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Overhaul of cutter objects for optimized rendering

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Old version of cutters had many shared surfaces which caused lag in preview window and caused fast-csg fail to provide speed boosts. Replaced with minkowski function to get the fillets. Benchmark: 5x3x6-5x2 reduced from 8 minutes to 6 seconds. Fixed a small error with the outer size (42mm to 41.5mm) to account for tolerances. Created gifs to illustrate the scripts functions.
This commit is contained in:
kennetek 2022-08-04 01:10:32 -07:00
parent bd828ab050
commit 2a21923f4e
9 changed files with 230 additions and 181 deletions
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.gitignore vendored Normal file
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gridfinity-rebuilt.scad
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// if F5 preview fails due to too many polygons or it is too slow to be usable, multiply both of these values by 10 and do an F6 render. Return back to normal for the final 3D print render. $fa = 8;
$fa = 5;
$fs = 0.25; $fs = 0.25;
// number of bases along x-axis
gridx = 5;
// ===== Parameters ===== // number of bases along y-axis
gridy = 3;
gridx = 2; // number of bases along x-axis // unit height along z-axis (2, 3, or 6, but can be any)
gridy = 2; // number of bases along y-axis gridz = 6;
gridz = 3; // unit height along z-axis (2, 3, or 6, but can be anything)
n_divx = 2; // number of x compartments (ideally, coprime w/ gridx)
n_divy = 2; // number of y compartments (ideally, coprime w/ gridy)
// set n_div values to 0 for a solid bin (for custom bins)
length = 42; // base unit (if you want to go rogue ig) // number of x compartments (ideally, coprime w/ gridx)
n_divx = 5;
// type of tab style. alignment only matters if tabs are large enough // number of y compartments (ideally, coprime w/ gridy)
// 0:full, 1:automatic, 2:right, 3:center, 4:left, 5:none n_divy = 2;
style_tab = 0; // set n_div values to 0 for a solid bin (for custom bins)
enable_scoop = true; // the rounded edge that allows for easy removal // base unit (if you want to go rogue ig)
enable_holes = true; // holes on the base for magnet / screw length = 42;
enable_holeslit = true; // extra cut within holes for better slicing
// type of tab. alignment only matters if tabs are large enough
// tab style. 0:full, 1:automatic, 2:left, 3:center, 4:right, 5:none
style_tab = 1;
// the rounded edge that allows for easy removal
enable_scoop = true;
// holes on the base for magnet / screw
enable_holes = true;
// extra cut within holes for better slicing
enable_hole_slit = true;
// ===== Info ===== // ===== Info =====
// the red plane that is the top of the internal bin is d_height+h_base above z=0
// the tab cutter object causes serious lag in the preview, I think it has something to do with cutting the same surfaces as other cutting objects, but I cannot seem to fix it, apologies // rendering will be better for analyzing the model if fast-csg is enabled. This feature is only available in the nightly build and not the official release of OpenSCAD, but if makes rendering only take a couple seconds. Enable it in Edit > Preferences > Features > fast-csg
// the plane that is the top of the internal bin solid is d_height+h_base above z=0
// the magnet holes have an extra cut in them to make it easier to print without supports // the magnet holes have an extra cut in them to make it easier to print without supports
// tabs will automatically be disabled when gridz is less than 3 // tabs will automatically be disabled when gridz is less than 3, as the tabs take up too much space
// ===== Dimensions ===== // ===== Dimensions =====
// base
h_base = 5; // height of the base h_base = 5; // height of the base
r_base = 4; // outside rounded radius of bin r_base = 4; // outside rounded radius of bin
r_c1 = 0.8; // lower base chamfer "radius" r_c1 = 0.8; // lower base chamfer "radius"
r_c2 = 2.4; // upper base chamfer "radius" r_c2 = 2.4; // upper base chamfer "radius"
h_bot = 2.2; // bottom thiccness of bin h_bot = 2.2; // bottom thiccness of bin
r_fo1 = 7.5; // outside radii
r_fo2 = 3.2;
r_fo3 = 1.6;
// base holes
r_hole1 = 1.5; // screw hole radius r_hole1 = 1.5; // screw hole radius
r_hole2 = 3.25; // magnet hole radius r_hole2 = 3.25; // magnet hole radius
d_hole = 26; // center-to-center distance between holes d_hole = 26; // center-to-center distance between holes
h_hole = 2.4; // magnet hole depth h_hole = 2.4; // magnet hole depth
// fillets
r_f1 = 0.6; // top edge fillet radius r_f1 = 0.6; // top edge fillet radius
r_f2 = 2.8; // internal fillet radius r_f2 = 1.5; // internal fillet radius
r_f3 = 0.6; // lip fillet radius r_f3 = 0.6; // lip fillet radius
// misc
d_div = 1.2; // width of divider between compartments d_div = 1.2; // width of divider between compartments
d_wall = 0.95; // minimum wall thickness d_wall = 0.95; // minimum wall thickness
d_clear = 0.25; // tolerance fit factor d_clear = 0.25; // tolerance fit factor
// tabs
d_tabh = 15.85; // height of tab (yaxis, measured from inner wall) d_tabh = 15.85; // height of tab (yaxis, measured from inner wall)
d_tabw = length; // maximum width of tab d_tabw = length; // maximum width of tab
a_tab = 32; a_tab = 36;
// calculations
d_height = (gridz-1)*7 + 2; d_height = (gridz-1)*7 + 2;
r_scoop = length*gridz/12; // scoop radius r_scoop = enable_scoop ? length*gridz/12 - r_f2 : 0; // scoop radius
d_wall2 = r_base-r_c1-d_clear*sqrt(2); d_wall2 = r_base-r_c1-d_clear*sqrt(2);
d_pitchx = (gridx*length-0.5-2*d_wall-(n_divx-1)*d_div)/n_divx;
d_pitchx = (gridx*length-2*d_wall-(n_divx-1)*d_div)/n_divx; d_pitchy = (gridy*length-0.5-2*d_wall-(n_divy-1)*d_div)/n_divy;
d_pitchy = (gridy*length-2*d_wall-(n_divy-1)*d_div)/n_divy;
b_notab = style_tab == 5 || gridz < 3;
d_planey = d_pitchy/2 - d_div - d_tabh - 0.1;
// magic numbers (cutter parameters)
v_tab = [r_f2, r_f3, d_height-h_bot-(d_tabh-d_wall)*tan(a_tab), d_tabh-d_wall-r_f3/tan(a_tab/2), d_height-h_bot-r_f3, 179, a_tab, -d_planey];
v_edg = [r_f2, 0, d_height-h_bot-d_wall2, d_wall2-d_wall, d_height-h_bot-d_wall, 90, 45, -d_planey];
v_slo = [r_scoop, 0, 2*d_height, 0, 0, 30, 10, d_planey];
v_clr = [r_f2, 0, 2*d_height-h_bot-d_wall2, d_wall2-d_wall, 2*d_height-h_bot-d_wall, 90, 45, -d_planey];
color("tomato")
gridfinity(); gridfinity();
// ===== Modules ===== // ===== Modules =====
module gridfinity() { module gridfinity() {
difference() { difference() {
// solid bin // solid bin
block_bottom(d_height); color("firebrick") block_bottom(d_height);
// subtraction blocks // subtraction blocks
block_cutter(); color("sienna") block_cutter();
} }
block_base();
block_wall(); color("orange") block_base();
color("royalblue") block_wall();
} }
module profile_base() { module profile_base() {
@ -105,20 +107,37 @@ module profile_base() {
} }
module block_base() { module block_base() {
color("orange") translate([0,0,h_base])
rounded_rectangle(gridx*length-0.5+0.002, gridy*length-0.5+0.002, h_bot/1.5, r_fo1/2+0.001);
pattern_linear(gridx, gridy, length) pattern_linear(gridx, gridy, length)
render() union() { render()
sweep_rounded(length-2*r_base,length-2*r_base) profile_base(); difference() {
pattern_circular(4) difference() { translate([0,0,h_base])
linear_extrude(h_base) square(length/2-r_base); mirror([0,0,1])
if (enable_holes) union() {
translate([d_hole/2, d_hole/2, 0]) union() { hull() {
cylinder(h = 3*h_base, r = r_hole1, center=true); rounded_square(length-0.5-2*r_c2-2*r_c1, h_base, r_fo3/2);
cylinder(h = 2*h_hole, r = r_hole2, center=true); rounded_square(length-0.5-2*r_c2, h_base-r_c1, r_fo2/2);
if (enable_holeslit) intersection() { }
cylinder(h = 2*(h_hole+0.2), r = r_hole2, center=true); hull() {
cube([r_hole1*2,r_hole2*3,2*(h_hole+0.4)], center=true); rounded_square(length-0.5-2*r_c2, r_c2, r_fo2/2);
mirror([0,0,1])
rounded_square(length-0.5, h_bot/2, r_fo1/2);
}
}
if (enable_holes)
pattern_circular(4)
translate([d_hole/2, d_hole/2, 0]) {
union() {
difference() {
cylinder(h = 2*(h_hole+(enable_hole_slit?0.2:0)), r = r_hole2, center=true);
if (enable_hole_slit)
copy_mirror([0,1,0])
translate([-1.5*r_hole2,r_hole1+0.1,h_hole])
cube([r_hole2*3,r_hole2*3, 0.4]);
} }
cylinder(h = 3*h_base, r = r_hole1, center=true);
} }
} }
} }
@ -129,15 +148,17 @@ module profile_wall_sub() {
polygon([ polygon([
[0,0], [0,0],
[d_wall/2,0], [d_wall/2,0],
[d_wall/2,d_height-d_wall2-d_wall/2], [d_wall/2,d_height-1.2-d_wall2+d_wall/2],
[d_wall2,d_height-d_wall], [d_wall2,d_height-1.2],
[d_wall2,d_height+h_base], [d_wall2,d_height+h_base],
[0,d_height+h_base] [0,d_height+h_base]
]); ]);
color("red")
offset(delta = 0.25) offset(delta = 0.25)
translate([r_base,d_height,0]) translate([r_base,d_height,0])
mirror([1,0,0]) mirror([1,0,0])
profile_base(); profile_base();
square([d_wall,0.1]);
} }
} }
@ -157,145 +178,171 @@ module profile_wall() {
} }
module block_wall() { module block_wall() {
color("royalblue")
translate([0,0,h_base]) translate([0,0,h_base])
sweep_rounded(gridx*length-2*r_base, gridy*length-2*r_base) sweep_rounded(gridx*length-2*r_base-0.5-0.001, gridy*length-2*r_base-0.5-0.001)
profile_wall(); profile_wall();
} }
module block_bottom( h = 2.2 ) { module block_bottom( h = 2.2 ) {
color("firebrick") translate([0,0,h_base+0.1])
translate([0,0,h_base]) rounded_rectangle(gridx*length-0.5-d_wall/4, gridy*length-0.5-d_wall/4, d_height-0.1, r_base+0.01);
hull()
sweep_rounded(gridx*length-2*r_base, gridy*length-2*r_base)
translate([r_base-0.1,0,0])
mirror([1,0,0])
square([d_wall, d_height]);
}
module profile_cutter(r = 0, width = 1, stretch = 0) {
extent = width/2-r_f2+0.1;
translate([r-r_f2,0,0])
union() {
difference() {
union() {
translate([0,extent,0]) circle(r=r_f2);
square([r_f2,extent]);
}
translate([-r_f2,0,0]) square([r_f2,extent+r_f2]);
}
mirror([1,0,0]) square([stretch,extent+r_f2]);
}
}
module part_bend(t=[0,0], rot, ang, rad, width, s = 0) {
translate([t.x,t.y,0])
rotate([0,0,rot])
rotate_extrude(angle = ang, convexity = 4)
profile_cutter(rad,width,s);
}
module part_line(t=[0,0], rot, d, width, s = 0) {
translate([t.x,t.y,0])
rotate([90,0,rot])
translate([r_f2,0,0])
linear_extrude(d)
profile_cutter(0,width,s);
}
module cutter_main(arr, width, off_back = 0, off_front = 0) {
r1 = arr[0];
r2 = arr[1];
a_end = arr[5];
a_slo = arr[6];
p_y3 = arr[2] - r1*tan((90-a_slo)/2);
p_x4 = arr[3];
p_y4 = arr[4];
d_pitchx = width;
d_extent = (gridy*length-2*d_wall-(n_divy-1)*d_div)/(2*n_divy)+0.1+off_front;
assert(p_x4 < d_extent, "IMPOSSIBLE GEOMETRY: COMPARTMENT Y LENGTH IS TOO SMALL, TRY DISABLING TABS. OTHERWISE, DECREASE NUMBER OF Y COMPARTMENTS OR INCREASE Y BASE COUNT.");
assert(r1 < d_extent, "IMPOSSIBLE GEOMETRY: COMPARTMENT Y LENGTH IS TOO SMALL, TRY DISABLING SCOOP. OTHERWISE, DECREASE NUMBER OF Y COMPARTMENTS OR INCREASE Y BASE COUNT.");
l_angle = ([p_x4-r1,p_y4-p_y3] * [[cos(a_slo), -sin(a_slo)], [sin(a_slo), cos(a_slo)]])[0];
difference() {
translate([0,d_extent-0.1-off_front,h_base+h_bot])
rotate([90,0,-90])
union()
copy_mirror([0,0,1])
translate([off_back,0,-0.1]) {
// outside of hull because of its concave geometry
if (p_x4 != 0 || p_y4 != 0) difference()
{
union() {
render() part_bend([p_x4, p_y4], a_slo+90, a_end-a_slo, -r2, d_pitchx, 2*r_f2);
part_line([p_x4, p_y4]+(r_f2+r2)*ta(a_end-90)-0.1*ta(a_end), a_end+90, d_extent, d_pitchx, 2*r_f2);
part_line([r1, p_y3]+(r1-r_f2)*-ta(-a_slo)+l_angle*ta(a_slo), a_slo+90, l_angle, d_pitchx, 2*r_f2);
}
copy_mirror([0,1,0]) translate([0,-0.1,-0.1]) cube([d_extent+0.1,r_f2,d_pitchx]);
}
hull()
{
// left bottom, angle, and scoop fillets
part_bend([r1, r1], -180, 90, r1, d_pitchx);
part_bend([r1, p_y3], 90+a_slo, 90-a_slo, r1, d_pitchx);
// bottom, left, right, angle (thin), angle (thicc)
part_line([d_extent, r_f2], -90, d_extent - r1, d_pitchx);
part_line([r_f2, r1], 180, p_y3 - r1, d_pitchx);
part_line([r1, p_y3]+(r1-r_f2)*-ta(-a_slo), a_slo+90, (d_extent-r1+(r1-r_f2)*cos(a_slo))/cos(a_slo), d_pitchx);
}
}
mirror([0,1,0]) translate([-gridx*length/2, 0.1+off_front, h_base]) cube([2*gridx*length, 2*gridy*length, 10*d_height]);
}
}
module cutter_tab(s = 1, values=v_edg) {
if ((d_pitchx > d_tabw && s != 0 && d_pitchx - d_tabw > 4*r_f2 ) || s == 5) {
d_w = (d_pitchx - (s==5?0:length)) / (s==3?2:1);
mirror([s==2?1:0, 0, 0])
copy_mirror([s==3?1:0, 0, 0])
translate([(d_pitchx-d_w)/2,0,0])
cutter_main(values, d_w, 0, -d_planey);
}
} }
module block_cutter() { module block_cutter() {
if (n_divx > 0) { for (j = [1:n_divy])
for (j = [1:n_divy]) translate(-(j-1)*(d_pitchy + d_div)*[0,1,0])
translate(((j-1)-(n_divy-1)/2)*(d_pitchy + d_div)*[0,1,0]) for (i = [1:n_divx])
for (i = [1:n_divx]) translate(((i-1)-(n_divx-1)/2)*(d_pitchx + d_div)*[1,0,0])
translate(((i-1)-(n_divx-1)/2)*(d_pitchx + d_div)*[1,0,0]) translate([0,gridy*length/2-0.25-d_wall,h_base+h_bot])
cutter_main(b_notab ? j==n_divy ? v_edg : v_clr : v_tab, d_pitchx, 0, -d_planey); rotate([90,0,-90])
cutter(i,j);
if (!b_notab) }
for (j = [1:n_divy])
translate(((j-1)-(n_divy-1)/2)*(d_pitchy + d_div)*[0,1,0]) module cutter(i,j) {
for (i = [1:n_divx])
translate(((i-1)-(n_divx-1)/2)*(d_pitchx + d_div)*[1,0,0]) v_len_tab = d_tabh;
cutter_tab(style_tab==1?(i==1?4:(i==n_divx?2:3)):style_tab, j==n_divy ? v_edg : v_clr); v_len_lip = d_wall2-d_wall+1.2;
v_cut_tab = d_tabh - (2*r_f1)/tan(a_tab);
for (j = [1:n_divy]) v_cut_lip = d_wall2-d_wall;
translate(((j-1)-(n_divy-1)/2)*(d_pitchy + d_div)*[0,1,0]) v_ang_tab = a_tab;
for (i = [1:n_divx]) v_ang_lip = 45;
translate(((i-1)-(n_divx-1)/2)*(d_pitchx + d_div)*[1,0,0])
mirror([0,1,0]) enable_tab = style_tab != 5;
cutter_main(enable_scoop?v_slo:j==1?v_edg:v_clr, d_pitchx, enable_scoop?j==1?d_wall2-d_wall:0:0, d_planey); height = d_height;
extent = (enable_scoop && j==n_divy ? d_wall2-d_wall : 0);
tab = ((gridz < 3 || style_tab == 5) && j == 1) ? v_len_lip : v_len_tab;
ang = ((gridz < 3 || style_tab == 5) && j == 1) ? v_ang_lip : v_ang_tab;
cut = ((gridz < 3 || style_tab == 5) && j == 1) ? v_cut_lip : v_cut_tab;
style = (style_tab > 1 && style_tab < 5) ? style_tab-3 : (i == 1 ? -1 : i == n_divx ? 1 : 0);
if (gridz >= 3 && d_pitchx - d_tabw > 4*r_f2) {
if (style_tab != 0 && style_tab != 5 && j == 1)
fillet_cutter(3,"bisque")
transform_tab(style)
translate([d_wall2-d_wall,0])
profile_cutter(height-h_bot, d_pitchy/2);
if (style_tab != 0 && style_tab != 5)
fillet_cutter(2,"indigo")
transform_tab(style)
difference() {
intersection() {
profile_cutter(height-h_bot, d_pitchy-extent);
profile_cutter_tab(height-h_bot, v_len_tab, v_ang_tab);
}
if (j==1) profile_cutter_tab(height-h_bot, v_len_lip, 45);
}
} }
if (!(style_tab == 5 && j != 1))
fillet_cutter(1,"seagreen")
transform_main()
translate([cut,0])
profile_cutter(height-h_bot,d_pitchy/2);
fillet_cutter(0,"hotpink")
transform_main()
difference() {
profile_cutter(height-h_bot, d_pitchy-extent);
if (!((gridz < 3 || style_tab == 5) && j != 1))
profile_cutter_tab(height-h_bot, tab, ang);
if (!enable_scoop && j == n_divy)
translate([d_pitchy-extent,0,0])
mirror([1,0,0])
profile_cutter_tab(height-h_bot, v_len_lip, v_ang_lip);
}
if (!enable_scoop && j == n_divy) {
fillet_cutter(5,"darkslategray")
translate([d_pitchy-(d_wall2-d_wall+2*r_f2)-v_cut_lip,0,0])
transform_main()
profile_cutter(height-h_bot,d_wall2-d_wall+2*r_f2);
}
}
module transform_main() {
translate([0,0,-(d_pitchx-2*r_f2)/2])
linear_extrude(d_pitchx-2*r_f2)
children();
}
module transform_tab(type) {
mirror([0,0,type==1?1:0])
copy_mirror([0,0,-(abs(type)-1)])
translate([0,0,-d_pitchx/2])
translate([0,0,r_f2])
linear_extrude((d_pitchx-length)/(1-(abs(type)-1))-2*r_f2)
children();
}
module fillet_cutter(t = 0, c = "goldenrod") {
color(c)
minkowski() {
children();
sphere(r = r_f2-t/1000);
}
}
module profile_cutter(h, length) {
translate([r_f2,r_f2])
hull() {
if (length-r_scoop-2*r_f2 > 0)
square(0.1);
if (r_scoop < h) {
translate([length-2*r_f2,h-r_f2/2])
mirror([1,1])
square(0.1);
translate([0,h-r_f2/2])
mirror([0,1])
square(0.1);
}
difference() {
translate([length-r_scoop-2*r_f2, r_scoop])
if (r_scoop != 0) {
intersection() {
circle(r_scoop);
mirror([0,1]) square(2*r_scoop);
}
} else mirror([1,0]) square(0.1);
translate([length-r_scoop-2*r_f2,-1])
square([-(length-r_scoop-2*r_f2),2*h]);
translate([0,h])
square([2*length,r_scoop]);
}
}
}
module profile_cutter_tab(h, tab, ang) {
if (tab > 0)
color("blue")
offset(delta = r_f2)
polygon([[0,h],[tab,h],[0,h-tab*tan(ang)]]);
} }
// ==== Utilities ===== // ==== Utilities =====
ta = function (a) [cos(a), sin(a)]; module rounded_rectangle(length, width, height, rad) {
linear_extrude(height)
offset(rad)
offset(-rad)
square([length,width], center = true);
}
module rounded_square(length, height, rad) {
rounded_rectangle(length, length, height, rad);
}
module copy_mirror(vec=[0,1,0]) { module copy_mirror(vec=[0,1,0]) {
children(); children();
mirror(vec) children(); if (vec != [0,0,0])
mirror(vec)
children();
} }
module pattern_linear(x = 1, y = 1, spacing = 0) { module pattern_linear(x = 1, y = 1, spacing = 0) {

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