Bio-inspired Tensegrity Soft Modular Robots

In this paper, we introduce a design principle to develop novel soft modular robots based on tensegrity structures and inspired by the cytoskeleton of living cells. We describe a novel strategy to realize tensegrity structures using planar manufacturing techniques, such as 3D printing. We use this strategy to develop icosahedron tensegrity structures with programmable variable stiffness that can deform in a three-dimensional space. We also describe a tendon-driven contraction mechanism to actively control the deformation of the tensegrity mod-ules. Finally, we validate the approach in a modular locomotory worm as a proof of concept.Comment: 12 pages, 7 figures, submitted to Living Machine conference 201

Design of a novel wheeled tensegrity robot: a comparison of tensegrity concepts and a prototype for travelling air ducts

Efforts in the research of tensegrity structures applied to mobile robots have recently been focused on a purely tensegrity solution to all design requirements. Locomotion systems based on tensegrity structures are currently slow and complex to control. Although wheeled locomotion provides better efficiency over distances there is no literature available on the value of wheeled methods with respect to tensegrity designs, nor on how to transition from a tensegrity structure to a fixed structure in mobile robotics. This paper is the first part of a larger study that aims to combine the flexibility, light weight, and strength of a tensegrity structure with the efficiency and simple control of a wheeled locomotion system. It focuses on comparing different types of tensegrity structure for applicability to a mobile robot, and experimentally finding an appropriate transitional region from a tensegrity structure to a conventional fixed structure on mobile robots. It applies this transitional structure to what is, to the authors' knowledge, the design of the world's first wheeled-tensegrity mobile robot that has been designed with the goal of traversing air ducts

The Design, Construction, and Experimental Characterization of Spatial Parallel Architectures of Elastofluidic Systems

Creating organic, life like motion has historically been extremely difficult and costly for general applications. Traditional structures and robots use rigid components with discrete joints to produce desired motions but are limited in freedom by the range of motion each additional component allows. In a traditionally rigid robot complex motion is obtained through the addition of joints and links. These additions add complexity to a rigid robot but improve its ability to create motion. Soft robotics aims to overcome the limitations of traditional robotics by creating integrated actuation and structure which more closely imitates organic movement. Often the most effective examples to learn from are natural phenomenon or organisms such as underwater and land based invertebrates. In pursuit of the goal of effective soft robotics researchers have explored the idea of a pneumatic elastofluidic actuator, one which expands and deforms in response to applied pressure. While these systems have demonstrated some limited success, they are often used either as a single entity or in series with one another to produce novel motions. In this thesis parallel structures made of these actuators are shown to have the potential to be extremely powerful and useful for soft robotic applications. These spatial arrangements of connected and dependent actuators exhibit behaviors impossible for a single actuator. This research concerns the effective design and construction of these complex parallel structures in an attempt to define a method of characterization which produces useful and desirable spatial architectures and motions

Form- und Parameterfindung von multistabilen Tensegrity-Strukturen mittels Optimierungsalgorithmen und Anwendungen in der Greifertechnik

Der Gegenstand der Arbeit sind Tensegrity-Strukturen mit mehreren stabilen Gleichgewichtskonfigurationen, sogenannte multistabile Tensegrity-Strukturen. Im Vordergrund der Arbeit steht die Entwicklung von Algorithmen, mit denen solche Strukturen entworfen, untersucht und gezielt ausgelegt werden können. Dafür werden Möglichkeiten zur Bestimmung der Gleichgewichtskonfigurationen von multistabilen Tensegrity-Strukturen betrachtet. Des Weiteren wird untersucht, wie Tensegrity-Strukturen so ausgelegt werden können, dass sie vorgegebene Eigenschaften aufweisen. Dazu werden Kenngrößen zur Charakterisierung dieser Eigenschaften definiert. Für beide Aufgabenstellungen werden Optimierungsprobleme hergeleitet. Zur Lösung dieser Optimierungsprobleme werden Algorithmen entworfen, getestet und analysiert. Aufbauend auf diesen theoretischen Untersuchungen liegt ein weiterer Schwerpunkt dieser Arbeit in der Betrachtung der Einsatzmöglichkeiten von multistabilen Tensegrity-Strukturen in der Greifertechnik. Es werden verschiedene Konzepte für die Entwicklung von Greifern aus diesen Strukturen diskutiert. Zu ausgewählten Konzepten erfolgen weiterführende Betrachtungen, unter anderem durch Einbeziehung dynamischer Analysen. Neben theoretischen Untersuchungen dieser Greifer werden die wichtigsten Erkenntnisse experimentell an Funktionsmustern überprüft und potentielle Einsatzgebiete werden aufgezeigt.The thesis considers tensegrity structures with several stable equilibrium configurations, so-called multistable tensegrity structures. The first part of the thesis is dedicated to the development of algorithms to design, examine and construct multistable tensegrity structures. For that, theoretical results to obtain the different equilibrium configurations of multistable tensegrity structures are derived. Further, methods to design tensegrity structures that have specific properties are investigated. Parameters that characterise these properties are defined. For these tasks optimisation problems are derived and algorithms to solve these problems are developed, tested and analysed. The second part of the thesis builds on these theoretical investigations to consider the application of multistable tensegrity structures in gripper technology. Different concepts to develop multistable tensegrity grippers are discussed. Further investigations, including dynamic analyses, are carried out for selected concepts. In addition to the theoretical considerations, the most important results are tested with development samples of the grippers and potential application fields are revealed