473 lines
15 KiB
Python
473 lines
15 KiB
Python
from dataclasses import dataclass
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import math
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import cadquery as Cq
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import nhf.parts.springs as springs
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from nhf import Role
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import nhf.utils
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TOL = 1e-6
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@dataclass
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class HirthJoint:
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"""
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A Hirth joint attached to a cylindrical base
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"""
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# r
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radius: float = 60
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# r_i
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radius_inner: float = 40
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base_height: float = 20
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n_tooth: float = 16
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# h_o
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tooth_height: float = 16
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def __post_init__(self):
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# Ensures tangent doesn't blow up
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assert self.n_tooth >= 5
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assert self.radius > self.radius_inner
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@property
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def tooth_angle(self):
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return 360 / self.n_tooth
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@property
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def total_height(self):
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return self.base_height + self.tooth_height
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def generate(self, is_mated=False, tol=0.01):
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"""
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is_mated: If set to true, rotate the teeth so they line up at 0 degrees.
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FIXME: Mate is not exact when number of tooth is low
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"""
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phi = math.radians(self.tooth_angle)
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alpha = 2 * math.atan(self.radius / self.tooth_height * math.tan(phi/2))
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#alpha = math.atan(self.radius * math.radians(180 / self.n_tooth) / self.tooth_height)
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gamma = math.radians(90 / self.n_tooth)
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# Tooth half height
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l = self.radius * math.cos(gamma)
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a = self.radius * math.sin(gamma)
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t = a / math.tan(alpha / 2)
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beta = math.asin(t / l)
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dx = self.tooth_height * math.tan(alpha / 2)
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profile = (
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Cq.Workplane('YZ')
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.polyline([
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(0, 0),
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(dx, self.tooth_height),
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(-dx, self.tooth_height),
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])
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.close()
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.extrude(-self.radius)
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.val()
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.rotate((0, 0, 0), (0, 1, 0), math.degrees(beta))
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.moved(Cq.Location((0, 0, self.base_height)))
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)
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core = Cq.Solid.makeCylinder(
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radius=self.radius_inner,
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height=self.tooth_height,
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pnt=(0, 0, self.base_height),
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)
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angle_offset = self.tooth_angle / 2 if is_mated else 0
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result = (
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Cq.Workplane('XY')
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.cylinder(
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radius=self.radius,
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height=self.base_height + self.tooth_height,
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centered=(True, True, False))
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.faces(">Z")
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.tag("bore")
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.cut(core)
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.polarArray(
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radius=self.radius,
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startAngle=angle_offset,
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angle=360,
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count=self.n_tooth)
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.cutEach(
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lambda loc: profile.moved(loc),
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)
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)
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(
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result
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.polyline([
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(0, 0, self.base_height),
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(0, 0, self.base_height + self.tooth_height)
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], forConstruction=True)
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.tag("mate")
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)
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(
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result
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.polyline([(0, 0, 0), (1, 0, 0)], forConstruction=True)
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.tag("directrix")
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)
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return result
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def assembly(self, offset: int = 1):
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"""
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Generate an example assembly
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"""
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tab = (
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Cq.Workplane('XY')
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.box(100, 10, 2, centered=False)
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)
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obj1 = (
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self.generate()
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.faces(tag="bore")
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.cboreHole(
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diameter=10,
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cboreDiameter=20,
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cboreDepth=3)
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.union(tab)
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)
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obj2 = (
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self.generate(is_mated=True)
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.union(tab)
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)
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angle = offset * self.tooth_angle
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result = (
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Cq.Assembly()
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.add(obj1, name="obj1", color=Role.PARENT.color)
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.add(obj2, name="obj2", color=Role.CHILD.color)
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.constrain("obj1", "Fixed")
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.constrain("obj1?mate", "obj2?mate", "Plane")
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.constrain("obj1?directrix", "obj2?directrix", "Axis", param=angle)
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.solve()
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)
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return result
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def comma_joint(radius=30,
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shaft_radius=10,
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height=10,
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flange=10,
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flange_thickness=25,
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n_serration=16,
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serration_angle_offset=0,
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serration_height=5,
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serration_inner_radius=20,
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serration_theta=2 * math.pi / 48,
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serration_tilt=-30,
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right_handed=False):
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"""
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Produces a "o_" shaped joint, with serrations to accomodate a torsion spring
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"""
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assert flange_thickness <= radius
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flange_poly = [
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(0, radius - flange_thickness),
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(0, radius),
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(flange + radius, radius),
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(flange + radius, radius - flange_thickness)
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]
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if right_handed:
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flange_poly = [(x, -y) for x,y in flange_poly]
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sketch = (
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Cq.Sketch()
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.circle(radius)
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.polygon(flange_poly, mode='a')
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.circle(shaft_radius, mode='s')
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)
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serration_poly = [
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(0, 0), (radius, 0),
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(radius, radius * math.tan(serration_theta))
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]
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serration = (
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Cq.Workplane('XY')
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.sketch()
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.polygon(serration_poly)
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.circle(radius, mode='i')
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.circle(serration_inner_radius, mode='s')
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.finalize()
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.extrude(serration_height)
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.translate(Cq.Vector((-serration_inner_radius, 0, height)))
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.rotate(
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axisStartPoint=(0, 0, 0),
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axisEndPoint=(0, 0, height),
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angleDegrees=serration_tilt)
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.val()
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)
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serrations = (
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Cq.Workplane('XY')
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.polarArray(radius=serration_inner_radius,
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startAngle=0+serration_angle_offset,
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angle=360+serration_angle_offset,
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count=n_serration)
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.eachpoint(lambda loc: serration.located(loc))
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)
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result = (
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Cq.Workplane()
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.add(sketch)
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.extrude(height)
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.union(serrations)
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.clean()
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)
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result.polyline([
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(0, 0, height - serration_height),
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(0, 0, height + serration_height)],
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forConstruction=True).tag("serrated")
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result.polyline([
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(0, radius, 0),
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(flange + radius, radius, 0)],
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forConstruction=True).tag("tail")
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result.faces('>X').tag("tail_end")
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return result
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def comma_assembly():
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joint1 = comma_joint()
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joint2 = comma_joint()
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spring = springs.torsion_spring()
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result = (
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Cq.Assembly()
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.add(joint1, name="joint1", color=Cq.Color(0.8,0.8,0.5,0.3))
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.add(joint2, name="joint2", color=Cq.Color(0.8,0.8,0.5,0.3))
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.add(spring, name="spring", color=Cq.Color(0.5,0.5,0.5,1))
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.constrain("joint1?serrated", "spring?bot", "Plane")
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.constrain("joint2?serrated", "spring?top", "Plane")
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.constrain("joint1?tail", "FixedAxis", (1, 0, 0))
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.constrain("joint2?tail", "FixedAxis", (-1, 0, 0))
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.solve()
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)
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return result
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@dataclass
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class TorsionJoint:
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"""
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This jonit consists of a rider puck on a track puck. IT is best suited if
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the radius has to be small and vertical space is abundant.
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The rider part consists of:
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1. A cylinderical base
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2. A annular extrusion with the same radius as the base, but with slots
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carved in
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3. An annular rider
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The track part consists of:
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1. A cylindrical base
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2. A slotted annular extrusion where the slot allows the spring to rest
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3. An outer and an inner annuli which forms a track the rider can move on
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"""
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# Radius limit for rotating components
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radius: float = 40
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track_disk_height: float = 10
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rider_disk_height: float = 8
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radius_spring: float = 15
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radius_axle: float = 6
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# If true, cover the spring hole. May make it difficult to insert the spring
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# considering the stiffness of torsion spring steel.
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spring_hole_cover_track: bool = False
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spring_hole_cover_rider: bool = False
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# Also used for the height of the hole for the spring
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spring_thickness: float = 2
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spring_height: float = 15
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spring_tail_length: float = 40
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groove_radius_outer: float = 35
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groove_radius_inner: float = 20
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groove_depth: float = 5
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rider_gap: float = 1
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rider_n_slots: float = 4
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# Degrees of the first and last rider slots
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rider_slot_begin: float = 0
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rider_slot_span: float = 90
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right_handed: bool = False
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def __post_init__(self):
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assert self.radius > self.groove_radius_outer
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assert self.groove_radius_outer > self.groove_radius_inner
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assert self.groove_radius_inner > self.radius_spring
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assert self.spring_height > self.groove_depth, "Groove is too deep"
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assert self.radius_spring > self.radius_axle
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@property
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def total_height(self):
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return self.track_disk_height + self.rider_disk_height + self.spring_height
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@property
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def _radius_spring_internal(self):
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return self.radius_spring - self.spring_thickness
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def _slot_polygon(self, flip: bool=False):
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r1 = self.radius_spring - self.spring_thickness
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r2 = self.radius_spring
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flip = flip != self.right_handed
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if flip:
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r1 = -r1
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r2 = -r2
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return [
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(0, r2),
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(self.spring_tail_length, r2),
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(self.spring_tail_length, r1),
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(0, r1),
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]
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def _directrix(self, height, theta=0):
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c, s = math.cos(theta), math.sin(theta)
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r2 = self.radius_spring
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l = self.spring_tail_length
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if self.right_handed:
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r2 = -r2
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# This is (0, r2) and (l, r2) transformed by rotation matrix
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# [[c, s], [-s, c]]
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return [
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(0, 0, height),
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(c, s, height)
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]
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return [
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(s * r2, -s * l + c * r2, height),
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(c * l + s * r2, -s * l + c * r2, height),
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]
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def spring(self):
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return springs.torsion_spring(
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radius=self.radius_spring,
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height=self.spring_height,
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thickness=self.spring_thickness,
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tail_length=self.spring_tail_length,
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)
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def track(self):
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groove_profile = (
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Cq.Sketch()
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.circle(self.radius)
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.circle(self.groove_radius_outer, mode='s')
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.circle(self.groove_radius_inner, mode='a')
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.circle(self.radius_spring, mode='s')
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)
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spring_hole_profile = (
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Cq.Sketch()
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.circle(self.radius)
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.circle(self.radius_spring, mode='s')
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)
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slot_height = self.spring_thickness
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if not self.spring_hole_cover_track:
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slot_height += self.groove_depth
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slot = (
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Cq.Workplane('XY')
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.sketch()
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.polygon(self._slot_polygon(flip=False))
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.finalize()
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.extrude(slot_height)
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.val()
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)
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result = (
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Cq.Workplane('XY')
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.cylinder(
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radius=self.radius,
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height=self.track_disk_height,
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centered=(True, True, False))
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.faces('>Z')
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.tag("spring")
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.placeSketch(spring_hole_profile)
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.extrude(self.spring_thickness)
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# If the spring hole profile is not simply connected, this workplane
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# will have to be created from the `spring-mate` face.
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.faces('>Z')
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.placeSketch(groove_profile)
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.extrude(self.groove_depth)
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.faces('>Z')
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.hole(self.radius_axle * 2)
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.cut(slot.moved(Cq.Location((0, 0, self.track_disk_height))))
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)
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# Insert directrix`
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result.polyline(self._directrix(self.track_disk_height),
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forConstruction=True).tag("directrix")
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return result
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def rider(self):
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def slot(loc):
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wire = Cq.Wire.makePolygon(self._slot_polygon(flip=False))
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face = Cq.Face.makeFromWires(wire)
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return face.located(loc)
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wall_profile = (
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Cq.Sketch()
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.circle(self.radius, mode='a')
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.circle(self.radius_spring, mode='s')
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.parray(
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r=0,
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a1=self.rider_slot_begin,
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da=self.rider_slot_span,
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n=self.rider_n_slots)
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.each(slot, mode='s')
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#.circle(self._radius_wall, mode='a')
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)
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contact_profile = (
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Cq.Sketch()
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.circle(self.groove_radius_outer, mode='a')
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.circle(self.groove_radius_inner, mode='s')
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)
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if not self.spring_hole_cover_rider:
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contact_profile = (
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contact_profile
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.parray(
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r=0,
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a1=self.rider_slot_begin,
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da=self.rider_slot_span,
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n=self.rider_n_slots)
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.each(slot, mode='s')
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.reset()
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)
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#.circle(self._radius_wall, mode='a')
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middle_height = self.spring_height - self.groove_depth - self.rider_gap - self.spring_thickness
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result = (
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Cq.Workplane('XY')
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.cylinder(
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radius=self.radius,
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height=self.rider_disk_height,
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centered=(True, True, False))
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.faces('>Z')
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.tag("spring")
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.workplane()
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.placeSketch(wall_profile)
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.extrude(middle_height)
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.faces(tag="spring")
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.workplane()
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# The top face might not be in one piece.
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.workplane(offset=middle_height)
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.placeSketch(contact_profile)
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.extrude(self.groove_depth + self.rider_gap)
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.faces(tag="spring")
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.workplane()
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.circle(self._radius_spring_internal)
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.extrude(self.spring_height)
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#.faces(tag="spring")
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#.workplane()
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.hole(self.radius_axle * 2)
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)
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theta_begin = math.radians(self.rider_slot_begin) + math.pi
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theta_span = math.radians(self.rider_slot_span)
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if abs(math.remainder(self.rider_slot_span, 360)) < TOL:
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theta_step = theta_span / self.rider_n_slots
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else:
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theta_step = theta_span / (self.rider_n_slots - 1)
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for i in range(self.rider_n_slots):
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theta = theta_begin - i * theta_step
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result.polyline(self._directrix(self.rider_disk_height, theta),
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forConstruction=True).tag(f"directrix{i}")
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return result
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def rider_track_assembly(self, directrix=0):
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rider = self.rider()
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track = self.track()
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spring = self.spring()
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result = (
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Cq.Assembly()
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.add(spring, name="spring", color=Role.DAMPING.color)
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.add(track, name="track", color=Role.PARENT.color)
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.constrain("track?spring", "spring?top", "Plane")
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.constrain("track?directrix", "spring?directrix_bot", "Axis")
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.add(rider, name="rider", color=Role.CHILD.color)
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.constrain("rider?spring", "spring?bot", "Plane")
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.constrain(f"rider?directrix{directrix}", "spring?directrix_top", "Axis")
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.solve()
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)
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return result
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