210 lines
6.8 KiB
Python
210 lines
6.8 KiB
Python
"""
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This schematics file contains all designs related to tool handles
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"""
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from dataclasses import dataclass
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import cadquery as Cq
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import nhf.metric_threads as NMt
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@dataclass(frozen=True)
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class Handle:
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"""
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Characteristic of a tool handle
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This assumes the handle segment material does not have threads. Each segment
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attaches to two insertions, which have threads on the inside. A connector
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has threads on the outside and joints two insertions.
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Note that all the radial sizes are diameters (in mm).
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"""
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# Outer and inner radius for the handle usually come in standard sizes
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diam: float = 38
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diam_inner: float = 33
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# Major diameter of the internal threads, following ISO metric screw thread
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# standard. This determines the wall thickness of the insertion.
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diam_threading: float = 27.0
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thread_pitch: float = 3.0
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# Internal cavity diameter. This determines the wall thickness of the connector
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diam_connector_internal: float = 18.0
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# If set to true, do not generate threads
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simplify_geometry: bool = True
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# Length for the rim on the female connector
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rim_length: float = 5
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insertion_length: float = 60
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# Amount by which the connector goes into the segment
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connector_length: float = 60
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def __post_init__(self):
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assert self.diam > self.diam_inner, "Material thickness cannot be <= 0"
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assert self.diam_inner > self.diam_insertion_internal, "Threading radius is too big"
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assert self.diam_insertion_internal > self.diam_connector_external
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assert self.diam_connector_external > self.diam_connector_internal, "Internal diameter is too large"
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assert self.insertion_length > self.rim_length
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@property
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def diam_insertion_internal(self):
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r = NMt.metric_thread_major_radius(
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self.diam_threading,
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self.thread_pitch,
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internal=True)
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return r * 2
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@property
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def diam_connector_external(self):
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r = NMt.metric_thread_minor_radius(
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self.diam_threading,
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self.thread_pitch)
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return r * 2
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def segment(self, length: float):
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result = (
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Cq.Workplane()
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.cylinder(
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radius=self.diam / 2,
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height=length)
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)
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result.faces("<Z").tag("mate1")
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result.faces(">Z").tag("mate2")
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return result
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def _external_thread(self):
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return NMt.external_metric_thread(
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self.diam_threading,
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self.thread_pitch,
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self.insertion_length,
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top_lead_in=True)
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def _internal_thread(self):
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return NMt.internal_metric_thread(
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self.diam_threading,
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self.thread_pitch,
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self.insertion_length)
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def insertion(self):
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"""
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This type of joint is used to connect two handlebar pieces. Each handlebar
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piece is a tube which cannot be machined, so the joint connects to the
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handle by glue.
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Tags:
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* lip: Co-planar Mates to the rod
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* mate: Mates to the connector
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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.diam_inner / 2,
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height=self.insertion_length - self.rim_length,
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centered=[True, True, False])
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)
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result.faces(">Z").tag("rim")
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if self.rim_length > 0:
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result = (
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result.faces(">Z")
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.workplane()
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.circle(self.diam / 2)
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.extrude(self.rim_length)
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.faces(">Z")
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.hole(self.diam_insertion_internal)
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)
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result.faces(">Z").tag("mate")
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if not self.simplify_geometry:
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thread = self._internal_thread().val()
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result = result.union(thread)
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return result
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def connector(self, solid: bool = False):
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"""
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Tags:
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* mate{1,2}: Mates to the connector
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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.diam / 2,
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height=self.connector_length,
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)
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)
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for (tag, selector) in [("mate1", "<Z"), ("mate2", ">Z")]:
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result.faces(selector).tag(tag)
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result = (
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result
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.faces(selector)
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.workplane()
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.circle(self.diam_connector_external / 2)
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.extrude(self.insertion_length)
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)
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if not solid:
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result = result.faces(">Z").hole(self.diam_connector_internal)
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if not self.simplify_geometry:
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thread = self._external_thread().val()
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result = (
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result
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.union(
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thread
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.located(Cq.Location((0, 0, self.connector_length / 2))))
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.union(
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thread
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.rotate((0,0,0), (1,0,0), angleDegrees=90)
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.located(Cq.Location((0, 0, -self.connector_length / 2))))
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)
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return result
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def one_side_connector(self):
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result = (
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Cq.Workplane('XY')
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.cylinder(
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radius=self.diam / 2,
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height=self.rim_length,
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)
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)
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result.faces(">Z").tag("mate")
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result.faces("<Z").tag("base")
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result = (
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result
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.faces(">Z")
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.workplane()
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.circle(self.diam_connector_external / 2)
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.extrude(self.insertion_length)
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)
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if not self.simplify_geometry:
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thread = self._external_thread().val()
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result = (
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result
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.union(
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thread
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.located(Cq.Location((0, 0, self.connector_length / 2))))
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)
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return result
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def connector_insertion_assembly(self):
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connector_color = Cq.Color(0.8,0.8,0.5,0.3)
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insertion_color = Cq.Color(0.7,0.7,0.7,0.3)
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result = (
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Cq.Assembly()
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.add(self.connector(), name="c", color=connector_color)
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.add(self.insertion(), name="i1", color=insertion_color)
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.add(self.insertion(), name="i2", color=insertion_color)
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.constrain("c?mate1", "i1?mate", "Plane")
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.constrain("c?mate2", "i2?mate", "Plane")
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.solve()
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)
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return result
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def connector_one_side_insertion_assembly(self):
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connector_color = Cq.Color(0.8,0.8,0.5,0.3)
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insertion_color = Cq.Color(0.7,0.7,0.7,0.3)
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result = (
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Cq.Assembly()
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.add(self.insertion(), name="i", color=connector_color)
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.add(self.one_side_connector(), name="c", color=insertion_color)
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.constrain("i?mate", "c?mate", "Plane")
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.solve()
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)
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return result
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