public static void Run() { bool dynamic = true; /// Choose one of the mesh files bundled with the project //string meshPath = projectDirectory + "\\cantilever_quad4.msh"; //string meshPath = projectDirectory + "\\cantilever_quad8.msh"; //string meshPath = projectDirectory + "\\cantilever_quad9.msh"; //string meshPath = projectDirectory + "\\cantilever_tri3.msh"; string meshPath = projectDirectory + "\\cantilever_tri6.msh"; /// Or set a path on your machine //string meshPath = @"C:\Users\Serafeim\Desktop\Presentation\cantilever.msh"; (IReadOnlyList <Node> nodes, IReadOnlyList <CellConnectivity <Node> > elements) = GenerateMeshFromGmsh(meshPath); //(IReadOnlyList<Node> nodes, IReadOnlyList<CellConnectivity<Node>> elements) = GenerateUniformMesh(); //(IReadOnlyList<Node> nodes, IReadOnlyList<CellConnectivity<Node>> elements) = GenerateMeshManually(); PreprocessorModel model = CreateModel(nodes, elements); if (dynamic) { ApplyLoadsDynamic(model); } else { ApplyLoadsStatic(model); } OutputRequests output = DefineOutput(); Solve(model, output, dynamic); }
private static OutputRequests DefineOutput() { OutputRequests output = new OutputRequests(workingDirectory + "\\Plots"); output.Displacements = true; output.Strains = true; output.Stresses = true; output.StressesVonMises = true; return(output); }
private static void Solve(PreprocessorModel model, OutputRequests output, bool dynamic) { // Set up the simulation procedure Job job = new Job(model); if (dynamic) { job.Procedure = Job.ProcedureOptions.DynamicImplicit; } else { job.Procedure = Job.ProcedureOptions.Static; } job.Integrator = Job.IntegratorOptions.Linear; job.Solver = Job.SolverOptions.DirectSkyline; job.FieldOutputRequests = output; // Run the simulation job.Submit(); }
private static void SolveDynamicLinearWall() { // Some values string workingDirectory = @"C:\Users\Serafeim\Desktop\Presentation"; double thickness = 0.1; double youngModulus = 2E6; double poissonRatio = 0.3; // Initialize model PreprocessorModel model = PreprocessorModel.Create2DPlaneStress(thickness); // Materials ElasticMaterial2D material = new ElasticMaterial2D(StressState2D.PlaneStress) { YoungModulus = youngModulus, PoissonRatio = poissonRatio }; DynamicMaterial dynamicProperties = new DynamicMaterial(25, 0.05, 0.05, true); // Read mesh from GMSH file string meshPath = workingDirectory + "\\wall.msh"; IReadOnlyList <Node> nodes; IReadOnlyList <CellConnectivity <Node> > elements; using (var reader = new GmshReader <Node>(meshPath)) { (nodes, elements) = reader.CreateMesh((id, x, y, z) => new Node(id: id, x: x, y: y, z: z)); } model.AddMesh2D(nodes, elements, material, dynamicProperties); // Prescribed displacements double tol = 1E-10; IEnumerable <Node> constrainedNodes = nodes.Where(node => Math.Abs(node.Y) <= tol); model.ApplyPrescribedDisplacements(constrainedNodes, StructuralDof.TranslationX, 0.0); model.ApplyPrescribedDisplacements(constrainedNodes, StructuralDof.TranslationY, 0.0); // Loads string accelerogramPath = workingDirectory + "\\elcentro_NS.txt"; Dictionary <IDofType, double> magnifications = new Dictionary <IDofType, double> { { StructuralDof.TranslationX, 1.0 } }; model.SetGroundMotion(accelerogramPath, magnifications, 0.02, 53.74); // Define output OutputRequests output = new OutputRequests(workingDirectory + "\\Plots"); output.Displacements = true; output.Strains = true; output.Stresses = true; output.StressesVonMises = true; // Set up the simulation procedure Job job = new Job(model); job.Procedure = Job.ProcedureOptions.DynamicImplicit; job.Integrator = Job.IntegratorOptions.Linear; job.Solver = Job.SolverOptions.DirectSkyline; job.FieldOutputRequests = output; // Run the simulation job.Submit(); }
private static void SolveStaticLinearWall() { // Some values string workingDirectory = @"C:\Users\Serafeim\Desktop\Presentation"; double height = 3.5; double thickness = 0.1; double youngModulus = 2E6; double poissonRatio = 0.3; double horizontalLoad = 1000.0; // Initialize model PreprocessorModel model = PreprocessorModel.Create2DPlaneStress(thickness); // Materials ElasticMaterial2D material = new ElasticMaterial2D(StressState2D.PlaneStress) { YoungModulus = youngModulus, PoissonRatio = poissonRatio }; // Read mesh from GMSH file string meshPath = workingDirectory + "\\wall.msh"; IReadOnlyList <Node> nodes; IReadOnlyList <CellConnectivity <Node> > elements; using (var reader = new GmshReader <Node>(meshPath)) { (nodes, elements) = reader.CreateMesh((id, x, y, z) => new Node(id: id, x: x, y: y, z: z)); } model.AddMesh2D(nodes, elements, material); // Prescribed displacements double tol = 1E-10; IEnumerable <Node> constrainedNodes = nodes.Where(node => Math.Abs(node.Y) <= tol); model.ApplyPrescribedDisplacements(constrainedNodes, StructuralDof.TranslationX, 0.0); model.ApplyPrescribedDisplacements(constrainedNodes, StructuralDof.TranslationY, 0.0); // Loads Node[] loadedNodes = nodes.Where( node => (Math.Abs(node.Y - height) <= tol) && ((Math.Abs(node.X) <= tol))).ToArray(); if (loadedNodes.Length != 1) { throw new Exception("Only 1 node was expected at the top left corner"); } model.ApplyNodalLoad(loadedNodes[0], StructuralDof.TranslationX, horizontalLoad); // Define output OutputRequests output = new OutputRequests(workingDirectory + "\\Plots"); output.Displacements = true; output.Strains = true; output.Stresses = true; output.StressesVonMises = true; // Set up the simulation procedure Job job = new Job(model); job.Procedure = Job.ProcedureOptions.Static; job.Integrator = Job.IntegratorOptions.Linear; job.Solver = Job.SolverOptions.DirectSkyline; job.FieldOutputRequests = output; // Run the simulation job.Submit(); }