Process modeling in composites manufacturing

There is a wealth of literature on modeling and simulation of polymer composite manufacturing processes. However, existing books neglect to provide a systematic explanation of how to formulate and apply science-based models in polymer composite manufacturing processes. Process Modeling in Composites Manufacturing, Second Edition provides tangible methods to optimize this process - and it remains a proven, powerful introduction to the basic principles of fluid mechanics and heat transfer. Includes tools to develop an experience base to aid in modeling a composite manufacturing process Building on past developments, this new book updates the previous edition's coverage of process physics and the state of modeling in the field. Exploring research derived from experience, intuition, and trial and error, the authors illustrate a state-of-the-art understanding of mass, momentum, and energy transfer during composites processing. They introduce computer-based solutions using MATLAB (R) code and flow simulation-based analysis, which complement closed-form solutions discussed in the book, to help readers understand the role of different material, geometric, and process parameters. This self-contained primer provides an introduction to modeling of composite manufacturing processes for anyone working in material science and engineering, industrial, mechanical, and chemical engineering. It introduces a scientific basis for manufacturing, using solved example problems which employ calculations provided in the book. End-of-chapter questions and problems and fill in the blanks sections reinforce the content in order to develop the experience base of the manufacturing, materials, and design engineer or scientists, as well as seniors and first-year graduate students.

Introduction Motivation and Contents Preliminaries Polymer Matrices for Composites Fibers Classification General Approach to Modeling Organization of the Book Overview of Manufacturing Processes Background Classification Based on Dominant Flow Process Short Fiber Suspension Manufacturing Methods Advanced Thermoplastic Manufacturing Methods Advanced Thermoset Composite Manufacturing Methods Transport Equations for Composite Processing Introduction to Process Models Conservation of Mass (Continuity Equation) Conservation of Momentum (Equation of Motion) Stress-Strain Rate Relationship Examples to Solve Viscous Flow Problems Conservation of Energy Constitutive Laws and Their Characterization Resin Viscosity Viscosity of Aligned Fiber Thermoplastic Laminates Suspension Viscosity Reaction Kinetics Thermoplastic Reactive Processing Crystallization Kinetics Permeability Fiber Stress Model Simplifications and Solution Formulation of Models Model and Geometry Simplifications Dimensionless Analysis and Dimensionless Numbers Customary Assumptions in Polymer Composite Processing Boundary Conditions for Flow Analysis Convection of Variables Process Models from Simplified Geometries Mathematical Tools for Simplification Solution Methods Numerical Methods Validation Short Fiber Composites Compression Molding Extrusion Injection Molding Exercises Advanced Thermoplastic Manufacturing Processes Composite Sheet Forming Processes Pultrusion Thermal Model Online Consolidation of Thermoplastics Processing Advanced Thermoset Fiber Composites Autoclave Molding Liquid Composite Molding Filament Winding of Thermosetting Matrix Composites Summary and Outlook MATLAB Files Solution to Example 8.13 using FDM Additional Examples with LIMS to Model Liquid Mold Filling Bibliography Index