A Practical Guide to Reliable Finite Element Modelling

Alan Morris has recently retired from his post at Cranfield University in the UK as Professor of Structural Analysis. His range of expertise covers the development and application of optimal design and analysis systems, with special emphasis on the finite element methods and structural optimisation programs. Previously, he was a Principal Research Officer in the Royal Aircraft Establishment (now QinetiQ) at Farnborough and was head of the Structures and Optimization Sections at the Advanced Concepts Section.

Preface. Chapter 1. Introduction. 1.1 Aim of the book. 1.2 Finite Element Types - a Brief Overview. 1.3 Finite Element Analysis and Finite Element Representations. 1.4 Multi-Model Analyses. 1.5 Consistency, Logic and Error Control. 1.6 Chapter Contents. Chapter 2 Overview of Static Finite Element Analysis. 2.1 Introduction. 2.2 The Direct Method for Static Analyses. 2.3 Reducing the Problem Size. Chapter 3: Overview of Dynamic Analysis 3.1 Introduction 3.2 Element Mass Matrix. 3.3 Additional Information that can be Extracted to Support a Dynamic Finite Element Analysis. 3.4 Forced Responses. 3.5 Damped Forced Responses. 3.6 Reducing the Problem Size. Chapter 4: What's Energy Got to Do with It? 4.1 Introduction . 4.2 Strain Energy. 4.3 Potential Energy. 4.4 Simple Bar. 4.5 General Case. 4.6 Minimum Potential Energy. 4.7 The Principle of Minimum Potential Energy Applied to a Simple Finite Element Problem. 4.8 Finite Element Formulation. 4.9 Direct Application to an Axial Bar Element. 4.10 Convergence in Energy and Convergence in Stress. 4.11 Results Interpretation. 4.12 Kinetic Energy. 4.13 Final Remark. Chapter 5. Preliminary Review of Errors and Error Control. 5.1 Introduction. 5.2 The Finite Element Process. 5.3 Error and Uncertainty. 5.4 Novelty, Complexity and Experience. 5.5 Role of Testing. 5.6 Initial Steps. 5.7 Analysis Validation Plan (AVP). 5.8 Applied Common Sense. 5.9 The Process. Chapter 6. Discretisation: Elements and Meshes or Some Ways to Avoid Generated Error. 6.1 Introduction. 6.2 Element Delivery. 6.3 Mesh Grading and Mesh Distortion. 6.4 The Accuracy Ladder. Chapter 7. Idealisation Error Types and Sources. 7.1 Design Reduction and Idealisation Errors. 7.2 Analysis Features. 7.3 The Domain. 7.4 Levels of Abstraction. 7.5 Boundary Conditions. 7.6 Material Properties. 7.7 Loads and Masses. Chapter 8. Error Control. 8.1 Introduction. 8.2 Approach and Techniques. 8.3 Accumulation of Errors and Uncertainties. 8.4 The Role of Testing. Chapter 9. Error Controlled Analyses. 9.1 Introduction. 9.2 Is the Finite Element System Fit for Purpose. 9.3 Quality Report. 9.4 The Error and Uncertainty Control Method. Chapter 10 FEMEC Walkthrough Example. 10.1 Introduction. 10.2 FEMEC Static Analysis Illustrative Problem. 10.3 A Brief Look at the Dynamic FEMEC World. Index.