update case and odb2vtk

main
harvo 2 years ago
parent 73d336312e
commit 4002d4401a

12
.gitignore vendored

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*.pyc
*.rpy*
*.msg
*.com
*.dat
*.ipm
*.jnl
*.lck
*.log
*.prt
*.sim
*.sta

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# odb2vtk
Python script converts Abaqus ODB files to VTK format for Paraview visualisation.
This Python script is released with the paper:
Qingbin Liu, Jiang Li, Jie Liu, 2017, ParaView visualization of Abaqus output on the mechanical deformation of complex microstructures, Computers and Geosciences, 99: 135-144.
Please cite it if the script is used in your reports/papers.

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----------input and output path----------
odb_path = 'C:\Temp'
odb_name = 'CP10_L6_DP1'
vtk_path = 'C:\Temp\CP10_L6_DP1'
--------------type of mesh--------------
mesh_type = '12'
-------------number of piece-------------
piecenum = '2'
----setting frame, step and instance----
frame = '1-20'
step = '0'
instance = '0'

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INPPATH = 'C:/abq2020/test1204MC.inp'
ODBPATH = 'C:/abq2020/test1204MC.odb'
OUTPATH = 'C:/abq2020/test1204MC.vtk'
from odbAccess import openOdb
from abaqus import *
from abaqusConstants import *
class DataSet:
def __init__(self):
self.nodes = {}
self.elements = {}
self.stress = {}
self.spstress = {}
self.displacement = {}
def insertNode(self, nid, x, y, z):
self.nodes[int(nid)] = [float(x), float(y), float(z)]
def insertHexa(self, eid, n0, n1, n2, n3, n4, n5, n6, n7):
self.elements[int(eid)] = [int(n0), int(n1), int(n2), int(n3), int(n4), int(n5), int(n6), int(n7)]
def insertStress(self, eid, s11, s22, s33, s12, s13, s23):
self.stress[int(eid)] = [float(s11), float(s22), float(s33), float(s12), float(s13), float(s23)]
def insertSpstress(self, eid, sp1, sp2, sp3):
self.spstress[int(eid)] = [float(sp1), float(sp2), float(sp3)]
def insertDisplacement(self, nid, ux, uy, uz):
self.displacement[int(nid)] = [float(ux), float(uy), float(uz)]
def save(self, file_name):
nids = sorted(self.nodes.keys())
eids = sorted(self.elements.keys())
with open(file_name, 'w') as ofs:
ofs.write('<?xml version="1.0"?>')
ofs.write('<VTKFile type="StructuredGrid" version="0.1" byte_order="LittleEndian" header_type="UInt32">')
ofs.write('<StructuredGrid> WholeExtent="x1 x2 x3 y1 y2 y3 z1 z2 z3">')
ofs.write('<Piece Extent="x1 x2 x3 y1 y2 y3 z1 z2 z3">')
### define Points element ###
ofs.write('<Points>')
ofs.write('<DataArray type="Float32" Name="Points" NumberOfComponents="3" format="ascii">')
for key in nids:
x, y, z = self.nodes[key]
ofs.write("%f %f %f " % (x, y, z))
ofs.write('</DataArray>')
ofs.write('</Points>')
### define PointsData element ###
ofs.write('<PointData Vectors="displacement">')
ofs.write('<DataArray type="Float32" NumberOfComponents="3" format="ascii" Name="displacement">')
for key in nids:
ux, uy, uz = self.displacement[key]
ofs.write("%f %f %f " % (ux, uy, uz))
ofs.write('</DataArray>')
ofs.write('</PointData>')
### define Cells element ###
ofs.write('<Cells>')
ofs.write('<DataArray type="Int64" Name="connectivity" format="ascii">')
for key in eids:
ns = self.elements[key]
nns = map(lambda x: str(x - 1), ns)
cons = " ".join(nns)
ofs.write(cons + ' ')
ofs.write('</DataArray>')
ofs.write('<DataArray type="Int64" Name="offsets" format="ascii">')
for key in eids:
ofs.write("%d " % (key * 8))
ofs.write('</DataArray>')
ofs.write('<DataArray type="UInt8" Name="types" format="ascii">')
for key in eids:
ofs.write("10 ")
ofs.write('</DataArray>')
ofs.write('</Cells>')
### define CellData element ###
ofs.write('<CellData Vectors="PrincipalStress" Tensors="Stress">')
ofs.write('<DataArray type="Float32" Name="PrincipalStress" NumberOfComponents="3" format="ascii">')
for key in eids:
sp1, sp2, sp3 = self.spstress[key][0:]
ofs.write("%f %f %f " % (sp1, sp2, sp3))
ofs.write('</DataArray>')
ofs.write('<DataArray type="Float32" Name="Stress" NumberOfComponents="9" format="ascii">')
for key in eids:
s11, s22, s33, s12, s13, s23 = self.stress[key][0:]
ofs.write("%f %f %f %f %f %f %f %f %f " % (s11, s12, s13, s12, s22, s23, s13, s23, s33))
ofs.write('</DataArray>')
ofs.write('</CellData>')
ofs.write('</Piece>')
ofs.write('</StructuredGrid>')
ofs.write('</VTKFile>')
ofs.close()
data = DataSet()
# 0 - nothing
# 1 - node
# 2 - hexahedron
state = 0
# read input file
with open(INPPATH, 'r') as input_file:
for line in input_file:
if line.strip() == '*Node':
state = 1
elif line.startswith('*Element, type=C3D8R'):
state = 2
else:
if line.startswith("*") and (not line.startswith("**")):
state = 0
elif state == 1:
uid, x, y, z = line.strip().split(',')
data.insertNode(uid, x, y, z)
elif state == 2:
el, n0, n1, n2, n3, n4, n5, n6, n7 = line.strip().split(',')
data.insertHexa(el, n0, n1, n2, n3, n4, n5, n6, n7)
else:
pass
# Open the odb
myodb = openOdb(ODBPATH)
# Get the frame repository for the step, find number of frames (starts at frame 0)
stepName = myodb.steps.keys()[0]
frames = myodb.steps[stepName].frames
numFrames = len(frames)
print("num Frame %d" % (numFrames))
# Isolate the instance, get the number of nodes and elements
instanceName = myodb.rootAssembly.instances.keys()[0]
myInstance = myodb.rootAssembly.instances[instanceName]
numNodes = len(myInstance.nodes)
numElements = len(myInstance.elements)
print("num Element %d, num Node %d" % (numElements, numNodes))
S=myodb.steps[stepName].frames[-1].fieldOutputs['S'].getSubset(position=INTEGRATION_POINT)
SPS=myodb.steps[stepName].frames[-1].fieldOutputs['S'].getSubset(position=INTEGRATION_POINT)
DISP=myodb.steps[stepName].frames[-1].fieldOutputs['U']
print("S: %d DISP: %d" % (len(S.values), len(DISP.values)))
for sts in S.values:
eid = sts.elementLabel
sxx = sts.data[0]
syy = sts.data[1]
szz = sts.data[2]
sxy = sts.data[3]
sxz = sts.data[4]
syz = sts.data[5]
data.insertStress(eid, float(sxx), float(syy), float(szz), float(sxy), float(sxz), float(syz))
for spsts in SPS.values:
eid = spsts.elementLabel
smin = spsts.maxPrincipal
smid = spsts.midPrincipal
smax = spsts.minPrincipal
data.insertSpstress(eid, float(smin), float(smid), float(smax))
for disp in DISP.values:
nid = disp.nodeLabel
ux = disp.data[0]
uy = disp.data[1]
uz = disp.data[2]
data.insertDisplacement(nid, ux, uy, uz)
data.save(OUTPATH)

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SUBROUTINE DFLUX(FLUX,SOL,KSTEP,KINC,TIME,NOEL,NPT,COORDS,JLTYP, TEMP, PRESS, SNAME)
INCLUDE 'ABA_PARAM.INC'
DIMENSION COORDS(3),FLUX(2),TIME(2)
CHARACTER*80 SNAME
real U,AI,v,yita,R0,qm
U=16.5
AI=60.
v=250./60.
yita=0.75
R0=5.
qm=yita*U*AI*1000./3.14/R0/R0
dx=v*TIME(1)
dy=0.
rr= (COORDS(1)-dx)**2 + (COORDS(2)-dy)**2
FLUX(1)=3.*qm*exp(-3.*rr/R0/R0)
! write(*,*) time,dx
! write(*,*) COORDS,rr
! write(*,*) FLUX
! write(*,*)
RETURN
END

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from odbAccess import openOdb
from abaqus import *
from abaqusConstants import *
from utils_odb2vtk import Physical_Quantity
class CAE_Model(Physical_Quantity, object):
def __init__(self):
super(CAE_Model, self).__init__()
# print('self.var_type', self.var_type)
self.nodes = {}
self.elements = {}
self.physical_quantity = {}
def read_inp(self, INPPATH):
# 0 - nothing
# 1 - node
# 2 - hexahedron
state = 0
# read input file
with open(INPPATH, 'r') as input_file:
for line in input_file:
if line.strip() == '*Node':
state = 1
elif line.startswith('*Element, type=C3D8R'):
state = 2
else:
if line.startswith("*") and (not line.startswith("**")):
state = 0
elif state == 1:
nid, x, y, z = line.strip().split(',')
# insertNode(uid, x, y, z)
self.nodes[int(nid)] = [float(x), float(y), float(z)]
elif state == 2:
eid, n0, n1, n2, n3, n4, n5, n6, n7 = line.strip().split(',')
# insertHexa(el, n0, n1, n2, n3, n4, n5, n6, n7)
self.elements[int(eid)] = [int(n0), int(n1), int(
n2), int(n3), int(n4), int(n5), int(n6), int(n7)]
else:
pass
def read_odb(self, ODBPATH):
# Open the odb
myodb = openOdb(ODBPATH)
# Get the frame repository for the step, find number of frames (starts at frame 0)
stepName = myodb.steps.keys()[0]
frames = myodb.steps[stepName].frames
numFrames = len(frames)
print("num Frame %d" % (numFrames))
# Isolate the instance, get the number of nodes and elements
instanceName = myodb.rootAssembly.instances.keys()[0]
myInstance = myodb.rootAssembly.instances[instanceName]
numNodes = len(myInstance.nodes)
numElements = len(myInstance.elements)
print("num Element %d, num Node %d" % (numElements, numNodes))
for var_id in ['U', 'A', 'V', 'RF', 'S', 'LE', 'PE', 'PEEQ', 'NT11', 'HFL', 'RFL11']:
# try:
if var_id == 'NT11':
# S=myodb.steps[stepName].frames[-1].fieldOutputs['S'].getSubset(position=INTEGRATION_POINT)
var_data = myodb.steps[stepName].frames[-1].fieldOutputs[var_id].values
print(var_id+": %d" % (len(var_data)))
self.pq_update(var_id)
self.physical_quantity[var_id] = self.insert(var_data)
# except:
# print('jump ', var_id)
def write_vtk(self, OUTPATH, var_ids):
self.nids = sorted(self.nodes.keys())
self.eids = sorted(self.elements.keys())
with open(OUTPATH, 'w') as ofs:
ofs.write('<?xml version="1.0"?>')
ofs.write(
'<VTKFile type="StructuredGrid" version="0.1" byte_order="LittleEndian" header_type="UInt32">')
ofs.write(
'<StructuredGrid> WholeExtent="x1 x2 x3 y1 y2 y3 z1 z2 z3">')
ofs.write('<Piece Extent="x1 x2 x3 y1 y2 y3 z1 z2 z3">')
### define Points element ###
ofs.write('<Points>')
ofs.write(
'<DataArray type="Float32" Name="Points" NumberOfComponents="3" format="ascii">')
for key in self.nids:
x, y, z = self.nodes[key]
ofs.write("%f %f %f " % (x, y, z))
ofs.write('</DataArray>')
ofs.write('</Points>')
### define Cells element ###
ofs.write('<Cells>')
ofs.write(
'<DataArray type="Int64" Name="connectivity" format="ascii">')
for key in self.eids:
ns = self.elements[key]
nns = map(lambda x: str(x - 1), ns)
cons = " ".join(nns)
ofs.write(cons + ' ')
ofs.write('</DataArray>')
ofs.write('<DataArray type="Int64" Name="offsets" format="ascii">')
for key in self.eids:
ofs.write("%d " % (key * 8))
ofs.write('</DataArray>')
ofs.write('<DataArray type="UInt8" Name="types" format="ascii">')
for key in self.eids:
ofs.write("10 ")
ofs.write('</DataArray>')
ofs.write('</Cells>')
# node data/element data
for var_id in var_ids:
self.pq_update(var_id)
# var_name = var_stress.__name__
var_name = var_id
var_type = self.var_type
NumberOfComponents = str(self.NumberOfComponents)
ofs.write('<'+var_type+'Data '+var_type+'="' + var_name + '">')
ofs.write('<DataArray type="Float32" format="ascii" Name="' +
var_name+'" NumberOfComponents="'+NumberOfComponents+'" >')
self.write(self.physical_quantity[var_id], ofs)
ofs.write('</DataArray>')
ofs.write('</'+var_type+'Data>')
# finshed
ofs.write('</Piece>')
ofs.write('</StructuredGrid>')
ofs.write('</VTKFile>')
ofs.close()
INPPATH = 'C:/Users/Harvo/Downloads/Digital-Twin/thermal/Thermal.inp'
ODBPATH = 'C:/Users/Harvo/Downloads/Digital-Twin/thermal/Thermal.odb'
OUTPATH = 'C:/Users/Harvo/Downloads/Digital-Twin/thermal/Thermal.vtk'
my_model = CAE_Model()
my_model.read_inp(INPPATH)
print('finish read_inp')
my_model.read_odb(ODBPATH)
print('finish read_odb')
my_model.write_vtk(OUTPATH, var_ids=['NT11'])
print('finish write_vtk')

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class Physical_Quantity(object):
def __init__(self):
pass
# Scalars NT11,RFL11
# Vectors displacement,HFL
# Tensors Stress,spstress
def pq_update(self, var_id):
if var_id == 'S':
self.pq_class = Stress()
if var_id == 'SPS':
self.pq_class = Spstress()
if var_id == 'DISP':
self.pq_class = Displacement()
if var_id == 'NT11':
self.pq_class = Temperature()
self.var_type = self.pq_class.var_type
self.NumberOfComponents = self.pq_class.NumberOfComponents
def insert(self, var_data):
return self.pq_class.insertData(var_data)
def write(self, *args):
# print(args)
self.pq_class.writeData(self.nids, self.eids, args)
class Stress:
def __init__(self):
self.var_type = 'Tensors'
self.NumberOfComponents = 9
def insertData(self, var_data):
this_pq = {}
for var_line in var_data:
eid = var_line.elementLabel
sxx = var_line.data[0]
syy = var_line.data[1]
szz = var_line.data[2]
sxy = var_line.data[3]
sxz = var_line.data[4]
syz = var_line.data[5]
this_pq[int(eid)] = [float(sxx), float(syy), float(
szz), float(sxy), float(sxz), float(syz)]
return this_pq
def writeData(self, stress, ofs):
for key in self.eids:
s11, s22, s33, s12, s13, s23 = stress[key][0:]
ofs.write("%f %f %f %f %f %f %f %f %f " %
(s11, s12, s13, s12, s22, s23, s13, s23, s33))
class Spstress:
def __init__(self):
self.var_type = 'Vectors'
self.NumberOfComponents = 3
def insertData(self, var_data):
this_pq = {}
for var_line in var_data:
eid = var_line.elementLabel
smin = var_line.maxPrincipal
smin = var_line.midPrincipal
smin = var_line.minPrincipal
this_pq[int(eid)] = [float(smin), float(smin), float(smin)]
return this_pq
def writeData(self, nids, eids, args):
spstress, ofs = args
for key in eids:
sp1, sp2, sp3 = spstress[key][0:]
ofs.write("%f %f %f " % (sp1, sp2, sp3))
class Displacement:
def __init__(self):
self.var_type = 'Vectors'
self.NumberOfComponents = 3
def insertData(self, var_data):
this_pq = {}
for var_line in var_data:
nid = var_line.nodeLabel
ux = var_line.data[0]
uy = var_line.data[1]
uz = var_line.data[2]
this_pq[int(nid)] = [float(ux), float(uy), float(uz)]
return this_pq
def writeData(self, nids, eids, args):
displacement, ofs = args
for key in nids:
ux, uy, uz = displacement[key]
ofs.write("%f %f %f " % (ux, uy, uz))
class Temperature(object):
def __init__(self):
self.var_type = 'Scalars'
self.NumberOfComponents = 1
def insertData(self, var_data):
this_pq = {}
for var_line in var_data:
nid = var_line.nodeLabel
temp = var_line.data
this_pq[int(nid)] = [float(temp)]
return this_pq
def writeData(self, nids, eids, args):
temperature, ofs = args
for key in nids:
temp = temperature[key][0]
# print(temp)
ofs.write("%f " % (temp,))
# ### define PointsData element ###
# ofs.write('<PointData Vectors="displacement">')
# ofs.write('<DataArray type="Float32" NumberOfComponents="3" format="ascii" Name="displacement">')
# for key in self.nids:
# ux, uy, uz = self.displacement[key]
# ofs.write("%f %f %f " % (ux, uy, uz))
# ofs.write('</DataArray>')
# ofs.write('</PointData>')
# ### define CellData element ###
# ofs.write('<CellData Vectors="PrincipalStress" Tensors="Stress">')
# ofs.write('<DataArray type="Float32" Name="PrincipalStress" NumberOfComponents="3" format="ascii">')
# for key in self.eids:
# sp1, sp2, sp3 = self.spstress[key][0:]
# ofs.write("%f %f %f " % (sp1, sp2, sp3))
# ofs.write('</DataArray>')
# ofs.write('<DataArray type="Float32" Name="Stress" NumberOfComponents="9" format="ascii">')
# for key in self.eids:
# s11, s22, s33, s12, s13, s23 = self.stress[key][0:]
# ofs.write("%f %f %f %f %f %f %f %f %f " % (s11, s12, s13, s12, s22, s23, s13, s23, s33))
# ofs.write('</DataArray>')
# ofs.write('</CellData>')
# ofs.write('</Piece>')
# ofs.write('</StructuredGrid>')
# ofs.write('</VTKFile>')
# ofs.close()
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