KratosMultiphysics: /home/runner/work/Documentation/Documentation/master/applications/ULFapplication/test_examples/lagrangian_droplet_test/lagrangian_droplet_test.py File Reference

KratosMultiphysics

KRATOS Multiphysics (Kratos) is a framework for building parallel, multi-disciplinary simulation software, aiming at modularity, extensibility, and high performance. Kratos is written in C++, and counts with an extensive Python interface.

Namespaces
	lagrangian_droplet_test

Functions
def	lagrangian_droplet_test.PrintResults (model_part)

Variables
	lagrangian_droplet_test.domain_size = ProjectParameters.domain_size
	setting the domain size for the problem to be solved More...

dictionary	lagrangian_droplet_test.variables_dictionary
	defining variables to be used More...

	lagrangian_droplet_test.lagrangian_model_part = ModelPart("LagrangianPart");

	lagrangian_droplet_test.SolverType = problem_settings.SolverType
	importing the solvers needed More...

	lagrangian_droplet_test.fluid_only_model_part = ModelPart("FluidOnlyPart");

	lagrangian_droplet_test.element_type = problem_settings.lagrangian_element
	Choosing element type for lagrangian_model_part. More...

	lagrangian_droplet_test.SolverSettings = ProjectParameters.FluidSolverConfiguration

	lagrangian_droplet_test.solver_lagr = import_solver(SolverSettings)

bool	lagrangian_droplet_test.compute_reactions = False

	lagrangian_droplet_test.gid_mode = GiDPostMode.GiD_PostBinary

	lagrangian_droplet_test.deformed_mesh_flag = WriteDeformedMeshFlag.WriteDeformed

	lagrangian_droplet_test.write_conditions = WriteConditionsFlag.WriteConditions

	lagrangian_droplet_test.multifile = MultiFileFlag.SingleFile

string	lagrangian_droplet_test.input_file_name = "lagrangian_droplet_test"

	lagrangian_droplet_test.gid_io = GidIO(input_file_name,gid_mode,multifile,deformed_mesh_flag, write_conditions)

	lagrangian_droplet_test.model_part_io_structure = ModelPartIO(input_file_name)

	lagrangian_droplet_test.box_corner1 = Vector(3);

	lagrangian_droplet_test.box_corner2 = Vector(3);

string	lagrangian_droplet_test.outstring2 = "convergence_info.txt"

	lagrangian_droplet_test.outputfile1 = open(outstring2, 'w')

	lagrangian_droplet_test.add_nodes = problem_settings.adaptive_refinement

	lagrangian_droplet_test.bulk_modulus = problem_settings.bulk_modulus

	lagrangian_droplet_test.density = problem_settings.density

	lagrangian_droplet_test.FSI = problem_settings.FSI

int	lagrangian_droplet_test.eul_model_part = 0

float	lagrangian_droplet_test.gamma = 0.072

float	lagrangian_droplet_test.contact_angle = 360.0

float	lagrangian_droplet_test.zeta_dissapative_JM = 0.0
	this is for sessile droplets#### More...

float	lagrangian_droplet_test.zeta_dissapative_BM = 0.0

float	lagrangian_droplet_test.zeta_dissapative_SM = 0.0

	lagrangian_droplet_test.lag_solver = solver_lagr.CreateSolver(lagrangian_model_part, SolverSettings, eul_model_part, gamma, contact_angle, zeta_dissapative_JM, zeta_dissapative_BM, zeta_dissapative_SM)
	the dissipative force is added utilizing the power law model, utilizing the capillary number when the velocity is the tangential component at the contact line, More...

bool	lagrangian_droplet_test.reform_dofs_at_each_step = False

	lagrangian_droplet_test.pDiagPrecond = DiagonalPreconditioner()

	lagrangian_droplet_test.alpha_shape

	lagrangian_droplet_test.echo_level

bool	lagrangian_droplet_test.Multifile = True

	lagrangian_droplet_test.Dt = ProjectParameters.Dt

	lagrangian_droplet_test.Nsteps = ProjectParameters.nsteps

	lagrangian_droplet_test.final_time = ProjectParameters.max_time

	lagrangian_droplet_test.output_time = ProjectParameters.output_time

	lagrangian_droplet_test.time = ProjectParameters.Start_time

int	lagrangian_droplet_test.out = 0

int	lagrangian_droplet_test.step = 0

	lagrangian_droplet_test.res_name1 = str("water")