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9781846288012

Collaborative Product Design and Manufacturing Methodologies and Applications

by ; ; ;
  • ISBN13:

    9781846288012

  • ISBN10:

    1846288010

  • Format: Hardcover
  • Copyright: 2007-04-30
  • Publisher: Springer Verlag
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Summary

Recently, there have been major innovations and paradigm shifts in product design methodologies and systems. The current R&D trend is the development of collaborative design and manufacturing methodologies and systems. Using a collaborative product development system, designers can participate in global design chains and collaborate with each other and overseas partners to pursue competitive advantages. It also allows designers to work closely with suppliers, manufacturing partners and customers across enterprise firewalls to obtain valuable inputs for their designs. Collaborative Product Design and Manufacturing Methodologies and Applications is an introduction to a wide spectrum of collaborative engineering issues in design and manufacturing. It contains state-of-the-art chapters written by international experts from academia and industry and reflects the most up-to-date R&D work and applications, especially those from the last three to five years. Collaborative Product Design and Manufacturing Methodologies and Applications is an essential reference for academics, upper-level undergraduate and graduate students and practitioners specialising in collaborative design and manufacturing issues, concurrent engineering, Internet-based/intelligent design and manufacturing, CAD/PDM/CAPP/CAM, Internet applications, product lifecycle management, supply chain, etc.

Author Biography

W.D. Li is a research fellow at the IMRC (Innovative Manufacturing Research Centre) at the University of Bath, UK. His research interests include collaborative product design and manufacturing, application of intelligent technologies in product design and manufacturing. CAD/CAPP/CAM, 3D geometric and feature-based modeling and applications, and design methodologies. In these areas, he has led various research and industrial projects as principal investigator or co-principal investigator.S.K. Ong is an associate professor in the Department of Mechanical Engineering at the National University of Singapore. Her research interests are intelligent and distributed manufacturing systems, computer-aided set-up planning, life cycle engineering, environment impact assessment, and virtual and augmented reality applications in manufacturing. In 2004, she received the M. Eugene Merchant Outstanding Young Manufacturing Engineer Award from the Society of Manufacturing Engineers. She was also a recipient of the 2004 Singapore Youth Award in the Science and Technology category.Andrew Y.C. Nee is a professor of manufacturing engineering in the Department of Mechanical Engineering at the National University of Singapore (NUS), and the Director of the Office of Research at the NUS. His research interests are computer applications for tool, die, fixture design and planning; intelligent and distributed manufacturing systems; and, virtual and augmented reality applications in manufacturing. He is an active member of CIRP and an elected Fellow of the Society of Manufacturing Engineers.Chris McMahon is a professor of engineering design in the Department of Mechanical Engineering at the University of Bath, UK, where he is an active teacher and researcher in engineering design and manufacture. He is also Director of the Bath Engineering Innovative Manufacturing Research Centre (IMRC), a center of excellence for research in design and manufacture funded by the UK's Engineering and Physical Sciences Research Council, and comprising some 35 researchers working in a variety of research topics in design technologies, design information and knowledge management, and manufacturing processes and systems. His research interests include computer-aided design, engineering information management, risk and uncertainty in design, design process improvement, design for remanufacturing, and design for fatigue.

Table of Contents

An Adaptable Service-based Framework for Distributed Product Realizationp. 1
Introductionp. 2
Need for an Adaptable Frameworkp. 3
An Open Engineering Systems Approachp. 3
Requirements and Features of an Adaptable Frameworkp. 4
Review of Capabilities Provided by Existing Frameworksp. 8
Web-based Systemsp. 8
Agent-based Systemsp. 10
Distributed Object-based Modeling and Evaluation (DOME)p. 13
NetBuilderp. 13
Web-DPRp. 14
Federated Intelligent Product EnviRonment (FIPER)p. 14
Motivating Example: Design of Linear Cellular Alloys (LCAs)p. 15
X-DPR (eXtensible Distributed Product Realization) Environmentp. 17
Overview of X-DPRp. 17
Elements of the Frameworkp. 18
Data Repositoryp. 20
Process Diagram Toolp. 21
Dynamic UI Generationp. 23
Interface Mapping Toolp. 24
Messaging and Agent Description in X-DPRp. 26
Publishing a Servicep. 26
Asset Search Servicep. 26
Using the X-DPR framework for LCAs designp. 27
X-DPR as an Adaptable Frameworkp. 28
Conclusionsp. 30
Acknowledgmentsp. 32
Referencesp. 32
A Web-based Intelligent Collaborative System for Engineering Designp. 37
Introductionp. 37
Related Workp. 38
Current State-of-the-art on Computer-aided Collaborative Engineering Design Systemsp. 38
Current State-of-the-art on Argumentation-based Conflict Resolutionp. 39
A Web-based Intelligent Collaborative Engineering Design Environment and Its Application Scenariosp. 40
Argumentation-based Conflict Resolution in the Collaborative Engineering Design Environmentp. 40
Structured Argumentation Through Dialog Graphp. 42
Argument Reduction Through Fuzzy Inferencep. 43
Linguistic Variable Through Fuzzy Membership Functionsp. 45
Fuzzy Inference Rulesp. 46
Fuzzy System and Defuzzificationp. 47
Structured Argumentation Through Dialog Graphp. 49
Design and Implementationp. 49
An Application Examplep. 50
Conclusionsp. 56
Acknowledgementsp. 56
Referencesp. 57
A Shared VE for Collaborative Product Development in Manufacturing Enterprisesp. 59
Introductionp. 59
Backgroundp. 60
Building the Shared VEp. 61
Virtual Environment Functionalityp. 63
Virtual Prototyping Functionp. 63
Behavioral Simulation Functionp. 63
Assembly Support Functionp. 64
Collision Detection Functionp. 65
Pilot Applicationp. 65
Conclusions and Future Researchp. 67
Acknowledgementsp. 68
Referencesp. 68
A `Plug-and-Play' Computing Environment for an Extended Enterprisep. 71
Introductionp. 71
Related Researchp. 72
Application Develoment Frameworkp. 75
Geometric Modeling Middleware Servicesp. 77
Modeling Functionsp. 77
Geometric Data XML Filep. 79
Application Relationship Manager (ARM)p. 80
Process Data Exchange Middleware Servicesp. 83
Reusable Application Classesp. 84
Illustrative Case Studyp. 84
Conclusionsp. 89
Referencesp. 90
Cooperative Design in Building Constructionp. 93
Introductionp. 93
System Architecture and Componentsp. 95
The Cooperative 3D Editorp. 96
The Cooperative Support Platformp. 98
The Integrated Design Project Databasep. 98
Considerations and Implementation for Collaborative Designp. 99
Interoperative and Multi-disciplinaryp. 99
The On-line Cooperative Workingp. 101
Design Error Detection During Integrationp. 102
System Evaluationp. 103
Conclusionsp. 106
Acknowledgementsp. 107
Referencesp. 107
A Fine-grain and Feature-oriented Product Database for Collaborative Engineeringp. 109
Introductionp. 109
Generic Feature Modelp. 112
Feature Shape Representationp. 113
Constraint Definitionp. 113
Other Feature Propertiesp. 114
Member Functionsp. 115
Application-specific Feature Modelp. 116
Mapping Mechanismsp. 116
Mapping from Extended EXPRESS Model to ACIS Workform Formatp. 117
Geometry Mappingp. 117
Generic Feature Definition Under ACIS Frameworkp. 118
Database Representation Schemap. 119
The Integration of Solid Modeler and Databasep. 119
Feature Model Re-evaluation and Constraint Solvingp. 120
Save Algorithmp. 121
Restore Algorithmp. 122
Feature Model Re-evaluationp. 122
Problems of Historical-dependent Systemp. 122
Dynamically Maintaining Feature Precedence Orderp. 124
History-independent Feature Model Re-evaluationp. 125
Adding a New Feature Instancep. 125
Deleting a Feature Instancep. 126
Modifying a Feature Instancep. 130
B-rep Evaluationp. 130
A Case Studyp. 130
Conclusionsp. 133
Acknowledgementsp. 134
Referencesp. 134
A Web-based Framework for Distributed and Collaborative Manufacturingp. 137
Introductionp. 137
Distributed and Collaborative Manufacturingp. 139
Proposed Framework and Implementationp. 140
A Case Studyp. 142
Conclusionsp. 148
Referencesp. 148
Wise-ShopFloor: A Portal toward Collaborative Manufacturingp. 151
Introductionp. 151
Enabling Technologiesp. 152
Wise-ShopFloor Frameworkp. 153
Adaptive Process Planning and Schedulingp. 155
Architecture Designp. 155
Machining Process Sequencingp. 156
Function Block Design And Utilizationp. 158
Shop Floor Integrationp. 163
Web-based Real-time Monitoring and Controlp. 164
System Configurationp. 164
Sensor Data Collection for Real-Time Monitoringp. 165
Data Packet Formatp. 167
Java 3D Enabled Visualizationp. 167
Web-based Remote CNC Controlp. 169
A Case Studyp. 169
Conclusionsp. 172
Acronymsp. 173
Referencesp. 174
Real Time Distributed Shop Floor Scheduling: An Agent-Based Service-Oriented Frameworkp. 175
Introductionp. 175
Scheduling Problems in Multiple Workcell Shop Floorp. 176
Workcell Scheduling Problemp. 177
Dynamic Scheduling Problemp. 179
Distributed Scheduling Problemp. 180
Scheduling Algorithms for Multiple Workcell Shop Floorp. 181
Workcell Scheduling Algorithmp. 182
Dynamic Scheduling Algorithmp. 183
Distributed Scheduling Algorithmp. 185
Agent-Based Service-Oriented System Integrationp. 187
System Overviewp. 188
Dynamic Scheduling Algorithmp. 189
Scheduler Agent Designp. 190
Coordination between Scheduler Agent and Real Time Controller Agentp. 191
Coordination between Scheduling Servicesp. 192
System Implementationp. 194
A Case Studyp. 194
Conclusionsp. 195
Referencesp. 197
Leveraging Design Process Related Intellectual Capital - A Key to Enhancing Enterprise Agilityp. 201
Design Processes - An Enterprise's Fundamental Intellectual Capitalp. 202
Examples of Design Process Scenariosp. 204
Description of LCAs design problemp. 205
LCAs design process strategiesp. 206
Strategy 1: Sequential Design - Thermal Firstp. 206
Strategy 2: Sequential Design - Structural Firstp. 207
Strategy 3: Set-based Designp. 207
Strategy 4: Use of Surrogate Modelsp. 207
Strategy 5: Parallel Iterative Designp. 208
Requirements and Critical Issues for Leveraging Design Process Related Intellectual Capitalp. 209
Support for Design Information Transformationsp. 209
Support for Design Decision-makingp. 210
Modeling and Representation of Design Processesp. 210
Analyzing Design Processesp. 211
Synthesizing Design Processesp. 211
Research Issues and Strategies for Designing Design Processesp. 212
Modeling Design Processesp. 214
Research Issuep. 214
Previous Workp. 214
Research Questionsp. 214
Strategy: a Decision-centric Approachp. 214
Computational Representations for Design Processesp. 216
Research Issuep. 216
Previous Workp. 216
Research Questionsp. 217
Strategy: Separating Declarative Information from Procedural Informationp. 217
Storage of Design Informationp. 218
Research Issuep. 218
Previous Workp. 218
Research Questionsp. 219
Strategy: Process Templatesp. 219
Developing metrics for assessing design processesp. 220
Research Issuep. 220
Previous Workp. 221
Research Questionsp. 221
Strategy: Process Templatesp. 221
Configuring Design Processesp. 222
Research Issuep. 222
Previous Workp. 222
Research Questionsp. 222
Strategy: Process Familiesp. 223
Configuring Design Processesp. 223
Research Issuep. 223
Previous Workp. 224
Research Questionsp. 224
Strategy: Identifying Process Decisionsp. 224
Integrating Design Processes with Other Processes in PLMp. 225
Research Issuep. 225
Previous Workp. 225
Research Questionsp. 226
Strategy: a Decision-centric Approachp. 226
Conclusionsp. 227
Acknowledgmentsp. 228
Referencesp. 228
Manufacturing Information Organization in Product Lifecycle Managementp. 235
Introductionp. 235
Information and Knowledge Infrastructures for Manufacturep. 236
Context Awareness: Its Significance for Information Organizationp. 239
Product Contextp. 239
Life Cycle Contextp. 241
Context Relationshipsp. 242
Exploiting Manufacturing Standardsp. 246
STEP for Manufacturingp. 246
Mandate - Resource, Time And Flow Modelsp. 247
Process Specification Languagep. 248
Exploiting Product and Process Knowledge in Futurep. 249
Conclusionsp. 251
Referencesp. 252
Semantic Interoperability to Support Collaborative Product Developmentp. 255
Introductionp. 255
Semantic Interoperability Concepts and Technologiesp. 257
Data-driven Interoperability Standardp. 258
Ontologiesp. 258
Product Modelsp. 260
Product Semantics Capturing and STEP Extension Modelingp. 263
Representing Semantics in Supplementary Information Modelsp. 263
Embedding Supplementary Information in CAD Modelsp. 264
Modeling STEP Extensionsp. 265
Capturing Semantics in STEP-compliant Product Modelsp. 266
Taxonomy and Ontologyp. 267
Vocabulary Taxonomyp. 267
OWL Ontologyp. 268
Semantics-driven Schema Mappingp. 270
Software Prototype Developmentp. 272
Software System Architecturep. 272
Client Toolkitsp. 273
Collaboration Server Components and Servicesp. 276
Collaboration Scenariosp. 278
Support of Collaborative Design Processp. 278
Design Objects Modeling and Semantics Capturingp. 279
Semantics Sharing with Heterogeneous Systemsp. 281
Conclusionsp. 283
Acknowledgementsp. 284
Acronymsp. 284
Referencesp. 284
A Proposal of Distributed Virtual Factory for Collaborative Production Managementp. 287
Introductionp. 287
Distributed Virtual Factoryp. 288
Conceptp. 288
Structurep. 289
Time Bucket Mechanismp. 289
Cost Analysisp. 291
Cost Analysis In Manufacturing Systemsp. 291
Activity Based Costing (ABC)p. 291
DVF and ABCp. 292
Manufacturing Modelp. 292
Formulations for Costp. 292
Experimental Resultsp. 297
Simulation Modelp. 297
Total Factory Management in DVFp. 297
Cost Analysysp. 300
Conclusionsp. 301
Referencesp. 303
Indexp. 305
Table of Contents provided by Publisher. All Rights Reserved.

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