//
// You will also need 4 x M4 machine screws and nuts.
//
+// This is the default.
+//
// ===== Light duty 3-armed spool for 3mm x <=30m coil =====
//
// A light duty 3-armed spool suitable for up to around 30m
// Set
// fdia=2.85
// lightduty=true
+// (or look in filamentspool-lt.scad).
+//
// And print following parts
// Hub
// ArmEnd x 3
// Set
// fdia=2.85
// lightduty=false
+// (or look in filamentspool-sm.scad).
+//
// And print one of these, according to taste
// StorageArmLeft
// StorageArmRight
exteffrad = 70;
hubeffrad = selsz(30, 82, 40);
hubbigrad = selsz(20, 38, 38);
-hublwidth = selsz(3, 2.5, 4);
+hublwidth = selsz(3, 2.5, 3.0);
hubstemwidth = 2;
hublthick = 10;
hubaxlerad = selsz(5, 28/2, 28/2);
include <cliphook.scad>
include <filamentteeth.scad>
include <axlepin.scad>
+include <commitid.scad>
hub_clip_baseextend = (hubeffrad - DoveClip_depth()
- hubbigrad + hublwidth);
-armendwallthick + totalwidth/2,
-armendbasethick -1])
cylinder(r= nondove_armhole_hole/2, h=totalheight+2, $fn=10);
+ translate([-nondove_armbase, -armendwallthick, -armendbasethick])
+ rotate([90,0,0])
+ Commitid_BestCount([nondove_armbase, totalwidth]);
}
}
- for (otherside=[0,1]) {
- for (circum = [300:100:1500]) {
- assign(rad = circum / tau)
- assign(fn = str("filamentspool-number-n",circum,".dxf"))
- assign(rotateoffset = [0, totalwidth/2, 0])
- assign(xlen = rad - real_exteffrad) {
- if (xlen >= numbers_tick_width/2
- + (otherside ? numbers_height_allow : 0) &&
- xlen <= length - (otherside ? 0 : numbers_height_allow))
- translate([xlen, -armendwallthick,
- -armendbasethick + (totalheight - numbers_tick_len)/2])
- translate(rotateoffset)
- rotate([0,0, otherside*180])
- translate(-rotateoffset){
- translate([-numbers_tick_width/2, -1, 0])
- cube([numbers_tick_width, numbers_relief+1, numbers_tick_len]);
- translate([numbers_tick_width/2 + numbers_tick_linespc,
- 1,
- numbers_tick_len])
- rotate([90,0,0])
- rotate([0,0,-90])
- linear_extrude(height= numbers_relief+1)
- // scale(templatescale)
- import(file=fn, convexity=100);
- }
+ difference(){
+ union(){
+ difference(){
+ translate([0, -armendwallthick, -armendbasethick])
+ cube([length, totalwidth, totalheight]);
+ translate([-1, 0, 0])
+ cube([length+1 - ratchettooth, channelwidth, channeldepth+1]);
+ translate([-1, 0, ratchettoothheight])
+ cube([length+2, channelwidth, channeldepth+1]);
+ }
+ for (dx = [0 : ratchetstep : length - ratchetstep]) translate([dx,0,0]) {
+ translate([ratchettoothsmoothr+0.5, armendwallthick/2, 0]) minkowski(){
+ rotate([90,0,0])
+ cylinder($fn=20, r=ratchettoothsmoothr, h=armendwallthick);
+ multmatrix([ [ 1, 0, ratchettoothslope, 0 ],
+ [ 0, 1, 0, 0 ],
+ [ 0, 0, 1, 0 ],
+ [ 0, 0, 0, 1 ]])
+ cube([ratchettooth - ratchettoothsmoothr*2,
+ channelwidth, ratchettoothheight - ratchettoothsmoothr]);
+ }
}
}
- }
- difference(){
- translate([0, -armendwallthick, -armendbasethick])
- cube([length, totalwidth, totalheight]);
- translate([-1, 0, 0])
- cube([length+1 - ratchettooth, channelwidth, channeldepth+1]);
- translate([-1, 0, ratchettoothheight])
- cube([length+2, channelwidth, channeldepth+1]);
- }
- for (dx = [0 : ratchetstep : length - ratchetstep]) translate([dx,0,0]) {
- translate([ratchettoothsmoothr+0.5, armendwallthick/2, 0]) minkowski(){
- rotate([90,0,0])
- cylinder($fn=20, r=ratchettoothsmoothr, h=armendwallthick);
- multmatrix([ [ 1, 0, ratchettoothslope, 0 ],
- [ 0, 1, 0, 0 ],
- [ 0, 0, 1, 0 ],
- [ 0, 0, 0, 1 ]])
- cube([ratchettooth - ratchettoothsmoothr*2,
- channelwidth, ratchettoothheight - ratchettoothsmoothr]);
+ for (otherside=[0,1]) {
+ for (circum = [300:100:1500]) {
+ assign(rad = circum / tau)
+ assign(fn = str("filamentspool-number-n",circum,".dxf"))
+ assign(rotateoffset = [0, totalwidth/2, 0])
+ assign(xlen = rad - real_exteffrad) {
+ if (xlen >= numbers_tick_width/2
+ + (otherside ? numbers_height_allow : 0) &&
+ xlen <= length - (otherside ? 0 : numbers_height_allow))
+ translate([xlen, -armendwallthick,
+ -armendbasethick + (totalheight - numbers_tick_len)/2])
+ translate(rotateoffset)
+ rotate([0,0, otherside*180])
+ translate(-rotateoffset){
+ translate([-numbers_tick_width/2, -1, 0])
+ cube([numbers_tick_width, numbers_relief+1, numbers_tick_len]);
+ translate([numbers_tick_width/2 + numbers_tick_linespc,
+ 1,
+ numbers_tick_len])
+ rotate([90,0,0])
+ rotate([0,0,-90])
+ linear_extrude(height= numbers_relief+1)
+ // scale(templatescale)
+ import(file=fn, convexity=100);
+ }
+ }
+ }
+ }
+
+ if (usedove()){
+ translate([0, -armendwallthick, -armendbasethick])
+ Commitid_BestCount_M([length/3, totalwidth]);
}
}
}
}
}
-module FilamentCup() { ////toplevel
+module FilamentCupPositive() {
FilamentCupHandle();
gapy = prongwidth;
}
}
+module FilamentCup() { ////toplevel
+ difference(){
+ FilamentCupPositive();
+ translate([0, -stalkwidth, 0])
+ Commitid_BestCount_M([stalklength - stalkwidth, stalkwidth]);
+ }
+}
+
module CupSecuringClipSolid(w,d,h1,h2){
rotate([0,-90,0]) translate([0,-h1/2,-w/2]) linear_extrude(height=w) {
polygon(points=[[0,0], [d,0], [d,h2], [0,h1]]);
}
}
translate([0,0,-1]) cylinder($fn=60, h=hubaxlelen+2, r=axlerad);
+
+ rotate([0,0, selsz(0,0,45)])
+ translate([axlerad+hublwidth,
+ -hublwidth/2,
+ 0])
+ rotate([90,0,0])
+ Commitid_BestCount([(hubbigrad-hublwidth) - (axlerad+hublwidth),
+ hublthick +
+ hublwidth/2 * hubaxlelen/(hubbigrad-axlerad),
+ ]);
}
}
translate([-real_exteffrad,-20,0]) Hub();
ArmEnd();
translate([ratchettooth*2, 30, 0]) FilamentCup();
+ if (selsz(true,false,false)) {
+ translate([-exteffrad + hubeffrad - hub_clip_baseextend, -10, 0])
+ ArmExtender();
+ }
}
//ArmEnd();