gridfinity-rebuilt-openscad.../gridfinity-rebuilt-baseplate.scad
Eddie Soller 9b93f5945d use drawer dimensions for assertion
assertion previously used an uninitialized variable to assert either grid count or drawer size were specified.
this change updates the assertion to use the drawer dimension parameters. now a baseplate can be created purely with draw dimensions and without grid counts
2022-12-19 11:26:42 -08:00

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4.2 KiB
OpenSCAD

include <gridfinity-rebuilt-utility.scad>
// ===== INFORMATION ===== //
/*
IMPORTANT: rendering will be better for analyzing the model if fast-csg is enabled. As of writing, this feature is only available in the development builds and not the official release of OpenSCAD, but it makes rendering only take a couple seconds, even for comically large bins. Enable it in Edit > Preferences > Features > fast-csg
https://github.com/kennetek/gridfinity-rebuilt-openscad
*/
// ===== PARAMETERS ===== //
/* [Setup Parameters] */
$fa = 8;
$fs = 0.25;
/* [General Settings] */
// number of bases along x-axis
gridx = 4;
// number of bases along y-axis
gridy = 4;
// base unit
length = 42;
/* [Fit to Drawer] */
// minimum length of baseplate along x (leave zero to ignore, will automatically fill area if gridx is zero)
distancex = 0;
// minimum length of baseplate along y (leave zero to ignore, will automatically fill area if gridy is zero)
distancey = 0;
/* [Styles] */
// baseplate styles
style_plate = 2; // [0: thin, 1:weighted, 2:skeletonized]
// enable magnet hole
enable_magnet = true;
// hole styles
style_hole = 2; // [0:none, 1:contersink, 2:counterbore]
// ===== IMPLEMENTATION ===== //
color("tomato")
gridfinityBaseplate(gridx, gridy, length, distancex, distancey, style_plate, enable_magnet, style_hole);
// ===== CONSTRUCTION ===== //
module gridfinityBaseplate(gridx, gridy, length, dix, diy, sp, sm, sh) {
assert(gridx > 0 || dix > 0, "Must have positive x grid amount!");
assert(gridy > 0 || diy > 0, "Must have positive y grid amount!");
gx = gridx == 0 ? floor(dix/length) : gridx;
gy = gridy == 0 ? floor(diy/length) : gridy;
dx = max(gx*length-0.5, dix);
dy = max(gy*length-0.5, diy);
off = (sp==0?0:sp==1?bp_h_bot:h_skel+(sm?h_hole:0)+(sh==0?0:sh==1?d_cs:h_cb));
difference() {
translate([0,0,h_base])
mirror([0,0,1])
rounded_rectangle(dx, dy, h_base+off, r_base);
gridfinityBase(gx, gy, length, 1, 1, 0, 0.5, false);
translate([0,0,h_base-0.6])
rounded_rectangle(dx*2, dy*2, h_base*2, r_base);
pattern_linear(gx, gy, length) {
if (sm) block_base_hole(1);
if (sp == 1)
translate([0,0,-off])
cutter_weight();
else if (sp == 2)
linear_extrude(10*(h_base+off), center = true)
profile_skeleton();
translate([0,0,-off]) {
if (sh == 1) cutter_countersink();
else if (sh == 2) cutter_counterbore();
}
}
}
}
module cutter_weight() {
union() {
linear_extrude(bp_cut_depth*2,center=true)
square(bp_cut_size, center=true);
pattern_circular(4)
translate([0,10,0])
linear_extrude(bp_rcut_depth*2,center=true)
union() {
square([bp_rcut_width, bp_rcut_length], center=true);
translate([0,bp_rcut_length/2,0])
circle(d=bp_rcut_width);
}
}
}
module cutter_countersink() {
pattern_circular(4)
translate([d_hole/2, d_hole/2, 0]) {
cylinder(r = r_hole1+d_clear, h = 100*h_base, center = true);
translate([0,0,d_cs])
mirror([0,0,1])
hull() {
cylinder(h = d_cs+10, r=r_hole1+d_clear);
translate([0,0,d_cs])
cylinder(h=d_cs+10, r=r_hole1+d_clear+d_cs);
}
}
}
module cutter_counterbore() {
pattern_circular(4)
translate([d_hole/2,d_hole/2,0]) {
cylinder(h=100*h_base, r=r_hole1+d_clear, center=true);
difference() {
cylinder(h = 2*(h_cb+0.2), r=r_cb, center=true);
copy_mirror([0,1,0])
translate([-1.5*r_cb,r_hole1+d_clear+0.1,h_cb-h_slit])
cube([r_cb*3,r_cb*3, 10]);
}
}
}
module profile_skeleton() {
l = length-2*r_c2-2*r_c1;
minkowski() {
difference() {
square([l-2*r_skel+2*d_clear,l-2*r_skel+2*d_clear], center = true);
pattern_circular(4)
translate([d_hole/2,d_hole/2,0])
minkowski() {
square([l,l]);
circle(r_hole2+r_skel+2);
}
}
circle(r_skel);
}
}