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E-raamat: Integrated Design of Multiscale, Multifunctional Materials and Products

, (Professor of Mechanical Engineering and General Dynamics Faculty Fellow at the University of Texa), , , (Regents Professor and Carter N. Paden, Jr. Distinguished Chair in Metals Processing, Georgia Institute of Technology, Atlanta, GA, USA),
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  • Ilmumisaeg: 30-Sep-2009
  • Kirjastus: Butterworth-Heinemann Ltd
  • Keel: eng
  • ISBN-13: 9780080952208
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Integrated Design of Multiscale, Multifunctional Materials and ProductsSuurem pilt
  • Formaat: PDF+DRM
  • Ilmumisaeg: 30-Sep-2009
  • Kirjastus: Butterworth-Heinemann Ltd
  • Keel: eng
  • ISBN-13: 9780080952208
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Integrated Design of Multiscale, Multifunctional Materials and Products is the first of its type to consider not only design of materials, but concurrent design of materials and products. In other words, materials are not just selected on the basis of properties, but the composition and/or microstructure iw designed to satisfy specific ranged sets of performance requirements. This book presents the motivation for pursuing concurrent design of materials and products, thoroughly discussing the details of multiscale modeling and multilevel robust design and provides details of the design methods/strategies along with selected examples of designing material attributes for specified system performance. It is intended as a monograph to serve as a foundational reference for instructors of courses at the senior and introductory graduate level in departments of materials science and engineering, mechanical engineering, aerospace engineering and civil engineering who are interested in next generation systems-based design of materials.

Arvustused

"Mechanical and materials engineers examine systems strategies for concurrent robust design of materials and systems, along with elements of distributed modeling and simulation environments. They show how several primary disciplines or endeavors that have traditionally been distinct can combine to serve as a foundation of modern materials design. They are systems-based engineering design, computational materials science and engineering, robust system design, and information technology. Among their topics are critical path issues in materials design, decision making in engineering design, mathematical tools for decision making in design, integrated and concurrent design of materials and products, and distributed collaborative design frameworks." --Reference and Research Book News

Muu info

Integrated Design of Multiscale, Multifunctional Materials and Products is the first book of its kind that considers not only materials, but concurrent design of materials and products
Preface ix
Authors xv
About the Authors xvii
Integrated Material, Product, and Process Design---A New Frontier in Engineering Systems Design
1(22)
Motivation for the Integrated Design of Materials and Products
1(3)
Systems-based Multilevel Materials Design
4(7)
Context of Systems-based Materials Design
11(4)
Multilevel Design---Challenges and Approach
15(6)
References
21(2)
Critical Path Issues in Materials Design
23(16)
The Need for Material Models and Databases
23(2)
Characterizing and Managing Uncertainty in Materials Modeling and Design
25(2)
Multiscale Linkage of Material Models in Materials Design
27(2)
A Systems Perspective for Integrated Product, Process, and Materials Design
29(3)
The Need for an Integrated Product-Materials Design Methodology
32(1)
References
33(6)
Overview of the Framework for Integrated Design of Materials, Products, and Design Processes
39(26)
Systems-based Materials Design as a Process
40(2)
Robust Multi-objective Materials Design
42(8)
Managing Complexity in Multilevel Product and Materials Design
50(3)
Computational Framework for Distributed Product and Materials Design
53(3)
Materials Design Examples
56(6)
References
62(3)
Decision Making in Engineering Design
65(22)
Designing---A Goal-oriented Activity
66(8)
Decision-based Design
74(4)
Utility Theory
78(4)
Closing Remarks
82(1)
References
82(5)
Mathematical Tools for Decision Making in Design
87(26)
An Illustrative Example---Integrated Design of Pressure Vessel and Composite Material
88(3)
Selection Decision Support Problem
91(9)
Compromise Decision Support Problem
100(11)
Closing Remarks
111(1)
References
112(1)
Robust Design of Materials---Design Under Uncertainty
113(34)
Uncertainty in Materials Design
114(2)
Examples of Uncertainty in Material Models
116(5)
An Introduction to Robust Design
121(3)
Taguchi Method---Type I Robust Design
124(6)
Robust Concept Exploration Method (RCEM)---Type II Robust Design
130(5)
Requirements for New Types of Robust Design
135(1)
Requirements for New Multilevel Robust Design Methods
135(4)
References
139(8)
Integrated Design of Materials and Products---Robust Topology Design of a Cellular Material
147(32)
Multifunctional Design of Prismatic Cellular Structures
149(6)
Robust Topology Design of Cellular Structures with Processing-induced Imperfections
155(8)
Flexible, Collaborative Design of Prismatic Cellular Combustor Liner Structures
163(10)
Closing Remarks
173(2)
References
175(4)
Integrated Design of Materials and Products---Robust Design Methods for Multilevel Systems
179(62)
Robust Concept Exploration Method with Error Margin Indices (RCEM-EMI)---A Method for Type I, II, and III Robust Design
181(30)
Inductive Design Exploration Method---A Multilevel Robust Design Method
211(25)
Summary of IDEM
236(2)
References
238(3)
Concurrent Design of Materials and Products---Managing Design Complexity
241(72)
Managing Design Complexity
242(6)
Frame of Reference: Multilevel Materials Design
248(4)
Background---Decision Making Under Uncertainty and Value-of-Information
252(6)
Approach for Systems-based Integrated Design of Materials, Products, and Design Processes
258(13)
Utilizing the Improvement Potential for Management of Complexity in Design Processes
271(5)
Application of the Simulation Model Refinement Approach to a Materials Design Problem
276(8)
Applying the Method for Integrated Design of Materials, Products, and Design Processes to the Energetic Material Design Problem
284(3)
Materials and Systems-level Simulation Models for Energetic Material Design
287(11)
Results Using the Stepwise Refinement of Interaction Patterns (Steps 4-9)
298(7)
Closing Remarks
305(3)
References
308(5)
Distributed Collaborative Design Frameworks
313(38)
Frame of Reference---Framework for the Distributed Concurrent Design of Materials and Products
314(4)
Review of Existing Frameworks
318(7)
Motivating Example: Design of Linear Cellular Alloys (LCAs)
325(2)
X-DPR (eXtensible Distributed Product Realization) Environment
327(16)
Closing Remarks: Future Needs
343(2)
References
345(6)
Closure---Advancing the Vision of Integrated Design of Materials and Products
351(10)
References
359(2)
Index 361
Dr. McDowell joined Georgia Tech in 1983 and holds a dual appointment in the Woodruff School of Mechanical Engineering and the School of Materials Science and Engineering. He served as the Director of the Mechanical Properties Research Laboratory from 1992-2012. In 2012 he was named Founding Director of the Institute for Materials (IMat), one of Georgia Techs interdisciplinary Research Institutes charged with fostering an innovative ecosystem for research and education. He has served as Executive Director of IMat since 2013. His research focuses on the development of physically-based, microstructure-sensitive constitutive models for nonlinear and time-dependent behavior of materials, with emphasis on wrought and cast metals. Topics of interest include finite strain inelasticity and defect field mechanics, microstructure-sensitive computational approaches to deformation and damage of heterogeneous materials, with emphasis on metal fatigue, atomistic and coarse-grained atomistic simulations of dislocations, dynamic deformation and failure of materials, irradiation effects on materials, and multiscale modeling with methods for uncertainty quantification. He has contributed to schemes for computational materials science and mechanics to inform systems design of materials. Applications of current interest span lightweight structural materials, materials for hot sections of aircraft gas turbine engines, titanium alloys, ferritic and austenitic alloys, and nanocrystalline materials, among others. Prof. Carolyn Conner Seepersad is a Professor of Mechanical Engineering and General Dynamics Faculty Fellow at the University of Texas at Austin. She received a PhD in Mechanical Engineering from Georgia Tech in 2004, an MA/BA in Philosophy, Politics and Economics from Oxford University in 1998 (as a Rhodes Scholar), and a BS in Mechanical Engineering from West Virginia University in 1996. Dr. Seepersads research involves the development of methods and computational tools for engineering design and additive manufacturing. Her research interests include simulation-based design of complex systems and materials, design for additive manufacturing, innovation, and environmentally conscious design of products and energy systems.
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