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157ff60e19
The screws test now tests polysinks and has printable sample.
330 lines
13 KiB
OpenSCAD
330 lines
13 KiB
OpenSCAD
//
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// NopSCADlib Copyright Chris Palmer 2018
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// nop.head@gmail.com
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// hydraraptor.blogspot.com
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//
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// This file is part of NopSCADlib.
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//
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// NopSCADlib is free software: you can redistribute it and/or modify it under the terms of the
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// GNU General Public License as published by the Free Software Foundation, either version 3 of
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// the License, or (at your option) any later version.
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//
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// NopSCADlib is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
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// without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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// See the GNU General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License along with NopSCADlib.
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// If not, see <https://www.gnu.org/licenses/>.
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//
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//
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//! Machine screws and wood screws with various head styles.
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//!
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//! For an explanation of ```screw_polysink()``` see <https://hydraraptor.blogspot.com/2020/12/sinkholes.html>.
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//
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include <../utils/core/core.scad>
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use <washer.scad>
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use <nut.scad>
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use <../utils/rounded_cylinder.scad>
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use <../utils/thread.scad>
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include <inserts.scad>
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function screw_head_type(type) = type[2]; //! Head style hs_cap, hs_pan, hs_cs, hs_hex, hs_grub, hs_cs_cap, hs_dome
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function screw_radius(type) = type[3] / 2; //! Nominal radius
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function screw_head_radius(type) = type[4] / 2; //! Head radius
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function screw_head_height(type) = type[5]; //! Head height
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function screw_socket_depth(type) = type[6]; //! Socket or slot depth
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function screw_socket_af(type) = type[7]; //! Socket across flats
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function screw_max_thread(type) = type[8]; //! Maximum thread length
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function screw_washer(type) = type[9]; //! Default washer
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function screw_nut(type) = type[10]; //! Default nut
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function screw_pilot_hole(type) = type[11]; //! Pilot hole radius for wood screws, tap radius for machine screws
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function screw_clearance_radius(type) = type[12]; //! Clearance hole radius
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function screw_nut_radius(type) = screw_nut(type) ? nut_radius(screw_nut(type)) : 0; //! Radius of matching nut
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function screw_boss_diameter(type) = max(washer_diameter(screw_washer(type)) + 1, 2 * (screw_nut_radius(type) + 3 * extrusion_width)); //! Boss big enough for nut trap and washer
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function screw_head_depth(type, d = 0) = //! How far a counter sink head will go into a straight hole diameter d
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screw_head_height(type)
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? 0
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: let(r = screw_radius(type)) screw_head_radius(type) - max(r, d / 2) + r / 5;
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function screw_longer_than(x) = x <= 5 ? 5 : //! Returns shortest screw length longer or equal to x
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x <= 6 ? 6 :
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x <= 8 ? 8 :
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x <= 10 ? 10 :
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x <= 12 ? 12 :
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x <= 16 ? 16 :
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ceil(x / 5) * 5;
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function screw_shorter_than(x) = x >= 20 ? floor(x / 5) * 5 : //! Returns longest screw length shorter than or equal to x
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x >= 16 ? 16 :
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x >= 12 ? 12 :
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x >= 10 ? 10 :
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x >= 8 ? 8 :
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x >= 6 ? 6 :
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5;
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function screw_smaller_than(d) = d >= 2.5 && d < 3 ? 2.5 : floor(d); // Largest diameter screw less than or equal to specified diameter
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function screw_insert(screw, i = 0) = let(d = screw_radius(screw) * 2)
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i >= len(inserts) ? undef
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: insert_screw_diameter(inserts[i]) == d ? inserts[i]
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: screw_insert(screw, i + 1);
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module screw(type, length, hob_point = 0, nylon = false) { //! Draw specified screw, optionally hobbed or nylon
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description = str("Screw ", nylon ? "Nylon " : "", type[1], length < 10 ? " x " : " x ", length, "mm", hob_point ? str(", hobbed at ", hob_point) : "");
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vitamin(str("screw(", type[0], "_screw, ", length, arg(hob_point, 0, "hob_point"), arg(nylon, false, "nylon"), "): ", description));
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head_type = screw_head_type(type);
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rad = screw_radius(type) - eps;
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head_rad = screw_head_radius(type);
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head_height = screw_head_height(type);
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socket_af = screw_socket_af(type);
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socket_depth= screw_socket_depth(type);
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socket_rad = socket_af / cos(30) / 2;
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max_thread = screw_max_thread(type);
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thread = max_thread ? length >= max_thread + 5 ? max_thread
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: length
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: length;
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d = 2 * screw_radius(type);
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pitch = metric_coarse_pitch(d);
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colour = nylon || head_type == hs_grub ? grey(40) : grey(80);
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module shaft(socket = 0, headless = false) {
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point = screw_nut(type) ? 0 : 3 * rad;
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shank = length - thread - socket;
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if(show_threads && !point && pitch)
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translate_z(-length)
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male_metric_thread(d, pitch, thread - (shank > 0 || headless ? 0 : socket), false, top = headless ? -1 : 0, solid = !headless, colour = colour);
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else
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color(colour * 0.9)
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rotate_extrude() {
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translate([0, -length + point])
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square([rad, length - socket - point]);
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if(point)
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polygon([
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[0.4, -length], [0, point - length], [rad, point - length]
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]);
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}
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if(shank > 0)
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color(colour)
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translate_z(-shank - socket)
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cylinder(r = rad + eps, h = shank);
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}
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module cs_head(socket_rad, socket_depth) {
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head_t = rad / 5;
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head_height = head_rad + head_t;
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rotate_extrude()
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difference() {
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polygon([[0, 0], [head_rad, 0], [head_rad, -head_t], [0, -head_height]]);
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translate([0, -socket_depth + eps])
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square([socket_rad, 10]);
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}
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translate_z(-socket_depth)
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linear_extrude(socket_depth)
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difference() {
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circle(socket_rad + 0.1);
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children();
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}
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}
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explode(length + 10) {
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if(head_type == hs_cap) {
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color(colour) {
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cylinder(r = head_rad, h = head_height - socket_depth);
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translate_z(head_height - socket_depth)
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linear_extrude(socket_depth)
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difference() {
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circle(head_rad);
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circle(socket_rad, $fn = 6);
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}
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}
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shaft();
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}
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if(head_type == hs_grub) {
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color(colour) {
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r = show_threads ? rad - pitch / 2 : rad;
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translate_z(-socket_depth)
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linear_extrude(socket_depth)
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difference() {
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circle(r);
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circle(socket_rad, $fn = 6);
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}
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shaft(socket_depth, true);
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if(show_threads)
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translate_z(-length)
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cylinder(r = r, h = length - socket_depth);
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}
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}
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if(head_type == hs_hex) {
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color(colour)
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cylinder(r = head_rad, h = head_height, $fn = 6);
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shaft();
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}
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if(head_type == hs_pan) {
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socket_rad = 0.6 * head_rad;
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socket_depth = 0.5 * head_height;
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socket_width = 1;
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color(colour) {
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rotate_extrude()
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difference() {
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rounded_corner(r = head_rad, h = head_height, r2 = head_height / 2);
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translate([0, head_height - socket_depth])
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square([socket_rad, 10]);
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}
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linear_extrude(head_height)
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difference() {
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circle(socket_rad + eps);
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square([2 * socket_rad, socket_width], center = true);
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square([socket_width, 2 * socket_rad], center = true);
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}
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}
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shaft();
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}
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if(head_type == hs_dome) {
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lift = 0.38;
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h = head_height - lift;
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r = min(2 * head_height, (sqr(head_rad) + sqr(h)) / 2 * h); // Special case for M2
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y = sqrt(sqr(r) - sqr(head_rad));
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color(colour) {
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rotate_extrude() {
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difference() {
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intersection() {
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translate([0, -y + lift])
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circle(r);
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square([head_rad, head_height]);
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}
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translate([0, head_height - socket_depth])
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square([socket_rad, 10]);
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}
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}
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linear_extrude(head_height)
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difference() {
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circle(socket_rad + eps);
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circle(socket_rad, $fn = 6);
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}
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}
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shaft();
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}
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if(head_type == hs_cs) {
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socket_rad = 0.6 * head_rad;
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socket_depth = 0.3 * head_rad;
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socket_width = 1;
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color(colour)
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cs_head(socket_rad, socket_depth) {
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square([2 * socket_rad, socket_width], center = true);
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square([socket_width, 2 * socket_rad], center = true);
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}
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shaft(socket_depth);
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}
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if(head_type == hs_cs_cap) {
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color(colour)
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cs_head(socket_rad, socket_depth)
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circle(socket_rad, $fn = 6);
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shaft(socket_depth);
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}
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}
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}
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module screw_countersink(type, drilled = true) { //! Countersink shape
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head_type = screw_head_type(type);
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head_rad = screw_head_radius(type);
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rad = screw_radius(type);
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head_t = rad / 5;
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head_height = head_rad + head_t;
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if(head_type == hs_cs || head_type == hs_cs_cap)
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translate_z(-head_height)
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if(drilled)
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cylinder(h = head_height + eps, r1 = 0, r2 = head_rad + head_t);
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else
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intersection() {
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cylinder(h = head_height + eps, r1 = 0, r2 = head_rad + head_t);
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cylinder(h = head_height + eps, r = head_rad + eps);
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}
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}
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function screw_polysink_r(type, z) = //! Countersink hole profile corrected for rounded staircase extrusions.
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let(rad = screw_radius(type),
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head_t = rad / 5,
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head_rad = screw_head_radius(type)
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)
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limit(head_rad + head_t - z + (sqrt(2) - 1) * layer_height / 2, screw_clearance_radius(type), head_rad);
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module screw_polysink(type, h = 100, alt = false) { //! A countersink hole made from stacked polyholes for printed parts
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head_depth = screw_head_depth(type);
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assert(head_depth, "Not a countersunk screw");
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layers = ceil(head_depth / layer_height);
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rmin = screw_clearance_radius(type);
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sides = sides(rmin);
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lh = layer_height + eps;
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render(convexity = 5)
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for(side = [0, 1]) mirror([0, 0, side]) {
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for(i = [0 : layers - 1])
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translate_z(i * layer_height) {
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r = screw_polysink_r(type, i * layer_height + layer_height / 2);
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if(alt)
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rotate(i % 2 == layers % 2 ? 180 / sides : 0)
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poly_cylinder(r = r, h = lh, center = false, sides = sides);
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else
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poly_cylinder(r = r, h = lh, center = false);
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}
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translate_z(layers * layer_height)
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poly_cylinder(r = rmin, h = h / 2 - layers * layer_height, center = false);
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}
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}
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module screw_and_washer(type, length, star = false, penny = false) { //! Screw with a washer which can be standard or penny and an optional star washer on top
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washer = screw_washer(type);
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head_type = screw_head_type(type);
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if(head_type != hs_cs && head_type != hs_cs_cap) {
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translate_z(exploded() * 6)
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if(penny)
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penny_washer(washer);
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else
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washer(washer);
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translate_z(washer_thickness(washer)) {
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if(star) {
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translate_z(exploded() * 8)
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star_washer(washer);
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translate_z(washer_thickness(washer))
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screw(type, length);
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}
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else
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screw(type, length);
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}
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}
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else
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translate_z(eps)
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screw(type, length);
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}
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