mirror of
https://github.com/kennetek/gridfinity-rebuilt-openscad.git
synced 2024-11-14 04:20:51 +00:00
316 lines
9.4 KiB
OpenSCAD
316 lines
9.4 KiB
OpenSCAD
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$fa = 5;
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$fs = 0.25;
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// ===== Parameters =====
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gridx = 2; // number of bases along x-axis
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gridy = 2; // number of bases along y-axis
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gridz = 3; // unit height along z-axis (2, 3, or 6, but can be anything)
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n_div = 2; // number of compartments (ideally, coprime w/ gridx)
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// set n_div to 0 for a solid bin (for custom bins)
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length = 42; // base unit (if you want to go rogue ig)
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// type of tab style. alignment only matters if tabs are large enough
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// 0:full, 1:automatic, 2:right, 3:center, 4:left, 5:none
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style_tab = 0;
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enable_scoop = true; // the rounded edge that allows for easy removal
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enable_holes = true; // holes on the base for magnet / screw
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enable_holeslit = true; // extra cut within holes for better slicing
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// ===== Info =====
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// the red plane that is the top of the internal bin is d_height+h_base above z=0
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// 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
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// the magnet holes have an extra cut in them to make it easier to print without supports
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// ===== Dimensions =====
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// base
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h_base = 5; // height of the base
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r_base = 4; // outside rounded radius of bin
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r_c1 = 0.8; // lower base chamfer "radius"
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r_c2 = 2.4; // upper base chamfer "radius"
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h_bot = 2.2; // bottom thiccness of bin
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// base holes
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r_hole1 = 1.5; // screw hole radius
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r_hole2 = 3.25; // magnet hole radius
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d_hole = 26; // center-to-center distance between holes
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h_hole = 2.4; // magnet hole depth
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// fillets
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r_f1 = 0.6; // top edge fillet radius
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r_f2 = 2.8; // internal fillet radius
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r_f3 = 0.6; // lip fillet radius
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// misc
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d_div = 1.2; // width of divider between compartments
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d_wall = 0.95; // minimum wall thickness
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d_clear = 0.25; // tolerance fit factor
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// tabs
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d_tabh = 15.85; // height of tab (yaxis, measured from inner wall)
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d_tabw = length; // maximum width of tab
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a_tab = 32;
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// calculations
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d_height = (gridz-1)*7 + 2;
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r_scoop = length*gridz/12; // scoop radius
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d_wall2 = r_base-r_c1-d_clear*sqrt(2);
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d_width = (gridx*length-2*d_wall-(n_div-1)*d_div)/n_div;
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b_notab = style_tab == 5 || gridz < 3;
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// magic numbers (cutter parameters)
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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, r_f2];
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v_edg = [r_f2, 0, d_height-h_bot-d_wall2, d_wall2-d_wall, d_height-h_bot-d_wall, 90, 45];
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v_slo = [r_scoop, 0, 2*d_height, 0, 0, 30, 10];
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gridfinity();
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// ===== Modules =====
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module gridfinity() {
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difference() {
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// solid bin
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block_bottom(d_height);
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// subtraction blocks
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block_cutter();
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}
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block_base();
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block_wall();
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}
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module profile_base() {
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polygon([
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[0,0],
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[0,h_base],
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[r_base,h_base],
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[r_base-r_c2,h_base-r_c2],
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[r_base-r_c2,r_c1],
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[r_base-r_c2-r_c1,0]
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]);
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}
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module block_base() {
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color("orange")
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pattern_linear(gridx, gridy, length)
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render() union() {
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sweep_rounded(length-2*r_base,length-2*r_base) profile_base();
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pattern_circular(4) difference() {
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linear_extrude(h_base) square(length/2-r_base);
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if (enable_holes)
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translate([d_hole/2, d_hole/2, 0]) union() {
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cylinder(h = 3*h_base, r = r_hole1, center=true);
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cylinder(h = 2*h_hole, r = r_hole2, center=true);
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if (enable_holeslit) intersection() {
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cylinder(h = 2*(h_hole+0.2), r = r_hole2, center=true);
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cube([r_hole1*2,r_hole2*3,2*(h_hole+0.4)], center=true);
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}
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}
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}
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}
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}
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module profile_wall_sub() {
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difference() {
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polygon([
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[0,0],
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[d_wall/2,0],
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[d_wall/2,d_height-d_wall2-d_wall/2],
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[d_wall2,d_height-d_wall],
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[d_wall2,d_height+h_base],
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[0,d_height+h_base]
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]);
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offset(delta = 0.25)
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translate([r_base,d_height,0])
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mirror([1,0,0])
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profile_base();
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}
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}
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module profile_wall() {
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translate([r_base,0,0])
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mirror([1,0,0])
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difference() {
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profile_wall_sub();
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difference() {
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translate([0, d_height+h_base-d_clear*sqrt(2), 0])
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circle(r_base/2);
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offset(r = r_f1)
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offset(delta = -r_f1)
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profile_wall_sub();
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}
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}
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}
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module block_wall() {
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color("royalblue")
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translate([0,0,h_base])
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sweep_rounded(gridx*length-2*r_base, gridy*length-2*r_base)
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profile_wall();
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}
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module block_bottom( h = 2.2 ) {
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color("firebrick")
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translate([0,0,h_base])
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hull()
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sweep_rounded(gridx*length-2*r_base, gridy*length-2*r_base)
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translate([r_base-0.1,0,0])
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mirror([1,0,0])
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square([d_wall, d_height]);
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}
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module profile_cutter(r = 0, width = 1, stretch = 0) {
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extent = width/2-r_f2+0.1;
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translate([r-r_f2,0,0])
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union() {
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difference() {
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union() {
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translate([0,extent,0]) circle(r=r_f2);
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square([r_f2,extent]);
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}
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translate([-r_f2,0,0]) square([r_f2,extent+r_f2]);
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}
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mirror([1,0,0]) square([stretch,extent+r_f2]);
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}
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}
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module part_bend(t=[0,0], rot, ang, rad, width, s = 0) {
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translate([t.x,t.y,0])
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rotate([0,0,rot])
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rotate_extrude(angle = ang, convexity = 4)
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profile_cutter(rad,width,s);
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}
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module part_line(t=[0,0], rot, d, width, s = 0) {
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translate([t.x,t.y,0])
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rotate([90,0,rot])
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translate([r_f2,0,0])
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linear_extrude(d)
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profile_cutter(0,width,s);
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}
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module cutter_main(arr, width, offset = 0) {
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r1 = arr[0];
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r2 = arr[1];
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a_end = arr[5];
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a_slo = arr[6];
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p_y3 = arr[2] - r1*tan((90-a_slo)/2);
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p_x4 = arr[3];
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p_y4 = arr[4];
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d_width = width;
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d_extent = gridy*length/2 - d_wall + 0.1;
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l_angle = ([p_x4-r1,p_y4-p_y3] * [[cos(a_slo), -sin(a_slo)], [sin(a_slo), cos(a_slo)]])[0];
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translate([0,gridy*length/2-d_wall,h_base+h_bot])
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rotate([90,0,-90])
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union()
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copy_mirror([0,0,1])
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translate([offset,0,-0.1]) {
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// outside of hull because of its concave geometry
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if (p_x4 != 0 || p_y4 != 0) difference()
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{
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union() {
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render() part_bend([p_x4, p_y4], a_slo+90, a_end-a_slo, -r2, d_width, 2*r_f2);
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part_line([p_x4, p_y4]+(r_f2+r2)*ta(a_end-90)-0.1*ta(a_end), a_end+90, d_extent, d_width, 2*r_f2);
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part_line([r1, p_y3]+(r1-r_f2)*-ta(-a_slo)+l_angle*ta(a_slo), a_slo+90, l_angle, d_width, 2*r_f2);
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}
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copy_mirror([0,1,0]) translate([0,-0.1,-0.1]) cube([d_extent+0.1,r_f2,d_width]);
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}
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hull()
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{
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// left bottom, angle, and scoop fillets
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part_bend([r1, r1], -180, 90, r1, d_width);
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part_bend([r1, p_y3], 90+a_slo, 90-a_slo, r1, d_width);
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// bottom, left, right, angle (thin), angle (thicc)
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part_line([d_extent, r_f2], -90, d_extent - r1, d_width);
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part_line([r_f2, r1], 180, p_y3 - r1, d_width);
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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_width);
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}
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}
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}
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module cutter_tab(s = 1) {
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d_divw = (gridx*length-2*d_wall-(n_div-1)*d_div)/n_div;
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if ((d_divw > d_tabw && s != 0 && d_divw - d_tabw > 4*r_f2 ) || s == 5) {
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d_w = (d_divw - (s==5?0:length)) / (s==3?2:1);
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mirror([s==2?1:0, 0, 0])
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copy_mirror([s==3?1:0, 0, 0])
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translate([(d_divw-d_w)/2,0,0])
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cutter_main(v_edg, d_w);
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}
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}
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module block_cutter() {
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if (n_div > 0) {
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pattern_linear(n_div, 1, d_width + d_div)
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cutter_main(b_notab ? v_edg : v_tab, d_width);
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if (!b_notab) {
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for (i = [1:n_div])
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translate([((i-1)-(n_div-1)/2)*(d_width + d_div),0,0])
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cutter_tab(style_tab==1?(i==1?4:(i==n_div?2:3)):style_tab);
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}
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mirror([0,1,0])
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for (i = [1:n_div])
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translate(((i-1)-(n_div-1)/2)*(d_width + d_div)*[1,0,0])
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cutter_main(enable_scoop?v_slo:v_edg, d_width, enable_scoop?d_wall2-d_wall : 0);
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}
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}
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// ==== Utilities =====
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ta = function (a) [cos(a), sin(a)];
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module copy_mirror(vec=[0,1,0]) {
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children();
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mirror(vec) children();
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}
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module pattern_linear(x = 1, y = 1, spacing = 0) {
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translate([-(x-1)*spacing/2,-(y-1)*spacing/2,0])
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for (i = [1:x])
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for (j = [1:y])
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translate([(i-1)*spacing,(j-1)*spacing,0])
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children();
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}
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module pattern_circular(n=2) {
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for (i = [1:n])
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rotate(i*360/n)
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children();
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}
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module sweep_rounded(w=10, h=10) {
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union() pattern_circular(2) {
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copy_mirror([1,0,0])
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translate([w/2,h/2,0])
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rotate_extrude(angle = 90, convexity = 4)
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children();
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translate([w/2,0,0])
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rotate([90,0,0])
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linear_extrude(height = h, center = true)
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children();
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rotate([0,0,90])
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translate([h/2,0,0])
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rotate([90,0,0])
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linear_extrude(height = w, center = true)
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children();
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}
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}
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