# -*- coding: utf-8 -*-
-# Copyright (C) 2014-2020 EDF R&D
+# Copyright (C) 2014-2021 EDF R&D
#
# This library is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
#
# See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
#
+"""Fissure dans un coude"""
+import logging
import os
+import math
+
+import GEOM
+import SMESH
+
+from . import initLog
from .geomsmesh import geompy, smesh
from .geomsmesh import geomPublish
from .geomsmesh import geomPublishInFather
-from . import initLog
-
-import math
-import GEOM
-import SALOMEDS
-import SMESH
-import logging
from .fissureGenerique import fissureGenerique
from .creeZoneDefautDansObjetSain import creeZoneDefautDansObjetSain
from .construitFissureGenerale import construitFissureGenerale
from .sortEdges import sortEdges
+from .putName import putName
O, OX, OY, OZ = triedreBase()
class fissureCoude(fissureGenerique):
- """
- problème de fissure du Coude : version de base
- maillage hexa
- """
+ """Problème de fissure du Coude : version de base - maillage hexa"""
nomProbleme = "fissureCoude"
+ longitudinale = None
+ circonferentielle = None
+ elliptique = None
# ---------------------------------------------------------------------------
def setParamGeometrieSaine(self):
Rotation_2 = geompy.MakeRotation(OZ, OY, angleCoude*math.pi/180.0)
tube_2 = geompy.MakePrismVecH(Rotation_1, Rotation_2, -l_tube_p2)
plan_y = geompy.MakePlaneLCS(None, 100000, 3)
- geomPublish(initLog.debug, plan_y, "plan_y" )
- geomPublish(initLog.debug, tube_1, "tube_1" )
- geomPublish(initLog.debug, coude, "coude" )
- geomPublish(initLog.debug, tube_2, "tube_2" )
+ geomPublish(initLog.debug, plan_y, "plan_y", self.numeroCas )
+ geomPublish(initLog.debug, tube_1, "tube_1", self.numeroCas )
+ geomPublish(initLog.debug, coude, "coude", self.numeroCas )
+ geomPublish(initLog.debug, tube_2, "tube_2", self.numeroCas )
P1 = O
- geompy.addToStudy(P1, "P1" )
+ geomPublish(initLog.always, P1, "P1", self.numeroCas )
op2 = geompy.MakeVertex(0, 0, -l_tube_p1)
P2 = geompy.MakeRotation(op2, axe, angleCoude*math.pi/180.0)
P2 = geompy.MakeTranslationVectorDistance(P2, Rotation_2, -l_tube_p2)
- geompy.addToStudy(P2, "P2" )
+ geomPublish(initLog.always, P2, "P2", self.numeroCas )
# --- tube coude sain
geometrieSaine = geompy.MakePartition([tube_1, coude, tube_2, P1, P2], [plan_y], [], [], geompy.ShapeType["SOLID"], 0, [], 1)
- geomPublish(initLog.debug, geometrieSaine, self.nomCas )
+ geomPublish(initLog.debug, geometrieSaine, self.nomCas, self.numeroCas )
[P1, P2] = geompy.RestoreGivenSubShapes(geometrieSaine, [P1, P2], GEOM.FSM_GetInPlaceByHistory, False, True)
xmin = -de -r_cintr -l_tube_p2
grped = geompy.CutGroups(grped, long_p2)
ep = geompy.CutGroups(grped, long_coude)
geomPublishInFather(initLog.debug, geometrieSaine, long_p1, 'long_p1' )
- geomPublishInFather(initLog.debug, geometrieSaine, ep, 'ep' )
+ geomPublishInFather(initLog.debug, geometrieSaine, ep, 'ep')
geomPublishInFather(initLog.debug, geometrieSaine, long_coude, 'long_coude' )
geomPublishInFather(initLog.debug, geometrieSaine, circ_g, 'circ_g' )
geomPublishInFather(initLog.debug, geometrieSaine, circ_d, 'circ_d' )
edge1Ids = geompy.GetShapesOnPlaneIDs(geometrieSaine, geompy.ShapeType["EDGE"], OZ, GEOM.ST_ON)
edge2Ids = geompy.GetShapesOnCylinderIDs(geometrieSaine, geompy.ShapeType["EDGE"], OZ, de/2. -epais, GEOM.ST_ON)
- edgesIds = []
+ edgesIds = list()
for edge in edge1Ids:
if edge in edge2Ids:
edgesIds.append(edge)
pp2 = geompy.MakeTranslationVectorDistance(P2, Rotation_2, 10)
vec2 = geompy.MakeVector(P2, pp2)
- #geomPublish(initLog.debug, vec2, 'vec2')
+ #geomPublish(initLog.debug, vec2, 'vec2', self.numeroCas)
facesIds = geompy.GetShapesOnPlaneIDs(geometrieSaine, geompy.ShapeType["FACE"], vec2, GEOM.ST_ON)
CLGV = geompy.CreateGroup(geometrieSaine, geompy.ShapeType["FACE"])
geompy.UnionIDs(CLGV, facesIds)
extru2 = geompy.MakePrismVecH(rot1, Rotation_2, -l_tube_p2)
interne = geompy.MakeFuse(extru1, revol1)
interne = geompy.MakeFuse(extru2, interne)
- geomPublish(initLog.debug, interne, 'interne')
+ geomPublish(initLog.debug, interne, 'interne', self.numeroCas)
facesIds = geompy.GetShapesOnShapeIDs(interne, geometrieSaine, geompy.ShapeType["FACE"], GEOM.ST_ONIN)
PEAUINT = geompy.CreateGroup(geometrieSaine, geompy.ShapeType["FACE"])
geompy.UnionIDs(PEAUINT, facesIds)
extru2 = geompy.MakePrismVecH(rot1, Rotation_2, -l_tube_p2)
externe = geompy.MakeFuse(extru1, revol1)
externe = geompy.MakeFuse(extru2, externe)
- geomPublish(initLog.debug, externe, 'externe')
+ geomPublish(initLog.debug, externe, 'externe', self.numeroCas)
facesIds = geompy.GetShapesOnShapeIDs(externe, geometrieSaine, geompy.ShapeType["FACE"], GEOM.ST_ON)
PEAUEXT = geompy.CreateGroup(geometrieSaine, geompy.ShapeType["FACE"])
geompy.UnionIDs(PEAUEXT, facesIds)
n_long_p2 = meshParams['n_long_p2']
maillageSain = smesh.Mesh(geometrieSaine)
+ putName(maillageSain, "maillageSain", i_pref=self.numeroCas)
algo3d = maillageSain.Hexahedron()
algo2d = maillageSain.Quadrangle()
- smesh.SetName(algo3d, "algo3d_maillageSain")
- smesh.SetName(algo2d, "algo2d_maillageSain")
algo1d_long_p1 = maillageSain.Segment(geom=long_p1)
hypo1d_long_p1 = algo1d_long_p1.NumberOfSegments(n_long_p1)
- smesh.SetName(algo1d_long_p1, "algo1d_long_p1")
- smesh.SetName(hypo1d_long_p1, "hypo1d_long_p1")
+ putName(hypo1d_long_p1, "n_long_p1={}".format(n_long_p1), i_pref=self.numeroCas)
algo1d_ep = maillageSain.Segment(geom=ep)
hypo1d_ep = algo1d_ep.NumberOfSegments(n_ep)
- smesh.SetName(algo1d_ep, "algo1d_ep")
- smesh.SetName(hypo1d_ep, "hypo1d_ep")
+ putName(hypo1d_ep, "n_ep={}".format(n_ep), i_pref=self.numeroCas)
algo1d_long_coude = maillageSain.Segment(geom=long_coude)
hypo1d_long_coude = algo1d_long_coude.NumberOfSegments(n_long_coude)
- smesh.SetName(algo1d_long_coude, "algo1d_long_coude")
- smesh.SetName(hypo1d_long_coude, "hypo1d_long_coude")
+ putName(hypo1d_long_coude, "n_long_coude={}".format(n_long_coude), i_pref=self.numeroCas)
algo1d_circ_g = maillageSain.Segment(geom=circ_g)
hypo1d_circ_g = algo1d_circ_g.NumberOfSegments(n_circ_g)
- smesh.SetName(algo1d_circ_g, "algo1d_circ_g")
- smesh.SetName(hypo1d_circ_g, "hypo1d_circ_g")
+ putName(hypo1d_circ_g, "n_circ_g={}".format(n_circ_g), i_pref=self.numeroCas)
algo1d_circ_d = maillageSain.Segment(geom=circ_d)
hypo1d_circ_d = algo1d_circ_d.NumberOfSegments(n_circ_d)
- smesh.SetName(algo1d_circ_d, "algo1d_circ_d")
- smesh.SetName(hypo1d_circ_d, "hypo1d_circ_d")
+ putName(hypo1d_circ_d, "n_circ_d={}".format(n_circ_d), i_pref=self.numeroCas)
algo1d_long_p2 = maillageSain.Segment(geom=long_p2)
hypo1d_long_p2 = algo1d_long_p2.NumberOfSegments(n_long_p2)
- smesh.SetName(algo1d_long_p2, "algo1d_long_p2")
- smesh.SetName(hypo1d_long_p2, "hypo1d_long_p2")
-
- is_done = maillageSain.Compute()
- text = "maillageSain.Compute"
- if is_done:
- logging.info(text+" OK")
- else:
- text = "Erreur au calcul du maillage.\n" + text
- logging.info(text)
- raise Exception(text)
+ putName(hypo1d_long_p2, "n_long_p2={}".format(n_long_p2), i_pref=self.numeroCas)
_ = maillageSain.GroupOnGeom(P1,'P1',SMESH.NODE)
_ = maillageSain.GroupOnGeom(P2,'P2',SMESH.NODE)
_ = maillageSain.GroupOnGeom(PEAUEXT,'PEAUEXT',SMESH.FACE)
_ = maillageSain.GroupOnGeom(COUDE,'COUDSAIN',SMESH.VOLUME)
+ is_done = maillageSain.Compute()
+ text = "maillageSain.Compute"
+ if is_done:
+ logging.info(text+" OK")
+ else:
+ text = "Erreur au calcul du maillage.\n" + text
+ logging.info(text)
+ raise Exception(text)
+
return [maillageSain, True] # True : maillage hexa
# ---------------------------------------------------------------------------
logging.info("genereShapeFissure %s", self.nomCas)
logging.info("shapeFissureParams %s", shapeFissureParams)
- angleCoude = geomParams['angleCoude']
r_cintr = geomParams['r_cintr']
l_tube_p1 = geomParams['l_tube_p1']
- l_tube_p2 = geomParams['l_tube_p2']
epais = geomParams['epais']
de = geomParams['de']
if 'elliptique' in shapeFissureParams:
self.elliptique = shapeFissureParams['elliptique']
-
-
azimut = -azimut # axe inverse / ASCOUF
axe = geompy.MakeTranslation(OY, -r_cintr, 0, -l_tube_p1)
- geomPublish(initLog.debug, axe,"axe")
+ geomPublish(initLog.debug, axe, "axe", self.numeroCas)
if not lgInfluence:
lgInfluence = profondeur
self.circonferentielle = False
self.longitudinale = False
if self.fissureLongue and not self.elliptique:
- if abs(orientation) < 45 :
- self.longitudinale = True
- else:
- self.circonferentielle = True
+ self.longitudinale = bool(abs(orientation) < 45)
+ self.circonferentielle = not bool(abs(orientation) < 45)
nbp1 = 10
if self.circonferentielle:
raybor = de/2. - epais
rayint = raybor + profondeur
rayext = raybor - profondeur/5.0
- lgfond = longueur -2*profondeur
- angle = lgfond/(2*raybor)
+ lgfond = longueur -2.*profondeur
+ angle = lgfond/(2.*raybor)
pb = geompy.MakeVertex(raybor, 0, 0)
pi = geompy.MakeVertex(rayint, 0, 0)
pbl = geompy.MakeRotation(pb, OZ, angle)
pbr = geompy.MakeRotation(pb, OZ, -angle)
- geomPublish(initLog.debug, pbl,"pbl")
- geomPublish(initLog.debug, pbr,"pbr")
+ geomPublish(initLog.debug, pbl,"pbl", self.numeroCas)
+ geomPublish(initLog.debug, pbr,"pbr", self.numeroCas)
pal = geompy.MakeTranslationVector(pbl, OZ)
par = geompy.MakeTranslationVector(pbr, OZ)
axl = geompy.MakeVector(pbl,pal)
axr = geompy.MakeVector(pbr,par)
pil = geompy.MakeRotation(pi, OZ, angle)
pir = geompy.MakeRotation(pi, OZ, -angle)
- points = []
+ points = list()
nbp = 3*nbp1
- for i in range(nbp):
- angi = dp*(nbp -i)*(2.0*math.pi/3.0)/nbp
+ for i_aux in range(nbp):
+ angi = dp*(nbp - i_aux)*(2.0*math.pi/3.0)/nbp
pt = geompy.MakeRotation(pil, axl, angi)
points.append(pt)
- for i in range(nbp):
- angi = angle -2.0*i*angle/nbp
+ for i_aux in range(nbp):
+ angi = angle -2.0*float(i_aux)*angle/nbp
pt = geompy.MakeRotation(pi, OZ, angi)
points.append(pt)
- for i in range(nbp+1):
- angi = -dp*i*(2.0*math.pi/3.0)/nbp
+ for i_aux in range(nbp+1):
+ angi = -dp*float(i_aux)*(2.0*math.pi/3.0)/nbp
pt = geompy.MakeRotation(pir, axr, angi)
points.append(pt)
- for i, pt in enumerate(points):
+ for i_aux, pt in enumerate(points):
pt = geompy.MakeRotation(pt, OZ, azimut*math.pi/180.)
pt = geompy.MakeTranslation(pt, 0, 0, -l_tube_p1)
pt = geompy.MakeRotation(pt, axe, alpha*math.pi/180.)
- points[i] = pt
+ points[i_aux] = pt
wire0 = geompy.MakeInterpol(points[0:nbp+1])
wire1 = geompy.MakeInterpol(points[nbp:2*nbp+1])
wire2 = geompy.MakeInterpol(points[2*nbp:3*nbp+1])
#wiretube = geompy.MakeInterpol(points)
wiretube=geompy.MakeWire([wire0,wire1,wire2])
- geomPublish(initLog.debug, wiretube,"wiretube")
+ geomPublish(initLog.debug, wiretube,"wiretube", self.numeroCas)
pe = geompy.MakeVertex(rayext, 0, 0)
pe = geompy.MakeRotation(pe, OZ, azimut*math.pi/180.)
pe = geompy.MakeRotation(pe, axe, alpha*math.pi/180.)
arce = geompy.MakeArc(points[0], pe, points[-1])
- geomPublish(initLog.debug, arce,"arce")
+ geomPublish(initLog.debug, arce,"arce", self.numeroCas)
facefiss = geompy.MakeFaceWires([arce, wiretube], 1)
- geomPublish(initLog.debug, facefiss, 'facefissPlace' )
+ geomPublish(initLog.debug, facefiss, 'facefissPlace', self.numeroCas )
pc = geompy.MakeVertex((raybor + rayint)/2.0, 0, 0)
centre = geompy.MakeRotation(pc, OZ, azimut*math.pi/180.)
centre = geompy.MakeTranslation(centre, 0, 0, -l_tube_p1)
centre = geompy.MakeRotation(centre, axe, alpha*math.pi/180.)
- geomPublish(initLog.debug, centre, 'centrefissPlace' )
+ geomPublish(initLog.debug, centre, 'centrefissPlace', self.numeroCas )
wiretube = geompy.GetInPlace(facefiss, wiretube)
- geomPublish(initLog.debug, wiretube, 'wiretubePlace' )
+ geomPublish(initLog.debug, wiretube, 'wiretubePlace', self.numeroCas )
try:
edgetube = geompy.MakeEdgeWire(wiretube)
- geomPublish(initLog.debug, edgetube,"edgetube")
+ geomPublish(initLog.debug, edgetube,"edgetube", self.numeroCas)
except:
logging.debug("erreur MakeEdgeWire sur fond de fissure, on fait sans")
edgetube = None
pil = geompy.MakeRotation(pi, axe, alfrd -angle, "pil")
pir = geompy.MakeRotation(pi, axe, alfrd +angle, "pir")
- curves = []
+ curves = list()
- points = []
+ points = list()
nbp = 3*nbp1
- xs = []
+ xs = list()
totx = 0
- for i in range(nbp+2):
- x = math.sin(i*math.pi/(nbp+1)) # fonction de répartition des points : distance relative
+ for i_aux in range(nbp+2):
+ x = math.sin(float(i_aux)*math.pi/(nbp+1)) # fonction de répartition des points : distance relative
x2 = x*x
totx += x2
xs.append(totx)
logging.debug("x2: %s, totx: %s", x2, totx)
- for i in range(nbp+1):
- #posi = nbp -i # répartition équidistante des points sur la courbe
- posi = nbp*(1 -xs[i]/totx) # points plus resserrés aux extrémités de la courbe
+ for i_aux in range(nbp+1):
+ #posi = nbp - i_aux # répartition équidistante des points sur la courbe
+ posi = nbp*(1 -xs[i_aux]/totx) # points plus resserrés aux extrémités de la courbe
angi = -dp*posi*(5.0*math.pi/8.0)/nbp
pt = geompy.MakeRotation(pil, axl, angi)
points.append(pt)
curves.append(geompy.MakeInterpol(points))
point0 = points[0]
- geomPublish(initLog.debug, curves[-1],"curve0")
-# for i, pt in enumerate(points):
-# name = "point%d"%i
+ geomPublish(initLog.debug, curves[-1],"curve0", self.numeroCas)
+# for i_aux, pt in enumerate(points):
+# name = "point%d"%i_aux
# geomPublishInFather(initLog.debug,curves[-1], pt, name)
- points = []
+ points = list()
nbp = 3*nbp1
- xs =[]
+ xs = list()
totx = 0
- for i in range(nbp+1):
- x = math.sin(i*math.pi/nbp)
+ for i_aux in range(nbp+1):
+ x = math.sin(float(i_aux)*math.pi/nbp)
#x = 1.0 # répartition équidistante des points sur la courbe
x2 = x*x # points plus resserrés aux extrémités de la courbe
totx += x2
xs.append(totx)
logging.debug("x2: %s, totx: %s", x2, totx)
- for i in range(nbp):
- angi = alfrd -angle +2.0*angle*xs[i]/totx
+ for i_aux in range(nbp):
+ angi = alfrd -angle +2.0*angle*xs[i_aux]/totx
pt = geompy.MakeRotation(pi, axe, angi)
points.append(pt)
curves.append(geompy.MakeInterpol(points))
- geomPublish(initLog.debug, curves[-1],"curve1")
-# for i, pt in enumerate(points):
-# name = "point%d"%i
+ geomPublish(initLog.debug, curves[-1],"curve1", self.numeroCas)
+# for i_aux, pt in enumerate(points):
+# name = "point%d"%i_aux
# geomPublishInFather(initLog.debug,curves[-1], pt, name)
- points = []
+ points = list()
nbp = 3*nbp1
- xs = []
+ xs = list()
totx = 0
- for i in range(nbp+2):
- x = math.sin(i*math.pi/(nbp+1))
+ for i_aux in range(nbp+2):
+ x = math.sin(float(i_aux)*math.pi/(nbp+1))
x2 = x*x
totx += x2
xs.append(totx)
logging.debug("x2: %s, totx: %s", x2, totx)
- for i in range(nbp+1):
- #posi = nbp -i # répartition équidistante des points sur la courbe
- posi = nbp*xs[i]/totx # points plus resserrés aux extrémités de la courbe
+ for i_aux in range(nbp+1):
+ #posi = nbp - i_aux # répartition équidistante des points sur la courbe
+ posi = nbp*xs[i_aux]/totx # points plus resserrés aux extrémités de la courbe
angi = dp*posi*(5.0*math.pi/8.0)/nbp
pt = geompy.MakeRotation(pir, axr, angi)
points.append(pt)
curves.append(geompy.MakeInterpol(points))
point1 = points[-1]
- geomPublish(initLog.debug, curves[-1],"curve2")
-# for i, pt in enumerate(points):
-# name = "point%d"%i
+ geomPublish(initLog.debug, curves[-1],"curve2", self.numeroCas)
+# for i_aux, pt in enumerate(points):
+# name = "point%d"%i_aux
# geomPublishInFather(initLog.debug,curves[-1], pt, name)
wiretube = geompy.MakeWire(curves)
- geomPublish(initLog.debug, wiretube,"wiretube")
+ geomPublish(initLog.debug, wiretube,"wiretube", self.numeroCas)
try:
edgetube = geompy.MakeEdgeWire(wiretube)
- geomPublish(initLog.debug, edgetube,"edgetube")
+ geomPublish(initLog.debug, edgetube,"edgetube", self.numeroCas)
except:
logging.debug("erreur MakeEdgeWire sur fond de fissure, on fait sans")
edgetube = None
- pts = []
+ pts = list()
pts.append(point0)
dpr = prof*math.cos(5.0*math.pi/8.0)
pe = geompy.MakeTranslation(pb, dpr*cosaz, dpr*sinaz, 0., "pe")
- for i in range(nbp):
- angi = alfrd -angle +2.0*i*angle/nbp
+ for i_aux in range(nbp):
+ angi = alfrd -angle +2.0*float(i_aux)*angle/nbp
pt = geompy.MakeRotation(pe, axe, angi)
pts.append(pt)
pts.append(point1)
arce = geompy.MakeInterpol(pts)
- geomPublish(initLog.debug, arce,"arce")
+ geomPublish(initLog.debug, arce,"arce", self.numeroCas)
facefiss = geompy.MakeFaceWires([arce, wiretube], 0)
- geomPublish(initLog.debug, facefiss, 'facefissPlace' )
+ geomPublish(initLog.debug, facefiss, 'facefissPlace', self.numeroCas)
pc = geompy.MakeTranslation(pb, 0.5*prof*cosaz, 0.5*prof*sinaz, 0.)
centre = geompy.MakeRotation(pc, axe, alfrd)
- geomPublish(initLog.debug, centre, 'centrefissPlace' )
+ geomPublish(initLog.debug, centre, 'centrefissPlace', self.numeroCas)
edges = geompy.ExtractShapes(facefiss, geompy.ShapeType["EDGE"], True)
- edgesTriees, minl, maxl = sortEdges(edges)
+ edgesTriees, _, _ = sortEdges(edges)
edges = edgesTriees[:-1] # la plus grande correspond à arce, on l'elimine
wiretube = geompy.MakeWire(edges)
#wiretube = edgesTriees[-1]
- geomPublish(initLog.debug, wiretube, 'wiretubePlace' )
+ geomPublish(initLog.debug, wiretube, 'wiretubePlace', self.numeroCas)
# ---------------------------------------------------------
arci = geompy.MakePosition(arco, originLCS, localLCS, "arci")
arce = geompy.MakePosition(lino, originLCS, localLCS, "arce")
facefiss = geompy.MakeFaceWires([arce, arci], 0)
- geomPublish(initLog.debug, facefiss, 'facefissPlace' )
+ geomPublish(initLog.debug, facefiss, 'facefissPlace', self.numeroCas )
edges = geompy.ExtractShapes(facefiss, geompy.ShapeType["EDGE"], True)
- edgesTriees, minl, maxl = sortEdges(edges)
+ edgesTriees, _, _ = sortEdges(edges)
edgetube = edgesTriees[-1] # la plus grande correspond à arci
wiretube = edgetube
pc = geompy.MakeTranslation(pb, 0.5*prof*cosaz, 0.5*prof*sinaz, 0.)
centre = geompy.MakeRotation(pc, axe, alfrd)
- geomPublish(initLog.debug, centre, 'centrefissPlace' )
+ geomPublish(initLog.debug, centre, 'centrefissPlace', self.numeroCas )
coordsNoeudsFissure = genereMeshCalculZoneDefaut(facefiss, profondeur/2. ,profondeur, \
- mailleur)
+ mailleur, self.numeroCas)
return [facefiss, centre, lgInfluence, coordsNoeudsFissure, wiretube, edgetube]
areteFaceFissure = taille cible de l'arête des triangles en face de fissure.
"""
self.maillageFissureParams = dict(nomRep = os.curdir,
- nomFicSain = self.nomCas,
- nomFicFissure = 'fissure_' + self.nomCas,
+ nomFicSain = self.nomProbleme,
+ nomFicFissure = self.nomProbleme + "_fissure",
nbsegRad = 5,
nbsegCercle = 6,
areteFaceFissure = 5)
# ---------------------------------------------------------------------------
def genereZoneDefaut(self, geometriesSaines, maillagesSains, shapesFissure, shapeFissureParams, maillageFissureParams):
- elementsDefaut = creeZoneDefautDansObjetSain(geometriesSaines, maillagesSains, shapesFissure, shapeFissureParams, maillageFissureParams)
+ elementsDefaut = creeZoneDefautDansObjetSain(geometriesSaines, maillagesSains, shapesFissure, shapeFissureParams, maillageFissureParams, \
+ self.numeroCas)
return elementsDefaut
# ---------------------------------------------------------------------------
mailleur="MeshGems"):
maillageFissure = construitFissureGenerale(shapesFissure, shapeFissureParams, \
maillageFissureParams, elementsDefaut, \
- step, mailleur)
+ mailleur, self.numeroCas)
return maillageFissure
# ---------------------------------------------------------------------------
def setReferencesMaillageFissure(self):
- self.referencesMaillageFissure = dict(Entity_Node = 77917,
- Entity_Quad_Edge = 975,
- Entity_Quad_Triangle = 2182,
- Entity_Quad_Quadrangle = 6842,
- Entity_Quad_Tetra = 20135,
- Entity_Quad_Hexa = 8994,
- Entity_Quad_Penta = 972,
- Entity_Quad_Pyramid = 1038)
+ self.referencesMaillageFissure = dict( \
+ Entity_Quad_Edge = 975, \
+ Entity_Quad_Quadrangle = 6842, \
+ Entity_Quad_Hexa = 8994, \
+ Entity_Node = 77917, \
+ Entity_Quad_Triangle = 2182, \
+ Entity_Quad_Tetra = 20135, \
+ Entity_Quad_Pyramid = 1038, \
+ Entity_Quad_Penta = 972 \
+ )