public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = (SetFieldsAblDictData)_fileHandler.Read(path); d.xMax = _model.xMax; d.yMax = _model.yMax; d.zMax = _model.zMax; d.logInit = _model.logInit; d.deltaU = _model.deltaU; d.deltaV = _model.deltaV; d.Uperiods = _model.Uperiods; d.Vperiods = _model.Vperiods; d.zPeak = _model.zPeak; d.zInversion = _model.zInversion; d.widthInversion = _model.widthInversion; d.Tbottom = _model.Tbottom; d.Ttop = _model.Ttop; d.dTdz = _model.dTdz; d.Ug = _model.Ug; d.UgDir = _model.UgDir; d.z0 = _model.z0; d.kappa = _model.kappa; d.updateInternalFields = _model.updateInternalFields; d.updateBoundaryFields = _model.updateBoundaryFields; _fileHandler.Write(path, d); _model.AcceptChanges(); }); }
public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = (DecomposeParDictData)_fileHandler.Read(path); d.numberOfSubdomains = _model.ParallelProcessors; //TODO: Mesh refinement _fileHandler.Write(path, d); _model.AcceptChanges(); }); }
public override void Write(string path, object data) { var obj = (TurbulencePropertiesData)data; var txt = new StringBuilder(TurbulencePropertiesRes.Template); txt.Replace("({[[simulationType]]})", obj.SimulationType.ToString()); WriteToFile(path, txt.ToString()); if (_fileHandler != null) { path = path.Replace("\\constant\\turbulenceProperties", ""); _fileHandler.Write(_fileHandler.GetPath(path), (obj.SimulationType == TurbulenceModel.RASModel) ? (object)obj.RasProperties : obj.LesProperties); } }
public Action GetSaveCommand() { return(() => { foreach (var x in viewTurbineType.TurbineTypes) { if (x.ShowInstance != Visibility.Collapsed) { x.Save(_vProject.ProjectDir); } } var p = new TurbineArrayPropData() { outputControl = viewPropArray.OutputControl, outputInterval = viewPropArray.OutputInterval }; foreach (var item in viewPropArray.Turbines) { if (item.ShowInstance != Visibility.Collapsed) { p.turbine.Add(new TurbineInstance() { azimuth = item.Azimuth, baseLocation = new Vertice(item.BaseLocation.X, item.BaseLocation.Y, item.BaseLocation.Z), turbineType = item.TurbineType, bladeUpdateType = item.BladeUpdateType, epsilon = item.Epsilon, fluidDensity = item.FluidDensity, nacYaw = item.NacYaw, numBladePoints = item.NumBladePoints, pitch = item.Pitch, pointDistType = item.PointDistType, pointInterpType = item.PointInterpType, rotSpeed = item.RotSpeed, rotationDir = item.RotationDir, tipRootLossCorrType = item.TipRootLossCorrType }); } } var path = _fileHandler.GetPath(_vProject.ProjectDir); _fileHandler.Write(path, p); }); }
public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = (AblPropertiesData)_fileHandler.Read(path); d.turbineArrayOn = _model.TurbineArrayOn; d.driveWindOn = _model.DriveWindOn; d.UWindSpeedDim.ScalarValue = _model.UWindSpeed; d.UWindDir = _model.UWindDir; d.HWindDim.ScalarValue = _model.HWind; d.alpha = _model.Alpha; d.lowerBoundaryName = _model.LowerBoundaryName; d.upperBoundaryName = _model.UpperBoundaryName; d.meanAvgStartTime = _model.MeanAvgStartTime; d.corrAvgStartTime = _model.CorrAvgStartTime; d.statisticsOn = _model.StatisticsOn; d.statisticsFrequency = _model.StatisticsFrequency; _fileHandler.Write(path, d); _model.AcceptChanges(); }); }
public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = (ControlDictData)_fileHandler.Read(path); d.application = _model.Application; d.startFrom = _model.StartFrom; d.startTime = _model.StartTime; d.stopAt = _model.StopAt; d.endTime = _model.EndTime; d.deltaT = _model.DeltaT; d.writeControl = _model.WriteControl; d.writeInterval = _model.WriteInterval; d.purgeWrite = _model.PurgeWrite; d.writeFormat = _model.WriteFormat; d.writePrecision = _model.WritePrecision; d.writeCompression = _model.WriteCompression; d.timeFormat = _model.TimeFormat; d.timePrecision = _model.TimePrecision; d.runTimeModifiable = _model.IsRunTimeModifiable ? FlagYesNo.yes : FlagYesNo.no; d.adjustTimeStep = _model.AdjustTimeStep ? FlagYesNo.yes : FlagYesNo.no; d.maxCo = _model.MaxCo; d.maxDeltaT = _model.MaxDeltaT; // Functions _fileHandler.Write(path, d); _model.AcceptChanges(); }); }
public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = (TransportPropertiesData)_fileHandler.Read(path); d.betaM = _model.BetaM; d.betaSurfaceStress = _model.BetaSurfaceStress; d.deltaLESCoeff = _model.DeltaLESCoeff; d.gammM = _model.GammM; d.LESModel = _model.LESModel; d.nu = _model.MolecularViscosity; d.z0 = _model.RoughnessHeight; d.Cs = _model.SmagorinskyConstant; d.surfaceStressModel = _model.SurfaceStressModel; d.q0 = _model.SurfaceTemperatureFlux; d.TRef = _model.TRef; d.transportModel = _model.TransportModel; d.kappa = _model.VonKarmanConstant; _fileHandler.Write(path, d); _model.AcceptChanges(); }); }
public Action GetSaveCommand() { return(() => { var path = _fileHandler.GetPath(_vProject.ProjectDir); var d = new FvSchemesData(true); foreach (var x in schemes.cInterpolation) { d.interpolationSchemes.Add(new InterpolationScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, interpolation = x.InterpolationType, view = x.BoundView, lower_limit = (x.BoundView != BoundView.None) ? x.LowerLimit : 0, upper_limit = (x.BoundView != BoundView.None) ? x.UpperLimit : 0, flux = x.Flux, psi = x.Psi }); } foreach (var x in schemes.cSnGrad) { d.snGradSchemes.Add(new SurfaceNormalGradientScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, type = x.SurfaceNoramGradientType, psi = x.Psi }); } foreach (var x in schemes.cGradient) { d.gradSchemes.Add(new GradientScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, interpolation = x.InterpolationType, discretisation = x.DiscretisationType, limited = x.LimitedType, psi = x.Psi }); } foreach (var x in schemes.cDivergence) { d.divSchemes.Add(new DivergenceScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, discretisation = x.DiscretisationType, interpolation = x.InterpolationType, view = x.BoundView, lower_limit = (x.BoundView != BoundView.None) ? x.LowerLimit : 0, upper_limit = (x.BoundView != BoundView.None) ? x.UpperLimit : 0, psi = x.Psi }); } foreach (var x in schemes.cLaplacian) { d.laplacianSchemes.Add(new LaplacianScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, interpolation = x.InterpolationType, discretisation = x.DiscretisationType, snGradScheme = x.SurfaceNoramGradientType, psi = x.Psi }); } foreach (var x in schemes.cTime) { d.ddtSchemes.Add(new TimeScheme() { scheme = x.Scheme, use_default = (x.Scheme == "default"), function = x.Function, type = x.TimeSchemeType, psi = x.Psi }); } foreach (var x in schemes.cFlux) { d.fluxCalculation.Add(new FluxCalculation() { flux = x.Flux, enable = x.Enable }); } _fileHandler.Write(path, d); schemes.AcceptChanges(); }); }