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3. Bob Gilliver MSC/ARIES European Product Marketing and Support Manager
4. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
5. GeometryFull function ACIS based modelerConstraintsfull partial noneACIS data exchangeAutoCADBentleyIntegraphHP
6. GeometryModify dimensions
7. GeometryModification by dimensionParametric relationships
8. GeometryComplex solidsSkin operatorSweep operatorExtensive blending and chamferingRegion operator to sub-divide geometryMap meshingLoad footprint areasSymmetry
9. MSC/ARIES Base - AssembliesVisualizationPackagingClearance InterferenceMass properties
10. MSC/ARIES Base - Mass Properties
11. Geometry - Regioning
12. Geometry - Regioning
13. Geometry - Regioning
14. Geometry - Regioning
15. Pre Release Solids ShellingShelling of solids to
16. Analysis Of ACIS &Imported GeometryCADARIES
17. Geometry Interface - ACISSupport for ACIS sat
18. Geometry Interface - Autocad Import
19. Geometry Interface - Autocad Import
20. Geometry Interface - Autocad ImportLin. Static Error Contours
21. Geometry Interface - Autocad Export
22. Geometry Interface - IGES ImportSupportsWireframe Point, line,
23. Geometry Interface - IGES ExportSupportsWireframe Point, line,
24. Geometry Interface - DXF ImportWireframePoint, line, arc, polylineText
25. Geometry Interface - DXF ExportSupportsWireframe Point, line,
26. Geometry Interfaces - STEP, VDAFSPDES/STEP AP203Import and
27. Geometry Interfaces -StereolithographyTranslates solids into standard “stl” formatRapid manufacture for physical part prototyping
28. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
29. LBC’s applied to geometry or to nodes
30. Constant or functional varying magnitude Geometry based
31. Load and Boundary ConditionsDirection control for load/boundary conditionsXYZRadialTangential
32. Load and Boundary ConditionsLoad case combination (5 * load_1) + (3 * load_2)
33. Automeshing technologyEdges -- 1D elements (beam, gap, rigid, spring)Surfaces -- quad
34. Auto MeshingSolid Element Automesh
35. FE MeshingAdaptive mesh refinementAutomatic mesh refinement to
36. Original mesh -
37. FE MeshingDirect creation of nodes/elementsExtrude/revolve 1D to
38. Display optionsVectorContourGraphAnimationCutting planeResults in any coordinate systemData averaging controlResults combinationError calculationResults Review
39. Linear StaticsLoads constant with timeMaterial assumed linear and perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force
40. Normal ModesCalculates undamped natural modes of vibrationMaterial assumed linear and perfectly elasticResults calculated (normalized)StressDisplacementStrainStrain energyReaction force
41. Linear BucklingCalculates load factor for critical bucklingMaterial assumed linear and perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force
42. Non-Linear StaticsGeometric non-linearityChange in stiffness associated with
43. Non-Linear StaticsNon-linear Elastic Material
44. Structures-2 Non-Linear Statics Load FollowingDeformed - load followingDeformed - load followingFFFUndeformed
45. Linear Transient DynamicsTime varying geometry and finite
46. Heat TransferSteady state and transient linear and
47. Heat Transfer
48. MSC/ARIES To MSC/PATRANARIES Created Geometry
49. MSC/ARIES To MSC/PATRANImported ARIES Geometry in MSC/PATRAN
50. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
51. OptimizationAn Automated Process That:Satisfies Your Design Objective Within Design Constraint(s) By Modifying Design Variables
52. Optimization - Overview1 Design Objective minimize/maximize weight,
53. Optimization - OverviewShape Geometry dimensions as design
54. Initial Design
61. Final Design
62. Optimization - ApplicationBuild solid or surface geometryAssociate
63. Optimization - ApplicationCreate finite element modelSelect Optimization
64. R1L2L1R3R2DEP INDEPR1
65. Optimization - Results ReviewPost process in Optimization
67. P-Elements - OverviewAutomatically increases element’s shape function
68. P-Elements - OverviewEach edge of each element has its p-order independently controlled in MSC/NASTRAN552314
69. P-Elements - ApplicationSupported element typesTetrahedronBrickPentahedron (wedge)p-order min/max
70. P-Elements - ApplicationConstrains shared edges to
71. P-Elements - ApplicationHex to tet mesh connection
72. P-Elements - Results Reviewp-element results review identical to h-elementsCan display final p element order contours
73. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
74. Two- and three-dimensional mechanism modeling analysis and
75. Create link geometryGeometry can be solid, surface
76. Mechanisms Results ReviewAnimated motion of linksMotion path
77. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
78. Plastics3D mold fill analysisUses Moldflow/Flowcheck solverSolves “Will
79. PlasticsMSC/ARIES Created Solid
80. PlasticsMold Fill Time Contours
82. Modular Configuration
83. Modular Configuration
84. MSC/ARIES Base
85. Optional Modules
86. Platform Support WindowsNTSun SolarisSGIHPIBMDigital Unix
87. Intel based (not Digital NT)Recommend >= Pentium
88. Supported Unix workstation32Mb RAM125 Mb swap spaceLicensingNode-lock, andFloating network licensePlatform Requirements - Unix
89. GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning
90. MSC/ARIES PositioningStandalone Design and Analysis SystemDesigned and
91. StructuralThermalMechanismsPlastic Molding AnalysisMSC/ARIES Positioning
92. MSC/ARIES The Flow of DevelopmentProductAlmost all design concepts will be decided
93. Positioning of MSC/ARIESFEA AnalystDesign EngineerLow priceHigh priceStatic-Eigenvalues-Optimization-Heat-Dynamic-Nonlinear-Electromagnetic-Crash-NVHEasy
94. Positioning of MSC/ARIESEndStartManufacturing ProcessManufacturingBill of MaterialsMaterial DatabaseDraftingAnalysisOptimizationModelingDesignMSC/ARIESPredictive EngineeringCAD linkedCAD SystemModification Costs
95. Positioning of MSC/ARIESMSC/ARIESTargeted UserNon-FE SpecialistGeometry Based AnalysisConceptual
96. Positioning of MSC/ARIESGuide line thought / Question ProcessCAD SystemImport GeometryCreateGeometryFEAwareN4WARIESPoss.No SaleConflict WithExistingModellerNeed ToCreateDrawingsACIS DraftingPackage (AutoCAD etc)NOYes
97. THE END
98. Mentor BoardStation InterfaceBi-directional interface using Mentor IDF
99. Скачать презентацию
100. Похожие презентации

Bob Gilliver MSC/ARIES European Product Marketing and Support Manager

Bob Gilliver MSC/ARIES European Product Marketing and Support Manager

GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning

GeometryFull function ACIS based modelerConstraintsfull partial noneACIS data exchangeAutoCADBentleyIntegraphHP

GeometryModification by dimensionParametric relationships

GeometryComplex solidsSkin operatorSweep operatorExtensive blending and chamferingRegion operator to sub-divide geometryMap meshingLoad footprint areasSymmetry

MSC/ARIES Base - AssembliesVisualizationPackagingClearance InterferenceMass properties

Pre Release Solids ShellingShelling of solids to thin walled solidsPer face (uniform)

Analysis Of ACIS &Imported GeometryCADARIES

Geometry Interface - ACISSupport for ACIS sat (ASCII) and sab (binary) file

Geometry Interface - Autocad ImportLin. Static Error Contours

Geometry Interface - IGES ImportSupportsWireframe Point, line, arc, composite curve, spline (112,126),

Geometry Interface - IGES ExportSupportsWireframe Point, line, arc, composite curve, spline (112,126),

Geometry Interface - DXF ImportWireframePoint, line, arc, polylineText

Geometry Interface - DXF ExportSupportsWireframe Point, line, arc, composite curve, spline Solid/surfaceDecomposed

Geometry Interfaces - STEP, VDAFSPDES/STEP AP203Import and export of solid/surface/wireframe dataVDAFSImport and

Geometry Interfaces -StereolithographyTranslates solids into standard “stl” formatRapid manufacture for physical part prototyping

LBC’s applied to geometry or to nodes & elements Supported loadsForce, moment,

Constant or functional varying magnitude Geometry based load and boundary conditions survive

Load and Boundary ConditionsDirection control for load/boundary conditionsXYZRadialTangential

Load and Boundary ConditionsLoad case combination (5 * load_1) + (3 * load_2)

Automeshing technologyEdges -- 1D elements (beam, gap, rigid, spring)Surfaces -- quad dominant or all triasVolumes -- tets onlyMap

FE MeshingAdaptive mesh refinementAutomatic mesh refinement to optimize mesh density Use with

Original mesh - 21 % ErrorRefined mesh -

FE MeshingDirect creation of nodes/elementsExtrude/revolve 1D to 2D, 2D to 3DMirrorMesh editingElement

Display optionsVectorContourGraphAnimationCutting planeResults in any coordinate systemData averaging controlResults combinationError calculationResults Review

Linear StaticsLoads constant with timeMaterial assumed linear and perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force

Normal ModesCalculates undamped natural modes of vibrationMaterial assumed linear and perfectly elasticResults calculated (normalized)StressDisplacementStrainStrain energyReaction force

Linear BucklingCalculates load factor for critical bucklingMaterial assumed linear and perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force

Non-Linear StaticsGeometric non-linearityChange in stiffness associated with large deformations Load follows deformed

Non-Linear StaticsNon-linear Elastic Material

Structures-2 Non-Linear Statics Load FollowingDeformed - load followingDeformed - load followingFFFUndeformed

Linear Transient DynamicsTime varying geometry and finite element loadsStructural and modal dampingResults

Heat TransferSteady state and transient linear and non-linear heat transfer Heat

MSC/ARIES To MSC/PATRANARIES Created Geometry

MSC/ARIES To MSC/PATRANImported ARIES Geometry in MSC/PATRAN

OptimizationAn Automated Process That:Satisfies Your Design Objective Within Design Constraint(s) By Modifying Design Variables

Optimization - Overview1 Design Objective minimize/maximize weight, frequency, load factor‘n’ Design Constraints

Optimization - OverviewShape Geometry dimensions as design variablesSizing (element properties) Shell thickness,

Optimization - ApplicationBuild solid or surface geometryAssociate dimension variables in Parametrics:Use as

Optimization - ApplicationCreate finite element modelSelect Optimization application1 Design Objective minimize/maximize:weight, frequency,

Optimization - Results ReviewPost process in Optimization applicationGraph design objective/ constraint(s)/ variable(s)

P-Elements - OverviewAutomatically increases element’s shape function polynomial order during solution until

P-Elements - OverviewEach edge of each element has its p-order independently controlled in MSC/NASTRAN552314

P-Elements - ApplicationSupported element typesTetrahedronBrickPentahedron (wedge)p-order min/max controlRecommended p-order range 3-10Adaptivity automatically

P-Elements - ApplicationConstrains shared edges to p-order = 1Can mix h

P-Elements - ApplicationHex to tet mesh connection works identically for p-elements: Automatic

P-Elements - Results Reviewp-element results review identical to h-elementsCan display final p element order contours

Two- and three-dimensional mechanism modeling analysis and results reviewUses MDI/ADAMS Kinematics solver

Create link geometryGeometry can be solid, surface or wireframeAdd joints (supports all

Mechanisms Results ReviewAnimated motion of linksMotion path of any pointJoint reaction force/momentRotational/translational

Plastics3D mold fill analysisUses Moldflow/Flowcheck solverSolves “Will It Fill”Fast analysis to calculate

Platform Support WindowsNTSun SolarisSGIHPIBMDigital Unix

Intel based (not Digital NT)Recommend >= Pentium 75MHz, 32Mb RAM125 Mb swap

Supported Unix workstation32Mb RAM125 Mb swap spaceLicensingNode-lock, andFloating network licensePlatform Requirements - Unix

MSC/ARIES PositioningStandalone Design and Analysis SystemDesigned and analyzed in MSC/ARIESAnalysis of ACIS

StructuralThermalMechanismsPlastic Molding AnalysisMSC/ARIES Positioning

MSC/ARIES The Flow of DevelopmentProductAlmost all design concepts will be decided

Positioning of MSC/ARIESFEA AnalystDesign EngineerLow priceHigh priceStatic-Eigenvalues-Optimization-Heat-Dynamic-Nonlinear-Electromagnetic-Crash-NVHEasy to use

Positioning of MSC/ARIESEndStartManufacturing ProcessManufacturingBill of MaterialsMaterial DatabaseDraftingAnalysisOptimizationModelingDesignMSC/ARIESPredictive EngineeringCAD linkedCAD SystemModification Costs

Positioning of MSC/ARIESMSC/ARIESTargeted UserNon-FE SpecialistGeometry Based AnalysisConceptual CAE Tool & ModellerACIS imported

Positioning of MSC/ARIESGuide line thought / Question ProcessCAD SystemImport GeometryCreateGeometryFEAwareN4WARIESPoss.No SaleConflict WithExistingModellerNeed ToCreateDrawingsACIS DraftingPackage (AutoCAD etc)NOYes

Mentor BoardStation InterfaceBi-directional interface using Mentor IDF 2.0 file formatImports Mentor Board

Mentor BoardStation InterfaceSupports board holes, vias, keep out and keep within areas2D

Слайды презентации

Слайд 2

Слайд 3

Bob Gilliver MSC/ARIES European Product Marketing and Support
Manager

Слайд 4

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 5

Geometry
Full function ACIS based modeler
Constraints
full
partial
none
ACIS data

exchange
AutoCAD
Bentley
Integraph
HP

Слайд 6

Geometry
Modify dimensions

Слайд 7

Geometry
Modification by dimension
Parametric relationships

Слайд 8

Geometry
Complex solids
Skin operator
Sweep operator
Extensive blending and chamfering
Region operator

to sub-divide geometry
Map meshing
Load footprint areas
Symmetry

Слайд 9

MSC/ARIES Base - Assemblies
Visualization
Packaging
Clearance
Interference
Mass properties

Слайд 10

MSC/ARIES Base - Mass Properties

Слайд 11

Geometry - Regioning

Слайд 12

Geometry - Regioning

Слайд 13

Geometry - Regioning

Слайд 14

Geometry - Regioning

Слайд 15

Pre Release Solids Shelling
Shelling of solids to thin

Pre Release Solids ShellingShelling of solids to thin walled solidsPer face

walled solids
Per face (uniform) thickness control
Face exclusion to create

“open” solids
Full Parametrics support
Not supported
Spline faces (fillet, sweep, skin, spline segments in curve based primitives, extrude with draft )

Слайд 16

Analysis Of ACIS
&
Imported Geometry

CAD

ARIES

Слайд 17

Geometry Interface - ACIS
Support for ACIS sat (ASCII)

Geometry Interface - ACISSupport for ACIS sat (ASCII) and sab (binary)

and sab (binary) file formats
Allows bi-directional exchange of solids,

surface and wireframe
Currently the most reliable solids data exchange format
Transfers geometry only
No feature or history information

Слайд 18

Geometry Interface - Autocad Import

Слайд 19

Geometry Interface - Autocad Import

Слайд 20

Geometry Interface - Autocad Import
Lin. Static Error Contours

Слайд 21

Geometry Interface - Autocad Export

Слайд 22

Geometry Interface - IGES Import
Supports
Wireframe
Point, line, arc,

Geometry Interface - IGES ImportSupportsWireframe Point, line, arc, composite curve, spline

composite curve, spline (112,126), conics (104), copious data (106)
Surface
Untrimmed

(118, 120, 122, 128)
Trimmed (144)
Solid
Solid BREP (186, 514, 510, 508, 504, 502,)

Слайд 23

Geometry Interface - IGES Export
Supports
Wireframe
Point, line, arc,

Geometry Interface - IGES ExportSupportsWireframe Point, line, arc, composite curve, spline

composite curve, spline (112,126), conics (104)
Solid/surface
Decomposed to precise wireframe

BREP
Decomposed to surface collection (trimmed or untrimmed - 128, 142, 144)
Text
Hidden line removal
Silhouette edge generation

Слайд 24

Geometry Interface - DXF Import
Wireframe
Point, line, arc, polyline
Text

Слайд 25

Geometry Interface - DXF Export
Supports
Wireframe
Point, line, arc,

Geometry Interface - DXF ExportSupportsWireframe Point, line, arc, composite curve, spline

composite curve, spline
Solid/surface
Decomposed to precise wireframe BREP
Text
Hidden line

removal
Silhouette edge generation

Слайд 26

Geometry Interfaces - STEP, VDAFS
PDES/STEP AP203
Import and export

Geometry Interfaces - STEP, VDAFSPDES/STEP AP203Import and export of solid/surface/wireframe dataVDAFSImport

of solid/surface/wireframe data
VDAFS
Import and export of surface/wireframe data
Data format

that emphasizes surface transfer
Used predominantly by European automotive industry

Слайд 27

Geometry Interfaces -Stereolithography
Translates solids into standard “stl” format
Rapid

manufacture for physical part prototyping

Слайд 28

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 29

LBC’s applied to geometry or to nodes &

LBC’s applied to geometry or to nodes & elements Supported loadsForce,

elements
Supported loads
Force, moment, pressure
Gravity
Velocity
Translational
Rotational
Acceleration
Translational
Load and Boundary Conditions

Слайд 30

Constant or functional varying magnitude
Geometry based load

Constant or functional varying magnitude Geometry based load and boundary conditions

and boundary conditions survive geometry change
Load and Boundary Conditions

Слайд 31

Load and Boundary Conditions
Direction control for load/boundary conditions
XYZ
Radial
Tangential

Слайд 32

Load and Boundary Conditions
Load case combination
(5 *

load_1) +
(3 * load_2)

Слайд 33

Automeshing technology
Edges -- 1D elements (beam, gap, rigid, spring)
Surfaces -- quad dominant

Automeshing technologyEdges -- 1D elements (beam, gap, rigid, spring)Surfaces -- quad dominant or all triasVolumes -- tets

or all trias
Volumes -- tets only
Map meshing for surfaces and volumes
3/4

side surfaces, 5/6 face volumes
Composite edge support

FE Meshing

Слайд 34

Auto Meshing
Solid Element Automesh

Слайд 35

FE Meshing
Adaptive mesh refinement
Automatic mesh refinement to optimize

FE MeshingAdaptive mesh refinementAutomatic mesh refinement to optimize mesh density Use

mesh density
Use with automatically generated h or p

meshes
Global or local refinement
New mesh density based on current error versus target error
Reduces mesh density related errors

Слайд 36

Original mesh - 21

% Error
Refined mesh - 7 % Error

Automatic

refinement

Original mesh

Слайд 37

FE Meshing
Direct creation of nodes/elements
Extrude/revolve 1D to 2D,

FE MeshingDirect creation of nodes/elementsExtrude/revolve 1D to 2D, 2D to 3DMirrorMesh

2D to 3D
Mirror
Mesh editing
Element quality checks
Merge node
Auto

MPC connection of meshes between linear or quad tets to linear hex

Слайд 38

Display options
Vector
Contour
Graph
Animation
Cutting plane
Results in any coordinate system
Data averaging

control
Results combination
Error calculation
Results Review

Слайд 39

Linear Statics
Loads constant with time
Material assumed linear and

perfectly elastic
Results calculated
Stress
Displacement
Strain
Strain energy
Reaction force

Слайд 40

Normal Modes
Calculates undamped natural modes of vibration
Material assumed

linear and perfectly elastic
Results calculated (normalized)
Stress
Displacement
Strain
Strain energy
Reaction force

Слайд 41

Linear Buckling
Calculates load factor for critical buckling
Material assumed

linear and perfectly elastic
Results calculated
Stress
Displacement
Strain
Strain energy
Reaction force

Слайд 42

Non-Linear Statics
Geometric non-linearity
Change in stiffness associated with large

Non-Linear StaticsGeometric non-linearityChange in stiffness associated with large deformations Load follows

deformations
Load follows deformed shape
Material non-linearity
Bi-linear elastic/plastic with plastic

strain, or
Non-linear elastic, no plastic strain
Compressive/tensile stress-strain curves can be different

Слайд 43

Non-Linear Statics
Non-linear Elastic Material

Слайд 44

Structures-2 Non-Linear Statics Load Following
Deformed - load following
Deformed -

load following
F
F
F
Undeformed

Слайд 45

Linear Transient Dynamics
Time varying geometry and finite element

Linear Transient DynamicsTime varying geometry and finite element loadsStructural and modal

loads
Structural and modal damping
Results calculated for each time step
Stress
Displacement
Strain
Velocity
Acceleration
Reaction

force

Слайд 46

Heat Transfer
Steady state and transient linear and non-linear

heat transfer
Heat transfer modes

Conduction
Free convection
Forced convection
Radiation
Temperature and time dependent
Heat flux
Mass flow rate

Слайд 47

Heat Transfer

Слайд 48

MSC/ARIES To MSC/PATRAN
ARIES Created Geometry

Слайд 49

MSC/ARIES To MSC/PATRAN
Imported ARIES Geometry in MSC/PATRAN

Слайд 50

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 51

Optimization
An Automated Process That:
Satisfies Your Design Objective
Within

Design Constraint(s)
By Modifying Design Variables

Слайд 52

Optimization - Overview
1 Design Objective
minimize/maximize weight, frequency,

Optimization - Overview1 Design Objective minimize/maximize weight, frequency, load factor‘n’ Design

load factor
‘n’ Design Constraints - local and or global
min/max

stress, displacement, freq, load factor
‘n’ Design Variables
Dimensional variables
Element shell thickness, Non Structural Mass
Solve multiple constraints simultaneously
Linear statics (with multiple load cases)
Modal (per mode shape max/min control)
Buckling analysis

Слайд 53

Optimization - Overview
Shape
Geometry dimensions as design variables
Sizing

Optimization - OverviewShape Geometry dimensions as design variablesSizing (element properties) Shell

(element properties)
Shell thickness, non-structural mass
Design sensitivity
Effect of a

change in a design variable on
Design Objective, Design Constraint(s)
Shape and sizing can be combined

Слайд 54

Initial Design

Слайд 55

Слайд 56

Слайд 57

Слайд 58

Слайд 59

Слайд 60

Слайд 61

Final Design

Слайд 62

Optimization - Application
Build solid or surface geometry
Associate dimension

Optimization - ApplicationBuild solid or surface geometryAssociate dimension variables in Parametrics:Use

variables in Parametrics:
Use as design variables for Optimization
Maintain

design intent
(Parameterize using DRP)
Maintain design intent
(Attach DRP model(s) to solids in Parametrics)

Слайд 63

Optimization - Application
Create finite element model
Select Optimization application
1

Optimization - ApplicationCreate finite element modelSelect Optimization application1 Design Objective minimize/maximize:weight,

Design Objective minimize/maximize:
weight, frequency, load_factor
‘n’ Design Constraints - local

and/or global min/max stress, disp, freq, load factor
‘n’ Design Variables
Dimensional,
Shell thickness, Non Structural Mass

Слайд 64

R1
L2
L1
R3
R2
DEP INDEP
R1

= 2 x R2 R2 = R3 L2

= R1 x 3

Thick

DRP Model

Selecting Design Variables

Слайд 65

Optimization - Results Review
Post process in Optimization application
Graph

Optimization - Results ReviewPost process in Optimization applicationGraph design objective/ constraint(s)/

design objective/ constraint(s)/ variable(s) against design cycle
Display geometry at

intermediate design cycles
Review results of final design in FE_Results
Standard results review process
Animate between FEmodels across design cycles

Слайд 66

Слайд 67

P-Elements - Overview
Automatically increases element’s shape function polynomial

P-Elements - OverviewAutomatically increases element’s shape function polynomial order during solution

order during solution until convergence
Convergence based on per element

strain energy difference between p-order changes
Mesh remains unchanged

Слайд 68

P-Elements - Overview
Each edge of each element has

its p-order independently controlled in MSC/NASTRAN

5
5
2
3
1
4

Слайд 69

P-Elements - Application
Supported element types
Tetrahedron
Brick
Pentahedron (wedge)
p-order min/max control
Recommended

p-order range 3-10
Adaptivity automatically turns off below specified von

Mises stress or strain minimum
Turns off adaptivity for elements where stress and or strain is negligible
Reduces CPU time and system resources

Слайд 70

P-Elements - Application

Constrains shared edges to p-order

= 1

Can mix h and p elements

Use p-elements in

areas where high accuracy required, h-elements elsewhere

Слайд 71

P-Elements - Application
Hex to tet mesh connection works

P-Elements - ApplicationHex to tet mesh connection works identically for p-elements:

identically for p-elements:

Automatic (h-adaptive) mesh refinement supported for

automeshed p-elements

Uses ERROR DATASET calculated from FER TOOLKIT error estimation

Слайд 72

P-Elements - Results Review
p-element results review identical to

h-elements
Can display final p element order contours

Слайд 73

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 74

Two- and three-dimensional mechanism modeling analysis and results

Two- and three-dimensional mechanism modeling analysis and results reviewUses MDI/ADAMS Kinematics

review
Uses MDI/ADAMS Kinematics solver
Solves motion of fully constrained

(0 DOF) kinematic systems i.e. the motion of the system is completely constrained by applied motion(s) and joint constraints

Mechanisms

Слайд 75

Create link geometry
Geometry can be solid, surface or

Create link geometryGeometry can be solid, surface or wireframeAdd joints (supports

wireframe
Add joints (supports all MDI/ADAMS joints)
Add constant, harmonic, step,

random motion
Add motion constraints (e.g. cams), applied forces, springs, gravity
Solve

Mechanisms Pre Processing

Links

Joints

Contact

Слайд 76

Mechanisms Results Review
Animated motion of links
Motion path of

Mechanisms Results ReviewAnimated motion of linksMotion path of any pointJoint reaction

any point
Joint reaction force/moment
Rotational/translational link displacement, velocity, acceleration
Clearance/interference between

links
Results interrogation in local static/dynamic coordinate system

Слайд 77

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 78

Plastics
3D mold fill analysis
Uses Moldflow/Flowcheck solver
Solves “Will It

Plastics3D mold fill analysisUses Moldflow/Flowcheck solverSolves “Will It Fill”Fast analysis to

Fill”
Fast analysis to calculate areas of fill / no-fill /

possible fill
Experiment with number of injection points/ location, material and part thickness
Solves “Fill_Pattern”
Fill time
Air trap location
Weld line locations

Слайд 79

Plastics
MSC/ARIES Created Solid

Слайд 80

Plastics
Mold Fill Time Contours

Слайд 81

Слайд 82

Modular Configuration

Слайд 83

Modular Configuration

Слайд 84

MSC/ARIES Base

Слайд 85

Optional Modules

Слайд 86

Platform Support
WindowsNT
Sun Solaris
SGI
HP
IBM
Digital Unix

Слайд 87

Intel based (not Digital NT)
Recommend >= Pentium 75MHz,

Intel based (not Digital NT)Recommend >= Pentium 75MHz, 32Mb RAM125 Mb

32Mb RAM
125 Mb swap space
Any Microsoft supported graphics adapter

in 256 color mode
WindowsNT
Windows 3.1 and Windows95 not available
Licensing
Node-lock, standalone only
No network license support
Requires Ethernet adapter for licensing

Platform Requirements - WinNT

Слайд 88

Supported Unix workstation
32Mb RAM
125 Mb swap space
Licensing
Node-lock, and
Floating

network license
Platform Requirements - Unix

Слайд 89

Geometry
FE Analysis
Optimization
Mechanisms
Plastics
MSC/ARIES Positioning

Слайд 90

MSC/ARIES Positioning
Standalone Design and Analysis System
Designed and analyzed

MSC/ARIES PositioningStandalone Design and Analysis SystemDesigned and analyzed in MSC/ARIESAnalysis of

in MSC/ARIES
Analysis of ACIS Based Geometry
Design built in CAD

system
Design geometry import into MSC/ARIES
Analyzed in MSC/ARIES
Focus on Ease-of-Use and Automation For...

Слайд 91

Structural
Thermal
Mechanisms
Plastic Molding Analysis
MSC/ARIES Positioning

Слайд 92

MSC/ARIES The Flow of Development
Product

Almost all design concepts will

be decided

Слайд 93

Positioning of MSC/ARIES
FEA Analyst
Design Engineer
Low price
High price

Static-Eigenvalues-Optimization-Heat-Dynamic-Nonlinear-Electromagnetic-Crash-NVH

Easy to

use

CAD-Integration Functionality

MSC/ARIES

MSC/PATRAN

PC/Windows

Workstation

Mainframe

Слайд 94

Positioning of MSC/ARIES
End
Start

Manufacturing Process

Manufacturing
Bill of Materials
Material Database
Drafting
Analysis
Optimization
Modeling
Design
MSC/ARIES
Predictive Engineering
CAD

linked
CAD
System

Modification Costs

Слайд 95

Positioning of MSC/ARIES

MSC/ARIES
Targeted User
Non-FE Specialist
Geometry Based Analysis
Conceptual CAE

Positioning of MSC/ARIESMSC/ARIESTargeted UserNon-FE SpecialistGeometry Based AnalysisConceptual CAE Tool & ModellerACIS

Tool & Modeller
ACIS imported analysis
Designer

MSC/N4W
Targeted User
FE Knowledgeable
GUI Nastran

pre & post
Limited Geometry Creation
Relies on Geometry Import
Windows Look & Feel
Low-High End FE User

Слайд 96

Positioning of MSC/ARIES
Guide line thought / Question Process
CAD

System
Import
Geometry
Create
Geometry
FE
Aware
N4W
ARIES
Poss.
No Sale
Conflict With
Existing
Modeller
Need To
Create
Drawings
ACIS Drafting
Package (AutoCAD etc)

NO

Yes

Слайд 97

THE END

Слайд 98

Mentor BoardStation Interface
Bi-directional interface using Mentor IDF 2.0

Mentor BoardStation InterfaceBi-directional interface using Mentor IDF 2.0 file formatImports Mentor

file format
Imports Mentor Board Station PCB and component data

as an assembly of solids
Components represented by automatically generated primitives or user created representations

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Обратная связь

Презентация на тему по сопромату3

Содержание

Слайд 3 Bob Gilliver MSC/ARIES European Product Marketing and Support Manager

Слайд 4 GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning

Слайд 5 GeometryFull function ACIS based modelerConstraintsfull partial noneACIS data

exchangeAutoCADBentleyIntegraphHP

Слайд 6 GeometryModify dimensions

Слайд 7 GeometryModification by dimensionParametric relationships

Слайд 8 GeometryComplex solidsSkin operatorSweep operatorExtensive blending and chamferingRegion operator

to sub-divide geometryMap meshingLoad footprint areasSymmetry

Слайд 9 MSC/ARIES Base - AssembliesVisualizationPackagingClearance InterferenceMass properties

Слайд 10 MSC/ARIES Base - Mass Properties

Слайд 11 Geometry - Regioning

Слайд 12 Geometry - Regioning

Слайд 13 Geometry - Regioning

Слайд 14 Geometry - Regioning

Слайд 15 Pre Release Solids ShellingShelling of solids to thin

walled solidsPer face (uniform) thickness controlFace exclusion to create

Слайд 16 Analysis Of ACIS &Imported GeometryCADARIES

Слайд 17 Geometry Interface - ACISSupport for ACIS sat (ASCII)

and sab (binary) file formatsAllows bi-directional exchange of solids,

Слайд 18 Geometry Interface - Autocad Import

Слайд 19 Geometry Interface - Autocad Import

Слайд 20 Geometry Interface - Autocad ImportLin. Static Error Contours

Слайд 21 Geometry Interface - Autocad Export

Слайд 22 Geometry Interface - IGES ImportSupportsWireframe Point, line, arc,

composite curve, spline (112,126), conics (104), copious data (106)SurfaceUntrimmed

Слайд 23 Geometry Interface - IGES ExportSupportsWireframe Point, line, arc,

composite curve, spline (112,126), conics (104)Solid/surfaceDecomposed to precise wireframe

Слайд 24 Geometry Interface - DXF ImportWireframePoint, line, arc, polylineText

Слайд 25 Geometry Interface - DXF ExportSupportsWireframe Point, line, arc,

composite curve, spline Solid/surfaceDecomposed to precise wireframe BREPTextHidden line

Слайд 26 Geometry Interfaces - STEP, VDAFSPDES/STEP AP203Import and export

of solid/surface/wireframe dataVDAFSImport and export of surface/wireframe dataData format

Слайд 27 Geometry Interfaces -StereolithographyTranslates solids into standard “stl” formatRapid

manufacture for physical part prototyping

Слайд 28 GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning

Слайд 29 LBC’s applied to geometry or to nodes &

elements Supported loadsForce, moment, pressureGravityVelocityTranslational RotationalAccelerationTranslationalLoad and Boundary Conditions

Слайд 30 Constant or functional varying magnitude Geometry based load

and boundary conditions survive geometry changeLoad and Boundary Conditions

Слайд 31 Load and Boundary ConditionsDirection control for load/boundary conditionsXYZRadialTangential

Слайд 32 Load and Boundary ConditionsLoad case combination (5 *

load_1) + (3 * load_2)

Слайд 33 Automeshing technologyEdges -- 1D elements (beam, gap, rigid, spring)Surfaces -- quad dominant

or all triasVolumes -- tets onlyMap meshing for surfaces and volumes3/4

Слайд 34 Auto MeshingSolid Element Automesh

Слайд 35 FE MeshingAdaptive mesh refinementAutomatic mesh refinement to optimize

mesh density Use with automatically generated h or p

Слайд 36 Original mesh - 21

% ErrorRefined mesh - 7 % ErrorAutomatic

Слайд 37 FE MeshingDirect creation of nodes/elementsExtrude/revolve 1D to 2D,

2D to 3DMirrorMesh editingElement quality checksMerge nodeAuto

Слайд 38 Display optionsVectorContourGraphAnimationCutting planeResults in any coordinate systemData averaging

controlResults combinationError calculationResults Review

Слайд 39 Linear StaticsLoads constant with timeMaterial assumed linear and

perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force

Слайд 40 Normal ModesCalculates undamped natural modes of vibrationMaterial assumed

linear and perfectly elasticResults calculated (normalized)StressDisplacementStrainStrain energyReaction force

Слайд 41 Linear BucklingCalculates load factor for critical bucklingMaterial assumed

linear and perfectly elasticResults calculatedStressDisplacementStrainStrain energyReaction force

Слайд 42 Non-Linear StaticsGeometric non-linearityChange in stiffness associated with large

deformations Load follows deformed shapeMaterial non-linearityBi-linear elastic/plastic with plastic

Слайд 43 Non-Linear StaticsNon-linear Elastic Material

Слайд 44 Structures-2 Non-Linear Statics Load FollowingDeformed - load followingDeformed -

load followingFFFUndeformed

Слайд 45 Linear Transient DynamicsTime varying geometry and finite element

loadsStructural and modal dampingResults calculated for each time stepStressDisplacementStrainVelocityAccelerationReaction

Слайд 46 Heat TransferSteady state and transient linear and non-linear

heat transfer Heat transfer modes

Слайд 47 Heat Transfer

Слайд 48 MSC/ARIES To MSC/PATRANARIES Created Geometry

Слайд 49 MSC/ARIES To MSC/PATRANImported ARIES Geometry in MSC/PATRAN

Слайд 50 GeometryFE AnalysisOptimizationMechanismsPlasticsMSC/ARIES Positioning

Слайд 51 OptimizationAn Automated Process That:Satisfies Your Design Objective Within

Design Constraint(s) By Modifying Design Variables

Слайд 52 Optimization - Overview1 Design Objective minimize/maximize weight, frequency,

load factor‘n’ Design Constraints - local and or globalmin/max