// // NopSCADlib Copyright Chris Palmer 2018 // nop.head@gmail.com // hydraraptor.blogspot.com // // This file is part of NopSCADlib. // // NopSCADlib is free software: you can redistribute it and/or modify it under the terms of the // GNU General Public License as published by the Free Software Foundation, either version 3 of // the License, or (at your option) any later version. // // NopSCADlib is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; // without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. // See the GNU General Public License for more details. // // You should have received a copy of the GNU General Public License along with NopSCADlib. // If not, see . // // //! Heatfit threaded inserts. Can be pushed into thermoplastics using a soldering iron with a conical bit set to 200°C. // include <../utils/core/core.scad> use <../utils/quadrant.scad> use <../utils/thread.scad> function insert_length(type) = type[1]; //! Length function insert_outer_d(type) = type[2]; //! Outer diameter at the top function insert_hole_radius(type) = type[3] / 2; //! Radius of the required hole in the plastic function insert_screw_diameter(type) = type[4]; //! Screw size function insert_barrel_d(type) = type[5]; //! Diameter of the main barrel function insert_ring1_h(type) = type[6]; //! Height of the top and middle rings function insert_ring2_d(type) = type[7]; //! Diameter of the middle ring function insert_ring3_d(type) = type[8]; //! Diameter of the bottom ring function insert_hole_length(type) = round_to_layer(insert_length(type)); module insert(type) { //! Draw specified insert length = insert_length(type); ring1_h = insert_ring1_h(type); chamfer1 = (insert_ring2_d(type) - insert_barrel_d(type)) / 2; chamfer2 = (insert_ring3_d(type) - insert_barrel_d(type)) / 2; ring2_h = ring1_h + chamfer1; gap = (length - ring1_h - ring2_h- chamfer2) / 3; vitamin(str("insert(", type[0], "): Heatfit insert M", insert_screw_diameter(type))); $fn = 64; thread_d = insert_screw_diameter(type); explode(20, offset =[0, 0, -5]) translate_z(eps) vflip() { r1 = thread_d / 2; r2 = insert_barrel_d(type) / 2; r3 = insert_ring3_d(type) / 2; r4 = insert_ring2_d(type) / 2; r5 = insert_outer_d(type) / 2; h1 = ring1_h; h2 = ring1_h + gap; h3 = ring1_h + gap + ring2_h; h4 = ring1_h + gap + ring2_h + gap; color(brass) rotate_extrude() polygon([ [r1, 0], [r1, length], [r2, length], [r3, length - chamfer2], [r3, h4], [r2, h4], [r2, h3], [r4, h3 - chamfer1], [r4, h2], [r2, h2], [r2, h1], [r5, h1], [r5, 0], ]); if(show_threads) female_metric_thread(thread_d, metric_coarse_pitch(thread_d), length, center = false, colour = brass); } } module insert_hole(type, counterbore = 0, horizontal = false) { //! Make a hole to take an insert, ```counterbore``` is the extra length for the screw h = insert_hole_length(type); render(convexity = 2) if(horizontal) { teardrop_plus(r = insert_hole_radius(type), h = 2 * h); if(counterbore) teardrop_plus(r = insert_screw_diameter(type) / 2 + 0.1, h = 2 * (h + counterbore)); } else { poly_cylinder(r = insert_hole_radius(type), h = 2 * h, center = true); if(counterbore) poly_cylinder(r = insert_screw_diameter(type) / 2 + 0.1, h = 2 * (h + counterbore), center = true); } } function insert_boss_radius(type, wall) = corrected_radius(insert_hole_radius(type)) + wall; //! Compute the outer radius of an insert boss module insert_boss(type, z, wall = 2 * extrusion_width) { //! Make a boss to take an insert ir = insert_hole_radius(type); or = corrected_radius(ir) + wall; module shape() hull() poly_ring(or, ir); linear_extrude(height = z) poly_ring(or, ir); linear_extrude(height = z - insert_hole_length(type)) difference() { shape(); poly_circle(insert_screw_diameter(type) / 2 + 0.1); } if(z > insert_hole_length(type) + 2 * layer_height) linear_extrude(height = 2 * layer_height) // cap the end if room shape(); } module insert_lug(insert, wall, counter_bore = 0, extension = 0, corner_r = 0, flying = true) { //! Make a flying insert lug, see [ssr_shroud](#Ssr_shroud) boss_r = insert_boss_radius(insert, wall); boss_h = insert_hole_length(insert); boss_h2 = boss_h + counter_bore; module shape() intersection() { hull() { circle(boss_r); translate([boss_r + extension - eps, 0]) square([eps, 2 * boss_r], center = true); } if(corner_r) translate([boss_r + extension - corner_r, 0]) rotate(-45) quadrant(w = 100, r = corner_r - eps, center = true); } translate_z(-boss_h) linear_extrude(height = boss_h) difference() { shape(); poly_circle(insert_hole_radius(insert)); } // insert boss counter_bore translate_z(-boss_h2) { linear_extrude(height = counter_bore + eps) difference() { shape(); poly_circle(insert_screw_diameter(insert) / 2 + 0.1); } // support cone if(flying) hull() { linear_extrude(height = eps) shape(); translate([boss_r + extension - wall - eps, 0, - (2 * boss_r + extension - wall)]) cube(eps, center = true); } } }