磁場の制御を用いた磁性流体による変形ロボットシートの研究

筑波大学 (University of Tsukuba)201

Simulation and development of paper-based actuators

Soft robots have become an attractive research topic for opening new doors for robots' limitations by being flexible, light, and small and with the ability to have an adaptable shape. An essential component in a soft robot is the soft actuator, which provides the system with a deformable body and allows it to interact with the environment to achieve the desired actuation pattern. Among the various materials used in soft actuators, paper-based actuators have special attention because paper is an abundant, lightweight, and biodegradable material. This work illustrates an insight into the soft actuators field and focuses on developing unique paper-based actuators applying the microwave heat for a liquid-vapor phase transition, in this case, water. This document focuses on the study of different designs, materials, and thick-nesses by changing the paper, elastomer, and double-sided tape.Os robôs flexíveis tornaram-se um tópico de pesquisa atraente por abrirem novas portas para as limitações dos robôs por serem flexíveis, leves e pequenos e com a capacidade de ter uma forma adaptável. Um componente essencial em um robô flexível é o atuador flexível, que fornece ao sistema um corpo deformável e permite que este interaja com o ambiente para atingir o movi-mento desejado. Dos vários materiais usados em atuadores flexíveis, os atuadores baseados em papel têm especial atenção porque o papel é um material abundante, leve e biodegradável. Este trabalho ilustra uma visão da área de atuadores flexíveis e foca no desenvolvimento de atuadores únicos baseados em papel , aplicando o calor de microondas para uma transição de fase líquido-vapor, neste caso, água. Este documento mostra o estudo de diferentes designs, ma-teriais e espessuras, alterando o papel, elastómero e fita dupla-face

Tissue manipulation using nano-particles ferrofluids for minimal access surgical applications

Nano-scale Iron-Oxide ferrofluids exhibit a special property, ‘superparamagnetism’, that induces an attractive force toward an external magnetic field. The aim of this project is to investigate the use of ferrofluids for tissue retraction during Minimally Access Surgery (MAS). In the in-vivo porcine experiments, 0.3 ml of ferrofluid (200 mg/ml concentration) containing 10 nm particles is injected subserosally into the small bowel, respectively. A 0.6 T magnetic field is created using a combination of 10 mm and 20 mm diameter Neodymium Iron Boron magnets. The vertical retraction distance is measured up to 80 mm and video-recorded. The results demonstrate the capacity of ferrofluid to facilitate the tissue manipulation and analysis of the migration of the particles within the tissue using micro computed tomography (CT). A theoretical model developed to validate the experimental results is also beneficial for predicting retraction force. In conclusion, this feasibility study provides a protocol for systematically using small volumes of ferrofluid, without the need to mechanically grasp the tissue

Modular robots for sorting

Current industrial sorting systems allow for low error, high throughput sorts with tightly constrained properties. These sorters, however, are often hardware limited to certain items and criteria. There is a need for more adaptive sorting systems for processes that involve a high throughput of heterogeneous items such as import testing by port authorities, warehouse sorting for online retailers, and sorting recycling. The variety of goods that need to be sorted in these applications mean that existing sorting systems are unsuitable, and the objects often need to be sorted by hand. In this work I detail my design and control of a modular, robotic sorting system using linear actuating robots to create both low-frequency vibrations and peristaltic waves for sorting. The adaptability of the system allows for multimodal sorting and can improve heterogeneous sorting systems. I have designed a novel modular robot called the Linbot. These Linbots are based on an actuator design utilising a voice coil for linear motion. I designed this actuator to be part of a modular robot by adding on-board computation, sensing and communication. I demonstrate the individual characteristics of these robots through a series of experiments in order to give a comprehensive overview of their abilities. By combining multiple Linbots in a collective I demonstrate their ability to move and sort objects using cooperative peristaltic motion. In order to allow for rapid optimisation of control schemes for Linbot collectives I required a peristaltic table simulator. I designed and implemented a peristaltic table simulator, called PeriSim, due to a lack of existing solutions. Controllers optimised in simulation often suffer from a reduction in performance when moved to a real-world system due to the inaccuracies in the simulation, this effect is called the reality gap. I used a method for reducing the reality gap called the radical envelope of noise hypothesis, whereby I only modelled the key aspects of peristalsis in PeriSim and then varied the underlying physics of the simulation between runs. I used PeriSim to optimise controllers in simulation that worked on a real-world system. I demonstrate the how the Linbots and PeriSim can be used to build and control an adaptive sorter. I built an adaptive sorter made of a 5x5 grid of Linbots with a soft sheet covering them. I demonstrate that the sorter can grade produce and move objects of varying shapes and sizes. My work can guide the future design of industrial adaptive sorting systems

NASA Tech Briefs, March 1992

Topics include: New Product Ideas; Electronic Components and Circuits; Electronic Systems; Physical Sciences; Materials; Computer Programs; Mechanics; Machinery; Fabrication Technology; Mathematics and Information Sciences; Life Sciences

Distributed manipulation by controlling force fields through arrays of actuators

Tato práce se zaměřuje na řízení distribuované manipulace prostřednictvím fyzikálních polí vytvářených maticí akčních členů. Práce se zabývá především manipulací s objekty pomocí nehomogenního elektrického a magnetického pole - dielektroforézou a magnetoforézou. Pro oba principy jsou odvozeny matematické modely vhodné pro začlenění do zpětnovazební řídicí smyčky. Modely mají v obou doménách podobnou strukturu, která dovoluje vývoj jednotného řídicího systému. Nelineární model dynamiky systému je v každé vzorkovací periodě invertován pomocí numerického řešení optimalizačního problému. Výhodou navržené strategie řízení je, že dovoluje paralelní manipulaci - nezávislou manipulaci s několika objekty najednou. Práce vedle teoretických konceptů popisuje také technické detaily experimentálních platforem spolu s výsledky mnoha experimentů. Pro dielektroforézu je navrženo nové uspořádání elektrod, které umožňuje manipulaci s více objekty v rovině a zároveň vyžaduje pouze jednovrstvou výrobní technologii. Na algoritmické straně práce představuje nové použití fázové modulace napětí pro řízení dielektroforézy. Dále také popisuje součásti vyvinuté instrumentace, jako jsou vícekanálové generátory pro řízení dielektroforézy prostřednictvím amplitudové a fázové modulace a optické měření polohy v reálném čase pomocí senzoru bez objektivu. Pro magnetoforézu je detailně popsána modulární experimentální platforma sestávající se z pole cívek se železnými jádry. Díky modularitě může být platforma použita k ověření nejen centralizovaných, ale také distribuovaných řídicích systémů.This work focuses on the control of distributed manipulation through physical fields created by arrays of actuators. In particular, the thesis addresses manipulation of objects using non-uniform electric and magnetic fields---dielectrophoresis and magnetophoresis, respectively. In both domains, mathematical models suitable for incorporation into a feedback control loop are derived. The models in the two domains exhibit a similar structure, which encourages the development of a unified approach to control. The nonlinear model of the system dynamics is inverted by solving a numerical optimization problem in every sampling period. A powerful attribute of the proposed control strategy is that a parallel manipulation---the simultaneous and independent manipulation of several objects---can be demonstrated. Besides the theoretical concepts, the thesis also describes technical details of experimental platforms for both physical domains, together with outcomes from numerous experiments. For dielectrophoresis, a new layout of electrodes is documented that allows full planar manipulation while requiring only a one-layer fabrication technology. On the algorithmic side, work presents a novel use of phase modulation of the voltages to control dielectrophoresis. Dedicated instrumentation is also discussed in the thesis such as multichannel generators for control of dielectrophoresis through amplitude and phase modulation and optical real-time position measurements using common optics and a lensless sensor. For magnetophoresis, a modular test bed composed of a planar array of coils with iron cores is described in detail. Thanks to the modularity, the platform can be used for verification of not only the centralized but also distributed control strategies

An overview of novel actuators for soft robotics

In this systematic survey, an overview of non-conventional actuators particularly used in soft-robotics is presented. The review is performed by using well-defined performance criteria with a direction to identify the exemplary and potential applications. In addition to this, initial guidelines to compare the performance and applicability of these novel actuators are provided. The meta-analysis is restricted to five main types of actuators: shape memory alloys (SMAs), fluidic elastomer actuators (FEAs), shape morphing polymers (SMPs), dielectric electro-activated polymers (DEAPs), and magnetic/electro-magnetic actuators (E/MAs). In exploring and comparing the capabilities of these actuators, the focus was on eight different aspects: compliance, topology-geometry, scalability-complexity, energy efficiency, operation range, modality, controllability, and technological readiness level (TRL). The overview presented here provides a state-of-the-art summary of the advancements and can help researchers to select the most convenient soft actuators using the comprehensive comparison of the suggested quantitative and qualitative criteria