mirror of
https://github.com/DJSundog/NopSCADlib.git
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354 lines
15 KiB
OpenSCAD
354 lines
15 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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//! Powersupplies. Can be a simple cube or can be defined by a list of six faces, each with thickness, holes, cutouts, etc.
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//!
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//! Face order is bottom, top, left, right, front, back.
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//
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include <../core.scad>
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include <../printed/fan_guard.scad>
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use <../utils/maths.scad>
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use <../utils/sector.scad>
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use <../utils/round.scad>
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use <fan.scad>
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use <iec.scad>
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use <rocker.scad>
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function psu_face_holes(type) = type[0]; //! List of screw hole positions
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function psu_face_thickness(type) = type[1]; //! The thickness
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function psu_face_cutouts(type) = type[2]; //! List of polygons to remove
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function psu_face_grill(type) = type[3]; //! Is this face a grill
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function psu_face_fan(type) = type[4]; //! Fan x,y position and type
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function psu_face_iec(type) = type[5]; //! IEC connector x,y, rotation and type
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function psu_face_switch(type) = type[6]; //! Rocker switch x,y, rotation and type
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function psu_face_vents(type) = type[7]; //! Vents array position x,y, rotation, size and corner radius
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function psu_name(type) = type[1]; //! The part name
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function psu_length(type) = type[2]; //! Length
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function psu_width(type) = type[3]; //! Width
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function psu_height(type) = type[4]; //! Height
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function psu_screw(type) = type[5]; //! Screw type
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function psu_screw_hole_radius(type) = type[6]; //! Clearance hole for screw, bigger than normal on ATX
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function atx_psu(type) = type[7]; //! True if an ATX style PSU
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function psu_left_bay(type) = type[8]; //! Bay for terminals
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function psu_right_bay(type) = type[9]; //! Bay for heatsink
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function psu_terminals(type) = type[10]; //! How many terminals and the y offset from the back
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function psu_faces(type) = type[11]; //! List of face descriptions
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function psu_accessories(type) = type[12]; //! Accessories to add to BOM, e.g. mains lead
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function terminal_block_pitch(type) = type[0]; //! Pitch between screws
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function terminal_block_divider(type) = type[1]; //! Width of the dividers
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function terminal_block_height(type) = type[2]; //! Height of the dividers
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function terminal_block_depth(type) = type[3]; //! Total depth
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function terminal_block_height2(type) = type[4]; //! Height under the contacts
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function terminal_block_depth2(type) = type[5]; //! Depth of contact well
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function terminal_block_length(type, ways) = terminal_block_pitch(type) * ways + terminal_block_divider(type); //! Total length of terminal block
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module terminal_block(type, ways) { //! Draw a power supply terminal block
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tl = terminal_block_length(type, ways);
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depth = terminal_block_depth(type);
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depth2 = terminal_block_depth2(type);
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div = terminal_block_divider(type);
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h = terminal_block_height(type);
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h2 = terminal_block_height2(type);
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pitch = terminal_block_pitch(type);
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back_wall = depth - depth2;
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contact_depth = depth2 - back_wall;
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contact_width = pitch - div;
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contact_h = 0.4;
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washer_t = 1.2;
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translate([0, -tl]) {
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color(grey20) {
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cube([depth, tl, h2]);
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translate([depth2, 0])
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cube([depth - depth2, tl, h]);
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for(i = [0 : ways])
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translate([0, i * pitch + div])
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rotate([90, 0, 0])
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linear_extrude(div)
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hull() {
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r = 2;
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square([depth, eps]);
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translate([depth - eps, 0])
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square([eps, h]);
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translate([r, h - r])
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circle4n(r);
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}
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}
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color("silver")
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for(i = [0 : ways - 1]) translate([0, i * pitch + div, h2]) {
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translate([back_wall, 1])
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cube([contact_depth, contact_width - 2, contact_h]);
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translate([back_wall + contact_depth / 2 - contact_width / 2, 0])
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cube([contact_width, contact_width, contact_h + washer_t]);
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translate([back_wall + contact_depth / 2, contact_width / 2, contact_h + washer_t])
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not_on_bom() no_explode()
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screw(M3_pan_screw, 8);
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}
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}
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}
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function psu_face_transform(type, face) = //! Returns a transformation matrix to get to the specified face
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let(l = psu_length(type),
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w = psu_width(type),
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h = psu_height(type),
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f = psu_faces(type)[face],
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left = psu_left_bay(type),
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right = psu_right_bay(type),
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rotations = [[180, 0, 0], [0, 0, 0], [90, 0, -90], [90, 0, 90], [90, 0, 0], [-90, 0, 0]],
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translations = [h / 2, h / 2, l / 2 - left, l / 2 - right, w / 2, w / 2]
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) translate([0, 0, h / 2]) * rotate(rotations[face]) * translate([0, 0, translations[face]]);
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grill_hole = 4.5;
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grill_gap = 1.5;
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module psu_grill(width, height) {
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nx = floor(width / (grill_hole + grill_gap));
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xpitch = width / nx;
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ny = floor(height / ((grill_hole + grill_gap) * cos(30)));
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ypitch = height / ny;
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for(y = [0 : ny - 1], x = [0 : nx - 1 - (y % 2)]) {
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x = -width / 2 + (x + 0.5 + (y % 2) / 2) * xpitch;
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y = -height / 2 + (y + 0.5) * ypitch;
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translate([x, y])
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circle(d = grill_hole);
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}
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}
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function psu_terminal_block_z(type) = psu_face_cutouts(psu_faces(type)[f_left])[0][2].y + psu_height(type) / 2;
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module psu(type) { //! Draw a power supply
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vitamin(str("psu(", type[0], "): PSU ", psu_name(type)));
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for(part = psu_accessories(type))
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vitamin(part);
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l = psu_length(type);
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w = psu_width(type);
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h = psu_height(type);
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faces = psu_faces(type);
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left = psu_left_bay(type);
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right = psu_right_bay(type);
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if(len(faces) < 2)
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translate_z(h / 2)
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color("silver") cube([l, w, h], center = true);
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else {
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for(i = [0 : 1 : len(faces) - 1]) {
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f = faces[i];
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t = psu_face_thickness(f);
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xw = [l, l - left - right, w, w, l, l - left - right][i];
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yw = [w, w, h, h, h, h][i];
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xo = [0, left / 2 - right / 2, 0, 0, 0, left / 2 - right / 2][i];
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fan = psu_face_fan(f);
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iec = psu_face_iec(f);
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switch = psu_face_switch(f);
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vents = psu_face_vents(f);
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multmatrix(psu_face_transform(type, i))
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translate([xo, 0, -t]) {
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color("silver") linear_extrude(t)
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union() {
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difference() {
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square([xw, yw], center = true);
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cutouts = psu_face_cutouts(f);
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if(cutouts)
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for(cutout = cutouts)
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polygon([for(p = cutout) p]);
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for(h = psu_face_holes(f))
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translate(h)
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drill(screw_pilot_hole(psu_screw(type)), 0);
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if(psu_face_grill(f)) {
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mx = 6;
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my1 = i == f_top && psu_face_grill(faces[f_back]) ? 0 : 6;
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my2 = i == f_back && psu_face_grill(faces[f_top]) ? 0 : 6;
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translate([0, (my2 - my1) / 2])
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psu_grill(xw - 2 * mx, yw - my1 - my2);
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}
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if(fan)
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translate([fan.x, fan.y]) intersection() {
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fan_holes(fan.z, h = 0);
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difference() {
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square(inf, true);
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fan_guard(fan.z, thickness = 0, grill = true);
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}
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}
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if(iec)
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translate([iec.x, iec.y])
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rotate(iec.z)
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iec_holes(iec[3], 0);
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if(switch)
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translate([switch.x, switch.y])
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rotate(switch.z)
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rocker_hole(switch[3], 0);
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if(vents)
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for(i = [0 : len(vents) - 1]) {
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// vent is of form: [ [pos.x, pos.y, angle], [size.x, size.y], corner radius ]
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vent = vents[i];
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translate([vent[0].x, vent[0].y])
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rotate(vent[0].z)
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rounded_square(vent[1], vent[2]-eps, center = true);
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}
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}
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}
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not_on_bom() no_explode() {
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if(fan)
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translate([fan.x, fan.y, -fan_depth(fan.z) / 2]) {
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fan(fan.z);
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screw = alternate_screw(hs_cs_cap, fan_screw(fan.z));
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fan_hole_positions(fan.z)
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translate_z(t + eps)
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screw(screw, 8);
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}
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if(iec)
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translate([iec.x, iec.y])
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rotate(iec.z)
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iec_assembly(iec[3], t);
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if(switch)
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translate([switch.x, switch.y, t])
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rotate(switch.z)
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rocker(switch[3]);
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}
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}
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}
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}
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// Special case for lighting type PSUs with teminals at the end
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terminals = psu_terminals(type);
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if(terminals) {
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ft = psu_face_thickness(faces[f_front]);
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bt = psu_face_thickness(faces[f_back]);
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rt = psu_face_thickness(faces[f_right]);
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lt = psu_face_thickness(faces[f_left]);
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cutout = psu_face_cutouts(faces[f_left])[0];
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z = psu_terminal_block_z(type);
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pw = w -ft - bt;
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pl = l - right - rt;
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pcb_thickness = 1.6;
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heatsink_offset = 13.5;
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color("#FCD67E")
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translate([(-right - rt) / 2, (ft - bt) / 2, z - pcb_thickness])
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linear_extrude(pcb_thickness)
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difference() {
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square([pl, pw], center = true);
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translate([-pl / 2, -pw / 2])
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square(16, center = true);
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}
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tab_w = w / 2 + cutout[2].x;
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// if the cutout is too wide, then don't draw earth strap, pillar and screw
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if (tab_w - bt > 0) {
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// earth strap
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color("silver")
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translate([-l / 2, w / 2 - tab_w, z])
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cube([left, tab_w - bt, lt]);
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// Earth pillar and screw
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earth_inset = 4.5;
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earth_d = 5;
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translate([-l / 2 + earth_inset, w / 2 - tab_w / 2]) {
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color("silver")
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cylinder(d = earth_d, h = z - pcb_thickness);
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translate_z(z + lt)
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not_on_bom() no_explode()
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spring_washer(M3_washer)
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screw(M3_pan_screw, 8);
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}
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}
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// terminal block
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tb = terminals[2];
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if(tb)
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translate([-l / 2, w / 2 - terminals.y, z])
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terminal_block(tb, terminals[0]);
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// Heatsink
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//
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heatsink_cutout = psu_face_cutouts(faces[f_right])[0];
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if(right && heatsink_cutout) {
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z_top = heatsink_cutout[1].y + h / 2;
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length = heatsink_cutout[2].x + w / 2 - 1.5;
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color("silver")
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translate([l / 2, -w / 2])
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rotate([90, 0, 180])
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linear_extrude(length) {
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translate([right + rt, z_top])
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rotate(135)
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square([rt, right * sqrt(2)]);
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square([rt, z_top - right]);
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translate([rt, z_top - right])
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sector(rt, 135, 180);
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}
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}
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}
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}
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module psu_screw_positions(type, face = undef) { //! Position children at the screw positions on the preferred mounting face, which can be overridden.
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faces = psu_faces(type);
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f = is_undef(face) ? faces && psu_face_holes(faces[f_bottom]) ? f_bottom
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: f_front
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: face;
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if(len(psu_faces(type)) > f)
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multmatrix(psu_face_transform(type, f))
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for(point = psu_face_holes(psu_faces(type)[f]))
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translate(point)
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children();
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}
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module atx_psu_cutout(type) { //! Cut out for the rear of an ATX
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holes = psu_face_holes(psu_faces(type)[f_front]);
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translate([holes[0].x, -psu_width(type) / 2, psu_height(type) / 2 + holes[0].y])
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rotate([90, 0, 0])
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linear_extrude(100, center = true)
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round(5)
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polygon([ // https://www.techpowerup.com/forums/threads/pc-component-dimensions.157239, tweaked
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[18.7, -13],
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[ 5.7, 0],
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[ 5.7, 54],
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[18.7, 67],
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[127, 67],
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[140, 67 - 13 / tan(52)],
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[140, -5 + 11 / tan(52)],
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[129, -5],
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[81.3, -5],
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[73.3, -13],
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]);
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}
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