[project_box] Add support for cutouts

This commit is contained in:
Correl Roush 2022-12-07 10:40:32 -05:00
parent b1af6c8e0f
commit 0250e7662d
2 changed files with 140 additions and 51 deletions

44
garage_door.scad Normal file
View file

@ -0,0 +1,44 @@
use <project_box.scad>
$fn=50;
mode = "all"; // ["case", "lid", "all"]
x = 50;
y = 70;
z = 30;
module cutouts() {
// USB Port (Front)
cutout_front([x,y,z])
translate([10, 5, 0])
square([15,10]);
// Switch (Back)
cutout_back([x,y,z])
translate([10, 5, 0])
square([15,10]);
// Sensor Wires (Right)
cutout_right([x,y,z])
translate([10,5,0])
square([15,10]);
// Something (Left)
cutout_left([x,y,z])
translate([10,5,0])
square([15,10]);
// LEDs (Top)
cutout_top([x,y,z])
translate([10,5,0])
square([15,10]);
}
project_box(x, y,
above=z,
below=10,
mode=mode) {
cutouts();
}
// cutouts();

View file

@ -3,6 +3,10 @@
A parametric box for electronics projects using perforated circuit boards. The
board is held above the bottom of the box by four corner supports, and snaps
into place to hold it snugly while allowing easy removal.
Shapes provided as children will be used as cutouts, translated to the origin
point of the top of the circuit board. Modules are provided for cutting out
two-dimensional shapes from each wall face as well as the lid.
*/
$fn=50;
@ -29,7 +33,6 @@ module _rounded_box(h, w, d, r) {
translate([0 + r,d - r,0])
cylinder(h=h, r=r);
}
}
module corner_post(h, r) {
@ -93,64 +96,106 @@ module project_box(x, y,
lid_height = wall_width; // Replaces most of the top wall
height=board_thickness + above + below + (fit_tolerance * 2) + lid_height;
// lid
if (mode == "all") {
translate([wall_width / 2 + fit_tolerance, wall_width + fit_tolerance, height + wall_width + fit_tolerance]) {
lid(lid_width - (fit_tolerance * 2), lid_depth - (fit_tolerance * 2), lid_height - (fit_tolerance * 2));
}
} else if (mode == "lid") {
// Flip the lid and translate it into place for printing
translate([lid_width - (fit_tolerance * 2),0,lid_height - (fit_tolerance * 2)])
rotate([0, 180, 0])
lid(lid_width - (fit_tolerance * 2), lid_depth - (fit_tolerance * 2), lid_height - (fit_tolerance * 2));
}
// case
if ((mode == "case") || (mode == "all")) {
difference() {
_rounded_box(h=height + (wall_width * 2),
w=width + (wall_width * 2),
d=depth + (wall_width * 2),
r=corner_radius);
translate([wall_width,wall_width,wall_width])
cube([width, depth, height + (wall_width * 2)]);
// lid slot
translate([wall_width / 2, wall_width, height + wall_width + 0.001]) {
lid_base(lid_width, lid_depth, lid_height);
union() {
// hollow shell
difference() {
_rounded_box(h=height + (wall_width * 2),
w=width + (wall_width * 2),
d=depth + (wall_width * 2),
r=corner_radius);
translate([wall_width,wall_width,wall_width])
cube([width, depth, height + (wall_width * 2)]);
// lid slot
translate([wall_width / 2, wall_width, height + wall_width + 0.001]) {
lid_base(lid_width, lid_depth, lid_height);
}
}
// supports
translate([wall_width,wall_width,wall_width]) {
translate([0,0,0])
corner_post(h=below, r=support_radius);
translate([width,0,0])
rotate([0,0,90])
corner_post(h=below, r=support_radius);
translate([0,depth,0])
rotate([0,0,270])
corner_post(h=below, r=support_radius);
translate([width,depth,0])
rotate([0,0,180])
corner_post(h=below, r=support_radius);
}
// locking nubs
translate([wall_width,wall_width,wall_width]) {
nub_size = fit_tolerance * 2;
nub_width = board_y / 4;
nub_height = below + board_thickness + (nub_size/2) + (fit_tolerance*2);
translate([0,board_y / 2 - nub_width / 2,nub_height])
rotate([270,0,0])
cylinder(h=nub_width, r=nub_size/2);
translate([width,board_y / 2 - nub_width / 2,nub_height])
rotate([270,0,0])
cylinder(h=nub_width, r=nub_size/2);
}
if (mode == "all") {
// lid
translate([wall_width / 2 + fit_tolerance, wall_width + fit_tolerance, height + wall_width + fit_tolerance]) {
lid(lid_width - (fit_tolerance * 2), lid_depth - (fit_tolerance * 2), lid_height - (fit_tolerance * 2));
}
}
}
// cutouts
translate([wall_width + fit_tolerance, wall_width + fit_tolerance, wall_width + below])
children();
}
} else if (mode == "lid") {
// Flip the lid and translate it into place for printing
translate([lid_width - (fit_tolerance * 2),0,lid_height - (fit_tolerance * 2)]) {
rotate([0, 180, 0]) {
difference() {
lid(lid_width - (fit_tolerance * 2), lid_depth - (fit_tolerance * 2), lid_height - (fit_tolerance * 2));
translate([wall_width + fit_tolerance, wall_width + fit_tolerance, -0.001])
children();
}
}
}
// supports
translate([wall_width,wall_width,wall_width]) {
translate([0,0,0])
corner_post(h=below, r=support_radius);
translate([width,0,0])
rotate([0,0,90])
corner_post(h=below, r=support_radius);
translate([0,depth,0])
rotate([0,0,270])
corner_post(h=below, r=support_radius);
translate([width,depth,0])
rotate([0,0,180])
corner_post(h=below, r=support_radius);
}
// locking nubs
translate([wall_width,wall_width,wall_width]) {
nub_size = fit_tolerance * 2;
nub_width = board_y / 4;
nub_height = below + board_thickness + (nub_size/2) + (fit_tolerance*2);
translate([0,board_y / 2 - nub_width / 2,nub_height])
rotate([270,0,0])
cylinder(h=nub_width, r=nub_size/2);
translate([width,board_y / 2 - nub_width / 2,nub_height])
rotate([270,0,0])
cylinder(h=nub_width, r=nub_size/2);
}
}
}
module cutout_front(volume) {
rotate([90, 0, 0])
linear_extrude(height=volume.y * 2)
children(0);
}
module cutout_back(volume) {
translate([volume.x,0,0])
rotate([90, 0, 180])
linear_extrude(height=volume.y * 2)
children(0);
}
module cutout_right(volume) {
rotate([90, 0, 90])
linear_extrude(height=volume.x * 2)
children(0);
}
module cutout_left(volume) {
translate([volume.x, volume.y, 0])
rotate([90, 0, 270])
linear_extrude(height=volume.x * 2)
children(0);
}
module cutout_top(volume) {
linear_extrude(height=volume.y * 2)
children(0);
}
project_box(board_x, board_y,
above=clearance_above,
below=clearance_below,