Molding 3D curved structures by selective heating

TL;DR

This paper introduces three innovative, cutting-free methods for shaping flat thermo-responsive sheets into complex 3D curved structures by selective heating, enabling precise control over intrinsic metrics and embeddings.

Contribution

It presents three novel, algorithmic methods for molding flat sheets into 3D curved structures with desired metrics without cutting or gluing, expanding fabrication techniques.

Findings

Demonstrated successful physical molding of complex shapes

Developed algorithms for pattern design based on desired metrics

Achieved embedding control through selective heating patterns

Abstract

It is of interest to fabricate curved surfaces in three dimensions from easily available homogeneous material in the form of flat sheets. The aim is not just to obtain a surface $M$ in $\mathbb{R}^3$ which has a desired intrinsic Riemannian metric, but to get the desired embedding $M \subset \mathbb{R}^3$ up to translations and rotations (the Riemannian metric alone need not uniquely determine this). In this paper, we demonstrate three generic methods of molding a flat sheet of thermo-responsive plastic by selective contraction induced by targeted heating. These methods do not involve any cutting and gluing, which is a property they share with origami. The first method is inspired by tailoring, which is the usual method for making garments out of plain pieces of cloth. Unlike usual tailoring, this method produces the desired embedding in $\mathbb{R}^3$, and in particular, we get the desired intrinsic Riemannian metric. The second method just aims to bring about the desired new Riemannian metric via an appropriate pattern of local contractions, without directly controlling the embedding. The third method is based on triangulation, and seeks to induce the desired local distances. This results in getting the desired embedding in $\mathbb{R}^3$, in particular, it also gives us the target Riemannian metric. The second and the third methods, and also the first method for the special case of surfaces of revolution, are algorithmic in nature. We give a theoretical account of these methods, followed by illustrated examples of different shapes that were physically molded by these methods.