def check(self):
if self.currentTab == 0 or True:
#Pipe
if self.lineEdit_outerDiameter.text() == "":
error("Insert some value (OUTER DIAMETER)!", title="INPUT CROSS-SECTION ERROR")
return
elif self.lineEdit_thickness.text() == "":
error("Insert some value (THICKENSS)!", title="INPUT CROSS-SECTION ERROR")
return
offset_y = 0
offset_z = 0
try:
outerDiameter = float(self.lineEdit_outerDiameter.text())
except Exception:
error("Wrong input for OUTER DIAMETER!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
try:
thickness = float(self.lineEdit_thickness.text())
except Exception:
error("Wrong input for THICKENSS!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
if self.lineEdit_offset_y.text() != "":
try:
offset_y = float(self.lineEdit_offset_y.text())
except Exception:
error("Wrong input for OFFSET Y!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
if self.lineEdit_offset_z.text() != "":
try:
offset_z = float(self.lineEdit_offset_z.text())
except Exception:
error("Wrong input for OFFSET Z!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
if outerDiameter<thickness:
error("The OUTER DIAMETER must be greater than THICKNESS!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
elif thickness == 0.0:
error("The THICKNESS must be greater than zero!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
elif abs(offset_y) > 0.2*(outerDiameter/2):
error("The OFFSET_Y must be less than 20{%} of the external radius!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
elif abs(offset_z) > 0.2*(outerDiameter/2):
error("The OFFSET_Y must be less than 20{%} of the external radius!", title=">>> INPUT CROSS-SECTION ERROR <<<")
return
self.cross_section = CrossSection(outerDiameter, thickness, offset_y, offset_z)
self.complete = True
self.close()
else:
pass
def set_flange_cross_section_to_list_elements(self, list_elements):
section_parameters = {}
for element_id in list_elements:
element = self.structural_elements[element_id]
if self.flag_checkBox:
cross_section = element.cross_section
if cross_section is None:
section_parameters = {}
return True
else:
outer_diameter = self.outer_diameter
inner_diameter = cross_section.inner_diameter
thickness = (self.outer_diameter - inner_diameter) / 2
offset_y = cross_section.offset_y
offset_z = cross_section.offset_z
insulation_thickness = cross_section.insulation_thickness
insulation_density = cross_section.insulation_density
else:
outer_diameter = self.outer_diameter
inner_diameter = self.inner_diameter
thickness = (outer_diameter - inner_diameter) / 2
offset_y = self.offset_y
offset_z = self.offset_z
insulation_thickness = self.insulation_thickness
insulation_density = self.insulation_density
if outer_diameter <= inner_diameter:
section_parameters = {}
title = "Invalid input to the outer/inner diameters"
message = "The outer diameter input should be greater than the inner diameter. \n"
message += "This condition must be satified to proceed."
PrintMessageInput([title, message, window_title_1])
return True
section_parameters[element_id] = {
"outer_diameter": outer_diameter,
"thickness": thickness,
"offset_y": offset_y,
"offset_z": offset_z,
"insulation_thickness": insulation_thickness,
"insulation_density": insulation_density
}
for element_id in list_elements:
pipe_section_info = {
"section_type_label": "Pipe section",
"section_parameters": section_parameters[element_id]
}
self.cross_section = CrossSection(
pipe_section_info=pipe_section_info)
self.project.set_cross_section_by_elements([element_id],
self.cross_section)
return False
def mesh_():
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
cross_section = CrossSection(0.05, 0.008)
preprocessor = Preprocessor()
preprocessor.generate('iges_files\\tube_1.iges', 0.01)
preprocessor.set_prescribed_dofs_bc_by_node([40, 1424, 1324], np.zeros(6))
preprocessor.set_material_by_element('all', steel)
preprocessor.set_cross_section_by_element('all', cross_section)
return mesh
def model():
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
cross_section = CrossSection(0.05, 0.008)
preprocessor = Preprocessor()
preprocessor.generate('iges_files\\tube_1.iges', 0.01)
preprocessor.set_prescribed_dofs_bc_by_node([40, 1424, 1324], np.zeros(6))
preprocessor.set_material_by_element('all', steel)
preprocessor.set_cross_section_by_element('all', cross_section)
assembly = AssemblyStructural(preprocessor)
# We need to separate it in multiple atribute or functions as soon as possible.
names = ['Kadd_lump', 'Madd_lump', 'K', 'M', 'Kr', 'Mr', 'K_lump', 'M_lump', 'C_lump', 'Kr_lump', 'Mr_lump', 'Cr_lump']
answer = assembly.get_all_matrices()
return dict(zip(names, answer))
def load_mapped_cross_section(self):
label_etypes = ['pipe_1', 'pipe_2', 'shell']
indexes = [0, 1, 2]
dict_etype_index = dict(zip(label_etypes,indexes))
dict_index_etype = dict(zip(indexes,label_etypes))
dict_tag_entity = self.mesh.get_dict_of_entities()
map_cross_section_to_lines = defaultdict(list)
map_cross_section_to_elements = defaultdict(list)
for line, entity in dict_tag_entity.items():
ext_diam = entity.crossSection.external_diameter
thickness = entity.crossSection.thickness
offset_y = entity.crossSection.offset_y
offset_z = entity.crossSection.offset_z
e_type = entity.element_type
if e_type is None:
e_type = 'pipe_1'
self.acoustic_analysis = True
poisson = entity.material.poisson_ratio
if poisson is None:
poisson = 0
index_etype = dict_etype_index[e_type]
elements = self.mesh.line_to_elements[line]
map_cross_section_to_lines[str([ext_diam, thickness, offset_y, offset_z, poisson, index_etype])].append(line)
map_cross_section_to_elements[str([ext_diam, thickness, offset_y, offset_z, poisson, index_etype])].append(elements)
for key, elements in map_cross_section_to_elements.items():
cross_strings = key[1:-1].split(',')
vals = [float(value) for value in cross_strings]
el_type = dict_index_etype[vals[-1]]
cross_section = CrossSection(vals[0], vals[1], vals[2], vals[3], poisson_ratio=vals[4], element_type=el_type)
list_flatten = [item for sublist in elements for item in sublist]
self.mesh.set_cross_section_by_element(list_flatten, cross_section, update_cross_section=True)
from pulse.preprocessing.cross_section import CrossSection
from pulse.preprocessing.material import Material
from pulse.preprocessing.fluid import Fluid
from pulse.preprocessing.preprocessor import Preprocessor
from pulse.processing.assembly_acoustic import AssemblyAcoustic
from pulse.processing.solution_acoustic import SolutionAcoustic
from pulse.postprocessing.plot_acoustic_data import get_acoustic_frf
# Fluid setup
speed_of_sound = 343.21
density = 1.2041
air = Fluid('air', density, speed_of_sound)
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
# Tube setup
cross_section = CrossSection(0.05, 0.008, offset_y=0, offset_z=0)
cross_section.update_properties()
cross_section_expansion = CrossSection(0.288, 0.008, offset_y=0, offset_z=0)
cross_section_expansion.update_properties()
cross_section_branch = CrossSection(0.025, 0.004, offset_y=0, offset_z=0)
cross_section_branch.update_properties()
# Preprocessor init
preprocessor = Preprocessor()
preprocessor.generate('examples/iges_files/tube_2.iges', 0.01)
preprocessor.set_material_by_element('all', steel)
preprocessor.set_acoustic_pressure_bc_by_node(50, 1 + 0j)
unflanged = True
flanged = False
if unflanged:
from pulse.processing.solution_acoustic import SolutionAcoustic
from pulse.postprocessing.plot_structural_data import get_structural_frf, get_structural_response
from pulse.postprocessing.plot_acoustic_data import get_acoustic_frf, get_acoustic_response
from pulse.animation.plot_function import plot_results
'''
|=============================================================================|
| Please, it's necessary to copy and paste main.py script at OpenPulse file |
| then type "python main.py" in the terminal to run the code ! |
|=============================================================================|
'''
speed_of_sound = 350.337
density = 24.85
hydrogen = Fluid('hydrogen', density, speed_of_sound)
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
# Tube setup
cross_section = CrossSection(0.05, 0.008, offset_y=0.005, offset_z=0.005)
# Mesh init
mesh = Mesh()
run = 2
anechoic_termination = True
if run == 1:
mesh.generate('examples/iges_files/tube_2.iges', 0.01)
mesh.set_acoustic_pressure_BC_by_node([50], 1)
# Anechoic termination
if anechoic_termination:
mesh.set_specific_impedance_BC_by_node(1086, speed_of_sound * density)
if run == 2:
mesh.load_mesh('examples/validation_acoustic/coord.dat',
'examples/validation_acoustic/connect.dat')
# Acoustic boundary conditions - Prescribe pressure
mesh.set_acoustic_pressure_BC_by_node([1], 1)
from time import time
import numpy as np
import matplotlib.pyplot as plt
from pulse.preprocessing.cross_section import CrossSection
from pulse.preprocessing.material import Material
from pulse.preprocessing.mesh import Mesh
from pulse.processing.solution_structural import SolutionStructural
from pulse.postprocessing.plot_data import get_frf
# PREPARING MESH
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
cross_section = CrossSection(0.05, 0.034)
mesh = Mesh()
mesh.load_mesh('coord.dat', 'connect.dat')
mesh.set_material_by_element('all', steel)
mesh.set_cross_section_by_element('all', cross_section)
mesh.set_prescribed_dofs_bc_by_node([1, 1200, 1325], np.zeros(6))
mesh.set_structural_load_bc_by_node([361], np.array([1, 0, 0, 0, 0, 0]))
# SOLVING THE PROBLEM BY TWO AVALIABLE METHODS
frequencies = np.arange(0, 202, 2)
modes = 200
solution = SolutionStructural(mesh)
direct = solution.direct_method(frequencies)
modal = solution.mode_superposition(frequencies, modes)
# GETTING FRF
node = 711
local_dof = 2
mesh = Mesh()
load_file = 1
if load_file==1:
mesh.generate('examples/iges_files/tube_1.iges', 0.01)
mesh.set_prescribed_dofs_bc_by_node([40, 1424, 1324], np.zeros(6))
mesh.set_structural_load_bc_by_node([359], np.array([1,0,0,0,0,0]))
if load_file==2:
mesh.load_mesh('examples/mesh_files/Geometry_01/coord.dat', 'examples/mesh_files/Geometry_01/connect.dat')
mesh.set_prescribed_dofs_bc_by_node([1, 1200, 1325], np.zeros(6))
mesh.set_structural_load_bc_by_node([361], np.array([1,0,0,0,0,0]))
mesh.set_element_type_by_element('all', element_type)
mesh.set_material_by_element('all', steel)
offset = [0.005, 0.005]
cross_section = CrossSection(0.05, 0.008, offset[0], offset[1], steel.poisson_ratio, element_type=element_type, division_number=64)
mesh.set_cross_section_by_element('all', cross_section)
solution = SolutionStructural(mesh)
f_max = 200
df = 2
frequencies = np.arange(0, f_max+df, df)
modes = 200
direct = solution.direct_method(frequencies, is_viscous_lumped=True)
modal = solution.mode_superposition(frequencies, modes, fastest=True)
# natural_frequencies, modal_shape = solution.modal_analysis(modes=20)
dt = time()-t0
print('Total elapsed time:', dt,'[s]')
######################################################################################
## POST-PROCESSING THE RESULTS ##
d_out = 0.05
d_in = 0.034
area = np.pi * ((d_out**2) - (d_in**2)) / 4
Iyy = np.pi * ((d_out**4) - (d_in**4)) / 64
Izz = np.pi * ((d_out**4) - (d_in**4)) / 64
Iyz = 0
section_info = ["Generic section", None]
cross_section = CrossSection(d_out,
0,
0,
0,
steel.poisson_ratio,
element_type=element_type,
area=area,
Iyy=Iyy,
Izz=Izz,
Iyz=Iyz,
additional_section_info=section_info)
# offset = [0.005, 0.005]
# cross_section = CrossSection(0.05, 0.008, offset[0], offset[1], steel.poisson_ratio, element_type=element_type, division_number=64)
preprocessor.set_cross_section_by_element('all', cross_section)
f_max = 200
df = 2
frequencies = np.arange(0, f_max + df, df)
| Please, it's necessary to copy and paste main.py script at OpenPulse file |
| then type "python main.py" in the terminal to run the code ! |
|=============================================================================|
'''
t0 = time()
# PREPARING MESH
speed_of_sound = 331.2 # speed of sound at 0ºC
density = 1.204
air = Fluid('air', density, speed_of_sound)
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
offset = [0.005, 0.005]
element_type = 'pipe_1'
cross_section = CrossSection(0.05,
0.008,
offset_y=offset[0],
offset_z=offset[1],
poisson_ratio=steel.poisson_ratio)
cross_section.update_properties()
preprocessor = Preprocessor()
preprocessor.generate('examples/iges_files/tube_2.iges', 0.01)
# preprocessor.set_acoustic_pressure_bc_by_node([50], 1e5 + 0j)
# preprocessor.set_specific_impedance_bc_by_node(1086, speed_of_sound * density+ 0j)
preprocessor.set_prescribed_dofs_bc_by_node([1136, 1236], np.zeros(6) + 0j)
preprocessor.set_element_type_by_element('all', element_type)
preprocessor.set_fluid_by_element('all', air)
preprocessor.set_material_by_element('all', steel)
preprocessor.set_cross_section_by_element('all', cross_section)
preprocessor.set_structural_load_bc_by_node([50],
from pulse.preprocessing.cross_section import CrossSection
from pulse.preprocessing.material import Material
from pulse.preprocessing.preprocessor import Preprocessor
from pulse.processing.assembly_structural import get_global_matrices
# create materials
steel = Material('Steel', density=7860, young_modulus=210e9, poisson_ratio=0.3)
alloy_steel = Material('AISI4140',
density=7850,
young_modulus=203200000000,
poisson_ratio=0.27)
# create cross sections
large_tube = CrossSection(0.05, 0.034)
thin_tube = CrossSection(0.01, 0.005)
# create preprocessor
preprocessor = Preprocessor()
# define mesh file and element size
preprocessor.generate('tube_2.iges', 0.01)
# set properties to all elements
preprocessor.set_material_by_element('all', steel)
preprocessor.set_cross_section_by_element('all', large_tube)
# set properties for specific lines
preprocessor.set_cross_section_by_line([37, 38, 39], thin_tube)
preprocessor.set_material_by_lines([37, 38, 39], alloy_steel)
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
# Tube setup
section_parameters = {
"outer_diameter": 0.04859,
"thickness": 0.003,
"offset_y": 0,
"offset_z": 0,
"insulation_thickness": 0,
"insulation_density": 0
}
pipe_section_info = {
"section_type_label": "Pipe section",
"section_parameters": section_parameters
}
cross_section1 = CrossSection(pipe_section_info=pipe_section_info)
cross_section1.update_properties()
section_parameters = {
"outer_diameter": 0.04044,
"thickness": 0.003,
"offset_y": 0,
"offset_z": 0,
"insulation_thickness": 0,
"insulation_density": 0
}
pipe_section_info = {
"section_type_label": "Pipe section",
"section_parameters": section_parameters
}
from pulse.processing.assembly_acoustic import AssemblyAcoustic
from pulse.processing.solution_acoustic import SolutionAcoustic
from pulse.postprocessing.plot_acoustic_data import get_acoustic_frf
# Fluid setup
speed_of_sound = 347.21
density = 1.1614
air = Fluid('air', density, speed_of_sound)
air.isentropic_exponent = 1.400
air.thermal_conductivity = 0.0263
air.specific_heat_Cp = 1007
air.dynamic_viscosity = 1.846e-05
steel = Material('Steel', 7860, young_modulus=210e9, poisson_ratio=0.3)
# Tube setup
cross_section = CrossSection(0.273, 0.00927, offset_y=0, offset_z=0)
cross_section.update_properties()
cross_section_expansion = CrossSection(0.56, 0.00475, offset_y=0, offset_z=0)
cross_section_expansion.update_properties()
# preprocessor init
preprocessor = Preprocessor()
preprocessor.generate('examples/validation_perforated_plate/silencer_wpp.iges',
0.01)
preprocessor.set_material_by_element('all', steel)
preprocessor.set_acoustic_pressure_bc_by_node(188, 2 + 0j)
preprocessor.set_radiation_impedance_bc_by_node(234, 0)
element_type = 'undamped'
preprocessor.set_acoustic_element_type_by_element('all',
element_type,
def getDictOfEntitiesFromFile(self):
material_list = configparser.ConfigParser()
material_list.read(self._materialListPath)
fluid_list = configparser.ConfigParser()
fluid_list.read(self._fluidListPath)
entityFile = configparser.ConfigParser()
entityFile.read(self._entityPath)
dict_material = {}
dict_cross = {}
dict_element_type = {}
dict_fluid = {}
for entity in entityFile.sections():
element_type = entityFile[entity]['Element Type']
if element_type != "":
dict_element_type[int(entity)] = element_type
self.element_type_is_structural = True
else:
dict_element_type[int(entity)] = 'pipe_1'
material_id = entityFile[entity]['Material ID']
if material_id.isnumeric():
material_id = int(material_id)
for material in material_list.sections():
if int(material_list[material]
['identifier']) == material_id:
name = str(material_list[material]['name'])
identifier = str(material_list[material]['identifier'])
density = str(material_list[material]['density'])
youngmodulus = str(
material_list[material]['young modulus'])
poisson = str(material_list[material]['poisson'])
color = str(material_list[material]['color'])
youngmodulus = float(youngmodulus) * (10**(9))
temp_material = Material(name,
float(density),
identifier=int(identifier),
young_modulus=youngmodulus,
poisson_ratio=float(poisson),
color=color)
dict_material[int(entity)] = temp_material
diam_ext = entityFile[entity]['Outer Diameter']
thickness = entityFile[entity]['Thickness']
offset = entityFile[entity]['Offset [e_y, e_z]']
offset_y, offset_z = self._get_offset_from_string(offset)
try:
diam_ext = float(diam_ext)
thickness = float(thickness)
offset_y = float(offset_y)
offset_z = float(offset_z)
cross = CrossSection(
diam_ext, thickness, offset_y, offset_z
) #, poisson_ratio=poisson, element_type=element_type)
dict_cross[int(entity)] = cross
except Exception:
print('Error - load cross-section parameters from file!')
return
fluid_id = entityFile[entity]['Fluid ID']
if fluid_id.isnumeric():
fluid_id = int(fluid_id)
for fluid in fluid_list.sections():
if int(fluid_list[fluid]['identifier']) == fluid_id:
name = str(fluid_list[fluid]['name'])
identifier = str(fluid_list[fluid]['identifier'])
fluid_density = str(fluid_list[fluid]['fluid density'])
speed_of_sound = str(
fluid_list[fluid]['speed of sound'])
# acoustic_impedance = str(fluid_list[fluid]['impedance'])
color = str(fluid_list[fluid]['color'])
temp_fluid = Fluid(name,
float(fluid_density),
float(speed_of_sound),
color=color,
identifier=int(identifier))
dict_fluid[int(entity)] = temp_fluid
return dict_material, dict_cross, dict_element_type, dict_fluid
def accept_pipe(self):
line_diam_externo = float(self.line_diam_externo.text())
line_diam_interno = float(self.line_diam_interno.text())
self.cross = CrossSection(line_diam_externo, line_diam_interno)
self.close()
