Three dimensional contact for FEA meshes (demo_FEA_contacts.cpp)
Tutorial that teaches how to use the FEA module to perform FEA simulations involving contact between meshes in threedimensional space.
// =============================================================================
// PROJECT CHRONO - http://projectchrono.org
//
// Copyright (c) 2014 projectchrono.org
// All rights reserved.
//
// Use of this source code is governed by a BSD-style license that can be found
// in the LICENSE file at the top level of the distribution and at
// http://projectchrono.org/license-chrono.txt.
//
// =============================================================================
// Authors: Alessandro Tasora
// =============================================================================
//
// FEA contacts
//
// =============================================================================
#include "chrono/physics/ChSystemSMC.h"
#include "chrono/physics/ChBodyEasy.h"
#include "chrono/physics/ChLoadContainer.h"
#include "chrono/geometry/ChTriangleMeshConnected.h"
#include "chrono/solver/ChIterativeSolverLS.h"
#include "chrono/fea/ChElementTetra_4.h"
#include "chrono/fea/ChMesh.h"
#include "chrono/fea/ChMeshFileLoader.h"
#include "chrono/fea/ChContactSurfaceMesh.h"
#include "chrono/fea/ChContactSurfaceNodeCloud.h"
#include "chrono/fea/ChVisualizationFEAmesh.h"
#include "chrono/fea/ChElementCableANCF.h"
#include "chrono/fea/ChBuilderBeam.h"
#include "chrono_irrlicht/ChIrrApp.h"
using namespace chrono;
using namespace chrono::geometry;
using namespace chrono::fea;
using namespace chrono::irrlicht;
using namespace irr;
int main(int argc, char* argv[]) {
// Create a Chrono::Engine physical system
ChSystemSMC my_system;
// Create the Irrlicht visualization (open the Irrlicht device,
// bind a simple user interface, etc. etc.)
// Easy shortcuts to add camera, lights, logo and sky in Irrlicht scene:
application.AddTypicalLogo();
application.AddTypicalSky();
application.AddTypicalLights();
application.AddTypicalCamera(core::vector3df(0, (f32)0.6, -1));
application.AddLightWithShadow(core::vector3df(1.5, 5.5, -2.5), core::vector3df(0, 0, 0), 3, 2.2, 7.2, 40, 512,
video::SColorf(1, 1, 1));
application.SetContactsDrawMode(ChIrrTools::CONTACT_DISTANCES);
//
// CREATE THE PHYSICAL SYSTEM
//
// Set default effective radius of curvature for all SCM contacts.
// collision::ChCollisionModel::SetDefaultSuggestedEnvelope(0.0); // not needed, already 0 when using ChSystemSMC
0.006); // max inside penetration - if not enough stiffness in material: troubles
// Use this value for an outward additional layer around meshes, that can improve
// robustness of mesh-mesh collision detection (at the cost of having unnatural inflate effect)
double sphere_swept_thickness = 0.002;
// Create the surface material, containing information
// about friction etc.
// It is a SMC (penalty) material that we will assign to
// all surfaces that might generate contacts.
auto mysurfmaterial = chrono_types::make_shared<ChMaterialSurfaceSMC>();
mysurfmaterial->SetYoungModulus(6e4);
mysurfmaterial->SetFriction(0.3f);
mysurfmaterial->SetRestitution(0.2f);
mysurfmaterial->SetAdhesion(0);
// Create a floor:
bool do_mesh_collision_floor = false;
auto mmeshbox = chrono_types::make_shared<ChTriangleMeshConnected>();
if (do_mesh_collision_floor) {
// floor as a triangle mesh surface:
auto mfloor = chrono_types::make_shared<ChBody>();
mfloor->SetPos(ChVector<>(0, -1, 0));
mfloor->SetBodyFixed(true);
mfloor->SetMaterialSurface(mysurfmaterial);
my_system.Add(mfloor);
mfloor->GetCollisionModel()->ClearModel();
sphere_swept_thickness);
mfloor->GetCollisionModel()->BuildModel();
mfloor->SetCollide(true);
auto masset_meshbox = chrono_types::make_shared<ChTriangleMeshShape>();
masset_meshbox->SetMesh(mmeshbox);
mfloor->AddAsset(masset_meshbox);
auto masset_texture = chrono_types::make_shared<ChTexture>();
masset_texture->SetTextureFilename(GetChronoDataFile("concrete.jpg"));
mfloor->AddAsset(masset_texture);
} else {
// floor as a simple collision primitive:
auto mfloor = chrono_types::make_shared<ChBodyEasyBox>(2, 0.1, 2, 2700, true);
mfloor->SetBodyFixed(true);
mfloor->SetMaterialSurface(mysurfmaterial);
my_system.Add(mfloor);
auto masset_texture = chrono_types::make_shared<ChTexture>();
masset_texture->SetTextureFilename(GetChronoDataFile("concrete.jpg"));
mfloor->AddAsset(masset_texture);
}
// two falling objects:
auto mcube = chrono_types::make_shared<ChBodyEasyBox>(0.1, 0.1, 0.1, 2700, true);
mcube->SetPos(ChVector<>(0.6, 0.5, 0.6));
mcube->SetMaterialSurface(mysurfmaterial);
my_system.Add(mcube);
auto msphere = chrono_types::make_shared<ChBodyEasySphere>(0.1, 2700, true);
msphere->SetPos(ChVector<>(0.8, 0.5, 0.6));
msphere->SetMaterialSurface(mysurfmaterial);
my_system.Add(msphere);
//
// Example 1: tetrahedrons, with collisions
//
// Create a mesh. We will use it for tetrahedrons.
auto my_mesh = chrono_types::make_shared<ChMesh>();
// 1) a FEA tetrahedron(s):
// Create a material, that must be assigned to each solid element in the mesh,
// and set its parameters
auto mmaterial = chrono_types::make_shared<ChContinuumElastic>();
mmaterial->Set_E(0.01e9); // rubber 0.01e9, steel 200e9
mmaterial->Set_v(0.3);
mmaterial->Set_RayleighDampingK(0.003);
mmaterial->Set_density(1000);
if (false) {
for (int k = 0; k < 3; ++k)
for (int j = 0; j < 3; ++j)
for (int i = 0; i < 3; ++i) {
// Creates the nodes for the tetrahedron
ChVector<> offset(j * 0.21, i * 0.21, k * 0.21);
auto mnode1 = chrono_types::make_shared<ChNodeFEAxyz>(ChVector<>(0, 0.1, 0) + offset);
auto mnode2 = chrono_types::make_shared<ChNodeFEAxyz>(ChVector<>(0, 0.1, 0.2) + offset);
auto mnode3 = chrono_types::make_shared<ChNodeFEAxyz>(ChVector<>(0, 0.3, 0) + offset);
auto mnode4 = chrono_types::make_shared<ChNodeFEAxyz>(ChVector<>(0.2, 0.1, 0) + offset);
my_mesh->AddNode(mnode1);
my_mesh->AddNode(mnode2);
my_mesh->AddNode(mnode3);
my_mesh->AddNode(mnode4);
auto melement1 = chrono_types::make_shared<ChElementTetra_4>();
melement1->SetNodes(mnode1, mnode2, mnode3, mnode4);
melement1->SetMaterial(mmaterial);
my_mesh->AddElement(melement1);
}
}
if (true) {
for (int i = 0; i < 4; ++i) {
try {
ChCoordsys<> cdown(ChVector<>(0, -0.4, 0));
ChCoordsys<> crot(VNULL,
ChCoordsys<> cydisp(ChVector<>(-0.3, 0.1 + i * 0.1, -0.3));
ChCoordsys<> ctot = cdown >> crot >> cydisp;
ChMatrix33<> mrot(ctot.rot);
GetChronoDataFile("fea/beam.ele").c_str(), mmaterial, ctot.pos, mrot);
} catch (ChException myerr) {
GetLog() << myerr.what();
return 0;
}
}
}
// Create the contact surface(s).
// In this case it is a ChContactSurfaceMesh, that allows mesh-mesh collsions.
auto mcontactsurf = chrono_types::make_shared<ChContactSurfaceMesh>();
my_mesh->AddContactSurface(mcontactsurf);
mcontactsurf->AddFacesFromBoundary(sphere_swept_thickness); // do this after my_mesh->AddContactSurface
mcontactsurf->SetMaterialSurface(mysurfmaterial); // use the SMC penalty contacts
// Remember to add the mesh to the system!
my_system.Add(my_mesh);
//
// Example 2: beams, with collisions
//
// Create a mesh. We will use it for beams only.
auto my_mesh_beams = chrono_types::make_shared<ChMesh>();
// 2) an ANCF cable:
auto msection_cable2 = chrono_types::make_shared<ChBeamSectionCable>();
msection_cable2->SetDiameter(0.05);
msection_cable2->SetYoungModulus(0.01e9);
msection_cable2->SetBeamRaleyghDamping(0.05);
ChBuilderCableANCF builder;
builder.BuildBeam(my_mesh_beams, // the mesh where to put the created nodes and elements
msection_cable2, // the ChBeamSectionCable to use for the ChElementCableANCF elements
10, // the number of ChElementCableANCF to create
ChVector<>(0, 0.1, -0.1), // the 'A' point in space (beginning of beam)
ChVector<>(0.5, 0.13, -0.1)); // the 'B' point in space (end of beam)
// Create the contact surface(s).
// In this case it is a ChContactSurfaceNodeCloud, so just pass
// all nodes to it.
auto mcontactcloud = chrono_types::make_shared<ChContactSurfaceNodeCloud>();
my_mesh_beams->AddContactSurface(mcontactcloud);
mcontactcloud->AddAllNodes(0.025); // use larger point size to match beam section radius
mcontactcloud->SetMaterialSurface(mysurfmaterial);
// Remember to add the mesh to the system!
my_system.Add(my_mesh_beams);
//
// Optional... visualization
//
// ==Asset== attach a visualization of the FEM mesh.
// This will automatically update a triangle mesh (a ChTriangleMeshShape
// asset that is internally managed) by setting proper
// coordinates and vertex colors as in the FEM elements.
// Such triangle mesh can be rendered by Irrlicht or POVray or whatever
// postprocessor that can handle a colored ChTriangleMeshShape).
// Do not forget AddAsset() at the end!
auto mvisualizemesh = chrono_types::make_shared<ChVisualizationFEAmesh>(*(my_mesh.get()));
mvisualizemesh->SetFEMdataType(ChVisualizationFEAmesh::E_PLOT_NODE_SPEED_NORM);
mvisualizemesh->SetColorscaleMinMax(0.0, 5.50);
mvisualizemesh->SetSmoothFaces(true);
my_mesh->AddAsset(mvisualizemesh);
auto mvisualizemeshcoll = chrono_types::make_shared<ChVisualizationFEAmesh>(*(my_mesh.get()));
mvisualizemeshcoll->SetFEMdataType(ChVisualizationFEAmesh::E_PLOT_CONTACTSURFACES);
mvisualizemeshcoll->SetWireframe(true);
mvisualizemeshcoll->SetDefaultMeshColor(ChColor(1, 0.5, 0));
my_mesh->AddAsset(mvisualizemeshcoll);
auto mvisualizemeshbeam = chrono_types::make_shared<ChVisualizationFEAmesh>(*(my_mesh_beams.get()));
mvisualizemeshbeam->SetFEMdataType(ChVisualizationFEAmesh::E_PLOT_NODE_SPEED_NORM);
mvisualizemeshbeam->SetColorscaleMinMax(0.0, 5.50);
mvisualizemeshbeam->SetSmoothFaces(true);
my_mesh->AddAsset(mvisualizemeshbeam);
auto mvisualizemeshbeamnodes = chrono_types::make_shared<ChVisualizationFEAmesh>(*(my_mesh_beams.get()));
mvisualizemeshbeamnodes->SetFEMglyphType(ChVisualizationFEAmesh::E_GLYPH_NODE_DOT_POS);
mvisualizemeshbeamnodes->SetFEMdataType(ChVisualizationFEAmesh::E_PLOT_NONE);
mvisualizemeshbeamnodes->SetSymbolsThickness(0.008);
my_mesh->AddAsset(mvisualizemeshbeamnodes);
// ==IMPORTANT!== Use this function for adding a ChIrrNodeAsset to all items
// in the system. These ChIrrNodeAsset assets are 'proxies' to the Irrlicht meshes.
// If you need a finer control on which item really needs a visualization proxy in
// Irrlicht, just use application.AssetBind(myitem); on a per-item basis.
application.AssetBindAll();
// ==IMPORTANT!== Use this function for 'converting' into Irrlicht meshes the assets
// that you added to the bodies into 3D shapes, they can be visualized by Irrlicht!
application.AssetUpdateAll();
// Use shadows in realtime view
application.AddShadowAll();
// SIMULATION LOOP
auto solver = chrono_types::make_shared<ChSolverMINRES>();
my_system.SetSolver(solver);
solver->SetMaxIterations(40);
solver->SetTolerance(1e-12);
solver->EnableDiagonalPreconditioner(true);
solver->EnableWarmStart(true); // Enable for better convergence when using Euler implicit linearized
my_system.SetSolverForceTolerance(1e-10);
application.SetTimestep(0.001);
while (application.GetDevice()->run()) {
application.BeginScene();
application.DrawAll();
application.DoStep();
application.EndScene();
}
return 0;
}
std::string GetChronoDataFile(const std::string &filename)
Obtain the complete path to the specified filename, given relative to the Chrono data directory (thre...
Definition: ChGlobal.cpp:95
static void SetDefaultSuggestedMargin(double mmargin)
Using this function BEFORE you start creating collision shapes, it will make all following collision ...
Definition: ChCCollisionModel.cpp:40
void SetSolverForceTolerance(double tolerance)
Set a solver tolerance threshold at force level (default: not specified).
Definition: ChSystem.h:211
void SetContactsDrawMode(ChIrrTools::eCh_ContactsDrawMode mm)
Set the draw mode for contacts.
Definition: ChIrrAppInterface.h:112
ChLog & GetLog()
Global function to get the current ChLog object.
Definition: ChLog.cpp:39
void SetTimestep(double val)
Set/Get the time step for time integration.
Definition: ChIrrAppInterface.cpp:532
Definition of a 3x3 fixed size matrix to represent 3D rotations and inertia tensors.
Definition: ChMatrix33.h:31
irr::scene::ILightSceneNode * AddLightWithShadow(irr::core::vector3df pos, irr::core::vector3df aim, double radius, double mnear, double mfar, double angle, irr::u32 resolution=512, irr::video::SColorf color=irr::video::SColorf(1.f, 1.f, 1.f, 1.f), bool directional=false, bool clipborder=true)
Add a point light that cast shadow (using soft shadows/shadow maps) Note that the quality of the shad...
Definition: ChIrrAppInterface.h:209
Class to add some GUI to Irrlicht+ChronoEngine applications.
Definition: ChIrrApp.h:29
ChQuaternion< double > Q_from_AngAxis(double angle, const ChVector< double > &axis)
Get the quaternion from an angle of rotation and an axis, defined in abs coords.
Definition: ChQuaternion.cpp:100
virtual void EndScene()
Call this to end the scene draw at the end of each animation frame.
Definition: ChIrrAppInterface.cpp:578
Namespace for classes which represent basic geometric objects.
Definition: ChBasisToolsBspline.h:24
static void SetDefaultEffectiveCurvatureRadius(double eff_radius)
Set the default effective radius of curvature (for SMC contact).
Definition: ChCCollisionInfo.cpp:62
Definition of general purpose 3d vector variables, such as points in 3D.
Definition: ChVector.h:35
virtual void DoStep()
Call this important function inside a cycle like while(application.GetDevice()->run()) {....
Definition: ChIrrAppInterface.cpp:590
static void FromTetGenFile(std::shared_ptr< ChMesh > mesh, const char *filename_node, const char *filename_ele, std::shared_ptr< ChContinuumMaterial > my_material, ChVector<> pos_transform=VNULL, ChMatrix33<> rot_transform=ChMatrix33<>(1))
Load tetrahedrons from .node and .ele files as saved by TetGen.
Definition: ChMeshFileLoader.cpp:42
Class for a physical system in which contact is modeled using a smooth (penalty-based) method.
Definition: ChSystemSMC.h:31
void Add(std::shared_ptr< ChPhysicsItem > item)
Attach an arbitrary ChPhysicsItem (e.g.
Definition: ChAssembly.cpp:190
double ChRandom()
Returns random value in (0..1) interval with Park-Miller method.
Definition: ChMathematics.cpp:53
virtual void SetSolver(std::shared_ptr< ChSolver > newsolver)
Attach a solver (derived from ChSolver) for use by this system.
Definition: ChSystem.cpp:205
Utility class for creating complex beams using ChElementCableANCF elements, for example subdivides a ...
Definition: ChBuilderBeam.h:88
void BuildBeam(std::shared_ptr< ChMesh > mesh, std::shared_ptr< ChBeamSectionCable > sect, const int N, const ChVector<> A, const ChVector<> B)
Adds beam FEM elements to the mesh to create a segment beam from point A to point B,...
Definition: ChBuilderBeam.cpp:257
virtual void BeginScene(bool backBuffer=true, bool zBuffer=true, irr::video::SColor color=irr::video::SColor(255, 0, 0, 0))
Call this to clean the canvas at the beginning of each animation frame.
Definition: ChIrrAppInterface.cpp:559
virtual void DrawAll()
Call this important function inside a loop like while(application.GetDevice()->run()) {....
Definition: ChIrrAppInterface.cpp:699