mirror of
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392 lines
14 KiB
OpenSCAD
392 lines
14 KiB
OpenSCAD
//
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// NopSCADlib Copyright Chris Palmer 2020
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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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//! Housings for PCB cameras.
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//
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include <../core.scad>
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include <../vitamins/cameras.scad>
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use <../vitamins/pcb.scad>
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use <../vitamins/insert.scad>
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wall = 1.75;
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min_wall = 2 * extrusion_width;
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clearance = 0.2;
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connector_size = [23, 6, 2.65]; // Worst case size of flat flex connector
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cam_back_clearance = round_to_layer(1.5); // Clearance for components on the back of the pcb
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cam_back_overlap = 1; // How much the back overlaps the edge of the pcb
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cam_back_wall = min_wall;
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function cam_front_clearance(cam) = round_to_layer(camera_connector_size(cam).z + clearance);
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function cam_back_size(cam) = let(
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pcb = camera_pcb(cam),
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pcb_size = pcb_size(pcb),
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nut = screw_nut(pcb_screw(pcb)),
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holes = [for(h = pcb_holes(pcb)) pcb_coord(pcb, h).x],
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pitch = max(holes) - min(holes),
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length = pitch + 2 * (nut_radius(nut) + min_wall),
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width = pcb_size.y + (length - pcb_size.x) * cos(30)
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) [length, width, wall + max(connector_size.z, cam_back_clearance + nut_trap_depth(nut))];
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function cam_front_size(cam) = cam_back_size(cam) + [ //! Outside dimensions of the case
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2 * (wall + clearance),
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2 * (wall + clearance),
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pcb_thickness(camera_pcb(cam)) + cam_front_clearance(cam) + wall
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];
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hinge_screw = M2_cap_screw;
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hinge_nut = screw_nut(hinge_screw);
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hinge_screw_length = 12;
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hinge_r = nut_trap_radius(hinge_nut) + 3 * extrusion_width;
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hinge_h = wall + nut_trap_depth(hinge_nut);
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hinge_offset = hinge_r + 1;
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bracket_screw = M3_dome_screw;
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function cam_screw_length(cam) = let(
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front = cam_front_size(cam),
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screw = pcb_screw(camera_pcb(cam)),
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nut = screw_nut(screw)
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) screw_length(screw, front.z - nut_trap_depth(nut), 1, nyloc = true);
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function hinge_z(cam) = cam_screw_length(cam) - hinge_r;
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module cam_holes(cam) {
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pcb = camera_pcb(cam);
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lens_y = camera_lens_offset(cam).y;
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two_holes = !!len([for (h = pcb_holes(pcb)) if(abs(pcb_coord(pcb, h).y - lens_y) < 1) true]);
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pcb_screw_positions(pcb) // screw holes
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if($i > 1 || !two_holes)
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children();
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}
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module rpi_camera_focus_ring_stl() { //! Focus ring the glue onto RPI lens
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stl("rpi_camera_focus_ring");
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rad = 15 / 2;
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hole_r1 = 2.5 / 2;
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hole_r2 = 5 / 2;
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thickness = 3;
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flutes = 8;
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angle = 180 / flutes;
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x = rad / (sin(angle / 2) + cos(angle / 2));
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r = x * sin(angle / 2);
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difference() {
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linear_extrude(height = thickness, convexity = 5)
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difference() {
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union() {
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circle(x);
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for(i = [0 : flutes - 1])
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rotate([0, 0, 2 * angle * i])
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translate([x, 0])
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circle(r);
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}
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for(i = [0 : flutes - 1])
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rotate([0, 0, 2 * angle * i + angle])
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translate([x, 0])
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circle(r);
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}
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hull() {
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poly_cylinder(r = hole_r1, h = 0.1, center = true);
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translate([0, 0, thickness])
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poly_cylinder(r = hole_r2, h = 0.1, center = true);
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}
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}
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}
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module camera_back(cam) { //! Make the STL for a camera case back
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stl(str("camera_back_", cam[0]));
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pcb = camera_pcb(cam);
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back = cam_back_size(cam);
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screw = pcb_screw(pcb);
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nut = screw_nut(screw);
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translate_z(back.z)
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hflip()
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difference() {
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translate_z(back.z / 2)
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cube(back, center = true);
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translate([0, -cam_back_overlap])
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cube([pcb_length(pcb) - 2 * cam_back_overlap, pcb_width(pcb), 2 * cam_back_clearance], center = true);
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translate([0, -pcb_width(pcb) / 2])
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cube([connector_size.x + 2 * clearance, 2 * connector_size.y + 1, 2 * round_to_layer(connector_size.z + clearance)], center = true);
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translate_z(back.z)
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cam_holes(cam)
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hflip()
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nut_trap(screw, nut, supported = true);
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}
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}
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module camera_front(cam, hinge = 0) { //! Make the STL for a camera case front
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stl(str("camera_front_", cam[0]));
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front = cam_front_size(cam);
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back = cam_back_size(cam);
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pcb = camera_pcb(cam);
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pcb_size = pcb_size(pcb);
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lens_offset = camera_lens_offset(cam);
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screw = pcb_screw(pcb);
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shelf = front.z - back.z;
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connector_slot = connector_size + 2 * [clearance, 0, layer_height];
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rad = wall;
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led_hole_r = 1;
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led_clearance = [5, 2, 1 * 2];
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res_clearance = [3.5, 2, 1 * 2];
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conn_pos = camera_connector_pos(cam);
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conn = camera_connector_size(cam);
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sensor_length = conn_pos.y + conn.y / 2 - lens_offset.y + clearance;
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module hinge_pos()
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if(!is_undef(hinge))
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rotate(hinge * 90)
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translate([0, (hinge ? front.x * hinge : front.y) / 2 + hinge_offset, hinge_r])
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children();
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difference() {
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union() {
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hull()
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for(x = [-1, 1], y = [-1, 1])
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translate([x * (front.x / 2 - rad), y * (front.y / 2 - rad)])
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hull() { // 3D truncated teardrop gives radiused edges without exceeding 45 degree overhang
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translate_z(front.z - 1)
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cylinder(r = rad, h = 1);
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translate_z(rad)
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sphere(rad);
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cylinder(r = rad * (sqrt(2) - 1), h = eps);
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}
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hinge_pos()
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hull() {
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rotate([-90, 0, -90])
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teardrop(r = hinge_r, h = hinge_h, center = false);
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translate([0, -10, -hinge_r])
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cube([hinge_h, eps, 2 * hinge_r]);
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}
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}
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hinge_pos()
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rotate([90, 0, 90])
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teardrop_plus(r = screw_clearance_radius(hinge_screw), h = 100, center = true);
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translate_z(front.z / 2 + shelf - layer_height) // recess for the back
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cube([back.x + 2 * clearance, back.y + 2 * clearance, front.z], center = true);
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translate_z(front.z / 2 + shelf - pcb_size.z) // recess for PCB
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cube([pcb_size.x + 2 * clearance, pcb_size.y + 2 * clearance, front.z], center = true);
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translate_z(shelf)
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hflip() {
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pcb_component_position(pcb, "smd_led") // clearance for LED
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cube(led_clearance, center = true);
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pcb_component_position(pcb, "smd_res") // clearance for resistor
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cube(res_clearance, center = true);
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}
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translate([conn_pos.x, lens_offset.y + sensor_length / 2, shelf - pcb_size.z]) // clearance for sensor connector
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cube([conn.x + 2 * clearance, sensor_length, 2 * cam_front_clearance(cam)], center = true);
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translate([0, -front.y / 2, shelf + front.z / 2]) // slot for connector
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cube([connector_slot.x, connector_slot.y, front.z], center = true);
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translate_z(cam_back_clearance + layer_height)
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cam_holes(cam)
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rotate(90)
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poly_cylinder(r = screw_clearance_radius(screw), h = 100, center = true);
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translate_z(shelf - pcb_size.z)
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hflip()
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camera_lens(cam, clearance);
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hflip()
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pcb_component_position(pcb, "smd_led")
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rotate(45)
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poly_cylinder(r = led_hole_r, h = 100, center = true); // hole for led
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}
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}
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function bracket_thickness(cam) = max(wall, min(3.5, hinge_z(cam) - hinge_r - 1));
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module camera_bracket_screw_positions(cam) { //! Position children at the bracket screw positions
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r = washer_radius(screw_washer(bracket_screw)) + 0.5;
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wide = bracket_thickness(cam) == wall;
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pitch = wide ? cam_front_size(cam).x / 2 - r : hinge_h + 1 + r;
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for(side = [-1, 1])
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translate([side * pitch, 0])
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children();
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}
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module camera_bracket_position(cam) //! Position children at the bracket position
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translate([0, cam_front_size(cam).y / 2 + hinge_offset])
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children();
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module camera_bracket(cam) { //! Make the STL for the camera bracket
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stl(str("camera_bracket_", cam[0]));
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t = bracket_thickness(cam);
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z = hinge_z(cam);
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translate([hinge_h / 2, 0])
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difference() {
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hull() {
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translate_z(eps / 2)
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cube([hinge_h, 2 * hinge_r, eps], center = true);
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translate_z(z)
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rotate([0, 90, 0])
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cylinder(r = hinge_r, h = hinge_h, center = true);
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}
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translate([hinge_h / 2, 0, z])
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rotate([90, 0, 90])
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nut_trap(hinge_screw, screw_nut(hinge_screw), horizontal = true);
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}
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linear_extrude(t)
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difference() {
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hull()
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camera_bracket_screw_positions(cam)
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circle(washer_radius(screw_washer(bracket_screw)) + 0.5);
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camera_bracket_screw_positions(cam)
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poly_circle(screw_clearance_radius(bracket_screw));
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}
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}
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module camera_assembly(cam, angle = 0) //! Camera case assembly
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assembly(str("camera_", cam[0])) {
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front = cam_front_size(cam);
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screw = pcb_screw(camera_pcb(cam));
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nut = screw_nut(screw);
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screw_length = cam_screw_length(cam);
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hinge_z = hinge_z(cam);
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hinge_pos = [0, front.y / 2 + hinge_offset, -hinge_r];
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camera_bracket_position(cam) {
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nut = screw_nut(hinge_screw);
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stl_colour(pp1_colour) render()
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camera_bracket(cam);
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translate([-hinge_h, 0, hinge_z(cam)])
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rotate([-90, 0, 90]) {
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vflip()
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translate_z(2 * hinge_h - nut_trap_depth(nut))
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nut(nut, true);
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screw_and_washer(hinge_screw, screw_longer_than(2 * hinge_h));
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}
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}
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translate_z(hinge_z(cam) + hinge_r)
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translate(hinge_pos)
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rotate([-angle, 0, 0])
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translate(-hinge_pos) {
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translate_z(cam_back_size(cam).z - front.z)
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camera(cam);
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stl_colour(pp1_colour) render()
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translate_z(-front.z)
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camera_back(cam);
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cam_holes(cam) {
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screw_and_washer(screw, screw_length);
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translate_z(-front.z + nut_trap_depth(nut))
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vflip()
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nut(nut, true);
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}
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*translate(camera_lens_offset(cam))
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translate_z(1.5)
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stl_colour(pp1_colour) render()
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rpi_camera_focus_ring_stl();
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stl_colour(pp2_colour) render()
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hflip()
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camera_front(cam, 0);
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}
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}
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module camera_fastened_assembly(cam, thickness, angle = 0) {
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camera_assembly(cam, angle);
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camera_bracket_position(cam)
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camera_bracket_screw_positions(cam) {
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nut = screw_nut(bracket_screw);
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t = bracket_thickness(cam);
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screw_length = screw_length(bracket_screw, thickness + t, 2, nyloc = true);
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vflip()
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translate_z(thickness)
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screw_and_washer(bracket_screw, screw_length);
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translate_z(t)
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nut_and_washer(nut, true);
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}
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}
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module camera_back_rpi_camera_stl() camera_back(rpi_camera);
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module camera_back_rpi_camera_v1_stl() camera_back(rpi_camera_v1);
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module camera_back_rpi_camera_v2_stl() camera_back(rpi_camera_v2);
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module camera_front_rpi_camera_stl() camera_front(rpi_camera);
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module camera_front_rpi_camera_v1_stl() camera_front(rpi_camera_v1);
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module camera_front_rpi_camera_v2_stl() camera_front(rpi_camera_v2);
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module camera_bracket_rpi_camera_stl() camera_bracket(rpi_camera);
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module camera_bracket_rpi_camera_v1_stl() camera_bracket(rpi_camera_v1);
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module camera_bracket_rpi_camera_v2_stl() camera_bracket(rpi_camera_v2);
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module camera_rpi_camera_assembly() camera_assembly(rpi_camera);
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module camera_rpi_camera_v1_assembly() camera_assembly(rpi_camera_v1);
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module camera_rpi_camera_v2_assembly() camera_assembly(rpi_camera_v2);
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module camera_housing(cam) {
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front = cam_front_size(cam);
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camera_front(cam, 0);
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translate([front.x, 0])
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camera_back(cam);
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translate([-front.x / 2 - 2 - hinge_r, 0])
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rotate(90)
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camera_bracket(cam);
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}
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cam = rpi_camera_v2;
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if($preview)
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camera_fastened_assembly(cam, 3);
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else
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camera_housing(cam);
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