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Stress Analysis with Non-linear Material Models


This core package allows engineers to perform a static stress analysis with nonlinear material models to predict material deflection, deformation and displacement. This core package also includes static stress analysis with linear material models; weight, center of gravity and mass moment of inertia analysis; linear contact; FEMPRO, an easy-to-use, single user interface for finite element modeling, results evaluation and presentation; and a suite of modeling capabilities.

Springs, connectors and components made from plastic or rubber are often the subjects of nonlinear static stress analyses. Damping and mass effects are ignored due to the absence of motion; however, contact between parts of a mechanism or among independent parts can be handled in nonlinear static stress analyses.

Nonlinear static stress analyses produce more accurate stress results than linear static stress analyses for models that undergo loading in a concentrated area, have small features such as a small fillet radius or have constraints that act over small regions. This is because linear static stress analyses only produce stresses based on the initial shape of the object, whereas nonlinear static stress analyses determine stresses based on the object's deformed shape under loading.

TYPICAL APPLICATIONS

  • Material transport and storage
  • Product life cycle simulation (failure)
  • Snap-fit
  • Snap-through buckling
  • Tolerance testing
  • Press-fit
  • Pre-stress concrete
  • MEMS (Micro Electro Mechanical Systems) design
  • Underwater design optimization
  • Wear analysis

ANALYSIS CAPABILITIES

  • Static stress with linear material models
  • Multiple-body contact and interaction
  • Hertzian contact
  • Permanent deformation
  • Local buckling
  • Pre-stress
  • Residual stress analysis
  • Hydrodynamic effects
  • Geometric nonlinearity
  • Weight, center of gravity and mass moment of inertia
  • Static stress with nonlinear material models
  • Elastic deformation
  • Thermal stress
  • Sub-modeling
  • Voltage-induced effects
  • Creep analysis
  • Sub-modeling
  • Voltage-induced effects
  • Load stiffening

MODELING

  • InCAD technology for direct CAD/CAE data exchange with Alibre Design, Autodesk Inventor, Inovate, IronCAD, KeyCreator, Mechanical Desktop, Pro/ENGINEER, Solid Edge and SolidWorks
  • Full associativity with each design change for Alibre Design, Autodesk Inventor, Inovate, IronCAD, Pro/ENGINEER, Solid Edge and SolidWorks
  • CAD support for Rhinoceros
  • CAD support for 3-D solid models in ACIS, IGES, STEP and STL file formats
  • CAD support for 2-D and 3-D wireframe geometry in CDL, DXF and IGES file formats
  • Ability to create a CAD Transfer Utility installation package to provide direct data exchange even when ALGOR and the CAD package (Alibre Design, Autodesk Inventor, Inovate, IronCAD, KeyCreator, Mechanical Desktop, Pro/ENGINEER, Solid Edge or SolidWorks) reside on separate computers
  • Capability to open CAD models in ALGOR even if the CAD package (Alibre Design, Autodesk Inventor, Inovate, IronCAD, KeyCreator, Mechanical Desktop, Pro/ENGINEER, Rhinoceros, Solid Edge or SolidWorks) is not open
  • A user-controlled feature suppression tool with the option to suppress details either manually or based on feature size
  • Ability to merge parts from any CAD source into a single FEA model
  • Part names from a CAD solid model captured in the FEA model
  • Part colors from a CAD solid model captured in the FEA model
  • Automatically selects the unit system based on the unit of length of the CAD solid model
  • Superdraw 2- and 3-D sketching tools including capabilities to draw points, lines, rectangles, arcs, circles, splines and tangent lines and modify sketch objects with commands including copy, divide, fillet, intersect, rotate, mirror, move, parallel, trim/extend and delete
  • Complex surface modeling using NURBS, polylines and b-splines
  • Joint Creation Utility for automatically creating pin and ball joints based on either two specified endpoints or a mid-point
  • Capability to combine all element types available for a given analysis type in a single model
  • Capability to define loads and constraints relative to a local coordinate system
  • Provides direct access to AISC section property data for use with beam elements
  • Interactive definition of beam cross-section orientation
  • Capability to define beam offset locations
  • Capability to import FEA models that are stored in ABAQUS, ANSYS, FEMAP, NASTRAN, PATRAN or SDRC file formats
  • Support for Tsai-Wu, Maximum Stress or Maximum Strain failure criteria for composites
  • KinePak mechanism wizard to define links and then dynamically examine the motion of various types of basic mechanisms including:
    • Four-bar
    • Toggle
    • Slider/Crank
    • Class 1 lever
    • Class 2 lever
    • Class 3 lever
    • Triangle

MESHING

  • 2- and 3-D parametric, structured meshing options for 3-point triangular, 4-point rectangular, 8-point 3-D, between two objects and 4-object 3-D meshing
  • Automatic, unstructured 2-D meshing
  • Automatic, unstructured 3-D quadrilateral or triangular surface mesh generation and refinement
  • Automatic, intelligent, feature-based mesh refinement and point-and-click definition of areas where a finer mesh is desired
  • A midplane mesh engine for reducing thin, solid features in a CAD model to plate/shell elements with automatic handling of parts, assemblies, multi-thickness regions and mixed element type models
  • Automatic, hex-dominant hybrid solid meshing to produce higher quality elements on the first pass and more accurate results
  • One-step assembly meshing

ELEMENT LIBRARY

  • 2-D hydrodynamic element
  • General contact element
  • Coupling element
  • Pipe element
  • Pulley element
  • 3-D truss element
  • 3-D membrane element
  • 3-D shell element
  • 3-D brick element
  • Gap element
  • Rigid element
  • 3-D membrane plane stress element
  • 3-D hydrodynamic element
  • Contact element
  • Slider element
  • Spring element
  • 2-D element
  • 3-D beam element
  • 3-D plate element
  • Sandwich (thick) composite element
  • 3-D tetrahedral element
  • Cable element
  • Thin composite element
  • Motion-enabled composite element

MATERIAL MODELS

  • Elastic
  • Thermoplastic
  • Viscoelastic
  • Mooney-Rivlin
  • Curve description with cutoff tension
  • von Mises curve with isotropic hardening
  • Multiple-coefficient (5-constant) Mooney-Rivlin
  • Linear elastic orthotropic
  • Linear elastic isotropic
  • Plastic
  • Thermoelastic
  • Viscoplastic
  • Ogden
  • von Mises with isotropic hardening
  • von Mises curve with kinematic hardening
  • Multiple-coefficient (9-constant) Mooney-Rivlin
  • Temperature-dependent composite
  • General piezoelectric
  • Variable tangent
  • Curve description
  • Drucker-Prager
  • Piezoelectric
  • von Mises with kinematic hardening
  • Temperature-dependent orthotropic
  • Linear temperature-dependent isotropic
  • Linear temperature-dependent orthotropic
  • Composite laminate

LOADING AND CONSTRAINTS

  • Impact planes
  • Static friction
  • Edge forces
  • Surface temperatures
  • Prescribed displacements
  • Prescribed rotations
  • Pressures
  • Hydrostatic pressures
  • Gravitational forces
  • Global and off-axis constraints
  • Variable-stiffness off-axis constraints
  • End releases
  • Point-to-surface contact
  • Forces
  • Moments
  • Voltages
  • Surface prescribed displacements
  • Surface prescribed rotations
  • Tractions
  • Distributed loads
  • Global and off-axis surface constraints
  • Variable-stiffness off-axis surface constraints
  • Curing temperature difference
  • Surface-to-surface contact
  • Surface forces
  • Temperatures
  • Surface voltages
  • Edge prescribed displacements
  • Edge prescribed rotations
  • Variable surface loads
  • Centrifugal forces
  • Global and off-axis edge constraints
  • Variable-stiffness off-axis edge constraints
  • Mean temperature difference

SOLVER OPTIONS

  • Banded
  • Symmetric sparse
  • Skyline
  • Iterative
  • Riks method
  • Restart capability
  • Automatic time-stepping
  • Parallel processing for multiple processors

RESULTS EVALUATION

  • Integrated environment for model visualization and results evaluation
  • 3-D dynamic viewing options and rich colors provided by OpenGL-based displays
  • Material and result rendering for model and analysis visualization
  • Cross-sectional viewing options
  • Dynamic clipping planes for slicing models
  • Capability to display parts as transparent (translucent)
  • Multiple methods for selecting parts or elements in order to hide areas of the model
  • Result contours of:
      • Displacement
      • Strain
      • Strain energy density
      • Factor of safety
      • Stress
      • Reaction force
      • Vector plots of principal stress directions
      • Plastic strain
  • Annotations to highlight the location of minimum and maximum results
  • Capability to define result probes at desired locations
  • Annotation of graph values
  • Capability to display or graph results in an arbitrary orientation using a local coordinate system
  • Capability to simultaneously view varying result types through multiple view windows
  • Capability to dynamically monitor the distance between parts or surfaces involved in surface-to-surface contact
  • Shear and bending moment diagrams
  • Text output of weight, volume, center of gravity, mass moment of inertia and products of inertia
  • Precision contouring for accuracy assessment
  • Stress linearization utility for use with a linear static stress analysis on thin-walled structures
  • Capability to combine the results of multiple linear static stress analyses
  • Built-in, virtual instrumentation through Monitor for result graphs
  • Capability to graph the magnitude; first, second and third derivative; and integral of time-dependent results
  • Fast Fourier Transform (FFT) display
  • Automatic display of units in the results legend
  • Uses TrueType fonts for legend and annotations
  • Dynamic controls for positioning the results legend, annotations and background images
  • Pre-defined and user-defined color palettes for result contours
  • Slider to dynamically control the scale and display of the displaced model
  • Capability to display the undisplaced model using transparency
  • Slider for controlling the display of elements based on a lower or upper result limit
  • Capability to individually control the color, mesh and display of results for each part
  • Realistic visualization of beam elements
  • Realistic visualization of plate elements
  • Point-and-click result inquiry options
  • Inquire mode enables results from selected objects or load and constraint data to be displayed and available for copy and paste operations to other applications
  • Result text listing
  • Support for exporting results to common Windows applications
  • Capability to save all settings for a specific presentation and view that same display at any time or use those settings with a different model
  • Graphical element orientation display

For more information please visit Algor Professional Static NLM

 
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