Abaqus Learning: Fracture & Fatigue Theory & Implementation.
Abaqus Learning: Fracture & Fatigue Theory & Implementation.
Published 8/2024
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.21 GB | Duration: 2h 58m
Fatigue Crack Growth Using XFEM Method With Paris Law In ABAQUS (Direct cyclic Low cycle fatigue approach)
What you'll learn
Introduction to fracture mechanics (theory)
Finite element method (FEM) and Extended finite element method (XFEM) ((theory))
Fatigue crack growth (theory)
ABAQUS general explanation
fatigue model creation "how to define the XFEM, how to implement Paris law, define the pre-crack length & location, direct cyclic and how to control accuracy.
Three different case studies
how to deal with stationary cracks to calculate fracture mechanics parameters like SIF.
Requirements
only the basic knowledge of material properties. as the course content contains the basis for fracture mechanics, FEM and ABAQUS explanation from zero
Description
Fatigue represents the most common cause of mechanical structure failures. To investigate this phenomenon, studies have conducted experiments, conducting actual fatigue experiments demands extensive time, substantial financial resources, and is constrained by size limitations. The solution lies in the development and validation of precise numerical models. This is the primary driver behind our course, as it enables accurate and reliable predictions of crack growth. This course delves into the advanced simulation of fatigue crack growth using the eXtended Finite Element Method (XFEM) combined with the Paris Law formulation, fully implemented in ABAQUS software. The course emphasizes the direct cyclic and low cycle fatigue approaches, providing a comprehensive framework for analyzing the degradation of materials under cyclic loading.You Will Learn:1. Fundamentals of fracture mechanics and Fatigue Crack Growth:2. Finite Element Method (FEM) and eXtended Finite Element Method (XFEM) - Core principles of FEM and how they apply to crack propagation simulations. - Coverage of XFEM, including enrichment functions, and level-set methods. - How to model cracks without remeshing the mesh during propagation and how XFEM handles discontinuities.3. Fatigue Crack Propagation Regimes: - Understanding the relationship between crack size and cycles, including factors like stress ratio effects. - Detailed exploration of crack growth laws, including Paris Law, Walker Law, and NASGRO formulations. - Methods for life prediction, failure criteria, and assessing the factor of safety in fatigue analysis.4. Model Creation in ABAQUS: - Step-by-step guidance on part creation and material definition, including damage models for traction separation. - Implementation of direct cyclic and low cycle fatigue steps, focusing on Fourier representations, and convergence criteria. - Special interaction properties like pre-crack definitions and Paris Law implementation for fatigue analysis.5. Results Interpretation and Post-Processing: - Visualizing crack propagation patterns across different cycles. - Generating and analyzing key outputs such as crack length vs. cycle graphs and fatigue crack growth rates (da/dN vs. ΔK).6. Three different case studies.Course Features:- Detailed theoretical background paired with practical modeling exercises in ABAQUS.- Real-world case studies and examples, including complex geometries.- Guidance on setting up simulations for brittle materials using LEFM principles.Who Should Enroll:This course is designed for engineers, researchers, and under graduate or graduate students who wanted to get a very good understanding of finite element analysis and wish to expand their knowledge in the field of fracture and fatigue analysis using ABAQUS. It is particularly beneficial for those interested in crack growth modeling and the application of advanced methods like XFEM and direct cyclic analysis in practical engineering scenarios.By the end of the course, participants will be able to simulate, analyze, and interpret fatigue crack growth in various materials and loading conditions, providing them with a competitive edge in the field of structural analysis and design.
Overview
Section 1: Introduction to fracture mechanics
Lecture 1 Introduction
Lecture 2 overview
Lecture 3 Stress Concentrations Around Cracks
Lecture 4 Modes of Loading
Lecture 5 Stress intensity factor
Lecture 6 Superpostion principle
Lecture 7 Fracture toughness
Lecture 8 Linear elastic fracture mechanics (LEFM)
Lecture 9 Fatigue crack growth (FCG)
Section 2: Finite element method v.s extended finite element method (theory)
Lecture 10 Finite element method
Lecture 11 Extended finite element method
Section 3: Fatigue crack growth theory (FCG)
Lecture 12 Definition of Loading
Lecture 13 fatigue crack growth relationships
Lecture 14 Failure criteria, life time and factor of safety
Section 4: ABAQUS Model Creation
Lecture 15 Part Creation
Lecture 16 material definition
Lecture 17 Direct cyclic
Lecture 18 Specifying convergence criteria
Lecture 19 Edit accuracy parameters and restart analysis
Lecture 20 Low cycle fatigue
Lecture 21 Field output requesting
Lecture 22 Interactions and special crack definition
Lecture 23 Paris law implementation
Lecture 24 load, Mesh and Job modules
Section 5: Case studies
Lecture 25 Case study 1
Lecture 26 Case study 2
Lecture 27 Case study 3
Lecture 28 Static analysis and calculating K and Y
for all levels in ABAQUS and fracture mechanics
What you'll learn
Introduction to fracture mechanics (theory)
Finite element method (FEM) and Extended finite element method (XFEM) ((theory))
Fatigue crack growth (theory)
ABAQUS general explanation
fatigue model creation "how to define the XFEM, how to implement Paris law, define the pre-crack length & location, direct cyclic and how to control accuracy.
Three different case studies
how to deal with stationary cracks to calculate fracture mechanics parameters like SIF.
Requirements
only the basic knowledge of material properties. as the course content contains the basis for fracture mechanics, FEM and ABAQUS explanation from zero
Description
Fatigue represents the most common cause of mechanical structure failures. To investigate this phenomenon, studies have conducted experiments, conducting actual fatigue experiments demands extensive time, substantial financial resources, and is constrained by size limitations. The solution lies in the development and validation of precise numerical models. This is the primary driver behind our course, as it enables accurate and reliable predictions of crack growth. This course delves into the advanced simulation of fatigue crack growth using the eXtended Finite Element Method (XFEM) combined with the Paris Law formulation, fully implemented in ABAQUS software. The course emphasizes the direct cyclic and low cycle fatigue approaches, providing a comprehensive framework for analyzing the degradation of materials under cyclic loading.You Will Learn:1. Fundamentals of fracture mechanics and Fatigue Crack Growth:2. Finite Element Method (FEM) and eXtended Finite Element Method (XFEM) - Core principles of FEM and how they apply to crack propagation simulations. - Coverage of XFEM, including enrichment functions, and level-set methods. - How to model cracks without remeshing the mesh during propagation and how XFEM handles discontinuities.3. Fatigue Crack Propagation Regimes: - Understanding the relationship between crack size and cycles, including factors like stress ratio effects. - Detailed exploration of crack growth laws, including Paris Law, Walker Law, and NASGRO formulations. - Methods for life prediction, failure criteria, and assessing the factor of safety in fatigue analysis.4. Model Creation in ABAQUS: - Step-by-step guidance on part creation and material definition, including damage models for traction separation. - Implementation of direct cyclic and low cycle fatigue steps, focusing on Fourier representations, and convergence criteria. - Special interaction properties like pre-crack definitions and Paris Law implementation for fatigue analysis.5. Results Interpretation and Post-Processing: - Visualizing crack propagation patterns across different cycles. - Generating and analyzing key outputs such as crack length vs. cycle graphs and fatigue crack growth rates (da/dN vs. ΔK).6. Three different case studies.Course Features:- Detailed theoretical background paired with practical modeling exercises in ABAQUS.- Real-world case studies and examples, including complex geometries.- Guidance on setting up simulations for brittle materials using LEFM principles.Who Should Enroll:This course is designed for engineers, researchers, and under graduate or graduate students who wanted to get a very good understanding of finite element analysis and wish to expand their knowledge in the field of fracture and fatigue analysis using ABAQUS. It is particularly beneficial for those interested in crack growth modeling and the application of advanced methods like XFEM and direct cyclic analysis in practical engineering scenarios.By the end of the course, participants will be able to simulate, analyze, and interpret fatigue crack growth in various materials and loading conditions, providing them with a competitive edge in the field of structural analysis and design.
Overview
Section 1: Introduction to fracture mechanics
Lecture 1 Introduction
Lecture 2 overview
Lecture 3 Stress Concentrations Around Cracks
Lecture 4 Modes of Loading
Lecture 5 Stress intensity factor
Lecture 6 Superpostion principle
Lecture 7 Fracture toughness
Lecture 8 Linear elastic fracture mechanics (LEFM)
Lecture 9 Fatigue crack growth (FCG)
Section 2: Finite element method v.s extended finite element method (theory)
Lecture 10 Finite element method
Lecture 11 Extended finite element method
Section 3: Fatigue crack growth theory (FCG)
Lecture 12 Definition of Loading
Lecture 13 fatigue crack growth relationships
Lecture 14 Failure criteria, life time and factor of safety
Section 4: ABAQUS Model Creation
Lecture 15 Part Creation
Lecture 16 material definition
Lecture 17 Direct cyclic
Lecture 18 Specifying convergence criteria
Lecture 19 Edit accuracy parameters and restart analysis
Lecture 20 Low cycle fatigue
Lecture 21 Field output requesting
Lecture 22 Interactions and special crack definition
Lecture 23 Paris law implementation
Lecture 24 load, Mesh and Job modules
Section 5: Case studies
Lecture 25 Case study 1
Lecture 26 Case study 2
Lecture 27 Case study 3
Lecture 28 Static analysis and calculating K and Y
for all levels in ABAQUS and fracture mechanics
