// // 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 . // // //! A cover to go over the mains end of a PSU terminal strip to make it safe. //! The stl and assembly must be given a name and parameterless wrappers for the stl and assembly added to the project. // include <../core.scad> use <../vitamins/insert.scad> use <../vitamins/wire.scad> use <../vitamins/psu.scad> use <../utils/round.scad> wall = 1.8; top = 1.5; screw = M3_cap_screw; insert = screw_insert(screw); boss_r = insert_boss_radius(insert, wall); counter_bore = 2; rad = 2; clearance = layer_height; overlap = 6; cable_tie_inset = wall + 4; function psu_shroud_extent(type) = 15 + wall; //! How far it extends beyond the PSU to clear the connections function psu_shroud_depth(type) = //! Outside depth of the shroud psu_left_bay(type) + overlap + psu_shroud_extent(type); function psu_shroud_width(type) = //! Outside width of the shroud let(terminals = psu_terminals(type)) terminals ? let(y = terminals.y, tb = terminals.z) wall + clearance / 2 + y + 3 * terminal_block_pitch(tb) + terminal_block_divider(tb) / 2 + wall / 2 : psu_width(type) + 2 * wall + clearance; function psu_shroud_height(type) = psu_height(type) + top + clearance; //! Outside height function psu_shroud_centre_y(type) = //! Shroud centre relative to PSU centre psu_width(type) / 2 + clearance / 2 + wall - psu_shroud_width(type) / 2; function psu_shroud_pitch(type) = psu_shroud_width(type) - 2 * boss_r - eps; function psu_shroud_screw(type) = screw; //! Screw used to fasten function psu_shroud_cable_pitch(cable_d) = cable_d + 5; //! Pitch between cable entries module psu_shroud_hole_positions(type) //! Place children at the screw hole positions for($side = [-1, 1]) translate([-psu_length(type) / 2 - boss_r - 1, psu_shroud_centre_y(type) + $side * psu_shroud_pitch(type) / 2]) children(); module psu_shroud_cable_positions(type, cable_d, cables = 1) //! Place children at the cable tie positions for(i = [0 : 1 : cables - 1]) translate([-psu_length(type) / 2 - psu_shroud_extent(type) + cable_tie_inset, psu_shroud_centre_y(type) + (i - cables / 2 + 0.5) * psu_shroud_cable_pitch(cable_d)]) children(); module psu_shroud_holes(type, cable_d, cables = 1) { //! Drill the screw and ziptie holes psu_shroud_hole_positions(type) drill(screw_clearance_radius(screw), 0); psu_shroud_cable_positions(type, cable_d, cables) cable_tie_holes(cable_d / 2, h = 0); } module psu_shroud(type, cable_d, name, cables = 1) { //! Generate the STL file for a specified ssr and cable stl(str("psu_shroud_", name)); extent = psu_shroud_extent(type); depth = psu_shroud_depth(type); width = psu_shroud_width(type); height = psu_shroud_height(type); centre_x = -psu_length(type) / 2 - psu_shroud_extent(type) + psu_shroud_depth(type) / 2; centre_y = psu_shroud_centre_y(type); terminal_clearance = 0.5; tb = psu_terminals(type).z; module shape() { difference() { round(or = wall / 2 - eps, ir = 0) difference() { rounded_square([depth, width], rad); rounded_square([depth - 2 * wall, width - 2 * wall], rad - wall); translate([depth / 2, 0]) square([2 * rad, width], center = true); translate([depth / 2, width / 2 - 5]) square([2 * (overlap + terminal_clearance), 10], center = true); } for(i = [0 : 1 : cables - 1]) translate([0, (i - cables / 2 + 0.5) * psu_shroud_cable_pitch(cable_d)]) square([depth + 1, cable_d], center = true); } } // base and sides translate([centre_x, -centre_y]) { rounded_rectangle([depth - eps, width - eps, top], rad, center = false); linear_extrude(height) difference() { shape(); translate([depth / 2, width / 2 - 5]) square([2 * (depth - extent + terminal_clearance), 10], center = true); } linear_extrude(height - terminal_block_height(tb) - psu_terminal_block_z(type) - terminal_clearance) shape(); } // cable slots for(i = [0 : 1 : cables - 1]) translate([centre_x - depth / 2 + wall / 2, -centre_y + (i - cables / 2 + 0.5) * psu_shroud_cable_pitch(cable_d), height / 2]) rotate([90, 0, 90]) linear_extrude(wall, center = true) difference() { square([cable_d + eps, height], center = true); translate([0, height / 2]) vertical_tearslot(h = 0, r = cable_d / 2, l = cable_d); } // insert lugs mirror([0, 1, 0]) psu_shroud_hole_positions(type) translate_z(height) rotate($side * 90) insert_lug(insert, wall, counter_bore); } module psu_shroud_assembly(type, cable_d, name, cables = 1) //! The printed parts with inserts fitted assembly(str("PSU_shroud_", name)) { translate_z(psu_shroud_height(type)) vflip() stl_colour(pp1_colour) psu_shroud(type, cable_d, name, cables); psu_shroud_hole_positions(type) vflip() insert(insert); } module psu_shroud_fastened_assembly(type, cable_d, thickness, name, cables = 1) //! Assembly with screws in place { screw_length = screw_length(screw,thickness + counter_bore, 2, true); psu_shroud_assembly(type, cable_d, name, cables); translate_z(-thickness) psu_shroud_hole_positions(type) vflip() screw_and_washer(screw, screw_length, true); psu_shroud_cable_positions(type, cable_d, cables) cable_tie(cable_d / 2, thickness); }