Exemple #1
0
def CreateRoundStrutwithCone(name, diameter, start, height, coneHeight, topDiameter, frameHeight):
    #print(name)
    vector = XYZ(0, 0, height*-1)
    coneVector = XYZ(0, 0, (coneHeight-frameHeight)*-1)
    frameVector = XYZ(0, 0, frameHeight * -1)

    pp = Plane.CreateByNormalAndOrigin(vector, start + coneVector + frameVector*2)
    ppCone = Plane.CreateByNormalAndOrigin(vector, start + frameVector)
    ppFrame = Plane.CreateByNormalAndOrigin(vector, start)
    frameProfile = CurveLoop().Create([Arc.Create(ppFrame, topDiameter/2, 0, math.pi), Arc.Create(ppFrame, topDiameter/2, math.pi, math.pi*2)])
    coneProfile = CurveLoop().Create([Arc.Create(ppCone, topDiameter/2 + frameHeight + 1/12, 0, math.pi), Arc.Create(ppCone, topDiameter/2 + frameHeight + 1/12, math.pi, math.pi*2)])
    profile = CurveLoop().Create([Arc.Create(pp, diameter/2, 0, math.pi), Arc.Create(pp, diameter/2, math.pi, math.pi*2)])

    frame = GeometryCreationUtilities.CreateExtrusionGeometry([frameProfile], frameVector, frameHeight)
    geo = GeometryCreationUtilities.CreateExtrusionGeometry([profile], vector, height - coneHeight-frameHeight)
    try:
        cone = GeometryCreationUtilities.CreateLoftGeometry([coneProfile, profile], SolidOptions(ElementId.InvalidElementId, ElementId.InvalidElementId))
        # Create Element
        ele = DirectShape.CreateElement(doc, ElementId(-2000151))
        ele.SetShape([geo, cone, frame])
        ele.SetName(name)
        return ele.Id
    except:
        ele = DirectShape.CreateElement(doc, ElementId(-2000151))
        ele.SetShape([geo, frame])
        ele.SetName(name)
        return ele.Id
Exemple #2
0
    def find_outer_contur_in_cls(cls, curve_loops):
        """Ищет внешний контур."""
        all_cl_with_extrussion = []
        inner_cls = []
        outer_cls = []
        i_x = 0
        for cl in curve_loops:
            plane_normal = cl.GetPlane().Normal
            solid_elem = GeometryCreationUtilities.CreateExtrusionGeometry(
                [cl], plane_normal, 1)
            i_x = i_x + 1
            for face in solid_elem.Faces:
                if face.FaceNormal.IsAlmostEqualTo(plane_normal):
                    all_cl_with_extrussion.append((
                        face,
                        cl,
                        i_x))

        for elem in all_cl_with_extrussion:
            outside = True
            for elem_2 in all_cl_with_extrussion:
                if not elem[2] == elem_2[2]:
                    if cls.first_point_is_inside_face(elem, elem_2):
                        outside = False
                        break
            if outside:
                outer_cls.append(elem[1])
            else:
                inner_cls.append(elem[1])
        return (outer_cls, inner_cls)
Exemple #3
0
def CreateStraightPipe(name, diameter, thickness, startO, endO, length):
    #correction = XYZ(0, 0, diameter/2)
    #print("Diameter" + str(diameter))
    #print(name)
    correction = XYZ(0, 0, 0)
    start = startO + correction
    end = endO + correction
    #print(name)
    #print(length)
    if (end - start).GetLength() > 0.1:
        pp = Plane.CreateByNormalAndOrigin(end - start, start)
        profile = CurveLoop().Create([
            Arc.Create(pp, diameter / 2 + thickness, 0, math.pi),
            Arc.Create(pp, diameter / 2 + thickness, math.pi, math.pi * 2)
        ])
        geo = GeometryCreationUtilities.CreateExtrusionGeometry([profile],
                                                                end - start,
                                                                length)
        ele = DirectShape.CreateElement(doc, ElementId(-2000151))
        ele.SetShape([geo])
        ele.SetName(name)
        return ele.Id
    else:
        print("Duct too small")
        return None
Exemple #4
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def CreateCubeStrut(csdname, csdwidth, csdlength, csdheight, csdstart,
                    csdrotation, scdthickness):
    #print(csdname)
    vector = XYZ(0, 0, csdheight * -1)
    pp = Plane.CreateByNormalAndOrigin(vector, csdstart)

    trans = Transform.CreateRotationAtPoint(vector, csdrotation, csdstart)

    point1 = csdstart + XYZ(csdwidth / 2, csdlength / 2, 0)
    point2 = csdstart + XYZ(csdwidth / 2 * -1, csdlength / 2, 0)
    point3 = csdstart + XYZ(csdwidth / 2 * -1, csdlength / 2 * -1, 0)
    point4 = csdstart + XYZ(csdwidth / 2, csdlength / 2 * -1, 0)

    profileorigion = CurveLoop().Create([
        Line.CreateBound(point1, point2),
        Line.CreateBound(point2, point3),
        Line.CreateBound(point3, point4),
        Line.CreateBound(point4, point1)
    ])

    finalProfile = CurveLoop.CreateViaTransform(profileorigion, trans)
    geo = GeometryCreationUtilities.CreateExtrusionGeometry([finalProfile],
                                                            vector, csdheight)
    ele = DirectShape.CreateElement(doc, ElementId(-2000151))
    ele.SetShape([geo])
    ele.SetName(csdname)
    return ele.Id
Exemple #5
0
def CreateRoundStrut(name, diameter, start, height):
    vector = XYZ(0, 0, height * -1)

    print(name)
    print(height)
    pp = Plane.CreateByNormalAndOrigin(vector, start)
    profile = CurveLoop().Create([
        Arc.Create(pp, diameter / 2, 0, math.pi),
        Arc.Create(pp, diameter / 2, math.pi, math.pi * 2)
    ])
    geo = GeometryCreationUtilities.CreateExtrusionGeometry([profile], vector,
                                                            height)
    ele = DirectShape.CreateElement(doc, ElementId(-2000151))
    ele.SetShape([geo])
    ele.SetName(name)
    return ele.Id
Exemple #6
0
def CreateStraightPipe(name, diameter, thickness, startO, endO, length):
    correction = XYZ(0, 0, diameter / 2)
    start = startO + correction
    end = endO + correction
    print(name)
    print(length)
    pp = Plane.CreateByNormalAndOrigin(end - start, start)
    profile = CurveLoop().Create([
        Arc.Create(pp, diameter / 2 + thickness, 0, math.pi),
        Arc.Create(pp, diameter / 2 + thickness, math.pi, math.pi * 2)
    ])
    geo = GeometryCreationUtilities.CreateExtrusionGeometry([profile],
                                                            end - start,
                                                            length)
    ele = DirectShape.CreateElement(doc, ElementId(-2000151))
    ele.SetShape([geo])
    ele.SetName(name)
    return ele.Id
Exemple #7
0
def get_solid_extrusion_from_bbox(bbox):
    solid_opt = SolidOptions(ElementId.InvalidElementId,
                             ElementId.InvalidElementId)
    b1 = XYZ(bbox.Min.X, bbox.Min.Y, bbox.Min.Z)
    b2 = XYZ(bbox.Max.X, bbox.Min.Y, bbox.Min.Z)
    b3 = XYZ(bbox.Max.X, bbox.Max.Y, bbox.Min.Z)
    b4 = XYZ(bbox.Min.X, bbox.Max.Y, bbox.Min.Z)
    bbox_height = bbox.Max.Z - bbox.Min.Z

    lines = List[Curve]()
    lines.Add(Line.CreateBound(b1, b2))
    lines.Add(Line.CreateBound(b2, b3))
    lines.Add(Line.CreateBound(b3, b4))
    lines.Add(Line.CreateBound(b4, b1))
    rectangle = [CurveLoop.Create(lines)]

    extrusion = GeometryCreationUtilities.CreateExtrusionGeometry(
        List[CurveLoop](rectangle),
        XYZ.BasisZ,
        bbox_height,
        solid_opt,
    )
    return extrusion
Exemple #8
0
def CreateStraightDuct(csdname, csdwidth, csdheight, thickness, csdstartO,
                       csdendO, csdlength):
    #print(csdname)
    #correction = XYZ(0, 0, csdheight / 2)
    correction = XYZ(0, 0, 0)
    csdstart = csdstartO + correction
    csdend = csdendO + correction
    if (csdend - csdstart).GetLength() > 0.1:
        pp = Plane.CreateByNormalAndOrigin(csdend - csdstart, csdstart)
        profile1 = Arc.Create(pp, csdwidth / 2 + thickness, 0, math.pi)
        interVector = XYZ((csdend - csdstart).Y * -1, (csdend - csdstart).X, 0)
        a = profile1.GetEndPoint(0)
        b = profile1.GetEndPoint(1)
        profile2 = Arc.Create(pp, csdheight / 2 + thickness, math.pi / 2,
                              math.pi * 3 / 2)
        c = profile2.GetEndPoint(0)
        d = profile2.GetEndPoint(1)
        point1 = a + c - csdstart
        point2 = b + c - csdstart
        point3 = b + d - csdstart
        point4 = a + d - csdstart
        l1 = Line.CreateBound(point1, point2)

        vector1 = point1 - point2
        vector2 = XYZ((point1 - point2).X, (point1 - point2).Y, 0)
        #print(vector1)
        #print(vector2)
        angle = vector1.AngleOnPlaneTo(interVector,
                                       (csdend - csdstart).Normalize())
        #angle = vector2.AngleTo(vector1)
        #print(angle)
        #print(point1)
        #print(point2)
        trans1 = Transform.CreateRotationAtPoint(csdend - csdstart, angle,
                                                 csdstart)
        trans2 = Transform.CreateRotationAtPoint(csdend - csdstart,
                                                 angle * (-1), csdstart)
        trans3 = Transform.CreateRotationAtPoint(csdend - csdstart,
                                                 angle * (-1) + math.pi / 2,
                                                 csdstart)
        trans4 = Transform.CreateRotationAtPoint(csdend - csdstart,
                                                 angle + math.pi / 2, csdstart)
        #print(angle)
        #print(angle*(-1))
        #print(angle * (-1) + math.pi/2)
        #print(angle + math.pi / 2)

        #print(point4)
        profileorigion = CurveLoop().Create([
            Line.CreateBound(point1, point2),
            Line.CreateBound(point2, point3),
            Line.CreateBound(point3, point4),
            Line.CreateBound(point4, point1)
        ])
        #print(l1.GetEndPoint(0))
        #print(l1.GetEndPoint(1))

        numbers = {}
        list = []
        l1Test1 = l1.CreateTransformed(trans1)
        l1Test2 = l1.CreateTransformed(trans2)
        l1Test3 = l1.CreateTransformed(trans3)
        l1Test4 = l1.CreateTransformed(trans4)

        numbers[abs(l1Test1.GetEndPoint(0).Z -
                    l1Test1.GetEndPoint(1).Z)] = trans1
        numbers[abs(l1Test2.GetEndPoint(0).Z -
                    l1Test2.GetEndPoint(1).Z)] = trans2
        numbers[abs(l1Test3.GetEndPoint(0).Z -
                    l1Test3.GetEndPoint(1).Z)] = trans3
        numbers[abs(l1Test4.GetEndPoint(0).Z -
                    l1Test4.GetEndPoint(1).Z)] = trans4

        list.append(abs(l1Test1.GetEndPoint(0).Z - l1Test1.GetEndPoint(1).Z))
        list.append(abs(l1Test2.GetEndPoint(0).Z - l1Test2.GetEndPoint(1).Z))
        list.append(abs(l1Test3.GetEndPoint(0).Z - l1Test3.GetEndPoint(1).Z))
        list.append(abs(l1Test4.GetEndPoint(0).Z - l1Test4.GetEndPoint(1).Z))
        list.sort()
        finalProfile = CurveLoop.CreateViaTransform(profileorigion,
                                                    numbers[list[0]])
        geo = GeometryCreationUtilities.CreateExtrusionGeometry(
            [finalProfile], csdend - csdstart, csdlength)
        ele = DirectShape.CreateElement(doc, ElementId(-2000151))
        ele.SetShape([geo])
        ele.SetName(csdname)
        return ele.Id
    else:
        print("Duct too small")
        return None
    doc.GetElement(elem_id) for elem_id in uidoc.Selection.GetElementIds()
]
first_selected = selection[0]
solid_opt = SolidOptions(ElementId.InvalidElementId,
                         ElementId.InvalidElementId)

bbox = first_selected.get_BoundingBox(None)
bottom_z_offset = 0.1
bbox.Min = XYZ(bbox.Min.X, bbox.Min.Y, bbox.Min.Z - bottom_z_offset)
b1 = XYZ(bbox.Min.X, bbox.Min.Y, bbox.Min.Z)
b2 = XYZ(bbox.Max.X, bbox.Min.Y, bbox.Min.Z)
b3 = XYZ(bbox.Max.X, bbox.Max.Y, bbox.Min.Z)
b4 = XYZ(bbox.Min.X, bbox.Max.Y, bbox.Min.Z)
bbox_height = bbox.Max.Z - bbox.Min.Z

lines = List[Curve]()
lines.Add(Line.CreateBound(b1, b2))
lines.Add(Line.CreateBound(b2, b3))
lines.Add(Line.CreateBound(b3, b4))
lines.Add(Line.CreateBound(b4, b1))
rectangle = [CurveLoop.Create(lines)]

extrusion = GeometryCreationUtilities.CreateExtrusionGeometry(
    List[CurveLoop](rectangle), XYZ.BasisZ, bbox_height, solid_opt)

category_id = ElementId(Bic.OST_GenericModel)

with db.Transaction("solid_bbox_direct_shape") as tx:
    direct_shape = DirectShape.CreateElement(doc, category_id, "A", "B")
    direct_shape.SetShape([extrusion])