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module threadPiece(Xa, Ya, Za, Xb, Yb, Zb, radiusa, radiusb, tipRatioa, tipRatiob, threadAngleTop, threadAngleBottom)
{
angleZ=atan2(Ya, Xa);
twistZ=atan2(Yb, Xb)-atan2(Ya, Xa);
polyPoints=[
[Xa+ radiusa*cos(+angleZ), Ya+ radiusa*sin(+angleZ), Za ],
[Xa+ radiusa*cos(+angleZ), Ya+ radiusa*sin(+angleZ), Za + radiusa*tipRatioa ],
[Xa , Ya , Za+ radiusa*(tipRatioa+sin(threadAngleTop)) ],
[Xa , Ya , Za ],
[Xa , Ya , Za+ radiusa*sin(threadAngleBottom) ],
[Xb+ radiusb*cos(angleZ+twistZ), Yb+ radiusb*sin(angleZ+twistZ), Zb ],
[Xb+ radiusb*cos(angleZ+twistZ), Yb+ radiusb*sin(angleZ+twistZ), Zb+ radiusb*tipRatiob ],
[Xb , Yb , Zb+ radiusb*(tipRatiob+sin(threadAngleTop)) ],
[Xb , Yb , Zb ],
[Xb , Yb , Zb+ radiusb*sin(threadAngleBottom)] ];
polyTriangles=[
[ 0, 1, 6 ], [ 0, 6, 5 ], // tip of profile
[ 1, 7, 6 ], [ 1, 2, 7 ], // upper side of profile
[ 0, 5, 4 ], [ 4, 5, 9 ], // lower side of profile
[ 4, 9, 3 ], [ 9, 8, 3 ], [ 3, 8, 2 ], [ 8, 7, 2 ], // back of profile
[ 0, 4, 3 ], [ 0, 3, 2 ], [ 0, 2, 1 ], // a side of profile
[ 5, 8, 9 ], [ 5, 7, 8 ], [ 5, 6, 7 ] // b side of profile
];
polyhedron( polyPoints, polyTriangles );
}
module shaftPiece(Xa, Ya, Za, Xb, Yb, Zb, radiusa, radiusb, tipRatioa, tipRatiob, threadAngleTop, threadAngleBottom)
{
angleZ=atan2(Ya, Xa);
twistZ=atan2(Yb, Xb)-atan2(Ya, Xa);
threadAngleTop=15;
threadAngleBottom=-15;
shaftRatio=0.5;
polyPoints1=[
[Xa, Ya, Za + radiusa*sin(threadAngleBottom) ],
[Xa, Ya, Za + radiusa*(tipRatioa+sin(threadAngleTop)) ],
[Xa*shaftRatio, Ya*shaftRatio , Za + radiusa*(tipRatioa+sin(threadAngleTop)) ],
[Xa*shaftRatio , Ya*shaftRatio , Za ],
[Xa*shaftRatio , Ya*shaftRatio , Za + radiusa*sin(threadAngleBottom) ],
[Xb, Yb, Zb + radiusb*sin(threadAngleBottom) ],
[Xb, Yb, Zb + radiusb*(tipRatiob+sin(threadAngleTop)) ],
[Xb*shaftRatio , Yb*shaftRatio , Zb + radiusb*(tipRatiob+sin(threadAngleTop)) ],
[Xb*shaftRatio , Yb*shaftRatio , Zb ],
[Xb*shaftRatio , Yb*shaftRatio , Zb + radiusb*sin(threadAngleBottom) ] ];
polyTriangles1=[
[ 0, 1, 6 ], [ 0, 6, 5 ], // tip of profile
[ 1, 7, 6 ], [ 1, 2, 7 ], // upper side of profile
[ 0, 5, 4 ], [ 4, 5, 9 ], // lower side of profile
[ 3, 4, 9 ], [ 9, 8, 3 ], [ 2, 3, 8 ], [ 8, 7, 2 ], // back of profile
[ 0, 4, 3 ], [ 0, 3, 2 ], [ 0, 2, 1 ], // a side of profile
[ 5, 8, 9 ], [ 5, 7, 8 ], [ 5, 6, 7 ] // b side of profile
];
// this is the back of the raised part of the profile
polyhedron( polyPoints1, polyTriangles1 );
}
module trapezoidThread(
length=45, // axial length of the threaded rod
pitch=10, // axial distance from crest to crest
pitchRadius=10, // radial distance from center to mid-profile
threadHeightToPitch=0.5, // ratio between the height of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
profileRatio=0.5, // ratio between the lengths of the raised part of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
threadAngle=30, // angle between the two faces of the thread
// std value for Acme is 29 or for metric lead screw is 30
RH=true, // true/false the thread winds clockwise looking along shaft, i.e.follows the Right Hand Rule
clearance=0.1, // radial clearance, normalized to thread height
backlash=0.1, // axial clearance, normalized to pitch
stepsPerTurn=24 // number of slices to create per turn
)
{
numberTurns=length/pitch;
steps=stepsPerTurn*numberTurns;
trapezoidRatio= 2*profileRatio*(1-backlash);
function threadAngleTop(i)= threadAngle/2;
function threadAngleBottom(i)= -threadAngle/2;
function threadHeight(i)= pitch*threadHeightToPitch;
function pitchRadius(i)= pitchRadius;
function minorRadius(i)= pitchRadius(i)-0.5*threadHeight(i);
function X(i)= minorRadius(i)*cos(i*360*numberTurns);
function Y(i)= minorRadius(i)*sin(i*360*numberTurns);
function Z(i)= pitch*numberTurns*i;
function tip(i)= trapezoidRatio*(1-0.5*sin(threadAngleTop(i))+0.5*sin(threadAngleBottom(i)));
// this is the threaded rod
if (RH==true)
translate([0,0,-threadHeight(0)*sin(threadAngleBottom(0))])
for (i=[0:steps-1])
{
threadPiece(
Xa= X(i/steps),
Ya= Y(i/steps),
Za= Z(i/steps),
Xb= X((i+1)/steps),
Yb= Y((i+1)/steps),
Zb= Z((i+1)/steps),
radiusa= threadHeight(i/steps),
radiusb= threadHeight((i+1)/steps),
tipRatioa= tip(i/steps),
tipRatiob= tip((i+1)/steps),
threadAngleTop= threadAngleTop(i),
threadAngleBottom= threadAngleBottom(i)
);
shaftPiece(
Xa= X(i/steps),
Ya= Y(i/steps),
Za= Z(i/steps),
Xb= X((i+1)/steps),
Yb= Y((i+1)/steps),
Zb= Z((i+1)/steps),
radiusa= threadHeight(i/steps),
radiusb= threadHeight((i+1)/steps),
tipRatioa= tip(i/steps),
tipRatiob= tip((i+1)/steps),
threadAngleTop= threadAngleTop(i),
threadAngleBottom= threadAngleBottom(i)
);
}
if (RH==false)
translate([0,0,-threadHeight(0)*sin(threadAngleBottom(0))])
mirror([0,1,0])
for (i=[0:steps-1])
{
threadPiece(
Xa= X(i/steps),
Ya= Y(i/steps),
Za= Z(i/steps),
Xb= X((i+1)/steps),
Yb= Y((i+1)/steps),
Zb= Z((i+1)/steps),
radiusa= threadHeight(i/steps),
radiusb= threadHeight((i+1)/steps),
tipRatioa= tip(i/steps),
tipRatiob= tip((i+1)/steps),
threadAngleTop= threadAngleTop(i),
threadAngleBottom= threadAngleBottom(i)
);
shaftPiece(
Xa= X(i/steps),
Ya= Y(i/steps),
Za= Z(i/steps),
Xb= X((i+1)/steps),
Yb= Y((i+1)/steps),
Zb= Z((i+1)/steps),
radiusa= threadHeight(i/steps),
radiusb= threadHeight((i+1)/steps),
tipRatioa= tip(i/steps),
tipRatiob= tip((i+1)/steps),
threadAngleTop= threadAngleTop(i),
threadAngleBottom= threadAngleBottom(i)
);
}
rotate([0,0,180/stepsPerTurn])
cylinder(
h=length+threadHeight(1)*(tip(1)+sin( threadAngleTop(1) )-1*sin( threadAngleBottom(1) ) ),
r1=minorRadius(0)-clearance*threadHeight(0),
r2=minorRadius(0)-clearance*threadHeight(0),
$fn=stepsPerTurn
);
}
module trapezoidThreadNegativeSpace(
length=45, // axial length of the threaded rod
pitch=10, // axial distance from crest to crest
pitchRadius=10, // radial distance from center to mid-profile
threadHeightToPitch=0.5, // ratio between the height of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
profileRatio=0.5, // ratio between the lengths of the raised part of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
threadAngle=30, // angle between the two faces of the thread
// std value for Acme is 29 or for metric lead screw is 30
RH=true, // true/false the thread winds clockwise looking along shaft, i.e.follows the Right Hand Rule
countersunk=0, // depth of 45 degree chamfered entries, normalized to pitch
clearance=0.1, // radial clearance, normalized to thread height
backlash=0.1, // axial clearance, normalized to pitch
stepsPerTurn=24 // number of slices to create per turn
)
{
translate([0,0,-countersunk*pitch])
cylinder(
h=2*countersunk*pitch,
r2=pitchRadius+clearance*pitch+0.25*pitch,
r1=pitchRadius+clearance*pitch+0.25*pitch+2*countersunk*pitch,
$fn=24
);
translate([0,0,countersunk*pitch])
translate([0,0,-pitch])
trapezoidThread(
length=length+0.5*pitch, // axial length of the threaded rod
pitch=pitch, // axial distance from crest to crest
pitchRadius=pitchRadius+clearance*pitch, // radial distance from center to mid-profile
threadHeightToPitch=threadHeightToPitch, // ratio between the height of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
profileRatio=profileRatio, // ratio between the lengths of the raised part of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
threadAngle=threadAngle, // angle between the two faces of the thread
// std value for Acme is 29 or for metric lead screw is 30
RH=true, // true/false the thread winds clockwise looking along shaft
// i.e.follows Right Hand Rule
clearance=0, // radial clearance, normalized to thread height
backlash=-backlash, // axial clearance, normalized to pitch
stepsPerTurn=stepsPerTurn // number of slices to create per turn
);
translate([0,0,length-countersunk*pitch])
cylinder(
h=2*countersunk*pitch,
r1=pitchRadius+clearance*pitch+0.25*pitch,
r2=pitchRadius+clearance*pitch+0.25*pitch+2*countersunk*pitch,$fn=24,
$fn=24
);
}
module trapezoidNut(
length=45, // axial length of the threaded rod
radius=25, // outer radius of the nut
pitch=10, // axial distance from crest to crest
pitchRadius=10, // radial distance from center to mid-profile
threadHeightToPitch=0.5, // ratio between the height of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
profileRatio=0.5, // ratio between the lengths of the raised part of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
threadAngle=30, // angle between the two faces of the thread
// std value for Acme is 29 or for metric lead screw is 30
RH=true, // true/false the thread winds clockwise looking along shaft, i.e.follows the Right Hand Rule
countersunk=0, // depth of 45 degree chamfered entries, normalized to pitch
clearance=0.1, // radial clearance, normalized to thread height
backlash=0.1, // axial clearance, normalized to pitch
stepsPerTurn=24 // number of slices to create per turn
)
{
difference()
{
cylinder(
h=length,
r1=radius,
r2=radius,
$fn=6
);
trapezoidThreadNegativeSpace(
length=length, // axial length of the threaded rod
pitch=pitch, // axial distance from crest to crest
pitchRadius=pitchRadius, // radial distance from center to mid-profile
threadHeightToPitch=threadHeightToPitch, // ratio between the height of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
profileRatio=profileRatio, // ratio between the lengths of the raised part of the profile and the pitch
// std value for Acme or metric lead screw is 0.5
threadAngle=threadAngle, // angle between the two faces of the thread
// std value for Acme is 29 or for metric lead screw is 30
RH=true, // true/false the thread winds clockwise looking along shaft
// i.e.follows Right Hand Rule
countersunk=countersunk, // depth of 45 degree countersunk entries, normalized to pitch
clearance=clearance, // radial clearance, normalized to thread height
backlash=backlash, // axial clearance, normalized to pitch
stepsPerTurn=stepsPerTurn // number of slices to create per turn
);
}
}

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display-camera-pi-mount-experiment.stl (Stored with Git LFS)

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@ -8,30 +8,9 @@ $triangle_y_hole_gap = 20;
$triangle_x_offset = 19; $triangle_x_offset = 19;
$triangle_y_offset = 5; $triangle_y_offset = 5;
$fn=10; $fn=200;
use <Thread_Library.scad> screen_mount();
camera_mount();
$camera_mount_thickness = 1;
$camera_screw_gap_y = 25.2;
$camera_screw_diameter = 2.75;
module camera_mount() {
difference() {
cylinder(h=$camera_mount_thickness, d=$camera_screw_gap_y);
translate([0, 0, -0.1])
cylinder(h=3 * $camera_mount_thickness, d=$camera_screw_gap_y - $camera_screw_diameter * 3);
rotate([0, 0, 90])
translate([$camera_screw_gap_y / 2 - $camera_screw_diameter / 1.33, 0, -0.1])
cylinder(h=3 * $camera_mount_thickness, d=$camera_screw_diameter);
rotate([0, 0, -90])
translate([$camera_screw_gap_y / 2 - $camera_screw_diameter / 1.33, 0, -0.1])
cylinder(h=3 * $camera_mount_thickness, d=$camera_screw_diameter);
translate([-1 * $camera_screw_gap_y - $camera_screw_diameter / 1.33, -1 * $camera_screw_gap_y / 2, -0.1])
cube([$camera_screw_gap_y, $camera_screw_gap_y, 3 * $camera_mount_thickness]);
};
}
module attachment_point() { module attachment_point() {
difference() { difference() {

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@ -1,115 +0,0 @@
/**
# Parameters
*/
$box_inner_width = 15;
$box_inner_depth = 6;
$box_inner_height = 15;
$box_wall_thickness = 6;
// [0, 1] Higher the ratio, the bigger the bottom will be.
$box_bottom_top_height_fraction = 0.2;
// [0, 1] The amount the bottom and top will overlap.
$overlap_fraction = 0.8;
// [0, 1] The thickness of the overlap as a fraction of the wall thickness.
$overlap_thickness_fraction = 0.5;
// [1, *] Bottom scale. Scale the bottom up by settings this to a small amount like 1.05 to increase the gap between lid and bottom. Raise this number if the lid is too tight and won't go in, lower it if the lid is too loose.
$bottom_scale = 1.05;
// [0, 1] Screw scale. Lower this number if the screw is too tight and won't go through the hole.
$lid_screw_scale = 0.94;
/**
# Code
*/
include <Thread_Library.scad>;
$fn = $preview ? 12 : 200;
$box_outer_width = $box_inner_width + $box_wall_thickness * 2;
$box_outer_depth = $box_inner_depth + $box_wall_thickness * 2;
$box_outer_height = $box_inner_height + $box_wall_thickness * 2;
$bottom_height = $box_inner_height * $box_bottom_top_height_fraction;
$top_height = $box_inner_height * (1 - $box_bottom_top_height_fraction);
$overlap_height = $box_inner_height * $overlap_fraction;
$overlap_thickness = $box_wall_thickness * $overlap_thickness_fraction;
scale([$lid_screw_scale, $lid_screw_scale, $lid_screw_scale])
translate([0, 0, 5])
rotate([90, 0, 0])
screw();
difference() {
scale([$bottom_scale, $bottom_scale, 1])
bottom();
thread();
};
translate([-10, 0, $bottom_height + $top_height + 2 * $box_wall_thickness])
rotate([0, 180, 0])
difference() {
color("blue")
translate([$box_outer_width, 0, $bottom_height + $top_height + 2 * $box_wall_thickness])
rotate([0, 180, 0])
top();
thread();
};
module top() {
difference() {
box_half($box_inner_width, $box_inner_depth, $top_height, $box_wall_thickness);
translate([-0.002, -0.002, 0])
scale([1.001, 1.001, 1.001])
translate([0, 0, $top_height + $bottom_height + $box_wall_thickness * 2])
color("red")
mirror([0, 0, 1])
bottom();
};
}
module bottom() {
union() {
box_half($box_inner_width, $box_inner_depth, $bottom_height, $box_wall_thickness);
box_half(
$box_inner_width + $box_wall_thickness,
$box_inner_depth + $box_wall_thickness, $overlap_height + $box_wall_thickness,
$overlap_thickness
);
};
};
module box_half($width, $depth, $height, $wall_thickness) {
difference() {
cube([
$width + $wall_thickness * 2,
$depth + $wall_thickness * 2,
$height + $wall_thickness
]);
translate([$wall_thickness, $wall_thickness, $wall_thickness])
cube([$width, $depth, $height + 0.1]);
};
};
$thread_z_offset = $bottom_height + $overlap_height / 2 + 7;
$screw_scale = 0.33;
module thread(length=$box_wall_thickness * (1/$screw_scale)) {
color("pink")
translate([$box_outer_width / 2, $box_wall_thickness + 0.1, $thread_z_offset])
rotate([90, 0, 0])
scale([$screw_scale, $screw_scale, $screw_scale])
trapezoidThread(length=length);
}
module screw() {
color("orange")
translate([$box_outer_width / 2, 0, $thread_z_offset])
rotate([90, 0, 0])
cylinder(h=5, d=15, $fn=6);
color("red")
translate([0, 0, 0])
thread(length=$box_wall_thickness * (1/$screw_scale));
}

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gift-box.stl (Stored with Git LFS)

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