[Abaqus 02. 기본] 2.4 사용자 설명서
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(2023-01-21)
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Abaqus Analysis User's Manual(6.10), DS Simulia
http://130.149.89.49:2080/v6.10/books/usb/default.htm?startat=pt06ch24s01abo23.html
(1) 편
(2) 장
(3) 목차
아바쿠스의 사용자 설명서(Abaqus Analysis User's Manual)
(1) 편
"아바쿠스 사용자 설명서(Abaqus Analysis User's Manual)"는 9개 편(관련 장)으로 구성되어 있다.
- 1편: 소개, 모델링, 실행(Introduction, Spatial Modeling, and Execution): 1,2,3장
- 2편: 결과(Output): 4,5장
- 3편: 해석 절차, 해석 제어(Analysis Procedures, Solution, and Control): 6,7장
- 4편: 해석 기법(Analysis Techniques): 8,9,10,11,12,13,14,15,16,17장
- 5편: 재료(Materials): 18,19,20,21,22,23장
- 6편: 요소(Elements): 24,25,26,27,28,29장
- 7편: 경계조건(Prescribed Conditions): 30장
- 8편: 구소조건(Constraints): 31장
- 9편: 접촉문제(Interactions): 32,33,34,35,36,37장
- A편: 변수/요소 색인(Output Variable and Element Indexes)
(2) 장
"아바쿠스 사용자 설명서(Abaqus Analysis User's Manual)"는 37장으로 구성되어 있다.
---1편: 소개, 모델링, 실행
- 1장. 소개(Introduction)
- 2장. 모델링(Spatial Modeling)
- 3장. 실행(Job Execution)
---2편: 결과
- 4장. 결과(Output)
- 5장. 출력 양식(File Output Format)
---3편: 해석 절차, 해석 제어
- 6장. 해석 절차(Analysis Procedures)
- 7장. 해석 제어(Analysis Solution and Control)
---4편: 해석 기법
- 8장. 개요(Analysis Techniques: Introduction)
- 9장. 연속 해석(Analysis Continuation Techniques)
- 10장. 모델링 요약(Modeling Abstractions)
- 11장. 특수해석 기법(Special-Purpose Techniques)
- 12장. 적응 기법A(daptivity Techniques)
- 13장. 오일러 해석(Eulerian Analysis)
- 14장. 다중물리 해석(Multiphysics Analyses)
- 15장. 사용자 정의 함수(Extending Abaqus Analysis Functionality)
- 16장. 설계 민감도 해석(Design Sensitivity Analysis)
- 17장. 매개변수해석(Parametric Studies)
---5편: 재료
- 18장. 개요(Materials: Introduction)
- 19장. 탄성(Elastic Mechanical Properties)
- 20장. 비탄성(Inelastic Mechanical Properties)
- 21장. 진행형 손상과 파괴(Progressive Damage and Failure)
- 22장. 동수역학(Hydrodynamic Properties)
- 23장. 기타(Other Material Properties)
---6편: 요소
- 24장. 개요(Elements: Introduction)
- 25장. 연속체(Continuum Elements)
- 26장. 구조체(Structural Elements)
- 27장. 관성/강체/전기(Inertial, Rigid, and Capacitance Elements)
- 28장. 연결(Connector Elements)
- 29장. 특수 목적(Special-Purpose Elements)
---7편: 경계조건
- 30장. 경계(Prescribed Conditions)
---8편: 구소조건
- 31장. 구속(Constraints)
---9편: 접촉문제
- 32장. 정의(Defining Contact Interactions)
- 33장. 성질(Contact Property Models)
- 34장. 기법(Contact Formulations and Numerical Methods)
- 35장. Q&A(Contact Difficulties and Diagnostics)
- 36장. 요소(Contact Elements in Abaqus/Standard)
- 37장. 열전달(Defining Cavity Radiation in Abaqus/Standard)
---A편: 변수/요소 색인
- 변수(Variable Index)
- 요소(Element Index)
(3) 목차
Introduction, Spatial Modeling, and Execution
1 Introduction
1.1 Introduction
1.2 Abaqus syntax and conventions
1.3 Abaqus model definition
1.4 Parametric modeling
2 Spatial Modeling
2.1 Node definition
2.2 Element definition
2.3 Surface definition
2.4 Rigid body definition
2.5 Integrated output section definition
2.6 Nonstructural mass definition
2.7 Distribution definition
2.8 Display body definition
2.9 Assembly definition
2.10 Matrix definition
3 Job Execution
3.1 Execution procedures: overview
3.2 Execution procedures
3.3 Environment file settings
3.4 Managing memory and disk resources
3.5 Parallel execution
3.6 File extension definitions
3.7 FORTRAN unit numbers
Output
4 Output
4.1 Output
4.2 Output variables
4.3 The postprocessing calculator
5 File Output Format
5.1 Accessing the results file
Analysis Procedures, Solution, and Control
6 Analysis Procedures
6.1 Introduction
6.2 Static stress/displacement analysis
6.3 Dynamic stress/displacement analysis
6.4 Steady-state transport analysis
6.5 Heat transfer and thermal-stress analysis
6.6 Fluid dynamic analysis
6.7 Electrical analysis
6.8 Coupled pore fluid flow and stress analysis
6.9 Mass diffusion analysis
6.10 Acoustic and shock analysis
6.11 Abaqus/Aqua analysis
6.12 Annealing
7 Analysis Solution and Control
7.1 Solving nonlinear problems
7.2 Analysis convergence controls
Analysis Techniques
8 Analysis Techniques: Introduction
8.1 Introduction
9 Analysis Continuation Techniques
9.1 Restarting an analysis
9.2 Importing and transferring results
10 Modeling Abstractions
10.1 Substructuring
10.2 Submodeling
10.3 Generating global matrices
10.4 Symmetric model generation, results transfer, and analysis of cyclic symmetry models
10.5 Meshed beam cross-sections
10.6 Modeling discontinuities as an enriched feature using the extended finite element method
11 Special-Purpose Techniques
11.1 Inertia relief
11.2 Mesh modification or replacement
11.3 Geometric imperfections
11.4 Fracture mechanics
11.5 Hydrostatic fluid modeling
11.6 Surface-based fluid modeling
11.7 Mass scaling
11.8 Selective subcycling
11.9 Steady-state detection
12 Adaptivity Techniques
12.1 Adaptivity techniques: overview
12.2 ALE adaptive meshing
12.3 Adaptive remeshing
12.4 Analysis continuation after mesh replacement
13 Eulerian Analysis
13.1 Eulerian analysis
14 Multiphysics Analyses
14.1 Co-simulation
14.2 Sequentially coupled multiphysics analyses
15 Extending Abaqus Analysis Functionality
15.1 User subroutines and utilities
16 Design Sensitivity Analysis
16.1 Design sensitivity analysis
17 Parametric Studies
17.1 Scripting parametric studies
17.2 Parametric studies: commands
Materials
18 Materials: Introduction
18.1 Introduction
18.2 General properties
19 Elastic Mechanical Properties
19.1 Overview
19.2 Linear elasticity
19.3 Porous elasticity
19.4 Hypoelasticity
19.5 Hyperelasticity
19.6 Stress softening in elastomers
19.7 Viscoelasticity
19.8 Hysteresis
19.9 Rate sensitive elastomeric foams
20 Inelastic Mechanical Properties
20.1 Overview
20.2 Metal plasticity
20.3 Other plasticity models
20.4 Fabric materials
20.5 Jointed materials
20.6 Concrete
20.7 Permanent set in rubberlike materials
21 Progressive Damage and Failure
21.1 Progressive damage and failure: overview
21.2 Damage and failure for ductile metals
21.3 Damage and failure for fiber-reinforced composites
21.4 Damage and failure for ductile materials in low-cycle fatigue analysis
22 Hydrodynamic Properties
22.1 Overview
22.2 Equations of state
23 Other Material Properties
23.1 Mechanical properties
23.2 Heat transfer properties
23.3 Acoustic properties
23.4 Hydrostatic fluid properties
23.5 Mass diffusion properties
23.6 Electrical properties
23.7 Pore fluid flow properties
23.8 User materials
Elements
24 Elements: Introduction
24.1 Introduction
24.1.1 Element library: overview
24.1.2 Choosing the element's dimensionality
24.1.3 Choosing the appropriate element for an analysis type
24.1.4 Section controls
25 Continuum Elements
25.1 General-purpose continuum elements
25.2 Fluid continuum elements
25.3 Infinite elements
25.4 Warping elements
26 Structural Elements
26.1 Membrane elements
26.2 Truss elements
26.3 Beam elements
26.4 Frame elements
26.5 Elbow elements
26.6 Shell elements
27 Inertial, Rigid, and Capacitance Elements
27.1 Point mass elements
27.2 Rotary inertia elements
27.3 Rigid elements
27.4 Capacitance elements
28 Connector Elements
28.1 Connector elements
28.2 Connector element behavior
29 Special-Purpose Elements
29.1 Spring elements
29.2 Dashpot elements
29.3 Flexible joint elements
29.4 Distributing coupling elements
29.5 Cohesive elements
29.6 Gasket elements
29.7 Surface elements
29.8 Hydrostatic fluid elements
29.9 Tube support elements
29.10 Line spring elements
29.11 Elastic-plastic joints
29.12 Drag chain elements
29.13 Pipe-soil elements
29.14 Acoustic interface elements
29.15 Eulerian elements
29.16 User-defined elements
Prescribed Conditions
30 Prescribed Conditions
30.1 Overview
30.2 Initial conditions
30.3 Boundary conditions
30.4 Loads
30.5 Prescribed assembly loads
30.6 Predefined fields
Constraints
31 Constraints
31.1 Overview
31.2 Multi-point constraints
31.3 Surface-based constraints
31.4 Embedded elements
31.5 Element end release
31.6 Overconstraint checks
Interactions
32 Defining Contact Interactions
32.1 Overview
32.2 Defining general contact in Abaqus/Standard
32.3 Defining contact pairs in Abaqus/Standard
32.4 Defining general contact in Abaqus/Explicit
32.5 Defining contact pairs in Abaqus/Explicit
33 Contact Property Models
33.1 Mechanical contact properties
33.2 Thermal contact properties
33.3 Electrical contact properties
33.4 Pore fluid contact properties
34 Contact Formulations and Numerical Methods
34.1 Contact formulations and numerical methods in Abaqus/Standard
34.2 Contact formulations and numerical methods in Abaqus/Explicit
35 Contact Difficulties and Diagnostics
35.1 Resolving contact difficulties in Abaqus/Standard
35.2 Resolving contact difficulties in Abaqus/Explicit
36 Contact Elements in Abaqus/Standard
36.1 Contact modeling with elements
36.2 Gap contact elements
36.3 Tube-to-tube contact elements
36.4 Slide line contact elements
36.5 Rigid surface contact elements
37 Defining Cavity Radiation in Abaqus/Standard
37.1 Defining cavity radiation
Output Variable and Element Indexes
Abaqus/Standard Output Variable Index
Abaqus/Explicit Output Variable Index
Abaqus/Standard Element Index
Abaqus/Explicit Element Index