Initial commit : Tevo Tarantula X carriage, L-Core & L-Minion, Creature Comfort parts

2024-10-14 18:21:15 +02:00 · 2024-10-14 18:21:15 +02:00 · e98fef0cdb
commit e98fef0cdb
7 changed files with 582 additions and 0 deletions
--- a/Comfort/ComfortCards.scad
+++ b/Comfort/ComfortCards.scad
@ -0,0 +1,53 @@
 $fn = 60;
 module base()
 {
    difference()
    {
        square([146, 101.5]);
 //        translate([0, 101.5/2]) circle(48.5/2);
 //        translate([146, 101.5/2]) circle(48.5/2);
        translate([3.3+68/2, 7.75 - 27.5/2]) circle(27.5/2);
        translate([3.3+68+3.4+68/2, 7.75 - 27.5/2]) circle(27.5/2);
        translate([3.3+68/2, 101.5 - 7.75 + 27.5/2]) circle(27.5/2);
        translate([3.3+68+3.4+68/2, 101.5 - 7.75 + 27.5/2]) circle(27.5/2);
    }
 }
 minkowski()
 {
    difference()
    {
        linear_extrude(29)
        minkowski(convexity = 2)
        {
            offset(-4) base();
            circle(4);
        }
        translate([3.3, 2.75, 1])
        linear_extrude(35)
        //minkowski(convexity = 2)
        {
            //offset(-4) 
            square([68, 96]);
            //circle(4);
        }
        translate([3.3+68+3.4, 2.75, 1])
        linear_extrude(35)
        //minkowski(convexity = 2)
        {
            //offset(-4) 
            square([68, 96]);
            //circle(4);
        }
 //        translate([146/2, 101.5/2, -1]) cylinder(35,r=48.5/2);
    }
    translate([1,1,0]) cylinder(1, 1, 0);
 }
--- a/Comfort/TravelerCards.scad
+++ b/Comfort/TravelerCards.scad
@ -0,0 +1,38 @@
 $fn = 60;
 module base()
 {
    difference()
    {
        square([138, 101.5]);
        translate([0, 101.5/2]) circle(48.5/2);
        translate([138, 101.5/2]) circle(48.5/2);
        translate([138/2, 7.75 - 27.5/2]) circle(27.5/2);
        translate([138/2, 101.5 - 7.75 + 27.5/2]) circle(27.5/2);
    }
 }
 minkowski()
 {
    difference()
    {
        linear_extrude(13.3)
        minkowski(convexity = 2)
        {
            offset(-4) base();
            circle(4);
        }
        translate([8, 9.75, 1])
        linear_extrude(30)
        minkowski(convexity = 2)
        {
            offset(-4) square([122, 82]);
            circle(4);
        }
        translate([138/2, 101.5/2, -1]) cylinder(30,r=48.5/2);
    }
    translate([1,1,0]) cylinder(1, 1, 0);
 }
--- a/L-Core/lead-screw-constraint-front-left-3.1.scad
+++ b/L-Core/lead-screw-constraint-front-left-3.1.scad
@ -0,0 +1,56 @@
 $fn=60;
 // Physical dimensions
 EXTRUSION_WIDTH = 40;
 EXTRUSION_HEIGHT = 40;
 EXTRUSION_GROOVE_WIDTH = 8.2;
 MOTOR_WIDTH = 43.0;
 MOTOR_HEIGHT = 43.0;
 MOTOR_DEPTH = 40.0;
 MOTOR_CORNER = 4.5;
 MOTOR_SHAFT_HOLE_DIAMETER = 24;
 BOLT_HOLE_DIAMETER = 6.4;       // M6
 BOLT_HOLE_HEAD_DIAMETER = 11;       // M6
 MGN_RAIL_WR = 12;
 MGN_RAIL_HR = 8;
 F688ZZ_D = 16;
 // Parameters
 CORNER_SIZE = 5.0;                      // Part corner size
 MOTOR_TO_BORDER_CLEARANCE = 5.0;
 CHAMFER_SIZE = 1;
 EXTRUSION_BORDER_CLEARANCE = 4;         // Distance between extrusion and part borders
 EXTRUSION_GROOVE_SLIDE_CLEARANCE = 0.2; // Slide to groove clearance
 EXTRUSION_GROOVE_SLIDE_DEPTH = 2;       // Slide depth
 // Variables
 total_width = EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + MOTOR_WIDTH + MOTOR_TO_BORDER_CLEARANCE;
 total_height = EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + MOTOR_HEIGHT + MOTOR_TO_BORDER_CLEARANCE;
 //minkowski()
 {
    linear_extrude(8 - CHAMFER_SIZE)
    difference()
    {
        hull()
        {
            square([EXTRUSION_WIDTH + 3, EXTRUSION_HEIGHT + 3]);
            translate([EXTRUSION_WIDTH + MOTOR_WIDTH / 2, EXTRUSION_HEIGHT + MOTOR_HEIGHT / 2]) circle(F688ZZ_D/2 + MOTOR_TO_BORDER_CLEARANCE);
        }
        translate([-1, -1]) square([EXTRUSION_WIDTH + 1, EXTRUSION_HEIGHT +1]);
        translate([EXTRUSION_WIDTH + MOTOR_WIDTH / 2, EXTRUSION_HEIGHT + MOTOR_HEIGHT / 2]) circle(F688ZZ_D/2);
        translate([EXTRUSION_WIDTH / 2 - MGN_RAIL_WR / 2, EXTRUSION_HEIGHT - 1]) square([MGN_RAIL_WR, MGN_RAIL_HR + 1]);
        square([EXTRUSION_WIDTH / 2 - MGN_RAIL_WR / 2, EXTRUSION_HEIGHT + MGN_RAIL_HR + 10]);
        square([EXTRUSION_WIDTH + 10, EXTRUSION_BORDER_CLEARANCE]);
    }
    translate([CHAMFER_SIZE, CHAMFER_SIZE]) cylinder(CHAMFER_SIZE,CHAMFER_SIZE,0);
 }
--- a/L-Core/lead-screw-motor-cage-front-3.1.scad
+++ b/L-Core/lead-screw-motor-cage-front-3.1.scad
@ -0,0 +1,224 @@
 $fn=60;
 // Physical dimensions
 EXTRUSION_WIDTH = 40;
 EXTRUSION_HEIGHT = 40;
 EXTRUSION_GROOVE_WIDTH = 8.2;
 MOTOR_WIDTH = 43.0;
 MOTOR_HEIGHT = 43.0;
 MOTOR_DEPTH = 40.0;
 MOTOR_CORNER = 4.5;
 MOTOR_SHAFT_HOLE_DIAMETER = 24;
 BOLT_HOLE_DIAMETER = 6.4;       // M6
 BOLT_HOLE_HEAD_DIAMETER = 11;       // M6
 // Parameters
 CORNER_SIZE = 5.0;                      // Part corner size
 MOTOR_TO_BORDER_CLEARANCE = 8.0;
 CHAMFER_SIZE = 0.4;
 EXTRUSION_BORDER_CLEARANCE = 1;         // Distance between extrusion and part borders
 EXTRUSION_GROOVE_SLIDE_CLEARANCE = 0.2; // Slide to groove clearance
 EXTRUSION_GROOVE_SLIDE_DEPTH = 2;       // Slide depth
 // Variables
 total_width = EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + MOTOR_WIDTH + MOTOR_TO_BORDER_CLEARANCE;
 total_height = EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + MOTOR_HEIGHT + MOTOR_TO_BORDER_CLEARANCE;
 base_p = [
            [0,                         CORNER_SIZE],
            [0,                         total_height - CORNER_SIZE],
            [CORNER_SIZE,               total_height],
            [total_width - CORNER_SIZE, total_height],
            [total_width,               total_height - CORNER_SIZE],
            [total_width,               CORNER_SIZE],
            [total_width - CORNER_SIZE, 0],
            [CORNER_SIZE, 0]
        ];
 motor_p = [
            [0,                             MOTOR_CORNER],
            [0,                             MOTOR_HEIGHT - MOTOR_CORNER],
            [MOTOR_CORNER,                  MOTOR_HEIGHT],
            [MOTOR_WIDTH - MOTOR_CORNER,    MOTOR_HEIGHT],
            [MOTOR_WIDTH,                   MOTOR_HEIGHT - MOTOR_CORNER],
            [MOTOR_WIDTH,                   MOTOR_CORNER],
            [MOTOR_WIDTH - MOTOR_CORNER,    0],
            [MOTOR_CORNER,                  0]
          ];
 module hexagon(ri =  1.0)   // inner radius of hexagon
 {
 	ra = ri*2/sqrt(3);
 	circle(r = ra, $fn=6);
 }
 module m3nut(height)
 {
    linear_extrude(height) hexagon(5.6 / 2);
 }
 module groove(s)
 {
    groove_p = [
                 [0, 0],
                 [0, EXTRUSION_GROOVE_SLIDE_DEPTH - 0.6],
                 [0.6, EXTRUSION_GROOVE_SLIDE_DEPTH],
                 [EXTRUSION_GROOVE_WIDTH - 0.6, EXTRUSION_GROOVE_SLIDE_DEPTH],
                 [EXTRUSION_GROOVE_WIDTH, EXTRUSION_GROOVE_SLIDE_DEPTH - 0.6],
                 [EXTRUSION_GROOVE_WIDTH, 0],
               ];
    translate([0,s,0])
    rotate([90,0,0])
    linear_extrude(s)
    polygon(groove_p);
 }
 module base()
 {
        union()
        {
            hull()
            {
                linear_extrude(2)
                offset(-4)
                polygon(base_p);
                translate([0, 0, 2])
                linear_extrude(14)
                offset(-1.75)
                polygon(base_p);
                translate([0, 0, 16])
                linear_extrude(8)
                polygon(base_p);
            }
            // Grooves
            translate([EXTRUSION_WIDTH / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 0, 2+14+8])
            groove(10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE);
            translate([EXTRUSION_WIDTH / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 
                       10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 9, 
                       2+14+8])
            groove(11);
            translate([EXTRUSION_WIDTH / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 9, 2+14+8])
            groove(11.5);
            translate([0, EXTRUSION_HEIGHT / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE + EXTRUSION_GROOVE_WIDTH, 2+14+8])
            rotate([0,0,-90])
            groove(10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE);
            translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 9, EXTRUSION_HEIGHT / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE + EXTRUSION_GROOVE_WIDTH, 2+14+8])
            rotate([0,0,-90])
            groove(11);
            translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 9, EXTRUSION_HEIGHT / 2 - EXTRUSION_GROOVE_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE + EXTRUSION_GROOVE_WIDTH, 2+14+8])
            rotate([0,0,-90])
            groove(11.5);
        }
 }
 motor_shaft_hole_radius = MOTOR_SHAFT_HOLE_DIAMETER / 2;
 motor_center_x = EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + MOTOR_WIDTH / 2;
 motor_center_y = EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + MOTOR_HEIGHT / 2;
 difference()
 {
    base();
    translate([-EXTRUSION_BORDER_CLEARANCE, -EXTRUSION_BORDER_CLEARANCE, -1])
    cube([EXTRUSION_WIDTH, EXTRUSION_HEIGHT, 29]);
    translate([EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE, EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE, 5])
    linear_extrude(20)
    polygon(motor_p);
    // Motor holes
    translate([motor_center_x, motor_center_y, -1])
    cylinder(20, r=motor_shaft_hole_radius);
    translate([motor_center_x - 31/2, motor_center_y - 31/2, -1])
    cylinder(20, r=3.4/2);
    translate([motor_center_x + 31/2, motor_center_y - 31/2, -1])
    cylinder(20, r=3.4/2);
    translate([motor_center_x - 31/2, motor_center_y + 31/2, -1])
    cylinder(20, r=3.4/2);
    translate([motor_center_x + 31/2, motor_center_y + 31/2, -1])
    cylinder(20, r=3.4/2);
    // Chamfers
    translate([motor_center_x, motor_center_y, -0.01])
    cylinder(1, motor_shaft_hole_radius+0.5, motor_shaft_hole_radius);
    translate([motor_center_x - 31/2, motor_center_y - 31/2, -0.01])
    cylinder(1, (3.4+0.5)/2);
    translate([motor_center_x + 31/2, motor_center_y - 31/2, -0.01])
    cylinder(1, (3.4+0.5)/2);
    translate([motor_center_x - 31/2, motor_center_y + 31/2, -0.01])
    cylinder(1, (3.4+0.5)/2);
    translate([motor_center_x + 31/2, motor_center_y + 31/2, -0.01])
    cylinder(1, (3.4+0.5)/2);
    // Groove holes
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 4.5, 11.2])
    cylinder(35, r = BOLT_HOLE_DIAMETER / 2);
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, 11.2])
    cylinder(35, r = BOLT_HOLE_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, 11.2])
    cylinder(35, r = BOLT_HOLE_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, 11.2])
    cylinder(35, r = BOLT_HOLE_DIAMETER / 2);
    // Bolt head holes
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 4.5, -1])
    cylinder(12, r = BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, -1])
    cylinder(12, r = BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, -1])
    cylinder(12, r = BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, -1])
    cylinder(12, r = BOLT_HOLE_HEAD_DIAMETER / 2);
    // Bold head chamfers
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 4.5, -0.01])
    cylinder(1, (BOLT_HOLE_HEAD_DIAMETER+1) / 2, BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([EXTRUSION_WIDTH / 2 - EXTRUSION_BORDER_CLEARANCE, 10.5 + EXTRUSION_HEIGHT - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, -0.01])
    cylinder(1, (BOLT_HOLE_HEAD_DIAMETER+1) / 2, BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, -0.01])
    cylinder(1, (BOLT_HOLE_HEAD_DIAMETER+1) / 2, BOLT_HOLE_HEAD_DIAMETER / 2);
    translate([10.5 + EXTRUSION_WIDTH - EXTRUSION_BORDER_CLEARANCE + 9 + 11 + 4.5, EXTRUSION_HEIGHT / 2 - EXTRUSION_BORDER_CLEARANCE, -0.01])
    cylinder(1, (BOLT_HOLE_HEAD_DIAMETER+1) / 2, BOLT_HOLE_HEAD_DIAMETER / 2);
 }
--- a/L-Minion/y_motor_cage.scad
+++ b/L-Minion/y_motor_cage.scad
@ -0,0 +1,132 @@
 $fn=100;
 EXTRUSION_W = 40;
 EXTRUSION_H = 40;
 EXTRUSION_D = 40;
 MOTOR_W = 43;
 MOTOR_H = 43;
 p = [
     [0,                    0],
     [0,                    EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 1.5],
     [MOTOR_W + 5,          EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 1.5],
     [MOTOR_W + 5,          EXTRUSION_H],
     [MOTOR_W + 5 + 60,     EXTRUSION_H],
     [MOTOR_W + 5 + 60,     0],
    ];
 p2 = [
      [0,               0],
      [0,               EXTRUSION_H - MOTOR_H / 2 - 1.5],
      [EXTRUSION_D,     EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 1.5],
      [EXTRUSION_D + 5, EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 1.5],
      [EXTRUSION_D + 5, 0],
     ];
 module plate()
 {
    difference()
    {
        union()
        {
            translate([0,5,0])
            rotate([90,0,0])
            linear_extrude(5)
            polygon(p);
            hull()
            {
                translate([0,5,0])
                rotate([90,0,0])
                linear_extrude(5)
                square([MOTOR_W + 60 + 5, EXTRUSION_H - 1.5 - 8]);
                translate([MOTOR_W - 6, 5+12-1, 0])
                rotate([90,0,0])
                linear_extrude(1)
                square([60 + 5 + 6, EXTRUSION_H - 1.5 - 8 - 2]);
                translate([MOTOR_W, 5+20-1, 0])
                rotate([90,0,0])
                linear_extrude(1)
                square([60 + 5 - 8, EXTRUSION_H - 1.5 - 8 - 2 - 4]);
            }
            translate([0, -EXTRUSION_D, 0])
            cube([MOTOR_W, EXTRUSION_D, EXTRUSION_H - MOTOR_H / 2 - 1.5]);
            translate([-5, -EXTRUSION_D, 0])
            rotate([90,0,90])
            linear_extrude(5)
            polygon(p2);
            translate([MOTOR_W, -EXTRUSION_D, 0])
            rotate([90,0,90])
            linear_extrude(5)
            polygon(p2);
        }
        // Motor shaft hole
        translate([MOTOR_W / 2, 25, EXTRUSION_H - 1.5])
        rotate([90,0,0])
        cylinder(26, r= 24/2);
        // Motor screws holes
        translate([6, 25, EXTRUSION_H - MOTOR_H / 2 + 6  - 1.5])
        rotate([90,0,0])
        cylinder(26, r= 3.3/2);
        translate([6, 25, EXTRUSION_H - MOTOR_H / 2 + 6  - 1.5])
        rotate([90,0,0])
        cylinder(21, r= 6/2);
        translate([MOTOR_W - 6, 25, EXTRUSION_H - MOTOR_H / 2 + 6 - 1.5])
        rotate([90,0,0])
        cylinder(26, r= 3.3/2);
        translate([MOTOR_W - 6, 25, EXTRUSION_H - MOTOR_H / 2 + 6 - 1.5])
        rotate([90,0,0])
        cylinder(21, r= 6/2);
        translate([6, 25, EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 6 - 1.5])
        rotate([90,0,0])
        cylinder(26, r= 3.3/2);
        translate([MOTOR_W - 6, 25, EXTRUSION_H - MOTOR_H / 2 + MOTOR_H - 6 - 1.5])
        rotate([90,0,0])
        cylinder(26, r= 3.3/2);
        // part screw hold hole 1
        translate([MOTOR_W + 15, 25, EXTRUSION_H / 2])
        rotate([90,0,0])
        cylinder(26, r= 6.3/2);
        translate([MOTOR_W + 15, 25, EXTRUSION_H / 2])
        rotate([90,0,0])
        cylinder(21, r= 12/2);
        // part screw hold hole 2
        translate([MOTOR_W + 15 + 30, 25, EXTRUSION_H / 2])
        rotate([90,0,0])
        cylinder(26, r= 6.3/2);
        translate([MOTOR_W + 15 + 30, 25, EXTRUSION_H / 2])
        rotate([90,0,0])
        cylinder(20, r= 12/2);
    }
 }
 plate();
--- a/README.md
+++ b/README.md
--- a/Tarantula/x-carriage-plate.scad
+++ b/Tarantula/x-carriage-plate.scad
@ -0,0 +1,79 @@
 $fn=100;
 WIDTH = 76;
 DEPTH = 64;
 THICKNESS = 5;
 BASE_PLATE_CORNER_RADIUS = 10;
 VSLOT_WHEEL_HOLE_DIA_SMALL = 5;
 VSLOT_WHEEL_HOLE_DIA_BIG = 7;
 WHEEL_DIA = 24;
 WHEEL_FLANGE = 2.25;
 EXTRUSION_WIDTH = 20;
 WHEEL_FLANGE_IN_EXTRUSION_SIZE = 2;     // /!\ Max = WHEEL_FLANGE
 module base_plate ()
 {
    difference()
    {
        linear_extrude(THICKNESS)
        minkowski()
        {
            offset(-BASE_PLATE_CORNER_RADIUS)
            square([WIDTH, DEPTH]);
            circle(BASE_PLATE_CORNER_RADIUS);
        }
        // Wheel holes
        cy = DEPTH / 2;
        wheel_radius = WHEEL_DIA / 2;
        translate([10, cy - EXTRUSION_WIDTH / 2 - (wheel_radius - WHEEL_FLANGE_IN_EXTRUSION_SIZE), -1])
        cylinder(h=THICKNESS + 2, r=VSLOT_WHEEL_HOLE_DIA_SMALL / 2);
        translate([WIDTH - 10, cy - EXTRUSION_WIDTH / 2 - (wheel_radius - WHEEL_FLANGE_IN_EXTRUSION_SIZE), -1])
        cylinder(h=THICKNESS + 2, r=VSLOT_WHEEL_HOLE_DIA_SMALL / 2);
        translate([10, cy + EXTRUSION_WIDTH / 2 + (wheel_radius - WHEEL_FLANGE_IN_EXTRUSION_SIZE), -1])
        cylinder(h=THICKNESS + 2, r=VSLOT_WHEEL_HOLE_DIA_BIG / 2);
        translate([WIDTH - 10, cy + EXTRUSION_WIDTH / 2 + (wheel_radius - WHEEL_FLANGE_IN_EXTRUSION_SIZE), -1])
        cylinder(h=THICKNESS + 2, r=VSLOT_WHEEL_HOLE_DIA_BIG / 2);
    }
 }
 module belt_attach()
 {
    linear_extrude(8)
    union()
    {
        translate([0, THICKNESS - 4])
        union()
        {
            hull()
            {
                translate([2, 1.5]) square([3.5, 2.5]);
                translate([2, 2]) circle(2);
            }
            translate([5.5, 1.5]) square([4.7, 2.5]);
        }
        translate([5.5 + 4.7, -1]) square([7+1, THICKNESS + 2]);
    }
 }
 difference()
 {
    base_plate();
    translate([17, DEPTH / 2 - 4, 0.01])
    rotate([90,0,180])
    belt_attach();
    translate([WIDTH - 17, DEPTH / 2 + 4, 0.01])
    rotate([90,0,0])
    belt_attach();
 }