more advanced chimera hotend

author: Michael Krelin <hacker@klever.net> 2016-07-21 21:38:59 (UTC)
committer: Michael Krelin <hacker@klever.net> 2016-07-21 21:38:59 (UTC)
commit: 9b39333e40abf93141ee39f40ef3733890ee0db8 (patch) (unidiff)
tree: 125a56fc01499ee602e6f918a8b910fef5e6f0e3
parent: 9cceb044d036c37c8c8703926c9c84d1d88cc2e0 (diff)
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1 files changed, 74 insertions, 1 deletions
diff --git a/fanduct.scad b/fanduct.scad
index ba63717..2bc5623 100644
--- a/fanduct.scad
+++ b/fanduct.scad
@@ -1,422 +1,495 @@
 use <snapper.scad>;
        extrusion_width=.5; layer_height=.2;    // print parameters
        epsilon=.005;   // for finer cuts
        type="simple"; // circular|3jets
        ductshape="square"; // square|round
        dual=true;      // dual or single
        nozzles_apart = 18;     // distance between nozzles for dual hotend
        space_behind_nozzle = 10;// space behind the nozzle where we're allowed to go
                                // without the fear of hitting carriage
        inlet_w = 12.5;         // inlet width
        inlet_h = 17;   // inlet height
        inlet_short_l = 7;// inlet length of protrusion (or depth of intrusion:))
        inlet_away = 15;// how far away inlet is
 inlet_long_l = inlet_short_l+inlet_h;
 function hypothenuse(a,b) = sqrt(pow(a,2)+pow(b,2));
 silicone_shell = 2;
 heater_clearance = dual
       ? max(20,15.5) - 4.5 + silicone_shell
       : max(
                hypothenuse(16/2     +silicone_shell, 20-4.5 +silicone_shell),// E3D v6
                hypothenuse(11.5-4.5 +silicone_shell, 15.5   +silicone_shell)// E3D volcano
       );
        fanduct_elevation = 3;                                          // fanduct elevation above nozzle tip
        fanduct_blowtarget = -2;                                        // what to blow at
        fanduct_h = 6;                                                  // inner height of the duct
        fanduct_w = 7;                                                  // inner width of the duct
        fanduct_shell=1.2;                                              // shell thickness
        fanduct_ir = heater_clearance+5;                                // inner radius
        jet_angle = 60-2;       // angular width of the jet
 hotend_clearance = heater_clearance;
        snapper_d = 8; snapper_overlap=0.2;// snip snap
 draft=true;
 smooth_f = draft? 30 : 120;
 to_midduct = fanduct_ir+fanduct_shell+fanduct_w/2;
 dual_spots = [ [+space_behind_nozzle, -(to_midduct+nozzles_apart/2)],
               [-         to_midduct, -(to_midduct+nozzles_apart/2)],
               [-         to_midduct, 0] ];
 module fanduct(type=type,ductshape=ductshape,dual=dual) {
         //     ***duct is all around!
 module duct(what) {
  module ductshape(what,sh,sv,r) {
   smax = max(sh,sv);
   translate([what=="in"?0:fanduct_shell,what=="in"?0:fanduct_shell])
   if(ductshape=="round") {
    translate([sh/2+r,sv/2])
    scale([sh/smax,sv/smax])
    circle(d=smax,$fn=4*smax);
   }else if(ductshape=="square") {
    translate([r,0])
    if(what=="in")
     square([sh,sv]);
    else if(what=="out") union() {
     square([sh,sv/2]);
     translate([sh/2,sv/2])
     scale([sh/smax,sv/smax])
     circle(d=smax,$fn=4*smax);
    }
   }
  }
  module single() {
   if(what=="in") {
    sh = fanduct_w+2*fanduct_shell; sv = fanduct_h+2*fanduct_shell;
    rotate_extrude($fn=smooth_f)
    ductshape(what=what,sh=sh,sv=sv,r=fanduct_ir);
   }else if(what=="out") {
    sh = fanduct_w; sv = fanduct_h;
    smax = max(sh,sv);
    rotate_extrude($fn=smooth_f)
    ductshape(what=what,sh=sh,sv=sv,r=fanduct_ir);
   }
  }
  module dual() {
   module hulls(spots=dual_spots) {
    for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {
     for(p=[spots[pn],spots[pn+1]]) translate(p) children();
    }
   }
   if(what=="in") {
    hulls() cylinder(d=fanduct_w+2*fanduct_shell,h=fanduct_h+2*fanduct_shell);
   }else if(what=="out") {
    sh = fanduct_w; sv = fanduct_h;
    smax = max(sh,sv);
    translate([0,0,fanduct_shell]) hulls() {
     cylinder(d=fanduct_w,h=fanduct_h/2);
     translate([0,0,fanduct_h/2])
     scale([sh/smax,sh/smax,sv/smax])
     intersection() {
      sphere(d=smax,$fn=36);
      translate([0,0,-1])
      cylinder(d=smax+2,h=smax+2,$fn=36);
     }
    }
   }
  }
  module dual_simple() {
   for(my=[0,1]) mirror([0,my,0])
   if(what=="in") {
    sh = fanduct_w+2*fanduct_shell; sv = fanduct_h+2*fanduct_shell;
    translate([0,nozzles_apart/2,0])
    intersection() {
     rotate_extrude($fn=smooth_f)
      translate([fanduct_ir,0]) square([sh,sv]);
     translate([-fanduct_ir-sh-1,0,-1])
     cube(size=[fanduct_ir+sh+2,fanduct_ir+sh+2,sv+2]);
    }
    translate([-fanduct_ir-sh,-epsilon,0])
    cube(size=[sh,nozzles_apart/2+2*epsilon,sv]);
    translate([0,sh/2+fanduct_ir+nozzles_apart/2,0]) cylinder(d=sh,h=sv,$fn=36);
   }else if(what=="out") {
    sh = fanduct_w; sv = fanduct_h;
    translate([0,nozzles_apart/2,fanduct_shell])
    intersection() {
     rotate_extrude($fn=smooth_f)
      translate([fanduct_ir+fanduct_shell,0]) square([sh,sv]);
     translate([-fanduct_ir-2*fanduct_shell-sh-1,-1,0])
     cube(size=[fanduct_ir+2*fanduct_shell+sh+2,fanduct_ir+2*fanduct_shell+sh+2,sv]);
    }
    translate([-fanduct_ir-fanduct_shell-sh,-epsilon,fanduct_shell])
    cube(size=[sh,nozzles_apart/2+2*epsilon,sv]);
    translate([0,sh/2+fanduct_shell+fanduct_ir+nozzles_apart/2,fanduct_shell])
    cylinder(d=sh,h=sv,$fn=36);
   }
  }
+  module dual_complex() {
+   for(my=[0,1]) mirror([0,my,0])
+    if(what=="in") {
+     sh = fanduct_w+2*fanduct_shell;
+     sv = fanduct_h+2*fanduct_shell;
+     for(mx=[0,1]) mirror([mx,0,0])
+     mirror([0,1,0]) rotate([90,0,0])
+     translate([0,0,-1])
+     linear_extrude(height=nozzles_apart/2+1+epsilon)
+     ductshape(sh=sh,sv=sv,r=fanduct_ir,what=what);
+     translate([0,nozzles_apart/2,0])
+     difference() {
+      rotate_extrude($fn=smooth_f)
+      ductshape(sh=sh,sv=sv,r=fanduct_ir,what=what);
+      mirror([0,1,0]) translate([-fanduct_ir-sh-1,0,-1])
+      cube(size=[2*(fanduct_ir+sh+1),fanduct_ir+sh+1,sv+2]);
+     }
+    }else{
+     sh = fanduct_w; sv = fanduct_h;
+     for(mx=[0,1]) mirror([mx,0,0])
+     mirror([0,1,0]) rotate([90,0,0])
+     translate([0,0,-1])
+     linear_extrude(height=nozzles_apart/2+1+epsilon)
+     ductshape(sh=sh,sv=sv,r=fanduct_ir,what=what);
+     translate([0,nozzles_apart/2,0])
+     difference() {
+      rotate_extrude($fn=smooth_f)
+      ductshape(sh=sh,sv=sv,r=fanduct_ir,what=what);
+      mirror([0,1,0]) translate([-fanduct_ir-sh-1,0,-1])
+      cube(size=[2*(fanduct_ir+sh+1),fanduct_ir+sh+1,sv+2]);
+     }
+    }
+  }
  if(dual) {
   if(type=="simple")
    dual_simple();
+   else if(type=="jets")
+    dual_complex();
   else dual();
  }else single();
 }
         //     ***bumps for easier position adjustments in line with hotend
 module marks(what) {
  if(what=="in") {
   for(y=[-1,1]) translate([0,dual?y*nozzles_apart/2:0,0])
    hull() for(z=[0,-fanduct_shell-fanduct_h/2])
     translate([0,y*(fanduct_ir+fanduct_shell+fanduct_w/2),fanduct_shell*2+fanduct_h+z])
     rotate([90,0,0]) {
      cylinder(r=fanduct_shell,h=fanduct_w,center=true,$fn=30);
      for(z=[-1,1]) translate([0,0,z*fanduct_w/2])
       sphere(r=fanduct_shell,$fn=30);
     }
  }
 }
         //     ***output
 module output(what,type=type) {
  module guideline(xyxy) {
   module pin(xy) {
    translate([xy[0],xy[1],0])
    cylinder(d=2*extrusion_width,h=2*fanduct_shell+inlet_h,$fn=6);
   }
   xyxyxy=concat(xyxy,[[0,dual?nozzles_apart/2:0]]);
   for(i=[0:1:len(xyxyxy)-2])
    hull() for(j=[i,i+1]) pin(xyxyxy[j]);
  }
  module circus(what) {
   if(what=="in") {
    difference() {
     rotate_extrude($fn=smooth_f)
      polygon([
       [0,-fanduct_elevation+fanduct_blowtarget+epsilon],
       [fanduct_ir+fanduct_shell,fanduct_shell+fanduct_h/2],
       [fanduct_ir+fanduct_shell+fanduct_w/2,0],
       [0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);
     translate([0,0,-1])
     cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);
     mirror([0,0,1])
     translate([0,0,-epsilon])
     cylinder(r=fanduct_ir+2*fanduct_shell+fanduct_w+1,h=fanduct_elevation+.1+2);
    }
   }else if(what=="out") {
    rotate_extrude($fn=smooth_f)
    polygon([
     [0,-fanduct_elevation+fanduct_blowtarget+epsilon],
     [fanduct_ir+fanduct_shell+1,fanduct_h/2],
     [fanduct_ir+fanduct_w/2+fanduct_shell+1,fanduct_shell],
     [0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);
   }else if(what=="airguides") {
    inr = fanduct_ir+fanduct_shell; our = inr+fanduct_w;
    union() {
     for(my=[0,1]) mirror([0,my,0]) {
      guideline([
       [-our,inlet_w/6],
       [-inr*sin(60),inr*cos(60)]
      ]);
      a0=30; as=15; a1=180;
      for(a=[a0+as:as:a1]) {
       f = as/(a1-a+as);
       rotate([0,0,a]) guideline([[-inr-fanduct_w*f,0]]);
      }
      guideline([
       [-our+fanduct_w*cos(30)*3/4,fanduct_w*sin(30)*3/4],
       [-inr*cos(10),inr*sin(10)]
      ]);
     }
    }/*union*/
   }/*airguides*/
  }
  module jets(what) {
   od = fanduct_h*2/3+fanduct_shell;
   md = fanduct_ir+fanduct_shell+fanduct_w/2;
   jww = 2*md*sin(jet_angle/2);
   difference() {
    for(a=[0:120:359]) rotate([0,0,a]) {
     if(what=="in") {
      hull() {
       intersection() {
        translate([md-fanduct_w/2,-jww/2,0])
        cube(size=[fanduct_shell+fanduct_w/2,jww,od]);
        duct(what=what);
       }
       translate([0,0,-fanduct_elevation]) sphere(r=.5);
      }
     }else if(what=="out") {
      hull() {
       intersection() {
        translate([md-fanduct_w/2,-jww/2+fanduct_shell,fanduct_shell])
        cube(size=[fanduct_w/2,jww-2*fanduct_shell,od-2*fanduct_shell]);
        duct(what=what);
       }
       translate([0,0,-fanduct_elevation]) sphere(r=.2);
      }
     }
    }
    if(what=="in") {
     translate([0,0,-fanduct_elevation-2+epsilon])
     cylinder(r=fanduct_ir+fanduct_shell*2+fanduct_w+1,h=fanduct_elevation+2);
     translate([0,0,-hotend_clearance])
     rotate([0,0,30])
     cylinder(r1=hotend_clearance*2,r2=0,h=hotend_clearance*2,$fn=6);
    }
   }
  }
  module dual(what=what) {
   module hulls(spots=dual_spots) {
    for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {
     for(p=[spots[pn],spots[pn+1]]) translate(p) children(0);
     children([1:$children-1]);
    }
   }
   if(what=="in") {
    cfn= 4; // clearance cutout $fn
    difference() {
     hulls() {
      cylinder(d=fanduct_w+2*fanduct_shell,h=2*fanduct_shell+fanduct_h/2);
      translate([0,-nozzles_apart/2,-fanduct_elevation-fanduct_blowtarget]) sphere(d=.1);
     }
     translate([0,0,epsilon]) hull() for(my=[0:1]) mirror([0,my,0]) for(s=dual_spots) translate(s)
      mirror([0,0,1]) cylinder(d=fanduct_w+2*fanduct_shell+2,h=fanduct_elevation-fanduct_blowtarget+1);
     for(s=[-1,1]) translate([0,s*nozzles_apart/2,-1])
      rotate([0,0,180/cfn]) cylinder(r=hotend_clearance/cos(180/cfn),h=fanduct_h+2*fanduct_shell+2,$fn=cfn);
    }
   }else if(what=="out") {
    hulls() {
     translate([0,0,fanduct_shell]) cylinder(d=fanduct_w,h=fanduct_h/2-fanduct_shell/2);
     translate([0,-nozzles_apart/2,-fanduct_elevation+fanduct_blowtarget]) sphere(d=.1);
    }
   }else if(what=="airguides") {
    far = fanduct_ir+fanduct_shell+fanduct_w;
    near = fanduct_ir;
    union() {
     for(my=[0,1]) mirror([0,my,0]) {
      guideline([ [-far             ,0], [0, nozzles_apart/8] ]);
      guideline([ [-far             ,inlet_w/2/4 ],
                  [-near            ,to_midduct/2] ]);
      guideline([ [-near-fanduct_w/3,  to_midduct/2       ],
                  [-near            ,nozzles_apart/2+near ] ]);
      guideline([ [0                ,nozzles_apart/2+near+fanduct_w*space_behind_nozzle/to_midduct] ]);
     }
    }
   }
  }
+  module dual_jets(what=what) {
+   od=fanduct_h*2/3+fanduct_shell;
+   md=fanduct_ir+fanduct_shell+fanduct_w/2;
+   jww = 2*md*sin(jet_angle/2);
+   difference() {
+    for(my=[0,1]) mirror([0,my,0])
+    translate([0,nozzles_apart/2,0])
+    for(a=[45,135]) rotate([0,0,a])
+    if(what=="in") {
+     hull() {
+      intersection() {
+       translate([md-fanduct_w/2,-jww/2,0])
+       cube(size=[fanduct_shell+fanduct_w/2,jww,od]);
+       rotate([0,0,-a]) translate([0,-nozzles_apart/2,0]) duct(what=what);
+      } // intersection
+      translate([0,0,-fanduct_elevation]) sphere(r=.5);
+     } // hull
+    }else if(what=="out") {
+     hull() {
+      intersection() {
+       translate([md-fanduct_w/2,-jww/2+fanduct_shell,fanduct_shell])
+       cube(size=[fanduct_w/2,jww-2*fanduct_shell,od-2*fanduct_shell]);
+       rotate([0,0,-a]) translate([0,-nozzles_apart/2,0]) duct(what=what);
+      } // intersection
+      translate([0,0,-fanduct_elevation]) sphere(r=.5);
+     } // hull
+    } // what=="out"
+    if(what=="in") {
+     translate([0,0,-fanduct_elevation/2-1+epsilon])
+     cube(size=[2*(fanduct_ir+2*fanduct_shell+fanduct_w+1),nozzles_apart+2*(fanduct_ir+2*fanduct_shell+fanduct_w+1),fanduct_elevation+2],center=true);
+     for(my=[0,1]) mirror([0,my,0])
+      translate([0,nozzles_apart/2,-hotend_clearance])
+      cylinder(r1=hotend_clearance*2,r2=0,h=hotend_clearance*2,$fn=4);
+    }
+   } // difference
+  }
  module dual_simple(what=what) {
   for(my=[0:1]) mirror([0,my,0]) if(what=="in") {
    difference() {
     hull() {
      translate([0,nozzles_apart/2+fanduct_ir+fanduct_shell+fanduct_w/2,0])
      cylinder(d=fanduct_w+2*fanduct_shell,h=fanduct_h*2/3+2*fanduct_shell);
      translate([0,nozzles_apart/2,-fanduct_elevation+fanduct_blowtarget])
      rotate([0,90,0]) cylinder(r=.5,h=fanduct_w*2,center=true);
     }
     rr = 2*(fanduct_ir+fanduct_shell*2+fanduct_w+2);
     translate([-rr/2,0,0]) mirror([0,0,1]) cube(size=[rr,rr,rr]);
    }
   }else if(what=="out") {
    hull() {
     translate([0,nozzles_apart/2+fanduct_ir+fanduct_shell+fanduct_w/2,fanduct_shell])
     cylinder(d=fanduct_w,h=fanduct_h*2/3);
     translate([0,nozzles_apart/2,-fanduct_elevation+fanduct_blowtarget])
     rotate([0,90,0]) cylinder(d=.5,h=fanduct_w*2,center=true);
    }
   }
  }
  if(dual) {
   if(type=="simple") dual_simple(what);
+   else if(type=="jets") dual_jets(what);
   else dual(what);
  }else if(type=="circular") circus(what);
  else if(type=="3jets") jets(what);
 }
         //     ***air intake
 module intake(what) {
  module placeit() {
   translate([-fanduct_ir-2*fanduct_shell-fanduct_w-inlet_away,0,fanduct_shell])
   rotate([0,-90,0])
   children();
  }
  if(what=="in") {
   placeit() translate([0,-inlet_w/2,0]) {
    difference() {
     cube(size=[inlet_h,inlet_w,inlet_long_l+fanduct_shell]); translate([inlet_h+fanduct_shell,0,inlet_long_l+fanduct_shell])
     rotate([-90,0,0])
     translate([0,0,-1])
     cylinder(r=inlet_h,h=inlet_w+2*fanduct_shell+2,$fn=inlet_h*4);
    }
    // supports
    for(i=[-1,0,1])
     translate([-fanduct_shell,
      (i+1)*(inlet_w-extrusion_width)/2,
     -inlet_away-fanduct_w/2])
     cube(size=[fanduct_shell+1,
      extrusion_width,
      inlet_long_l+fanduct_shell+inlet_away+fanduct_w/2]);
   }
   hull() {
    placeit() translate([-fanduct_shell,-inlet_w/2-fanduct_shell,0])
    cube(size=[inlet_h+2*fanduct_shell,inlet_w+2*fanduct_shell,fanduct_shell]);
    translate([-fanduct_ir-fanduct_shell-fanduct_w/2,0,0])
    translate([0,-inlet_w/2-fanduct_shell/2,0])
    cube(size=[1,inlet_w+fanduct_shell,fanduct_shell*2+fanduct_h]);
   }
  }else if(what=="out") {
   placeit() translate([fanduct_shell,-inlet_w/2+fanduct_shell,0])
   cube(size=[inlet_h-2*fanduct_shell,inlet_w-2*fanduct_shell,inlet_long_l+fanduct_shell+1]);
   hull() {
    placeit() translate([fanduct_shell,-inlet_w/2+fanduct_shell,0])
    cube(size=[inlet_h-2*fanduct_shell,inlet_w-2*fanduct_shell,fanduct_shell]);
    translate([-fanduct_ir-fanduct_shell-fanduct_w/2,0,fanduct_shell])
    translate([0,-inlet_w/2+fanduct_shell,0])
    cube(size=[1,inlet_w-2*fanduct_shell,fanduct_h]);
   }
  }
 }
         //     ***DUCT TAILS!!! WOO-OO! (every day they're out there making duct tails…)
 module tails(what) {
-  if(dual) {
+  if(dual && type=="simple") {
   // XXX: not sure if it will ever be
  }else{
   if(what=="in") {
    for(mx=[0,1]) mirror([mx,0,0])
    translate([fanduct_ir+fanduct_shell+fanduct_w/2,0,fanduct_shell+fanduct_h/2])
    rotate([90,0,90])
    translate([0,0,-snapper_d/2])
    snapper(d=snapper_d,o=snapper_overlap,side=0,l=fanduct_h*3/2+fanduct_shell);
   }
  }
 }
 module parts(what) {
  union() {
   duct(what);
   marks(what);
   output(what);
   intake(what);
   tails(what);
  }
 }
 difference() {
  parts("in");
  parts("out");
 }
 intersection() {
  union() {
   output("airguides");
   sphere(d=epsilon);
  }
  union() {
   duct("in"); output("in"); intake("in");
  }
 }
 }
 view="*"; // hcut|vcut|*
 hinfinity=4*(fanduct_ir+fanduct_shell*2+fanduct_w+inlet_away);
 vinfinity=2*(fanduct_shell*2+fanduct_h+inlet_h);
 if(view=="hcut") {
 difference() {
  fanduct();
  translate([-hinfinity/2,-hinfinity/2,fanduct_shell+fanduct_h/2])
  cube(size=[hinfinity,hinfinity,vinfinity]);
 }
 }else if(view=="vcut") {
 difference() {
  fanduct();
  translate([-hinfinity/2,0,-vinfinity/2])
  cube(size=[hinfinity,hinfinity,vinfinity]);
 }
 }else fanduct();
 /* vim:set sw=1 ai: */
author	Michael Krelin <hacker@klever.net>	2016-07-21 21:38:59 (UTC)
committer	Michael Krelin <hacker@klever.net>	2016-07-21 21:38:59 (UTC)
commit	9b39333e40abf93141ee39f40ef3733890ee0db8 (patch) (unidiff)
tree	125a56fc01499ee602e6f918a8b910fef5e6f0e3
parent	9cceb044d036c37c8c8703926c9c84d1d88cc2e0 (diff)
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