import salome salome.salome_init() import GEOM from salome.geom import geomBuilder geompy = geomBuilder.New() from math import pi, sqrt def simpleCubic(theta = 0.01, fillet = False, direction = [1, 0, 0]): ### # Parameters ## r0 = 1.0 L = 2 * r0 radius = r0 / (1 - theta) xn, yn, zn = 3, 3, 3 length = L * sqrt(2) width = L * sqrt(2) height = L xl = sqrt(length ** 2 * 0.5) yw = xl zh = height C1, C2 = 0.8, 0.5 #0.8, 0.05 theta1, theta2 = 0.01, 0.28 Cf = C1 + (C2 - C1) / (theta2 - theta1) * (theta - theta1) filletradius = 0.2 - Cf * (radius - r0) scale = 100 oo = geompy.MakeVertex(0, 0, 0) ### # Bounding box ## if direction == [1, 0, 0]: sk = geompy.Sketcher3D() sk.addPointsAbsolute(xl, 0, 0) sk.addPointsAbsolute(0, yw, 0) sk.addPointsAbsolute(0, yw, zh) sk.addPointsAbsolute(xl, 0, zh) sk.addPointsAbsolute(xl, 0, 0) inletface = geompy.MakeFaceWires([sk.wire()], True) vecflow = geompy.GetNormal(inletface) cubic = geompy.MakePrismVecH(inletface, vecflow, width) elif direction == [0, 0, 1]: sk = geompy.Sketcher3D() sk.addPointsAbsolute(0, yw, 0) sk.addPointsAbsolute(xl, 0, 0) sk.addPointsAbsolute(2 * xl, yw, 0) sk.addPointsAbsolute(xl, 2 * yw, 0) sk.addPointsAbsolute(0, yw, 0) inletface = geompy.MakeFaceWires([sk.wire()], True) vecflow = geompy.GetNormal(inletface) cubic = geompy.MakePrismVecH(inletface, vecflow, height) else: raise Exception("The direction is not implemented") inletface = geompy.MakeScaleTransform(inletface, oo, scale) cubic = geompy.MakeScaleTransform(cubic, oo, scale) faces = geompy.ExtractShapes(cubic, geompy.ShapeType["FACE"], False) symetryface = [] for face in faces: norm = geompy.GetNormal(face) angle = round(geompy.GetAngle(norm, vecflow), 0) if (angle == 0 or angle == 180) and not face == inletface: outletface = face else: symetryface.append(face) ### # Grains ## ox = geompy.MakeVectorDXDYDZ(1, 0, 0) oy = geompy.MakeVectorDXDYDZ(0, 1, 0) oz = geompy.MakeVectorDXDYDZ(0, 0, 1) grain = geompy.MakeSphereR(radius) lattice = geompy.MakeMultiTranslation2D(grain, ox, L, xn, oy, L, yn) lattice = geompy.MakeMultiTranslation1D(lattice, oz, L, zn) grains = geompy.ExtractShapes(lattice, geompy.ShapeType["SOLID"], True) grains = geompy.MakeFuseList(grains, False, False) grains = geompy.MakeScaleTransform(grains, oo, scale) if fillet: grains = geompy.MakeFilletAll(grains, filletradius * scale) ### # Groups ## shape = geompy.MakeCutList(cubic, [grains]) shape = geompy.MakeScaleTransform(shape, oo, 1 / scale, theName = "simpleCubic") sall = geompy.CreateGroup(shape, geompy.ShapeType["FACE"]) geompy.UnionIDs(sall, geompy.SubShapeAllIDs(shape, geompy.ShapeType["FACE"])) inlet = geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = "inlet") inletshape = geompy.MakeCutList(inletface, [grains]) inletshape = geompy.MakeScaleTransform(inletshape, oo, 1 / scale) geompy.UnionList(inlet, geompy.SubShapeAll( geompy.GetInPlace(shape, inletshape, True), geompy.ShapeType["FACE"])) outlet = geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = "outlet") outletshape = geompy.MakeCutList(outletface, [grains]) outletshape = geompy.MakeScaleTransform(outletshape, oo, 1 / scale) geompy.UnionList(outlet, geompy.SubShapeAll( geompy.GetInPlace(shape, outletshape, True), geompy.ShapeType["FACE"])) symetry = [] for (n, face) in enumerate(symetryface): name = "symetry" + str(n) symetry.append(geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = name)) symetryshape = geompy.MakeCutList(face, [grains]) symetryshape = geompy.MakeScaleTransform(symetryshape, oo, 1 / scale) geompy.UnionList(symetry[n], geompy.SubShapeAll( geompy.GetInPlace(shape, symetryshape, True), geompy.ShapeType["FACE"])) groups = [] groups.append(inlet) groups.append(outlet) groups.extend(symetry) wall = geompy.CutListOfGroups([sall], groups, theName = "wall") groups.append(wall) return shape, groups def simpleHexagonalPrism(theta = 0.01, fillet = False, direction = [1, 1, 1]): ### # Parameters ## r0 = 1.0 L = 2 * r0 radius = r0 / (1 - theta) xn, yn, zn = 3, 3, 3 length = L * sqrt(2) width = L * sqrt(2) height = L point = [] xl, yw, zh = -L - L / 6, -L - L / 6, -L / 6 point.append((L + xl, L + yw, L + zh)) point.append((5 * L / 3 + xl, 2 * L / 3 + yw, 2 * L / 3 + zh)) point.append((2 * L + xl, L + yw, 0 + zh)) point.append((5 * L / 3 + xl, 5 * L / 3 + yw, -L / 3 + zh)) point.append((L + xl, 2 * L + yw, 0 + zh)) point.append((2 * L / 3 + xl, 5 * L / 3 + yw, 2 * L / 3 + zh)) point.append((L + xl, L + yw, L + zh)) C1, C2 = 0.8, 0.5 # 0.8, 0.05 theta1, theta2 = 0.01, 0.28 Cf = C1 + (C2 - C1) / (theta2 - theta1) * (theta - theta1) filletradius = 0.2 - Cf * (radius - r0) scale = 100 oo = geompy.MakeVertex(0, 0, 0) ### # Bounding box ## sk = geompy.Sketcher3D() for p in point: sk.addPointsAbsolute(*p) inletface = geompy.MakeFaceWires([sk.wire()], False) vecflow = geompy.GetNormal(inletface) hexagonPrism = geompy.MakePrismVecH(inletface, vecflow, L * sqrt(3)) inletface = geompy.MakeScaleTransform(inletface, oo, scale) hexagonPrism = geompy.MakeScaleTransform(hexagonPrism, oo, scale) faces = geompy.ExtractShapes(hexagonPrism, geompy.ShapeType["FACE"], False) symetryface = [] for face in faces: norm = geompy.GetNormal(face) angle = round(geompy.GetAngle(norm, vecflow), 0) if (angle == 0 or angle == 180) and not face == inletface: outletface = face else: symetryface.append(face) ### # Grains ## ox = geompy.MakeVectorDXDYDZ(1, 0, 0) oy = geompy.MakeVectorDXDYDZ(0, 1, 0) oz = geompy.MakeVectorDXDYDZ(0, 0, 1) grain = geompy.MakeSphereR(radius) lattice = geompy.MakeMultiTranslation2D(grain, ox, L, xn, oy, L, yn) lattice = geompy.MakeMultiTranslation1D(lattice, oz, L, zn) grains = geompy.ExtractShapes(lattice, geompy.ShapeType["SOLID"], True) grains = geompy.MakeFuseList(grains, False, False) grains = geompy.MakeScaleTransform(grains, oo, scale) if fillet: grains = geompy.MakeFilletAll(grains, filletradius * scale) ### # Groups ## shape = geompy.MakeCutList(hexagonPrism, [grains]) shape = geompy.MakeScaleTransform(shape, oo, 1 / scale, theName = "simpleCubic") sall = geompy.CreateGroup(shape, geompy.ShapeType["FACE"]) geompy.UnionIDs(sall, geompy.SubShapeAllIDs(shape, geompy.ShapeType["FACE"])) inlet = geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = "inlet") inletshape = geompy.MakeCutList(inletface, [grains]) inletshape = geompy.MakeScaleTransform(inletshape, oo, 1 / scale) geompy.UnionList(inlet, geompy.SubShapeAll( geompy.GetInPlace(shape, inletshape, True), geompy.ShapeType["FACE"])) outlet = geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = "outlet") outletshape = geompy.MakeCutList(outletface, [grains]) outletshape = geompy.MakeScaleTransform(outletshape, oo, 1 / scale) geompy.UnionList(outlet, geompy.SubShapeAll( geompy.GetInPlace(shape, outletshape, True), geompy.ShapeType["FACE"])) symetry = [] for (n, face) in enumerate(symetryface): name = "symetry" + str(n) symetry.append(geompy.CreateGroup(shape, geompy.ShapeType["FACE"], theName = name)) symetryshape = geompy.MakeCutList(face, [grains]) symetryshape = geompy.MakeScaleTransform(symetryshape, oo, 1 / scale) geompy.UnionList(symetry[n], geompy.SubShapeAll( geompy.GetInPlace(shape, symetryshape, True), geompy.ShapeType["FACE"])) groups = [] groups.append(inlet) groups.append(outlet) groups.extend(symetry) wall = geompy.CutListOfGroups([sall], groups, theName = "wall") groups.append(wall) return shape, groups