Inventor 2019 lancering
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One AutoCAD – Tool set:• AutoCAD • AutoCAD Architecture • AutoCAD Electrical • AutoCAD Map 3D • AutoCAD Mechanical • AutoCAD MEP • AutoCAD Plant 3D (inkl.
P&ID)• AutoCAD Raster Design • AutoCAD mobile • appAutoCAD web app
Inventor ProfessionalFactory Design Utility (Layout i AutoCAD og Inventor)Nesting UtilityNavisworks3ds MaxFusion 360Vault BasicNastran In-CADHSM Ultimate Recap ProAutodesk driveAutodesk Rendering
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PD&M Collection nyheder
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One Autocad
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One Autocad
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ArchitectureMechanical Electrical MEP Plant 3D Map 3D Raster Design
Specialized Toolsets
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HSM
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Autodesk HSM - Functionality
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Express (Free) Ultimate (Embedded in PDMC)
2.5 Axis 2- to 5- Axis, 3+2, Multi-Axis, Turning
- Fusion 360 Standard (3 Axis)
Inventor Add-in (2.5 Axis) Inventor Add-in (5 Axis)
SolidWorks Add-in (2.5 Axis) SolidWorks Add-in (5 Axis)
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2D Toolpaths
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2D Pocket
2D Adaptive
2D Contour
TraceSlot
Engrave
Drilling
Thread/BoreCircular
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3D Toolpaths
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Parallel MorphFlow
Scallop
Contour/Ramp
Project
Morphed Spiral
RadialSpiral
Horizontal
Pencil
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Turning
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Parting
Chamfer
Single Groove
Groove Profile
Thread
Face
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Nastran IN-CAD
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ATTN! - Nastran In-CAD joined Collection!
Assemblies Bolted connections, sliding interfaces, friction
Time Transient dynamic loads, vibration, fatigue, and shock
Temperature Consider the effects of heat. Solve for temps, heat loads,
resulting thermal expansion and thermal stresses
Nonlinear Go Beyond Linear Analysis – large displacement effects,
nonlinear (flexible) materials, buckling
http://feaforall.com/
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Denmark · Iceland · Sweden · Norway · Germany
Analyze types
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Positioning Nastran In-CAD
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Low
Cos
t of
Entry
Hig
h C
ost o
f En
try
ENGINEER ANALYSTDESIGNER
ANSYS
3DS Simulia
COMSOL
MSC Marc
MSC Nastran
Siemens Nastran
SolidWorks Sim
Nastran In-CAD
MSC ApexANSYS AIM
Fusion 360/ Fusion 360 Ultimate
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Linear Statics
Linear statics is one of the most common types of analysis. Determine stress, strain, and deformation resulting from applied static loads and imposed constraints. Linear stress, strain, deflection Inertial relief Thermal stress and deflection Prestress Mass properties Multiaxial fatigue Linear statics is the easiest and most common class of FEA. It
provides the capability to simulate static loads and slowly applied loads.
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Buckling
Use buckling to assess the stability of a device under loads. Buckling examines structures for sudden failure modes caused by compressive forces. Critical loads and mode shapes Linear and nonlinear initial stress Linear buckling is computed with the Euler buckling formula. Use nonlinear buckling to simulate large deformations, contact
and nonlinear material behavior in calculation of buckling load.
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Prestress Static and Normal Modes
Use prestress static and normal modes to analyze structures subjected to initial stress, and model the effect of the initial stress state on the structures' displacements, stresses, and modes.
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Normal Modes
Use normal modes to determine the undamped natural mode shapes and frequencies of structures. This allows designer engineers to explore and resolve problems with noise and vibration. Natural frequencies and mode shapes Flexible and rigid body motion Modal participation factors, effective mass/weight, and
reaction forces Linear and nonlinear prestress (stiffening) Virtual fluid mass
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Linear Steady State Heat Transfer
Analyze heat transfer to determine the temperature distribution using the principles of conduction and convection heat transfer. Compute steady state and time-dependent heat loading using: Conduction Convection Radiation You can transfer temperature results to structural analyses as
thermal loads.
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Denmark · Iceland · Sweden · Norway · Germany
Composites
Simulate the performance of complex ply data. Analysis based on latest failure indices, including Puck and LaRC02. Linear and nonlinear 2D and 3D laminated elements Especially suited for fiber reinforced materials Special failure techniques for sandwich composites Cohesive zone models for delamination failures Failure index and factor of safety calculations Many possible theories
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Assembly Modeling with Contact
Go beyond analyzing individual parts. Real world simulation of assemblies is possible with sophisticated modeling of different kinds of contact interactions including sliding, friction and welded contact types.
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Thermal Stress
Analyze structures subjected to thermal loads.
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Nonlinear Statics
Nonlinear statics provides the ability to add more realistic simulation with contacting parts, nonlinear elastic and plastic materials, and large deformations. Computes advanced nonlinear solutions such as large
displacements/rotation, large strain, plasticity, hyperelasticity, and creep.
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Nonlinear Transient Heat Transfer
Simulate heat transfer with nonlinear linear thermal boundary conditions that vary through time. An example is transient heat generation caused by power fluctuations. Conduction Convection Radiation
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Nonlinear Steady State Heat Transfer
Simulate heat transfer with nonlinear thermal boundary conditions such as temperature-dependent thermal properties.
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Random Response
Analyze structural behavior in response to random dynamic loads.
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Frequency Response
Dynamic solutions add the ability to include time and mass in the solution. Capabilities include: Enforced harmonic motion - frequency response Time dependent motion and loads - transient response Random excitation Shock loading Use frequency response to determine the structural harmonic
response based upon frequency-dependent loads.
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Linear and Nonlinear Transient Response Simulate the time-dependent response of a structure under the
influence of constant or time-dependent loads. An example is impulse loading.
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Advanced Nonlinear and Hyperelastic Materials Simulate complex nonlinear phenomena such as plasticity,
hyperelasticity, and shape-memory effect. This enables the analysis of a wide range of materials, from metals and shape-memory alloys to rubbers and soft tissue.
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Automated Impact Analysis (AIA) and Drop Test Simulate drop tests and other impact type loadings easily and
automatically. Define impacting parts, path, and velocity. Define initial conditions and loads, and run as a nonlinear transient analysis. Sophisticated treatment provides realistic and meaningful
impact and drop test simulations. The only inputs required are projectile velocity and acceleration.
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