Numerical modeling of static equilibria and bifurcations in elastic strip networks.

We propose a numerical framework to study mechanics of elastic networks that are made of thin strips. Each strip is modeled as a Kirchhoff rod, and the entire strip network is formulated as a two-point boundary value problem (BVP) that can be solved by a general-purpose BVP solver. We first study the buckling behavior of a bigon, which consists of two strips initially straight and deformed so as to intersect with each other through a fixed angle at the two ends. Numerical results match with experimental observations in that the intersection angle and aspect ratio of the strip's cross section contribute to make a bigon buckle out of plane. Then we study a bigon ring that is composed of a series of bigons to form a loop. A bigon ring is observed to be multistable, depending on the intersection angle, number of bigon cells, and the anisotropy of the strip's cross section. We find both experimentally and numerically that a bigon ring can fold into a multiply-covered loop, which is similar to the folding of a bandsaw blade. Finally we explore the static equilibria and bifurcations of a 6-bigon ring, and find several families of equilibrium shapes. Our numerical framework captures the experimental configurations of a bigon ring well and further reveals interesting connections among various states. Our framework can be applied to study general elastic strip networks that may contain flexible joints, naturally curved strips of different lengths, etc. The folding and multistable behaviors of a bigon ring may inspire the design of novel deployable and morphable structures.