275 lines
11 KiB
OpenSCAD
275 lines
11 KiB
OpenSCAD
/**
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* Optical Printer Rails
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*
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* Camera Drive = +X
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* Lens Drive = -X
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**/
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use <2020_profile.scad>
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//include <jk_rails.scad>
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include <./common/common.scad>
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include <./common/motors.scad>
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include <./common/rods.scad>
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RailSpacing = 100; //160
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ThreadedRodSpacing = 50;
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RailEndX = RailSpacing + 40;
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TNutVoid = 17;
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BoltSpacingX = 110;
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module rail_debug (H = 175) {
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color("lime") linear_extrude(height=H) {
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2020_profile();
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}
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}
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module m3_bolt_void (pos = [0, 0, 0], BoltH = 20, CapH = 3) {
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D = 3.25;
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CapD = 6;
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translate(pos) {
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translate([0, 0, CapH / 2]) cylinder(r = R(CapD), h = CapH, center = true, $fn = 40);
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translate([0, 0, -BoltH / 2]) cylinder(r = R(D), h = BoltH + 0.01, center = true, $fn = 40);
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}
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}
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module bolt_voids_2020 (pos = [0, 0, 0]) {
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translate(pos) {
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//translate([0, -25, 0]) rotate([90, 0, 0]) m3_bolt_void(CapH = 6);
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translate([0, 20, 0]) rotate([-90, 0, 0]) m3_bolt_void(CapH = 20);
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translate([-16, 0, 0]) rotate([0, -90, 0]) m3_bolt_void(CapH = 6, BoltH = 10);
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}
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}
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module bolt_voids_motor (pos = [0, 0, 0]) {
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Corner = NEMA17BoltSpacing / 2;
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translate(pos) {
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translate([Corner, Corner, 0]) m3_bolt_void(CapH = 30, BoltH = 40);
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translate([Corner, -Corner, 0]) m3_bolt_void(CapH = 30, BoltH = 40);
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translate([-Corner, Corner, 0]) m3_bolt_void(CapH = 30, BoltH = 40);
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translate([-Corner, -Corner, 0]) m3_bolt_void(CapH = 30, BoltH = 40);
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}
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}
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module T_nut_void (pos = [0, 0, 0], rot = [0, 0, 0]) {
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translate(pos) rotate(rot) {
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cylinder(r = R(TNutDiameter2 + 0.1), h = TNutVoid + .01, center = true, $fn = 60);
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translate([0, 0, -(TNutVoid / 2) + (6 / 2)]) cylinder(r = R(TNutDiameter1 + 0.1), h = 6.01, center = true, $fn = 60);
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translate([8, 0, 0]) cylinder(r = R(3), h = 10, center = true, $fn = 30);
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translate([-8, 0, 0]) cylinder(r = R(3), h = 10, center = true, $fn = 30);
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translate([0, 8, 0]) cylinder(r = R(3), h = 10, center = true, $fn = 30);
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translate([0, -8, 0]) cylinder(r = R(3), h = 10, center = true, $fn = 30);
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}
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}
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module bearing_void (pos = [0, 0, 0], Width = 8, Hole = true, Fuzz = 0.1) {
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$fn = 80;
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innerD = 8.05;
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outerD = 22.1 - .4;
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color("blue") translate (pos) difference () {
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cylinder(r = R(outerD) + Fuzz, h = Width, center = true);
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if (Hole) cylinder(r = R(innerD) - Fuzz, h = Width + 1, center = true);
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}
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}
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module rail_end (pos = [0, 0, 0], rot = [90, 0, 0], Motors = true) {
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Z = 95;
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RailVoid = 20.4;
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translate(pos) rotate(rot) difference () {
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difference () {
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translate([0, -10, 20]) rounded_cube([RailEndX, Z, 80], d = 10, center = true, $fn = 50);
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translate([0, 10, 50]) rotate([0, 90, 0]) rounded_cube([60, Z, RailEndX + 1], d = 10, center = true, $fn = 50);
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}
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//rails
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translate([-RailSpacing / 2, 0, 5]) cube([RailVoid, RailVoid, 40], center = true);
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translate([RailSpacing / 2, 0, 5]) cube([RailVoid, RailVoid, 40], center = true);
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//rails bolts
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bolt_voids_2020([-RailSpacing / 2, 0, 0]);
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rotate([0, 180, 0]) bolt_voids_2020([-RailSpacing / 2, 0, 0]);
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if (Motors) {
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//camera drive motor
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translate([ThreadedRodSpacing / 2, 0, 0]) {
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cylinder(r = R(NEMA17PadD + 0.5), h = 60, center = true, $fn = 100);
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bolt_voids_motor([0, 0, 16 - 21]);
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}
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//lens drive motor
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translate([-ThreadedRodSpacing / 2, 0, 0]) {
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cylinder(r = R(NEMA17PadD + 0.5), h = 60, center = true, $fn = 100);
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bolt_voids_motor([0, 0, 16 - 21]);
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}
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} else {
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translate([-ThreadedRodSpacing / 2, 0, 0]) cylinder(r = R(LinearBearingOuterDiameter + 0.5), h = 60, center = true, $fn = 100);
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translate([-ThreadedRodSpacing / 2, 0, 0]) cylinder(r = R(LinearBearingOuterDiameter + 0.5), h = 60, center = true, $fn = 100);
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}
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//linear motion rod
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translate([0, 0, 5]) cylinder(r = R(ThreadDiameter), h = 40, center = true, $fn = 50);
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//mounting bolts
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translate([BoltSpacingX / 2, 0, 40]) rotate([90, 0, 0]) cylinder(r = R(10), h = 150, center = true, $fn = 40);
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translate([-BoltSpacingX / 2, 0, 40]) rotate([90, 0, 0]) cylinder(r = R(10), h = 150, center = true, $fn = 40);
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}
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}
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module sled (pos = [0, 0, 0], rot = [90, 0, 0], Length = 60) {
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X = RailEndX;
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Y = 60;
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Z = Length;
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translate(pos) rotate(rot) difference () {
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translate([0, 7.5, 0]) rounded_cube([X, Y, Z], d = 10, center = true, $fn = 50);
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//extrusion rails
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translate([-RailSpacing / 2, 0, 0]) cube([21, 22, Z + 1], center = true);
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translate([RailSpacing / 2, 0, 0]) cube([21, 22, Z + 1], center = true);
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//void for bearing roller
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translate([-RailSpacing / 2, -20, 0]) cube([13, 22, Z + 1], center = true);
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translate([RailSpacing / 2, -20, 0]) cube([13, 22, Z + 1], center = true);
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//linear motion rod void
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cylinder(r = R(LinearMotionDiameter + 1), h = Z + 1, center = true, $fn = 60);
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//linear motion rod bearing voids
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translate([0, 0, (Length / 2) - (LinearBearingHeight / 2) + 0.01]) cylinder(r = R(LinearBearingOuterDiameter + 0.2), h = LinearBearingHeight, center = true, $fn = 100);
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translate([0, 0, -(Length / 2) + (LinearBearingHeight / 2) - 0.01]) cylinder(r = R(LinearBearingOuterDiameter + 0.2), h = LinearBearingHeight, center = true, $fn = 100);
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//threaded rod voids
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translate([ThreadedRodSpacing / 2, 0, 0]) cylinder(r = R(ThreadDiameter + 2), h = Z + 1, center = true, $fn = 60);
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translate([-ThreadedRodSpacing / 2, 0, 0]) cylinder(r = R(ThreadDiameter + 2), h = Z + 1, center = true, $fn = 60);
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}
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}
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module camera_sled (pos = [0, 0, 0], rot = [0, 0, 0]) {
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translate(pos) sled(Length = 110);
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}
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module sled_bearing_void (pos = [0, 0, 0], rot = [0, 0, 0]) {
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translate(pos) rotate(rot) {
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cylinder(r = R(27), h = 11, center = true, $fn = 120);
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cylinder(r = R(8.3), h = 16, center = true, $fn = 80);
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translate([0, -10, 0]) cube([8.3, 20, 16 ], center = true, $fn = 60);
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cylinder(r = R(5.2), h = 40, center = true, $fn = 60);
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translate([0, 0, 28]) cylinder(r = R(8.3), h = 30, center = true, $fn = 60);
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}
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}
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module lens_sled_m3_bolt_voids (pos = [0, 0, 0], rot = [0, 0, 0]) {
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D = 16;
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translate(pos) rotate(rot) {
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translate([0, 0, D]) m3_bolt_void(CapH = 10);
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translate([0, 0, -D]) rotate([0, 180, 0]) m3_bolt_void(CapH = 10);
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translate([D, 0, 0]) rotate([0, 90, 0]) m3_bolt_void(CapH = 10);
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translate([-D, 0, 0]) rotate([0, -90, 0]) m3_bolt_void(CapH = 10);
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}
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}
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module lens_sled (pos = [0, 0, 0], rot = [90, 0, 0]) {
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Y = 40;
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LensDriveX = -ThreadedRodSpacing / 2;
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RailVoid = 20.4;
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translate(pos) rotate(rot) {
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difference () {
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union () {
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sled(rot = [0, 0, 0], Length = Y);
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translate([(RailEndX / 2) - (Y / 2), (60 / 2) + (40 / 2) - 5, 0]) cube([Y, 30, Y], center = true);
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translate([-(RailEndX / 2) + (Y / 2), (60 / 2) + (40 / 2) - 5, 0]) cube([Y, 30, Y], center = true);
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}
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T_nut_void ([LensDriveX, 0, (Y / 2) - (TNutVoid / 2) + 0.01], [180, 0, 0]);
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T_nut_void ([LensDriveX, 0, -(Y / 2) + (TNutVoid / 2) - 0.01]);
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//camera drive passthrough
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translate([-LensDriveX, 0, 0]) cylinder(r = R(ThreadDiameter + 1), h = Y + 1, center = true, $fn = 60);
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//
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sled_bearing_void([RailSpacing / 2, 21.5, 0], [0, 90, 0]);
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sled_bearing_void([-RailSpacing / 2, 21.5, 0], [0, -90, 0]);
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//lens carriage frame
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translate([RailSpacing / 2, 53.5, 0]) cube([RailVoid, 32, RailVoid], center = true);
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translate([-RailSpacing / 2, 53.5, 0]) cube([RailVoid, 32, RailVoid], center = true);
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//
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lens_sled_m3_bolt_voids([(RailEndX / 2) - (Y / 2), (60 / 2) + (40 / 2) - 5, 0]);
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lens_sled_m3_bolt_voids([(-RailEndX / 2) + (Y / 2), (60 / 2) + (40 / 2) - 5, 0]);
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}
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//debug
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//translate([-ThreadedRodSpacing / 2, 0, -(Y / 2) + 8.4]) T_nut();
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//translate([-ThreadedRodSpacing / 2, 0, (Y / 2) - 7.5]) rotate([180, 0, 0]) T_nut();
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}
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}
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module bearing_roller (pos = [0, 0, 0], rot = [0, 0, 0]) {
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A = 5.75;
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D1 = 25.4;
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D2 = 24;
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translate(pos) rotate(rot) difference () {
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union () {
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cylinder(r = R(D2), h = 10, center = true, $fn = 100);
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cylinder(r = R(D1), h = A, center = true, $fn = 100);
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translate([0, 0, (A / 2) + (1 / 2)]) cylinder(r1 = R(D1), r2 = R(D2), h = 1, center = true, $fn = 100);
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translate([0, 0, -(A / 2) - (1 / 2)]) cylinder(r2 = R(D1), r1 = R(D2), h = 1, center = true, $fn = 100);
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}
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translate([0, 0, 1]) bearing_void(Hole = false, Fuzz = 0.3, Width = 9.01);
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cylinder(r = R(19.5), h = 10 + 1, center = true, $fn = 100);
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}
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}
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module bearing_roller_inner (pos = [0, 0, 0], rot = [0, 0, 0]) {
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translate(pos) rotate(rot) difference () {
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union () {
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cylinder(r = R(7.8), h = 15, center = true, $fn = 60);
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translate([0, 0, 4.5]) cylinder(r = R(11), h = 1, center = true, $fn = 80);
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}
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cylinder(r = R(5.25), h = 20 + 1, center = true, $fn = 60);
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}
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}
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module debug () {
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//translate([50 , -90 - 10, 22]) rotate([0, 90, 0]) bearing_void();
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rail_end();
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//camera_sled([0, -90, 0]);
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difference () {
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lens_sled([0, -90, 0]);
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translate([ 50 + (RailSpacing / 2), -90, 0]) cube([100, 100, 100], center = true);
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//translate([ -50 - (RailSpacing / 2), -90, 0]) cube([100, 100, 100], center = true);
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}
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//color("green") translate([RailSpacing / 2, -90 + 15, 20]) rotate([0, 0, 0]) linear_extrude(height=100) 2020_profile();
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//difference () {
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//intersection() {
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//lens_sled([0, -90, 0]);
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//translate([-30, -90 + 30 - 1, 10]) cube([90, 60, 45], center = true);
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//translate([150, -90, 50]) cube([200, 100, 100], center = true);
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//}
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translate([RailSpacing / 2, -90, 21.5]) rotate([0, 90, 0]) {
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bearing_roller();
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bearing_roller_inner();
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}
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//bearing_roller();
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//debug
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//translate([-RailSpacing / 2, 0, 0]) rotate([90, 0, 0]) rail_debug(175);
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color("green") translate([RailSpacing / 2, 0, 0]) rotate([90, 0, 0]) linear_extrude(height=175) 2020_profile();
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//translate([ThreadedRodSpacing / 2, 40, 0]) rotate([90, 0, 0]) color("blue") NEMA17();
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//translate([-ThreadedRodSpacing / 2, 40, 0]) rotate([90, 0, 0]) color("blue") NEMA17();
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}
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PART = "lens_sled";
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if (PART == "rail_end") {
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rail_end();
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} else if (PART == "lens_sled") {
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lens_sled();
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} else if (PART == "bearing_roller") {
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bearing_roller();
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} else if (PART == "bearing_roller_inner") {
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rotate([180, 0, 0]) bearing_roller_inner();
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} else {
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debug();
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} |