include // ===== 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 the magnet holes can 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, as the tabs take up too much space base functions can be found in "gridfinity-rebuilt-utility.scad" examples at end of file BIN HEIGHT the original gridfinity bins had the overall height defined by 7mm increments a bin would be 7*u millimeters tall the lip at the top of the bin (3.8mm) added onto this height The stock bins have unit heights of 2, 3, and 6: Z unit 2 -> 7*2 + 3.8 -> 17.8mm Z unit 3 -> 7*3 + 3.8 -> 24.8mm Z unit 6 -> 7*6 + 3.8 -> 45.8mm https://github.com/kennetek/gridfinity-rebuilt-openscad */ // ===== PARAMETERS ===== // /* [Setup Parameters] */ $fa = 8; $fs = 0.25; /* [General Settings] */ // number of bases along x-axis gridx = 3; // number of bases along y-axis gridy = 2; // bin height. See bin height information and "gridz_define" below. gridz = 6; /* [Linear Compartments] */ // number of X Divisions (set to zero to have solid bin) divx = 0; // number of Y Divisions (set to zero to have solid bin) divy = 0; /* [Cylindrical Compartments] */ // number of cylindrical X Divisions (mutually exclusive to Linear Compartments) cdivx = 0; // number of cylindrical Y Divisions (mutually exclusive to Linear Compartments) cdivy = 0; // orientation c_orientation = 2; // [0: x direction, 1: y direction, 2: z direction] // diameter of cylindrical cut outs cd = 10; // cylinder height ch = 1; // spacing to lid c_depth = 1; // chamfer around the top rim of the holes c_chamfer = 0.5; /* [Height] */ // determine what the variable "gridz" applies to based on your use case gridz_define = 0; // [0:gridz is the height of bins in units of 7mm increments - Zack's method,1:gridz is the internal height in millimeters, 2:gridz is the overall external height of the bin in millimeters] // overrides internal block height of bin (for solid containers). Leave zero for default height. Units: mm height_internal = 0; // snap gridz height to nearest 7mm increment enable_zsnap = false; /* [Features] */ // the type of tabs style_tab = 1; //[0:Full,1:Auto,2:Left,3:Center,4:Right,5:None] // how should the top lip act style_lip = 0; //[0: Regular lip, 1:remove lip subtractively, 2: remove lip and retain height] // scoop weight percentage. 0 disables scoop, 1 is regular scoop. Any real number will scale the scoop. scoop = 1; //[0:0.1:1] /* [Base] */ // number of divisions per 1 unit of base along the X axis. (default 1, only use integers. 0 means automatically guess the right division) div_base_x = 0; // number of divisions per 1 unit of base along the Y axis. (default 1, only use integers. 0 means automatically guess the right division) div_base_y = 0; /* [Base Hole Options] */ // only cut magnet/screw holes at the corners of the bin to save uneccesary print time only_corners = false; //Use gridfinity refined hole style. Not compatible with magnet_holes! refined_hole = true; // Base will have holes for 6mm Diameter x 2mm high magnets. magnet_holes = false; // Base will have holes for M3 screws. screw_holes = false; // Magnet holes will have crush ribs to hold the magnet. crush_ribs = false; // Magnet holes will have a chamfer to ease insertion. chamfer_magnet_holes = false; chamfer_magnet_holes = true; // Screw holes and magnet holes will be printed so supports are not needed. printable_hole_top = true; hole_options = bundle_hole_options(refined_hole, magnet_holes, screw_holes, crush_ribs, chamfer_magnet_holes, printable_hole_top); // ===== IMPLEMENTATION ===== // color("tomato") { gridfinityInit(gridx, gridy, height(gridz, gridz_define, style_lip, enable_zsnap), height_internal, sl=style_lip) { if (divx > 0 && divy > 0) { cutEqual(n_divx = divx, n_divy = divy, style_tab = style_tab, scoop_weight = scoop); } else if (cdivx > 0 && cdivy > 0) { cutCylinders(n_divx=cdivx, n_divy=cdivy, cylinder_diameter=cd, cylinder_height=ch, coutout_depth=c_depth, orientation=c_orientation, chamfer=c_chamfer); } } gridfinityBase(gridx, gridy, l_grid, div_base_x, div_base_y, hole_options, only_corners=only_corners); } // ===== EXAMPLES ===== // // 3x3 even spaced grid /* gridfinityInit(3, 3, height(6), 0, 42) { cutEqual(n_divx = 3, n_divy = 3, style_tab = 0, scoop_weight = 0); } gridfinityBase(3, 3, 42, 0, 0, 1); */ // Compartments can be placed anywhere (this includes non-integer positions like 1/2 or 1/3). The grid is defined as (0,0) being the bottom left corner of the bin, with each unit being 1 base long. Each cut() module is a compartment, with the first four values defining the area that should be made into a compartment (X coord, Y coord, width, and height). These values should all be positive. t is the tab style of the compartment (0:full, 1:auto, 2:left, 3:center, 4:right, 5:none). s is a toggle for the bottom scoop. /* gridfinityInit(3, 3, height(6), 0, 42) { cut(x=0, y=0, w=1.5, h=0.5, t=5, s=0); cut(0, 0.5, 1.5, 0.5, 5, 0); cut(0, 1, 1.5, 0.5, 5, 0); cut(0,1.5,0.5,1.5,5,0); cut(0.5,1.5,0.5,1.5,5,0); cut(1,1.5,0.5,1.5,5,0); cut(1.5, 0, 1.5, 5/3, 2); cut(1.5, 5/3, 1.5, 4/3, 4); } gridfinityBase(3, 3, 42, 0, 0, 1); */ // Compartments can overlap! This allows for weirdly shaped compartments, such as this "2" bin. /* gridfinityInit(3, 3, height(6), 0, 42) { cut(0,2,2,1,5,0); cut(1,0,1,3,5); cut(1,0,2,1,5); cut(0,0,1,2); cut(2,1,1,2); } gridfinityBase(3, 3, 42, 0, 0, 1); */ // Areas without a compartment are solid material, where you can put your own cutout shapes. using the cut_move() function, you can select an area, and any child shapes will be moved from the origin to the center of that area, and subtracted from the block. For example, a pattern of three cylinderical holes. /* gridfinityInit(3, 3, height(6), 0, 42) { cut(x=0, y=0, w=2, h=3); cut(x=0, y=0, w=3, h=1, t=5); cut_move(x=2, y=1, w=1, h=2) pattern_linear(x=1, y=3, sx=42/2) cylinder(r=5, h=1000, center=true); } gridfinityBase(3, 3, 42, 0, 0, 1); */ // You can use loops as well as the bin dimensions to make different parametric functions, such as this one, which divides the box into columns, with a small 1x1 top compartment and a long vertical compartment below /* gx = 3; gy = 3; gridfinityInit(gx, gy, height(6), 0, 42) { for(i=[0:gx-1]) { cut(i,0,1,gx-1); cut(i,gx-1,1,1); } } gridfinityBase(gx, gy, 42, 0, 0, 1); */ // Pyramid scheme bin /* gx = 4.5; gy = 4; gridfinityInit(gx, gy, height(6), 0, 42) { for (i = [0:gx-1]) for (j = [0:i]) cut(j*gx/(i+1),gy-i-1,gx/(i+1),1,0); } gridfinityBase(gx, gy, 42, 0, 0, 1); */