This book presents the mathematics behind the formulation, approximation, and numerical analysis of contact and friction problems. It also provides a survey of recent developments in the numerical approximation of such problems as well as several remaining unsolved issues. Particular focus is placed on the Signorini problem and on frictionless unilateral contact in small strain. The final chapters cover more complex, applications-oriented problems, such as frictional contact, multi-body contact, and large strain.
Finite Element Approximation of Contact and Friction in Elasticity will be a valuable resource for researchers in the area. It may also be of interest to those studying scientific computing and computational mechanics.
Author(s): Franz Chouly, Patrick Hild, Yves Renard
Series: Advances in Mechanics and Mathematics, 48
Publisher: Birkhäuser
Year: 2023
Language: English
Pages: 305
City: Basel
Preface
Acknowledgments
Contents
Acronyms
Notations
Part I Basic Concepts
1 Introduction
1.1 An Overview of the Content
1.2 Prerequisites
1.3 An Informal Presentation of the Methods
1.3.1 The Signorini Problem
1.3.2 Some Numerical Approximations for Signorini Contact
1.4 How to Use This Book
2 Sobolev Spaces
2.1 Distributions
2.1.1 Continuous and Differentiable Functions
2.1.2 Test Functions
2.1.3 Distributions and Distributional Derivatives
2.1.4 Regular Distributions and Dirac Distribution
2.1.5 Distributional Gradient and Divergence
2.1.6 Level Sets of Locally Integrable Functions
2.2 Fractional Order Sobolev Spaces
2.2.1 Square-Integrable Functions
2.2.2 Sobolev Spaces of Fractional Order
2.2.3 The Slobodeckij Semi-norm
2.2.4 Some Useful Properties
2.3 Lipschitz Domains
2.3.1 A First Definition Using Lipschitz Hypographs
2.3.2 Examples and Counterexamples of Lipschitz Domains
2.3.3 Bi-Lipschitz Homeomorphisms
2.3.4 Lipschitz Domains as a Collection of Lipschitz Mappings
2.3.5 Partition of Unity for a Lipschitz Boundary
2.3.6 Sobolev Spaces on the Boundary
2.3.7 Sobolev Spaces on a Part of the Boundary
2.3.8 Other Density Theorems
2.3.9 The Slobodeckij Semi-norm, Once Again
2.3.10 Domains with Smoother Boundary
2.4 Trace and Lifting Operators
2.4.1 The Trace on a Hyperplane
2.4.2 The Trace on a Lipschitz Boundary
2.4.3 The Lifting Operator
2.4.4 First Consequences of Trace and Lifting Theorems
2.5 Green Formulas
2.5.1 Preliminaries
2.5.2 Green Formulas
2.5.3 Green Formulas on a Part of the Boundary
2.6 Polynomial Approximation in Fractional Sobolev Spaces
2.6.1 A Fractional Poincaré-Friedrichs Inequality
2.6.2 Fractional Deny–Lions Lemma
2.7 Further Comments
2.7.1 Distributions and Sobolev Spaces
2.7.2 Lipschitz Boundaries, Traces and Green Formulas
2.7.3 Deny–Lions Lemma
2.7.4 Differential Operators
3 Signorini's Problem
3.1 Presentation
3.1.1 The Domain and Its Boundaries
3.1.2 Small Strain Elasticity
3.1.3 The Nonpenetration Condition
3.1.4 A First Formulation of Signorini's Problem
3.2 Weak Form and Contact Conditions
3.2.1 The Weak Formulation for Signorini's Problem
3.2.2 Displacement and Stress on the Contact Boundary
3.2.3 Green Formula in Elasticity
3.2.4 Contact Conditions and Strong Form of Signorini
3.3 Well-posedness
3.3.1 Ellipticity of the Bilinear Form
3.3.2 The Well-posedness Result
3.4 Regularity
3.4.1 Global Regularity of the Solution
3.4.2 Binding/Nonbinding Transitions on the Contact Set
3.5 Further Comments
3.5.1 About Signorini Contact
3.5.2 About the Second Korn Inequality
4 Lagrange Finite Elements and Interpolation
4.1 Lagrange Finite Elements on Simplices
4.1.1 Simplicial Meshes
4.1.2 Lagrange Finite Elements
4.1.3 Conformity
4.1.4 Basis of Shape Functions
4.1.5 The Reference Element
4.2 Some Basic Interpolation Estimates
4.2.1 The Lagrange Interpolation Operator
4.2.2 Lagrange Interpolation on the Boundary
4.2.3 Estimates for Lagrange Interpolation
4.3 Other Useful Results
4.3.1 Interpolation Estimate for the Gradient on the Boundary
4.3.2 Some Discrete Inverse Inequalities
4.3.3 Discrete Liftings
4.3.4 Properties of Projection Operators
4.4 Further Comments
4.4.1 FEM and Lagrange FEM
4.4.2 Other Approximation Methods
Part II Numerical Approximation for Signorini
5 Finite Elements for Signorini
5.1 Preliminaries
5.1.1 Finite Element Spaces
5.1.2 A Discrete Variational Inequality
5.1.3 A Preliminary Error Estimate
5.2 Finite Element Approximation with Various Cones
5.2.1 The Convex Cones for Linear Lagrange Finite Elements
5.2.2 The Convex Cones for Quadratic Lagrange Finite Elements
5.2.3 The Discrete Problems
5.2.4 An Abstract Lemma
5.3 Error Analysis in the Two-Dimensional Case
5.3.1 Some Local Estimates for the Contact Stress and the Normal Displacement
5.3.2 Error Analysis for Linear Finite Elements
5.3.2.1 Conforming Approximation
5.3.2.2 Nonconforming Approximation
5.3.3 Error Analysis for Quadratic Finite Elements
5.3.3.1 Sobolev Regularity 3/2 < s < 5/2
5.3.3.2 Sobolev Regularity s=5/2
5.4 Error Analysis in the Three-Dimensional Case
5.4.1 Extreme Points and New Discrete Convex Cones
5.4.2 Main Results
5.4.3 A Quasi-Interpolation Operator
5.4.4 Error Analysis for Linear Finite Elements
5.4.5 Error Analysis for Quadratic Finite Elements
5.4.5.1 Sobolev Regularity 3/2 < s < 5/2
5.4.5.2 Sobolev Regularity s = 5/2
5.5 Further Comments
5.5.1 First Results of Numerical Approximation
5.5.2 Towards Optimal Rates (Higher Sobolev Regularities)
5.5.3 The Case of Lower Sobolev Regularities
5.5.4 Errors in the L2-Norm and Aubin–Nitsche
5.5.5 Related Results and Other Approximation Methods
6 Nitsche's Method
6.1 A First Derivation of Nitsche's Method for Signorini Problem
6.1.1 The Positive Part Operator
6.1.2 A Reformulation of the Signorini Conditions
6.1.3 An Incomplete Nitsche Formulation
6.2 Nitsche Discrete Formulations and Variants
6.2.1 A Family of Methods
6.2.2 The Symmetric Nitsche's Method
6.2.3 Link with Barbosa and Hughes Stabilization
6.3 Consistency, Well-posedness and Optimal Error Estimates
6.3.1 Consistency
6.3.2 Well-posedness
6.3.3 An Abstract a priori Error Estimate
6.3.4 Optimal a priori Error Estimate
6.4 Implementation
6.5 Further Comments
6.5.1 About Nitsche's Method
6.5.2 The First Application to Bilateral Contact
6.5.3 Nitsche for Unilateral Contact
6.5.4 Symmetry, Skew-symmetry, Etc.
6.5.5 Lower Sobolev Regularity
6.5.6 Link with Stabilized Methods and the Augmented Lagrangian
6.5.7 Other Discretization Methods
7 Mixed Methods
7.1 Duality Principle and Mixed Weak Form of Signorini
7.1.1 Obtention of a Lagrangian
7.1.2 Mixed Problem as a Saddle-Point
7.1.3 An inf-sup Condition
7.2 A Mixed Finite Element Method
7.2.1 The Mixed Method
7.2.2 Well-Posedness
7.2.3 An Equivalent Discrete Variational Inequality
7.2.4 A Discrete inf-sup Condition
7.3 An a priori Error Estimate for the Mixed Formulation
7.3.1 An Abstract Lemma
7.3.2 An Optimal Error Estimate
7.4 Other Mixed Methods
7.4.1 A Stabilized Mixed Method
7.4.2 Mortar and LAC Methods
7.4.2.1 Formulations
7.4.2.2 The inf-sup Condition
7.4.2.3 Optimal Error Estimates
7.5 Proximal Augmented Lagrangian
7.5.1 Obtention of an Augmented Lagrangian
7.5.2 An Augmented Mixed Method
7.5.3 From Nitsche to Augmented Lagrangian Formulations
7.6 Implementation
7.6.1 Semi-Smooth Newton for the Augmented Lagrangian
7.6.2 Uzawa's Algorithm
7.6.3 A Penalty Formulation from Uzawa
7.7 Further Comments
7.7.1 About Mixed Methods
7.7.2 Discrete inf-sup Conditions
7.7.3 About the Mixed Methods in This Chapter
7.7.4 Augmented Lagrangian
Part III Extension to Frictional Contact and Large Strain
8 Tresca Friction
8.1 Setting
8.2 Discrete Variational Inequality
8.2.1 A Discrete Variational Inequality
8.2.2 A Preliminary Convergence Result
8.3 Nitsche for Tresca Friction
8.3.1 Setting
8.3.2 Well-Posedness and Error Estimates
8.3.2.1 Well-Posedness
8.3.2.2 Error Analysis
8.4 Mixed and Augmented Lagrangian Methods
8.4.1 Global Setting
8.4.2 A Mixed Method
8.4.3 An Augmented Lagrangian Formulation
8.5 Penalized Frictional Contact
8.5.1 The Penalty Method
8.5.2 Convergence Analysis
8.6 Further Comments
8.6.1 Tresca Friction
8.6.2 First Error Estimates for Tresca
8.6.3 Further Error Estimates for Tresca
8.6.4 Implementation
9 Coulomb Friction
9.1 The Frictional Contact Problem in Elasticity
9.2 Weak Formulation and Existence of Solutions
9.2.1 Weak Formulations
9.2.2 Existence, Uniqueness, and Non-uniqueness of Solutions
9.3 Mixed Finite Element Approximation
9.3.1 Setting
9.3.2 Existence and Uniqueness
9.3.3 An a priori Error Estimate
9.4 Finite Element Approximation with Nitsche
9.4.1 Preliminaries
9.4.2 Nitsche Formulation
9.4.3 Existence and Uniqueness Results
9.5 Further Comments
9.5.1 Mixed Methods and Error Estimates
9.5.2 Nitsche Method
9.5.3 Bifurcation Tracking
10 Contact Between Two Elastic Bodies
10.1 Setting
10.1.1 The General Configuration
10.1.2 Biased Contact
10.1.3 Contact Pairing
10.1.4 The Contact Conditions
10.1.5 Friction
10.1.6 Equilibrium
10.1.7 Weak Form
10.2 Finite Element Approximations
10.2.1 Discrete Variational Inequality, Mortar and LAC
10.2.2 Nitsche's Method
10.2.3 Mixed Methods
10.2.4 Augmented Lagrangian
10.2.5 Penalty
10.3 Unbiased Formulation for Self- and Multi-body Contact
10.3.1 Derivation
10.3.2 The Unbiased Method
10.4 Further Comments
10.4.1 Semi-smooth Newton Once Again
10.4.2 Numerical Integration
11 Contact and Self-contact in Large Strain
11.1 Setting
11.1.1 Hyperelasticity
11.1.2 The Contact Mapping and the Gap Function
11.1.3 Contact and Friction Conditions
11.2 Augmented Lagrangian Formulations
11.2.1 A First Augmented Lagrangian Formulation
11.2.2 Another Augmented Lagrangian Formulation
11.3 Unbiased and Biased Nitsche Formulations
11.3.1 Frictionless Contact
11.3.2 Frictional Contact
11.3.3 A Biased Nitsche Method
11.4 Directional Derivatives of the Gap
11.4.1 A Preliminary Result
11.4.2 Derivatives of the Gap
11.4.3 More and More Derivatives
11.4.4 Implications in Terms of Numerical Robustness
11.5 Numerical Results
11.5.1 Elastic Half-Ring
11.5.2 Crossed Tubes with Self-contact
11.6 Further Comments
11.6.1 Existence Results
11.6.2 Numerical Methods
A Test-Cases for Verification
A.1 Scalar Signorini
A.2 A Manufactured Solution for Tresca Friction
References
Index
