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• Title:Product performance evaluation using CAD/CAE / Kuang-Hua Chang.
  
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• Author/Creator:Chang, Kuang-Hua, 1960-
  
• Published/Created:Oxford : Academic, 2013.
  

• Holdings

  Holdings Record Display

  • Location:WOODWARD LIBRARY stacksWhere is this?
    
  • Call Number: TA174 .C43 2013
    
  • Number of Items:1
    
  • Status:Available
    
  • Links:Donor bookplate
    

   
• Library of Congress Subjects:Engineering design--Computer-aided design.
  Engineering design--Computer-aided design--Case studies.
  
• Description:xix, 543 p. : ill. ; 24 cm.
  
• Series:Computer aided engineering design series.
  
• Summary:This is one book of a four-part series, which aims to integrate discussion of modern engineering design principles, advanced design tools, and industrial design practices throughout the design process. Through this series, the reader will: Understand basic design principles and modern engineering design paradigms; Understand CAD/CAE/CAM tools available for various design related tasks; Understand how to put an integrated system together to conduct product design using the paradigms and tools; Understand industrial practices in employing virtual engineering design and tools for product development.
  
• Notes:Includes bibliographical references and index.
  
• ISBN:9780123984609 (hbk.)
  0123984602 (hbk.)
  
• Contents:Machine generated contents note: ch. 1 Introduction to e-Design
  1.1. Introduction
  1.2. e-Design Paradigm
  1.3. Virtual Prototyping
  1.3.1. Parameterized CAD Product Model
  1.3.2. Product Performance Analysis
  1.3.3. Product Virtual Manufacturing
  1.3.4. Tool Integration
  1.3.5. Design Decision Making
  1.4. Physical Prototyping
  1.4.1. Rapid Prototyping
  1.4.2. CNC Machining
  1.5. Example: Simple Airplane Engine
  1.6. Example: High-Mobility Multipurpose Wheeled Vehicle
  1.7. Summary
  Questions and Exercises
  References
  Sources
  ch. 2 Structural Analysis
  2.1. Introduction
  2.2. Analytical Methods
  2.2.1. Strength of Materials
  2.2.2. Energy Method
  2.2.3. Linear Elasticity
  2.2.4. Failure Criteria
  2.2.5. Uncertainties, Variations, and Safety Factors
  2.3. Finite-Element Methods
  2.3.1. Simple Example
  2.3.2. Finite-Element Formulation
  2.3.3. p-Version FEA
  2.3.4. Meshless Method
  2.3.5. Using the Finite-Element Method
  2.4. Finite-Element Modeling
  2.4.1. General Process and Potential Pitfalls
  2.4.2. Idealization and Simplification
  2.4.3. Mesh Generation and Refinement
  2.4.4. CAD Model Translations
  2.4.5. Loads and Boundary Conditions
  2.4.6. Results Checking
  2.4.7. Strategy for Complex Problems
  2.5. Commercial FEA Software
  2.5.1. General-Purpose Codes
  2.5.2. Specialized Codes
  2.6. Case Study and Tutorial Examples
  2.6.1. Case Study
  2.6.2. Tutorial Examples
  2.7. Summary
  Questions and Exercises
  References
  Sources
  Appendix: The Default in.-1bm-sec Unit System
  ch. 3 Motion Analysis
  3.1. Introduction
  3.2. Analytical Methods
  3.2.1. Particle Motion
  3.2.2. Rigid-Body Motion
  3.2.3. Multibody Kinematic Analysis
  3.2.4. Multibody Dynamic Analysis
  3.3. Computer-Aided Methods
  3.3.1. Kinematic Analysis
  3.3.2. Kinematic Joints
  3.3.3. Multibody Dynamic Analysis
  3.4. Motion Simulation
  3.4.1. Creating Motion Models
  3.4.2. Motion Analysis
  3.4.3. Results Visualization
  3.5. Motion Simulation Software
  3.5.1. General-Purpose Codes
  3.5.2. Specialized Codes
  3.6. Case Studies
  3.6.1. Formula SAE Racecar
  3.6.2. High-Mobility Multipurpose Wheeled Vehicle
  3.6.3. Driving Simulators
  3.6.4. Recreational Waterslides
  3.7. Tutorial Examples
  3.7.1. Sliding Block
  3.7.2. Single-Piston Engine
  3.8. Summary
  Questions and Exercises
  References
  Sources
  ch. 4 Fatigue and Fracture Analysis
  4.1. Introduction
  4.2. Physics of Fatigue
  4.3. Stress-Life Approach
  4.3.1. S-N Diagram
  4.3.2. Nonfully Reversed Cyclic Loads
  4.3.3. In-Phase Bending and Torsion
  4.3.4. Complex Multiaxial Stress
  4.3.5. Cumulative Damage
  4.4. Strain-Based Approach
  4.4.1. Manson-Coffin Equation
  4.4.2. Multiaxial Analysis
  4.5. Fracture Mechanics
  4.5.1. Basic Approaches
  4.5.2. Linear Elastic Fracture Mechanics
  4.5.3. Mixed Mode
  4.5.4. Quasistatic Crack Growth
  4.5.5. Extended Finite Element Method
  4.6. Dynamic Stress Calculation and Cumulative Damage
  4.6.1. Dynamic Stress Calculations
  4.6.2. Peak-Valley Editing
  4.6.3. Rain-Flow Counting
  4.6.4. Blocks to Failure
  4.7. Fatigue and Fracture Simulation Software
  4.7.1. General-Purpose Codes for Crack Initiation
  4.7.2. Non-FEA-Based Crack Propagation
  4.7.3. FEA-Based Crack Propagation
  4.8. Case Studies and Tutorial Example
  4.8.1. Case Study: Tracked Vehicle Roadarm
  4.8.2. Case Study: Engine Connecting Rod
  4.8.3. Tutorial Example: Crankshaft
  4.9. Summary
  Questions and Exercises
  References
  Sources
  ch. 5 Reliability Analysis
  5.1. Introduction
  5.2. Probability of Failure
  Basic Concepts
  5.2.1. Deterministic Design versus Probabilistic Prediction
  5.2.2. Probabilistic Design
  5.2.3. Short Summary
  5.3. Basics of Statistics and Probabilistic Theory
  5.3.1. Events and Basic Probability Rules
  5.3.2. Random Variables and Distribution Functions
  5.3.3. Probabilistic Distributions
  5.4. Reliability Analysis Methods
  5.4.1. Limit State Function
  5.4.2. Monte Carlo Simulation
  5.4.3. First-Order Reliability Method
  5.4.4. Second-Order Reliability Method
  5.4.5. Transformation of Random Variables
  5.4.6. Importance Sampling
  5.4.7. Response Surface Method
  5.4.8. Short Summary
  5.5. Multiple Failure Modes
  5.5.1. Series System
  5.5.2. Parallel System
  5.5.3. FORM Approximation for a Series System
  5.6. General-Purpose Reliability Analysis Tools
  5.7. Case Study
  5.8. Summary
  Questions and Exercises
  References
  Sources.