturally deform by simultaneously bending and stretching, and while this coupling gives them great stability for engineering applications, it makes folding a surface of arbitrary curvature a nontrivial task. Here we discuss the geometry of folding a creased shell, and demonstrate theoretically the conditions under which it may fold smoothly. When these conditions are violated we show, using experiments and simulations, that shells undergo rapid snapping motion to fold from one stable configuration to another. Although material asymmetry is a proven mechanism for creating this bifurcation of stability, for the case of a creased shell, the inherent geometry itself serves as a barrier to folding. We discuss here how two fundamental geometric concepts, creases and curvature, combine to allow rapid transitions from one stable state to another. Independent of material system and length scale, the design rule that we introduce here explains how to generate snapping transitions in arbitrary surfaces, thus facilitating the creation of programmable multistable materials with fast actuation capabilities.
Understanding mechanics behind ultra high DOF actuators: Bendy straws
- Overcurvature induced multistability of linked conical frusta: how a ‘bendy straw’ holds its shape
- Journal: Soft Matter
- Authors : Nakul P Bende, Tian Yu, Nicholas A Corbin, Marcelo A Dias, Christian D Santangelo, James A Hanna, Ryan C Hayward
- Abstract:
- We study the origins of multiple mechanically stable states exhibited by an elastic shell comprising multiple conical frusta, a geometry common to reconfigurable corrugated structures such as ‘bendy straws’. This multistability is characterized by mechanical stability of axially extended and collapsed states, as well as a partially inverted ‘bent’ state that exhibits stability in any azimuthal direction. To understand the origin of this behavior, we study how geometry and internal stress affect the stability of linked conical frusta. We find that tuning geometrical parameters such as the frustum heights and cone angles can provide axial bistability, whereas stability in the bent state requires a sufficient amount of internal pre-stress, resulting from a mismatch between the natural and geometric curvatures of the shell. We provide insight into the latter effect through curvature analysis during deformation using X-ray computed tomography (CT), and with a simple mechanical model that captures the qualitative behavior of these highly reconfigurable systems.