模擬
Creo Simulation Live 概觀
Creo Simulation Live 入門
Creo Simulation Live 硬體需求
取得 Creo Simulation Live 試用版授權
Creo Simulation Live 設定
工作流程 - Creo Simulation Live
Creo Simulation Live 使用者介面
Creo Simulation Live 研究
執行結構模擬 - Creo Simulation Live
範例:結構模擬
執行熱模擬研究 - Creo Simulation Live
範例:熱模擬
執行模態模擬 - Creo Simulation Live
範例:模態模擬
在 Creo Simulation Live 中執行組合研究
執行流體模擬研究 - Creo Simulation Live
範例 - Creo Simulation Live 的內部流動模擬
範例 - Creo Simulation Live 內的外部流體模擬
範例:移除內部幾何
執行共軛熱轉移研究 - Creo Simulation Live
範例:共軛熱轉移研究 - Simulation Live
Creo Simulation Live 中的多主體支援
定義即時模擬的範圍
Creo Simulation Live 中的接觸
Creo Simulation Live 中的扣件
在 Creo Simulation Live 中定義扣件
Creo Simulation Live 中的多主體支援
在 Creo Simulation Live 中使用組件
將零件層級中的 Simulation Live 研究匯入至組件層級
時間限制
模擬品質
模擬輸入 - Creo Simulation Live
條件約束
固定條件約束 - Creo Simulation Live
位移條件約束 - Creo Simulation Live
圓柱條件約束
球條件約束 - Creo Simulation Live
平面條件約束 - Creo Simulation Live
熱邊界條件
規定溫度邊界條件 - Creo Simulation Live
初始溫度 - Creo Simulation Live
對流邊界條件 - Creo Simulation Live
對流輻射邊界條件 - Creo Simulation Live
流體模擬邊界條件
流速 - Creo Simulation Live
入口壓力
出口壓力
質量流量邊界條件 - Creo Simulation Live
滑動對稱 - Creo Simulation Live
旋轉壁邊界條件
在 Creo Simulation Live 中旋轉流體域
渦流入口邊界條件
結構負載
力負載 - Creo Simulation Live
力矩負載 - Creo Simulation Live
壓力負載 - Creo Simulation Live
軸承負載 - Creo Simulation Live
重力負載 - Creo Simulation Live
離心力負載 - Creo Simulation Live
線性加速度負載 - Creo Simulation Live
扣件預負載 - Creo Simulation Live
熱負載
熱流負載 - Creo Simulation Live
熱通量負載 - Creo Simulation Live
Simulation Live 結果
在 Creo Simulation Live 中顯示結果
結果選項 - Creo Simulation Live
流線的結果顯示選項
粒子的結果顯示選項
向量的結果顯示選項
在 Creo Simulation Live 中使用結果圖例
範例:採用不同彩現方法所產生的結果
模擬時間
在 Creo Simulation Live 中顯示流體分析的結果
在 Creo Simulation Live 研究的結果中顯示流線
在結果中顯示粒子
在 Creo Simulation Live 研究的結果中顯示向量
在結果中顯示切削平面 - Creo Simulation Live
在結果中顯示方向域 - Creo Simulation Live
在 Creo Simulation Live 中查詢及儲存結果
模擬結果報告
匯出 Simulation Live 結果
驗證指南 - Creo Simulation Live 與 Creo Ansys Simulation
驗證案例 - 靜態結構分析
驗證案例 - 模態分析
熱分析的驗證案例
基準案例
Creo Ansys Simulation
Creo Ansys Simulation 概述
Creo Ansys Simulation 入門
執行 Creo Ansys Simulation 的先決條件
啟動 Creo Ansys Simulation 應用程式
使用者介面 - Creo Ansys Simulation
工作流程 - Creo Ansys Simulation
Creo Ansys Simulation 的設定
組態選項 - Creo Ansys Simulation
Creo Ansys Simulation 中的單位
指派材料 - Creo Ansys Simulation
在 Creo Ansys Simulation 中建立材料
線性同向性材料 - Creo Ansys Simulation
橫向同向性材料 - Creo Ansys Simulation
正交材料 - Creo Ansys Simulation
超彈性材料 - Creo Ansys Simulation
彈塑性材料 - Creo Ansys Simulation
普松比率 - 同向性
普松比率
楊氏模數 - 同向性
楊氏模數
剪切模數
熱膨脹係數 - 同向性
熱膨脹係數
同向性內容的熱值
正交內容的熱值
橫向同向性內容的熱值
材料失效準則 - Creo Ansys Simulation
修改過的 Mohr 破壞理論失效準則 - Creo Ansys Simulation
最大剪切應力 (Tresca) 失效準則
最大應變失效準則
最大應力失效準則
Tsai-Wu 失效準則 - Creo Ansys Simulation
正常化的 Tsai-Wu 互動條件
扭曲力 (von Mises) 失效準則
伸展終極應力 - Creo Ansys Simulation
壓縮終極應力 - Creo Ansys Simulation
伸展屈服應力
剪切終極應力 - Creo Ansys Simulation
熱軟化係數
Creo Ansys Simulation 中的結構條件約束
固定條件約束 - Creo Ansys Simulation
位移條件約束 - Creo Ansys Simulation
範例:從遠端點套用位移條件約束
平面條件約束 - Creo Ansys Simulation
圓柱條件約束 - Creo Ansys Simulation
球條件約束 - Creo Ansys Simulation
無摩擦條件約束 - Creo Ansys Simulation
慣性止裂槽 - Creo Ansys Simulation
結構負載
力負載 - Creo Ansys Simulation
力矩負載 - Creo Ansys Simulation
軸承負載 - Creo Ansys Simulation
最佳作法 - Creo Ansys Simulation 中的負載
壓力負載 - Creo Ansys Simulation
重力負載 - Creo Ansys Simulation
離心力負載 - Creo Ansys Simulation
Creo Ansys Simulation 中的扣件預負載
線性加速度負載 - Creo Ansys Simulation
結構溫度負載 - Creo Ansys Simulation
Creo Ansys Simulation 中的熱邊界條件
規定溫度邊界條件 - Creo Ansys Simulation
對流邊界條件 - Creo Ansys Simulation
輻射邊界條件 - Creo Ansys Simulation
熱負載
熱流負載 - Creo Ansys Simulation
熱通量負載 - Creo Ansys Simulation
熱產生負載 - Creo Ansys Simulation
理想模型
質量理想模型 - Creo Ansys Simulation
彈簧 - Creo Ansys Simulation
彈簧行為 - Creo Ansys Simulation
樑理想模型 - Creo Ansys Simulation
樑截面 - Creo Ansys Simulation
樑釋放 - Creo Ansys Simulation
殼 - Creo Ansys Simulation
殼對 - Creo Ansys Simulation
連接
Creo Ansys Simulation 中的接觸
Creo Ansys Simulation 中的接觸行為
接頭 - Creo Ansys Simulation
接頭行為 - Creo Ansys Simulation
Creo Ansys Simulation 中的扣件
在 Creo Ansys Simulation 中定義扣件
分割曲面特徵 - Creo Ansys Simulation
Creo Ansys Simulation 中的網格化
控制網格
全域網格大小控制 - Creo Ansys Simulation
局部網格細分
執行模擬研究
執行模擬研究 - Creo Ansys Simulation
執行瞬態結構研究
執行隨機變動分析
Creo Ansys Simulation 中的疲勞分析
範例:在 Creo Ansys Simulation 中執行疲勞研究
在 Creo Ansys Simulation 中使用流程管理員
Creo Ansys Simulation 的診斷
審核幾何 - Creo Ansys Simulation
Creo Ansys Simulation 中的結果
關於 Creo Ansys Simulation 中的結果
檢視整體結果
定義結果 - Creo Ansys Simulation
使用結果範本 - Creo Ansys Simulation
Creo Ansys Simulation 中的結果圖例
查詢結果 - Creo Ansys Simulation
檢視 Creo Ansys Simulation 結果中的橫截面
在 Creo Ansys Simulation 中使用輔助視窗
Creo Ansys Simulation 中的結果類型
解讀疲勞研究中的結果
自訂常用的結果清單
在 Creo Ansys Simulation 中儲存及匯出結果
Creo Ansys Simulation 中的模擬物件狀況
Creo Ansys Simulation 中的求解器設定
將模擬物件從其他模擬工具匯入至 Creo Ansys Simulation
驗證指南 - Creo Ansys Simulation
將模型匯出為 Ansys Mechanical 格式
Intel 使用者授權合約
Creo Simulate
Creo Simulate Overview
About Creo Simulate
Updates for Creo Simulate
Getting Started with Creo Simulate
Getting Started
Operating Modes
Operating Modes
FEM Mode
Considerations for Multiple Model Sessions
Integrated Mode
Standalone Mode
File Types Supported in Creo Simulate Standalone
Creo Simulate Products
The Creo Simulate Product Line
Creo Simulate Structure
Creo Simulate Thermal
Creo Simulate Fatigue Advisor
Creo Simulate Workflow
Creo Simulate Workflow
Native Mode Workflow
Developing a Model (Native Mode)
Analyzing a Model (Native Mode)
Defining Design Changes (Native Mode)
Optimizing a Model (Native Mode)
FEM Mode Workflow
Developing a Model (FEM Mode)
Defining an Analysis (FEM Mode)
Creating a Mesh (FEM Mode)
Solving a Model (FEM Mode)
Planning and Modeling Considerations
Planning and Modeling Considerations
Building Part and Assemblies
Planning and Building Parts and Assemblies
Using Flexible Modeling Tools in Creo Simulate
Strategy: Keeping Models Simple
Methods of Simplifying Your Model
Example: Using a Simplified Part
Strategy: Suppressing Nonessential Features
Strategy: Techniques for Refining your Geometry
Strategy: Techniques for Fully Specifying Your Geometry
When a Nonessential Feature Causes Unexpected Model Behavior Changes
When a Nonessential Feature Provides Hidden Benefits
Planning for Shape Changes
Planning for Shape Changes
Strategy: Planning Ahead for Shape Changes
Strategy: Developing a Featuring Scheme
Strategy: Identifying Relationships that Affect Shape Changes
Strategy: Changing Dimension Names
Strategy: Avoiding Topology Conflicts
Example: Avoiding Interference
Example: Dependent Movement in Patterned Features
Example: Featuring Your Part
Example: Pre-planning for Shape Changes
Assembly Considerations
Assembly Modeling Entities, Idealizations, and Connections
Connected and Unconnected Parts
Simplified Assembly Representations in Creo Simulate
Retrieving Assemblies Modified in Creo Direct
Multi-CAD Assemblies in Creo Simulate
Using Creo Product Insight with Creo Simulate
About File Names in Creo Simulate
Using Effective Modeling Techniques
Simulation Modeling Techniques and Prerequisites
About Units
Using Coordinate Systems
Using Datum Features
Guidelines and Tips for Using Datum Points
Working with Surface and Volume Regions
To Dynamically Edit a Feature
About Editing and Replacing the References of Features
Using Parameters
Driven and Driving Parameters
Parameters as Measures
Parameters as Design Variables
Taking Advantage of Symmetry
Working with Symmetric Models
Comparing Mirror and Cyclic Symmetry
Example: Using Mirror Symmetry
Example: Using Cyclic Symmetry
Preparing a 2D Model
Example: Modeling Specialized Loads with a Cylindrical Coordinate System
Example: Setting up a Solid Model for a 2D Analysis on an Internal Surface
Planning for Optimization
Planning for Optimization Effects
Optimization and Suppressed Features
Optimization and Assemblies
Optimization and Generic Parts
Optimization and Reference Parts
User Interface Basics
Working with the User Interface
Using Dialog Boxes and Message Boxes
Creo Simulate Ribbon User Interface
Customizing the Ribbon
Process Guide
About Process Guide
Process Guide Session
Starting a New Process Guide Session
Re-entering an Existing Process Guide Session
Process Guide Dialog Box
Understanding the Navigation Area
Understanding the Instruction Area
Navigation Area Task Status
Working with the Process Guide Dialog Box
Process Guide Templates
Process Template
Designing Process Guide Templates
Template Structure
Sample Process Guide Template
Process Guide Tasks
Model Objects and Attributes
Managing Constraints in Process Guide
Managing Loads in Process Guide
Process Guide Template Dialog Box
To Create a Process Guide Template
Guidelines for Using Process Guide
Selection Methods
SIM SELECT Menu
Fix and Flip Normals
Object Action
Object Action Shortcut Menus
To Set Simulation Entity Prehighlighting Filters
Search Tool
Search Tool Dialog Box
Building and Saving Queries
Mini Toolbar
About the Mini Toolbar in Creo Simulate
Mini Toolbar Commands in 2D Models
Mini Toolbar Commands in 3D Models
About Customizing the Mini Toolbar and Right Mouse Button Commands
Using Layers
Grouping for ANSYS
Managing Modeling Entities Through Suppression and Family Tables
Suppression and Family Tables
To Suppress Modeling Entities Through a Family Table
Simulation Display
Setting Simulation Visibility
Settings Tab
To Set Transparency for a Model
Modeling Entities Tab
Loads/Constraints Tab
Set Visibilities Tab
Mesh Tab
Controlling Mesh Display
Controlling FEM Mesh Display
Displaying the Mesh Model
FEM Mesh Display Buttons
To Control Icon Appearance
To Set Icon Visibilities for Modeling Entities
To Set Icon Visibilities for Loads and Constraints
Applying Colors to Simulation Objects
Getting Information on Your Model
Removing Simulation Entities from Your Model
Using Mapkeys
Printing Your Model
Creo Simulate Options
Changing Configuration Settings
Simulation Model
Tolerance Report
Guidelines for Meshing Large Assemblies
Limitations for Meshing Large Assemblies
Model Accuracy
Permanent and Session-based Configuration Files
Configuration File Options
About Configuration File Options
About Unit Settings Option
About Simulation Display Options
About General Modeling Options
About FEM Mode Modeling, Meshing, and Output Options
About Fatigue Options
About Run Options
About Result Display Options
About Miscellaneous Options
Variation in Properties
Online Help
Getting Help for Simulate
Online Help for Simulate
Supplemental Online Documents for Simulate
Help Not Available for Selected Menu Item
Modeling Structure and Thermal Problems
About Creating Models in Creo Simulate
About Regenerating Models
Support for Multibody Models in Creo Simulate
Entering Creo Simulate with Failed Features
Using the Notification Center
Model Type
Setting Up a Model
Default Interface
About Model Types
Creo Simulate Lite
About Creo Simulate Lite
To Run a Creo Simulate Lite Analysis
To Display Simulation Entities in Model Tree
To Create a Model Note
To modify a Model Note
Structure Model Types
3D Model Type
2D Plane Stress Structure Model Type
2D Plane Strain Structure Model Type
2D Axisymmetric Structure Model Type
Thermal Model Type
3D Model Type
2D Plane Stress Thermal Model Type
2D Plane Strain Thermal Model Type
2D Axisymmetric Thermal Model Type
Guidelines for Working with Model Types
Example: 2D Axisymmetric Modeling
Invalid Surfaces for 2D Axisymmetric Models
Invalid Curves for 2D Axisymmetric Models
Example: 2D Plane Strain Modeling
To Specify a Mode and Model Type
To Define 2D Model Types
Features
About Features
Datum Feature Interoperability
Datum Feature Interoperability
Promoting Datum Features
To Promote Simulation Features
Creating Features
Datum Feature Creation
Simulation Feature Creation Methods
Guidelines for Simulation Features
Datum Point
Datum Point
To Create Datum Points
Datum Plane
Datum Plane
To Create Datum Planes
Datum Axis
Datum Axis
To Create Datum Axes
Datum Curve
Datum Curve
To Create a Datum Curve through Points
To Create a Datum Curve from Equations
To Create a Datum Curve Using a Cross Section
Editing Curves in Creo Simulate
To Create a Wrapped Datum Curve
To Copy Curves or Edges
To Create a Projected Datum Curve by Selecting Chains
To Create a Projected Datum Curve by Sketching
To Create a Projected Datum Curve by Cosmetic Sketching
To Offset a Curve Along a Surface
To Intersect Surfaces
To Offset a Curve Normal to Surface
To Trim a Curve or Quilt
Coordinate Systems
About Coordinate Systems
To Create a Coordinate System
Coordinate System Guidelines
Coordinate System Types
Setting a Current Coordinate System
To Set a Current Coordinate System
To Edit a Coordinate System Definition
To Modify an Offset Coordinate System
Coordinate Systems and Functions
Coordinate Systems and Loads and Constraints
Cartesian Coordinate System
Coordinates for Cylindrical UCS
Cylindrical UCS
Coordinates for Spherical UCS
Spherical UCS
Example: Cylindrical Coordinate System
Example: Material Coordinate System for a Cylindrical UCS
Axis and Component Equivalents in Different Coordinate Systems
Datum Reference
Intent Objects
Creating Intent Surfaces from Patterned Geometry
Datum References
To Create Datum References
Using Lattices in Creo Simulate
Working with Homogenized Lattices in Creo Simulate
Regions
Divide Surface
Divide Surface Feature—Creo Simulate
Volume Region
Volume Region
To Create Volume Regions
Split Surface
Separate Surface Region
To Create a Separate Surface Using Automatic Selection of Contours
To Create a Separate Surface Using Manual Selection of Contours
Connections
About Connections
Welds
About Welds
Weld Definition Dialog Box
About Automatic Midsurface Connections
Results When Using Automatic Midsurface Connections
End Welds
End Welds
End Weld Definition
Example: Extend Adjacent Surfaces for End Weld
To Create an End Weld
Perimeter Welds
Perimeter Welds
Perimeter Weld Definition
To Create a Perimeter Weld
Guidelines for Surface-Surface Connections and Interfaces (FEM mode)
Spot Welds
Spot Welds
Spot Weld Definition
To Create a Spot Weld
Weld Feature Welds
Weld Feature
Weld Feature Weld Definition
To Create a Weld Feature Weld
Glued Interface for Weld Features
To Automatically Detect Weld Feature Welds
Fasteners
About Fasteners
About Fasteners
Fastener Modeling Prerequisites
Example: Intervening Geometry
Rotation and Separation in Fasteners
Example: Unwanted Rotation About a Fastener
Creating Fasteners
Fastener Definition Dialog Box—Connecting Shells
Fastener Definition Dialog Box—Connecting Solids
Defining Fasteners Using Diameter and Material
Defining Fasteners Using Spring Stiffness Properties
Modeling Fasteners—Connecting Shells
Modeling Fasteners—Connecting Solids
To Create a Fastener
Account for Stiffness
Opening Models with Fasteners Created in Pre-Creo Simulate 1.0 Releases
Rigid Link
About Rigid Links
To Create a Rigid Link
To Edit a Rigid Link
To Delete a Rigid Link
To Create an Advanced Rigid Link
Example: Rigid Link
Degrees of Freedom for Rigid Links
Rigid Links (FEM mode)
About Rigid Links (FEM Mode)
Rigid Links in NASTRAN
Creating Rigid Links (FEM mode)
Creating Rigid Links
To Create a Rigid Link (FEM Mode)
Rigid Link Icon
Example: Advanced Rigid Link
Weighted Links
About Weighted Links
Creating Weighted Links
To Create a Weighted Link
Example: Weighted Link
Degrees of Freedom for Weighted Links
Reference Entities for Weighted Links
Weighted Link Icon
Weighted Links (FEM mode)
About Weighted Links (FEM Mode)
Creating Weighted Links (FEM mode)
To Create a Weighted Link (FEM Mode)
Interfaces
About Interfaces
Creating Interfaces
Interfaces in Native Mode
Interfaces in FEM Mode
To Create an Interface
Simulation Geometry Dialog Box
To Export Simulation Geometry
Structure Interfaces
Bonded Interfaces
Free Interfaces
Contact Interfaces
To Auto Detect and Create Contacts
Thermal Interfaces
Bonded Interfaces
Adiabatic Interfaces
Thermal Resistance Interface
To Create Adiabatic Interfaces
Interface Types
Example: Interface Types
Precedence Rules for Interfaces
To Create a Bonded Interface
To Create a Contact Interface
To Create a Free Interface
To Create a Thermal Resistance Interface
Gaps
About Gaps (FEM Mode)
Creating Gaps (FEM Mode)
To Create a Gap (FEM Mode)
Surface-Surface Gaps
Y Direction for Gaps
Precedence Rules
Example: Geometric Precedence Rules
Idealizations
About Idealizations
Shells
About Shells
Standard Shells
Shell Definition
Simple Shells
To Define a Simple Shell
Advanced Shells
To Define an Advanced Shell
Surfaces and Curves Used in Shell Definition
Midsurface Shells
Before You Define a Shell Model
Before You Define a Shell Model
Pairing Schemes
Unopposed Surfaces
Model Entities and Idealizations
Gaps in Parts
Gaps in Assemblies
Omit Unopposed Surfaces
Example: Part with Unopposed Surfaces
Example: Collet Illustration
Example: Invalidating a Modeling Entity
Example: T-Bracket
Shell Model Development
Defining Solid or Shell Models
Specifying Mesh Treatment for Models with Midsurfaces
Shell Pair Definition
Edit Shell Pair Definition
To Create a Shell Pair
Auto Detect Shell Pairs
Example: Variable thickness Shell Pairs
Example: Extend Adjacent Surfaces
Example: Unpaired Surface on L-Bracket
Shell Compression
Shell Compression
To Test Shell Compression
To Create Shells
Beams
About Beams
Example: Beam Display
Beam Coordinate Systems
Creating Beams
Beam Definition Dialog Box
Beam References
Beam Type
Y Direction for Beams
To Create a Beam
Extra Tab on Beam Definition Dialog Box
Point–Point Pairs
Masses
About Masses
Native Mode
Mass Definition Dialog Box
Setting a Coordinate System for an Advanced Mass
To Add a Mass to a Point
Masses Based on Components
Guidelines for Assigning Mass Properties
Parameter-Capable Edit Fields
FEM Mode
Mass Definition Dialog Box (FEM mode)
To Add a Mass (FEM mode)
Masses Based on Components (FEM mode)
Properties According to Mass Type (FEM mode)
Springs
About Springs
Guidelines for Spring Creation
Simple Springs
Using Simple Springs
Force-Deflection Curve
To Create a Simple Spring
To Create a Nonlinear Spring
To Ground Springs
Using To Ground Springs
To Create a To Ground Spring
Advanced Springs
Using Advanced Springs
Advanced Spring Restrictions (FEM mode)
Y Direction for Advanced Springs
Orientation for Zero Length Springs in 2D Models
To Create an Advanced Spring
Spring References
Cracks
About Cracks
To Define a Crack
Precedence Rules
Zoom Into Idealizations
Properties
About Properties
Deleting Properties
Background Information
Properties on Idealizations and Geometry
Considerations for Using Properties
Beam Sections
About Beam Sections
Beam Sections Dialog Box
Beam Section Icons
Beam Section Library
Library Lists for Beam Sections, Shell Properties, and Spring Properties
Managing Library Files
Beam Section Definition Dialog Box
General
Area
Iyy, Iyz, Izz
J
Shear FY, Shear FZ
Shear DY, Shear DZ
Stress Grids
Square
Rectangle
Hollow Rect
Channel
I-Beam
L-Section
Diamond
Solid Circle
Hollow Circle
Solid Ellipse
Hollow Ellipse
Sketched Solid and Sketched Thin
Warp & Mass Tab
To Create a Sketched Thin Beam Section
Connections in Thin Wall Beam Sections
To Create Connections for a Sketched Thin Beam Section
Beam Stress Calculations
Beam Section Property Calculations
To Create a Beam Section
Review Beam Section Properties
Beam Orientation
About Beam Orientations
Beam Action Coordinate System
Beam Shape Coordinate System
Beam Centroidal Principal Coordinate System
Beam Orientation Definition Dialog Box
To Define Beam Orientation
Example: Orienting the BSCS Shear Center
Example: Orienting the BSCS to the BACS
Beam Releases
About Beam Releases
Beam Release Definition Dialog Box
Beam Release Icons
To Create a Beam Release
Example: Beam Releases on Composite Curves
Shell Properties
About Shell Properties
Shell Thickness
Shell Property Library
Library Lists for Beam Sections, Shell Properties, and Spring Properties
Managing Library Files
Shell Property Types
Guidelines for Using Shell Properties
About the Shell Properties Dialog Box
Shell Property Definition Dialog Box
Homogeneous Stiffness
Property Type
Laminate Stiffness
Calculating Stresses and Strains
About the Laminate Layup
Example: Laminate Layup
Symmetry Type
About the Material or Sub-laminate Menu
Thickness
Orientation
Example: Laminate Orientation
Count
Parameter-Capable Edit Fields
Working with the Laminate Layup Dialog Box
To Review and Save Laminate Layup and Stiffness
Example: Reviewing Laminate Layup and Stiffness
To Define Shell Properties
Spring Properties
About Spring Properties
Spring Property Library
Library Lists for Beam Sections, Shell Properties, and Spring Properties
Managing Library Files
Defining Spring Stiffness and Damping Properties
Defining Spring Properties for 2D and 3D Models
To Define Spring Properties
Mass Properties
About Mass Properties
Specifying the Off-diagonal Moments of Inertia
Materials
About Materials
Guidelines and Background
Guidelines for Using Materials
About Material Properties
Material Types
Material Property Requirements
Material Property Requirements—Failure Criterion
Material Basics
Material Definition for Native and FEM Mode
Parameter
Reserved Material Parameters
Opening a Model containing Materials from a release before Pro/ENGINEER Wildfire 3.0
Converting the Material Library File to the Pro/ENGINEER Wildfire 3.0 Format
Failure Criterion
Modified Mohr Failure Criterion
Distortion Energy (von Mises) Failure Criterion
Tsai-Wu Failure Criterion
Normalized Tsai-Wu Interaction Term
Compressive Ultimate Stress
Material Library
Material Library
Default Material Library
Units for Materials
Materials
Materials Dialog Box
Assign a Material
Assign a Material
To Assign a Material
To Assign a Creo Simulate Material in Creo+
Create a Material
Material Definition Dialog Box
Create a Material
Density
Structural Options for Material Definition
Thermal Options for Material Definition
To Create a Material
To Create a Hyperelastic Material
To Create a Hyperelastic Material Using Tests
Edit a Material
Edit a Material
To Edit a Material
Copy a Material
Copy a Material
To Copy a Material
Delete a Material
Delete a Material
To Delete a Material
Material Functions
To Create a Table Function
Table Function
Reference Topics - Materials
Hyperelastic Materials
About Material Models
Arruda-Boyce
Coefficient of Thermal Expansion — Isotropic
Graphs for Hyperelastic Material Definition
Hyperelastic Materials in Material Library
Hyperelastic Material
Hyperelastic Material Definition Dialog Box
Tests for Hyperelastic Material Definition
Isotropic
Linear Isotropic Materials
Material Model for Hyperelastic Material Definition
Material Limits
Mooney-Rivlin
Neo-Hookean
Orthotropic
Poisson's Ratio — Isotropic
Poisson's Ratio
Shear Modulus
Tsai Definition for Poisson's Ratios
Polynomial Form of order 2
Reduced Polynomial Form of Order 2
Uniaxial Tests
Biaxial Tests
Planar Tests
Volumetric Tests
Transversely Isotropic
Shear Ultimate Stress
Tensile Ultimate Stress
Yeoh
Coefficient of Thermal Expansion
Young's Modulus
Young's Modulus — Isotropic
Thermal Values for Orthotropic Properties
Thermal Values for Transversely Isotropic Properties
Thermal Values for Isotropic Properties
Guidelines for Fitting the Material Model
Conversion of Tensile Ultimate Stress from Wildfire 4.0 Models
Thermal Conductivity as a Function of Temperature
Elastoplastic Materials
Creating Elastoplastic Materials
To Define an Elastoplastic Material
To Create an Elastoplastic Material Using Tests
Tensile Yield Stress
Coefficient of Thermal Softening
Stress and Strain Data for the Material Definition Dialog Box
Material Assignment
About Material Assignment
Material Assignment Dialog Box
Guidelines for Material Assignment
Material Orientation
About Material Orientation
Default Material Orientation
Guidelines for Material Orientation
Material Orientations Dialog Box
About the Material Orientations Dialog Box
Factors Determining the Selection of Entities
Create a Material Orientation
Material Orientation Definition Dialog Box
About the Material Orientation Definition Dialog Box
Defining Material Orientation for Volumes
To Create a Volumetric Material Orientation
Defining Material Orientation for Surfaces
To Create a Material Orientation for Surfaces
To Create an Orientation for Parts, Solids, Volumes
To Create an Orientation for Surfaces
Rotate About
Order of Rotation
Using the Coordinate System Option
Copy a Material Orientation
To Duplicate a Material Orientation
Material Directions 1, 2, and 3
Example: Material Directions
Projected Vector in WCS
Example: Project a Vector onto a Surface
Structural Constraints
About Structure Constraints
Adding Constraints
Constraints and Loads on Compressed Geometry
Constraints on Compressed Midsurfaces
Constraints, Loads, and Analysis Types
Taking Advantage of Planar Symmetry
Constraints on Entities
Insufficiently Constrained Models
Problems with Loads and Constraints
Problems with Properties
Troubleshooting Constraints
Guidelines for Structure Constraint Sets
Guidelines for Structure Constraint Sets
Understanding Structure Constraint Sets
Guidelines for Structure Constraints
Structure Constraints on Geometry
Structure Constraints and Coordinate Systems
Structure Constraints on Datum Points
Structure Constraints on Regions
Displacement Constraints
Displacement Constraints
Constraint Settings
Constraint Options
Structure Constraint Icons
To Define Displacement Constraints
Guidelines for Prescribed Displacement Constraints
Troubleshooting Your Constraints
Verifying a Constraint
Performing a Body Check for Assemblies
Handling Stress Concentrations
Symmetry Constraints
Symmetry Constraints
Working with Symmetric Models
Cyclic Symmetry Constraints
Cyclic Symmetry Constraints
Guidelines for Cyclic Symmetry
To Add a Cyclic Symmetry Constraint
To Create a Cyclic Symmetry Model Section
To Define a Cyclic Symmetry Constraint
Example: Cut for Cyclic Symmetry
Mirror Symmetry Constraints
Mirror Symmetry Constraints
To Define a Mirror Symmetry Constraint
Example: Axis of Symmetry
Planar, Pin and Ball Constraints
About Surface Constraints
To Define a Planar Constraint
To Define a Pin Constraint
To Define a Ball Constraint
Thermal Boundary Conditions
About Thermal Boundary Conditions
Guidelines for Thermal Boundary Conditions
Guidelines for Thermal Boundary Conditions for Geometry
Boundary Condition Sets
Boundary Condition and Load Sets in Thermal Analyses
Guidelines for Thermal Boundary Condition Sets
Convection Conditions
Convection Conditions
Convection Coefficient, h
Bulk Temperature, Tb
Spatial Variation for Convection Conditions
Time Dependent Convection Condition
Temperature Dependent Convection Condition
To Create a Time-Dependent Convection Condition
To Define Convection Condition
Background
Calculating the Convective Heat Transfer Rate
Calculating the Radiative Heat Transfer Rate
Ramping of Heat Loads and Convection Conditions
Using External Data
External Data for Convection Conditions
Creating FNF Files for External Loads and Constraints
Sample FNF File for External Temperature
Sample FNF File for External Convection Conditions
Sample FNF file for External Pressure Load
FNF Files in Product Data Management
Working in Online and Offline Modes in Creo Simulate
Radiation Conditions
Radiation Conditions
Emissivity, ε
Ambient Temperature
Spatial Variation for Radiation Conditions
Temperature Dependent Radiation Condition
To Define Radiation Condition
Prescribed Temperatures
Prescribed Temperature Conditions
Understanding Thermal Boundary Condition Sets
Spatially Varying Temperatures
Spatially Varying Temperatures
Guidelines for Spatially Varying Temperatures
Interpolated Over Entity
Function of Coordinates
To Define a Prescribed Temperature
Structure Loads
About Loads
About Structure Loads
Applying Loads
Load Basics
Guidelines for Structure Loads
Structure Loads on Geometry
Structure Loads on Points
Structure Loads on Regions
Guidelines for Load Sets
Understanding Load Sets
Guidelines for Load Sets
Force and Moment Loads
Force and Moment Loads
Guidelines for Force and Moment Loads
Specifying Magnitude and Direction for Loads
From and To Fields for Dir Points & Mag
Distribution for Load
Force Per Unit Type
Total Load
Total Load at Point
Total Bearing Load at Point
Force Per Unit Type Guidelines
Spatial Variation
External Coefficients Field
Preview
To Define Force and Moment Loads
Interpolated Over Entity
Function of Coordinates
Example: Function of Coordinates
Function of Arc Length
Load Interpolation
Add for Interpolation
Preview for Interpolation
Remove for Interpolation
Functional Form of Interpolation
Guidelines for Spatially Varying Loads
Example: Spatially Varying Loads
Bearing Loads
Bearing Loads
Guidelines for Bearing Loads
Preview
To Define Bearing Loads
Example: Bearing Load
Example: Bearing Load on a Surface
Example: Bearing Load on an Open Curve
Bolt Preloads
Bolt Preloads
To Create a Prismatic Bolt Preload
To Create a General Bolt Preload
Rules for Setting Solid Type
Centrifugal Loads
Centrifugal Loads
Guidelines for Centrifugal Loads
Strategy: Scaling Results for Centrifugal Loads in a Combined Load Set
From and To Fields for Centrifugal Loads
Preview
To Define Centrifugal Loads
Gravity Loads
Gravity Loads
Guidelines for Gravity Loads
Preview
To Define Gravity Loads
Pressure Loads
Pressure Loads
Guidelines for Pressure Loads
Pressure Load Direction
Preview
To Define Pressure Loads
Load Preview Dialog Box
Color Scale
Example: Auto-mapping an Imported Coefficient Mesh
Example: Pressure Load
Temperature Loads
Temperature Loads
Guidelines for Temperature Loads
Structural Temperature Loads
To Define Structural Temperature Loads
MEC/T Temperature Loads
MEC/T Temperature Loads
Guidelines for MEC/T Temperature Loads
Use Previous Design Study
Step
To Define MEC/T Temperature Loads
MEC/T History Temperature Loads
MEC/T History Temperature Loads
To Define MEC/T History Temperature Loads
Guidelines for MEC/T History Temperature Loads
Use Previous Design Study
Mechanism Loads
Mechanism Loads
To Import Mechanism Loads
How Structure Imports Loads from Mechanism Design
How Loads Transfer to Structure
Mechanism Load Import Dialog Box
Troubleshooting Your Loads
Troubleshooting Loads
Verifying a Load
Reviewing Resultant Loads
To Review Resultant Loads
Load Resultant Dialog Box for Structure Loads
Performing a Body Check for Assemblies
Handling Stress Concentrations
Thermal Loads
About Loads
About Heat Loads
Guidelines for Heat Loads
Heat Loads on Internal Surfaces
Combine Spatial and Temporal Functions
Guidelines for Load Sets
Understanding Load Sets
Guidelines for Load Sets
Example: Load Set
Defining Heat Loads
Load Per Unit Type
Total Load for Heat Loads
Heat Transfer Rate (Q)
Function of Time
To Define Heat Loads
Units According to Model Type and Entity
Defining Component Heat Loads
Heat Transfer Rate (Q)
Function of Time
Reviewing Total Heat Loads
To Review Total Heat Loads
Total Heat Load Dialog Box
Measures
About Simulation Measures
Uses of Measures
Measure Basics
Measure Basics
Guidelines for Measures
Predefined, User-Defined, and Automatically-Defined Measures
UCS-Based Measures
Predefined Measures
Predefined Measures
Predefined Measures in Structure
Predefined Measures in Thermal
User-Defined Measures
User-Defined Measures
Reasons to Create User-Defined Measures
Datum Points for User-Defined Measures
Automatically-Defined Measures
Global and Local Measures
Global and Local Measures
Point Measures
Near Point Measures
Example: Near Point Measures and Geometric Intersection
Example: Near Point Measures and Model Types
Parameter-Based Measures
Parameter-Based Measures
Parameter-Based Measure Basics
Results Specific to a Parameter-Based Parameter
Results for a Specialized Quantity
Setting Up Optimization Goals
Setting Up Optimization Limits
Setting Up Parameters for Regeneration Analyses
Example: Using Parameter-Based Measures
Parameter-Based Measures—Goal
Parameter-Based Measures—Limit
Parameter-Based Measures—Parameters
Coordinate Systems and Measures
Measures and Output
Measures Dialog Box
Measures Dialog Box
Multiple Measure Copy Dialog Box
To Define Measures for Structural Analyses
To Define a Center of Mass Measure
To Define a Displacement Measure
To Define a Driven Parameter Measure
To Define a Failure Index Measure
To Define a Fatigue Measure
To Define a Force Measure
To Define an Interface Measure for Structural Analysis
To Define a Moment Measure
To Define a Moment of Inertia Measure
To Define a Phase Measure
To Define a Rotation Measure
To Define a Rotational Acceleration Measure
To Define a Rotational Velocity Measure
To Define a Stress or Strain Measure
To Define a Stress Intensity Factor Measure
To Define a Time Measure
To Define a Velocity Measure
To Define an Acceleration Measure
To Define Measures for Thermal Analyses
To Define a Heat Flux or Temperature Gradient Measure
To Define a Heat Transfer Rate Measure
To Define a Interface Measure for Thermal Analysis
To Define a Temperature Measure
Measures Definition Dialog Box
Measure Definition Dialog Box
About the Quantity Option for Measure Definition
Using Heat Transfer Rate Measure
Heat Transfer Rate Measure
Define Measures in Structure
Measures for Basic Analyses
User-Defined Measures for Basic Analyses
Basic Analysis Measure Selections
Quantity—Basic Analyses
Component—Basic Analyses
Component—Stress and Strain Quantities
Component—Displacement, Rotation, and Reaction Quantities
Component—Contact Force Quantity
Component—Center of Mass Quantities
Component—Moment of Inertia Quantities
Spatial Evaluation Method—Basic and Dynamic Analyses
Measures for Dynamic Analyses
Measures for Dynamic Analyses
User-Defined Measures for Dynamic Analyses
Quantity—Dynamic Analyses
Component—Dynamic Analyses
Time or Frequency Evaluation Method—Dynamic Analyses
At Each Step—Time or Frequency Evaluation Method
Maximum—Time or Frequency Evaluation Method
Minimum—Time or Frequency Evaluation Method
Maximum Absolute—Time or Frequency Evaluation Method
Time Stamp
Dynamic Analysis Measure Selections
Global Spatial Evaluation Methods
Time/Frequency Eval Options
Measures Not Calculated for Dynamic Random Analyses
Measure Quantities
Stress, Strain
Component—Stress, Strain
Spatial Evaluation—Structure
Radius
Failure Index
Displacement
Rotation
Force
Moment
Computed Measure
Velocity
Acceleration
Rotational Velocity
Rotational Acceleration
Stress Intensity Factor (SIF)
Phase
Phase Type
Time
Fatigue Measures
Interface Measures
Center of Mass
Moment of Inertia
Driven Parameter
Resultant Measure
Time/Frequency Eval
Dynamic Evaluation in Structure
At Each Step
Maximum
Minimum
Max Absolute
RMS
Apparent Frequency
Define Measures in Thermal
User-Defined Measures for Thermal Analyses
Quantity—Thermal Analyses
Component—Thermal Analyses
Spatial Evaluation Method—Thermal Analyses
Time Evaluation Method—Thermal Analyses
At Each Step—Time Evaluation (Thermal Analysis)
Maximum—Time Evaluation (Thermal Analysis)
Minimum—Time Evaluation (Thermal Analysis)
Maximum Absolute—Time Evaluation (Thermal Analysis)
Thermal Analysis Measure Selections
Temperature
Heat Flux, Temperature Gradient
Dynamic Evaluation in Thermal
Spatial Evaluation—Thermal
Results Available for Measures
Selecting One or More Measures
Meshes
Native Mode Meshes
About AutoGEM
Controlling an AutoGEM Mesh
Controlling an AutoGEM Mesh
Maximum Element Size
Edge Length By Curvature Control
Minimum Edge Length
To Control Minimum Edge Length in an AutoGEM Mesh
Isolate for Exclusion (IEAC)
Isolating Elements for IEAC
Guidelines for Using IEAC Mesh Control
Hard Points
Hard Curves
Hard Surface Control
Edge Distribution
To Control Edge Distribution in an AutoGEM Mesh
Prismatic Elements
Requirements for Creating Valid Prismatic Elements
Example: AutoGEM Mesh with Prismatic Control
Thin Solid
Example: AutoGEM Mesh with Thin Solid Control
Requirements for Creating Valid Thin Solid Regions
Auto Detect Thin Solids
Example: Limitations Involving Side Surfaces
Example: Split Surfaces
Precedence Rules
About Mapped Meshing
Mapped Mesh
To Create a Mapped Mesh Control
Example: AutoGEM Mesh with Mapped Mesh Control
Guidelines for Mapped Meshing
Wedge and Tri Mapped Mesh Regions
Ignored AutoGEM Control
Creating an AutoGEM Mesh
Preparing Your Model
AutoGEM Dialog Box
Creating AutoGEM Mesh Elements
AutoGEM File Menu
AutoGEM File Names
AutoGEM Info Menu
Elements with Approximated Linear Edges
Element Types
How AutoGEM Uses Existing Geometry
How AutoGEM Uses Existing Elements
AutoGEM Overconstrained
Surface
Surface
Using Surface
Strategies for Using the Surface Option
Volume
Status Messages
If AutoGEM Completes Successfully
Max Aspect Ratio
Interrupting AutoGEM
AutoGEM Interruption Guidelines
Diagnosing AutoGEM Problems
Using the AutoGEM Log File
Example: Reducing the Element Count
Reduce the Number of Solid Elements
Problems with Elements
Improperly Connected Idealizations
Improperly Constrained Springs, Beams, or Shells
Applying AutoGEM Settings
AutoGEM Settings Dialog Box
Specifying Mesh Treatment for Models with Midsurfaces
Working with Geometry Tolerances
About Geometry Tolerance
Geometry Tolerance Settings Dialog Box
Absolute and Relative Tolerance Settings
Example: Orientation and Tolerance Settings
Required Modeling Entities
FEM Meshes
About FEM Meshes
Transient and Retained FEM Meshes
Transient and Retained Meshes
If You Use Transient Meshes
If You Use Retained Meshes
Meshing Guidelines
Guidelines for Transient Meshes
Guidelines for Retained Meshes
Invalidating a Mesh
Troubleshooting FEM Mesh Generation
Assembly Meshing
Assembly Meshing Methods
Flat Meshing
Hierarchical Meshing
Hierarchical Meshing
Hierarchical Meshing Workflow
Understanding Hierarchical Meshes
Example: Hierarchical Mesh Generation
Connections in Assembly Meshing
Creating Load Paths for FEM Meshing
Load Paths for Flat Meshes
Load Paths for Hierarchical Meshes
Example: Creating Load Paths for Pre-meshed Components
Techniques for Establishing Consistent Hierarchical Meshes
Strategy: Establishing Geometrically-Consistent Node Locations
Controlling a FEM Mesh
Controlling a FEM Mesh
Maximum Element Size (FEM mode)
Minimum Element Size (FEM mode)
Hard Points (FEM mode)
Hard Curves (FEM mode)
Hard Surface Control
Edge Distribution (FEM mode)
Shell Element Direction (FEM mode)
Displacement Coordinate System (FEM mode)
Conflicting Coordinate Systems
Mesh Numbering (FEM mode)
Mesh ID Offset (FEM mode)
About Mapped Meshing
Mapped Mesh
To Create a Mapped Mesh Control
Example: AutoGEM Mesh with Mapped Mesh Control
Guidelines for Mapped Meshing
Wedge and Tri Mapped Mesh Regions
Ignored Mesh Control (FEM mode)
Mesh Control Icons (FEM mode)
Precedence Rules for Mesh Controls
Creating a FEM Mesh
Types of FEM Meshes
To Create a FEM Mesh
Shell Mesh
Mixed Mesh (FEM mode)
About Quilts
FEM Mesh Settings
FEM Mesh Settings Dialog Box
FEM Mesh Settings
Solid-Shell Links
Performing FEM Mode Mesh Operations
Performing FEM Mesh Operations
Importing NASTRAN Files
Guidelines for NASTRAN Deck Import
Improving a FEM Mesh
Reviewing a FEM Mesh
Reviewing a FEM Mesh
Review Nodes Dialog Box
Review Elements Dialog Box
Reviewing Analyses
Checking Elements
Checking a FEM Mesh
Aspect Ratio (FEM mode)
Warp Angle (FEM mode)
Skew (FEM mode)
Taper (FEM mode)
Edge Angle (FEM mode)
Distortion (FEM mode)
Mid Ratio (FEM mode)
Saving a FEM Mesh
FEM Mesh File Names
Retrieving a FEM Mesh
Verifying Models
Checking Your Model
Validity Checking
Structure and Thermal Errors
Structure and Thermal Errors
Missing Properties
Invalid Analysis Definitions
Structure Errors
Structure Errors
Constraint–Constraint Conflicts
Missing Constraints
Thermal Errors
Thermal Errors
Missing Prescribed Temperatures or Convection Conditions
Conflicting Prescribed Temperatures
Creating Analyses
About Analyses
About Creating and Running Analyses and Design Studies
Creating Analyses and Design Studies
Analyses and Design Studies Dialog Box
Analyses and Design Studies Toolbar
Analysis and Design Study Workflow
Modifying Analyses and Design Studies
Analysis Results in Product Data Management
Analysis Types
Displaying Analyses on the Model Tree
Structural Analysis
About Structural Analysis
Constraint and Load Sets in Structural Analyses
Sample Uses for Prestress and Buckling Analyses
Static and Prestress Static Analyses
Static Analysis
Inertia Relief
Load Sets for Analysis
Static Analysis Overview
To Create a Static Analysis
Temperature Distribution for Static Analyses
Prestress Static Analysis
Prestress Static Analysis Overview
To Create a Prestress Static Analysis
Previous Analysis Options for Prestress Analyses
Use Static Analysis Results From Previous Design Study
Load Scale Factor for Prestress Analyses
Combine Results with Results from Previous Static Analysis
To Use Previous Analysis Results in a Prestress Analysis
Sum Load Sets
Constraint Sets for Analysis
Nonlinear Analyses
Nonlinear Options
Large Deformation Static Analysis
Static Analysis of Models with Large Deformation
Static Analysis with Large Deformation Overview
Strain Measures in Large Deformation Static Analysis
About Loads, Idealizations and Connections in Static Analysis with Large Deformation
To Create a Static Analysis with Large Deformation
Example: Large Deformation Analysis for Elastoplastic Materials
To Select Master Steps
Static Analysis of Models with Contact Interfaces
Static Analysis of Models with Hyperelastic Materials
Static Analysis of Models with Elastoplastic Materials
Convergence Options
Convergence Options for Structural Analyses
Convergence Measures
Convergence Method
Multi-Pass Adaptive Convergence Method
Single-Pass Adaptive Convergence Method
Strategy: Improving Convergence
Strategy: Identifying and Resolving Potential Trouble Spots in a Model
Advanced SPA Convergence Control
Convergence Options for Thermal Analyses
Steady Thermal Convergence Method
Transient Thermal Convergence Method
Convergence Percentage Calculation
Convergence Quantities for Steady Thermal Analysis
Local Temperatures and Local Energy Norms
Local Temperatures and Local and Global Energy Norms
Thermal Measures
Convergence Quantity for Buckling Analyses
Convergence Quantity for Modal and Prestress Modal Analyses
Convergence Quantity for Static, Prestress Static, Large Deformation, and Contact Analyses
Check Contact Force
About Press Fit
Localized Mesh Refinement
Press fit (initial interpretation)
Polynomial Order
Guidelines for Entering Polynomial Order
Include Snap-through
To Set Convergence for a Structural Analysis
To Set Convergence for a Thermal Analysis
Percent Convergence
Percent Convergence
Strategy: Specifying Polynomial Order for a Multi-Pass Adaptive Analysis
Convergence Indicators
BLF Convergence
Frequency Convergence
Global Energy Index
Global RMS Stress Index
Local Disp/Energy Index, Local Temp/Energy Index
Measure Convergence
Modal and Prestress Modal Analyses
Modal and Prestress Modal Analyses
Mode Options for Modal and Prestress Modal Analyses
Modal Analysis Overview
Mass of a Supported Part
Number of Modes, All Modes in Frequency Range
Min Frequency, Max Frequency
Constraints and Modal Analysis
To Create a Modal Analysis
To Select Mode Options for a Modal Analysis
Prestress Modal Analysis Overview
To Create a Prestress Modal Analysis
Spin Softening
Temperature Distribution
Units of Modal Frequency Results
Constrained, With Rigid Mode Search
Unconstrained
Buckling Analysis
Buckling Analysis
Buckling Analysis Overview
To Create a Buckling Analysis
Buckling Load Factor and Optimization Studies
Previous Analysis Options for Buckling Analysis
To Use Previous Analysis Results in a Buckling Analysis
Fatigue Analysis
About Fatigue Analysis
Fatigue
To Assign Fatigue Properties to Materials
Fatigue Analysis Overview
About the External Fatigue Material File
Example: External Fatigue Material File
To Use an External Fatigue Material File in a Fatigue Analysis
To Create a Fatigue Analysis
Combination Criteria for Load Histories:
Advanced Tuning for Fatigue Advisor
Adjusting Cyclic Material Properties for Fatigue
Adjusting the Material Confidence Level for Fatigue
Adjusting the Mean Stress Parameter for Fatigue
Adjusting the Biaxiality Parameter for Fatigue
To Define the Load History for a Fatigue Analysis
Load History Options for Fatigue Analysis
Loading Types for Fatigue Analysis
To Use Previous Analysis Results in a Fatigue Analysis
Previous Analysis Options for Fatigue Analysis
Output for Structural Analyses
To Select Output Options for a Structural Analysis
Calculate Quantities for Analyses
Mass Participation Factor Results
Plotting Grid
Output Steps
Number of Master Steps
Thermal Analysis
About Thermal Analysis
Boundary Condition and Load Sets in Thermal Analyses
Steady Thermal Analysis
Steady Thermal Analysis
Nonlinear Steady Thermal Analysis
Steady Thermal Analysis Overview
To Create a Steady Thermal Analysis
Ramp Function
To Select Output Options for a Steady Thermal Analysis
Transient Thermal Analysis
Transient Thermal Analysis
Transient Thermal Analysis Overview
To Create a Transient Thermal Analysis
Temperature Options for Transient Thermal Analysis
To Select Temperature Options for a Transient Thermal Analysis
Initial Temperature Distribution
Use Temperatures from Previous Design Study
Accuracy
Understanding Accuracy
Automatically Smooth Convections
Estimated Variation
To Select Output Options for a Transient Thermal Analysis
Heat Flux
Plotting Grid
Output Steps for Thermal Analyses
Output Options for Thermal Analyses
Time Range
Time Range Specification
User-defined Steps for Thermal Analyses
Vibration Analysis
About Vibration Analysis
Guidelines for Using Dynamic Analyses
Steps in a Dynamic Analysis
Dynamic Time Analysis
Dynamic Time Analysis
Dynamic Time Analysis Overview
Base Excitation for a Dynamic Time Analysis
Translations at Three Points
Output for a Dynamic Time Analysis
Calculate Quantities for a Dynamic Time Analysis
Mode Options for Dynamic Analyses
To Create a Dynamic Time Analysis
To Select Output Options for a Dynamic Time Analysis
Dynamic Frequency Analysis
Dynamic Frequency Analysis
Dynamic Frequency Analysis Overview
Strategy: Displaying Graphs with Logarithmic Scales
Base Excitation for a Dynamic Frequency Analyses
Translations at Three Points
Output for a Dynamic Frequency Analysis
Calculate Quantities for a Dynamic Frequency Analysis
To Create a Dynamic Frequency Analysis
To Select Output Options for a Dynamic Frequency Analysis
Frequency Range
Output Steps
Full Results
User-defined Steps
Time Range
Dynamic Random Analysis
Dynamic Random Analysis
Dynamic Random Analysis Overview
Base Excitation for a Dynamic Random Analysis
Translations at Three Points
Output for a Dynamic Random Analysis
Calculate Quantities for a Dynamic Random Analysis
To Create a Dynamic Random Analysis
To Select Output Options for a Dynamic Random Analysis
Dynamic Shock Analysis
Dynamic Shock Analysis
Direction of Base Excitation for a Dynamic Shock Analysis
To Create a Dynamic Shock Analysis
Output for a Dynamic Shock Analysis
Calculate Quantities for a Dynamic Shock Analysis
Response Spectrum Options for Dynamic Shock Analysis
To Select Load Functions for a Dynamic Analysis
To Select Output Options for a Dynamic Shock Analysis
To Define the Response Spectrum for a Dynamic Shock Analysis
Load Set Functions
Modes Included
To Select Mode Options for a Dynamic Analysis
To Use Previous Analysis Results in a Dynamic Analysis
Damping Coefficient (%)
For Individual Modes
Function of Frequency
Previous Analysis Options for Dynamic Analysis
Use Modes From Previous Design Study
FEM Analysis
About FEM Analysis
FEM Analyses
Defining a FEM Analysis
Defining a Modal FEM Analysis
To Create a FEM Analysis
To Create a Modal FEM Analysis
Point Loads, Point Constraints, Point Heat Loads, Point Prescribed Temperatures, Point Convection Conditions
Excluded Elements Options for Structural Analyses
Excluded Elements Options for Thermal Analyses
Ignore for Excluded Elements
Ignore Heat Flux in Excluded Elements
Limit Polynomial Order for Excluded Element
To Exclude Elements From a Structural Analysis
To Exclude Elements From a Thermal Analysis
Example: Point Loads
Example: Excluded Elements — Point and Line Loads
Example: Excluded Elements — Point Loads
Example: Excluded Elements — Reentrant Corners
Creating Design Studies
About Design Studies
Strategies for Running a Standard Design Study
Design Study Files
Redefine the Design Study
Restrictions When Specifying Multiple Working Directories
Design Variables
Overview of Design Variables
Example: Design Variable
Prepare Your Model for Design Variables
Types of Design Variables
Design Variables
Example: Relations
Design Variables with Laminate Layup
Dimension Selection Dialog Box
Strategy: Using Design Variables
Creating Design Studies
Analyses and Design Studies Dialog Box
To Create a Design Study
To Add a Dimension to a Design Study
To Add a Section Dimension to a Design Study
Defining Variables in a Design Study
Design Study Options Dialog Box
Standard Study for Structure and Thermal
Standard Design Study
To Create a Standard Design Study
Regeneration Analysis
To Run a Regeneration Analysis
Standard Design Study with Variables
Global Sensitivity Study for Structure and Thermal
Global Sensitivity Study
Repeat P-Loop Convergence
Regeneration Analysis
To Create a Global Sensitivity Study
Using Global Sensitivity Studies Effectively
Strategy: Running a Global Sensitivity Study
Varying a Single Variable in a Global Sensitivity Study
Local Sensitivity Study for Structure and Thermal
Local Sensitivity Study
Regeneration Analysis
To Create a Local Sensitivity Study
Strategy: Optimizing a Model
Strategy: After You Run an Optimization Study
Strategy: Defining Optimization Studies
Strategy: Preparing for Optimization Studies
Strategy: Viewing Optimization Results
Optimization Study for Structure and Thermal
Optimization Design Study
Goal
To Define a Goal for an Optimization Study
Design Limits
To Define Design Limits for an Optimization Study
Using Measures More than Once for Optimization Limits
Selecting Load Sets and Modes for Optimization Studies
Track Specific Mode
Optimization Convergence
Optimization Algorithm
Maximum Iterations
Regeneration Analysis
To Create an Optimization Study
To Save an Optimized Shape
Shape Animate
Shape Animate
Example: Shape Animation
To Perform a Shape Animation
Design Variable Errors
Troubleshoot Shape Change Problems
Guidelines for Using Relations
Running Solvers
Native Mode Solvers
Running Analyses and Design Studies
Before You Run an Analysis or Design Study
Before You Run an Analysis or Design Study
Before Creo Simulate Starts a Run
Analyses and Design Studies Dialog Box
Results Menu
Default Result Windows Templates
To Start an Analysis or Design Study Run
Setting Up a Run
Setting Up a Run
Directory for Temporary Files
Directory for Output Files
Elements
Output File Format
Memory Allocation
Use Iterative Solver
Maximum Number of Iterations
After P-Loop Pass
To Select the Iterative Solver
Select the Solver
Start
Start
Existing Design Study Files
Invalid Design Studies
Error Detection
Allowable Errors
Boundary Edges
Boundary Faces
Matching Parameters
Error Detection in Optimization Studies
Temperature Distribution
Error Resolution
Inconsistent Shell Normals
Batch
Creating a Batch File
What Batch Does
Run a Batched Analysis or Design Study
Run Distributed Batch
Stop
Monitoring an Analysis or Design Study Run
Monitoring an Analysis or Design Study Run
Run Status
Summary Report Contents
Standard Studies: Static, Large Deformation Static, Contact, Prestress Static, Modal, Prestress Modal, Buckling, Steady-State Thermal, and Transient Thermal Analyses
Standard Studies: Dynamic Time, Frequency, and Random Analyses
Standard Studies, Dynamic Shock Analyses
Local Sensitivity Studies
Optimization Studies
Local Sensitivity Graph Notes
RMS Stress Error Estimates
Error Messages
Time and Disk Usage Information
Interactive Diagnostics
Summary, Log, and Checkpoints
Troubleshoot Run Problems
Troubleshoot Run Problems
Troubleshoot High Elapsed Run Times
Strategy: Fixing Convergence Problems
Strategy: Using Convergence Graphs to Review Results
mecbatch
mecbatch
Use mecbatch
Sample mecbatch File
msengine
msengine
Use msengine
–w working_dir1;working_dir2;...
Use External Optimizers
To Display Run Errors
FEM Solvers
About Running FEM Analyses and Generating Output Decks
Solving a Model Using an FEA Program
To Review the Mesh
To Solve a FEM Model Online or in the Background
Selecting a Solver
FEM Analysis Types
Element Shape
Fixing Parabolic Elements
NASTRAN Templates
Storing and Retrieving FEA Results
To Create an Output File
Using Solver Results in the Postprocessor
Determining a Run Method
Run Methods
Reviewing a FEM Mesh
Outputting Data to an Offline FEA Program
Output Formats
ANSYS
MSC/NASTRAN
FEM Neutral Format
Outputting to a User-Defined Solver
Creo Simulate Results Window
Results for Native Mode
About Results
Before You Use the Results Command
How Creo Simulate Handles Your Working Model
Working with the Results User Interface
About the Quick Access Toolbar
Selecting geometry in Results User Interface
Results User Interface Ribbon
Results User Interface Ribbon
Displaying Element IDs, Node IDs, and Result Values (FEM mode)
About Command Search
About Minimizing the Ribbon
Graphics Toolbar
Graphics Toolbar
Default View
Spin Center
Refit
Shortcut Menus in Graphics Window
Determining the Minimum and Maximum Locations for a Quantity
Basic Functions for the Results User Interface
Loading Result Windows
Loading Result Windows
Insert Result Windows from Template Dialog Box
Defining Result Windows
Result Window Definition Dialog Box
Study Selection Area
Step/Combination Selection
Display Type Area
Fringe Display Type
Vectors Display Type
Example: Max Principal Stress Vector Plot
Example: Vector Plot
Graph Display Type
Model Display Type
Quantity Tab
Secondary Quantity Menu
Beam Contribution
Recovery Points for Beam Results
Shell Contribution
Maximum and Minimum Shell Values
Top and Bottom Shell Location
Display Location Tab
Component and Layer Visibility in Results
Display Options Tab
Reviewing the Results
Updating Results Window
Quantity for Result Windows
Acceleration Results Quantity
Beam Resultant Results Quantity
Contact Pressure Results Quantity
Contact Tangential Traction Magnitude Result Quantity
Contact Slippage Indicator Results Quantity
Displacement Results Quantity
Element Stress Error Estimate Quantity
Failure Index Results Quantity
Fatigue Results Quantity
Flux Results Quantity
Interface Flux Results Quantity
Measure Results Quantity
P-Level Results Quantity
Reaction Results Quantity
Reaction Results Reporting
Reactions at Point Constraints Quantity
Rotation Results Quantity
Rotation Acceleration Results Quantity
Rotation Velocity Results Quantity
Shear & Moment Results Quantity
Shell Resultant Results Quantity
Strain Results Quantity
Strain Energy Density Results Quantity
Stress Results Quantity
Stress Notes
To Define a Stress Quantity
Temp Gradient Results Quantity
Temperature Results Quantity
Thermal Strain Results Quantity
Types of Measure Results Graphs
Velocity Results Quantity
Quantity Notes for Modal and Dynamic Analyses
Component
Components for Acceleration, Displacement, Reaction, Rotation, Rotation Acceleration, Rotation Velocity, or Velocity
Components for Beam Bending, Tension, Torsion, and Total
Components for Beam Resultant
Components for Fatigue
Components for Flux and Temp Gradient
Components for Reactions at Point Constraints
Components for Shear and Moment
Components for Shell Resultant
Components for Stress or Strain
How Stress Components Relate to Textbook Examples
To Define a Result Window
To Define a Results Display Location
To Display a Result Window
To Specify Result Window Display Options
To Define a Fringe Results Display
To Define a Deformed Results Display
Tips for Fringe Displays
Example: Fringe Display
To Define a Contour Results Display
To Define a Vectors Results Display
To Define a Graph Results Display
Graph Abscissa
To Define a Model Results Display
Contour Results Display
Contour Labels
Relabel Contour
Example: Contour Plot
Limitations of Averaging in Results
Deformed Results Display
To Specify a Result Window Quantity
To Define a Beam Resultant Quantity
To Define a Contact Pressure Quantity
To Define a Contact Slippage Indicator Quantity
To Define a Contact Tangential Traction Magnitude Quantity
To Define a Displacement Quantity
To Define a Failure Index Quantity
To Define a Fatigue Quantity
To Define a Flux or Temp Gradient Quantity
To Define an Interface Flux Results Quantity
To Define a Measure Quantity
To Define a Reaction Quantity
To Define a Reactions at Point Constraints Quantity
To Define a Rotation Acceleration Quantity
To Define a Rotation Quantity
To Define a Rotation Velocity Quantity
To Define a Shear & Moment Quantity
To Define a Shell Resultant Quantity
To Define a Strain Energy Density Quantity
To Define a Strain Quantity
To Define a Stress Error Estimate Quantity
To Define a Temperature Quantity
To Define a Thermal Strain Quantity
To Define a Velocity Quantity
To Define an Acceleration Quantity
Components for Raw and Normalized Stress
Strategy: Interpreting Beam Resultant Forces and Moments
Example: Resultant Force for a Simple Spring or Beam Model
Viewing Results
Viewing Results
Orienting Results
The Orientation Dialog Box
To Tie the Orientation of Multiple Windows
Controlling Result Windows and Model Appearance
Controlling Result Windows and Model Appearance
Visibilities
Overlay
Exploded
Spin Center
Label
To Set Labels
Animating Results Display
Animating Your Results Display
To Animate a Results Display
Displaying Result Windows
To Format a Fringe, Contour, Vector, Model, or Animation Result Window
Example: Comparing Mode Animations for the Same Model
Capping and Cutting Surfaces
Examining Model Interiors for Fringe and Contour Plots
Results Surface Definition Dialog Box
Defining Cutting or Capping Surface References
Defining Reference Planes for Cutting or Capping Surfaces
Defining Cutting or Capping Surface Depth
Dynamic Cutting and Capping Surface Displays
Defining Graph along Reference Planes for Cutting or Capping Surfaces
To Create a Capping Surface
To Create a Cutting Surface
To Modify a Capping Surface
To Modify a Cutting Surface
Arranging Multiple Result Windows
Arranging Multiple Result Windows
To Reorder Result Windows
To Swap Result Windows
Annotating Result Windows
Annotating Result Windows
To Annotate a Result Window
To Customize Annotation Styles
Note Style Dialog Box
Querying Results
Dynamic Query
About the Linearized Stress Report
About the Linearized Stress Report Dialog Box
Calculating the Linearized Stress Value
Component for Linearized Stress Results
About the Linearization Basis
Saving Linearized Stress Results
To Save a Report for Linearized Stress
To Query for Linearized Stress
Querying Quantities for Fringe Plots and Linearized Stress Analyses
Querying on Cutting or Capping Surfaces
To Query for Linearized Stress on Cutting or Capping Surfaces
Clearing Query Tags from a Result Window
Evaluating Results
Evaluating Results
Generate Report for Measure Results
Measures Dialog Box
Evaluating Fringe Contour and Vector Plots
Adjusting the Legend
Adjusting the Fringe, Contour, and Vector Legends
Edit Legend Dialog Box
Adjusting Color Scale for Fringe, Contour, and Vector Legends
Using Maximum and Minimum Legend Values to Get More Details
Saving Spectrum
Comparing Results
Probing Fringe, Contour, and Vector Plots
Shading Your Model
Evaluating Graphs
Managing Graphs
Customizing Graph Display Settings
Probing Graphs
To Segment a Graph
Segmenting a Graph
Evaluating Animations
Controlling Animations
Comparing Animations
Example: Comparing Mode Animations for the Same Model
Example: Comparing Animation Stages for the Same Model
Reviewing and Editing Result Windows
To Edit a Result Window
Copying, Deleting and Editing Result Windows
About Saving Results in Creo Simulate
About Saving Results in Creo Simulate
Save Options in Creo Simulate Results
Graph Report
Excel
HTML Report
To Export a File in HTML
Export HTML Dialog Box
About HTML Report Preferences File
Export HTML Setup Dialog Box
Graphic Size
Alignment
Export Movie
Movie Export Dialog Box
To Export a File as a Movie
NASTRAN Mesh
To Export a Surface Mesh in NASTRAN format
Creo View
VRML
To Mail Analyses Results
To Save Results to the Active Workspace
To Save Results as HTML Reports to the Active Workspace
Printing Result Windows
Output Format
Paper
Sample HTML Report Preferences File
Results for FEM
About FEM Results
Using the Postprocessor in FEM Mode
Loading NASTRAN Results Database
Graphical Result Windows
Viewing FEM Analysis Results
Supported FEA Solvers
Diagnostics and Troubleshooting in Creo Simulate
Diagnostics
Diagnostics Menu
Diagnostics Messages
Singularities
Singularities
Singularities and Constraints
Singularities and Loads
Strategy: Minimizing Singularities
Selecting Singularities for IEAC
Best Practices in Creo Simulate
Best Practice: Using Failure Index Results to Predict Material Failure in a Model
Maximum Shear Stress (Tresca) Failure Criterion
Maximum Strain Failure Criterion
Maximum Stress Failure Criterion
Best Practice: Using Fasteners in Creo Simulate
Best Practice: Using Composite Structures in Creo Simulate
Creo Simulate Verification Guide
Verification Overview
Static Analysis Problems
Modal Analysis Problems
Steady-State Thermal Analysis Problems
Transient Thermal Analysis Problems
Dynamic Time Response Analysis Problem
Dynamic Frequency Response Analysis Problem
Dynamic Shock Response Analysis Problem
Dynamic Random Response Analysis Problems
Buckling Analysis Problems
2D-3D Contact Analysis Problems
Static Analysis with Large Deformation Problem
Static Analysis with Plasticity Problems
Prestress Modal Analysis Problem
Optimization Analysis Problem
Additional Information
Units
About Units
Guidelines for Specifying Units
Specifying Units for Simulation Entities
Units Manager Dialog Box
Systems of Units Management
Predefined Systems of Units
Set the Principal System of Units
To Set a Principal System of Units
Custom System of Units
To Create a Custom System of Units
To Edit a Custom System of Units
To Review a System of Units
Units Management
Predefined Units
Custom Units
To Create a Custom Unit
To Edit a Custom Unit
To Review an Individual Unit
To Convert Simulation Values to Principal System of Units
Unit Conversion Tables
Units for Result Window
Working with Functions
Functions Dialog Box
Use of Function Definitions
Function Definition Dialog Box
Function Definition Dialog Box
Symbolic Function Type
Independent Variables
Valid Symbols
Table Function
Interpolation Method
Graph Function Dialog Box
Function Graphs
Function—Material Properties
Stability Check
Table Force-Deflection Functions beyond the specified Range
To Create a Function
To Create a Symbolic Function
Working With Normals
Surface Normals
Surface Normals
Normal Direction for Surfaces and Shells
Specifying Y Direction for Beams
Shell Normals
Improving Performance
Improving Performance
Managing RAM, Solram and Swap Space
Memory Usage—Different Scenarios
Managing Performance
Guidelines for Allocating RAM for Solver and Element Data
Guidelines for Managing Disk Space Resources
Guidelines for Disk Usage and Allocating Swap Space
Guidelines for Setting Solram
Strategy: If Solver RAM Is Too High
Strategy: If Solver RAM Is Too Low
Strategy: Running the Engine with Parallel Processing
Background Information
Long-Term Limitations
Icons Used in Creo Simulate
Bibliography
The Database
Database Considerations
Files Created by Creo Simulate
Information Transfer
FEM Neutral Format File
Specialized Information
Understanding Fatigue Analysis
Shell Property Equations
Relative To
Results Relative to Beam Orientation
Results Relative to Coordinate
Results Relative to Coordinate Systems
Results Relative to Curve Arc Length
Results Relative to Material Orientation
Results Relative to Ply Orientation
Glossary
Glossary for Creo Simulate
Mechanism Design 與 Mechanism Dynamics
Mechanism Design 和 Mechanism Dynamics 概觀
關於機器設計和 Mechanism Dynamics
關於 Mechanism Design、Mechanism Dynamics 和 Design Animation
關於機構使用者介面
關於機構樹
關於顯示資訊
範例:詳細摘要
關於機構故障診斷
Mechanism Design 和 Mechanism Dynamics 的組態選項
機構設計
使用 Mechanism Design Kinematics
Mechanism Design Kinematics 工作流程
檢查您的模型
為 Mechanism Design Kinematics 新增建模圖元
準備進行方位或運動分析
執行方位或運動分析
在 Mechanism Dynamics 中儲存和檢視分析結果
建立機器模型
要組裝機構模型
要編輯機構模型
為 Mechanism Design 建立模型
提示:修復失敗的組件
Mechanism Design 設定
定義機構設定
定義撞刀偵測設定值
關於進階拖曳選項
連接對與自由度
關於預定義的條件約束集
關於重新定義中斷連接的元件
關於繼承槽從動件連接
關於自由度
計算自由度和重複限制
關於重複限制
運動軸設定
關於運動軸設定
關於運動軸對話方塊
指定運動軸設定
關於再生值
設定再生值
設定範圍限制
關於動態屬性
指定摩擦
關於還原係數
剛性主體
關於 Mechanism Design 剛性主體
將元件重新定義為基底
欲反白剛性主體
凸輪
關於凸輪從動件連接
建立凸輪從動件連接
定義凸輪從動件連接的屬性
關於允許升離的凸輪從動件連接
關於凸輪從動件連接設計
關於用於凸輪從動件連接的曲面
關於用於凸輪從動件連接的曲線
關於凸輪從動件連接的深度參照
編輯凸輪從動件連接
在拖曳操作中使用凸輪從動件連接對
刪除凸輪從動件連接
建模圖元
齒輪
關於類屬齒輪對
關於動態齒輪對
動態齒輪對的類型
欲建立動態齒輪對
欲建立類屬齒輪對
欲建立正齒輪對
欲建立斜齒輪對
欲建立蝸桿齒輪對
欲建立齒條和小齒輪對
定義齒輪對定向
編輯齒輪對
在機構動態分析中使用齒輪對
關於類屬和動態齒輪的量測
伺服馬達
關於伺服馬達
瞭解幾何馬達
欲定義馬達
欲編輯馬達
欲定義表格馬達函數
欲定義使用者定義的馬達函數
關於 SCCA 馬達函數的設定
使用者定義的運算式定義
欲定義使用者定義的馬達函數
關於運算式圖形對話方塊
關於函數對話方塊
關於運算子對話方塊
關於變數對話方塊
關於常數對話方塊
帶和滑輪
關於帶和滑輪
關於帶和滑輪使用者介面
欲建立帶和滑輪系統
分析
方位分析
關於方位分析
建立方位分析
輸入方位及運動分析的偏好設定
運動學分析
關於運動分析
建立運動學分析
量測、圖形與計算方法
量測
關於量測結果
圖形化量測結果
關於量測結果對話方塊
關於與模型圖元關聯的量測
建立量測
量測類型
方位、速度與加速度
關於方位、速度及加速度量測
建立槽從動件脈衝量測
元件
插銷連接對反作用分量的量測
滑桿連接對反作用分量的量測
圓柱體連接對反作用分量的量測
球連接對反作用分量的量測
平面連接對反作用分量的量測
軸承連接對反作用分量的量測
焊接連接對反作用分量的量測
6DOF 連接對反作用分量的量測
一般連接對的分量
槽從動件連接對反作用分量的量測
量測剛性主體角速度、角加速度以及質心的分量
量測剛性主體質心慣性的分量
量測剛性主體定向的分量
系統線性動量、角度動量以及質心的分量量測
系統質心慣性分量的量測
其他量測
關於系統量測
建立系統量測
關於剛性主體量測
欲建立剛性主體量測
關於分隔量測
建立分隔量測
關於凸輪量測
關於使用者定義量測
建立使用者定義量測
關於使用者定義量測的數量
圖形
關於多個圖形
關於圖形化
計算方法
關於計算方法
關於偶爾評估方法
關於積分計算方法
範例:計算方法
軌跡曲線
關於追蹤曲線
關於追蹤曲線對話方塊
建立追蹤曲線
編輯 3D 軌跡曲線
使用分析結果
錄放
關於錄放
關於「錄放」對話方塊
播放結果集
欲在錄放時追蹤量測
關於影片時間表
關於顯示箭頭
關於顯示箭頭可用的量測
關於顯示箭頭可用的輸入負載
將結果集儲存到檔案中
還原已儲存的結果集檔案
關於動畫對話方塊
關於捕捉對話方塊
攫取錄放結果集
建立運動包絡
關於建立運動包絡對話方塊
欲移除錄放結果集
欲匯出錄放結果集
機構動態
使用 Mechanism Dynamics
為 Mechanism Dynamics 建立模型
Mechanism Dynamics 工作流程
為 Mechanism Dynamics 新增建模圖元
在 Mechanism Dynamics 中使用伺服馬達
在 Mechanism Dynamics 中準備分析
在 Mechanism Dynamics 中執行分析
初始條件
關於初始條件
關於初始條件定義對話方塊
建立初始條件
編輯初始條件
欲從播放建立初始條件
指定速度向量的方向
提示:使用初始條件
關於不相容的初始條件
關於初始條件的驗證檢查
使用拖曳對話方塊設定初始條件的運動軸方位
「終止條件」(Termination Conditions)
關於終止條件
欲建立終止條件
範例:使用終止條件
建立終止條件的指導方針
質量内容
關於質量屬性
關於質量屬性對話方塊
指定零件的質量屬性
指定組件的質量屬性
關於慣性
3D 接觸面
關於 3D 接觸面使用者介面
關於 3D 接觸面
欲建立 3D 接觸
建模圖元
執行馬達
關於執行馬達
力與扭矩
關於力和扭矩
欲建立力或扭矩
欲編輯力或扭矩
重力
關於重力
關於「重力」對話方塊
欲定義或編輯重力
刪除重力
關於凸輪從動件摩擦
彈簧與阻尼器
關於彈簧
關於彈簧使用者介面
建立彈簧
編輯彈簧
關於阻尼器
關於阻尼器使用者介面
建立阻尼器
編輯阻尼器
要在組件模型樹中顯示彈簧和阻尼器
「導套負載」(Bushing Loads)
關於導套負載
欲建立導套負載
自訂負載
關於自訂負載
關於自訂負載函數
關於函數與其引數值
建立自訂負載應用程式指南
自訂負載應用程式使用指南
分析
關於分析
關於「分析定義」對話方塊
執行分析
提示:執行分析
關於分析的鎖定圖元
複製分析
刪除分析
編輯分析定義
指定分析的馬達
指定分析的外部負載
啟用所有摩擦
啟用重力
輸入外部負載資訊
輸入馬達資訊
關於分析的驗證檢查
儲存和檢視方位或運動分析結果
動態分析:
關於動態分析
建立動態分析
定義動態分析的偏好設定
輸入動態分析的偏好設定
力平衡分析
關於力平衡分析
建立力平衡分析
定義力平衡分析的偏好設定
欲輸入力平衡分析的偏好設定
靜態分析
關於靜態分析
建立靜態分析
輸入靜態分析的偏好設定
範例:靜態分析
量測
關於連接反作用量測
建立連接對反作用量測
欲使用特定座標系建立連接反作用量測
其他量測
關於淨負載量測
關於比較淨負載與連接反作用量測
建立淨負載量測
關於測力計反作用量測
建立測力器反作用量測
建立測力器鎖
關於碰撞量測
建立碰撞量測
關於脈衝量測
建立運動軸脈衝量測
建立凸輪從動件脈衝量測
關於凸輪從動件連接的滑動分量
建立凸輪量測
建立凸輪從動件連接對反作用量測
建立位置、速度或加速度量測
傳輸至 PTC Creo Simulate 的負載
關於將負載轉移至 Creo Simulate 結構模式
關於負載匯出對話方塊
關於負載資訊清單
匯出負載至 Creo Simulate Structure 模式的指南
如何將負載轉移至 Creo Simulate Structure 模式
欲匯出負載至 Creo Simulate 結構模式
範例:凸輪組件的負載轉移
字彙表
Mechanism Design 術語表
設計動畫
設計動畫概觀
設計動畫
關於設計動畫
關於動畫
關於動畫使用者介面
建立動畫
定義動畫
設定快照動畫
設定爆炸動畫
執行動畫
欲編輯動畫
定義剛性主體
關於剛性主體
欲建立剛性主體
關於剛性主體定義對話方塊
建立關鍵畫面序列
關於關鍵畫面序列
關於關鍵畫面序列對話方塊
定義關鍵畫面序列
欲控制關鍵畫面序列中的剛性主體
關於管理關鍵畫面序列
關於關鍵畫面序列對話方塊上的剛性主體標籤
關於關鍵畫面序列對話方塊上的序列標籤
關於 KFS 例證對話方塊
範例:參照剛性主體
建立伺服馬達
關於伺服馬達
建立伺服馬達
欲管理伺服馬達
關於幾何伺服馬達
欲定義表格馬達函數
欲建立使用者定義的馬達函數
範例:馬達輪廓的類型
關於 SCCA 伺服馬達函數
關於圖形化
在動畫中包括伺服馬達
定義伺服馬達時間
關於運動軸設定
設定運動軸設定
定義運動零點參照
鎖定剛性主體
關於鎖定剛性主體
欲鎖定剛性主體
定義連接對狀態
關於連接對狀態
欲定義連接對狀態
關於連接對圖示
定義事件
關於事件
欲定義事件
包括子動畫
關於子動畫
關於子動畫對話方塊
執行和重播動畫
關於錄放
欲錄放動畫
關於動畫工具列
關於捕捉對話方塊
關於建立運動包絡對話方塊
定義時域
關於時域
設定時域
關於時域類型
定義視圖
關於偶爾檢視對話方塊
定義動畫的視圖
定義顯示樣式
關於「偶爾樣式」對話方塊
欲定義動畫的顯示樣式
定義設定
關於動畫設定
定義動畫設定
定義透明度
關於偶爾透明度
關於偶爾透明度對話方塊
定義動畫的透明度
關於內插對話方塊
Design Animation 時間表
關於動畫時間線
變更時間表顯示
字彙表
設計動畫術語表
Creo Flow Analysis
Creo Flow Analysis 入門
CFA 之工作流程
Creo Flow Analysis 介面
精靈
運算式編輯器
運算式編輯器基礎
函數
變數
全域變數
模組相關變數
範例
新增散逸曲線
驗證案例
驗證案例
熱傳遞
亂流
層流
DrivAer
高等物理 - 空蝕與多成分混合
高等物理或潰壩
預處理
流體域萃取
逸流封閉 (SEALS)
逸流封閉 (SEALS) 特徵
網格化
定義實體
定義實體
流動
流動 - 簡介
定義
實體
流動模型
條件
條件
材料屬性
邊界條件
阻力模型
非慣性框架
來源
初始條件與狀態
輸出變數
亂流
亂流 - 簡介
定義
實體
物理
壁實體
亂流模型
條件
條件
亂流黏度
邊界條件
來源
初始條件與狀態
輸出變數
熱
熱 - 簡介
定義
實體
物理
熱模型
條件
條件
材料內容
邊界條件
介面條件
來源
初始條件與狀態
輸出變數
多相
多相 - 簡介
定義
物理
尤拉模型與統御方程式
流體體積 (VOF) 模型的特殊考量
數值考量
條件
材料屬性
邊界條件
初始條件與狀態
輸出變數
氣蝕
空蝕 - 簡介
定義
物理
統御方程式
空蝕模型理論
空蝕模型
空蝕邊界建模
條件
材料屬性
邊界條件
初始條件與狀態
輸出變數
輻射
輻射 - 簡介
定義
物理
熱輻射的特性
辐射熱傳建模
條件
材料屬性
來源
邊界條件
多成分混合
多成分混合 - 簡介
定義
物理
條件
材料屬性
初始條件與狀態
邊界條件
輸出變數
粒子
粒子 - 簡介
實體
離散粒子模型
粒子沖蝕建模
粒子參數
邊界條件
粒子輸出
流線
流線 - 簡介
定義
物理
邊界條件
體積塊條件
顯示設定
動態
動態 - 簡介
定義
實體
剛體運動
ODE 求解器
條件
平移
平移力平衡模型 (1 DOF)
旋轉
旋轉力平衡模型 (1 DOF)
邊界條件
輸出變數
種類
物種 - 簡介
定義
實體
條件
材料屬性
邊界條件
初始條件與狀態
輸出變數
通用
一般 - 簡介
定義
條件
數值與收斂度
數字
收斂度
電場
定義
實體
條件
材料屬性
來源
邊界條件
介面條件
初始條件與狀態
聲學
模組參數
邊界或體積塊條件
輸出變數
PID 控制器
實體
控制器參數
輸出變數
針對結構模擬建立 FNF 檔案
執行模擬
後處理
模擬
後處理
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