def __init__(self,S,color=None,colormap=None,bkcolor=None,bkcolormap=None,linewidth=None,alpha=1.0,mode=None):
Actor.__init__(self)
TriSurface.__init__(self,S.coords,S.edges,S.faces)
self.setLineWidth(linewidth)
self.setColor(color,colormap)
self.setBkColor(bkcolor,bkcolormap)
self.setAlpha(alpha)
self.list = None
def createShellModel():
"""Create the Finite Element Model.
It is supposed here that the Geometry has been created and is available
as a global variable F.
"""
# Turn the Formex structure into a TriSurface
# This guarantees that element i of the Formex is element i of the TriSurface
S = TriSurface(F)
print "The structure has %s nodes, %s edges and %s faces" % (S.ncoords(),S.nedges(),S.nfaces())
nodes = S.coords
elems = S.elems # the triangles
clear()
draw(F)
# Shell section and material properties
# VALUES SHOULD BE SET CORRECTLY
glass_plate = {
'name': 'glass_plate',
'sectiontype': 'shell',
'thickness': 18,
'material': 'glass',
}
glass = {
'name': 'glass',
'young_modulus': 72000,
'shear_modulus': 26200,
'density': 2.5e-9, # T/mm**3
}
print glass_plate
print glass
glasssection = ElemSection(section=glass_plate,material=glass)
PDB = PropertyDB()
# All elements have same property:
PDB.elemProp(set=arange(len(elems)),section=glasssection,eltype='STRI3')
# Calculate the nodal loads
# Area of triangles
area,normals = S.areaNormals()
print "Area:\n%s" % area
### DEFINE LOAD CASE (ask user) ###
res = askItems([('Glass',True),('Snow',False)])
if not res:
return
step = 0
if res['Glass']:
step += 1
NODLoad = zeros((S.ncoords(),3))
# add the GLASS weight
wgt = 450e-6 # N/mm**2
# Or, calculate weight from density:
# wgt = glass_plate['thickness'] * glass['density'] * 9810
# assemble uniform glass load
for e,a in zip(S.elems,area):
NODLoad[e] += [ 0., 0., - a * wgt / 3 ]
# Put the nodal loads in the properties database
for i,P in enumerate(NODLoad):
PDB.nodeProp(tag=step,set=i,cload=[P[0],P[1],P[2],0.,0.,0.])
if res['Snow']:
step += 1
NODLoad = zeros((S.ncoords(),3))
# add NON UNIFORM SNOW
fn = 'hesperia-nieve.prop'
snowp = fromfile(fn,sep=',')
snow_uniform = 320e-6 # N/mm**2
snow_non_uniform = { 1:333e-6, 2:133e-6, 3:133e-6, 4:266e-6, 5:266e-6, 6:667e-6 }
# assemble non-uniform snow load
for e,a,p in zip(S.elems,area,snowp):
NODLoad[e] += [ 0., 0., - a * snow_non_uniform[p] / 3]
# Put the nodal loads in the properties database
for i,P in enumerate(NODLoad):
PDB.nodeProp(tag=step,set=[i],cload=[P[0],P[1],P[2],0.,0.,0.])
# Get support nodes
botnodes = where(isClose(nodes[:,2], 0.0))[0]
bot = nodes[botnodes].reshape((-1,1,3))
GD.message("There are %s support nodes." % bot.shape[0])
botofs = bot + [ 0.,0.,-0.2]
bbot2 = concatenate([bot,botofs],axis=1)
print bbot2.shape
S = Formex(bbot2)
draw(S)
## np_central_loaded = NodeProperty(3, displacement=[[1,radial_displacement]],coords='cylindrical',coordset=[0,0,0,0,0,1])
## #np_transf = NodeProperty(0,coords='cylindrical',coordset=[0,0,0,0,0,1])
## # Radial movement only
## np_fixed = NodeProperty(1,bound=[0,1,1,0,0,0],coords='cylindrical',coordset=[0,0,0,0,0,1])
# Since we left out the ring beam, we enforce no movement at the botnodes
bc = PDB.nodeProp(set=botnodes,bound=[1,1,1,0,0,0],csys=CoordSystem('C',[0,0,0,0,0,1]))
# And we record the name of the bottom nodes set
botnodeset = Nset(bc.nr)
fe_model = Dict(dict(nodes=nodes,elems=elems,prop=PDB,botnodeset=botnodeset,nsteps=step))
export({'fe_model':fe_model})
smooth()
lights(False)
def createFrameModel():
"""Create the Finite Element Model.
It is supposed here that the Geometry has been created and is available
as a global variable F.
"""
wireframe()
lights(False)
# Turn the Formex structure into a TriSurface
# This guarantees that element i of the Formex is element i of the TriSurface
S = TriSurface(F)
nodes = S.coords
elems = S.elems # the triangles
# Create edges and faces from edges
print "The structure has %s nodes, %s edges and %s faces" % (S.ncoords(),S.nedges(),S.nfaces())
# Create the steel structure
E = Formex(nodes[S.edges])
clear()
draw(E)
# Get the tri elements that are part of a quadrilateral:
prop = F.p
quadtri = S.faces[prop==6]
nquadtri = quadtri.shape[0]
print "%s triangles are part of quadrilateral faces" % nquadtri
if nquadtri > 0:
# Create triangle definitions of the quadtri faces
tri = compactElems(S.edges,quadtri)
D = Formex(nodes[tri])
clear()
flatwire()
draw(D,color='yellow')
conn = connections(quadtri)
print conn
# Filter out the single connection edges
internal = [ c[0] for c in conn if len(c[1]) > 1 ]
print "Internal edges in quadrilaterals: %s" % internal
E = Formex(nodes[S.edges],1)
E.p[internal] = 6
wireframe()
clear()
draw(E)
# Remove internal edges
tubes = S.edges[E.p != 6]
print "Number of tube elements after removing %s internals: %s" % (len(internal),tubes.shape[0])
D = Formex(nodes[tubes],1)
clear()
draw(D)
# Beam section and material properties
b = 60
h = 100
t = 4
b1 = b-2*t
h1 = h-2*t
A = b*h - b1*h1
print b*h**3
I1 = (b*h**3 - b1*h1**3) / 12
I2 = (h*b**3 - h1*b1**3) / 12
I12 = 0
J = 4 * A**2 / (2*(b+h)/t)
tube = {
'name':'tube',
'cross_section': A,
'moment_inertia_11': I1,
'moment_inertia_22': I2,
'moment_inertia_12': I12,
'torsional_rigidity': J
}
steel = {
'name':'steel',
'young_modulus' : 206000,
'shear_modulus' : 81500,
'density' : 7.85e-9,
}
print tube
print steel
tubesection = ElemSection(section=tube,material=steel)
# Calculate the nodal loads
# Area of triangles
area,normals = S.areaNormals()
print "Area:\n%s" % area
# compute bar lengths
bars = nodes[tubes]
barV = bars[:,1,:] - bars[:,0,:]
barL = sqrt((barV*barV).sum(axis=-1))
print "Member length:\n%s" % barL
### DEFINE LOAD CASE (ask user) ###
res = askItems([('Steel',True),
('Glass',True),
('Snow',False),
('Solver',None,'select',['Calpy','Abaqus']),
])
if not res:
return
nlc = 0
for lc in [ 'Steel','Glass','Snow' ]:
if res[lc]:
nlc += 1
NODLoad = zeros((nlc,S.ncoords(),3))
nlc = 0
if res['Steel']:
# the STEEL weight
lwgt = steel['density'] * tube['cross_section'] * 9810 # mm/s**2
print "Weight per length %s" % lwgt
# assemble steel weight load
for e,L in zip(tubes,barL):
NODLoad[nlc,e] += [ 0., 0., - L * lwgt / 2 ]
nlc += 1
if res['Glass']:
# the GLASS weight
wgt = 450e-6 # N/mm**2
# assemble uniform glass load
for e,a in zip(S.elems,area):
NODLoad[nlc,e] += [ 0., 0., - a * wgt / 3 ]
nlc += 1
if res['Snow']:
# NON UNIFORM SNOW
fn = 'hesperia-nieve.prop'
snowp = fromfile(fn,sep=',')
snow_uniform = 320e-6 # N/mm**2
snow_non_uniform = { 1:333e-6, 2:133e-6, 3:133e-6, 4:266e-6, 5:266e-6, 6:667e-6 }
# assemble non-uniform snow load
for e,a,p in zip(S.elems,area,snowp):
NODLoad[nlc,e] += [ 0., 0., - a * snow_non_uniform[p] / 3]
nlc += 1
# For Abaqus: put the nodal loads in the properties database
print NODLoad
PDB = PropertyDB()
for lc in range(nlc):
for i,P in enumerate(NODLoad[lc]):
PDB.nodeProp(tag=lc,set=i,cload=[P[0],P[1],P[2],0.,0.,0.])
# Get support nodes
botnodes = where(isClose(nodes[:,2], 0.0))[0]
bot = nodes[botnodes]
GD.message("There are %s support nodes." % bot.shape[0])
# Upper structure
nnodes = nodes.shape[0] # node number offset
ntubes = tubes.shape[0] # element number offset
PDB.elemProp(set=arange(ntubes),section=tubesection,eltype='FRAME3D')
# Create support systems (vertical beams)
bot2 = bot + [ 0.,0.,-200.] # new nodes 200mm below bot
botnodes2 = arange(botnodes.shape[0]) + nnodes # node numbers
nodes = concatenate([nodes,bot2])
supports = column_stack([botnodes,botnodes2])
elems = concatenate([tubes,supports])
## !!!
## THIS SHOULD BE FIXED !!!
supportsection = ElemSection(material=steel,section={
'name':'support',
'cross_section': A,
'moment_inertia_11': I1,
'moment_inertia_22': I2,
'moment_inertia_12': I12,
'torsional_rigidity': J
})
PDB.elemProp(set=arange(ntubes,elems.shape[0]),section=supportsection,eltype='FRAME3D')
# Finally, the botnodes2 get the support conditions
botnodes = botnodes2
## # Radial movement only
## np_fixed = NodeProperty(1,bound=[0,1,1,0,0,0],coords='cylindrical',coordset=[0,0,0,0,0,1])
## # No movement, since we left out the ring beam
## for i in botnodes:
## NodeProperty(i,bound=[1,1,1,0,0,0],coords='cylindrical',coordset=[0,0,0,0,0,1])
## np_central_loaded = NodeProperty(3, displacement=[[1,radial_displacement]],coords='cylindrical',coordset=[0,0,0,0,0,1])
## #np_transf = NodeProperty(0,coords='cylindrical',coordset=[0,0,0,0,0,1])
# Draw the supports
S = connect([Formex(bot),Formex(bot2)])
draw(S,color='black')
if res['Solver'] == 'Calpy':
fe_model = Dict(dict(solver='Calpy',nodes=nodes,elems=elems,prop=PDB,loads=NODLoad,botnodes=botnodes,nsteps=nlc))
else:
fe_model = Dict(dict(solver='Abaqus',nodes=nodes,elems=elems,prop=PDB,botnodes=botnodes,nsteps=nlc))
export({'fe_model':fe_model})
print "FE model created and exported as 'fe_model'"
totalrot = res['total rot']
xmin,xmax = bb[:,axis]
dx = (xmax-xmin) / nslices
x = arange(nslices+1) * dx
N = unitVector(axis)
P = [ bb[0]+N*s for s in x ]
return P,N,totalrot
else:
return None
reset()
smooth()
lights(True)
transparent(False)
setView('horse',[20,20,0])
S = TriSurface.read(getcfg('datadir')+'/horse.gts')
bb = S.bbox()
t = -0.3
bb[0] = (1.0-t)*bb[0] + t*bb[1]
draw(S,bbox=bb,view='front')
try:
P,n,t = askSlices(S.bbox())
except:
exit()
a = t/len(P)
F = S.toFormex()
G = []
axis = res['Direction']
nslices = res['# slices']
totalrot = res['total rot']
xmin,xmax = bb[:,axis]
dx = (xmax-xmin) / nslices
x = arange(nslices+1) * dx
N = unitVector(axis)
P = [ bb[0]+N*s for s in x ]
return P,N,totalrot
else:
return [],[]
smooth()
setView('horse',[20,20,0])
chdir('/home/bene/prj/pyformex/stl')
S = TriSurface.read('horse-upright.gts')
bb = S.bbox()
t = -0.3
bb[0] = (1.0-t)*bb[0] + t*bb[1]
draw(S,bbox=bb,view='front')
P,n,t = askSlices(S.bbox())
a = t/len(P)
F = S.toFormex()
G = []
old = seterr(all='ignore')
for i,p in enumerate(P):
F1 = F.cutAtPlane(p,-n)
F1.setProp(i)
