Air flow switch holder: Difference between revisions
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This is the OpenSCAD code to create a wafer air flow sensor (and backflow preventer) to hold a microswitch to stop the laser from firing if the exhaust flow stops. Dimensions have been set to match the exhaust nozzle. The current version of the nacelle doesn't quite match, even though the nozzle was reverse engineered from it. | This is the OpenSCAD code to create a wafer air flow sensor (and backflow preventer) to hold a microswitch to stop the laser from firing if the exhaust flow stops. Dimensions have been set to match the exhaust nozzle. The current version of the nacelle doesn't quite match, even though the nozzle was reverse engineered from it. | ||
This was printed on 5/1 and it has some issues. | |||
#The arms which hold the switch body interfere with the flap plate. | |||
#The flap plate axis of rotation could be lowered to improve the balance. | |||
#The thickness of the wafer can be increased to reduce the warpage of the piece. | |||
<pre> | <pre> |
Revision as of 04:47, 3 May 2017
This is the OpenSCAD code to create a wafer air flow sensor (and backflow preventer) to hold a microswitch to stop the laser from firing if the exhaust flow stops. Dimensions have been set to match the exhaust nozzle. The current version of the nacelle doesn't quite match, even though the nozzle was reverse engineered from it.
This was printed on 5/1 and it has some issues.
- The arms which hold the switch body interfere with the flap plate.
- The flap plate axis of rotation could be lowered to improve the balance.
- The thickness of the wafer can be increased to reduce the warpage of the piece.
/* exhaust airflow detector safety interlock for cheap Chinese laser at Hac DC This switch is a lug style wafer for insertion between the exhaust collector and the exhaust nozzle on the back of the laser chassis. When the exhaust fan is running and air is flowing the switch will operate to allow the laser to fire. This switch is upstream of the exhaust fan so air will leak into the exhaust stream, not exhaust leaking out into room air. James Sullivan 4-20-17 OpenSCAD version 2015.03-1 --dimensions from mating exhaust nozzle-- nid=60; //nozzle inner diameter nod=80; //nozzle outer diameter mod=100; //maximum outer diameter sh=30; //step height sw=5; //step width oah=50; //over-all height tlw=3; //top ledge width bcd=46.8*2; //bolt circle diameter bhd=3.6; //bolt hole diameter fw=12; //foot width fh=15; //foot height fod=108; //foot outside dimension, from outside edge to outside edge fid=(nid+nod)/2;//foot inside dimension, from inside edge to inside edge */ fid=60; //flange inner diameter, same as nid fod=80; //flange outer diameter, same as nod bhd=3.6; //bolt hole diameter bcd=93.6;//bolt circle diameter hph=10; //hinge pin height above center line, i.e. butterfly offset. Reduce to make switch more sensitive. Increse to make switch more stable. sfw=sqrt(fid*fid-4*hph*hph); //switch flap width shd=2; //switch hole diameter shp=10; //switch hole pitch, i.e. center to center spacing of mounting holes on microswitch srh=8; //switch roller height, i.e. height above switch hole centerline where switching action occurs sbw=6; //switch body width nfw=5; //nut face width nt=1; //nut thickness thick=3; //thickness of flange $fn=80; difference(){ union(){ cylinder(d=fod,h=thick); //wafer body hull(){ //horizontal lugs translate([bcd/2,0,0]) cylinder(d=3*bhd, h=thick); translate([-bcd/2,0,0]) cylinder(d=3*bhd, h=thick); } rotate([0,0,90]) hull(){ //vertical lugs translate([bcd/2,0,0]) cylinder(d=3*bhd, h=thick); translate([-bcd/2,0,0]) cylinder(d=3*bhd, h=thick); } } translate([0,0,-thick/2]) intersection(){ //bore cylinder(d=fid, h=2*thick); //circular top and bottom cube([sfw,fod,thick*4],true); //vertical left and right } for (angle=[0:90:270]){ //bolt holes in lugs rotate([0,0,angle]) translate([bcd/2,0,-thick/2]) cylinder(d=bhd,h=thick*2); } for (angle=[55:5:65]){ //wire holes through flange translate([0,0,thick/2]) rotate([0,90,angle]) cylinder(d=1,h=bcd/2); } translate([0,hph,thick/2]) rotate([0,90,0]) cylinder(d=1,h=bcd+4*bhd,center=true); //hinge pin axle hole } translate([0,fid/2-shp-3*shd,0]){ //switch holder difference(){ union(){ translate([sbw/2,0,0]) cube([thick,shp+3*shd,3*shd]); //left mount flange translate([-sbw/2-thick,0,0]) cube([thick,shp+3*shd,3*shd]);//right mount flange } translate([-sbw/2-3/2*thick,3/2*shd,3/2*shd]) rotate([0,90,0]) cylinder(d=shd,h=sbw+3*thick); //lower bolt hole translate([-sbw/2-3/2*thick,shp+3/2*shd,3/2*shd]) rotate([0,90,0]) cylinder(d=shd,h=sbw+3*thick);//upper bolt hole for (angle=[0:120:240]){ translate([-sbw/2-thick,3/2*shd,3/2*shd]) rotate([angle,0,0]) cube([nt*2,nfw,nfw/sqrt(3)],center=true); //lower nut socket translate([-sbw/2-thick,shp+3/2*shd,3/2*shd]) rotate([angle,0,0]) cube([nt*2,nfw,nfw/sqrt(3)],center=true); //upper nut socket } } translate([sbw/2+thick,shp/2+shd*1.5,shd*1.5]) cylinder(d1=shd*1.2,d2=0,h=shd*1.5); //flow direction arrow head translate([sbw/2+thick,shp/2+shd*1.5,0]) cylinder(d=shd*0.6,h=shd*1.5); //flow direction arrow shaft translate([-sbw/2-thick,shp/2+shd*1.5,shd*1.5]) cylinder(d1=shd*1.2,d2=0,h=shd*1.5);//flow direction arrow head translate([-sbw/2-thick,shp/2+shd*1.5,0]) cylinder(d=shd*0.6,h=shd*1.5); //flow direction arrow shaft } translate([0,fid/2+bcd/2+bhd*2,0]) difference(){ //flap disk intersection(){ //bore cylinder(d=fid-0.5, h=thick); //circular top and bottom cube([sfw-0.5,fod,thick*2],true); //vertical left and right } translate([0,hph,thick/2]) rotate([0,90,0]) cylinder(d=1,h=bcd+4*bhd,center=true); //hinge pin axis }