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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 黃漢邦(Han-Pang Huang) | |
dc.contributor.author | Ren-Jeng Wang | en |
dc.contributor.author | 王仁政 | zh_TW |
dc.date.accessioned | 2021-05-17T09:20:27Z | - |
dc.date.available | 2012-05-14 | |
dc.date.available | 2021-05-17T09:20:27Z | - |
dc.date.copyright | 2012-05-14 | |
dc.date.issued | 2012 | |
dc.date.submitted | 2012-03-28 | |
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dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/6890 | - |
dc.description.abstract | 本論文主要的目的,在發展不同於傳統工業機器手臂之擬人形機器手臂整合系統。此系統將可安裝於為不同目的而設計的機器人平台上,應用於不同環境中,取代人類或協助人類工作,甚至與人類進行安全的互動行為。
為了研發出一具備上述功能之多自由度擬人形機器手臂整合系統,本論文主要可分為兩大部分。第一部分將著重於模組化2軸驅動系統(DAMA)之機構設計與軟硬體架構建制,並藉由銜接三組該模組化2軸驅動系統,完成一擬人形6軸機器手臂之建置。而有鑑於傳統的致動器,無法同時滿足操作效能與安全互動之需求,本論文的第二部分將討論具安全互動行為機制的致動器與設計準則,提出可以滿足人機安全互動及提升系統效能的主動變剛性彈性驅動系統,並建立具有此特性之系統廣義線性數學模型,且進一步針對此一模型進行分析與控制器設計。最後分別設計製作出APVSEA、AVSEA與ADEA可自行調整輸出特性的主動變剛性彈性驅動器,以分別滿足安全與效能之需求。此設計將可取代傳統致動器,安裝於任一機器人系統上,以提升系統之性能。除擬人形機器手臂整合系統外,本文於最後將額外說明主動變剛性彈性驅動系統另一實質應用-手肘關節復健系統(AVSER)。 未來期許以本論文所發展的主動變剛性彈性驅動器來取代傳統致動器設計,安裝於所設計製作的多自由度擬人形機器手臂上,達到具有高操作效能仍可與人類進行安全的互動行為之設計目標。於復健系統則期許發展多關節手腳復健系統,達到具多關節復健功能之最終目標。 | zh_TW |
dc.description.abstract | This dissertation aims to develop an integrated humanoid robot arm system that can be assembled into robot platforms designed for a variety of purposes, assisting, cooperating, and even interacting with humans in different fields and environments.
The dissertation presents the development of this integrated system in two major parts. The first focuses on developing an integrated system for a vertically intersected dual-axis modularized actuator system (DAMA), which is applied to a 6-axis humanoid robot arm. This section does not carefully consider the safety of human-robot interaction. The second part discusses actuation design, focusing on achieving a proper level of safety in human-robot interaction, and proposes a new actuation approach, active variable stiffness elastic actuation (AVSEA). Several active variable stiffness elastic actuators (APVSEA, AVSEA, ADEA) are designed, offering a compromise between proper safety levels and high manipulation performance. The end section of the dissertation describes another application of active variable stiffness elastic actuators-the elbow rehabilitation system (AVSER). The research discussed involves the creation of a prototype for an active variable stiffness elastic actuator that has adjustable characteristics. It can be adapted to unknown environments and applied to the creation of a humanoid robot arm system that offers high levels of safety and performance. | en |
dc.description.provenance | Made available in DSpace on 2021-05-17T09:20:27Z (GMT). No. of bitstreams: 1 ntu-101-D94522031-1.pdf: 4114571 bytes, checksum: 6124caed1e7d1fa438edccb012ce0e0b (MD5) Previous issue date: 2012 | en |
dc.description.tableofcontents | 摘要 i
Abstract iii List of Tables ix List of Figures xi Nomenclature xv CHAPTER 1. Introduction 1 1.1. Motivation 1 1.2. Overview of the Dissertation 3 1.3. Contributions of the Dissertation 9 CHAPTER 2. Building a Humanoid Robot Arm 13 2.1. Introduction 14 2.2. Mechanical Design of a DAMA 19 2.2.1. The Concept of a DAMA 19 2.2.2. Detailed Structure of a DAMA (High Torque Module) 19 2.2.3. Detailed Structure of a DAMA (Small Size Module) 22 2.3. Simulation System 24 2.3.1. The Independent Joint Control of the DAMA System 24 2.3.2. Control and Simulation of the DAMA System 28 2.4. Finite Element Analysis 31 2.5. Hardware and Software 32 2.6. Experimental Results 33 2.7. Summary 40 CHAPTER 3. Background and Related Work of Inherently Safe Actuating Mechanisms 41 3.1. Introduction 42 3.2. Performance and Safety Constrains 44 3.2.1. Performance Indices 44 3.2.2. Safety Criteria 46 3.3. Pre-existing Compliant and Safety Actuator Design 50 3.3.1. Cable-and-Cylinder Drive Transmissions 50 3.3.2. Series Elastic Actuators (SEA) 51 3.3.3. Programmed Impedance Actuators 53 3.3.4. Variable Stiffness Actuators 54 3.3.5. Parallel Coupled Micro-Macro Actuators (DM2) 56 3.3.6. Antagonistic Pneumatic Artificial Muscle 56 3.3.7. Safe Link Mechanism and Safe Joint Mechanism 57 3.4. Summary 59 CHAPTER 4. APVSEA—An Active-Passive Variable Stiffness Elastic Actuator for Safety Robot Systems 63 4.1. Introduction 64 4.2. Precise Position Movement Actuation / Safe Actuation 65 4.2.1. Motor-Ball screw Drive System 65 4.2.2. Passive Variable Stiffness Serial Configuration 66 4.2.3. Active Variable Stiffness Serial Configuration 67 4.2.4. Active-Passive Variable Stiffness Elastic Actuator (APVSEA) 69 4.3. Design of an Active-Passive Variable Stiffness Elastic Actuator (APVSEA) 71 4.4. System Experiment Evaluation 75 4.4.1. Adaptive Compliant Property 75 4.4.2. Active Variable Stiffness Property 78 4.4.3. Safe Robot System 79 4.5. Summary 80 CHAPTER 5. AVSEA—Active Variable Stiffness Elastic Actuator:Design and Application for Safe Physical Human-Robot Interaction 83 5.1. Introduction 84 5.2. Precise Position Movement Actuation / Safe Actuation 84 5.2.1. Motor-Ball screw Drive System 85 5.2.2. Active Variable Stiffness Serial Configuration 88 5.2.3. Active Variable Stiffness Elastic Actuator (AVSEA) 90 5.3. Design of an Active Variable Stiffness Elastic Actuator 91 5.4. System Experiment Evaluation 96 5.4.1. Adaptive Compliant Property 96 5.4.2. Active Variable Stiffness Property 98 5.4.3. Response to Position Command with Variable Stiffness 98 5.4.4. Head Injury Criterion (HIC) 100 5.5. Summary 102 CHAPTER 6. ADEA—Active Variable Stiffness Differential Elastic Actuator:Design and Application for Safe Robotics 103 6.1. Introduction 104 6.2. General Idea of the Active Variable Stiffness Differential Elastic Actuator (ADEA) 105 6.2.2. Mathematical Description of the Active Variable Stiffness Differential Elastic Actuator (ADEA) 106 6.3. Design, Working Principle and Modeling of the ADEA 108 6.3.1. Mechanical Design and Working Principle 108 6.3.2. Mechanism Modeling of the ADEA System 111 6.3.3. Analysis of the ADEA System 112 6.4. System Experiment Evaluation 114 6.4.1. Adaptive Compliant Property of ADEA 115 6.4.2. Active Variable Stiffness Property of ADEA 117 6.4.3. Response to Position Command with Variable Stiffness 117 6.4.4. Head Injury Criterion (HIC) 119 6.5. Summary 121 CHAPTER 7. Application:Rehabilitation System 123 7.1. Introduction 124 7.2. New Rehabilitation Robot System—Active Variable Stiffness Exoskeleton Robot (AVSER) 128 7.3. Principle and Design of the Active Variable Stiffness Elastic Exoskeleton Robot (AVSER) 130 7.4. System Experiment Evaluation 130 7.5. Summary 137 CHAPTER 8. Conclusions and Future Works 139 8.1. Conclusions 139 8.2. Future Works 140 8.2.1. Active Variable Stiffness Elastic Actuator 141 8.2.2. Humanoid Robot System Design 141 8.2.3. Rehabilitation System 142 8.2.4. Exoskeleton System 142 References 144 | |
dc.language.iso | en | |
dc.title | 變剛性驅動器之發展與應用 | zh_TW |
dc.title | Development and Application of Variable Stiffness Actuators | en |
dc.type | Thesis | |
dc.date.schoolyear | 100-2 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 王國雄,宋震國,范光照,蔡得民,小菅一弘 | |
dc.subject.keyword | 模組化2軸驅動器,擬人形機器手臂,人機安全互動,主動變剛性彈性驅動器,手肘關節復健系統, | zh_TW |
dc.subject.keyword | DAMA,Humanoid Robot Arm,Safety Human-Robot Interaction,Active Variable Stiffness Elastic Actuator,Elbow Rehabilitation System, | en |
dc.relation.page | 154 | |
dc.rights.note | 同意授權(全球公開) | |
dc.date.accepted | 2012-03-29 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 機械工程學研究所 | zh_TW |
顯示於系所單位: | 機械工程學系 |
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