1 # -*- coding: utf-8 -*-
2 # Copyright (C) 2014-2022 EDF R&D
4 # This library is free software; you can redistribute it and/or
5 # modify it under the terms of the GNU Lesser General Public
6 # License as published by the Free Software Foundation; either
7 # version 2.1 of the License, or (at your option) any later version.
9 # This library is distributed in the hope that it will be useful,
10 # but WITHOUT ANY WARRANTY; without even the implied warranty of
11 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
12 # Lesser General Public License for more details.
14 # You should have received a copy of the GNU Lesser General Public
15 # License along with this library; if not, write to the Free Software
16 # Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
18 # See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
20 """Géométrie et maillage de base nécessaire au cas-test :
24 __revision__ = "V02.08"
31 from salome.shaper import model
32 from salome.smesh import smeshBuilder
33 from SketchAPI import *
37 from blocFissure import gmu
38 from blocFissure.gmu.putName import putName
40 #=============== Options ====================
41 # 1. NOM_OBJET = nom de l'objet
44 # 2.1. Le tube : rayon intérieur, rayon extérieur, hauteur
55 # Nombre de segments du tube
59 #============================================
68 partSet = model.moduleDocument()
71 Part_1 = model.addPart(partSet)
72 Part_1_doc = Part_1.document()
73 model.addParameter(Part_1_doc, "R_I", "%f" % RAYON_INT)
74 model.addParameter(Part_1_doc, "R_E", "%f" % RAYON_EXT)
75 model.addParameter(Part_1_doc, "H", "%f" % HAUTEUR)
76 model.addParameter(Part_1_doc, "F_L_1", "{}".format(F_L_1))
77 model.addParameter(Part_1_doc, "F_THETA_1", "{}".format(F_THETA_1))
78 model.addParameter(Part_1_doc, "F_R_1", "{}*{}".format(F_C_1,RAYON_INT))
79 model.addParameter(Part_1_doc, "F_L_2", "{}".format(F_L_2))
80 model.addParameter(Part_1_doc, "F_D_3", "{}*{}".format(F_C_3,RAYON_INT))
83 Sketch_1 = model.addSketch(Part_1_doc, model.defaultPlane("XOZ"))
86 SketchLine_1 = Sketch_1.addLine(11.11, -22.82842712474619, 9.84, -22.82842712474619)
89 SketchLine_2 = Sketch_1.addLine(9.84, -22.82842712474619, 9.84, 27.17157287525381)
92 SketchLine_3 = Sketch_1.addLine(9.84, 27.17157287525381, 11.11, 27.17157287525381)
95 SketchLine_4 = Sketch_1.addLine(11.11, 27.17157287525381, 11.11, -22.82842712474619)
96 Sketch_1.setCoincident(SketchLine_4.endPoint(), SketchLine_1.startPoint())
97 Sketch_1.setCoincident(SketchLine_1.endPoint(), SketchLine_2.startPoint())
98 Sketch_1.setCoincident(SketchLine_2.endPoint(), SketchLine_3.startPoint())
99 Sketch_1.setCoincident(SketchLine_3.endPoint(), SketchLine_4.startPoint())
100 Sketch_1.setHorizontal(SketchLine_1.result())
101 Sketch_1.setVertical(SketchLine_2.result())
102 Sketch_1.setHorizontal(SketchLine_3.result())
103 Sketch_1.setVertical(SketchLine_4.result())
104 Sketch_1.setLength(SketchLine_4.result(), "H")
106 ### Create SketchProjection
107 SketchProjection_1 = Sketch_1.addProjection(model.selection("VERTEX", "PartSet/Origin"), False)
108 SketchPoint_1 = SketchProjection_1.createdFeature()
109 Sketch_1.setHorizontalDistance(SketchAPI_Point(SketchPoint_1).coordinates(), SketchLine_1.endPoint(), "R_I")
110 Sketch_1.setHorizontalDistance(SketchAPI_Point(SketchPoint_1).coordinates(), SketchLine_1.startPoint(), "R_E")
113 ### Create Revolution
114 Revolution_1 = model.addRevolution(Part_1_doc, [model.selection("FACE", "Sketch_1/Face-SketchLine_4r-SketchLine_3r-SketchLine_2r-SketchLine_1r")], model.selection("EDGE", "PartSet/OZ"), 180, 0)
115 Revolution_1.result().setName("Tube")
116 Revolution_1.result().setTransparency(0.37)
119 Sketch_2 = model.addSketch(Part_1_doc, model.standardPlane("YOZ"))
122 SketchArc_1 = Sketch_2.addArc(-80, 0, 10.10993798722564, 4.722461741385164, 10.10993798722563, -4.722461741385561, True)
124 ### Create SketchProjection
125 SketchProjection_2 = Sketch_2.addProjection(model.selection("EDGE", "PartSet/OY"), False)
126 SketchLine_5 = SketchProjection_2.createdFeature()
127 Sketch_2.setCoincident(SketchArc_1.center(), SketchLine_5.result())
129 ### Create SketchProjection
130 SketchProjection_3 = Sketch_2.addProjection(model.selection("VERTEX", "PartSet/Origin"), False)
131 SketchPoint_2 = SketchProjection_3.createdFeature()
132 Sketch_2.setHorizontalDistance(SketchArc_1.center(), SketchAPI_Point(SketchPoint_2).coordinates(), "F_L_1")
134 ### Create SketchPoint
135 SketchPoint_3 = Sketch_2.addPoint(10.2336, 0)
136 SketchPoint_3.setAuxiliary(True)
137 Sketch_2.setCoincident(SketchPoint_3.coordinates(), SketchArc_1.results()[1])
138 Sketch_2.setMiddlePoint(SketchPoint_3.coordinates(), SketchArc_1.results()[1])
139 Sketch_2.setCoincident(SketchPoint_3.coordinates(), SketchLine_5.result())
141 ### Create SketchProjection
142 SketchProjection_4 = Sketch_2.addProjection(model.selection("VERTEX", "PartSet/Origin"), False)
143 SketchPoint_4 = SketchProjection_4.createdFeature()
144 Sketch_2.setHorizontalDistance(SketchPoint_3.coordinates(), SketchAPI_Point(SketchPoint_4).coordinates(), "F_R_1")
146 ### Create SketchLine
147 SketchLine_6 = Sketch_2.addLine(-80, 0, 10.10993798722564, 4.722461741385164)
148 SketchLine_6.setAuxiliary(True)
149 Sketch_2.setCoincident(SketchArc_1.center(), SketchLine_6.startPoint())
150 Sketch_2.setCoincident(SketchArc_1.startPoint(), SketchLine_6.endPoint())
152 ### Create SketchConstraintAngle
153 Sketch_2.setAngle(SketchLine_5.result(), SketchLine_6.result(), "F_THETA_1", type = "Direct")
155 ### Create SketchEllipticArc
156 SketchEllipticArc_1 = Sketch_2.addEllipticArc(-20, 8.956370781951521e-27, -10.21629725685072, 9.783702743149284, 10.10993798723031, 4.722461741243296, 9.7416, 8.052073253504034, False)
157 [SketchPoint_5, SketchPoint_6, SketchPoint_7, SketchPoint_8, SketchPoint_9, SketchPoint_10, SketchPoint_11, SketchLine_7, SketchLine_8] = \
158 SketchEllipticArc_1.construction(center = "aux", firstFocus = "aux", secondFocus = "aux", majorAxisStart = "aux", majorAxisEnd = "aux", minorAxisStart = "aux", minorAxisEnd = "aux", majorAxis = "aux", minorAxis = "aux")
159 Sketch_2.setCoincident(SketchEllipticArc_1.startPoint(), SketchLine_6.endPoint())
160 Sketch_2.setCoincident(SketchAPI_Point(SketchPoint_5).coordinates(), SketchLine_5.result())
161 Sketch_2.setTangent(SketchEllipticArc_1.result(), SketchArc_1.results()[1])
163 ### Create SketchProjection
164 SketchProjection_5 = Sketch_2.addProjection(model.selection("VERTEX", "PartSet/Origin"), False)
165 SketchPoint_12 = SketchProjection_5.createdFeature()
166 Sketch_2.setHorizontalDistance(SketchAPI_Point(SketchPoint_5).coordinates(), SketchAPI_Point(SketchPoint_12).coordinates(), "F_L_2")
168 ### Create SketchConstraintAngle
169 Sketch_2.setAngle(SketchLine_5.result(), SketchLine_7.result(), 45, type = "Supplementary")
171 ### Create SketchProjection
172 SketchProjection_6 = Sketch_2.addProjection(model.selection("VERTEX", "PartSet/Origin"), False)
173 SketchPoint_13 = SketchProjection_6.createdFeature()
174 Sketch_2.setHorizontalDistance(SketchEllipticArc_1.endPoint(), SketchAPI_Point(SketchPoint_13).coordinates(), "F_D_3")
176 ### Create SketchConstraintMirror
177 SketchConstraintMirror_1 = Sketch_2.addMirror(SketchLine_5.result(), [SketchEllipticArc_1.result()])
178 [SketchEllipticArc_2] = SketchConstraintMirror_1.mirrored()
180 ### Create SketchLine
181 SketchLine_9 = Sketch_2.addLine(9.7416, 8.052073253504034, 9.7416, -8.052073253504034)
182 Sketch_2.setCoincident(SketchEllipticArc_1.endPoint(), SketchLine_9.startPoint())
183 Sketch_2.setCoincident(SketchAPI_EllipticArc(SketchEllipticArc_2).endPoint(), SketchLine_9.endPoint())
187 Face_1 = model.addFace(Part_1_doc, [model.selection("FACE", "Sketch_2/Face-SketchArc_1_2r-SketchEllipticArc_1f-SketchLine_9f-SketchEllipticArc_2f")])
188 Face_1.result().setName("Fissure")
191 Group_1 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "Fissure/Modified_Edge&Sketch_2/SketchEllipticArc_1")])
194 Group_2 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "Fissure/Modified_Edge&Sketch_2/SketchArc_1_2")])
197 Group_3 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "Fissure/Modified_Edge&Sketch_2/SketchEllipticArc_2")])
200 Group_4 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "Fissure/Modified_Edge&Sketch_2/SketchLine_9")])
203 Group_5 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "[Tube/Generated_Face&Sketch_1/SketchLine_1][Tube/From_Face]")])
204 Group_5.setName("Epaisseur")
205 Group_5.result().setName("Epaisseur")
208 Group_6 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "[Tube/Generated_Face&Sketch_1/SketchLine_4][Tube/From_Face]")])
209 Group_6.setName("Hauteur")
210 Group_6.result().setName("Hauteur")
213 Group_7 = model.addGroup(Part_1_doc, "Edges", [model.selection("EDGE", "[Tube/Generated_Face&Sketch_1/SketchLine_4][Tube/Generated_Face&Sketch_1/SketchLine_1]")])
214 Group_7.setName("Peripherie")
215 Group_7.result().setName("Peripherie")
218 ficcao = os.path.join(gmu.pathBloc, "materielCasTests", "{}Fiss.xao".format(NOM_OBJET))
219 text = ".. Exportation de la géométrie de la fissure dans le fichier '{}'".format(ficcao)
221 _ = model.exportToXAO(Part_1_doc, ficcao, model.selection("FACE", "Fissure"), 'XAO')
226 ### SHAPERSTUDY component
229 model.publishToShaperStudy()
231 l_aux = SHAPERSTUDY.shape(model.featureStringId(Revolution_1))
239 smesh = smeshBuilder.New()
240 Maillage_tube = smesh.Mesh(objet)
241 putName(Maillage_tube.GetMesh(), NOM_OBJET)
243 for groupe in l_groups:
244 groupe_nom = groupe.GetName()
245 if ( groupe_nom[:1] == "E" ):
247 elif ( groupe_nom[:1] == "H" ):
249 elif ( groupe_nom[:1] == "P" ):
251 _ = Maillage_tube.GroupOnGeom(groupe,groupe_nom,SMESH.EDGE)
253 Regular_1D = Maillage_tube.Segment()
254 Nb_Segments_1 = Regular_1D.NumberOfSegments(NB_S_P)
255 Nb_Segments_1.SetDistrType( 0 )
256 Quadrangle_2D = Maillage_tube.Quadrangle(algo=smeshBuilder.QUADRANGLE)
257 Hexa_3D = Maillage_tube.Hexahedron(algo=smeshBuilder.Hexa)
259 Regular_1D_1 = Maillage_tube.Segment(geom=group_e)
260 Number_of_Segments_1 = Regular_1D_1.NumberOfSegments(NB_S_E)
261 Propagation_of_1D_Hyp = Regular_1D_1.Propagation()
263 Regular_1D_2 = Maillage_tube.Segment(geom=group_h)
264 Number_of_Segments_2 = Regular_1D_2.NumberOfSegments(NB_S_H)
265 Propagation_of_1D_Hyp_1 = Regular_1D_2.Propagation()
268 #smesh.SetName(Regular_1D.GetAlgorithm(), 'Regular_1D')
269 #smesh.SetName(Quadrangle_2D.GetAlgorithm(), 'Quadrangle_2D')
270 #smesh.SetName(Hexa_3D.GetAlgorithm(), 'Hexa_3D')
271 putName(Nb_Segments_1, 'Nb. Segments_1', i_pref='tube')
272 putName(Number_of_Segments_1, 'Number_of_Segments_1', i_pref='tube')
273 putName(Number_of_Segments_2, 'Number_of_Segments_2', i_pref='tube')
274 putName(Propagation_of_1D_Hyp, 'Propagation', i_pref='tube')
276 is_done = Maillage_tube.Compute()
277 text = "Maillage_tube.Compute"
279 logging.info(text+" OK")
281 text = "Erreur au calcul du maillage.\n" + text
283 raise Exception(text)
285 ficmed = os.path.join(gmu.pathBloc, "materielCasTests","{}.med".format(NOM_OBJET))
286 text = ".. Archivage du maillage dans le fichier '{}'".format(ficmed)
288 Maillage_tube.ExportMED(ficmed)
290 if salome.sg.hasDesktop():
291 salome.sg.updateObjBrowser()