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//
// NopSCADlib Copyright Chris Palmer 2018
// nop.head@gmail.com
// hydraraptor.blogspot.com
//
// This file is part of NopSCADlib.
//
// NopSCADlib is free software: you can redistribute it and/or modify it under the terms of the
// GNU General Public License as published by the Free Software Foundation, either version 3 of
// the License, or (at your option) any later version.
//
// NopSCADlib is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
// without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
// See the GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License along with NopSCADlib.
// If not, see <https://www.gnu.org/licenses/>.
//
//
//! Various electronic components used in hot ends and heated beds.
//
//
// Resistor model for hot end
//
include < ../core.scad >
include < tubings.scad >
include < spades.scad >
use < ../utils/rounded_cylinder.scad >
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use < ../utils/dogbones.scad >
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function resistor_length ( type ) = type [ 2 ] ; //! Body length
function resistor_diameter ( type ) = type [ 3 ] ; //! Body diameter
function resistor_wire_diameter ( type ) = type [ 4 ] ; //! Wire diameter
function resistor_wire_length ( type ) = type [ 5 ] ; //! Wire length from body
function resistor_hole ( type ) = type [ 6 ] ; //! Hole big enough to glue it into
function resistor_colour ( type ) = type [ 7 ] ; //! Body colour
function resistor_radial ( type ) = type [ 8 ] ; //! Radial gives bead thermistor style body
function resistor_sleeved ( type ) = type [ 9 ] ; //! Are the leads sleeved
splay_angle = 2 ; // radial lead splay angle
module resistor ( type ) { //! Draw specified type of resitor
length = resistor_length ( type ) ;
dia = resistor_diameter ( type ) ;
vitamin ( str ( "resistor(" , type [ 0 ] , "): " , type [ 1 ] ) ) ;
//
// wires
//
color ( [ 0.7 , 0.7 , 0.7 ] )
if ( resistor_radial ( type ) )
for ( side = [ - 1 , 1 ] )
translate ( [ side * dia / 6 , 0 , length / 2 ] )
rotate ( [ 0 , splay_angle * side , 0 ] )
cylinder ( r = resistor_wire_diameter ( type ) / 2 , h = resistor_wire_length ( type ) , center = false ) ;
else
cylinder ( r = resistor_wire_diameter ( type ) / 2 , h = length + 2 * resistor_wire_length ( type ) , center = true ) ;
//
// Sleeving
//
if ( resistor_sleeved ( type ) )
color ( [ 0.5 , 0.5 , 1 ] )
if ( resistor_radial ( type ) )
for ( side = [ - 1 , 1 ] )
translate ( [ side * resistor_diameter ( type ) / 6 , 0 , length / 2 ] ) {
rotate ( [ 0 , splay_angle * side , 0 ] )
cylinder ( r = resistor_wire_diameter ( type ) / 2 + 0.1 , h = resistor_wire_length ( type ) - 5 , center = false ) ; }
//
// Body
//
color ( resistor_colour ( type ) )
if ( resistor_radial ( type ) )
hull ( ) {
translate_z ( - length / 2 + dia / 2 )
sphere ( d = dia ) ;
cylinder ( d = dia / 2 , h = length / 2 ) ;
}
else
rotate_extrude ( )
for ( y = [ 0 , 1 ] )
mirror ( [ 0 , y ] )
rounded_corner ( r = dia / 2 , h = length / 2 , r2 = dia / 10 ) ;
}
module sleeved_resistor ( type , sleeving , bare = 5 , heatshrink = false ) { //! Draw a resistor with sleeved leads and option heatshrink
resistor ( type ) ;
sleeving_length = resistor_wire_length ( type ) - bare ;
for ( side = [ - 1 , 1 ] )
if ( resistor_radial ( type ) ) {
translate ( [ side * resistor_diameter ( type ) / 6 , 0 , 0 ] )
rotate ( [ 0 , splay_angle * side , 0 ] ) {
if ( ! resistor_sleeved ( type ) )
translate_z ( sleeving_length / 2 + resistor_length ( type ) / 2 + 20 * exploded ( ) )
tubing ( sleeving , sleeving_length ) ;
if ( heatshrink )
translate_z ( sleeving_length + resistor_length ( type ) / 2 + bare / 2 + 30 * exploded ( ) )
tubing ( heatshrink ) ;
}
}
else {
translate_z ( side * ( resistor_length ( type ) + sleeving_length + 40 * exploded ( ) ) / 2 )
tubing ( sleeving , sleeving_length ) ;
if ( heatshrink )
translate_z ( side * ( resistor_length ( type ) / 2 + sleeving_length + 30 * exploded ( ) ) )
tubing ( heatshrink ) ;
}
}
function al_clad_length ( type ) = type [ 1 ] ; //! Body length
function al_clad_width ( type ) = type [ 2 ] ; //! Width including tabs
function al_clad_tab ( type ) = type [ 3 ] ; //! Tab width
function al_clad_hpitch ( type ) = type [ 4 ] ; //! Lengthways pitch between screw holes
function al_clad_vpitch ( type ) = type [ 5 ] ; //! Widthways pitch between screw holes
function al_clad_thickness ( type ) = type [ 6 ] ; //! Tab thickness
function al_clad_hole ( type ) = type [ 7 ] ; //! Hole diameter
function al_clad_clearance ( type ) = type [ 8 ] ; //! Clearance from screw hole centre to the body
function al_clad_height ( type ) = type [ 9 ] ; //! Body height
function al_clad_wire_length ( type ) = type [ 10 ] ; //! Total length including wires
module al_clad_resistor_hole_positions ( type ) //! Position children at the screw holes of an aluminium clad resistor
for ( end = [ - 1 , 1 ] )
translate ( [ end * al_clad_hpitch ( type ) / 2 , end * al_clad_vpitch ( type ) / 2 , al_clad_thickness ( type ) ] )
children ( ) ;
module al_clad_resistor_holes ( type , h = 100 ) //! Drill screw holes for an aluminium clad resistor
al_clad_resistor_hole_positions ( type )
drill ( screw_clearance_radius ( al_clad_hole ( type ) > 3 ? M3_pan_screw : M2p5_pan_screw ) , h ) ;
module al_clad_resistor ( type , value , leads = true ) { //! Draw an aluminium clad resistor
vitamin ( str ( "al_clad_resistor(" , type [ 0 ] , ", " , value , arg ( leads , true , "leads" ) ,
"): Resistor aluminium clad " , type [ 0 ] , " " , value ) ) ;
length = al_clad_length ( type ) ;
width = al_clad_width ( type ) ;
height = al_clad_height ( type ) ;
tab = al_clad_tab ( type ) ;
thickness = al_clad_thickness ( type ) ;
terminal_h = 4 ;
terminal_t = 1 ;
terminal_l = 5 ;
body = al_clad_vpitch ( type ) - 2 * al_clad_clearance ( type ) ;
color ( "silver" ) {
rotate ( [ 90 , 0 , 90 ] )
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linear_extrude ( length , center = true )
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hull ( ) {
translate ( [ 0 , al_clad_height ( type ) / 2 ] )
intersection ( ) {
square ( [ body , al_clad_height ( type ) ] , center = true ) ;
circle ( body / 2 - eps ) ;
}
translate ( [ 0 , thickness / 2 ] )
square ( [ body , thickness ] , center = true ) ;
}
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linear_extrude ( thickness )
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difference ( ) {
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union ( )
for ( end = [ - 1 , 1 ] )
translate ( [ end * ( length - tab ) / 2 , end * ( width - width / 2 ) / 2 ] )
square ( [ tab , width / 2 ] , center = true ) ;
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al_clad_resistor_hole_positions ( type )
circle ( d = al_clad_hole ( type ) ) ;
}
if ( leads ) {
translate_z ( height / 2 )
rotate ( [ 0 , 90 , 0 ] )
cylinder ( r = 1 , h = al_clad_wire_length ( type ) - 2 * terminal_l + eps , center = true ) ;
for ( end = [ - 1 , 1 ] )
translate ( [ end * ( al_clad_wire_length ( type ) - terminal_l ) / 2 , 0 , height / 2 ] )
rotate ( [ 90 , 0 , 0 ] )
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linear_extrude ( terminal_t , center = true ) difference ( ) {
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square ( [ terminal_l , terminal_h ] , center = true ) ;
circle ( r = 1 ) ;
}
}
}
color ( "black" )
translate_z ( height / 2 )
rotate ( [ 0 , 90 , 0 ] )
cylinder ( r = leads ? 3 : height / 2 - 2 , h = length + eps , center = true ) ;
}
module al_clad_resistor_assembly ( type , value , sleeved = true ) { //* Draw aluminium clad resistor with optional sleaving, positions children at the screw positions
sleeving_length = 15 ;
sleeving = HSHRNK32 ;
al_clad_resistor ( type , value ) ;
if ( sleeved )
for ( end = [ - 1 , 1 ] )
translate ( [ end * ( al_clad_length ( type ) + sleeving_length + 0 ) / 2 , 0 , al_clad_height ( type ) / 2 ] )
rotate ( [ 0 , 90 , 0 ] )
scale ( [ 1.5 , 0.66 , 1 ] )
tubing ( sleeving , sleeving_length ) ;
al_clad_resistor_hole_positions ( type )
children ( ) ;
}
function TO220_thickness ( ) = 1.5 ; //! Thickness of the tab of a TO220
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module TO220 ( description , leads = 3 , lead_length = 16 ) { //! Draw a TO220 package, use `description` to describe what it is
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width = 10.2 ;
inset = 1.5 ;
hole = 3.3 ;
length = 15 ;
height = 4.4 ;
lead_height = 1.9 ;
lead_t = 0.4 ;
lead_w = 0.7 ;
lead_w2 = 1.4 ;
lead_l = 4.2 ;
body = 8 ;
hole_y = 2.9 ;
vitamin ( str ( "TO220(\"" , description , "\"" , arg ( leads , 3 , "leads" ) , arg ( lead_length , 16 , "lead_length" ) , "): " , description ) ) ;
translate ( [ 0 , - length + hole_y ] ) {
color ( "silver" ) {
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linear_extrude ( TO220_thickness ( ) )
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difference ( ) {
translate ( [ - width / 2 , inset ] )
square ( [ width , length - inset ] ) ;
translate ( [ 0 , length - hole_y ] )
circle ( d = hole ) ;
for ( side = [ - 1 , 1 ] )
translate ( [ side * width / 2 , 0 ] )
square ( [ inset * 2 , body * 2 ] , center = true ) ;
}
for ( i = [ - 1 : 1 ] )
if ( i || leads = = 3 ) {
translate ( [ inch ( 0.1 ) * i , - lead_length / 2 , lead_height ] )
cube ( [ lead_w , lead_length , lead_t ] , center = true ) ;
translate ( [ inch ( 0.1 ) * i , - lead_l / 2 , lead_height ] )
cube ( [ lead_w2 , lead_l , lead_t ] , center = true ) ;
}
}
color ( "dimgrey" )
translate ( [ - width / 2 , 0 , eps ] )
cube ( [ width , body , height ] ) ;
}
translate_z ( TO220_thickness ( ) )
children ( ) ;
}
panel_USBA_pitch = 30 ;
module panel_USBA_hole_positions ( ) //! Place children at hole positions
for ( side = [ - 1 , 1 ] )
translate ( [ side * panel_USBA_pitch / 2 , 0 ] )
children ( ) ;
module panel_USBA_holes ( h = 100 ) { //! Make holes for USBA connector
corner_clearance = 2 * cnc_bit_r * ( 1 - 1 / sqrt ( 2 ) ) ;
width = 5.5 + corner_clearance ;
length = 13 + corner_clearance ;
extrude_if ( h ) union ( ) {
rounded_square ( [ length , width ] , r = cnc_bit_r ) ;
panel_USBA_hole_positions ( )
drill ( M3_clearance_radius , 0 ) ;
}
}
module panel_USBA ( ) { //! Draw a panel mount USBA connector
vitamin ( "panel_USBA(): Socket USB A panel mount" ) ;
width = 12 ;
length = 40 ;
length2 = 22 ;
thickness = 5.5 ;
height = 33 ;
height2 = 27 ;
lead_dia = 10 ;
r1 = 1.5 ;
r2 = 5 ;
height3 = 9.5 ;
length3 = 17.5 ;
l = 17 ;
w = 13.3 ;
h = 5.7 ;
flange_t = 0.4 ;
h_flange_h = 0.8 ;
h_flange_l = 11.2 ;
v_flange_h = 0.8 ;
v_flange_l = 3.8 ;
tongue_w = 10 ;
tongue_t = 1.3 ;
vflip ( ) {
color ( "dimgrey" ) {
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linear_extrude ( thickness )
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difference ( ) {
hull ( )
for ( side = [ - 1 , 1 ] )
translate ( [ side * ( length / 2 - width / 2 ) , 0 ] )
circle ( d = width ) ;
square ( [ length3 , width + 1 ] , center = true ) ;
panel_USBA_hole_positions ( )
circle ( M3_clearance_radius ) ;
}
translate_z ( height2 )
cylinder ( d = lead_dia , h = height - height2 ) ;
hull ( ) {
dx = ( length2 / 2 - r2 ) ;
dy = ( width / 2 - r1 ) ;
translate_z ( l )
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rounded_rectangle ( [ length2 , width , 1 ] , r = r1 ) ;
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translate ( [ - dx , - dy , height2 - r2 ] )
rotate ( [ 90 , 0 , 0 ] )
rounded_cylinder ( r = r2 , r2 = r1 , h = r1 ) ;
translate ( [ dx , - dy , height2 - r2 ] )
rotate ( [ 90 , 0 , 0 ] )
rounded_cylinder ( r = r2 , r2 = r1 , h = r1 ) ;
translate ( [ - dx , dy , height2 - r2 ] )
rotate ( [ - 90 , 0 , 0 ] )
rounded_cylinder ( r = r2 , r2 = r1 , h = r1 ) ;
translate ( [ dx , dy , height2 - r2 ] )
rotate ( [ - 90 , 0 , 0 ] )
rounded_cylinder ( r = r2 , r2 = r1 , h = r1 ) ;
}
translate_z ( height3 )
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linear_extrude ( l - height3 )
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difference ( ) {
rounded_square ( [ length2 , width ] , r = r1 ) ;
square ( [ w - flange_t , h - flange_t ] , center = true ) ;
}
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linear_extrude ( height3 )
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difference ( ) {
rounded_square ( [ length2 , width ] , r = r1 ) ;
square ( [ length3 , width + 1 ] , center = true ) ;
}
}
* cube ( [ 12 , 4.5 , 32 ] , center = true ) ;
color ( "silver" ) {
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linear_extrude ( l )
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difference ( ) {
square ( [ w , h ] , center = true ) ;
square ( [ w - 2 * flange_t , h - 2 * flange_t ] , center = true ) ;
}
translate_z ( l - flange_t / 2 )
cube ( [ w , h , flange_t ] , center = true ) ;
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linear_extrude ( flange_t )
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difference ( ) {
union ( ) {
square ( [ h_flange_l , h + 2 * h_flange_h ] , center = true ) ;
square ( [ w + 2 * v_flange_h , v_flange_l ] , center = true ) ;
}
square ( [ w - 2 * flange_t , h - 2 * flange_t ] , center = true ) ;
}
}
color ( "white" )
translate ( [ 0 , h / 2 - 1 - tongue_t / 2 , l / 2 ] )
cube ( [ tongue_w , tongue_t , l ] , center = true ) ;
}
}
function tc_length ( type ) = type [ 1 ] ; //! Across the lugs
function tc_width ( type ) = type [ 2 ] ; //! Width of lugs
function tc_thickness ( type ) = type [ 3 ] ; //! Metal thickness
function tc_hole_dia ( type ) = type [ 4 ] ; //! Screw hole diameter
function tc_hole_pitch ( type ) = type [ 5 ] ; //! Screw hole pitch
function tc_body_length ( type ) = type [ 6 ] ; //! Plastic body length
function tc_body_width ( type ) = type [ 7 ] ; //! Plastic body width
function tc_body_height ( type ) = type [ 8 ] ; //! Plastic body height
function tc_body_inset ( type ) = type [ 9 ] ; //! How far metal is inset into the plastic body
function tc_spade_height ( type ) = type [ 10 ] ; //! Terminal spade height measured from base
function tc_spade_pitch ( type ) = type [ 11 ] ; //! Terminal spade pitch
module thermal_cutout_hole_positions ( type ) //! Place children at hole positions
for ( side = [ - 1 , 1 ] )
translate ( [ side * tc_hole_pitch ( type ) / 2 , 0 ] )
children ( ) ;
module thermal_cutout ( type ) { //! Draw specified thermal cutout
vitamin ( str ( "thermal_cutout(" , type [ 0 ] , "): Thermal cutout " , type [ 0 ] ) ) ;
w = tc_width ( type ) ;
t = tc_thickness ( type ) ;
h = tc_body_height ( type ) ;
bw = tc_body_width ( type ) ;
bl = tc_body_length ( type ) ;
spade = spade6p4 ;
color ( "silver" ) {
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linear_extrude ( tc_thickness ( type ) )
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difference ( ) {
hull ( )
for ( side = [ - 1 , 1 ] )
translate ( [ side * ( tc_length ( type ) - w ) / 2 , 0 ] )
circle ( d = w ) ;
thermal_cutout_hole_positions ( type )
circle ( d = tc_hole_dia ( type ) ) ;
}
body_inset = tc_body_inset ( type ) ;
translate_z ( ( h - body_inset ) / 2 )
cube ( [ bl - 2 * body_inset , bw + 2 * eps , h - body_inset ] , center = true ) ;
}
color ( "black" )
translate_z ( h / 2 + eps )
cube ( [ bl , bw , h ] , center = true ) ;
for ( side = [ - 1 , 1 ] )
translate ( [ side * tc_spade_pitch ( type ) / 2 , 0 , h ] )
rotate ( 90 )
spade ( spade , tc_spade_height ( type ) - h ) ;
translate_z ( t )
thermal_cutout_hole_positions ( type )
children ( ) ;
}
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function fack2spm_bezel_size ( ) = [ 19.2 , 35.5 , 2.6 , 2 ] ; //! FACK2SPM Bezel dimensions
module fack2spm_hole_positions ( ) //! Place children at the FACK2SPM mounting hole positions
for ( end = [ - 1 , 1 ] )
translate ( [ 0 , end * 28.96 / 2 ] )
children ( ) ;
function fack2spm_screw ( ) = M3_dome_screw ; //! Screw type for FACK2SPM
module fack2spm_holes ( h = 0 ) { //! Cut the holes for a FACK2SPM
fack2spm_hole_positions ( )
drill ( screw_clearance_radius ( fack2spm_screw ( ) ) , h ) ;
dogbone_rectangle ( [ 17.15 , 22.86 , h ] ) ;
}
module fack2spm ( ) { //! Draw a FACK2SPM Cat5E RJ45 shielded panel mount coupler
vitamin ( "tuk_fack2spm(): TUK FACK2SPM Cat5E RJ45 shielded panel mount coupler" ) ;
bezel = fack2spm_bezel_size ( ) ;
body = [ 16.8 , 22.8 , 9.8 ] ;
socket = [ 14.5 , 16.1 , 29.6 ] ;
y_offset = - ( 19.45 - 16.3 ) / 2 ;
plug = [ 12 , 6.8 , 10 ] ;
plug_y = y_offset - socket . y / 2 + 4 + plug . y / 2 ;
tab1 = [ 4 , 3 ] ;
tab2 = [ 6.3 , 1.6 ] ;
module socket ( )
translate ( [ 0 , y_offset ] )
square ( [ socket . x , socket . y ] , center = true ) ;
color ( "silver" ) {
linear_extrude ( bezel . z )
difference ( ) {
rounded_square ( [ bezel . x , bezel . y ] , bezel [ 3 ] ) ;
fack2spm_hole_positions ( )
circle ( d = 3.15 ) ;
socket ( ) ;
}
translate_z ( bezel . z - body . z )
linear_extrude ( body . z - eps )
difference ( ) {
square ( [ body . x , body . y ] , center = true ) ;
socket ( ) ;
}
translate_z ( bezel . z - socket . z )
linear_extrude ( socket . z - 0.1 )
difference ( ) {
offset ( - 0.1 ) socket ( ) ;
translate ( [ 0 , plug_y ] ) {
square ( [ plug . x , plug . y ] , center = true ) ;
translate ( [ 0 , - plug . y / 2 ] ) {
square ( [ tab1 . x , 2 * tab1 . y ] , center = true ) ;
square ( [ tab2 . x , 2 * tab2 . y ] , center = true ) ;
}
}
}
translate ( [ 0 , plug_y , - socket . z / 2 ] )
cube ( [ plug . x , plug . y , socket . z - 2 * plug . z ] , center = true ) ;
}
}