def resulting_plane(shape0):
p0 = resulting_pln(shape0)
return cq.Plane(
cq.Vector(p0.Location()),
cq.Vector(p0.XAxis().Direction()),
cq.Vector(p0.Axis().Direction()),
)
def make_line(start, direction):
"""Single linear edge in a Wire, as an indicator"""
start_v = cadquery.Vector(*start)
finish_v = start_v.add(cadquery.Vector(*direction))
edge = cadquery.Edge.makeLine(start_v, finish_v)
wire = cadquery.Wire.assembleEdges([edge])
return cadquery.Workplane('XY').newObject([wire])
def get_ball_torus(cls, rolling_radius, ball_radius):
return cadquery.Workplane("XY").union(
cadquery.CQ(cadquery.Solid.makeTorus(
rolling_radius, ball_radius, # radii
pnt=cadquery.Vector(0,0,0).wrapped,
dir=cadquery.Vector(0,0,1).wrapped,
angleDegrees1=0.,
angleDegrees2=360.,
))
)
def generate_part(num_pins):
calc_dim = dimensions(num_pins)
pins = generate_pins(num_pins)
body, insert = generate_body(num_pins, calc_dim)
# adjust for matching KiCad expectation
body = body.rotate((0, 0, 0),(0, 0, 1), 180).translate(cq.Vector(calc_dim.length-series_params.pin_inside_distance,series_params.pin_xpos,0))
pins = pins.rotate((0, 0, 0),(0, 0, 1), 180).translate(cq.Vector(calc_dim.length-series_params.pin_inside_distance,series_params.pin_xpos,0))
return (body, pins)
def test_fastener(self):
obj = FastenedAssembly()
bolt = obj.find('fastener.bolt')
nut = obj.find('fastener.nut')
self.assertEquals(bolt.world_coords.origin, cadquery.Vector(
(1, 2, 30)))
self.assertGreater(bolt.bounding_box.zlen,
obj.find('top').height + obj.find('base').height)
self.assertEquals(nut.world_coords.origin, cadquery.Vector((1, 2, 0)))
def simple_assy():
b1 = cq.Solid.makeBox(1, 1, 1)
b2 = cq.Workplane().box(1, 1, 2)
b3 = cq.Workplane().pushPoints([(0, 0), (-2, -5)]).box(1, 1, 3)
assy = cq.Assembly(b1, loc=cq.Location(cq.Vector(2, -5, 0)))
assy.add(b2, loc=cq.Location(cq.Vector(1, 1, 0)))
assy.add(b3, loc=cq.Location(cq.Vector(2, 3, 0)))
return assy
def nested_assy_sphere():
b1 = cq.Workplane().box(1, 1, 1).faces("<Z").tag("top_face").end()
b2 = cq.Workplane().box(1, 1, 1).faces("<Z").tag("bottom_face").end()
b3 = cq.Workplane().pushPoints([(-2, 0), (2, 0)]).tag("pts").sphere(1).tag("boxes")
assy = cq.Assembly(b1, loc=cq.Location(cq.Vector(0, 0, 0)), name="TOP")
assy2 = cq.Assembly(b2, loc=cq.Location(cq.Vector(0, 4, 0)), name="SECOND")
assy2.add(b3, loc=cq.Location(cq.Vector(0, 4, 0)), name="BOTTOM")
assy.add(assy2, color=cq.Color("green"))
return assy
def nested_assy():
b1 = cq.Workplane().box(1, 1, 1)
b2 = cq.Workplane().box(1, 1, 1)
b3 = cq.Workplane().pushPoints([(-2, 0), (2, 0)]).box(1, 1, 0.5)
assy = cq.Assembly(b1, loc=cq.Location(cq.Vector(0, 0, 0)), name="TOP")
assy2 = cq.Assembly(b2, loc=cq.Location(cq.Vector(0, 4, 0)), name="SECOND")
assy2.add(b3, loc=cq.Location(cq.Vector(0, 4, 0)), name="BOTTOM")
assy.add(assy2, color=cq.Color("green"))
return assy
def make(self):
cone_radius = self.diameter / 2
cone_height = cone_radius # to achieve a 45deg angle
cylinder_radius = cone_radius - self.chamfer
cylinder_height = self.height
shaft_radius = (self.diameter / 2.) - self.height
cone = cadquery.Workplane("XY").union(
cadquery.CQ(cadquery.Solid.makeCone(0, cone_radius, cone_height)) \
.translate((0, 0, -cone_height))
)
cylinder = cadquery.Workplane("XY") \
.circle(cylinder_radius).extrude(-cylinder_height)
head = cone.intersect(cylinder)
# Raised bubble (if given)
if self.raised:
sphere_radius = ((self.raised ** 2) + (cylinder_radius ** 2)) / (2 * self.raised)
sphere = cadquery.Workplane("XY").workplane(offset=-(sphere_radius - self.raised)) \
.sphere(sphere_radius)
raised_cylinder = cadquery.Workplane("XY").circle(cylinder_radius).extrude(self.raised)
from Helpers import show
raised_bubble = sphere.intersect(raised_cylinder)
head = head.union(raised_bubble)
# Bugle Head
if self.bugle and (0 <= self.bugle_ratio < 1.0):
# bugle_angle = angle head material makes with chamfer cylinder on top
bugle_angle = (pi / 4) * self.bugle_ratio
# face_span = longest straight distance along flat conical face (excluding chamfer)
face_span = sqrt(2) * (((self.diameter / 2.) - self.chamfer) - shaft_radius)
r2 = (face_span / 2.) / sin((pi / 4) - bugle_angle)
d_height = r2 * sin(bugle_angle)
r1 = (r2 * cos(bugle_angle)) + shaft_radius
torus = cadquery.Workplane("XY").union(
cadquery.CQ(cadquery.Solid.makeTorus(
r1, r2, # radii
pnt=cadquery.Vector(0,0,0),
dir=cadquery.Vector(0,0,1),
angleDegrees1=0.,
angleDegrees2=360.
)).translate((0, 0, -(self.height + d_height)))
)
head = head.cut(torus)
return head
def face_from_points(points):
# print('face_from_points()')
edges = []
num_pnts = len(points)
for i in range(len(points)):
p1 = points[i]
p2 = points[(i + 1) % num_pnts]
edges.append(
cq.Edge.makeLine(
cq.Vector(p1[0], p1[1], p1[2]),
cq.Vector(p2[0], p2[1], p2[2]),
))
face = cq.Face.makeFromWires(cq.Wire.assembleEdges(edges))
return face
def __render_outline(self, workplane, d, outlineArray, offset):
outline = cq.Workplane("XY")
arcs = []
for i in range(0, len(outlineArray)):
last_drill = outlineArray[(i-1) % len(outlineArray)]
this_drill = outlineArray[i]
next_drill = outlineArray[(i+1) % len(outlineArray)]
edge_ab = primitives.edge(self.__keyloc_to_xy_mm(last_drill["position"].x, last_drill["position"].y, last_drill["offsetByHandAngle"]), self.__keyloc_to_xy_mm(this_drill["position"].x, this_drill["position"].y, this_drill["offsetByHandAngle"]))
edge_bc = primitives.edge(self.__keyloc_to_xy_mm(this_drill["position"].x, this_drill["position"].y, this_drill["offsetByHandAngle"]), self.__keyloc_to_xy_mm(next_drill["position"].x, next_drill["position"].y, next_drill["offsetByHandAngle"]))
# Work out the offset from the centre, if overridden
this_offset = this_drill["radius"] if "radius" in this_drill else offset
# Flip convex/concave if we're generating an internal contour
convex = this_drill["convex"] if this_offset > 0 else not this_drill["convex"]
this_arc = primitives.arc(edge_ab, edge_bc, this_offset, convex)
if this_arc.chord_length > 1e-9:
arcs.append(this_arc)
last_arc = arcs[-1]
outline = outline.moveTo(primitives.mm2m(last_arc.end.x), primitives.mm2m(last_arc.end.y))
for this_arc in arcs:
outline = outline.lineTo(primitives.mm2m(this_arc.start.x), primitives.mm2m(this_arc.start.y))
outline = outline.tangentArcPoint(cq.Vector(primitives.mm2m(this_arc.end.x), primitives.mm2m(this_arc.end.y)), relative=False)
if bool(d["locations"]):
self.__circle_at_xy(workplane, this_arc.centre, self.__locationFiducialSize)
workplane.add(outline.wire().combine())
def make(self):
# cone radii
cone_radius_at = lambda z: self.roller_surface_radius + (
self.roller_surface_gradient * z)
cone_radius_base = cone_radius_at(self.base_height)
cone_radius_top = cone_radius_at(self.base_height + self.height)
# ring base shape
outer_ring = cadquery.Workplane('XY', origin=(0, 0, self.base_height)) \
.circle(self.outer_diam / 2).extrude(self.height)
# cut cone from base shape (provides conical rolling surface)
if abs(self.roller_surface_gradient) > 1e-6:
cone = cadquery.CQ(
cadquery.Solid.makeCone(
radius1=cone_radius_base,
radius2=cone_radius_top,
height=self.height,
dir=cadquery.Vector(0, 0, 1),
)).translate((0, 0, self.base_height))
outer_ring = outer_ring.cut(cone)
else:
outer_ring = outer_ring.faces('>Z') \
.circle(self.roller_surface_radius).cutThruAll()
return outer_ring
def create_hexapod():
# Some shortcuts
L = lambda *args: cq.Location(cq.Vector(*args))
C = lambda *args: cq.Color(*args)
# Leg assembly
leg = MAssembly(upper_leg, name="upper",
color=C("orange")).add(lower_leg,
name="lower",
color=C("orange"),
loc=L(80, 0, 0))
# Hexapod assembly
hexapod = (MAssembly(
base, name="bottom", color=C("gray"),
loc=L(0, 1.1 * width,
0)).add(base,
name="top",
color=C(0.9, 0.9, 0.9),
loc=L(0, -2.2 * width,
0)).add(stand,
name="front_stand",
color=C(0.5, 0.8, 0.9),
loc=L(40, 100,
0)).add(stand,
name="back_stand",
color=C(0.5, 0.8, 0.9),
loc=L(-40, 100, 0)))
for i, name in enumerate(leg_names):
hexapod.add(leg, name=name, loc=L(100, -55 * (i - 1.7), 0))
return hexapod
def bolthole(location, diameter, clamp_length, nuthole_size,
nuthole_depth):
"""
Create a bolthole at the specified location in the current workplane, with the given
measures.
:param location: The location to place the bolthole, using the point at the center of
the hole cross-section and at half its clamp length as the handle.
:param diameter: Diameter of the cylindrical section of the bolthole.
:param clamp_length: Length between start of the bolt head and start of the nuthole.
:param nuthole_size: Size between flats of a hexagonal hole for a nut.
:param nuthole_depth: Maximum depth of the nuthole. If the part ends earlier, this
depth is not reached.
"""
bolthole = (cq.Workplane().bolt(
bolt_size=diameter,
head_size=2 * diameter,
head_length=2 * diameter,
head_shape="cylindrical",
head_angle=90,
clamp_length=clamp_length,
nut_size=nuthole_size,
nut_length=nuthole_depth).val().located(
location *
cq.Location(cq.Vector(0, 0, -clamp_length / 2))))
# show_object(bolthole) # Debug helper.
return bolthole
def metadata_assy():
b1 = cq.Solid.makeBox(1, 1, 1)
b2 = cq.Workplane().box(1, 1, 2)
assy = cq.Assembly(
b1,
loc=cq.Location(cq.Vector(2, -5, 0)),
name="base",
metadata={"b1": "base-data"},
)
sub_assy = cq.Assembly(
b2, loc=cq.Location(cq.Vector(1, 1, 1)), name="sub", metadata={"b2": "sub-data"}
)
assy.add(sub_assy)
return assy
def __init__(self, origin, along_axis, radius, debug=False):
self.outer_radius = radius
self.axis = self.get_axis(along_axis)
xdir = self.get_ortho_vector(self.axis)
self.base = cq.Plane(cq.Vector(origin), xdir, self.axis.toTuple())
if debug:
utils.make_debug_cylinder(self.base, self.outer_radius)
def __init__(self, workplane, measures):
"""
A parametric, grooved wall element that can be integrated into panel walls.
.. todo: Since this is not a part that can be used as it is, it should rather be
implemented as a CadQuery plugin.
.. todo:: Parameter documentation.
.. todo:: Add parameters for edge and corner rounding.
"""
self.model = workplane
self.measures = measures
# Add optional measures if missing, using their default values.
if not hasattr(measures, 'center_offset'):
measures.center_offset = cq.Vector(0, 0, 0)
if not hasattr(measures, 'grooves'): measures.grooves = Measures()
if not hasattr(measures.grooves, 'left'): measures.grooves.left = False
if not hasattr(measures.grooves, 'right'):
measures.grooves.right = False
if not hasattr(measures.grooves, 'top'): measures.grooves.top = False
if not hasattr(measures.grooves, 'bottom'):
measures.grooves.bottom = False
self.build()
def make(self):
cone_radius_at = lambda z: self.roller_surface_radius + (
self.roller_surface_gradient * z)
cone_radius_base = cone_radius_at(self.base_height)
cone_radius_top = cone_radius_at(self.base_height + self.height)
# ring base shape
inner_ring = cadquery.Workplane('XY', origin=(0, 0, self.base_height)) \
.circle(max(cone_radius_base, cone_radius_top)) \
.circle(self.inner_diam / 2) \
.extrude(self.height)
# intersect cone with base shape (provides conical rolling surface)
if abs(self.roller_surface_gradient) > 1e-6:
cone = cadquery.CQ(
cadquery.Solid.makeCone(
radius1=cone_radius_base,
radius2=cone_radius_top,
height=self.height,
dir=cadquery.Vector(0, 0, 1),
)).translate((0, 0, self.base_height))
inner_ring = inner_ring.intersect(cone)
return inner_ring
def radial_holes_type(diameter, depth, size, n, offset, hole_type):
holes = []
if (hole_type == 'thru'):
[screw_diameter, length] = thru(size, 1)
if (hole_type == 'tap'):
[screw_diameter, length] = tap(size, 1)
for index in range(n):
theta = 360.0 * index / n + offset
x = diameter / 2.0 * math.cos(theta / 180.0 * math.pi)
y = diameter / 2.0 * math.sin(theta / 180.0 * math.pi)
p = cq.Vector(x, y, 0)
d = cq.Vector(-x, -y, 0)
# print(theta, p,d)
hole = cq.Solid.makeCylinder(screw_diameter / 2, depth, pnt=p, dir=d)
holes.append(hole)
return holes
def sa_cap(Usize=1):
# MODIFIED TO NOT HAVE THE ROTATION. NEEDS ROTATION DURING ASSEMBLY
sa_length = 18.25
bw2 = Usize * sa_length / 2
bl2 = sa_length / 2
m = 0
pw2 = 6 * Usize + 1
pl2 = 6
if Usize == 1:
m = 17 / 2
k1 = cq.Workplane('XY').polyline([(bw2, bl2), (bw2, -bl2), (-bw2, -bl2),
(-bw2, bl2), (bw2, bl2)])
k1 = cq.Wire.assembleEdges(k1.edges().objects)
k1 = cq.Workplane('XY').add(
cq.Solid.extrudeLinear(outerWire=k1,
innerWires=[],
vecNormal=cq.Vector(0, 0, 0.1)))
k1 = k1.translate((0, 0, 0.05))
k2 = cq.Workplane('XY').polyline([(pw2, pl2), (pw2, -pl2), (-pw2, -pl2),
(-pw2, pl2), (pw2, pl2)])
k2 = cq.Wire.assembleEdges(k2.edges().objects)
k2 = cq.Workplane('XY').add(
cq.Solid.extrudeLinear(outerWire=k2,
innerWires=[],
vecNormal=cq.Vector(0, 0, 0.1)))
k2 = k2.translate((0, 0, 12.0))
if m > 0:
m1 = cq.Workplane('XY').polyline([(m, m), (m, -m), (-m, -m), (-m, m),
(m, m)])
m1 = cq.Wire.assembleEdges(m1.edges().objects)
m1 = cq.Workplane('XY').add(
cq.Solid.extrudeLinear(outerWire=m1,
innerWires=[],
vecNormal=cq.Vector(0, 0, 0.1)))
m1 = m1.translate((0, 0, 6.0))
key_cap = hull_from_shapes((k1, k2, m1))
else:
key_cap = hull_from_shapes((k1, k2))
key_cap = key_cap.translate((0, 0, 5 + plate_thickness))
# key_cap = key_cap.color((220 / 255, 163 / 255, 163 / 255, 1))
return key_cap
def test_hull():
c1 = cq.Edge.makeCircle(0.5, (-1.5, 0.5, 0))
c2 = cq.Edge.makeCircle(0.5, (1.9, 0.0, 0))
c3 = cq.Edge.makeCircle(0.2, (0.3, 1.5, 0))
c4 = cq.Edge.makeCircle(0.2, (1.0, 1.5, 0))
c5 = cq.Edge.makeCircle(0.1, (0.0, 0.0, 0.0))
e1 = cq.Edge.makeLine(cq.Vector(0, -0.5), cq.Vector(-0.5, 1.5))
e2 = cq.Edge.makeLine(cq.Vector(2.1, 1.5), cq.Vector(2.6, 1.5))
edges = [c1, c2, c3, c4, c5, e1, e2]
h = hull.find_hull(edges)
assert len(h.Vertices()) == 11
assert h.IsClosed()
assert h.isValid()
def test_fastener(self):
obj = FastenedAssembly()
screw = obj.find('fastener.screw')
self.assertEquals(screw.world_coords.origin, cadquery.Vector(
(1, 2, 30)))
self.assertGreater(screw.bounding_box.zlen, obj.find('base').height)
self.assertLess(screw.bounding_box.zlen,
obj.find('top').height + obj.find('base').height)
def create_leg(x, y):
L = lambda *args: cq.Location(cq.Vector(*args))
C = lambda *args: cq.Color(*args)
leg = MAssembly(cq.Workplane("YZ").polyline([(0, 0), (x, 0), (x, y)]), name="base", color=C("Gray"))
for i, name in enumerate(link_list):
leg.add(parts[name], name=name, color=C(links[name]["col"]), loc=L(0, 0, i * 10 - 50))
return leg
def test_infinite_face_constraint_PointInPlane(origin, normal):
"""
An OCCT infinite face has a center at (1e99, 1e99), but when a user uses it
in a constraint, the center should be basePnt.
"""
f0 = cq.Face.makePlane(length=None, width=None, basePnt=origin, dir=normal)
c0 = cq.assembly.Constraint(
("point", "plane"),
(cq.Vertex.makeVertex(10, 10, 10), f0),
sublocs=(cq.Location(), cq.Location()),
kind="PointInPlane",
)
p0 = c0._getPln(c0.args[1]) # a gp_Pln
derived_origin = cq.Vector(p0.Location())
assert derived_origin == cq.Vector(origin)
def shovel_profile(self, m):
width = m.shovels.size
# Since the two arcs are at an angle (see center_angle_rad), the minimum thickness
# is less than m.shovels.cavity. TODO: Make this parametric in a reasonable way.
depth = m.shovels.cavity * 2 - 3.0
circumradius = m.baseplate.diameter / 2
# Angle at which the outer extension of the shovel appears from the baseplate center.
# TODO: Make the center angle configurable in a reasonable way. Currently it is
# derived from the number of shovels using a statis factor (0.45).
center_angle_rad = radians(360 / m.shovels.count) * 0.45
# Profile corner points.
left_bottom = cq.Vector((-width, -depth / 2))
right_bottom = (
(cq.Vector((circumradius, 0)) * -1) +
(cq.Vector(cos(center_angle_rad / 2),
-sin(center_angle_rad / 2)) * circumradius))
right_center = cq.Vector((0, 0))
right_top = (cq.Vector((circumradius, 0)) * -1 +
cq.Vector(cos(center_angle_rad / 2),
sin(center_angle_rad / 2)) * circumradius)
left_top = cq.Vector((-width, depth / 2))
profile = (self.moveTo(left_bottom.x, left_bottom.y).sagittaArc(
right_bottom.toTuple2D(), m.shovels.cavity).threePointArc(
right_center.toTuple2D(),
right_top.toTuple2D()).sagittaArc(
left_top.toTuple2D(), m.shovels.cavity).close())
return self.newObject(profile.objects)
def toLocalVector(self, x=0.0, y=0.0, z=0.0):
if type(x) is cq.Workplane:
x = x.first().val().Center().x
if type(y) is cq.Workplane:
y = y.first().val().Center().y
if type(z) is cq.Workplane:
z = z.first().val().Center().z
return self.plane.toLocalCoords(cq.Vector(x, y, z))
def _makeCross(loc):
pnts = []
t = 2 * pi / fn
R = r1 / 2 / sin(t)
for i in range(fn + 1):
pts = [R * cos(i * t + pi / fn), R * sin(i * t + pi / fn)]
pnts.append(cq.Vector(pts[0], pts[1], 0))
return cq.Wire.makePolygon(pnts, forConstruction).locate(loc)
def _one_heatsert(loc):
pnt = cq.Vector(0, 0, 0)
boreDir = cq.Vector(0, 0, -1)
hole = cq.Solid.makeCylinder(diam / 2.0, depth, pnt, boreDir)
if bolt_clear:
extra_hole_diam = bolt_diam * 1.2
extra_hole = cq.Solid.makeCylinder(extra_hole_diam / 2.0,
bolt_clear, pnt, boreDir)
hole = hole.fuse(extra_hole)
if chamfer:
cone_face_radius = diam / 2 + chamfer_vals[0]
cone = cq.Solid.makeCone(cone_face_radius, diam / 2,
chamfer_vals[1], pnt, boreDir)
hole = hole.fuse(cone)
return hole.move(loc)
def hull_bracket(angle, width, thickness, top_height, side_height,
top_hole_radius, top_hole_distance, top_hole_margin,
side_hole_radius, side_hole_distance, side_hole_margin):
thm = top_height / 2 - top_hole_margin
return (cq.Workplane("front").box(
width, top_height, thickness).faces('>Z').pushPoints([
(top_hole_distance / 2, thm), (-top_hole_distance / 2, thm)
]).circle(top_hole_radius).cutThruAll().faces(
">Y").workplane().transformed(
offset=cq.Vector(
0, thickness / 2 - sin(radians(angle)) * thickness / 2,
cos(radians(angle)) * thickness / 2),
rotate=cq.Vector(angle, 0, 0)).moveTo(0, side_height / 2).box(
width, side_height, thickness).faces('>Y').pushPoints([
(side_hole_distance / 2, side_hole_margin),
(-side_hole_distance / 2, side_hole_margin)
]).circle(side_hole_radius).cutThruAll())
def simple_assy2():
b1 = cq.Workplane().box(1, 1, 1)
b2 = cq.Workplane().box(2, 1, 1)
assy = cq.Assembly()
assy.add(b1, name="b1")
assy.add(b2, loc=cq.Location(cq.Vector(0, 0, 4)), name="b2")
return assy
