Analysis

class ansys.mechanical.stubs.v242.Ansys.ACT.Automation.Mechanical.Analysis

Bases: object

Defines a Analysis.

Overview

Methods

Activate	Activate the current object.
AddAMOverhangConstraint	Creates a new AMOverhangConstraint
AddAcceleration	Creates a new Acceleration
AddAcousticAbsorptionElement	Creates a new AcousticAbsorptionElement
AddAcousticAbsorptionSurface	Creates a new AcousticAbsorptionSurface
AddAcousticDiffuseSoundField	Creates a new AcousticDiffuseSoundField
AddAcousticFarFieldRadationSurface	Creates a new AcousticFarFieldRadationSurface
AddAcousticFreeSurface	Creates a new AcousticFreeSurface
AddAcousticImpedanceBoundary	Creates a new AcousticImpedanceBoundary
AddAcousticImpedanceSheet	Creates a new AcousticImpedanceSheet
AddAcousticIncidentWaveSource	Creates a new AcousticIncidentWaveSource
AddAcousticLowReducedFrequency	Creates a new AcousticLowReducedFrequency
AddAcousticMassSource	Creates a new AcousticMassSource
AddAcousticMassSourceRate	Creates a new AcousticMassSourceRate
AddAcousticPort	Creates a new AcousticPort
AddAcousticPortInDuct	Creates a new AcousticPortInDuct
AddAcousticPressure	Creates a new AcousticPressure
AddAcousticRadiationBoundary	Creates a new AcousticRadiationBoundary
AddAcousticRigidWall	Creates a new AcousticRigidWall
AddAcousticStaticPressure	Creates a new AcousticStaticPressure
AddAcousticSurfaceAcceleration	Creates a new AcousticSurfaceAcceleration
AddAcousticSurfaceVelocity	Creates a new AcousticSurfaceVelocity
AddAcousticSymmetryPlane	Creates a new AcousticSymmetryPlane
AddAcousticTemperature	Creates a new child ThermalCondition.
AddAcousticThermoViscousBLIBoundary	Creates a new AcousticThermoViscousBLIBoundary
AddAcousticTransferAdmittanceMatrix	Creates a new AcousticTransferAdmittanceMatrix
AddBearingLoad	Creates a new BearingLoad
AddBodyControl	Creates a new BodyControl
AddBoltPretension	Creates a new BoltPretension
AddCenterOfGravityConstraint	Creates a new CenterOfGravityConstraint
AddCommandSnippet	Creates a new CommandSnippet
AddComment	Creates a new child Comment.
AddComplexityIndexConstraint	Creates a new ComplexityIndexConstraint
AddComplianceConstraint	Creates a new ComplianceConstraint
AddCompressionOnlySupport	Creates a new CompressionOnlySupport
AddConstraintEquation	Creates a new ConstraintEquation
AddContactStepControl	Creates a new ContactStepControl
AddConvection	Creates a new Convection
AddCoupling	Creates a new Coupling
AddCriterionConstraint	Creates a new CriterionConstraint
AddCurrent	Creates a new Current
AddCyclicManufacturingConstraint	Creates a new CyclicManufacturingConstraint
AddCylindricalSupport	Creates a new CylindricalSupport
AddDetonationPoint	Creates a new DetonationPoint
AddDisplacement	Creates a new Displacement
AddDisplacementConstraint	Creates a new DisplacementConstraint
AddDynamicComplianceConstraint	Creates a new DynamicComplianceConstraint
AddEMTransducer	Creates a new EMTransducer
AddEarthGravity	Creates a new EarthGravity
AddElasticSupport	Creates a new ElasticSupport
AddElectricCharge	Creates a new ElectricCharge
AddElementBirthAndDeath	Creates a new ElementBirthAndDeath
AddExtrusionManufacturingConstraint	Creates a new ExtrusionManufacturingConstraint
AddFigure	Creates a new child Figure.
AddFixedRotation	Creates a new FixedRotation
AddFixedSupport	Creates a new FixedSupport
AddFluidPenetrationPressure	Creates a new Fluid Penetration Pressure object in Mechanical. This load object is used to simulate surrounding fluid or air penetrating into the contact interface.
AddFluidSolidInterface	Creates a new FluidSolidInterface
AddForce	Creates a new Force
AddFrictionlessSupport	Creates a new FrictionlessSupport
AddGeneralizedPlaneStrain	Creates a new GeneralizedPlaneStrain
AddGeometryBasedAdaptivity	Creates a new GeometryBasedAdaptivity
AddGlobalVonMisesStressConstraint	Creates a new GlobalVonMisesStressConstraint
AddHeatFlow	Creates a new HeatFlow
AddHeatFlux	Creates a new HeatFlux
AddHousingConstraint	Creates a new HousingConstraint
AddHydrostaticPressure	Creates a new HydrostaticPressure
AddImage	Creates a new child Image.
AddImpedanceBoundary	Creates a new ImpedanceBoundary
AddImportedCFDPressure	Creates a new ImportedCFDPressure
AddImportedLoadExternalData	Creates a new Imported Load (External Data).
AddImportedLoadFluidsResultsFile	Creates a new Import Load for Fluids Results File.
AddImportedLoadMAPDLResultsFile	Creates a new Import Load for MAPDL Results File.
AddImportedRemoteLoadsGroup	Creates a new Import Remote Load Group.
AddInitialVelocity	Creates a new child Initial Velocity.
AddInternalHeatGeneration	Creates a new InternalHeatGeneration
AddJointLoad	Creates a new JointLoad
AddLimitBoundary	Creates a new LimitBoundary
AddLinePressure	Creates a new LinePressure
AddLocalVonMisesStressConstraint	Creates a new LocalVonMisesStressConstraint
AddMagneticFluxParallel	Creates a new MagneticFluxParallel
AddMassConstraint	Creates a new MassConstraint
AddMassFlowRate	Creates a new MassFlowRate
AddMemberSizeManufacturingConstraint	Creates a new MemberSizeManufacturingConstraint
AddMoment	Creates a new Moment
AddMomentOfInertiaConstraint	Creates a new MomentOfInertiaConstraint
AddMorphingRegion	Creates a new MorphingRegion
AddNaturalFrequencyConstraint	Creates a new NaturalFrequencyConstraint
AddNodalDisplacement	Creates a new NodalDisplacement
AddNodalForce	Creates a new NodalForce
AddNodalOrientation	Creates a new NodalOrientation
AddNodalPressure	Creates a new NodalPressure
AddNodalRotation	Creates a new NodalRotation
AddNonlinearAdaptiveRegion	Creates a new NonlinearAdaptiveRegion
AddObjective	Creates a new Objective
AddOptimizationRegion	Creates a new OptimizationRegion
AddPSDAcceleration	Creates a new PSDAcceleration
AddPSDDisplacement	Creates a new PSDDisplacement
AddPSDGAcceleration	Creates a new PSDGAcceleration
AddPSDVelocity	Creates a new PSDVelocity
AddPatternRepetitionConstraint	Creates a new PatternRepetitionConstraint
AddPerfectlyInsulated	Creates a new PerfectlyInsulated
AddPhysicsRegion	Creates a new PhysicsRegion
AddPipeIdealization	Creates a new child PipeIdealization.
AddPipePressure	Creates a new PipePressure
AddPipeTemperature	Creates a new PipeTemperature
AddPlasticHeating	Creates a new PlasticHeating
AddPressure	Creates a new child Pressure.
AddPullOutDirectionManufacturingConstraint	Creates a new PullOutDirectionManufacturingConstraint
AddPythonCodeEventBased	Creates a new PythonCodeEventBased
AddRSAcceleration	Creates a new RSAcceleration
AddRSDisplacement	Creates a new RSDisplacement
AddRSVelocity	Creates a new RSVelocity
AddRadiation	Creates a new Radiation
AddReactionForceConstraint	Creates a new ReactionForceConstraint
AddRemoteDisplacement	Creates a new RemoteDisplacement
AddRemoteForce	Creates a new RemoteForce
AddRotatingForce	Creates a new RotatingForce
AddRotationalAcceleration	Creates a new RotationalAcceleration
AddRotationalVelocity	Creates a new RotationalVelocity
AddSimplySupported	Creates a new SimplySupported
AddSourceConductor	Creates a new child SourceConductor.
AddSubstructureGenerationCondensedPart	Creates a new SubstructureGenerationCondensedPart
AddSurfaceChargeDensity	Creates a new SurfaceChargeDensity
AddSymmetryManufacturingConstraint	Creates a new SymmetryManufacturingConstraint
AddSystemCouplingRegion	Creates a new SystemCouplingRegion
AddTemperature	Creates a new child Temperature.
AddTemperatureConstraint	Creates a new TemperatureConstraint
AddThermalComplianceConstraint	Creates a new ThermalComplianceConstraint
AddThermalCondition	Creates a new child ThermalCondition.
AddUniformConstraint	Creates a new UniformConstraint
AddVelocity	Creates a new Velocity
AddViscoelasticHeating	Creates a new ViscoelasticHeating
AddVoltage	Creates a new Voltage
AddVoltageCoupling	Creates a new Coupling
AddVoltageGround	Creates a new VoltageGround
AddVolumeChargeDensity	Creates a new VolumeChargeDensity
AddVolumeConstraint	Creates a new VolumeConstraint
ClearGeneratedData	Run the ClearGeneratedData action.
CopyTo	Copies all visible properties from this object to another.
CreateAutomaticFSI	Run the CreateAutomaticFSI action.
CreateAutomaticFSIandFarFieldRadiationSurfaces	Run the CreateAutomaticFSIandEquivalentSourceSurfaces action.
CreateAutomaticFarFieldRadiationSurfaces	Run the CreateAutomaticEquivalentSourceSurfaces action.
CreateParameter	Creates a new parameter for a Property.
Delete	Run the Delete action.
Duplicate	Duplicate method.
ExportNastranFile	Export Nastran File.
FilterBasedOnEnvironment	Enables interface filtering that only displays model-level items applicable to
GetChildren	Gets the list of children, filtered by type.
GetParameter	Gets the parameter corresponding to the given property.
GroupAllSimilarChildren	Run the GroupAllSimilarChildren action.
GroupSimilarObjects	Run the GroupSimilarObjects action.
ImportLoad	Import Load action.
OpenSolverFilesDirectory	Run the OpenSolverFilesDirectory action.
PropertyByAPIName	Get a property by its API name.
PropertyByName	Get a property by its unique name.
RemoveParameter	Removes the parameter from the parameter set corresponding to the given property.
SelectBodiesWithMultiplePhysicsRegion	Run the SelectBodiesWithMultiplePhysicsRegion action to select the bodies that belong to more than one Physics Region.
SelectBodiesWithoutPhysicsRegion	Run the SelectBodiesWithoutPhysicsRegion action to select the bodies that don't belong to a Physics Region.
Solve	Run the Solve action.
TransferDataFrom	Transfer Data From action.
UnlinkDataFrom	Unlink Data From action.
WriteSystemCouplingFiles	Writes the system coupling files. Usage WriteSystemCouplingFiles(“C:Desktoptempscp1.scp”);

Properties

AMProcessSimulation	Gets or sets the AMProcessSimulation.
Acoustics	Gets or sets the Acoustics.
AnalysisSettings	Gets the AnalysisSettings.
AnalysisType	Gets the AnalysisType.
CellId	Gets the CellId.
Children	Gets the list of children.
Comments	Gets the list of associated comments.
DataModelObjectCategory	Gets the current DataModelObject's category.
Electric	Gets the Electric.
EnvironmentTemperature	Gets or sets the EnvironmentTemperature.
Figures	Gets the list of associated figures.
GenerateInputOnly	Gets the GenerateInputOnly.
Images	Gets the list of associated images.
InitialConditions	Get InitialConditions.
InternalObject	Gets the internal object. For advanced usage only.
PhysicsType	Gets the PhysicsType.
Properties	Gets the list of properties for this object.
ReadOnly	Gets or sets the ReadOnly.
ResultFileName	Get the full path and name of the result file.
Solution	Gets the Solution.
Structural	Gets or sets the Structural.
SystemCaption	Gets the SystemCaption.
Thermal	Gets the Thermal.
VisibleProperties	Gets the list of properties that are visible for this object.

Property detail

property Analysis.AMProcessSimulation: Ansys.Mechanical.DataModel.Enums.AMProcessSimulationType | None

Gets or sets the AMProcessSimulation.

property Analysis.Acoustics: bool | None

Gets or sets the Acoustics.

property Analysis.AnalysisSettings: Ansys.ACT.Automation.Mechanical.AnalysisSettings.AnalysisSettings | None

Gets the AnalysisSettings.

property Analysis.AnalysisType: Ansys.Mechanical.DataModel.Enums.AnalysisType | None

Gets the AnalysisType.

property Analysis.CellId: str | None

Gets the CellId.

property Analysis.Children: List[Ansys.Mechanical.DataModel.Interfaces.IDataModelObject] | None

Gets the list of children.

property Analysis.Comments: Iterable[Ansys.ACT.Automation.Mechanical.Comment] | None

Gets the list of associated comments.

property Analysis.DataModelObjectCategory: Ansys.Mechanical.DataModel.Enums.DataModelObjectCategory | None

Gets the current DataModelObject's category.

property Analysis.Electric: bool | None

Gets the Electric.

property Analysis.EnvironmentTemperature: Ansys.Core.Units.Quantity | None

Gets or sets the EnvironmentTemperature.

property Analysis.Figures: Iterable[Ansys.ACT.Automation.Mechanical.Figure] | None

Gets the list of associated figures.

property Analysis.GenerateInputOnly: bool | None

Gets the GenerateInputOnly.

property Analysis.Images: Iterable[Ansys.ACT.Automation.Mechanical.Image] | None

Gets the list of associated images.

property Analysis.InitialConditions: List[Ansys.ACT.Automation.Mechanical.InitialCondition] | None

Get InitialConditions.

property Analysis.InternalObject: Ansys.Common.Interop.DSObjectsAuto.IDSEnvironmentAuto | None

Gets the internal object. For advanced usage only.

property Analysis.PhysicsType: Ansys.Mechanical.DataModel.Enums.PhysicsType | None

Gets the PhysicsType.

property Analysis.Properties: tuple[Ansys.ACT.Automation.Mechanical.Property] | None

Gets the list of properties for this object.

property Analysis.ReadOnly: bool | None

Gets or sets the ReadOnly.

property Analysis.ResultFileName: str | None

Get the full path and name of the result file.

property Analysis.Solution: Ansys.ACT.Automation.Mechanical.Solution | None

Gets the Solution.

property Analysis.Structural: bool | None

Gets or sets the Structural.

property Analysis.SystemCaption: str | None

Gets the SystemCaption.

property Analysis.Thermal: bool | None

Gets the Thermal.

property Analysis.VisibleProperties: tuple[Ansys.ACT.Automation.Mechanical.Property] | None

Gets the list of properties that are visible for this object.

Method detail

Analysis.Activate() → None

Activate the current object.

Analysis.AddAMOverhangConstraint() → Ansys.ACT.Automation.Mechanical.AMOverhangConstraint

Creates a new AMOverhangConstraint

Analysis.AddAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Acceleration

Creates a new Acceleration

Analysis.AddAcousticAbsorptionElement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticAbsorptionElement

Creates a new AcousticAbsorptionElement

Analysis.AddAcousticAbsorptionSurface() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticAbsorptionSurface

Creates a new AcousticAbsorptionSurface

Analysis.AddAcousticDiffuseSoundField() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticDiffuseSoundField

Creates a new AcousticDiffuseSoundField

Analysis.AddAcousticFarFieldRadationSurface() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticFarFieldRadationSurface

Creates a new AcousticFarFieldRadationSurface

Analysis.AddAcousticFreeSurface() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticFreeSurface

Creates a new AcousticFreeSurface

Analysis.AddAcousticImpedanceBoundary() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticImpedanceBoundary

Creates a new AcousticImpedanceBoundary

Analysis.AddAcousticImpedanceSheet() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticImpedanceSheet

Creates a new AcousticImpedanceSheet

Analysis.AddAcousticIncidentWaveSource() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticIncidentWaveSource

Creates a new AcousticIncidentWaveSource

Analysis.AddAcousticLowReducedFrequency() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticLowReducedFrequency

Creates a new AcousticLowReducedFrequency

Analysis.AddAcousticMassSource() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticMassSource

Creates a new AcousticMassSource

Analysis.AddAcousticMassSourceRate() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticMassSourceRate

Creates a new AcousticMassSourceRate

Analysis.AddAcousticPort() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticPort

Creates a new AcousticPort

Analysis.AddAcousticPortInDuct() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticPortInDuct

Creates a new AcousticPortInDuct

Analysis.AddAcousticPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticPressure

Creates a new AcousticPressure

Analysis.AddAcousticRadiationBoundary() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticRadiationBoundary

Creates a new AcousticRadiationBoundary

Analysis.AddAcousticRigidWall() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticRigidWall

Creates a new AcousticRigidWall

Analysis.AddAcousticStaticPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticStaticPressure

Creates a new AcousticStaticPressure

Analysis.AddAcousticSurfaceAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticSurfaceAcceleration

Creates a new AcousticSurfaceAcceleration

Analysis.AddAcousticSurfaceVelocity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticSurfaceVelocity

Creates a new AcousticSurfaceVelocity

Analysis.AddAcousticSymmetryPlane() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticSymmetryPlane

Creates a new AcousticSymmetryPlane

Analysis.AddAcousticTemperature() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticTemperature

Creates a new child ThermalCondition.

Analysis.AddAcousticThermoViscousBLIBoundary() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticThermoViscousBLIBoundary

Creates a new AcousticThermoViscousBLIBoundary

Analysis.AddAcousticTransferAdmittanceMatrix() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.AcousticTransferAdmittanceMatrix

Creates a new AcousticTransferAdmittanceMatrix

Analysis.AddBearingLoad() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.BearingLoad

Creates a new BearingLoad

Analysis.AddBodyControl() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.BodyControl

Creates a new BodyControl

Analysis.AddBoltPretension() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.BoltPretension

Creates a new BoltPretension

Analysis.AddCenterOfGravityConstraint() → Ansys.ACT.Automation.Mechanical.CenterOfGravityConstraint

Creates a new CenterOfGravityConstraint

Analysis.AddCommandSnippet() → Ansys.ACT.Automation.Mechanical.CommandSnippet

Creates a new CommandSnippet

Analysis.AddComment() → Ansys.ACT.Automation.Mechanical.Comment

Creates a new child Comment.

Analysis.AddComplexityIndexConstraint() → Ansys.ACT.Automation.Mechanical.ComplexityIndexConstraint

Creates a new ComplexityIndexConstraint

Analysis.AddComplianceConstraint() → Ansys.ACT.Automation.Mechanical.ComplianceConstraint

Creates a new ComplianceConstraint

Analysis.AddCompressionOnlySupport() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.CompressionOnlySupport

Creates a new CompressionOnlySupport

Analysis.AddConstraintEquation() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ConstraintEquation

Creates a new ConstraintEquation

Analysis.AddContactStepControl() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ContactStepControl

Creates a new ContactStepControl

Analysis.AddConvection() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Convection

Creates a new Convection

Analysis.AddCoupling() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Coupling

Creates a new Coupling

Analysis.AddCriterionConstraint() → Ansys.ACT.Automation.Mechanical.CriterionConstraint

Creates a new CriterionConstraint

Analysis.AddCurrent() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Current

Creates a new Current

Analysis.AddCyclicManufacturingConstraint() → Ansys.ACT.Automation.Mechanical.CyclicManufacturingConstraint

Creates a new CyclicManufacturingConstraint

Analysis.AddCylindricalSupport() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.CylindricalSupport

Creates a new CylindricalSupport

Analysis.AddDetonationPoint() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.DetonationPoint

Creates a new DetonationPoint

Analysis.AddDisplacement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Displacement

Creates a new Displacement

Analysis.AddDisplacementConstraint() → Ansys.ACT.Automation.Mechanical.DisplacementConstraint

Creates a new DisplacementConstraint

Analysis.AddDynamicComplianceConstraint() → Ansys.ACT.Automation.Mechanical.DynamicComplianceConstraint

Creates a new DynamicComplianceConstraint

Analysis.AddEMTransducer() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.EMTransducer

Creates a new EMTransducer

Analysis.AddEarthGravity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.EarthGravity

Creates a new EarthGravity

Analysis.AddElasticSupport() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ElasticSupport

Creates a new ElasticSupport

Analysis.AddElectricCharge() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ElectricCharge

Creates a new ElectricCharge

Analysis.AddElementBirthAndDeath() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ElementBirthAndDeath

Creates a new ElementBirthAndDeath

Analysis.AddExtrusionManufacturingConstraint() → Ansys.ACT.Automation.Mechanical.ExtrusionManufacturingConstraint

Creates a new ExtrusionManufacturingConstraint

Analysis.AddFigure() → Ansys.ACT.Automation.Mechanical.Figure

Creates a new child Figure.

Analysis.AddFixedRotation() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FixedRotation

Creates a new FixedRotation

Analysis.AddFixedSupport() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FixedSupport

Creates a new FixedSupport

Analysis.AddFluidPenetrationPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FluidPenetrationPressure

Creates a new Fluid Penetration Pressure object in Mechanical. This load object is used to simulate surrounding fluid or air penetrating into the contact interface.
    Users can apply this load to flexible-to-flexible or rigid-to-flexible contact pairs. This load object is available for static structural analysis.

Analysis.AddFluidSolidInterface() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FluidSolidInterface

Creates a new FluidSolidInterface

Analysis.AddForce() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Force

Creates a new Force

Analysis.AddFrictionlessSupport() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FrictionlessSupport

Creates a new FrictionlessSupport

Analysis.AddGeneralizedPlaneStrain() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.GeneralizedPlaneStrain

Creates a new GeneralizedPlaneStrain

Analysis.AddGeometryBasedAdaptivity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.GeometryBasedAdaptivity

Creates a new GeometryBasedAdaptivity

Analysis.AddGlobalVonMisesStressConstraint() → Ansys.ACT.Automation.Mechanical.GlobalVonMisesStressConstraint

Creates a new GlobalVonMisesStressConstraint

Analysis.AddHeatFlow() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.HeatFlow

Creates a new HeatFlow

Analysis.AddHeatFlux() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.HeatFlux

Creates a new HeatFlux

Analysis.AddHousingConstraint() → Ansys.ACT.Automation.Mechanical.HousingConstraint

Creates a new HousingConstraint

Analysis.AddHydrostaticPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.HydrostaticPressure

Creates a new HydrostaticPressure

Analysis.AddImage(filePath: str) → Ansys.ACT.Automation.Mechanical.Image

Creates a new child Image.
If a filePath is provided, the image will be loaded from that file,
if not, the image will be a screen capture of the Geometry window.

Analysis.AddImpedanceBoundary() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ImpedanceBoundary

Creates a new ImpedanceBoundary

Analysis.AddImportedCFDPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ImportedCFDPressure

Creates a new ImportedCFDPressure

Analysis.AddImportedLoadExternalData() → Ansys.ACT.Automation.Mechanical.ImportedLoads.ImportedLoadGroup

Creates a new Imported Load (External Data).

Analysis.AddImportedLoadFluidsResultsFile() → Ansys.ACT.Automation.Mechanical.ImportedLoads.ImportedLoadGroup

Creates a new Import Load for Fluids Results File.

Analysis.AddImportedLoadMAPDLResultsFile() → Ansys.ACT.Automation.Mechanical.ImportedLoads.ImportedLoadGroup

Creates a new Import Load for MAPDL Results File.

Analysis.AddImportedRemoteLoadsGroup() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.LoadGroup

Creates a new Import Remote Load Group.

Analysis.AddInitialVelocity() → Ansys.ACT.Automation.Mechanical.InitialCondition

Creates a new child Initial Velocity.

Analysis.AddInternalHeatGeneration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.InternalHeatGeneration

Creates a new InternalHeatGeneration

Analysis.AddJointLoad() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.JointLoad

Creates a new JointLoad

Analysis.AddLimitBoundary() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.LimitBoundary

Creates a new LimitBoundary

Analysis.AddLinePressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.LinePressure

Creates a new LinePressure

Analysis.AddLocalVonMisesStressConstraint() → Ansys.ACT.Automation.Mechanical.LocalVonMisesStressConstraint

Creates a new LocalVonMisesStressConstraint

Analysis.AddMagneticFluxParallel() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.MagneticFluxParallel

Creates a new MagneticFluxParallel

Analysis.AddMassConstraint() → Ansys.ACT.Automation.Mechanical.MassConstraint

Creates a new MassConstraint

Analysis.AddMassFlowRate() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.MassFlowRate

Creates a new MassFlowRate

Analysis.AddMemberSizeManufacturingConstraint() → Ansys.ACT.Automation.Mechanical.MemberSizeManufacturingConstraint

Creates a new MemberSizeManufacturingConstraint

Analysis.AddMoment() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Moment

Creates a new Moment

Analysis.AddMomentOfInertiaConstraint() → Ansys.ACT.Automation.Mechanical.MomentOfInertiaConstraint

Creates a new MomentOfInertiaConstraint

Analysis.AddMorphingRegion() → Ansys.ACT.Automation.Mechanical.MorphingRegion

Creates a new MorphingRegion

Analysis.AddNaturalFrequencyConstraint() → Ansys.ACT.Automation.Mechanical.NaturalFrequencyConstraint

Creates a new NaturalFrequencyConstraint

Analysis.AddNodalDisplacement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NodalDisplacement

Creates a new NodalDisplacement

Analysis.AddNodalForce() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NodalForce

Creates a new NodalForce

Analysis.AddNodalOrientation() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NodalOrientation

Creates a new NodalOrientation

Analysis.AddNodalPressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NodalPressure

Creates a new NodalPressure

Analysis.AddNodalRotation() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NodalRotation

Creates a new NodalRotation

Analysis.AddNonlinearAdaptiveRegion() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.NonlinearAdaptiveRegion

Creates a new NonlinearAdaptiveRegion

Analysis.AddObjective() → Ansys.ACT.Automation.Mechanical.Objective

Creates a new Objective

Analysis.AddOptimizationRegion() → Ansys.ACT.Automation.Mechanical.OptimizationRegion

Creates a new OptimizationRegion

Analysis.AddPSDAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PSDAcceleration

Creates a new PSDAcceleration

Analysis.AddPSDDisplacement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PSDDisplacement

Creates a new PSDDisplacement

Analysis.AddPSDGAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PSDGAcceleration

Creates a new PSDGAcceleration

Analysis.AddPSDVelocity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PSDVelocity

Creates a new PSDVelocity

Analysis.AddPatternRepetitionConstraint() → Ansys.ACT.Automation.Mechanical.PatternRepetitionConstraint

Creates a new PatternRepetitionConstraint

Analysis.AddPerfectlyInsulated() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PerfectlyInsulated

Creates a new PerfectlyInsulated

Analysis.AddPhysicsRegion() → Ansys.ACT.Automation.Mechanical.PhysicsRegion

Creates a new PhysicsRegion

Analysis.AddPipeIdealization() → Ansys.ACT.Automation.Mechanical.PipeIdealization

Creates a new child PipeIdealization.

Analysis.AddPipePressure() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PipePressure

Creates a new PipePressure

Analysis.AddPipeTemperature() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PipeTemperature

Creates a new PipeTemperature

Analysis.AddPlasticHeating() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.PlasticHeating

Creates a new PlasticHeating

Analysis.AddPressure(representation: Ansys.Mechanical.DataModel.MechanicalEnums.BoundaryConditions.DataRepresentation) → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Pressure

Creates a new child Pressure.
DataRepresentation.Field will use the Field object for working with tabular data
DataRepresentation.Flexible allows the use of the following types when the pressure is defined as a normal to a surface:
Quantity: The unit must be a valid Pressure unit
string: It is interpreted as s table if it matches a Table name. Else it is interpreted as an expresion
Table: A table object can be specified.

Analysis.AddPullOutDirectionManufacturingConstraint() → Ansys.ACT.Automation.Mechanical.PullOutDirectionManufacturingConstraint

Creates a new PullOutDirectionManufacturingConstraint

Analysis.AddPythonCodeEventBased() → Ansys.ACT.Automation.Mechanical.PythonCodeEventBased

Creates a new PythonCodeEventBased

Analysis.AddRSAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RSAcceleration

Creates a new RSAcceleration

Analysis.AddRSDisplacement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RSDisplacement

Creates a new RSDisplacement

Analysis.AddRSVelocity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RSVelocity

Creates a new RSVelocity

Analysis.AddRadiation() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Radiation

Creates a new Radiation

Analysis.AddReactionForceConstraint() → Ansys.ACT.Automation.Mechanical.ReactionForceConstraint

Creates a new ReactionForceConstraint

Analysis.AddRemoteDisplacement() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RemoteDisplacement

Creates a new RemoteDisplacement

Analysis.AddRemoteForce() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RemoteForce

Creates a new RemoteForce

Analysis.AddRotatingForce() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RotatingForce

Creates a new RotatingForce

Analysis.AddRotationalAcceleration() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RotationalAcceleration

Creates a new RotationalAcceleration

Analysis.AddRotationalVelocity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.RotationalVelocity

Creates a new RotationalVelocity

Analysis.AddSimplySupported() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.SimplySupported

Creates a new SimplySupported

Analysis.AddSourceConductor() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.LoadGroup

Creates a new child SourceConductor.

Analysis.AddSubstructureGenerationCondensedPart() → Ansys.ACT.Automation.Mechanical.SubstructureGenerationCondensedPart

Creates a new SubstructureGenerationCondensedPart

Analysis.AddSurfaceChargeDensity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.SurfaceChargeDensity

Creates a new SurfaceChargeDensity

Analysis.AddSymmetryManufacturingConstraint() → Ansys.ACT.Automation.Mechanical.SymmetryManufacturingConstraint

Creates a new SymmetryManufacturingConstraint

Analysis.AddSystemCouplingRegion() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.FluidSolidInterface

Creates a new SystemCouplingRegion

Analysis.AddTemperature(representation: Ansys.Mechanical.DataModel.MechanicalEnums.BoundaryConditions.DataRepresentation) → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Temperature

Creates a new child Temperature.
DataRepresentation.Field will use the Field object for working with tabular data
DataRepresentation.Flexible allows the use of the following types:
Quantity: The unit must be a valid temperature unit
string: It is interpreted as s table if it matches a Table name. Else it is interpreted as an expresion
Table: A table object can be specified.

Analysis.AddTemperatureConstraint() → Ansys.ACT.Automation.Mechanical.TemperatureConstraint

Creates a new TemperatureConstraint

Analysis.AddThermalComplianceConstraint() → Ansys.ACT.Automation.Mechanical.ThermalComplianceConstraint

Creates a new ThermalComplianceConstraint

Analysis.AddThermalCondition(representation: Ansys.Mechanical.DataModel.MechanicalEnums.BoundaryConditions.DataRepresentation) → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ThermalCondition

Creates a new child ThermalCondition.
DataRepresentation.Field will use the Field object for working with tabular data
DataRepresentation.Flexible allows the use of the following types:
Quantity: The unit must be a valid temperature unit
string: It is interpreted as s table if it matches a Table name. Else it is interpreted as an expresion
Table: A table object can be specified.

Analysis.AddUniformConstraint() → Ansys.ACT.Automation.Mechanical.UniformConstraint

Creates a new UniformConstraint

Analysis.AddVelocity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Velocity

Creates a new Velocity

Analysis.AddViscoelasticHeating() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.ViscoelasticHeating

Creates a new ViscoelasticHeating

Analysis.AddVoltage() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Voltage

Creates a new Voltage

Analysis.AddVoltageCoupling() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.Coupling

Creates a new Coupling

Analysis.AddVoltageGround() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.VoltageGround

Creates a new VoltageGround

Analysis.AddVolumeChargeDensity() → Ansys.ACT.Automation.Mechanical.BoundaryConditions.VolumeChargeDensity

Creates a new VolumeChargeDensity

Analysis.AddVolumeConstraint() → Ansys.ACT.Automation.Mechanical.VolumeConstraint

Creates a new VolumeConstraint

Analysis.ClearGeneratedData() → None

Run the ClearGeneratedData action.

Analysis.CopyTo(other: Ansys.ACT.Automation.Mechanical.DataModelObject) → None

Copies all visible properties from this object to another.

Analysis.CreateAutomaticFSI() → None

Run the CreateAutomaticFSI action.

Analysis.CreateAutomaticFSIandFarFieldRadiationSurfaces() → None

Run the CreateAutomaticFSIandEquivalentSourceSurfaces action.

Analysis.CreateAutomaticFarFieldRadiationSurfaces() → None

Run the CreateAutomaticEquivalentSourceSurfaces action.

Analysis.CreateParameter(propName: str) → Ansys.ACT.Interfaces.Mechanical.IParameter

Creates a new parameter for a Property.

Analysis.Delete() → None

Run the Delete action.

Analysis.Duplicate() → Ansys.Mechanical.DataModel.Interfaces.IDataModelObject

Duplicate method.

Analysis.ExportNastranFile(exportOptions: Ansys.ACT.Automation.Mechanical.NastranExportOptions) → None

Export Nastran File.

Analysis.FilterBasedOnEnvironment() → None

Enables interface filtering that only displays model-level items applicable to
    the currently selected environment type.

Analysis.GetChildren(recurses: bool, children: List[ChildrenType]) → List[ChildrenType]

Gets the list of children, filtered by type.

Analysis.GetParameter(propName: str) → Ansys.ACT.Interfaces.Mechanical.IParameter

Gets the parameter corresponding to the given property.

Analysis.GroupAllSimilarChildren() → None

Run the GroupAllSimilarChildren action.

Analysis.GroupSimilarObjects() → Ansys.ACT.Automation.Mechanical.TreeGroupingFolder

Run the GroupSimilarObjects action.

Analysis.ImportLoad(analysis: Ansys.ACT.Automation.Mechanical.Analysis) → None

Import Load action.

Analysis.OpenSolverFilesDirectory() → None

Run the OpenSolverFilesDirectory action.

Analysis.PropertyByAPIName(name: str) → Ansys.ACT.Automation.Mechanical.Property

Get a property by its API name.
If multiple properties have the same API Name, only the first property with that name will be returned.

Analysis.PropertyByName(name: str) → Ansys.ACT.Automation.Mechanical.Property

Get a property by its unique name.

Analysis.RemoveParameter(propName: str) → None

Removes the parameter from the parameter set corresponding to the given property.

Analysis.SelectBodiesWithMultiplePhysicsRegion() → None

Run the SelectBodiesWithMultiplePhysicsRegion action to select the bodies that belong to more than one Physics Region.

Analysis.SelectBodiesWithoutPhysicsRegion() → None

Run the SelectBodiesWithoutPhysicsRegion action to select the bodies that don't belong to a Physics Region.

Analysis.Solve(wait: bool) → None

Run the Solve action.

Analysis.TransferDataFrom(analysis: Ansys.ACT.Automation.Mechanical.Analysis) → None

Transfer Data From action.

Analysis.UnlinkDataFrom(analysis: Ansys.ACT.Automation.Mechanical.Analysis) → None

Unlink Data From action.

Analysis.WriteSystemCouplingFiles(filename: str) → None

Writes the system coupling files. Usage WriteSystemCouplingFiles(“C:Desktoptempscp1.scp”);