feat: Trident handle

2024-06-25 09:11:48 -04:00 · 2024-06-25 09:11:48 -04:00 · a41906d130
parent 32e5f543d9
commit a41906d130
6 changed files with 208 additions and 1 deletions
--- a/nhf/handle.py
+++ b/nhf/handle.py
@ -0,0 +1,156 @@
 """
 This schematics file contains all designs related to tool handles
 """
 from dataclasses import dataclass
 import cadquery as Cq
@dataclass(frozen=True)
 class Handle:
    """
    Characteristic of a tool handle
    """
    # Outer radius for the handle
    radius: float = 38 / 2
    # Inner radius
    radius_inner: float = 33 / 2
    # Wall thickness for the connector
    insertion_thickness: float = 4
    # The connector goes in the insertion
    connector_thickness: float = 4
    # Length for the rim on the female connector
    rim_length: float = 5
    insertion_length: float = 60
    connector_length: float = 60
    def __post_init__(self):
        assert self.radius > self.radius_inner
        assert self.radius_inner > self.insertion_thickness + self.connector_thickness
        assert self.insertion_length > self.rim_length
    @property
    def _r1(self):
        """
        Radius of inside of insertion
        """
        return self.radius_inner - self.insertion_thickness
    @property
    def _r2(self):
        """
        Radius of inside of connector
        """
        return self._r1 - self.connector_thickness
    def segment(self, length: float):
        result = (
            Cq.Workplane()
            .cylinder(radius=self.radius, height=length)
        )
        result.faces("<Z").tag("mate1")
        result.faces(">Z").tag("mate2")
        return result
    def insertion(self):
        """
        This type of joint is used to connect two handlebar pieces. Each handlebar
        piece is a tube which cannot be machined, so the joint connects to the
        handle by glue.
        Tags:
        * lip: Co-planar Mates to the rod
        * mate: Mates to the connector
        """
        result = (
            Cq.Workplane('XY')
            .cylinder(
                radius=self.radius_inner,
                height=self.insertion_length - self.rim_length,
                centered=[True, True, False])
        )
        result.faces(">Z").tag("lip")
        result = (
            result.faces(">Z")
            .workplane()
            .circle(self.radius)
            .extrude(self.rim_length)
            .faces(">Z")
            .hole(2 * self._r1)
        )
        result.faces(">Z").tag("mate")
        return result
    def connector(self, solid: bool = False):
        """
        Tags:
        * mate{1,2}: Mates to the connector
        """
        result = (
            Cq.Workplane('XY')
            .cylinder(
                radius=self.radius,
                height=self.connector_length,
            )
        )
        for (tag, selector) in [("mate1", "<Z"), ("mate2", ">Z")]:
            result.faces(selector).tag(tag)
            r1 = self.radius_inner
            result = (
                result
                .faces(selector)
                .workplane()
                .circle(self._r1)
                .extrude(self.insertion_length)
            )
        if not solid:
            result = result.faces(">Z").hole(2 * self._r2)
        return result
    def one_side_connector(self):
        result = (
            Cq.Workplane('XY')
            .cylinder(
                radius=self.radius,
                height=self.rim_length,
            )
        )
        result.faces("<Z").tag("mate")
        result.faces(">Z").tag("base")
        result = (
            result
            .faces("<Z")
            .workplane()
            .circle(self._r1)
            .extrude(self.insertion_length)
        )
        return result
    def connector_insertion_assembly(self):
        connector_color = Cq.Color(0.8,0.8,0.5,0.3)
        insertion_color = Cq.Color(0.7,0.7,0.7,0.3)
        result = (
            Cq.Assembly()
            .add(self.connector(), name="c", color=connector_color)
            .add(self.insertion(), name="i1", color=insertion_color)
            .add(self.insertion(), name="i2", color=insertion_color)
            .constrain("c?mate1", "i1?mate", "Plane")
            .constrain("c?mate2", "i2?mate", "Plane")
            .solve()
        )
        return result
    def connector_one_side_insertion_assembly(self):
        connector_color = Cq.Color(0.8,0.8,0.5,0.3)
        insertion_color = Cq.Color(0.7,0.7,0.7,0.3)
        result = (
            Cq.Assembly()
            .add(self.insertion(), name="i", color=connector_color)
            .add(self.one_side_connector(), name="c", color=insertion_color)
            .constrain("i?mate", "c?mate", "Plane")
            .solve()
        )
        return result
--- a/nhf/materials.py
+++ b/nhf/materials.py
@ -12,6 +12,7 @@ class Material(Enum):
    WOOD_BIRCH = 0.8, _color('bisque', 0.9)
    PLASTIC_PLA = 0.5, _color('azure3', 0.6)
    ACRYLIC_BLACK = 0.5, _color('gray50', 0.6)
    def __init__(self, density: float, color: Cq.Color):
        self.density = density
--- a/nhf/test.py
+++ b/nhf/test.py
@ -1,6 +1,7 @@
 import unittest
 import cadquery as Cq
 import nhf.joints
 import nhf.handle
 class TestJoints(unittest.TestCase):
@ -13,5 +14,13 @@ class TestJoints(unittest.TestCase):
    def test_joints_comma_assembly(self):
        nhf.joints.comma_assembly()
 class TestHandle(unittest.TestCase):
    def test_handle_assembly(self):
        h = nhf.handle.Handle()
        h.connector_insertion_assembly()
        h.connector_one_side_insertion_assembly()
 if __name__ == '__main__':
    unittest.main()
--- a/nhf/touhou/houjuu_nue/init.py
+++ b/nhf/touhou/houjuu_nue/init.py
@ -20,15 +20,18 @@ the wing which demands transluscency are created from 1/16" acrylic panels.
 These panels serve double duty as the exoskeleton.
 The wings are labeled r1,r2,r3,l1,l2,l3. The segments of the wings are labeled
-from root to tip s0 (root), s1, s2, s3. The joints are named (from root to tip)
+from root to tip s0 (root),
 s1, s2, s3. The joints are named (from root to tip)
 shoulder, elbow, wrist in analogy with human anatomy.
 """
 from dataclasses import dataclass
 import unittest
 import cadquery as Cq
 import nhf.joints
 import nhf.handle
 from nhf import Material
 import nhf.touhou.houjuu_nue.wing as MW
 import nhf.touhou.houjuu_nue.trident as MT
@dataclass(frozen=True)
 class Parameters:
@ -86,6 +89,8 @@ class Parameters:
    wing_r2_height = 100
    wing_r3_height = 100
    trident_handle: nhf.handle.Handle = nhf.handle.Handle()
    def __post_init__(self):
        assert self.wing_root_radius > self.hs_joint_radius,\
            "Wing root must be large enough to accomodate joint"
@ -301,3 +306,6 @@ class Parameters:
                result.constrain(f"harness?{name}_{i}", f"hs_{name}p?h{i}", "Point")
        result.solve()
        return result
    def trident_assembly(self):
        return MT.trident_assembly(self.trident_handle)
--- a/nhf/touhou/houjuu_nue/test.py
+++ b/nhf/touhou/houjuu_nue/test.py
@ -18,6 +18,9 @@ class Test(unittest.TestCase):
    def test_harness(self):
        p = M.Parameters()
        p.harness_assembly()
    def test_trident():
        p = M.Parameters()
        p.trident_assembly()
 if __name__ == '__main__':
    unittest.main()
--- a/nhf/touhou/houjuu_nue/trident.py
+++ b/nhf/touhou/houjuu_nue/trident.py
@ -0,0 +1,30 @@
 import math
 import cadquery as Cq
 from nhf import Material
 from nhf.handle import Handle
 def trident_assembly(
        handle: Handle,
        handle_segment_length: float = 24*25.4):
    def segment():
        return handle.segment(handle_segment_length)
    mat_i = Material.PLASTIC_PLA
    mat_s = Material.ACRYLIC_BLACK
    assembly = (
        Cq.Assembly()
        .add(handle.insertion(), name="i0", color=mat_i.color)
        .constrain("i0", "Fixed")
        .add(segment(), name="s1", color=mat_s.color)
        .constrain("i0?lip", "s1?mate1", "Plane", param=0)
        .add(handle.insertion(), name="i1", color=mat_i.color)
        .add(handle.connector(), name="c1", color=mat_i.color)
        .add(handle.insertion(), name="i2", color=mat_i.color)
        .constrain("s1?mate2", "i1?lip", "Plane", param=0)
        .constrain("i1?mate", "c1?mate1", "Plane")
        .constrain("i2?mate", "c1?mate2", "Plane")
        .add(segment(), name="s2", color=mat_s.color)
        .constrain("i2?lip", "s2?mate1", "Plane", param=0)
        .add(handle.insertion(), name="i3", color=mat_i.color)
        .constrain("s2?mate2", "i3?lip", "Plane", param=0)
    )
    return assembly.solve()