don't default to dual extrusion

author: Michael Krelin <hacker@klever.net> 2016-06-13 17:00:46 (UTC)
committer: Michael Krelin <hacker@klever.net> 2016-06-13 17:00:46 (UTC)
commit: 8ae83841f4b02964db406d2527d4e8a5b8d4906a (patch) (unidiff)
tree: 737652744d5e7f4baaa6d12525edcb6325d7c543
parent: 4ac6f9232e1bc986e9898eb76abb6c317b712be5 (diff)
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1 files changed, 1 insertions, 1 deletions
diff --git a/fanduct.scad b/fanduct.scad
index c402312..f5a7b7a 100644
--- a/fanduct.scad
+++ b/fanduct.scad
@@ -1,233 +1,233 @@
 use <snapper.scad>;
        extrusion_width=.5; layer_height=.2;    // print parameters
        epsilon=.005;   // for finer cuts
 function hypothenuse(a,b) = sqrt(pow(a,2)+pow(b,2));
 silicone_shell = 2;
 heater_clearance = 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
        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;
 hotend_clearance = heater_clearance;
        nozzles_apart = 18;     // distance between nozzles for dual hotend
        space_behind_nozzle = 15;// space behind the nozzle where we're allowed to go
                                // without the fear of hitting carriage
        snapper_d = 8; snapper_overlap=0.2;// snip snap
 smooth_f = 120;
        type="circular"; // circular|3jets
        ductshape="square"; // square|round
-        dual=true;      // dual or single
+        dual=false;     // dual or single
 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 single() {
   if(what=="in") {
    sh = fanduct_w+2*fanduct_shell; sv = fanduct_h+2*fanduct_shell;
    smax = max(sh,sv);
    rotate_extrude($fn=smooth_f)
     if(ductshape=="round")
      translate([sh/2+fanduct_ir,sv/2])
      scale([sh/smax,sv/smax])
      circle(d=smax,$fn=4*smax);
     else if(ductshape=="square")
      translate([fanduct_ir,0])
      square([sh,sv]);
   }else if(what=="out") {
    sh = fanduct_w; sv = fanduct_h;
    smax = max(sh,sv);
    rotate_extrude($fn=smooth_f)
     if(ductshape=="round")
      translate([sh/2+fanduct_shell+fanduct_ir,sv/2+fanduct_shell])
      scale([sh/smax,sv/smax])
      circle(d=smax,$fn=4*smax);
     else if(ductshape=="square")
      translate([fanduct_ir+fanduct_shell,fanduct_shell])
      union() {
       square([sh,sv/2]);
       translate([sh/2,sv/2])
       scale([sh/smax,sv/smax])
       circle(d=smax,$fn=36);
      }
   }
  }
  module dual() {
   module hulls(spots=dual_spots) {
    for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {
     for(p=[spots[pn],spots[pn+1]]) translate(p) children();
    }
   }
   if(what=="in") {
    hulls() cylinder(d=fanduct_w+2*fanduct_shell,h=fanduct_h+2*fanduct_shell);
   }else if(what=="out") {
    sh = fanduct_w; sv = fanduct_h;
    smax = max(sh,sv);
    translate([0,0,fanduct_shell]) hulls() {
     cylinder(d=fanduct_w,h=fanduct_h/2);
     translate([0,0,fanduct_h/2])
     scale([sh/smax,sh/smax,sv/smax])
     intersection() {
      sphere(d=smax,$fn=36);
      translate([0,0,-1])
      cylinder(d=smax+2,h=smax+2,$fn=36);
     }
    }
   }
  }
  if(dual) dual();
  else single();
 }
         //     ***bumps for easier position adjustments in line with hotend
 module marks(what) {
  if(what=="in") {
   for(y=[-1,1]) translate([0,dual?y*nozzles_apart/2:0,0])
    hull() for(z=[0,-fanduct_shell-fanduct_h/2])
     translate([0,y*(fanduct_ir+fanduct_shell+fanduct_w/2),fanduct_shell*2+fanduct_h+z])
     rotate([90,0,0]) {
      cylinder(r=fanduct_shell,h=fanduct_w,center=true,$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:$children-1]);
    }
   }
   if(what=="in") {
    difference() {
     hulls() {
      cylinder(d=fanduct_w+2*fanduct_shell,h=2*fanduct_shell+fanduct_h/2);
      translate([0,-nozzles_apart/2,-fanduct_elevation-fanduct_blowtarget]) sphere(d=.1);
     }
     translate([0,0,epsilon]) hull() for(my=[0:1]) mirror([0,my,0]) for(s=dual_spots) translate(s)
      mirror([0,0,1]) cylinder(d=fanduct_w+2*fanduct_shell+2,h=fanduct_elevation-fanduct_blowtarget+1);
     for(s=[-1,1]) translate([0,s*nozzles_apart/2,-1])
      cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);
    }
   }else if(what=="out") {
author	Michael Krelin <hacker@klever.net>	2016-06-13 17:00:46 (UTC)
committer	Michael Krelin <hacker@klever.net>	2016-06-13 17:00:46 (UTC)
commit	8ae83841f4b02964db406d2527d4e8a5b8d4906a (patch) (unidiff)
tree	737652744d5e7f4baaa6d12525edcb6325d7c543
parent	4ac6f9232e1bc986e9898eb76abb6c317b712be5 (diff)
download	fanductory-8ae83841f4b02964db406d2527d4e8a5b8d4906a.zip fanductory-8ae83841f4b02964db406d2527d4e8a5b8d4906a.tar.gz fanductory-8ae83841f4b02964db406d2527d4e8a5b8d4906a.tar.bz2

diff --git a/fanduct.scad b/fanduct.scad index c402312..f5a7b7a 100644 --- a/fanduct.scad +++ b/fanduct.scad
@@ -1,233 +1,233 @@
1	use <snapper.scad>;	1	use <snapper.scad>;
2	extrusion_width=.5; layer_height=.2; // print parameters	2	extrusion_width=.5; layer_height=.2; // print parameters
3		3
4	epsilon=.005; // for finer cuts	4	epsilon=.005; // for finer cuts
5		5
6	function hypothenuse(a,b) = sqrt(pow(a,2)+pow(b,2));	6	function hypothenuse(a,b) = sqrt(pow(a,2)+pow(b,2));
7		7
8	silicone_shell = 2;	8	silicone_shell = 2;
9	heater_clearance = max(	9	heater_clearance = max(
10	hypothenuse(16/2 +silicone_shell, 20-4.5 +silicone_shell),// E3D v6	10	hypothenuse(16/2 +silicone_shell, 20-4.5 +silicone_shell),// E3D v6
11	hypothenuse(11.5-4.5 +silicone_shell, 15.5 +silicone_shell)// E3D volcano	11	hypothenuse(11.5-4.5 +silicone_shell, 15.5 +silicone_shell)// E3D volcano
12	);	12	);
13		13
14	fanduct_elevation = 3; // fanduct elevation above nozzle tip	14	fanduct_elevation = 3; // fanduct elevation above nozzle tip
15	fanduct_blowtarget = -2; // what to blow at	15	fanduct_blowtarget = -2; // what to blow at
16	fanduct_h = 6; // inner height of the duct	16	fanduct_h = 6; // inner height of the duct
17	fanduct_w = 7; // inner width of the duct	17	fanduct_w = 7; // inner width of the duct
18	fanduct_shell=1.2; // shell thickness	18	fanduct_shell=1.2; // shell thickness
19	fanduct_ir = heater_clearance+5; // inner radius	19	fanduct_ir = heater_clearance+5; // inner radius
20		20
21	jet_angle = 60-2; // angular width of the jet	21	jet_angle = 60-2; // angular width of the jet
22		22
23	inlet_w = 12.5; // inlet width	23	inlet_w = 12.5; // inlet width
24	inlet_h = 17; // inlet height	24	inlet_h = 17; // inlet height
25	inlet_short_l = 7;// inlet length of protrusion (or depth of intrusion:))	25	inlet_short_l = 7;// inlet length of protrusion (or depth of intrusion:))
26	inlet_away = 15;// how far away inlet is	26	inlet_away = 15;// how far away inlet is
27		27
28	inlet_long_l = inlet_short_l+inlet_h;	28	inlet_long_l = inlet_short_l+inlet_h;
29	hotend_clearance = heater_clearance;	29	hotend_clearance = heater_clearance;
30		30
31	nozzles_apart = 18; // distance between nozzles for dual hotend	31	nozzles_apart = 18; // distance between nozzles for dual hotend
32	space_behind_nozzle = 15;// space behind the nozzle where we're allowed to go	32	space_behind_nozzle = 15;// space behind the nozzle where we're allowed to go
33	// without the fear of hitting carriage	33	// without the fear of hitting carriage
34		34
35	snapper_d = 8; snapper_overlap=0.2;// snip snap	35	snapper_d = 8; snapper_overlap=0.2;// snip snap
36		36
37	smooth_f = 120;	37	smooth_f = 120;
38		38
39	type="circular"; // circular\|3jets	39	type="circular"; // circular\|3jets
40	ductshape="square"; // square\|round	40	ductshape="square"; // square\|round
41	dual=true; // dual or single	41	dual=false; // dual or single
42		42
43	to_midduct = fanduct_ir+fanduct_shell+fanduct_w/2;	43	to_midduct = fanduct_ir+fanduct_shell+fanduct_w/2;
44	dual_spots = [ [+space_behind_nozzle, -(to_midduct+nozzles_apart/2)],	44	dual_spots = [ [+space_behind_nozzle, -(to_midduct+nozzles_apart/2)],
45	[- to_midduct, -(to_midduct+nozzles_apart/2)],	45	[- to_midduct, -(to_midduct+nozzles_apart/2)],
46	[- to_midduct, 0] ];	46	[- to_midduct, 0] ];
47		47
48	module fanduct(type=type,ductshape=ductshape,dual=dual) {	48	module fanduct(type=type,ductshape=ductshape,dual=dual) {
49	// ***duct is all around!	49	// ***duct is all around!
50	module duct(what) {	50	module duct(what) {
51	module single() {	51	module single() {
52	if(what=="in") {	52	if(what=="in") {
53	sh = fanduct_w+2fanduct_shell; sv = fanduct_h+2fanduct_shell;	53	sh = fanduct_w+2fanduct_shell; sv = fanduct_h+2fanduct_shell;
54	smax = max(sh,sv);	54	smax = max(sh,sv);
55	rotate_extrude($fn=smooth_f)	55	rotate_extrude($fn=smooth_f)
56	if(ductshape=="round")	56	if(ductshape=="round")
57	translate([sh/2+fanduct_ir,sv/2])	57	translate([sh/2+fanduct_ir,sv/2])
58	scale([sh/smax,sv/smax])	58	scale([sh/smax,sv/smax])
59	circle(d=smax,$fn=4*smax);	59	circle(d=smax,$fn=4*smax);
60	else if(ductshape=="square")	60	else if(ductshape=="square")
61	translate([fanduct_ir,0])	61	translate([fanduct_ir,0])
62	square([sh,sv]);	62	square([sh,sv]);
63	}else if(what=="out") {	63	}else if(what=="out") {
64	sh = fanduct_w; sv = fanduct_h;	64	sh = fanduct_w; sv = fanduct_h;
65	smax = max(sh,sv);	65	smax = max(sh,sv);
66	rotate_extrude($fn=smooth_f)	66	rotate_extrude($fn=smooth_f)
67	if(ductshape=="round")	67	if(ductshape=="round")
68	translate([sh/2+fanduct_shell+fanduct_ir,sv/2+fanduct_shell])	68	translate([sh/2+fanduct_shell+fanduct_ir,sv/2+fanduct_shell])
69	scale([sh/smax,sv/smax])	69	scale([sh/smax,sv/smax])
70	circle(d=smax,$fn=4*smax);	70	circle(d=smax,$fn=4*smax);
71	else if(ductshape=="square")	71	else if(ductshape=="square")
72	translate([fanduct_ir+fanduct_shell,fanduct_shell])	72	translate([fanduct_ir+fanduct_shell,fanduct_shell])
73	union() {	73	union() {
74	square([sh,sv/2]);	74	square([sh,sv/2]);
75	translate([sh/2,sv/2])	75	translate([sh/2,sv/2])
76	scale([sh/smax,sv/smax])	76	scale([sh/smax,sv/smax])
77	circle(d=smax,$fn=36);	77	circle(d=smax,$fn=36);
78	}	78	}
79	}	79	}
80	}	80	}
81	module dual() {	81	module dual() {
82	module hulls(spots=dual_spots) {	82	module hulls(spots=dual_spots) {
83	for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {	83	for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {
84	for(p=[spots[pn],spots[pn+1]]) translate(p) children();	84	for(p=[spots[pn],spots[pn+1]]) translate(p) children();
85	}	85	}
86	}	86	}
87	if(what=="in") {	87	if(what=="in") {
88	hulls() cylinder(d=fanduct_w+2fanduct_shell,h=fanduct_h+2fanduct_shell);	88	hulls() cylinder(d=fanduct_w+2fanduct_shell,h=fanduct_h+2fanduct_shell);
89	}else if(what=="out") {	89	}else if(what=="out") {
90	sh = fanduct_w; sv = fanduct_h;	90	sh = fanduct_w; sv = fanduct_h;
91	smax = max(sh,sv);	91	smax = max(sh,sv);
92	translate([0,0,fanduct_shell]) hulls() {	92	translate([0,0,fanduct_shell]) hulls() {
93	cylinder(d=fanduct_w,h=fanduct_h/2);	93	cylinder(d=fanduct_w,h=fanduct_h/2);
94	translate([0,0,fanduct_h/2])	94	translate([0,0,fanduct_h/2])
95	scale([sh/smax,sh/smax,sv/smax])	95	scale([sh/smax,sh/smax,sv/smax])
96	intersection() {	96	intersection() {
97	sphere(d=smax,$fn=36);	97	sphere(d=smax,$fn=36);
98	translate([0,0,-1])	98	translate([0,0,-1])
99	cylinder(d=smax+2,h=smax+2,$fn=36);	99	cylinder(d=smax+2,h=smax+2,$fn=36);
100	}	100	}
101	}	101	}
102	}	102	}
103	}	103	}
104		104
105	if(dual) dual();	105	if(dual) dual();
106	else single();	106	else single();
107	}	107	}
108		108
109	// ***bumps for easier position adjustments in line with hotend	109	// ***bumps for easier position adjustments in line with hotend
110	module marks(what) {	110	module marks(what) {
111	if(what=="in") {	111	if(what=="in") {
112	for(y=[-1,1]) translate([0,dual?y*nozzles_apart/2:0,0])	112	for(y=[-1,1]) translate([0,dual?y*nozzles_apart/2:0,0])
113	hull() for(z=[0,-fanduct_shell-fanduct_h/2])	113	hull() for(z=[0,-fanduct_shell-fanduct_h/2])
114	translate([0,y(fanduct_ir+fanduct_shell+fanduct_w/2),fanduct_shell2+fanduct_h+z])	114	translate([0,y(fanduct_ir+fanduct_shell+fanduct_w/2),fanduct_shell2+fanduct_h+z])
115	rotate([90,0,0]) {	115	rotate([90,0,0]) {
116	cylinder(r=fanduct_shell,h=fanduct_w,center=true,$fn=30);	116	cylinder(r=fanduct_shell,h=fanduct_w,center=true,$fn=30);
117	for(z=[-1,1]) translate([0,0,z*fanduct_w/2])	117	for(z=[-1,1]) translate([0,0,z*fanduct_w/2])
118	sphere(r=fanduct_shell,$fn=30);	118	sphere(r=fanduct_shell,$fn=30);
119	}	119	}
120	}	120	}
121	}	121	}
122		122
123	// ***output	123	// ***output
124	module output(what,type=type) {	124	module output(what,type=type) {
125	module guideline(xyxy) {	125	module guideline(xyxy) {
126	module pin(xy) {	126	module pin(xy) {
127	translate([xy[0],xy[1],0])	127	translate([xy[0],xy[1],0])
128	cylinder(d=2extrusion_width,h=2fanduct_shell+inlet_h,$fn=6);	128	cylinder(d=2extrusion_width,h=2fanduct_shell+inlet_h,$fn=6);
129	}	129	}
130	xyxyxy=concat(xyxy,[[0,dual?nozzles_apart/2:0]]);	130	xyxyxy=concat(xyxy,[[0,dual?nozzles_apart/2:0]]);
131	for(i=[0:1:len(xyxyxy)-2])	131	for(i=[0:1:len(xyxyxy)-2])
132	hull() for(j=[i,i+1]) pin(xyxyxy[j]);	132	hull() for(j=[i,i+1]) pin(xyxyxy[j]);
133	}	133	}
134		134
135	module circus(what) {	135	module circus(what) {
136	if(what=="in") {	136	if(what=="in") {
137	difference() {	137	difference() {
138	rotate_extrude($fn=smooth_f)	138	rotate_extrude($fn=smooth_f)
139	polygon([	139	polygon([
140	[0,-fanduct_elevation+fanduct_blowtarget+epsilon],	140	[0,-fanduct_elevation+fanduct_blowtarget+epsilon],
141	[fanduct_ir+fanduct_shell,fanduct_shell+fanduct_h/2],	141	[fanduct_ir+fanduct_shell,fanduct_shell+fanduct_h/2],
142	[fanduct_ir+fanduct_shell+fanduct_w/2,0],	142	[fanduct_ir+fanduct_shell+fanduct_w/2,0],
143	[0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);	143	[0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);
144	translate([0,0,-1])	144	translate([0,0,-1])
145	cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);	145	cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);
146	mirror([0,0,1])	146	mirror([0,0,1])
147	translate([0,0,-epsilon])	147	translate([0,0,-epsilon])
148	cylinder(r=fanduct_ir+2*fanduct_shell+fanduct_w+1,h=fanduct_elevation+.1+2);	148	cylinder(r=fanduct_ir+2*fanduct_shell+fanduct_w+1,h=fanduct_elevation+.1+2);
149	}	149	}
150	}else if(what=="out") {	150	}else if(what=="out") {
151	rotate_extrude($fn=smooth_f)	151	rotate_extrude($fn=smooth_f)
152	polygon([	152	polygon([
153	[0,-fanduct_elevation+fanduct_blowtarget+epsilon],	153	[0,-fanduct_elevation+fanduct_blowtarget+epsilon],
154	[fanduct_ir+fanduct_shell+1,fanduct_h/2],	154	[fanduct_ir+fanduct_shell+1,fanduct_h/2],
155	[fanduct_ir+fanduct_w/2+fanduct_shell+1,fanduct_shell],	155	[fanduct_ir+fanduct_w/2+fanduct_shell+1,fanduct_shell],
156	[0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);	156	[0,-fanduct_elevation+fanduct_blowtarget-epsilon]]);
157	}else if(what=="airguides") {	157	}else if(what=="airguides") {
158	inr = fanduct_ir+fanduct_shell; our = inr+fanduct_w;	158	inr = fanduct_ir+fanduct_shell; our = inr+fanduct_w;
159	union() {	159	union() {
160	for(my=[0,1]) mirror([0,my,0]) {	160	for(my=[0,1]) mirror([0,my,0]) {
161	guideline([	161	guideline([
162	[-our,inlet_w/6],	162	[-our,inlet_w/6],
163	[-inrsin(60),inrcos(60)]	163	[-inrsin(60),inrcos(60)]
164	]);	164	]);
165	a0=30; as=15; a1=180;	165	a0=30; as=15; a1=180;
166	for(a=[a0+as:as:a1]) {	166	for(a=[a0+as:as:a1]) {
167	f = as/(a1-a+as);	167	f = as/(a1-a+as);
168	rotate([0,0,a]) guideline([[-inr-fanduct_w*f,0]]);	168	rotate([0,0,a]) guideline([[-inr-fanduct_w*f,0]]);
169	}	169	}
170	guideline([	170	guideline([
171	[-our+fanduct_wcos(30)3/4,fanduct_wsin(30)3/4],	171	[-our+fanduct_wcos(30)3/4,fanduct_wsin(30)3/4],
172	[-inrcos(10),inrsin(10)]	172	[-inrcos(10),inrsin(10)]
173	]);	173	]);
174	}	174	}
175	}/union/	175	}/union/
176	}/airguides/	176	}/airguides/
177	}	177	}
178		178
179	module jets(what) {	179	module jets(what) {
180	od = fanduct_h*2/3+fanduct_shell;	180	od = fanduct_h*2/3+fanduct_shell;
181	md = fanduct_ir+fanduct_shell+fanduct_w/2;	181	md = fanduct_ir+fanduct_shell+fanduct_w/2;
182	jww = 2mdsin(jet_angle/2);	182	jww = 2mdsin(jet_angle/2);
183	difference() {	183	difference() {
184	for(a=[0:120:359]) rotate([0,0,a]) {	184	for(a=[0:120:359]) rotate([0,0,a]) {
185	if(what=="in") {	185	if(what=="in") {
186	hull() {	186	hull() {
187	intersection() {	187	intersection() {
188	translate([md-fanduct_w/2,-jww/2,0])	188	translate([md-fanduct_w/2,-jww/2,0])
189	cube(size=[fanduct_shell+fanduct_w/2,jww,od]);	189	cube(size=[fanduct_shell+fanduct_w/2,jww,od]);
190	duct(what=what);	190	duct(what=what);
191	}	191	}
192	translate([0,0,-fanduct_elevation]) sphere(r=.5);	192	translate([0,0,-fanduct_elevation]) sphere(r=.5);
193	}	193	}
194	}else if(what=="out") {	194	}else if(what=="out") {
195	hull() {	195	hull() {
196	intersection() {	196	intersection() {
197	translate([md-fanduct_w/2,-jww/2+fanduct_shell,fanduct_shell])	197	translate([md-fanduct_w/2,-jww/2+fanduct_shell,fanduct_shell])
198	cube(size=[fanduct_w/2,jww-2fanduct_shell,od-2fanduct_shell]);	198	cube(size=[fanduct_w/2,jww-2fanduct_shell,od-2fanduct_shell]);
199	duct(what=what);	199	duct(what=what);
200	}	200	}
201	translate([0,0,-fanduct_elevation]) sphere(r=.2);	201	translate([0,0,-fanduct_elevation]) sphere(r=.2);
202	}	202	}
203	}	203	}
204	}	204	}
205	if(what=="in") {	205	if(what=="in") {
206	translate([0,0,-fanduct_elevation-2+epsilon])	206	translate([0,0,-fanduct_elevation-2+epsilon])
207	cylinder(r=fanduct_ir+fanduct_shell*2+fanduct_w+1,h=fanduct_elevation+2);	207	cylinder(r=fanduct_ir+fanduct_shell*2+fanduct_w+1,h=fanduct_elevation+2);
208	translate([0,0,-hotend_clearance])	208	translate([0,0,-hotend_clearance])
209	rotate([0,0,30])	209	rotate([0,0,30])
210	cylinder(r1=hotend_clearance2,r2=0,h=hotend_clearance2,$fn=6);	210	cylinder(r1=hotend_clearance2,r2=0,h=hotend_clearance2,$fn=6);
211	}	211	}
212	}	212	}
213	}	213	}
214		214
215	module dual(what=what) {	215	module dual(what=what) {
216	module hulls(spots=dual_spots) {	216	module hulls(spots=dual_spots) {
217	for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {	217	for(my=[0,1]) mirror([0,my,0]) for(pn=[0:1:len(spots)-2]) hull() {
218	for(p=[spots[pn],spots[pn+1]]) translate(p) children(0);	218	for(p=[spots[pn],spots[pn+1]]) translate(p) children(0);
219	children([1:$children-1]);	219	children([1:$children-1]);
220	}	220	}
221	}	221	}
222	if(what=="in") {	222	if(what=="in") {
223	difference() {	223	difference() {
224	hulls() {	224	hulls() {
225	cylinder(d=fanduct_w+2fanduct_shell,h=2fanduct_shell+fanduct_h/2);	225	cylinder(d=fanduct_w+2fanduct_shell,h=2fanduct_shell+fanduct_h/2);
226	translate([0,-nozzles_apart/2,-fanduct_elevation-fanduct_blowtarget]) sphere(d=.1);	226	translate([0,-nozzles_apart/2,-fanduct_elevation-fanduct_blowtarget]) sphere(d=.1);
227	}	227	}
228	translate([0,0,epsilon]) hull() for(my=[0:1]) mirror([0,my,0]) for(s=dual_spots) translate(s)	228	translate([0,0,epsilon]) hull() for(my=[0:1]) mirror([0,my,0]) for(s=dual_spots) translate(s)
229	mirror([0,0,1]) cylinder(d=fanduct_w+2*fanduct_shell+2,h=fanduct_elevation-fanduct_blowtarget+1);	229	mirror([0,0,1]) cylinder(d=fanduct_w+2*fanduct_shell+2,h=fanduct_elevation-fanduct_blowtarget+1);
230	for(s=[-1,1]) translate([0,s*nozzles_apart/2,-1])	230	for(s=[-1,1]) translate([0,s*nozzles_apart/2,-1])
231	cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);	231	cylinder(r=hotend_clearance,h=fanduct_h+2*fanduct_shell+2,$fn=smooth_f);
232	}	232	}
233	}else if(what=="out") {	233	}else if(what=="out") {