// // 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 . // // //! Door hinges to hang an acrylic sheet door on a 3D printer, default 6mm thick. //! //! The screws are tapped into the acrylic. //! Rubber door [sealing strip](#sealing_strip) is used to make it airtight and a [door_latch](#door_latch) holds it closed. // include <../core.scad> width = 18; thickness = 4; rad = 3; dia = 12; pin_screw = M3_cap_screw; screw = M3_dome_screw; stat_screw = M4_dome_screw; stat_width = 15; stat_length = 34; stat_clearance = 0.75; function door_hinge_pin_x() = -dia / 2; //! X offset of the hinge pin function door_hinge_pin_y() = -dia / 2 - stat_clearance; //! Y offset of the hinge pin function door_hinge_screw() = screw; //! Screw type used for hinge pin function door_hinge_stat_screw() = stat_screw; //! Screw use to fasten the stationary part function door_hinge_stat_width() = stat_width; //! Width of the stationary part function door_hinge_stat_length() = stat_length; //! Length of the stationary part module door_hinge_hole_positions(dir = 0) { //! Position chidren at the door hole positions hole_pitch = width - 10; for(side = [-1, 1]) translate([width / 2 + side * hole_pitch / 2, -dir * width / 2 -side * hole_pitch / 2]) children(); } module door_hinge(door_thickness) { //! Generates STL for the moving part of the hinge stl(str("door_hinge_", door_thickness)); hole_pitch = width - 10; union() { rotate([90, 0, 0]) linear_extrude(height = width, center = true) difference() { hull() { translate([dia / 2, thickness + door_thickness / 2]) intersection() { rotate(180) teardrop(r = dia / 2, h = 0, truncate = false); square([dia + 1, 2 * thickness + door_thickness], center = true); } square([1, thickness + door_thickness]); } translate([dia / 2, thickness + door_thickness / 2]) teardrop(r = screw_clearance_radius(pin_screw), h = 0); } linear_extrude(height = thickness) difference() { hull() { translate([0, -width / 2]) square([1, width]); for(side = [-1, 1]) translate([-width + rad, side * (width / 2 - rad)]) circle4n(rad); } rotate(180) vflip() door_hinge_hole_positions() poly_circle(screw_clearance_radius(screw)); } } } module door_hinge_6_stl() door_hinge(6); module door_hinge_stat_hole_positions(dir = 0) { //! Position children over the screws holes of the stationary part hole_pitch = dia + (stat_length - dia) / 2; for(side = [-1, 1]) translate([side * hole_pitch / 2, dir * (stat_width / 2 + washer_thickness(screw_washer(pin_screw))), thickness]) children(); } module door_hinge_stat_stl() { //! Generates the STL for the stationary part stl("door_hinge_stat"); union() { linear_extrude(height = thickness) difference() { rounded_square([stat_length, stat_width], rad); door_hinge_stat_hole_positions() poly_circle(screw_clearance_radius(stat_screw)); } rotate([90, 0, 0]) linear_extrude(height = stat_width, center = true) difference() { hull() { translate([0, dia / 2 + stat_clearance]) circle(d = dia); translate([0, 0.5]) square([dia, 1], center = true); } translate([0, dia / 2 + stat_clearance]) teardrop(r = screw_clearance_radius(pin_screw), h = 0); } } } module door_hinge_assembly(top, door_thickness = 6) { //! The moving assembly that goes on the door dir = top ? -1 : 1; pin_x = door_hinge_pin_x(); pin_y = door_hinge_pin_y(); washer = screw_washer(screw); screw_length = screw_shorter_than(thickness + door_thickness + washer_thickness(washer)); translate([0, pin_y - (thickness + door_thickness / 2), dir * width / 2]) { rotate([90, 0, 180]) color(pp2_colour) door_hinge(door_thickness); rotate([90, 0, 0]) door_hinge_hole_positions() screw_and_washer(screw, screw_length); } translate([pin_x, pin_y, top ? 0 : -washer_thickness(screw_washer(pin_screw))]) washer(screw_washer(pin_screw)); translate([pin_x, pin_y, top ? washer_thickness(screw_washer(pin_screw)) + stat_width : width]) screw_and_washer(pin_screw, screw_longer_than(2 * washer_thickness(screw_washer(pin_screw)) + width + stat_width)); } module door_hinge_static_assembly(top, sheet_thickness = 3) { //! The stationary assembly dir = top ? -1 : 1; pin_x = door_hinge_pin_x(); stat_washer = screw_washer(stat_screw); stat_nut = screw_nut(stat_screw); stat_screw_length = screw_longer_than(thickness + sheet_thickness + 2 * washer_thickness(stat_washer) + nut_thickness(stat_nut, true)); translate([pin_x, 0, -dir * (stat_width / 2 + washer_thickness(screw_washer(pin_screw)))]) rotate([90, 0, 0]) { color(pp1_colour) door_hinge_stat_stl(); door_hinge_stat_hole_positions() { screw_and_washer(stat_screw, stat_screw_length); translate_z(-thickness - sheet_thickness) vflip() nut_and_washer(stat_nut, true); } } } module door_hinge_parts_stl() { //! Generates the STL for both parts of the hinge translate([2, width / 2 + 1]) door_hinge_6_stl(); translate([0, -stat_width / 2 - 1]) door_hinge_stat_stl(); }