示例#1
0
def bar(width, thick, diameter, tolerance, amount=0, stem=1, twist=False, tneck=0.5, tthick=0.01, twist_keep=False,
        twist_line=False, twist_line_amount=2, which='MF'):

    # width = length of the bar
    # thick = thickness of the bar
    # diameter = diameter of the tool for joint creation
    # tolerance = Tolerance in the joint
    # amount = amount of fingers in the joint 0 means auto generate
    # stem = amount of radius the stem or neck of the joint will have
    # twist = twist lock addition
    # tneck = percentage the twist neck will have compared to thick
    # tthick = thicknest of the twist material
    # Which M,F, MF, MM, FF

    global DT
    if amount == 0:
        amount = round(thick / ((4 + 2 * (stem - 1)) * diameter * DT)) - 1
    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=width, Simple_length=thick, use_cyclic_u=True, edit_mode=False)
    simple.active_name('tmprect')

    fingers(diameter, tolerance, amount, stem=stem)

    if which == 'MM' or which == 'M' or which == 'MF':
        simple.rename('fingers', '_tmpfingers')
        simple.rotate(-math.pi / 2)
        simple.move(x=width / 2)
        simple.rename('tmprect', '_tmprect')
        simple.union('_tmp')
        simple.active_name("tmprect")
        twistm('tmprect', thick, diameter, tolerance, twist, tneck, tthick, -math.pi / 2,
               x=width / 2, twist_keep=twist_keep)

    twistf('receptacle', thick, diameter, tolerance, twist, tneck, tthick, twist_keep=twist_keep)
    simple.rename('receptacle', '_tmpreceptacle')
    if which == 'FF' or which == 'F' or which == 'MF':
        simple.rotate(-math.pi / 2)
        simple.move(x=-width / 2)
        simple.rename('tmprect', '_tmprect')
        simple.difference('_tmp', '_tmprect')
        simple.active_name("tmprect")
        if twist_keep:
            simple.make_active('twist_keep_f')
            simple.rotate(-math.pi / 2)
            simple.move(x=-width / 2)
           
    simple.remove_multiple("_")  # Remove temporary base and holes
    simple.remove_multiple("fingers")  # Remove temporary base and holes

    if twist_line:
        joinery.twist_line(thick, tthick, tolerance, tneck, twist_line_amount, width)
        if twist_keep:
            simple.duplicate()
        simple.active_name('tmptwist')
        simple.difference('tmp', 'tmprect')
    simple.rename('tmprect', 'Puzzle_bar')
    simple.remove_multiple("tmp")  # Remove temporary base and holes
    simple.make_active('Puzzle_bar')
示例#2
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def arcbararc(length, radius, thick, angle, angleb, diameter, tolerance, amount=0, stem=1, twist=False,
              tneck=0.5, tthick=0.01, which='MF', twist_keep=False, twist_line=False, twist_line_amount=2):
    # length is the total width of the segments including 2 * radius and thick
    # radius = radius of the curve
    # thick = thickness of the bar
    # angle = angle of the female part
    # angleb = angle of the male part
    # diameter = diameter of the tool for joint creation
    # tolerance = Tolerance in the joint
    # amount = amount of fingers in the joint 0 means auto generate
    # stem = amount of radius the stem or neck of the joint will have
    # twist = twist lock addition
    # tneck = percentage the twist neck will have compared to thick
    # tthick = thicknest of the twist material
    # which = which joint to generate, Male Female MaleFemale M, F, MF

    length -= (radius * 2 + thick)  # adjust length to include 2x radius + thick

    # generate base rectangle
    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=length * 1.005, Simple_length=thick, use_cyclic_u=True, edit_mode=False)
    simple.active_name("tmprect")

    #  Generate male section and join to the base
    if which == 'M' or which == 'MF':
        arc(radius, thick, angleb, diameter, tolerance, amount=amount, stem=stem, twist=twist, tneck=tneck,
            tthick=tthick, which='M')
        simple.move(x=length / 2)
        simple.active_name('tmp_male')
        simple.select_multiple('tmp')
        bpy.ops.object.curve_boolean(boolean_type='UNION')
        simple.active_name('male')
        simple.remove_multiple('tmp')
        simple.rename('male', 'tmprect')

    # Generate female section and join to base
    if which == 'F' or which == 'MF':
        arc(radius, thick, angle, diameter, tolerance, amount=amount, stem=stem, twist=twist, tneck=tneck,
            tthick=tthick, which='F')
        simple.move(x=-length / 2)
        simple.active_name('tmp_receptacle')
        simple.union('tmp')
        simple.active_name('tmprect')

    if twist_line:
        joinery.twist_line(thick, tthick, tolerance, tneck, twist_line_amount, length)
        if twist_keep:
            simple.duplicate()
        simple.active_name('tmptwist')
        simple.difference('tmp', 'tmprect')

    simple.active_name('arcBarArc')
    simple.make_active('arcBarArc')
示例#3
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def finger(diameter, stem=2):
    # diameter = diameter of the tool for joint creation
    # DT = Bit diameter tolerance
    # stem = amount of radius the stem or neck of the joint will have
    global DT
    RESOLUTION = 12  # Data resolution
    cube_sx = diameter * DT * (2 + stem - 1)
    cube_ty = diameter * DT
    cube_sy = 2 * diameter * DT
    circle_radius = diameter * DT / 2
    c1x = cube_sx / 2
    c2x = cube_sx / 2
    c2y = 3 * circle_radius
    c1y = circle_radius

    bpy.ops.curve.simple(align='WORLD', location=(0, cube_ty, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=cube_sx, Simple_length=cube_sy, use_cyclic_u=True, edit_mode=False)
    bpy.context.active_object.name = "ftmprect"

    bpy.ops.curve.simple(align='WORLD', location=(c2x, c2y, 0), rotation=(0, 0, 0), Simple_Type='Ellipse',
                         Simple_a=circle_radius,
                         Simple_b=circle_radius, Simple_sides=4, use_cyclic_u=True, edit_mode=False, shape='3D')

    bpy.context.active_object.name = "ftmpcirc_add"
    bpy.context.object.data.resolution_u = RESOLUTION

    bpy.ops.object.origin_set(type='ORIGIN_CURSOR', center='MEDIAN')

    simple.duplicate()
    simple.mirrorx()

    simple.union('ftmp')
    simple.rename('ftmp', '_sum')

    rc1 = circle_radius

    bpy.ops.curve.simple(align='WORLD', location=(c1x, c1y, 0), rotation=(0, 0, 0), Simple_Type='Ellipse',
                         Simple_a=circle_radius, Simple_b=rc1, Simple_sides=4, use_cyclic_u=True, edit_mode=False,
                         shape='3D')

    bpy.context.active_object.name = "_circ_delete"
    bpy.context.object.data.resolution_u = RESOLUTION
    bpy.ops.object.origin_set(type='ORIGIN_CURSOR', center='MEDIAN')

    simple.duplicate()
    simple.mirrorx()
    simple.union('_circ')

    simple.difference('_', '_sum')
    bpy.ops.object.curve_remove_doubles()
    simple.rename('_sum', "_puzzle")
示例#4
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def t(length, thick, diameter, tolerance, amount=0, stem=1, twist=False, tneck=0.5, tthick=0.01, combination='MF',
      base_gender='M', corner=False):
    if corner:
        if combination == 'MF':
            base_gender = 'M'
            combination = 'f'
        elif combination == 'F':
            base_gender = 'F'
            combination = 'f'
        elif combination == 'M':
            base_gender = 'M'
            combination = 'm'

    bar(length, thick, diameter, tolerance, amount=amount, stem=stem, twist=twist, tneck=tneck,
        tthick=tthick, which=base_gender)
    simple.active_name('tmp')
    fingers(diameter, tolerance, amount=amount, stem=stem)
    if combination == 'MF' or combination == 'M' or combination == 'm':
        simple.make_active('fingers')
        simple.move(y=thick / 2)
        simple.duplicate()
        simple.active_name('tmp')
        simple.union('tmp')

    if combination == 'M':
        simple.make_active('fingers')
        simple.mirrory()
        simple.active_name('tmp')
        simple.union('tmp')

    if combination == 'MF' or combination == 'F' or combination == 'f':
        simple.make_active('receptacle')
        simple.move(y=-thick / 2)
        simple.duplicate()
        simple.active_name('tmp')
        simple.difference('tmp', 'tmp')

    if combination == 'F':
        simple.make_active('receptacle')
        simple.mirrory()
        simple.active_name('tmp')
        simple.difference('tmp', 'tmp')

    simple.remove_multiple('receptacle')
    simple.remove_multiple('fingers')

    simple.rename('tmp', 't')
    simple.make_active('t')
示例#5
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def tile(diameter, tolerance, tile_x_amount, tile_y_amount, stem=1):
    global DT
    diameter = diameter * DT
    # diameter * DT * (2 + stem - 1)
    (4 + 2 * (stem - 1)) * diameter
    width = (tile_x_amount) * (4 + 2 * (stem - 1)) * diameter + diameter
    height = (tile_y_amount) * (4 + 2 * (stem - 1)) * diameter + diameter

    print('size:', width, height)
    fingers(diameter, tolerance, amount=tile_x_amount+2, stem=stem)
    simple.add_rectangle(width, height)
    simple.active_name('_base')

    simple.make_active('fingers')
    simple.active_name('_fingers')
    simple.intersect('_')
    simple.remove_multiple('_fingers')
    simple.rename('intersection', '_fingers')
    simple.move(y=height/2)
    simple.union('_')
    simple.active_name('_base')
    simple.remove_doubles()
    simple.rename('receptacle', '_receptacle')
    simple.move(y=-height/2)
    simple.difference('_', '_base')
    simple.active_name('base')
    fingers(diameter, tolerance, amount=tile_y_amount, stem=stem)
    simple.rename('base', '_base')
    simple.remove_doubles()
    simple.rename('fingers', '_fingers')
    simple.rotate(math.pi/2)
    simple.move(x=-width/2)
    simple.union('_')
    simple.active_name('_base')
    simple.rename('receptacle', '_receptacle')
    simple.rotate(math.pi/2)
    simple.move(x=width/2)
    simple.difference('_', '_base')
    simple.active_name('tile_ ' + str(tile_x_amount) + '_' + str(tile_y_amount))
示例#6
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def open_curve(line, thick, diameter, tolerance, amount=0, stem=1, twist=False, t_neck=0.5, t_thick=0.01,
               twist_amount=1, which='MF', twist_keep=False):
    # puts puzzle connectors at the end of an open curve
    # optionally puts twist lock connectors at the puzzle connection
    # optionally puts twist lock connectors along the open curve
    # line = shapely linestring
    # thick = thickness of the bar
    # diameter = diameter of the tool for joint creation
    # tolerance = Tolerance in the joint
    # amount = amount of fingers in the joint 0 means auto generate
    # stem = amount of radius the stem or neck of the joint will have
    # twist = twist lock addition
    # twist_amount = twist amount distributed on the curve not counting the joint twist locks
    # tneck = percentage the twist neck will have compared to thick
    # tthick = thicknest of the twist material
    # Which M,F, MF, MM, FF

    coords = list(line.coords)

    start_angle = joinery.angle(coords[0], coords[1]) + math.pi/2
    end_angle = joinery.angle(coords[-1], coords[-2]) + math.pi/2
    p_start = coords[0]
    p_end = coords[-1]

    print('start angle', start_angle)
    print('end angle', end_angle)

    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=thick*2, Simple_length=thick * 2, use_cyclic_u=True, edit_mode=False, shape='3D')
    simple.active_name('tmprect')
    simple.move(y=thick)
    simple.duplicate()
    simple.rotate(start_angle)
    simple.move(x=p_start[0], y=p_start[1])
    simple.make_active('tmprect')
    simple.rotate(end_angle)
    simple.move(x=p_end[0], y=p_end[1])
    simple.union('tmprect')
    dilated = line.buffer(thick/2)  # expand shapely object to thickness
    utils.shapelyToCurve('tmp_curve', dilated, 0.0)
    simple.difference('tmp', 'tmp_curve')   # truncate curve at both ends with the rectangles

    fingers(diameter, tolerance, amount, stem=stem)
    simple.make_active('fingers')
    simple.rotate(end_angle)
    simple.move(x=p_end[0], y=p_end[1])
    simple.active_name('tmp_fingers')
    simple.union('tmp_')
    simple.active_name('tmp_curve')
    twistm('tmp_curve', thick, diameter, tolerance, twist, t_neck, t_thick, end_angle, x=p_end[0], y=p_end[1],
           twist_keep=twist_keep)

    twistf('receptacle', thick, diameter, tolerance, twist, t_neck, t_thick, twist_keep=twist_keep)
    simple.rename('receptacle', 'tmp')
    simple.rotate(start_angle+math.pi)
    simple.move(x=p_start[0], y=p_start[1])
    simple.difference('tmp', 'tmp_curve')
    if twist_keep:
        simple.make_active('twist_keep_f')
        simple.rotate(start_angle + math.pi)
        simple.move(x=p_start[0], y=p_start[1])

    if twist_amount > 0 and twist:
        twist_start = line.length / (twist_amount+1)
        joinery.distributed_interlock(line, line.length, thick, t_thick, tolerance, twist_amount,
                                      tangent=math.pi/2, fixed_angle=0, start=twist_start, end=twist_start,
                                      closed=False, type='TWIST', twist_percentage=t_neck)
        if twist_keep:
            simple.duplicate()
            simple.active_name('twist_keep')
            simple.join_multiple('twist_keep')
            simple.make_active('interlock')

        simple.active_name('tmp_twist')
        simple.difference('tmp', 'tmp_curve')
        simple.active_name('puzzle_curve')
示例#7
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def mitre(length, thick, angle, angleb, diameter, tolerance, amount=0, stem=1, twist=False,
          tneck=0.5, tthick=0.01, which='MF'):
    # length is the total width of the segments including 2 * radius and thick
    # radius = radius of the curve
    # thick = thickness of the bar
    # angle = angle of the female part
    # angleb = angle of the male part
    # diameter = diameter of the tool for joint creation
    # tolerance = Tolerance in the joint
    # amount = amount of fingers in the joint 0 means auto generate
    # stem = amount of radius the stem or neck of the joint will have
    # twist = twist lock addition
    # tneck = percentage the twist neck will have compared to thick
    # tthick = thicknest of the twist material
    # which = which joint to generate, Male Female MaleFemale M, F, MF

    # generate base rectangle
    bpy.ops.curve.simple(align='WORLD', location=(0, -thick / 2, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=length * 1.005 + 4 * thick, Simple_length=thick, use_cyclic_u=True,
                         edit_mode=False,
                         shape='3D')
    simple.active_name("tmprect")

    # generate cutout shapes
    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=4 * thick, Simple_length=6 * thick, use_cyclic_u=True, edit_mode=False,
                         shape='3D')
    simple.move(x=2 * thick)
    simple.rotate(angle)
    simple.move(x=length / 2)
    simple.active_name('tmpmitreright')

    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Rectangle',
                         Simple_width=4 * thick, Simple_length=6 * thick, use_cyclic_u=True, edit_mode=False,
                         shape='3D')
    simple.move(x=2 * thick)
    simple.rotate(angleb)
    simple.move(x=length / 2)
    simple.mirrorx()
    simple.active_name('tmpmitreleft')
    simple.difference('tmp', 'tmprect')
    simple.make_active('tmprect')

    fingers(diameter, tolerance, amount, stem=stem)

    #  Generate male section and join to the base
    if which == 'M' or which == 'MF':
        simple.make_active('fingers')
        simple.duplicate()
        simple.active_name('tmpfingers')
        simple.rotate(angle - math.pi / 2)
        h = thick / math.cos(angle)
        h /= 2
        simple.move(x=length / 2 + h * math.sin(angle), y=-thick / 2)
        if which == 'M':
            simple.rename('fingers', 'tmpfingers')
            simple.rotate(angleb - math.pi / 2)
            h = thick / math.cos(angleb)
            h /= 2
            simple.move(x=length / 2 + h * math.sin(angleb), y=-thick / 2)
            simple.mirrorx()

        simple.union('tmp')
        simple.active_name('tmprect')

    # Generate female section and join to base
    if which == 'MF' or which == 'F':
        simple.make_active('receptacle')
        simple.mirrory()
        simple.duplicate()
        simple.active_name('tmpreceptacle')
        simple.rotate(angleb - math.pi / 2)
        h = thick / math.cos(angleb)
        h /= 2
        simple.move(x=length / 2 + h * math.sin(angleb), y=-thick / 2)
        simple.mirrorx()
        if which == 'F':
            simple.rename('receptacle', 'tmpreceptacle2')
            simple.rotate(angle - math.pi / 2)
            h = thick / math.cos(angle)
            h /= 2
            simple.move(x=length / 2 + h * math.sin(angle), y=-thick / 2)
        simple.difference('tmp', 'tmprect')

    simple.remove_multiple('receptacle')
    simple.remove_multiple('fingers')
    simple.rename('tmprect', 'mitre')
示例#8
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def arc(radius, thick, angle, diameter, tolerance, amount=0, stem=1, twist=False, tneck=0.5, tthick=0.01,
        twist_keep=False, which='MF'):
    # radius = radius of the curve
    # thick = thickness of the bar
    # angle = angle of the arc
    # diameter = diameter of the tool for joint creation
    # tolerance = Tolerance in the joint
    # amount = amount of fingers in the joint 0 means auto generate
    # stem = amount of radius the stem or neck of the joint will have
    # twist = twist lock addition
    # tneck = percentage the twist neck will have compared to thick
    # tthick = thicknest of the twist material
    # which = which joint to generate, Male Female MaleFemale M, F, MF

    global DT  # diameter tolerance for diameter of finger creation

    if angle == 0:  # angle cannot be 0
        angle = 0.01

    negative = False
    if angle < 0:  # if angle < 0 then negative is true
        angle = -angle
        negative = True

    if amount == 0:
        amount = round(thick / ((4 + 2 * (stem - 1)) * diameter * DT)) - 1

    fingers(diameter, tolerance, amount, stem=stem)
    twistf('receptacle', thick, diameter, tolerance, twist, tneck, tthick, twist_keep=twist_keep)

    # generate arc
    bpy.ops.curve.simple(align='WORLD', location=(0, 0, 0), rotation=(0, 0, 0), Simple_Type='Segment',
                         Simple_a=radius - thick / 2,
                         Simple_b=radius + thick / 2, Simple_startangle=-0.0001, Simple_endangle=math.degrees(angle),
                         Simple_radius=radius, use_cyclic_u=False, edit_mode=False)
    bpy.context.active_object.name = "tmparc"

    simple.rename('fingers', '_tmpfingers')

    simple.rotate(math.pi)
    simple.move(x=radius)
    bpy.ops.object.origin_set(type='ORIGIN_CURSOR', center='MEDIAN')

    simple.rename('tmparc', '_tmparc')
    if which == 'MF' or which == 'M':
        simple.union('_tmp')
        simple.active_name("base")
        twistm('base', thick, diameter, tolerance, twist, tneck, tthick, math.pi, x=radius)
        simple.rename('base', '_tmparc')

    simple.rename('receptacle', '_tmpreceptacle')
    simple.mirrory()
    simple.move(x=radius)
    bpy.ops.object.origin_set(type='ORIGIN_CURSOR', center='MEDIAN')
    simple.rotate(angle)
    simple.make_active('_tmparc')

    if which == 'MF' or which == 'F':
        simple.difference('_tmp', '_tmparc')
    bpy.context.active_object.name = "PUZZLE_arc"
    bpy.ops.object.curve_remove_doubles()
    simple.remove_multiple("_")  # Remove temporary base and holes
    simple.make_active('PUZZLE_arc')
    if which == 'M':
        simple.rotate(-angle)
        simple.mirrory()
        bpy.ops.object.transform_apply(location=True, rotation=True, scale=False)
        simple.rotate(-math.pi / 2)
        simple.move(y=radius)
        simple.rename('PUZZLE_arc', 'PUZZLE_arc_male')
    elif which == 'F':
        simple.mirrorx()
        simple.move(x=radius)
        simple.rotate(math.pi / 2)
        simple.rename('PUZZLE_arc', 'PUZZLE_arc_receptacle')
    else:
        simple.move(x=-radius)
    # bpy.ops.object.transform_apply(location=True, rotation=False, scale=False, properties=False)
    #
    if negative:  # mirror if angle is negative
        simple.mirrory()