Updated cover pic

Made connector position based on encap height and added PCB.

core.scad

@@ -18,7 +18,7 @@
 //
 
 //
-// Include this file to use the miniumum library plus screws, nuts and washers
+// Include this file to use the minimum library plus screws, nuts and washers
 //
 include <utils/core/core.scad>
 //

global_defs.scad

@@ -33,7 +33,7 @@ $exploded       = is_undef($explode)         ? 0      : $explode;         // 1 f
 layer_height    = is_undef($layer_height)    ? 0.25   : $layer_height;    // layer heigth when printing
 extrusion_width = is_undef($extrusion_width) ? 0.5    : $extrusion_width; // filament width when printing
 nozzle          = is_undef($nozzle)          ? 0.45   : $nozzle;          // 3D printer nozzle
-cnc_bit_r       = is_undef($cnc_bit_r)       ? 1.2    : $cnc_bit_r;       // miniumum tool radius when milling 2D objects
+cnc_bit_r       = is_undef($cnc_bit_r)       ? 1.2    : $cnc_bit_r;       // minimum tool radius when milling 2D objects
 pp1_colour      = is_undef($pp1_colour)      ? [0, 146/255, 0] : $pp1_colour; // printed part colour 1, RepRap logo colour
 pp2_colour      = is_undef($pp2_colour)      ? "red"  : $pp2_colour;      // printed part colour 2
 pp3_colour      = is_undef($pp3_colour)      ? "blue" : $pp3_colour;      // printed part colour 3

lib.scad

@@ -43,6 +43,7 @@ include <vitamins/ldrs.scad>
 include <vitamins/leadnuts.scad>
 include <vitamins/led_meter.scad>
 include <vitamins/light_strips.scad>
+include <vitamins/magnets.scad>
 include <vitamins/mains_sockets.scad>
 include <vitamins/modules.scad>
 include <vitamins/panel_meters.scad>

libtest.scad

@@ -17,6 +17,23 @@
 // If not, see <https://www.gnu.org/licenses/>.
 //
 
+//!# NopSCADlib
+//! An ever expanding library of parts modelled in OpenSCAD useful for 3D printers and enclosures for electronics, etc.
+//!
+//! It contains lots of vitamins (the RepRap term for non-printed parts), some general purpose printed parts and some utilities.
+//! There are also Python scripts to generate Bills of Materials (BOMs),
+//! STL files for all the printed parts, DXF files for CNC routed parts in a project and a manual containing assembly
+//! instructions and exploded views by scraping markdown embedded in OpenSCAD comments, [see scripts](scripts/readme.md).
+//!
+//! A simple example project can be found [here](examples/MainsBreakOutBox/readme.md).
+//!
+//! For more examples of what it can make see the [gallery](gallery/readme.md).
+//!
+//! The license is GNU General Public License v3.0, see [COPYING](COPYING).
+//!
+//! See [usage](docs/usage.md) for requirements, installation instructions and a usage guide.
+//!
+//! <img src="libtest.png" width="100%"/>
 //
 // This file shows all the parts in the library.
 //
@@ -50,6 +67,7 @@ use <tests/LEDs.scad>
 use <tests/light_strips.scad>
 use <tests/linear_bearings.scad>
 use <tests/LED_meters.scad>
+use <tests/magnets.scad>
 use <tests/microswitches.scad>
 use <tests/modules.scad>
 use <tests/nuts.scad>
@@ -116,17 +134,17 @@ cable_grommets_y = 0;
 translate([x5, cable_grommets_y])
     cable_grommets();
 
-translate([x5, cable_grommets_y + 50])
-    feet();
+translate([x5 + 80, cable_grommets_y])
+    ribbon_clamps();
 
-translate([x5, cable_grommets_y + 75])
+translate([x5, cable_grommets_y + 60])
     fixing_blocks();
 
-translate([x5, cable_grommets_y + 100])
+translate([x5, cable_grommets_y + 90])
     corner_blocks();
 
 translate([x5, cable_grommets_y + 150])
-    ribbon_clamps();
+    feet();
 
 translate([x5 + 70, cable_grommets_y + 150])
     screw_knobs();
@@ -271,8 +289,9 @@ translate([x1, leadnuts_y])
 
 leds_y = 0;
 carriers_y = leds_y + 40;
-spades_y = carriers_y + 40;
-buttons_y = spades_y + 40;
+magnets_y = carriers_y + 40;
+spades_y = magnets_y + 20;
+buttons_y = spades_y + 20;
 jacks_y = buttons_y + 40;
 microswitches_y = jacks_y + 40;
 rockers_y = microswitches_y + 40;
@@ -288,6 +307,9 @@ translate([x2 + 35, leds_y])
 translate([x2 + 8, carriers_y])
     carriers();
 
+translate([x2, magnets_y])
+    magnets();
+
 translate([x2 + 20, carriers_y])
     led_meters();
 

printed/ribbon_clamp.scad

@@ -24,69 +24,72 @@ include <../core.scad>
 use <../vitamins/insert.scad>
 use <../vitamins/cable_strip.scad>
 
-wall = 2;
+wall = 1.6;
 min_wall = 2 * extrusion_width;
 screw = M3_cap_screw;
-insert = screw_insert(screw);
-screw_depth = insert_length(insert) + 1;
 
-function ribbon_clamp_hole_pitch(ways) = ribbon_clamp_slot(ways) + 2 * min_wall + 2 * corrected_radius(insert_hole_radius(insert)); //! Hole pitch
-function ribbon_clamp_width() = 2 * (insert_hole_radius(insert) + wall); //! Width
-function ribbon_clamp_length(ways) = ribbon_clamp_hole_pitch(ways) + ribbon_clamp_width(); //! Length given ways
-function ribbon_clamp_height() = screw_depth + 1; //! Height
+function ribbon_clamp_screw_depth(screw = screw) = insert_length(screw_insert(screw)) + 1;
+function ribbon_clamp_hole_pitch(ways, screw = screw) =
+    ribbon_clamp_slot(ways) + 2 * min_wall + 2 * corrected_radius(insert_hole_radius(screw_insert(screw))); //! Hole pitch
 
-module ribbon_clamp_hole_positions(ways, side = undef) //! Place children at hole positions
+function ribbon_clamp_width(screw = screw) = 2 * (insert_hole_radius(screw_insert(screw)) + wall); //! Width
+function ribbon_clamp_length(ways, screw = screw) = ribbon_clamp_hole_pitch(ways, screw) + ribbon_clamp_width(screw); //! Length given ways
+function ribbon_clamp_height(screw = screw) = ribbon_clamp_screw_depth(screw) + 1; //! Height
+
+module ribbon_clamp_hole_positions(ways, screw = screw, side = undef) //! Place children at hole positions
     for(x = is_undef(side) ? [-1, 1] : side)
-        translate([x * ribbon_clamp_hole_pitch(ways) / 2, 0])
+        translate([x * ribbon_clamp_hole_pitch(ways, screw) / 2, 0])
             children();
 
-module ribbon_clamp_holes(ways, h = 20) //! Drill screw holes
-    ribbon_clamp_hole_positions(ways)
+module ribbon_clamp_holes(ways, h = 20, screw = screw) //! Drill screw holes
+    ribbon_clamp_hole_positions(ways, screw)
         drill(screw_clearance_radius(screw), h);
 
-module ribbon_clamp(ways) { //! Generate STL for given number of ways
-    stl(str("ribbon_clamp_", ways));
+module ribbon_clamp(ways, screw = screw) { //! Generate STL for given number of ways
+    screw_d = screw_radius(screw) * 2;
+    stl(str("ribbon_clamp_", ways, screw_d != 3 ? str("_", screw_d) : ""));
 
-    pitch = ribbon_clamp_hole_pitch(ways);
-    d = ribbon_clamp_width();
-    h = ribbon_clamp_height();
-    t = h - ribbon_clamp_slot_depth() - wall;
+    pitch = ribbon_clamp_hole_pitch(ways, screw);
+    d = ribbon_clamp_width(screw);
+    h = ribbon_clamp_height(screw);
+    t = round_to_layer(ribbon_clamp_slot_depth() + wall);
+    insert = screw_insert(screw);
 
     difference() {
         union() {
             hull() {
                 translate_z(h - t / 2)
-                    cube([ribbon_clamp_hole_pitch(ways), d, t], center = true);
+                    cube([ribbon_clamp_hole_pitch(ways, screw), d, t], center = true);
 
                 translate_z(1)
                     cube([pitch, max(wall, d - 2 * (h - t)), 2], center = true);
             }
-            ribbon_clamp_hole_positions(ways, -1)
+            ribbon_clamp_hole_positions(ways, screw, -1)
                 cylinder(d = d, h = h);
 
-            ribbon_clamp_hole_positions(ways,  1)
+            ribbon_clamp_hole_positions(ways, screw, 1)
                 cylinder(d = d, h = h);
-
         }
 
         translate_z(h)
             cube([ribbon_clamp_slot(ways), d + 1, ribbon_clamp_slot_depth() * 2], center = true);
 
-        ribbon_clamp_hole_positions(ways)
+        ribbon_clamp_hole_positions(ways, screw)
             translate_z(h)
                 rotate(22.5)
-                    insert_hole(insert, screw_depth - insert_length(insert));
+                    insert_hole(insert, ribbon_clamp_screw_depth(screw) - insert_length(insert));
     }
 }
 
-module ribbon_clamp_assembly(ways) pose([55, 180, 25])  //! Printed part with inserts in place
-    assembly(str("ribbon_clamp_", ways)) {
-    h = ribbon_clamp_height();
+module ribbon_clamp_assembly(ways, screw) pose([55, 180, 25])  //! Printed part with inserts in place
+    assembly(let(screw_d = screw_radius(screw) * 2)str("ribbon_clamp_", ways, screw_d != 3 ? str("_", screw_d) : "")) {
+    h = ribbon_clamp_height(screw);
+    insert = screw_insert(screw);
 
     stl_colour(pp1_colour) render()
-        translate_z(h) vflip() ribbon_clamp(ways);
+        translate_z(h) vflip() ribbon_clamp(ways, screw);
 
-    ribbon_clamp_hole_positions(ways)
+    ribbon_clamp_hole_positions(ways, screw)
         vflip()
             insert(insert);
 }
@@ -99,20 +102,24 @@ module ribbon_clamp_fastened_assembly(ways, thickness, screw = screw) { //! Clam
     vitamin(str(": Tape self amalgamating silicone ",tape_l," x 25mm"));
 
     washer = screw_washer(screw);
-    screw_length = screw_shorter_than(2 * washer_thickness(washer) + thickness + screw_depth);
+    screw_length = screw_shorter_than(2 * washer_thickness(washer) + thickness + ribbon_clamp_screw_depth(screw));
 
-    ribbon_clamp_assembly(ways);
+    ribbon_clamp_assembly(ways, screw);
 
     color("red") translate_z(tape_thickness / 2)
         cube([tape_l, tape_width, tape_thickness], center = true);
 
-    ribbon_clamp_hole_positions(ways)
+    ribbon_clamp_hole_positions(ways, screw)
         vflip()
            translate_z(thickness)
                 screw_and_washer(screw, screw_length, true);
 }
 
 module ribbon_clamp_20_stl() ribbon_clamp(20);
+module ribbon_clamp_8_2_stl() ribbon_clamp(8, M2_dome_screw);
 
 //! * Place inserts into the holes and press home with a soldering iron with a conical bit heated to 200&deg;C.
 module ribbon_clamp_20_assembly() ribbon_clamp_assembly(20);
+
+//! * Place inserts into the holes and press home with a soldering iron with a conical bit heated to 200&deg;C.
+module ribbon_clamp_8_2_assembly() ribbon_clamp_assembly(8, M2_dome_screw);

readme.md

@@ -1,10 +1,12 @@
 # NopSCADlib
 An ever expanding library of parts modelled in OpenSCAD useful for 3D printers and enclosures for electronics, etc.
 
-It contains lots of vitamins (the RepRap term for non-printed parts), some general purpose printed parts and
-some utilities. There are also Python scripts to generate Bills of Materials (BOMs),
- STL files for all the printed parts, DXF files for CNC routed parts in a project and a manual containing assembly
-instructions and exploded views by scraping markdown embedded in OpenSCAD comments, [see scripts](scripts/readme.md). A simple example project can be found [here](examples/MainsBreakOutBox/readme.md).
+It contains lots of vitamins (the RepRap term for non-printed parts), some general purpose printed parts and some utilities.
+There are also Python scripts to generate Bills of Materials (BOMs),
+STL files for all the printed parts, DXF files for CNC routed parts in a project and a manual containing assembly
+instructions and exploded views by scraping markdown embedded in OpenSCAD comments, [see scripts](scripts/readme.md).
+
+A simple example project can be found [here](examples/MainsBreakOutBox/readme.md).
 
 For more examples of what it can make see the [gallery](gallery/readme.md).
 
@@ -20,27 +22,27 @@ See [usage](docs/usage.md) for requirements, installation instructions and a usa
 <th align="left"> Vitamins A-I </th><th align="left"> Vitamins J-Q </th><th align="left"> Vitamins R-Z </th><th align="left"> Printed </th><th align="left"> Utilities </th><th align="left"> Core Utilities </th></tr>
 <tr><td> <a href = "#Axials">Axials</a> </td><td> <a href = "#Jack">Jack</a> </td><td> <a href = "#Rails">Rails</a> </td><td> <a href = "#Box">Box</a> </td><td> <a href = "#Annotation">Annotation</a> </td><td> <a href = "#BOM">BOM</a> </td></tr>
 <tr><td> <a href = "#Ball_bearings">Ball_bearings</a> </td><td> <a href = "#KP_pillow_blocks">KP_pillow_blocks</a> </td><td> <a href = "#Ring_terminals">Ring_terminals</a> </td><td> <a href = "#Butt_box">Butt_box</a> </td><td> <a href = "#Bezier">Bezier</a> </td><td> <a href = "#Clip">Clip</a> </td></tr>
-<tr><td> <a href = "#Batteries">Batteries</a> </td><td> <a href = "#LDRs">LDRs</a> </td><td> <a href = "#Rockers">Rockers</a> </td><td> <a href = "#Cable_grommets">Cable_grommets</a> </td><td> <a href = "#Dogbones">Dogbones</a> </td><td> <a href = "#Global">Global</a> </td></tr>
-<tr><td> <a href = "#Belts">Belts</a> </td><td> <a href = "#LED_meters">LED_meters</a> </td><td> <a href = "#Rod">Rod</a> </td><td> <a href = "#Carriers">Carriers</a> </td><td> <a href = "#Fillet">Fillet</a> </td><td> <a href = "#Polyholes">Polyholes</a> </td></tr>
-<tr><td> <a href = "#Blowers">Blowers</a> </td><td> <a href = "#LEDs">LEDs</a> </td><td> <a href = "#SCS_bearing_blocks">SCS_bearing_blocks</a> </td><td> <a href = "#Corner_block">Corner_block</a> </td><td> <a href = "#Gears">Gears</a> </td><td> <a href = "#Rounded_rectangle">Rounded_rectangle</a> </td></tr>
-<tr><td> <a href = "#Bulldogs">Bulldogs</a> </td><td> <a href = "#Leadnuts">Leadnuts</a> </td><td> <a href = "#SK_brackets">SK_brackets</a> </td><td> <a href = "#Door_hinge">Door_hinge</a> </td><td> <a href = "#Hanging_hole">Hanging_hole</a> </td><td> <a href = "#Sphere">Sphere</a> </td></tr>
-<tr><td> <a href = "#Buttons">Buttons</a> </td><td> <a href = "#Light_strips">Light_strips</a> </td><td> <a href = "#SMDs">SMDs</a> </td><td> <a href = "#Door_latch">Door_latch</a> </td><td> <a href = "#Horiholes">Horiholes</a> </td><td> <a href = "#Teardrops">Teardrops</a> </td></tr>
-<tr><td> <a href = "#Cable_strips">Cable_strips</a> </td><td> <a href = "#Linear_bearings">Linear_bearings</a> </td><td> <a href = "#SSRs">SSRs</a> </td><td> <a href = "#Fan_guard">Fan_guard</a> </td><td> <a href = "#Layout">Layout</a> </td><td></td></tr>
-<tr><td> <a href = "#Cameras">Cameras</a> </td><td> <a href = "#Mains_sockets">Mains_sockets</a> </td><td> <a href = "#Screws">Screws</a> </td><td> <a href = "#Fixing_block">Fixing_block</a> </td><td> <a href = "#Maths">Maths</a> </td><td></td></tr>
-<tr><td> <a href = "#Circlips">Circlips</a> </td><td> <a href = "#Microswitches">Microswitches</a> </td><td> <a href = "#Sealing_strip">Sealing_strip</a> </td><td> <a href = "#Flat_hinge">Flat_hinge</a> </td><td> <a href = "#Offset">Offset</a> </td><td></td></tr>
-<tr><td> <a href = "#Components">Components</a> </td><td> <a href = "#Microview">Microview</a> </td><td> <a href = "#Sheets">Sheets</a> </td><td> <a href = "#Foot">Foot</a> </td><td> <a href = "#Quadrant">Quadrant</a> </td><td></td></tr>
-<tr><td> <a href = "#DIP">DIP</a> </td><td> <a href = "#Modules">Modules</a> </td><td> <a href = "#Spades">Spades</a> </td><td> <a href = "#Handle">Handle</a> </td><td> <a href = "#Round">Round</a> </td><td></td></tr>
-<tr><td> <a href = "#D_connectors">D_connectors</a> </td><td> <a href = "#Nuts">Nuts</a> </td><td> <a href = "#Spools">Spools</a> </td><td> <a href = "#PCB_mount">PCB_mount</a> </td><td> <a href = "#Rounded_cylinder">Rounded_cylinder</a> </td><td></td></tr>
-<tr><td> <a href = "#Displays">Displays</a> </td><td> <a href = "#O_ring">O_ring</a> </td><td> <a href = "#Springs">Springs</a> </td><td> <a href = "#PSU_shroud">PSU_shroud</a> </td><td> <a href = "#Rounded_polygon">Rounded_polygon</a> </td><td></td></tr>
-<tr><td> <a href = "#Extrusion_brackets">Extrusion_brackets</a> </td><td> <a href = "#Opengrab">Opengrab</a> </td><td> <a href = "#Stepper_motors">Stepper_motors</a> </td><td> <a href = "#Printed_box">Printed_box</a> </td><td> <a href = "#Sector">Sector</a> </td><td></td></tr>
-<tr><td> <a href = "#Extrusions">Extrusions</a> </td><td> <a href = "#PCB">PCB</a> </td><td> <a href = "#Swiss_clips">Swiss_clips</a> </td><td> <a href = "#Ribbon_clamp">Ribbon_clamp</a> </td><td> <a href = "#Sweep">Sweep</a> </td><td></td></tr>
-<tr><td> <a href = "#Fans">Fans</a> </td><td> <a href = "#PCBs">PCBs</a> </td><td> <a href = "#Toggles">Toggles</a> </td><td> <a href = "#SSR_shroud">SSR_shroud</a> </td><td> <a href = "#Thread">Thread</a> </td><td></td></tr>
-<tr><td> <a href = "#Fuseholder">Fuseholder</a> </td><td> <a href = "#PSUs">PSUs</a> </td><td> <a href = "#Transformers">Transformers</a> </td><td> <a href = "#Screw_knob">Screw_knob</a> </td><td> <a href = "#Tube">Tube</a> </td><td></td></tr>
-<tr><td> <a href = "#Geared_steppers">Geared_steppers</a> </td><td> <a href = "#Panel_meters">Panel_meters</a> </td><td> <a href = "#Tubings">Tubings</a> </td><td> <a href = "#Socket_box">Socket_box</a> </td><td></td><td></td></tr>
-<tr><td> <a href = "#Green_terminals">Green_terminals</a> </td><td> <a href = "#Pillars">Pillars</a> </td><td> <a href = "#Variacs">Variacs</a> </td><td> <a href = "#Strap_handle">Strap_handle</a> </td><td></td><td></td></tr>
-<tr><td> <a href = "#Hot_ends">Hot_ends</a> </td><td> <a href = "#Pin_headers">Pin_headers</a> </td><td> <a href = "#Veroboard">Veroboard</a> </td><td></td><td></td><td></td></tr>
-<tr><td> <a href = "#Hygrometer">Hygrometer</a> </td><td> <a href = "#Pulleys">Pulleys</a> </td><td> <a href = "#Washers">Washers</a> </td><td></td><td></td><td></td></tr>
-<tr><td> <a href = "#IECs">IECs</a> </td><td></td><td> <a href = "#Wire">Wire</a> </td><td></td><td></td><td></td></tr>
+<tr><td> <a href = "#Batteries">Batteries</a> </td><td> <a href = "#LDRs">LDRs</a> </td><td> <a href = "#Rockers">Rockers</a> </td><td> <a href = "#Cable_grommets">Cable_grommets</a> </td><td> <a href = "#Catenary">Catenary</a> </td><td> <a href = "#Global">Global</a> </td></tr>
+<tr><td> <a href = "#Belts">Belts</a> </td><td> <a href = "#LED_meters">LED_meters</a> </td><td> <a href = "#Rod">Rod</a> </td><td> <a href = "#Carriers">Carriers</a> </td><td> <a href = "#Dogbones">Dogbones</a> </td><td> <a href = "#Polyholes">Polyholes</a> </td></tr>
+<tr><td> <a href = "#Blowers">Blowers</a> </td><td> <a href = "#LEDs">LEDs</a> </td><td> <a href = "#SCS_bearing_blocks">SCS_bearing_blocks</a> </td><td> <a href = "#Corner_block">Corner_block</a> </td><td> <a href = "#Fillet">Fillet</a> </td><td> <a href = "#Rounded_rectangle">Rounded_rectangle</a> </td></tr>
+<tr><td> <a href = "#Bulldogs">Bulldogs</a> </td><td> <a href = "#Leadnuts">Leadnuts</a> </td><td> <a href = "#SK_brackets">SK_brackets</a> </td><td> <a href = "#Door_hinge">Door_hinge</a> </td><td> <a href = "#Gears">Gears</a> </td><td> <a href = "#Sphere">Sphere</a> </td></tr>
+<tr><td> <a href = "#Buttons">Buttons</a> </td><td> <a href = "#Light_strips">Light_strips</a> </td><td> <a href = "#SMDs">SMDs</a> </td><td> <a href = "#Door_latch">Door_latch</a> </td><td> <a href = "#Hanging_hole">Hanging_hole</a> </td><td> <a href = "#Teardrops">Teardrops</a> </td></tr>
+<tr><td> <a href = "#Cable_strips">Cable_strips</a> </td><td> <a href = "#Linear_bearings">Linear_bearings</a> </td><td> <a href = "#SSRs">SSRs</a> </td><td> <a href = "#Fan_guard">Fan_guard</a> </td><td> <a href = "#Horiholes">Horiholes</a> </td><td></td></tr>
+<tr><td> <a href = "#Cameras">Cameras</a> </td><td> <a href = "#Magnets">Magnets</a> </td><td> <a href = "#Screws">Screws</a> </td><td> <a href = "#Fixing_block">Fixing_block</a> </td><td> <a href = "#Layout">Layout</a> </td><td></td></tr>
+<tr><td> <a href = "#Circlips">Circlips</a> </td><td> <a href = "#Mains_sockets">Mains_sockets</a> </td><td> <a href = "#Sealing_strip">Sealing_strip</a> </td><td> <a href = "#Flat_hinge">Flat_hinge</a> </td><td> <a href = "#Maths">Maths</a> </td><td></td></tr>
+<tr><td> <a href = "#Components">Components</a> </td><td> <a href = "#Microswitches">Microswitches</a> </td><td> <a href = "#Sheets">Sheets</a> </td><td> <a href = "#Foot">Foot</a> </td><td> <a href = "#Offset">Offset</a> </td><td></td></tr>
+<tr><td> <a href = "#DIP">DIP</a> </td><td> <a href = "#Microview">Microview</a> </td><td> <a href = "#Spades">Spades</a> </td><td> <a href = "#Handle">Handle</a> </td><td> <a href = "#Quadrant">Quadrant</a> </td><td></td></tr>
+<tr><td> <a href = "#D_connectors">D_connectors</a> </td><td> <a href = "#Modules">Modules</a> </td><td> <a href = "#Spools">Spools</a> </td><td> <a href = "#PCB_mount">PCB_mount</a> </td><td> <a href = "#Round">Round</a> </td><td></td></tr>
+<tr><td> <a href = "#Displays">Displays</a> </td><td> <a href = "#Nuts">Nuts</a> </td><td> <a href = "#Springs">Springs</a> </td><td> <a href = "#PSU_shroud">PSU_shroud</a> </td><td> <a href = "#Rounded_cylinder">Rounded_cylinder</a> </td><td></td></tr>
+<tr><td> <a href = "#Extrusion_brackets">Extrusion_brackets</a> </td><td> <a href = "#O_ring">O_ring</a> </td><td> <a href = "#Stepper_motors">Stepper_motors</a> </td><td> <a href = "#Printed_box">Printed_box</a> </td><td> <a href = "#Rounded_polygon">Rounded_polygon</a> </td><td></td></tr>
+<tr><td> <a href = "#Extrusions">Extrusions</a> </td><td> <a href = "#Opengrab">Opengrab</a> </td><td> <a href = "#Swiss_clips">Swiss_clips</a> </td><td> <a href = "#Ribbon_clamp">Ribbon_clamp</a> </td><td> <a href = "#Sector">Sector</a> </td><td></td></tr>
+<tr><td> <a href = "#Fans">Fans</a> </td><td> <a href = "#PCB">PCB</a> </td><td> <a href = "#Toggles">Toggles</a> </td><td> <a href = "#SSR_shroud">SSR_shroud</a> </td><td> <a href = "#Sweep">Sweep</a> </td><td></td></tr>
+<tr><td> <a href = "#Fuseholder">Fuseholder</a> </td><td> <a href = "#PCBs">PCBs</a> </td><td> <a href = "#Transformers">Transformers</a> </td><td> <a href = "#Screw_knob">Screw_knob</a> </td><td> <a href = "#Thread">Thread</a> </td><td></td></tr>
+<tr><td> <a href = "#Geared_steppers">Geared_steppers</a> </td><td> <a href = "#PSUs">PSUs</a> </td><td> <a href = "#Tubings">Tubings</a> </td><td> <a href = "#Socket_box">Socket_box</a> </td><td> <a href = "#Tube">Tube</a> </td><td></td></tr>
+<tr><td> <a href = "#Green_terminals">Green_terminals</a> </td><td> <a href = "#Panel_meters">Panel_meters</a> </td><td> <a href = "#Variacs">Variacs</a> </td><td> <a href = "#Strap_handle">Strap_handle</a> </td><td></td><td></td></tr>
+<tr><td> <a href = "#Hot_ends">Hot_ends</a> </td><td> <a href = "#Pillars">Pillars</a> </td><td> <a href = "#Veroboard">Veroboard</a> </td><td></td><td></td><td></td></tr>
+<tr><td> <a href = "#Hygrometer">Hygrometer</a> </td><td> <a href = "#Pin_headers">Pin_headers</a> </td><td> <a href = "#Washers">Washers</a> </td><td></td><td></td><td></td></tr>
+<tr><td> <a href = "#IECs">IECs</a> </td><td> <a href = "#Pulleys">Pulleys</a> </td><td> <a href = "#Wire">Wire</a> </td><td></td><td></td><td></td></tr>
 <tr><td> <a href = "#Inserts">Inserts</a> </td><td></td><td> <a href = "#Zipties">Zipties</a> </td><td></td><td></td><td></td></tr>
 </table>
 
@@ -85,6 +87,7 @@ Axial components for PCBs.
 |   1 | ```ax_res(res1_4, 47000)``` |  Resistor 47000 Ohms 5% 0.25W |
 |   1 | ```ax_res(res1_2, 8200)``` |  Resistor 8200 Ohms 5% 0.5W |
 |   1 | ```ax_res(res1_2, 8250, tol = 1)``` |  Resistor 8250 Ohms 1% 0.5W |
+|   1 | ```wire_link(0.8, 10.16)``` |  Wire link 0.8mm x 0.4" |
 
 
 <a href="#top">Top</a>
@@ -209,6 +212,7 @@ Only models 2D paths, so not core XY!
 To make the back of the belt run against a smooth pulley on the outside of the loop specify a negative pitch radius.
 
 By default the path is a closed loop but a gap length and position can be specified to make open loops.
+To draw the gap its XY position is specified by ```gap_pos```. ```gap_pos.z``` can be used to specify a rotation if the gap is not at the bottom of the loop.
 
 Individual teeth are not drawn, instead they are represented by a lighter colour.
 
@@ -223,6 +227,7 @@ Individual teeth are not drawn, instead they are represented by a lighter colour
 | Function | Description |
 |:--- |:--- |
 | ```belt_pitch(type)``` | Pitch in mm |
+| ```belt_pitch_height(type)``` | Offset of the pitch radius from the tips of the teeth |
 | ```belt_thickness(type)``` | Total thickness including teeth |
 | ```belt_tooth_height(type)``` | Tooth height |
 | ```belt_width(type)``` | Width in mm |
@@ -231,12 +236,12 @@ Individual teeth are not drawn, instead they are represented by a lighter colour
 | Function | Description |
 |:--- |:--- |
 | ```belt_length(points, gap = 0)``` | Compute belt length given path and optional gap |
-| ```belt_pitch_height(type)``` | Offset of the pitch radius from the tips of the teeth |
+| ```belt_pitch_to_back(type)``` | Offset of the back from the pitch radius |
 
 ### Modules
 | Module | Description |
 |:--- |:--- |
-| ```belt(type, points, gap = 0, gap_pt = undef, belt_colour = grey(20)``` | Draw a belt path given a set of points and pitch radii where the pulleys are. Closed loop unless a gap is specified |
+| ```belt(type, points, gap = 0, gap_pos = undef, belt_colour = grey(20)``` | Draw a belt path given a set of points and pitch radii where the pulleys are. Closed loop unless a gap is specified |
 
 ![belts](tests/png/belts.png)
 
@@ -244,7 +249,7 @@ Individual teeth are not drawn, instead they are represented by a lighter colour
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
 |   1 | ```belt(GT2x6, [ ... ])``` |  Belt GT2 x 6mm x 128mm |
-|   1 | ```belt(GT2x6, [ ... ], 80, [0, 0.81])``` |  Belt GT2 x 6mm x 694mm |
+|   1 | ```belt(GT2x6, [ ... ], 80, [0, 0])``` |  Belt GT2 x 6mm x 696mm |
 |   1 | ```belt(T2p5x6, [ ... ])``` |  Belt T2.5 x 6mm x 130mm |
 |   1 | ```belt(T5x10, [ ... ])``` |  Belt T5 x 10mm x 130mm |
 |   1 | ```belt(T5x6, [ ... ])``` |  Belt T5 x 6mm x 130mm |
@@ -400,7 +405,7 @@ PCB mounted buttons. Can optionally have a coloured cap
 ## Cable_strips
 A strip of polypropylene used with ribbon cable to make a cable flexible in one direction only.
 
-Modelled with a Bezier spline, which is not quite the same as a miniumum energy curve but very close, epecially
+Modelled with a Bezier spline, which is not quite the same as a minimum energy curve but very close, epecially
 near the extreme positions, where the model needs to be accurate.
 
 When the sides are constrained then a circular model is more accurate.
@@ -900,7 +905,7 @@ Can draw three styles: solid, open frame and open frame with screw bosses.
 | ---:|:--- |:---|
 |   1 | ```fan(fan120x25)``` |  Fan 120mm x 25mm |
 |   1 | ```fan(fan17x8)``` |  Fan 17mm x 8mm |
-|   1 | ```fan(fan25x10)``` |  Fan 25mm x 10mm |
+|   1 | ```fan(fan25.4x10)``` |  Fan 25.4mm x 10mm |
 |   1 | ```fan(fan30x10)``` |  Fan 30mm x 10mm |
 |   1 | ```fan(fan40x11)``` |  Fan 40mm x 11mm |
 |   1 | ```fan(fan50x15)``` |  Fan 50mm x 15mm |
@@ -1250,6 +1255,7 @@ Heatfit threaded inserts. Can be pushed into thermoplastics using a soldering ir
 | Function | Description |
 |:--- |:--- |
 | ```insert_boss_radius(type, wall)``` | Compute the outer radius of an insert boss |
+| ```insert_nose_length(type, d)``` | The length before the second ring. |
 
 ### Modules
 | Module | Description |
@@ -1264,7 +1270,7 @@ Heatfit threaded inserts. Can be pushed into thermoplastics using a soldering ir
 ### Vitamins
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
-|   1 | ```insert(F1BM)``` |  Heatfit insert M2 |
+|   1 | ```insert(F1BM2)``` |  Heatfit insert M2 |
 |   1 | ```insert(F1BM2p5)``` |  Heatfit insert M2.5 |
 |   1 | ```insert(F1BM3)``` |  Heatfit insert M3 |
 |   1 | ```insert(F1BM4)``` |  Heatfit insert M4 |
@@ -1673,6 +1679,36 @@ LMnUU linear bearings.
 |   1 | ```linear_bearing(LM8UU)``` |  Linear bearing LM8UU |
 
 
+<a href="#top">Top</a>
+
+---
+<a name="Magnets"></a>
+## Magnets
+Cylindrical and ring magnets.
+
+
+[vitamins/magnets.scad](vitamins/magnets.scad) Object definitions.
+
+[vitamins/magnet.scad](vitamins/magnet.scad) Implementation.
+
+[tests/magnets.scad](tests/magnets.scad) Code for this example.
+
+### Properties
+| Function | Description |
+|:--- |:--- |
+| ```magnet_h(type)``` | Height |
+| ```magnet_id(type)``` | Inside diameter if a ring |
+| ```magnet_od(type)``` | Outer diameter |
+| ```magnet_r(type)``` | Corner radius |
+
+### Modules
+| Module | Description |
+|:--- |:--- |
+| ```magnet(type)``` | Draw specified magnet |
+
+![magnets](tests/png/magnets.png)
+
+
 <a href="#top">Top</a>
 
 ---
@@ -1976,6 +2012,8 @@ A permanent magnet that can be magnatized and de-magnatized electronically.
 | Function | Description |
 |:--- |:--- |
 | ```opengrab_depth()``` | Module height |
+| ```opengrab_pcb()``` | The PCB |
+| ```opengrab_pcb_z()``` | PCB offset from the front |
 | ```opengrab_target_thickness()``` | Target sheet thickness |
 | ```opengrab_width()``` | Module width |
 
@@ -2178,6 +2216,7 @@ PCBs and perfboard with optional components. The shape can be a rectangle with o
 |   1 | ```smd_resistor(RES0603, 1K)``` |  SMD resistor 0603 1K 0.1W |
 |   1 | ```smd_resistor(RES0805, 1K)``` |  SMD resistor 0805 1K 0.125W |
 |   1 | ```smd_resistor(RES1206, 1K)``` |  SMD resistor 1206 1K 0.25W |
+|   1 | ```square_button(button_4p5mm)``` |  Square button 4.5mm |
 |   1 | ```square_button(button_6mm)``` |  Square button 6mm |
 |   1 | ```pcb(TMC2130)``` |  TMC2130 |
 |   1 | ```green_terminal(gt_5p08, 2)``` |  Terminal block 2 way 0.2" |
@@ -2190,6 +2229,8 @@ PCBs and perfboard with optional components. The shape can be a rectangle with o
 |   2 | ```green_terminal(gt_3p5, 4)``` |  Terminal block 4 way 3.5mm |
 |   1 | ```terminal_35(4)``` |  Terminal block 4 way 3.5mm |
 |   1 | ```pcb(TestPCB)``` |  Test PCB |
+|   1 | ```wire_link(0.8, 5.08, h = 10.16)``` |  Wire link 0.8mm x 0.2" |
+|   1 | ```wire_link(0.8, 10.16)``` |  Wire link 0.8mm x 0.4" |
 
 
 <a href="#top">Top</a>
@@ -2293,14 +2334,14 @@ PCBs and perfboard with optional components. The shape can be a rectangle with o
 |   1 | ```pcb(EnviroPlus)``` |  Enviro+ |
 |   1 | ```pcb(ExtruderPCB)``` |  Extruder connection PCB |
 |   1 | ```pcb(Keyes5p1)``` |  Keyes5.1 Arduino Uno expansion board |
+|   1 | ```pcb(MP1584EN)``` |  MP1584EN 3A buck converter |
 |   1 | ```pcb(MT3608)``` |  MT3608 boost converter module |
-|   1 | ```pcb(Melzi)``` |  Melzi electronics |
-|   5 |  |  Micro SD card |
+|   4 |  |  Micro SD card |
 |   1 | ```molex_254(2)``` |  Molex KK header 2 way |
 |   1 | ```molex_254(3)``` |  Molex KK header 3 way |
 |  16 | ```nut(M2_nut, nyloc = true)``` |  Nut M2 x 1.6mm nyloc |
 |  34 | ```nut(M2p5_nut, nyloc = true)``` |  Nut M2.5 x 2.2mm nyloc |
-|  16 | ```nut(M3_nut, nyloc = true)``` |  Nut M3 x 2.4mm nyloc |
+|  12 | ```nut(M3_nut, nyloc = true)``` |  Nut M3 x 2.4mm nyloc |
 |  12 | ```nut(M4_nut, nyloc = true)``` |  Nut M4 x 3.2mm nyloc |
 |   1 | ```pcb(PI_IO)``` |  PI_IO V2 |
 |   1 | ```pcb(PSU12V1A)``` |  PSU 12V 1A |
@@ -2316,24 +2357,21 @@ PCBs and perfboard with optional components. The shape can be a rectangle with o
 |   1 | ```pcb(RPI0)``` |  Raspberry Pi Zero |
 |  12 | ```screw(M2_cap_screw, 16)``` |  Screw M2 cap x 16mm |
 |   4 | ```screw(M2_cap_screw, 20)``` |  Screw M2 cap x 20mm |
-|   2 | ```screw(M2p5_cap_screw, 16)``` |  Screw M2.5 cap x 16mm |
-|   4 | ```screw(M2p5_cap_screw, 20)``` |  Screw M2.5 cap x 20mm |
-|   4 | ```screw(M2p5_cap_screw, 25)``` |  Screw M2.5 cap x 25mm |
+|   2 | ```screw(M2p5_cap_screw, 20)``` |  Screw M2.5 cap x 20mm |
+|   8 | ```screw(M2p5_cap_screw, 25)``` |  Screw M2.5 cap x 25mm |
 |   8 | ```screw(M2p5_cap_screw, 30)``` |  Screw M2.5 cap x 30mm |
 |   4 | ```screw(M2p5_pan_screw, 20)``` |  Screw M2.5 pan x 20mm |
 |  12 | ```screw(M2p5_pan_screw, 25)``` |  Screw M2.5 pan x 25mm |
 |   4 | ```screw(M3_cap_screw, 16)``` |  Screw M3 cap x 16mm |
 |   8 | ```screw(M3_cap_screw, 30)``` |  Screw M3 cap x 30mm |
-|   4 | ```screw(M3_cap_screw, 35)``` |  Screw M3 cap x 35mm |
 |  12 | ```screw(M4_cap_screw, 35)``` |  Screw M4 cap x 35mm |
 |   1 | ```pcb(TP4056)``` |  TP4056 Li-lon Battery charger module |
 |   3 | ```terminal_35(2)``` |  Terminal block 2 way 3.5mm |
 |   2 | ```green_terminal(gt_2p54, 4)``` |  Terminal block 4 way 0.1" |
-|   1 |  |  USB A to Mini B lead |
 |   1 | ```pcb(WD2002SJ)``` |  WD2002SJ Buck Boost DC-DC converter |
 |  16 | ```washer(M2_washer)``` |  Washer  M2 x 5mm x 0.3mm |
 |  34 | ```washer(M2p5_washer)``` |  Washer  M2.5 x 5.9mm x 0.5mm |
-|  16 | ```washer(M3_washer)``` |  Washer  M3 x 7mm x 0.5mm |
+|  12 | ```washer(M3_washer)``` |  Washer  M3 x 7mm x 0.5mm |
 |  12 | ```washer(M4_washer)``` |  Washer  M4 x 9mm x 0.8mm |
 |   1 | ```pcb(ZC_A0591)``` |  ZC-A0591 ULN2003 driver PCB |
 
@@ -2344,22 +2382,21 @@ PCBs and perfboard with optional components. The shape can be a rectangle with o
 |   4 | pcb_spacer2070.stl |
 |   4 | pcb_spacer2080.stl |
 |   4 | pcb_spacer2090.stl |
-|   4 | pcb_spacer25100.stl |
 |   4 | pcb_spacer25110.stl |
 |   4 | pcb_spacer25120.stl |
-|   4 | pcb_spacer25130_2.stl |
+|   4 | pcb_spacer25130.stl |
 |   4 | pcb_spacer25140_2.stl |
 |   4 | pcb_spacer25150_2.stl |
-|   4 | pcb_spacer25180.stl |
+|   4 | pcb_spacer25160_2.stl |
 |   4 | pcb_spacer25190.stl |
-|   2 | pcb_spacer2570.stl |
-|   4 | pcb_spacer30160.stl |
+|   4 | pcb_spacer25200.stl |
+|   2 | pcb_spacer2580.stl |
 |   4 | pcb_spacer30170.stl |
-|   4 | pcb_spacer30230.stl |
+|   4 | pcb_spacer30180.stl |
 |   4 | pcb_spacer3050.stl |
-|   4 | pcb_spacer40200.stl |
 |   4 | pcb_spacer40210.stl |
 |   4 | pcb_spacer40220.stl |
+|   4 | pcb_spacer40230.stl |
 
 
 <a href="#top">Top</a>
@@ -2428,19 +2465,24 @@ Pin headers and sockets, etc.
 | Function | Description |
 |:--- |:--- |
 | ```hdr_base_colour(type)``` | Header insulator colour |
+| ```hdr_box_size(type)``` | Box header outside dimensions |
+| ```hdr_box_wall(type)``` | Box header wall thickness |
 | ```hdr_pin_below(type)``` | Header pin length underneath |
 | ```hdr_pin_colour(type)``` | Header pin colour |
 | ```hdr_pin_length(type)``` | Header pin length |
 | ```hdr_pin_width(type)``` | Header pin size |
 | ```hdr_pitch(type)``` | Header pitch |
+| ```hdr_ra_box_offset(type)``` | Offset between back of the box and the pins |
+| ```hdr_ra_height(type)``` | Height of right angle connector |
 | ```hdr_socket_depth(type)``` | Socket depth for female housing |
+| ```hdr_y_offset(type)``` | Y offset of pins from center of the box |
 
 ### Modules
 | Module | Description |
 |:--- |:--- |
 | ```box_header(type, cols = 1, rows = 1, smt = false, cutout = false)``` | Draw box header |
 | ```idc_transition(type, cols = 5, skip = [], cutout = false)``` | Draw IDC transition header |
-| ```jst_xh_header(type, pin_count, right_angle=false, colour, pin_colour)``` | Draw JST XH connector |
+| ```jst_xh_header(type, pin_count, right_angle = false, colour = false, pin_colour = false)``` | Draw JST XH connector |
 | ```pin(type, length = undef)``` | Draw a header pin |
 | ```pin_header(type, cols = 1, rows = 1, smt = false, right_angle = false, cutout = false, colour)``` | Draw pin header |
 | ```pin_socket(type, cols = 1, rows = 1, right_angle = false, height = 0, smt = false, cutout = false, colour)``` | Draw pin socket |
@@ -2451,11 +2493,18 @@ Pin headers and sockets, etc.
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
 |   1 | ```box_header(2p54header, 10, 2)``` |  Box header 10 x 2 |
+|   1 | ```box_header(2p54header, 8, 1)``` |  Box header 8 x 1 |
 |   1 | ```idc_transition(2p54header, 10)``` |  IDC transition header 10 x 2 |
 |   1 | ```pin_header(2p54header, 10, 2)``` |  Pin header 10 x 2 |
-|   1 | ```pin_header(2p54header, 10, 2, right_angle = true)``` |  Pin header 10 x 2 right_angle |
+|   1 | ```pin_header(2p54header, 3, 1, right_angle = true)``` |  Pin header 3 x 1 right_angle |
+|   1 | ```pin_header(2p54header, 3, 2, right_angle = true)``` |  Pin header 3 x 2 right_angle |
+|   1 | ```pin_header(2p54header, 3, 3, right_angle = true)``` |  Pin header 3 x 3 right_angle |
+|   1 | ```pin_header(2p54header, 8, 1)``` |  Pin header 8 x 1 |
 |   1 | ```pin_socket(2p54header, 10, 2)``` |  Pin socket 10 x 2 |
-|   1 | ```pin_socket(2p54header, 10, 2, right_angle = true)``` |  Pin socket 10 x 2 right_angle |
+|   1 | ```pin_socket(2p54header, 3, 1, right_angle = true)``` |  Pin socket 3 x 1 right_angle |
+|   1 | ```pin_socket(2p54header, 3, 2, right_angle = true)``` |  Pin socket 3 x 2 right_angle |
+|   1 | ```pin_socket(2p54header, 3, 3, right_angle = true)``` |  Pin socket 3 x 3 right_angle |
+|   1 | ```pin_socket(2p54header, 8, 1)``` |  Pin socket 8 x 1 |
 
 
 <a href="#top">Top</a>
@@ -2886,6 +2935,7 @@ Machine screws and wood screws with various head styles.
 |   1 | ```screw(No632_pan_screw, 30)``` |  Screw 6-32 pan x 30mm |
 |   1 | ```screw(M2_cap_screw, 10)``` |  Screw M2 cap x 10mm |
 |   1 | ```screw(M2_cs_cap_screw, 10)``` |  Screw M2 cs cap x 10mm |
+|   1 | ```screw(M2_dome_screw, 10)``` |  Screw M2 dome x 10mm |
 |   1 | ```screw(M2p5_cap_screw, 10)``` |  Screw M2.5 cap x 10mm |
 |   1 | ```screw(M2p5_pan_screw, 10)``` |  Screw M2.5 pan x 10mm |
 |   1 | ```screw(M3_cap_screw, 10)``` |  Screw M3 cap x 10mm |
@@ -3363,6 +3413,7 @@ NEMA stepper motor model.
 | ```NEMA_body_radius(type)``` | Body radius |
 | ```NEMA_boss_height(type)``` | Boss height |
 | ```NEMA_boss_radius(type)``` | Boss around the spindle radius |
+| ```NEMA_cap_heights(type)``` | Height of the end cap at the corner and the side |
 | ```NEMA_hole_pitch(type)``` | Screw hole pitch |
 | ```NEMA_length(type)``` | Body length |
 | ```NEMA_radius(type)``` | End cap radius |
@@ -3379,7 +3430,7 @@ NEMA stepper motor model.
 ### Modules
 | Module | Description |
 |:--- |:--- |
-| ```NEMA(type, shaft_angle = 0)``` | Draw specified NEMA stepper motor |
+| ```NEMA(type, shaft_angle = 0, jst_connector = false)``` | Draw specified NEMA stepper motor |
 | ```NEMA_outline(type)``` | 2D outline |
 | ```NEMA_screw_positions(type, n = 4)``` | Positions children at the screw holes |
 | ```NEMA_screws(type, screw, n = 4, screw_length = 8, earth = undef)``` | Place screws and optional earth tag |
@@ -4253,7 +4304,7 @@ Star washers can be omitted by setting ```star_washers``` to false.
 ### Vitamins
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
-|   3 | ```insert(F1BM)``` |  Heatfit insert M2 |
+|   3 | ```insert(F1BM2)``` |  Heatfit insert M2 |
 |   3 | ```insert(F1BM2p5)``` |  Heatfit insert M2.5 |
 |   3 | ```insert(F1BM3)``` |  Heatfit insert M3 |
 |   3 | ```insert(F1BM4)``` |  Heatfit insert M4 |
@@ -4415,7 +4466,7 @@ The ring spacing as well as the number of spokes can be specified, if zero a gas
 | ---:|:--- |
 |   1 | fan_guard_120.stl |
 |   1 | fan_guard_17.stl |
-|   1 | fan_guard_25.stl |
+|   1 | fan_guard_25.4.stl |
 |   1 | fan_guard_30.stl |
 |   1 | fan_guard_40.stl |
 |   1 | fan_guard_50.stl |
@@ -4473,7 +4524,7 @@ Star washers can be omitted by setting ```star_washers``` to false.
 ### Vitamins
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
-|   3 | ```insert(F1BM)``` |  Heatfit insert M2 |
+|   3 | ```insert(F1BM2)``` |  Heatfit insert M2 |
 |   3 | ```insert(F1BM2p5)``` |  Heatfit insert M2.5 |
 |   3 | ```insert(F1BM3)``` |  Heatfit insert M3 |
 |   3 | ```insert(F1BM4)``` |  Heatfit insert M4 |
@@ -4803,7 +4854,7 @@ It can also have printed feet on the base with the screws doubling up to hold th
 ### Vitamins
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
-|   4 | ```insert(F1BM)``` |  Heatfit insert M2 |
+|   4 | ```insert(F1BM2)``` |  Heatfit insert M2 |
 |   4 | ```insert(F1BM3)``` |  Heatfit insert M3 |
 |   4 | ```screw(M2_cap_screw, 6)``` |  Screw M2 cap x  6mm |
 |   3 | ```screw(M3_pan_screw, 6)``` |  Screw M3 pan x  6mm |
@@ -4902,41 +4953,48 @@ Clamp for ribbon cable and polypropylene strip.
 ### Functions
 | Function | Description |
 |:--- |:--- |
-| ```ribbon_clamp_height()``` | Height |
-| ```ribbon_clamp_hole_pitch(ways)``` | Hole pitch |
-| ```ribbon_clamp_length(ways)``` | Length given ways |
-| ```ribbon_clamp_width()``` | Width |
+| ```ribbon_clamp_height(screw = screw)``` | Height |
+| ```ribbon_clamp_length(ways, screw = screw)``` | Length given ways |
+| ```ribbon_clamp_width(screw = screw)``` | Width |
 
 ### Modules
 | Module | Description |
 |:--- |:--- |
-| ```ribbon_clamp(ways)``` | Generate STL for given number of ways |
-| ```ribbon_clamp_assembly(ways)``` | Printed part with inserts in place |
+| ```ribbon_clamp(ways, screw = screw)``` | Generate STL for given number of ways |
+| ```ribbon_clamp_assembly(ways, screw)``` | Printed part with inserts in place |
 | ```ribbon_clamp_fastened_assembly(ways, thickness, screw = screw)``` | Clamp with fasteners in place |
-| ```ribbon_clamp_hole_positions(ways, side = undef)``` | Place children at hole positions |
-| ```ribbon_clamp_holes(ways, h = 20)``` | Drill screw holes |
+| ```ribbon_clamp_hole_positions(ways, screw = screw, side = undef)``` | Place children at hole positions |
+| ```ribbon_clamp_holes(ways, h = 20, screw = screw)``` | Drill screw holes |
 
 ![ribbon_clamp](tests/png/ribbon_clamp.png)
 
 ### Vitamins
 | Qty | Module call | BOM entry |
 | ---:|:--- |:---|
+|   2 | ```insert(F1BM2)``` |  Heatfit insert M2 |
 |   2 | ```insert(F1BM3)``` |  Heatfit insert M3 |
 |   1 |  |  Ribbon cable 20 way 100mm |
+|   1 |  |  Ribbon cable 8 way 100mm |
+|   2 | ```screw(M2_dome_screw, 8)``` |  Screw M2 dome x  8mm |
 |   2 | ```screw(M3_cap_screw, 10)``` |  Screw M3 cap x 10mm |
+|   1 |  |  Tape self amalgamating silicone 11 x 25mm |
 |   1 |  |  Tape self amalgamating silicone 26 x 25mm |
+|   2 | ```washer(M2_washer)``` |  Washer  M2 x 5mm x 0.3mm |
 |   2 | ```washer(M3_washer)``` |  Washer  M3 x 7mm x 0.5mm |
+|   2 | ```star_washer(M2_washer)``` |  Washer star M2 x 0.3mm |
 |   2 | ```star_washer(M3_washer)``` |  Washer star M3 x 0.5mm |
 
 ### Printed
 | Qty | Filename |
 | ---:|:--- |
 |   1 | ribbon_clamp_20.stl |
+|   1 | ribbon_clamp_8_2.stl |
 
 ### Assemblies
 | Qty | Name |
 | ---:|:--- |
 |   1 | ribbon_clamp_20_assembly |
+|   1 | ribbon_clamp_8_2_assembly |
 
 
 <a href="#top">Top</a>
@@ -5191,6 +5249,36 @@ Bezier curves and function to get and adjust the length or minimum z point.
 ![bezier](tests/png/bezier.png)
 
 
+<a href="#top">Top</a>
+
+---
+<a name="Catenary"></a>
+## Catenary
+Catenary curve to model hanging wires, etc.
+
+Although the equation of the curve is simply ```y = a cosh(x / a)``` there is no explicit formula to calculate the constant ```a``` or the range of ```x``` given the
+length of the cable and the end point coordinates. See <https://en.wikipedia.org/wiki/Catenary#Determining_parameters>. The Newton-Raphson method is used to find
+```a``` numerically, see <https://en.wikipedia.org/wiki/Newton%27s_method>.
+
+The coordinates of the lowest point on the curve can be retrieved by calling ```catenary_points()``` with ```steps``` equal to zero.
+
+
+[utils/catenary.scad](utils/catenary.scad) Implementation.
+
+[tests/catenary.scad](tests/catenary.scad) Code for this example.
+
+### Functions
+| Function | Description |
+|:--- |:--- |
+| ```catenary(t, a)``` | Parametric catenary function linear along the length of the curve. |
+| ```catenary_ds_by_da(d, a)``` | First derivative of the length with respect to ```a```. |
+| ```catenary_find_a(d, l, a = 1, best_e = inf, best_a = 1)``` | Find the catenary constant ```a```, given half the horizontal span and the length. |
+| ```catenary_points(l, x, y, steps = 100)``` | Returns a list of 2D points on the curve that goes from the origin to ```(x,y)``` and has length ```l```. |
+| ```catenary_s(d, a)``` | Length of a symmetric catenary with width ```2d```. |
+
+![catenary](tests/png/catenary.png)
+
+
 <a href="#top">Top</a>
 
 ---
@@ -5307,6 +5395,8 @@ Method to print holes in mid air. See <https://hydraraptor.blogspot.com/2014/03/
 ## Horiholes
 Utilities for depicting the staircase slicing of horizontal holes made with [`teardrop_plus()`](#teardrops), see <https://hydraraptor.blogspot.com/2020/07/horiholes-2.html>
 
+```horicylinder()``` makes cylinders that fit inside a round hole. Layers that are less than 2 filaments wide and layers that need more than a 45 degree overhang are omitted.
+
 
 [utils/horiholes.scad](utils/horiholes.scad) Implementation.
 
@@ -5315,11 +5405,13 @@ Utilities for depicting the staircase slicing of horizontal holes made with [`te
 ### Functions
 | Function | Description |
 |:--- |:--- |
+| ```teardrop_minus_x(r, y, h)``` | Calculate the ordinate of a compensated teardrop given y and layer height. |
 | ```teardrop_plus_x(r, y, h)``` | Calculate the ordinate of a compensated teardrop given y and layer height. |
 
 ### Modules
 | Module | Description |
 |:--- |:--- |
+| ```horicylinder(r, z, h = 0, center = true)``` | For making horizontal cylinders that don't need support material and are correct dimensions |
 | ```horihole(r, z, h = 0, center = true)``` | For making horizontal holes that don't need support material and are correct dimensions |
 
 ![horiholes](tests/png/horiholes.png)
@@ -5366,7 +5458,14 @@ Maths utilities for manipulating vectors and matrices.
 | Function | Description |
 |:--- |:--- |
 | ```angle_between(v1, v2)``` | Return the angle between two vectors |
+| ```argcosh(x)``` | inverse hyperbolic cosine |
+| ```argcoth(x)``` | inverse hyperbolic cotangent |
+| ```argsinh(x)``` | inverse hyperbolic sine |
+| ```argtanh(x)``` | inverse hyperbolic tangent |
 | ```augment(m)``` | Augment a matrix by adding an identity matrix to the right |
+| ```circle_intersect(c1, r1, c2, r2)``` | Calculate one point where two circles in the X-Z plane intersect, clockwise around c1 |
+| ```cosh(x)``` | hyperbolic cosine |
+| ```coth(x)``` | hyperbolic cotangent |
 | ```degrees(radians)``` | Convert degrees to radians |
 | ```euler(R)``` | Convert a rotation matrix to a Euler rotation vector. |
 | ```identity(n, x = 1)``` | Construct an arbitrary size identity matrix |
@@ -5379,9 +5478,11 @@ Maths utilities for manipulating vectors and matrices.
 | ```rotate(a, v)``` | Generate a 4x4 rotation matrix, ```a``` can be a vector of three angles or a single angle around ```z```, or around axis ```v``` |
 | ```rowswap(m, i, j)``` | Swap two rows of a matrix |
 | ```scale(v)``` |  Generate a 4x4 matrix that scales by ```v```, which can be a vector of xyz factors or a scalar to scale all axes equally |
+| ```sinh(x)``` | hyperbolic sine |
 | ```solve(m, i = 0, j = 0)``` | Solve each row ensuring diagonal is not zero |
 | ```solve_row(m, i)``` | Make diagonal one by dividing the row by it and subtract from other rows to make column zero |
 | ```sqr(x)``` | Square x |
+| ```tanh(x)``` | hyperbolic tangent |
 | ```transform(v, m)``` | Apply 4x4 transform to a 3 vector by extending it and cropping it again |
 | ```transform_points(path, m)``` | Apply transform to a path |
 | ```translate(v)``` | Generate a 4x4 translation matrix, ```v``` can be ```[x, y]```, ```[x, y, z]``` or ```z``` |
@@ -5571,7 +5672,7 @@ An additional twist around the path can be specified. If the path is closed this
 ### Modules
 | Module | Description |
 |:--- |:--- |
-| ```sweep(path, profile, loop = false, twist = 0)``` | Draw a polyhedron that is the swept volume |
+| ```sweep(path, profile, loop = false, twist = 0, convexity = 1)``` | Draw a polyhedron that is the swept volume |
 
 ![sweep](tests/png/sweep.png)
 
@@ -5763,10 +5864,13 @@ Global constants, functions and modules. This file is used directly or indirectl
 | ```foot(x)``` | Foot to mm conversion |
 | ```in(list, x)``` | Returns true if ```x``` is an element in the ```list``` |
 | ```inch(x)``` | Inch to mm conversion (For fractional inches, 'inch(1 + 7/8)' will work as expected.) |
+| ```limit(x, min, max)``` | Force x in range min <= x <= max |
 | ```m(x)``` | m to mm conversion |
 | ```mm(x)``` | Explicit mm specified |
+| ```no_point(str)``` | Replace decimal point in string with 'p' |
 | ```r2sides(r)``` | Replicates the OpenSCAD logic to calculate the number of sides from the radius |
 | ```r2sides4n(r)``` | Round up the number of sides to a multiple of 4 to ensure points land on all axes |
+| ```slice(list, start = 0, end = undef)``` | Slice a list or string with Python type semantics |
 | ```sqr(x)``` | Returns the square of ```x``` |
 | ```yard(x)``` | Yard to mm conversion |
 
@@ -5812,7 +5916,7 @@ The module provides `poly_circle()`, `poly_cylinder()` and `poly_ring()` that is
 |:--- |:--- |
 | ```drill(r, h = 100, center = true)``` | Make a cylinder for drilling holes suitable for CNC routing, set h = 0 for circle |
 | ```poly_circle(r, sides = 0)``` | Make a circle adjusted to print the correct size |
-| ```poly_cylinder(r, h, center = false, sides = 0)``` | Make a cylinder adjusted to print the correct size |
+| ```poly_cylinder(r, h, center = false, sides = 0, chamfer = false)``` | Make a cylinder adjusted to print the correct size |
 | ```poly_drill(r, h = 100, center = true)``` | Make a cylinder for drilling holes suitable for CNC routing if cnc_bit_r is non zero, otherwise a poly_cylinder. |
 | ```poly_ring(or, ir, sides = 0)``` | Make a 2D ring adjusted to have the correct internal radius |
 | ```poly_tube(or, ir, h, center = false)``` | Make a tube adjusted to have the correct internal radius |

scripts/tests.py

@@ -97,7 +97,6 @@ def tests(tests):
     for dir in [deps_dir, png_dir, bom_dir]:
         if not os.path.isdir(dir):
             os.makedirs(dir)
-    doc_name = "readme.md"
     index = {}
     bodies = {}
     done = []
@@ -108,19 +107,33 @@ def tests(tests):
     #
     png_name = "libtest.png"
     scad_name = "libtest.scad"
-    if not os.path.isfile(png_name):
-        openscad.run(colour_scheme, "--projection=p", "--imgsize=%d,%d" % (w, h), "--camera=0,0,0,50,0,340,500", "--autocenter", "--viewall", "-o", png_name, scad_name);
-        do_cmd(["magick", png_name, "-trim", "-resize", "1280", "-bordercolor", background, "-border", "10", png_name])
+    if os.path.isfile(scad_name):
+        libtest = True
+        lib_blurb = scrape_blurb(scad_name)
+        if not os.path.isfile(png_name):
+            openscad.run(colour_scheme, "--projection=p", "--imgsize=%d,%d" % (w, h), "--camera=0,0,0,50,0,340,500", "--autocenter", "--viewall", "-o", png_name, scad_name);
+            do_cmd(["magick", png_name, "-trim", "-resize", "1280", "-bordercolor", background, "-border", "10", png_name])
+    else:
+        #
+        # Project tests so just a title
+        #
+        libtest = False
+        project = ' '.join(word[0].upper() + word[1:] for word in os.path.basename(os.getcwd()).split('_'))
+        lib_blurb = '#' + project + ' Tests\n'
+
+    doc_base_name = "readme" if libtest else "tests"
+    doc_name = doc_base_name + ".md"
     #
     # List of individual part files
     #
-    scads = [i for i in sorted(os.listdir(scad_dir), key = lambda s: s.lower()) if i[-5:] == ".scad"]
 
+    scads = [i for i in sorted(os.listdir(scad_dir), key = lambda s: s.lower()) if i[-5:] == ".scad"]
+    types = []
     for scad in scads:
         base_name = scad[:-5]
         if not tests or base_name in tests:
             done.append(base_name)
-            print(base_name)
+            print('\n'+base_name)
             cap_name = base_name[0].capitalize() + base_name[1:]
             base_name = base_name.lower()
             scad_name = scad_dir + '/' + scad
@@ -132,29 +145,42 @@ def tests(tests):
             if is_plural(base_name) and os.path.isfile(vits_name):
                 objects_name = vits_name
 
-            locations = [
-                ('vitamins/' + depluralise(base_name) + '.scad', 'Vitamins'),
-                ('printed/' + base_name + '.scad',               'Printed'),
-                ('utils/' + base_name + '.scad',                 'Utilities'),
-                ('utils/core/' + base_name + '.scad',            'Core Utilities'),
-            ]
+            locations = []
+            if os.path.isdir('vitamins'):
+                locations.append(('vitamins/' + depluralise(base_name) + '.scad', 'Vitamins'))
+            if os.path.isdir('printed'):
+                locations.append(('printed/' + base_name + '.scad',               'Printed'))
+            if os.path.isdir('utils'):
+                locations.append(('utils/' + base_name + '.scad',                 'Utilities'))
+            if libtest and os.path.isdir('utils/core'):
+                locations.append(('utils/core/' + base_name + '.scad',            'Core Utilities'))
 
             for name, type in locations:
                 if os.path.isfile(name):
                     impl_name = name
                     break
             else:
-                print("Can't find implementation!")
-                continue
+                if libtest:
+                    print("Can't find implementation!")
+                    continue
+                else:
+                    type = 'Tests'                         # OK when testing part of a project
+                    impl_name = None
 
-            vsplit = "AJR" + chr(ord('Z') + 1)
-            vtype = locations[0][1]
-            types = [vtype + ' ' + vsplit[i] + '-'  + chr(ord(vsplit[i + 1]) - 1) for i in range(len(vsplit) - 1)] + [loc[1] for loc in locations[1 :]]
-            if type == vtype:
-                for i in range(1, len(vsplit)):
-                    if cap_name[0] < vsplit[i]:
-                         type = types[i - 1]
-                         break
+            if libtest:
+                vsplit = "AJR" + chr(ord('Z') + 1)
+                vtype = locations[0][1]
+                types = [vtype + ' ' + vsplit[i] + '-' + chr(ord(vsplit[i + 1]) - 1) for i in range(len(vsplit) - 1)] + [loc[1] for loc in locations[1 :]]
+                if type == vtype:
+                    for i in range(1, len(vsplit)):
+                        if cap_name[0] < vsplit[i]:
+                             type = types[i - 1]
+                             break
+            else:
+                if not types:
+                    types = [loc[1] for loc in locations]   # No need to split up the vitamin list
+                    if not type in types:                   # Will happen when implementation is not found and type is set to Tests
+                        types.append(type)
 
             for t in types:
                 if not t in bodies:
@@ -250,24 +276,7 @@ def tests(tests):
         usage()
 
     with open(doc_name, "wt") as doc_file:
-        print('# NopSCADlib', file = doc_file)
-        print('''\
-An ever expanding library of parts modelled in OpenSCAD useful for 3D printers and enclosures for electronics, etc.
-
-It contains lots of vitamins (the RepRap term for non-printed parts), some general purpose printed parts and
-some utilities. There are also Python scripts to generate Bills of Materials (BOMs),
- STL files for all the printed parts, DXF files for CNC routed parts in a project and a manual containing assembly
-instructions and exploded views by scraping markdown embedded in OpenSCAD comments, [see scripts](scripts/readme.md). A simple example project can be found [here](examples/MainsBreakOutBox/readme.md).
-
-For more examples of what it can make see the [gallery](gallery/readme.md).
-
-The license is GNU General Public License v3.0, see [COPYING](COPYING).
-
-See [usage](docs/usage.md) for requirements, installation instructions and a usage guide.
-
-<img src="libtest.png" width="100%"/>\n
-''', file = doc_file)
-
+        print(lib_blurb, file = doc_file)
         print('## Table of Contents<a name="top"/>', file = doc_file)
         print('<table><tr>', file = doc_file)
         n = 0
@@ -288,10 +297,10 @@ See [usage](docs/usage.md) for requirements, installation instructions and a usa
         for type in types:
             for line in bodies[type]:
                 print(line, file = doc_file)
-    with open("readme.html", "wt") as html_file:
-        do_cmd("python -m markdown -x tables readme.md".split(), html_file)
+    with open(doc_base_name + ".html", "wt") as html_file:
+        do_cmd(("python -m markdown -x tables " + doc_name).split(), html_file)
     times.print_times()
-    do_cmd('codespell -L od readme.md'.split())
+    do_cmd(('codespell -L od ' + doc_name).split())
 
 if __name__ == '__main__':
     for arg in sys.argv[1:]:

tests/PCB.scad

@@ -86,10 +86,13 @@ test_pcb = ["TestPCB", "Test PCB",
         [  5, 218, 180, "hdmi"],
         [  3, 235, 180, "mini_hdmi"],
         [  6, 175, 180, "uSD", [12, 11.5, 1.4]],
+
+        [ 65,   9,   0, "link", inch(0.4)],
         [ 65,  12,   0, "ax_res", res1_8, 1000],
         [ 65,  17,   0, "ax_res", res1_4, 10000],
         [ 65,  22,   0, "ax_res", res1_2, 100000],
 
+        [ 80,   9,   0, "link", inch(0.2), inch(0.4)],
         [ 80,  12,   0, "ax_res", res1_8, 1000000, 1, inch(0.1)],
         [ 80,  17,   0, "ax_res", res1_4, 100,     2, inch(0.1)],
         [ 80,  22,   0, "ax_res", res1_2, 10,     10, inch(0.2)],
@@ -118,7 +121,8 @@ test_pcb = ["TestPCB", "Test PCB",
         [ 70, 130, 180, "term35", 3, "lime"],
         [ 50, 150,   0, "transition", 5],
         [ 50, 160,   0, "block", 10, 5, 8, "orange"],
-        [ 50, 170,   0, "button_6mm"],
+        [ 45, 170,   0, "button_6mm"],
+        [ 55, 170,   0, "button_4p5mm"],
         [ 50, 185,   0, "microswitch", small_microswitch],
         [ 52, 200,   0, "pcb", 11, TMC2130 ],
         [ 80, 200,   0, "pdip", 24, "27C32", true, inch(0.6) ],

tests/belts.scad

@@ -60,7 +60,7 @@ module belt_test() {
              [p4.x, p4.y, pulley_pr(GT2x20ob_pulley)]
            ];
     belt = GT2x6;
-    belt(belt, path, 80, [0,  belt_pitch_height(belt) - belt_thickness(belt) / 2]);
+    belt(belt, path, 80, [0,  0]);
 
     translate([-25, 0])
         layout([for(b = belts) belt_width(b)], 10)

tests/catenary.scad

@@ -0,0 +1,56 @@
+//
+// NopSCADlib Copyright Chris Palmer 2020
+// 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/>.
+//
+l = 250; // [1: 1000]
+x = 200; // [1: 1000]
+y = 50; //[-500 : 500]
+
+include <../utils/core/core.scad>
+use <../utils/catenary.scad>
+use <../utils/sweep.scad>
+use <../utils/annotation.scad>
+
+module catenaries() {
+    //
+    // catenary curve path from control points
+    //
+    curve = [for(p = catenary_points(l, x, y)) [p.x, p.y, 0]];
+    //
+    // Draw the curve
+    //
+    r = 0.5;
+    sweep(curve, circle_points(r, $fn = 64));
+    //
+    // Minimum Z
+    //
+    min_z = catenary_points(l, x, y, 0);
+
+    color("blue") {
+        translate([min_z.x, min_z.y + r])
+            rotate([-90, 0, 0])
+                arrow();
+
+        translate([min_z.x, min_z.y - r])
+            rotate([90, 0, 0])
+                arrow();
+    }
+}
+
+if($preview)
+    rotate(is_undef($bom) ? 0 : [70, 0, 315])
+        catenaries();

tests/foot.scad

@@ -21,14 +21,14 @@ use <../printed/foot.scad>
 
 module feet()
     if($preview) {
-        translate([50, 0])
+        translate([40, 0])
             foot_assembly(3);
 
         translate([foot_diameter(insert_foot()) / 2, 0])
             fastened_insert_foot_assembly(3);
     }
     else {
-        translate([50, 0])
+        translate([40, 0])
             foot();
 
         insert_foot();

tests/global.scad

@@ -29,6 +29,23 @@ module globals() {
         translate([50, 0])
             right_triangle(10, 20, 0);
     }
+    assert(slice("ABCD")    == "ABCD");
+    assert(slice("ABCD", 1) == "BCD");
+    assert(slice("ABCD", 2) == "CD");
+    assert(slice("ABCD", 3) == "D");
+    assert(slice("ABCD", 4) == "");
+    assert(slice("ABCD", 1, -1) == "BC");
+    assert(slice("ABCD", 2, -1) == "C");
+    assert(slice("ABCD", 3, -1) == "");
+    assert(slice("ABCD", 4, -1) == "");
+    assert(slice("ABCD", 0, -1) == "ABC");
+    assert(slice("ABCD", 0, -2) == "AB");
+    assert(slice("ABCD", 0, -3) == "A");
+    assert(slice("ABCD", 0, -4) == "");
+    assert(slice("ABCD", 0,  0) == "");
+    assert(slice("ABCD", 0,  1) == "A");
+    assert(slice("ABCD", 0,  2) == "AB");
+    assert(slice("ABCD", 0,  3) == "ABC");
 }
 
 rotate([70, 0, 315]) globals();

tests/horiholes.scad

@@ -69,9 +69,13 @@ module horiholes() {
             color(silver)
                 cylinder(r = $r, h = eps, center = true, $fn = 360);
 
+    hole_positions()
+        color("blue")
+            horicylinder(r = $r, z = $z, h = 2 * eps, center = true, $fn = 360);
+
     hole_positions()
         color("red")
-            linear_extrude(2 * eps, center = true)
+            linear_extrude(3 * eps, center = true)
                 intersection() {
                     difference() {
                         square(8, center = true);

tests/magnets.scad

@@ -0,0 +1,29 @@
+//
+// NopSCADlib Copyright Chris Palmer 2020
+// 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/>.
+//
+include <../core.scad>
+use <../utils/layout.scad>
+
+include <../vitamins/magnets.scad>
+
+module magnets()
+    layout([for(m = magnets) magnet_od(m)], 5)
+        magnet(magnets[$i]);
+
+if($preview)
+    magnets();

tests/maths.scad

@@ -69,6 +69,33 @@ module maths() {
     // Test Euler
     //
     assert(euler(rotate(r)) == r, "euler() failed");
+    //
+    // Circle intersect
+    //
+    r1 = 10;
+    c1 = [50, 0, 10];
+    r2 = 20;
+    c2 = [67, 0, 0];
+    p1 = circle_intersect(c1, r1, c2, r2);
+    p2 = circle_intersect(c2, r2, c1, r1);
+
+    rotate(90) {
+        color(grey(90))
+            translate(c1) rotate([90, 0, 0]) cylinder(r = r1, h = 4 * eps, center = true);
+
+        color(grey(80))
+            translate(c2) rotate([90, 0, 0]) cylinder(r = r2, h = eps, center = true);
+
+        color("red")
+            translate(p1) rotate([90, 0, 0]) cylinder(r = 0.1, h = 6 * eps, center = true);
+
+        color("blue")
+            translate(p2) rotate([90, 0, 0]) cylinder(r = 0.1, h = 6 * eps, center = true);
+
+        translate(p1) arrow();
+
+        translate(p2) vflip() arrow();
+    }
 }
 
 rotate(45)

tests/opengrab.scad

@@ -21,11 +21,11 @@ include <../utils/core/core.scad>
 use <../vitamins/opengrab.scad>
 
 module opengrab_test() {
-    opengrab_target();
-
     rotate(45)
-        translate_z(opengrab_target_thickness())
-            opengrab();
+        opengrab_target();
+
+    translate_z(opengrab_target_thickness())
+        opengrab();
 }
 
 if($preview)

tests/pin_headers.scad

@@ -23,26 +23,56 @@ include <../vitamins/pin_headers.scad>
 
 pins = 10;
 
-module pin_headers()
+module pin_headers() {
     layout([for(p = pin_headers) hdr_pitch(p) * pins], 15) {
         idc_transition(pin_headers[$i], 10);
 
         translate([0, 20])
-            pin_header(pin_headers[$i], 10, 2, right_angle = true);
+            pin_header(pin_headers[$i], 3, 2, right_angle = true);
+
+        translate([-10, 20])
+            pin_header(pin_headers[$i], 3, 1, right_angle = true);
+
+         translate([10, 20])
+            pin_header(pin_headers[$i], 3, 3, right_angle = true);
+
+        translate([0, 30])
+            pin_header(pin_headers[$i], 8, 1);
 
         translate([0, 40])
             pin_header(pin_headers[$i], 10, 2);
 
+        translate([0, 50])
+            box_header(pin_headers[$i], 8, 1);
+
         translate([0, 60])
             box_header(pin_headers[$i], 10, 2);
 
+        translate([0, 70])
+            pin_socket(pin_headers[$i], 8, 1);
+
         translate([0, 80])
             pin_socket(pin_headers[$i], 10, 2);
 
-        translate([0, 110])
-            pin_socket(pin_headers[$i], 10, 2, right_angle = true);
+        translate([-10, 105])
+            pin_socket(pin_headers[$i], 3, 1, right_angle = true);
 
+        translate([0, 105])
+            pin_socket(pin_headers[$i], 3, 2, right_angle = true);
+
+        translate([10, 105])
+            pin_socket(pin_headers[$i], 3, 3, right_angle = true);
     }
 
+    for(i = [0, 1], p = [5, 2][i], j = [0 , 1]) {
+        h = [jst_ph_header, jst_xh_header][j];
+        translate([-20 * (i + 1), 0 + j * 40])
+            jst_xh_header(h, p);
+
+        translate([-20 * (i + 1), 20 + j * 40])
+            jst_xh_header(h, p, true);
+    }
+}
+
 if($preview)
     pin_headers();

tests/ribbon_clamp.scad

@@ -16,20 +16,22 @@
 // You should have received a copy of the GNU General Public License along with NopSCADlib.
 // If not, see <https://www.gnu.org/licenses/>.
 //
-include <../utils/core/core.scad>
+include <../core.scad>
 use <../printed/ribbon_clamp.scad>
 use <../vitamins/wire.scad>
 
-ways = 20;
+ways = [8, 20];
+screws = [M2_dome_screw, M3_cap_screw];
 
 module ribbon_clamps()
-    translate([ribbon_clamp_length(ways) / 2, 0])
-        if($preview) {
-            ribbon_clamp_fastened_assembly(ways, 3);
+    for(i = [0 : len(screws) - 1])
+        translate([ribbon_clamp_length(ways[i]) / 2, i * 30])
+            if($preview) {
+                ribbon_clamp_fastened_assembly(ways[i], 3, screws[i]);
 
-            ribbon_cable(ways, 100);
-        }
-        else
-            ribbon_clamp(ways);
+                ribbon_cable(ways[i], 100);
+            }
+            else
+                ribbon_clamp(ways[i], screws[i]);
 
 ribbon_clamps();

tests/stepper_motors.scad

@@ -22,12 +22,12 @@ include <../vitamins/stepper_motors.scad>
 use <../utils/layout.scad>
 
 module stepper_motors()
-    layout([for(s = stepper_motors) NEMA_width(s)], 5) {
+    layout([for(s = stepper_motors) NEMA_width(s)], 5) let(m = stepper_motors[$i]) {
         rotate(180)
-            NEMA(stepper_motors[$i]);
+            NEMA(m, 0, m == NEMA17M || m == NEMA17M8);
 
         translate_z(4)
-            NEMA_screws(stepper_motors[$i], M3_pan_screw, n = $i, earth = $i > 4 ? undef : $i - 1);
+            NEMA_screws(m, M3_pan_screw, n = $i, earth = $i > 4 ? undef : $i - 1);
     }
 
 if($preview)

utils/catenary.scad

@@ -0,0 +1,52 @@
+//
+// NopSCADlib Copyright Chris Palmer 2020
+// 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/>.
+//
+
+//
+//! Catenary curve to model hanging wires, etc.
+//!
+//! Although the equation of the curve is simply ```y = a cosh(x / a)``` there is no explicit formula to calculate the constant ```a``` or the range of ```x``` given the
+//! length of the cable and the end point coordinates. See <https://en.wikipedia.org/wiki/Catenary#Determining_parameters>. The Newton-Raphson method is used to find
+//! ```a``` numerically, see <https://en.wikipedia.org/wiki/Newton%27s_method>.
+//!
+//! The coordinates of the lowest point on the curve can be retrieved by calling ```catenary_points()``` with ```steps``` equal to zero.
+//
+include <core/core.scad>
+use <maths.scad>
+
+function catenary(t, a) = let(u = argsinh(t)) a * [u, cosh(u)]; //! Parametric catenary function linear along the length of the curve.
+function catenary_s(d, a) = 2 * a * sinh(d / a); //! Length of a symmetric catenary with width ```2d```.
+function catenary_ds_by_da(d, a) = 2 * sinh(d / a) - 2 * d / a * cosh(d / a); //! First derivative of the length with respect to ```a```.
+
+function catenary_find_a(d, l, a = 1, best_e = inf, best_a = 1) =  //! Find the catenary constant ```a```, given half the horizontal span and the length.
+     assert(l > 2 * d, "Not long enough to span the gap") assert(d) let(error = abs(catenary_s(d, a) - l))
+     error >= best_e && error < 0.0001 ? best_a
+                                       : catenary_find_a(d, l, max(a - (catenary_s(d, a) - l) / catenary_ds_by_da(d, a), d / argsinh(1e99)), error, a);
+
+function catenary_points(l, x, y, steps = 100) = //! Returns a list of 2D points on the curve that goes from the origin to ```(x,y)``` and has length ```l```.
+    let(
+        d = x / 2,
+        a = catenary_find_a(d, sqrt(sqr(l) - sqr(y))),   // Find a to get the correct length
+        offset = argsinh(y / catenary_s(d, a)),
+        t0 = sinh(-d / a + offset),
+        t1 = sinh( d / a + offset),
+        h = a * cosh(-d / a + offset) - a,
+        lowest = offset > d / a ? [0, 0] : offset < -d / a ? [x, y] : [d - offset * a, -h],
+        p0 = catenary(t0, a)
+    )
+    steps ? [for(t = [t0 : (t1 - t0) / steps : t1]) catenary(t, a) - p0] : lowest;

utils/core/core.scad

@@ -18,7 +18,7 @@
 //
 
 //
-// Include this file to use the miniumum library
+// Include this file to use the minimum library
 //
 include <../../global_defs.scad>
 //

utils/core/global.scad

@@ -31,16 +31,27 @@ function m(x)    = x * 1000.0;
 
 function sqr(x) = x * x;                                                            //! Returns the square of ```x```
 function echoit(x) = echo(x) x;                                                     //! Echo expression and return it, useful for debugging
+function no_point(str) = chr([for(c = str(str)) if(c == ".") ord("p") else ord(c)]);//! Replace decimal point in string with 'p'
 function in(list, x) = !!len([for(v = list) if(v == x) true]);                      //! Returns true if ```x``` is an element in the ```list```
 function Len(x) = is_list(x) ? len(x) : 0;                                          //! Returns the length of a list or 0 if ```x``` is not a list
 function r2sides(r) = $fn ? $fn : ceil(max(min(360/ $fa, r * 2 * PI / $fs), 5));    //! Replicates the OpenSCAD logic to calculate the number of sides from the radius
 function r2sides4n(r) = floor((r2sides(r) + 3) / 4) * 4;                            //! Round up the number of sides to a multiple of 4 to ensure points land on all axes
+function limit(x, min, max) = max(min(x, max), min);                                //! Force x in range min <= x <= max
 
 module translate_z(z) translate([0, 0, z]) children();                              //! Shortcut for Z only translations
 module vflip() rotate([180, 0, 0]) children();                                      //! Invert children by doing a 180&deg; flip around the X axis
 module hflip() rotate([0, 180, 0]) children();                                      //! Invert children by doing a 180&deg; flip around the Y axis
 module ellipse(xr, yr) scale([1, yr / xr]) circle4n(xr);                            //! Draw an ellipse
 
+function slice_str(str, start, end, s ="") = start >= end ? s : slice_str(str, start + 1, end, str(s, str[start])); // Helper for slice()
+
+function slice(list, start = 0, end = undef) = let( //! Slice a list or string with Python type semantics
+        len = len(list),
+        start = limit(start < 0 ? len + start : start, 0, len),
+        end   = is_undef(end) ? len : limit(end   < 0 ? len + end : end, 0, len)
+    ) is_string(list) ? slice_str(list, start, end) : [for(i = [start : 1 : end - 1]) list[i]];
+
+
 module extrude_if(h, center = true)                 //! Extrudes 2D object to 3D when ```h``` is nonzero, otherwise leaves it 2D
     if(h)
         linear_extrude(h, center = center, convexity = 2) // 3D

utils/core/polyholes.scad

@@ -32,10 +32,14 @@ module poly_circle(r, sides = 0) { //! Make a circle adjusted to print the corre
     circle(r = corrected_radius(r,n), $fn = n);
 }
 
-module poly_cylinder(r, h, center = false, sides = 0) //! Make a cylinder adjusted to print the correct size
+module poly_cylinder(r, h, center = false, sides = 0, chamfer = false) {//! Make a cylinder adjusted to print the correct size
     extrude_if(h, center)
         poly_circle(r, sides);
 
+    if(h && chamfer)
+        poly_cylinder(r + layer_height, center ? layer_height * 2 : layer_height, center, sides = sides ? sides : sides(r));
+}
+
 module poly_ring(or, ir, sides = 0) { //! Make a 2D ring adjusted to have the correct internal radius
     cir = corrected_radius(ir, sides);
     filaments = (or - cir) / extrusion_width;

utils/hanging_hole.scad

@@ -39,11 +39,13 @@ module hanging_hole(z, ir, h = 100, h2 = 100) { //! Hole radius ```ir``` hanging
     infill_angle = z % (2 * layer_height) ? -45 : 45;
     below = min(z + eps, h2);
     big = 1000;
-
     render(convexity = 3) translate_z(z)
         union() {
             translate_z(2 * layer_height)
-                polyhole(ir - eps, h - 2 * layer_height);
+                if(sides(ir) > 4)
+                    polyhole(ir - eps, h - 2 * layer_height);
+                else
+                    poly_cylinder(ir, h - 2 * layer_height);
 
             difference() {
                 translate_z(-below)

utils/horiholes.scad

@@ -19,6 +19,8 @@
 
 //
 //! Utilities for depicting the staircase slicing of horizontal holes made with [`teardrop_plus()`](#teardrops), see <https://hydraraptor.blogspot.com/2020/07/horiholes-2.html>
+//!
+//! ```horicylinder()``` makes cylinders that fit inside a round hole. Layers that are less than 2 filaments wide and layers that need more than a 45 degree overhang are omitted.
 //
 include <../utils/core/core.scad>
 
@@ -53,3 +55,29 @@ module horihole(r, z, h = 0, center = true) { //! For making horizontal holes th
                         }
              }
 }
+
+function teardrop_minus_x(r, y, h) = //! Calculate the ordinate of a compensated teardrop given y and layer height.
+    let(fr = h / 2,
+        hpot = r - fr,
+        x2 = sqr(hpot) - sqr(y),
+        x = x2 > 0 ? sqrt(x2) : 0,
+        X = y >= -hpot / sqrt(2) ? x + fr : 0
+    )
+    X >= extrusion_width ? X : 0;
+
+module horicylinder(r, z, h = 0, center = true) { //! For making horizontal cylinders that don't need support material and are correct dimensions
+    bot_layer = floor((z - r) / layer_height);
+    top_layer = ceil((z + r) / layer_height);
+    render(convexity = 5)
+        extrude_if(h, center)
+            for(i = [bot_layer : top_layer]) {
+                Z = i * layer_height;
+                y = Z - z + layer_height / 2;
+                x = teardrop_minus_x(r, y, layer_height);
+                if(x >= extrusion_width)
+                    hull()
+                        for(end = [-1, 1])
+                            translate([end * (x - layer_height / 2), y])
+                                circle(d = layer_height, $fn = 32);
+             }
+}

utils/maths.scad

@@ -24,6 +24,14 @@ function sqr(x) = x * x;                        //! Square x
 function radians(degrees) = degrees * PI / 180; //! Convert radians to degrees
 function degrees(radians) = radians * 180 / PI; //! Convert degrees to radians
 
+function sinh(x) = (exp(x) - exp(-x)) / 2;      //! hyperbolic sine
+function cosh(x) = (exp(x) + exp(-x)) / 2;      //! hyperbolic cosine
+function tanh(x) = sinh(x) / cosh(x);           //! hyperbolic tangent
+function coth(x) = cosh(x) / sinh(x);           //! hyperbolic cotangent
+function argsinh(x) = ln(x + sqrt(sqr(x) + 1)); //! inverse hyperbolic sine
+function argcosh(x) = ln(x + sqrt(sqr(x) - 1)); //! inverse hyperbolic cosine
+function argtanh(x) = ln((1 + x) / (1 - x)) / 2;//! inverse hyperbolic tangent
+function argcoth(x) = ln((x + 1) / (x - 1)) / 2;//! inverse hyperbolic cotangent
 
 function translate(v) = let(u = is_list(v) ? len(v) == 2 ? [v.x, v.y, 0] //! Generate a 4x4 translation matrix, ```v``` can be ```[x, y]```, ```[x, y, z]``` or ```z```
                                                          : v
@@ -138,3 +146,10 @@ function invert(m) = let(n =len(m), m = solve(augment(m))) [ //! Invert a matrix
              each m[i][j]
     ]
 ];
+
+function circle_intersect(c1, r1, c2, r2) =     //! Calculate one point where two circles in the X-Z plane intersect, clockwise around c1
+    let(
+        v = c1 - c2,                            // Line between centres
+        d = norm(v),                            // Distance between centres
+        a = atan2(v.z, v.x) - acos((sqr(d) + sqr(r2) - sqr(r1)) / (2 * d * r2)) // Cosine rule to find angle from c2
+     ) c2 + r2 * [cos(a), 0, sin(a)];           // Point on second circle

utils/quadrant.scad

@@ -23,18 +23,21 @@
 include <../utils/core/core.scad>
 
 module quadrant(w, r, center = false) { //! Draw a square with one rounded corner, can be centered on the arc centre, when ```center``` is ```true```.
-    offset = center ? r - w : 0;
-    translate([offset, offset])
+    h = is_list(w) ? w.y : w;
+    w = is_list(w) ? w.x : w;
+    offset_w = center ? r - w : 0;
+    offset_h = center ? r - h : 0;
+    translate([offset_w, offset_h])
         hull() {
             intersection() {
-                translate([w - r, w - r])
+                translate([w - r, h - r])
                     circle4n(r);
 
-                square(w);
+                square([w, h]);
             }
 
             square([w, eps]);
 
-            square([eps, w]);
+            square([eps, h]);
         }
 }

utils/sweep.scad

@@ -34,14 +34,22 @@ function transpose3(m) = [ [m[0].x, m[1].x, m[2].x],
                            [m[0].y, m[1].y, m[2].y],
                            [m[0].z, m[1].z, m[2].z] ];
 //
+// Find the first non-colinear point
+//
+tiny = 0.00001;
+function find_curve(tangents, i = 1) =
+    i >= len(tangents) - 1 || norm(cross(tangents[0], tangents[i] - tangents[0])) > tiny ? i
+                                                                                         : find_curve(tangents, i + 1);
+//
 // Frenet-Serret frame
 //
 function fs_frame(tangents) =
     let(tangent = tangents[0],
-        normal = tangents[1] - tangents[0],
+        i = find_curve(tangents),
+        normal = tangents[i] - tangents[0],
         binormal = cross(tangent, normal),
         z = unit(tangent),
-        x = assert(norm(binormal) > 0.00001, "first three points are colinear") unit(binormal),
+        x = assert(norm(binormal) > tiny, "all points are colinear") unit(binormal),
         y = unit(cross(z, x))
        ) [[x.x, y.x, z.x],
           [x.y, y.y, z.y],
@@ -70,7 +78,6 @@ function orientate(p, r) =
          [x.y, y.y, z.y],
          [x.z, y.z, z.z],
          [p.x, p.y, p.z]];
-
 //
 // Rotate around z
 //
@@ -145,10 +152,10 @@ function sweep(path, profile, loop = false, twist = 0) = //! Generate the point
         faces = loop ? skin_faces : concat([cap(facets)], skin_faces, [cap(facets, npoints - 1)])
         ) [points, faces];
 
-module sweep(path, profile, loop = false, twist = 0) { //! Draw a polyhedron that is the swept volume
+module sweep(path, profile, loop = false, twist = 0, convexity = 1) { //! Draw a polyhedron that is the swept volume
     mesh = sweep(path, profile, loop, twist);
 
-    polyhedron(points = mesh[0], faces = mesh[1]);
+    polyhedron(points = mesh[0], faces = mesh[1], convexity = convexity);
 }
 
 function path_length(path, i = 0, length = 0) = //! Calculated the length along a path

vitamins/axial.scad

@@ -24,6 +24,7 @@ include <../utils/core/core.scad>
 include <../utils/round.scad>
 
 module wire_link(d, l, h = 1, tail = 3) { //! Draw a wire jumper link.
+    vitamin(str("wire_link(", d, ", ", l, arg(h, 1, "h"), arg(tail, 3, "tail"),  "): Wire link ", d, "mm x ", l / inch(1), "\""));
     r = d;
     $fn = 32;
 
@@ -57,13 +58,16 @@ module orientate_axial(length, height, pitch, wire_d) { // Orient horizontal or
     min_pitch = ceil((length + 1) / inch(0.1)) * inch(0.1);
     lead_pitch = pitch ? pitch : min_pitch;
     if(lead_pitch >= min_pitch) {
-        wire_link(wire_d, lead_pitch, height);
+        not_on_bom()
+            wire_link(wire_d, lead_pitch, height);
+
         translate_z(height)
             rotate([0, 90, 0])
                 children();
     }
     else {
-        wire_link(wire_d, lead_pitch, length + 0.7 + wire_d);
+        not_on_bom()
+            wire_link(wire_d, lead_pitch, length + 0.7 + wire_d);
 
         translate([-pitch / 2, 0, length / 2 + 0.2])
             children();

vitamins/belt.scad

@@ -24,29 +24,31 @@
 //! To make the back of the belt run against a smooth pulley on the outside of the loop specify a negative pitch radius.
 //!
 //! By default the path is a closed loop but a gap length and position can be specified to make open loops.
+//! To draw the gap its XY position is specified by ```gap_pos```. ```gap_pos.z``` can be used to specify a rotation if the gap is not at the bottom of the loop.
 //!
 //! Individual teeth are not drawn, instead they are represented by a lighter colour.
 //
 include <../utils/core/core.scad>
 use <../utils/rounded_polygon.scad>
+use <../utils/maths.scad>
 
 function belt_pitch(type)        = type[1]; //! Pitch in mm
 function belt_width(type)        = type[2]; //! Width in mm
 function belt_thickness(type)    = type[3]; //! Total thickness including teeth
 function belt_tooth_height(type) = type[4]; //! Tooth height
-function belt_pitch_height(type) = belt_tooth_height(type) + type[4]; //! Offset of the pitch radius from the tips of the teeth
+function belt_pitch_height(type) = type[5] + belt_tooth_height(type); //! Offset of the pitch radius from the tips of the teeth
 
-function no_point(str) = chr([for(c = str) if(c == ".") ord("p") else ord(c)]);
+function belt_pitch_to_back(type) = belt_thickness(type) - belt_pitch_height(type); //! Offset of the back from the pitch radius
 //
 // We model the belt path at the pitch radius of the pulleys and the pitch line of the belt to get an accurate length.
 // The belt is then drawn by offseting each side from the pitch line.
 //
-module belt(type, points, gap = 0, gap_pt = undef, belt_colour = grey(20), tooth_colour = grey(50)) { //! Draw a belt path given a set of points and pitch radii where the pulleys are. Closed loop unless a gap is specified
+module belt(type, points, gap = 0, gap_pos = undef, belt_colour = grey(20), tooth_colour = grey(50)) { //! Draw a belt path given a set of points and pitch radii where the pulleys are. Closed loop unless a gap is specified
     width = belt_width(type);
     pitch = belt_pitch(type);
     thickness = belt_thickness(type);
     part = str(type[0],pitch);
-    vitamin(str("belt(", no_point(part), "x", width, ", ", points, arg(gap, 0), arg(gap_pt, undef), "): Belt ", part," x ", width, "mm x ", length, "mm"));
+    vitamin(str("belt(", no_point(part), "x", width, ", ", points, arg(gap, 0), arg(gap_pos, undef), "): Belt ", part," x ", width, "mm x ", length, "mm"));
 
     len = len(points);
 
@@ -56,24 +58,28 @@ module belt(type, points, gap = 0, gap_pt = undef, belt_colour = grey(20), tooth
 
     module shape() rounded_polygon(points, tangents);
 
+    ph = belt_pitch_height(type);
+    th = belt_tooth_height(type);
     module gap()
         if(gap)
-            translate(gap_pt)
-                square([gap, thickness + eps], center = true);
+            translate([gap_pos.x, gap_pos.y])
+                rotate(is_undef(gap_pos.z) ? 0 : gap_pos.z)
+                    translate([0, ph - thickness / 2])
+                        square([gap, thickness + eps], center = true);
 
     color(belt_colour)
         linear_extrude(width, center = true)
             difference() {
-                offset(thickness - belt_pitch_height(type)) shape();
-                offset(-belt_pitch_height(type) + belt_tooth_height(type)) shape();
+                offset(-ph + thickness ) shape();
+                offset(-ph + th) shape();
                 gap();
-
             }
+
     color(tooth_colour)
         linear_extrude(width, center = true)
             difference() {
-                offset(-belt_pitch_height(type) + belt_tooth_height(type)) shape();
-                offset(-belt_pitch_height(type)) shape();
+                offset(-ph + th) shape();
+                offset(-ph) shape();
                 gap();
             }
 }

vitamins/cable_strip.scad

@@ -20,7 +20,7 @@
 //
 //! A strip of polypropylene used with ribbon cable to make a cable flexible in one direction only.
 //!
-//! Modelled with a Bezier spline, which is not quite the same as a miniumum energy curve but very close, epecially
+//! Modelled with a Bezier spline, which is not quite the same as a minimum energy curve but very close, epecially
 //! near the extreme positions, where the model needs to be accurate.
 //!
 //! When the sides are constrained then a circular model is more accurate.

vitamins/component.scad

@@ -161,13 +161,13 @@ module al_clad_resistor(type, value, leads = true) { //! Draw an aluminium clad
                 }
         linear_extrude(thickness)
             difference() {
-                for(end = [-1, 1])
-                    translate([end * (length - tab) / 2, end * (width - width / 2) / 2])
-                        square([tab, width / 2], center = true);
+                union()
+                    for(end = [-1, 1])
+                        translate([end * (length - tab) / 2, end * (width - width / 2) / 2])
+                            square([tab, width / 2], center = true);
 
                 al_clad_resistor_hole_positions(type)
                     circle(d = al_clad_hole(type));
-
             }
         if(leads) {
             translate_z(height / 2)

vitamins/fans.scad

@@ -17,28 +17,28 @@
 // If not, see <https://www.gnu.org/licenses/>.
 //
 
-//          w   d   b   h      s              h     t    o   b  b    a
-//          i   e   o   o      c              u     h    u   l  o    p
-//          d   p   r   l      r              b     i    t   a  s    p
-//          t   t   e   e      e                    c    e   d  s    e
-//          h   h              w              d     k    r   e       r
-//                      p                     i     n        s  d    t
-//                      i                     a     e    d           u
-//                      t                           s    i           r
-//                      c                           s    a           e
-//                      h
+//          w     d   b   h      s              h     t    o   b  b    a
+//          i     e   o   o      c              u     h    u   l  o    p
+//          d     p   r   l      r              b     i    t   a  s    p
+//          t     t   e   e      e                    c    e   d  s    e
+//          h     h              w              d     k    r   e       r
+//                        p                     i     n        s  d    t
+//                        i                     a     e    d           u
+//                        t                           s    i           r
+//                        c                           s    a           e
+//                        h
 //
-fan120x25= [120,25, 116,52.5,  M4_dome_screw, 41,   4,  140, 9, 0,   137];
-fan80x38 = [80, 38, 75, 35.75, M4_dome_screw, 40,   4.3, 84, 7, 0,   85];
-fan80x25 = [80, 25, 75, 35.75, M4_dome_screw, 40,   4.3, 84, 7, 0,   85];
-fan70x15 = [70, 15, 66, 30.75, M4_dome_screw, 29,   3.8, 70 ,7, 0,   undef];
-fan60x25 = [60, 25, 57, 25,    M4_dome_screw, 31.5, 3.6, 64, 7, 0,   63];
-fan60x15 = [60, 15, 57, 25,    M4_dome_screw, 29,   2.4, 60, 7, 7.7, 63];
-fan50x15 = [50, 15, 48, 20,    M4_dome_screw, 25,   12.5,100,7, 0,   undef];
-fan40x11 = [40, 11, 37, 16,    M3_dome_screw, 25,   7.5,100, 9, 0,   undef];
-fan30x10 = [30, 10, 27, 12,    M3_dome_screw, 17,   10, 100, 5, 0,   undef];
-fan25x10 = [25, 10, 24, 10,   M2p5_pan_screw, 16,   10, 100, 5, 0,   undef];
-fan17x8  = [17,  8, 16, 6.75,  M2_cap_screw,  12.6,  8, 100, 7, 0,   undef];
+fan120x25= [120, 25, 116,52.5,  M4_dome_screw, 41,   4,  140, 9, 0,   137];
+fan80x38 = [80,  38, 75, 35.75, M4_dome_screw, 40,   4.3, 84, 7, 0,   85];
+fan80x25 = [80,  25, 75, 35.75, M4_dome_screw, 40,   4.3, 84, 7, 0,   85];
+fan70x15 = [70,  15, 66, 30.75, M4_dome_screw, 29,   3.8, 70 ,7, 0,   undef];
+fan60x25 = [60,  25, 57, 25,    M4_dome_screw, 31.5, 3.6, 64, 7, 0,   63];
+fan60x15 = [60,  15, 57, 25,    M4_dome_screw, 29,   2.4, 60, 7, 7.7, 63];
+fan50x15 = [50,  15, 48, 20,    M4_dome_screw, 25,  12.5,100, 7, 0,   undef];
+fan40x11 = [40,  11, 37, 16,    M3_dome_screw, 25,   7.5,100, 9, 0,   undef];
+fan30x10 = [30,  10, 27, 12,    M3_dome_screw, 17,   10, 100, 5, 0,   undef];
+fan25x10 = [25.4,10, 24, 10,   M2p5_pan_screw, 16,   10, 100, 5, 0,   undef];
+fan17x8  = [17,   8, 16, 6.75,  M2_cap_screw,  12.6,  8, 100, 7, 0,   undef];
 
 fans = [fan17x8, fan25x10, fan30x10, fan40x11, fan50x15, fan60x15, fan60x25, fan70x15, fan80x25, fan80x38, fan120x25];
 

vitamins/hot_ends.scad

@@ -33,8 +33,7 @@
 //                                                                                       h      t     s   t              t     t
 //                                                                                              h
 //
-JHeadMk4  = ["JHeadMk4",  jhead, "JHead MK4",           64,  5.1, 16,    50, grey(20),     12,    4.64, 14, [0, 2.94, -5], 20,   20];
-JHeadMk5  = ["JHeadMk5",  jhead, "JHead MK5",         51.2,  5.1, 16,    40, grey(20),     12,    4.64, 13, [0, 2.38, -5], 20,   20];
+JHeadMk5  = ["JHeadMk5",  jhead, "JHead MK5",         51.2,  4.75,16,    40, grey(20),   12,    4.64, 13, [0, 2.38, -5], 20,   20];
 E3Dv5     = ["E3Dv5",     e3d,   "E3D V5 direct",       70,  3.7, 16,  50.1, "silver",   12,    6,    15, [1, 5,  -4.5], 14.5, 28];
 E3Dv6     = ["E3Dv6",     e3d,   "E3D V6 direct",       62,  3.7, 16,  42.7, "silver",   12,    6,    15, [1, 5,  -4.5], 14,   21];
 E3D_clone = ["E3D_clone", e3d,   "E3D clone aliexpress",66,  6.8, 16,    46, "silver",   12,    5.6,  15, [1, 5,  -4.5], 14.5, 21];

vitamins/insert.scad

@@ -24,17 +24,26 @@ include <../utils/core/core.scad>
 use <../utils/quadrant.scad>
 use <../utils/thread.scad>
 
-function insert_length(type)         = type[1]; //! Length
-function insert_outer_d(type)        = type[2]; //! Outer diameter at the top
+function insert_length(type)         = type[1];     //! Length
+function insert_outer_d(type)        = type[2];     //! Outer diameter at the top
 function insert_hole_radius(type)    = type[3] / 2; //! Radius of the required hole in the plastic
-function insert_screw_diameter(type) = type[4]; //! Screw size
-function insert_barrel_d(type)       = type[5]; //! Diameter of the main barrel
-function insert_ring1_h(type)        = type[6]; //! Height of the top and middle rings
-function insert_ring2_d(type)        = type[7]; //! Diameter of the middle ring
-function insert_ring3_d(type)        = type[8]; //! Diameter of the bottom ring
+function insert_screw_diameter(type) = type[4];     //! Screw size
+function insert_barrel_d(type)       = type[5];     //! Diameter of the main barrel
+function insert_ring1_h(type)        = type[6];     //! Height of the top and middle rings
+function insert_ring2_d(type)        = type[7];     //! Diameter of the middle ring
+function insert_ring3_d(type)        = type[8];     //! Diameter of the bottom ring
 
 function insert_hole_length(type) = round_to_layer(insert_length(type));
 
+function insert_nose_length(type, d) = let( //! The length before the second ring.
+        length = insert_length(type),
+        ring1_h = insert_ring1_h(type),
+        chamfer1 = (insert_ring2_d(type) - insert_barrel_d(type)) / 2,
+        chamfer2 = (insert_ring3_d(type) - insert_barrel_d(type)) / 2,
+        ring2_h = ring1_h + chamfer1,
+        gap = (length - ring1_h - ring2_h - chamfer2) / 3
+    ) ring1_h + gap + ring2_h - d + insert_barrel_d(type);
+
 module insert(type) { //! Draw specified insert
     length = insert_length(type);
     ring1_h = insert_ring1_h(type);
@@ -42,12 +51,12 @@ module insert(type) { //! Draw specified insert
     chamfer1 = (insert_ring2_d(type) - insert_barrel_d(type)) / 2;
     chamfer2 = (insert_ring3_d(type) - insert_barrel_d(type)) / 2;
     ring2_h = ring1_h + chamfer1;
-    gap = (length - ring1_h - ring2_h- chamfer2) / 3;
+    gap = (length - ring1_h - ring2_h - chamfer2) / 3;
 
     vitamin(str("insert(", type[0], "): Heatfit insert M", insert_screw_diameter(type)));
     $fn = 64;
     thread_d = insert_screw_diameter(type);
-    explode(20, offset =[0, 0, -5]) translate_z(eps) vflip() {
+    explode(20, offset = [0, 0, -5]) translate_z(eps) vflip() {
         r1 = thread_d / 2;
         r2 = insert_barrel_d(type) / 2;
         r3 = insert_ring3_d(type) / 2;
@@ -58,7 +67,7 @@ module insert(type) { //! Draw specified insert
         h3 = ring1_h + gap + ring2_h;
         h4 = ring1_h + gap + ring2_h + gap;
         color(brass)
-            rotate_extrude()
+            rotate_extrude(convexity = 3)
                 polygon([
                     [r1, 0],
                     [r1, length],
@@ -128,19 +137,26 @@ module insert_lug(insert, wall, counter_bore = 0, extension = 0, corner_r = 0, f
     boss_h = insert_hole_length(insert);
     boss_h2 = boss_h + counter_bore;
 
-    module shape()
-        intersection() {
+    module shape() {
+        module _shape()
             hull() {
                 circle(boss_r);
 
                 translate([boss_r + extension - eps, 0])
                     square([eps, 2 * boss_r], center = true);
             }
-            if(corner_r)
+
+        if(corner_r)
+            intersection() {
+                _shape();
+
                 translate([boss_r + extension - corner_r, 0])
                     rotate(-45)
                         quadrant(w = 100, r = corner_r - eps, center = true);
-        }
+            }
+        else
+            _shape();
+    }
 
     translate_z(-boss_h)
         linear_extrude(boss_h)

vitamins/inserts.scad

@@ -29,7 +29,7 @@
 //                          d         d          h    d    d
 //                                         d
 //
-F1BM2   = [ "F1BM",    4.0, 3.6, 3.2, 2,   3.0,  1.0, 3.4, 3.1 ];
+F1BM2   = [ "F1BM2",    4.0, 3.6, 3.2, 2,   3.0,  1.0, 3.4, 3.1 ];
 F1BM2p5 = [ "F1BM2p5", 5.8, 4.6, 4.0, 2.5, 3.65, 1.6, 4.4, 3.9 ];
 F1BM3   = [ "F1BM3",   5.8, 4.6, 4.0, 3,   3.65, 1.6, 4.4, 3.9 ];
 F1BM4   = [ "F1BM4",   8.2, 6.3, 5.6, 4,   5.15, 2.3, 6.0, 5.55 ];

vitamins/jhead.scad

@@ -29,7 +29,6 @@ include <zipties.scad>
 use <wire.scad>
 use <../utils/tube.scad>
 
-MK4_heater = [ 12.76, 15.88, 8.22, (15.88 / 2 - 4.5), (12.76 / 2 - 0.5 - 2.5 / 2),  (-15.88 / 2 + 5), 9.5, 3];
 MK5_heater = [ 12.76, 12.76, 8.22, (12.76 / 2 - 3.75), (12.76 / 2 - 0.5 - 2.5 / 2), (-12.76 / 2 + 4), 8,   2];
 
 function heater_width(type)  = type[0];
@@ -71,7 +70,7 @@ module heater_block(type, resistor, thermistor) {
         cone_start_r = nozzle_cone(type) / 2;
         straight = 1;
         nozzle_r = 0.4 / 2;
-        translate_z(-h / 2) vflip()
+        translate([nozzle_x(type), 0, -h / 2]) vflip()
             rotate_extrude()
                 polygon([
                     [nozzle_r,     0],
@@ -86,7 +85,7 @@ module heater_block(type, resistor, thermistor) {
 module jhead_hot_end(type, filament) {
     resistor = RIE1212UB5C5R6;
     thermistor = Epcos;
-    heater = type == JHeadMk4 ? MK4_heater : MK5_heater;
+    heater = MK5_heater;
 
     insulator_length = hot_end_insulator_length(type);
     inset = hot_end_inset(type);
@@ -106,7 +105,7 @@ module jhead_hot_end(type, filament) {
 
                     square([hot_end_insulator_diameter(type) / 2 - chamfer, insulator_length]);
                 }
-                square([3.2 / 2, insulator_length]);
+                square([(filament + 0.2) / 2, insulator_length]);
 
                 translate([hot_end_groove_dia(type) / 2, insulator_length - hot_end_inset(type) - hot_end_groove(type)])
                     square([100, hot_end_groove(type)]);
@@ -122,7 +121,7 @@ module jhead_hot_end(type, filament) {
 module jhead_hot_end_assembly(type, filament, naked = false) { //! Assembly with resistor, thermistor, tape, sleaving and ziptie
     resistor = RIE1212UB5C5R6;
     thermistor = Epcos;
-    heater = type == JHeadMk4 ? MK4_heater : MK5_heater;
+    heater = MK5_heater;
 
     insulator_length = hot_end_insulator_length(type);
     inset = hot_end_inset(type);
@@ -139,7 +138,7 @@ module jhead_hot_end_assembly(type, filament, naked = false) { //! Assembly with
     //
     // silcone tape
     //
-    if(!naked)
+    if(is_undef(naked) || !naked)
         color("red")
             if(exploded())
                 translate([0, max(hot_end_insulator_diameter(type) / 2, heater_length(heater) / 2 - nozzle_x(heater)),
@@ -157,7 +156,7 @@ module jhead_hot_end_assembly(type, filament, naked = false) { //! Assembly with
     //
     // Zip tie and heatshrink
     //
-    if(!naked)
+    if(!naked  && !is_undef(naked))
         rotate(10) {
             dia =  hot_end_insulator_diameter(type);
             scale([1, (bundle + dia) / dia])
@@ -180,23 +179,27 @@ module jhead_hot_end_assembly(type, filament, naked = false) { //! Assembly with
     //
     // heater block
     //
-    rotate(90)
-        translate([-nozzle_x(heater), 0, inset - insulator_length - heater_height(heater) / 2]) {
-            intersection() {
-                group() {
-                    translate([resistor_x(heater), -exploded() * 15, 0])
-                        rotate([90, 0, 0])
-                             sleeved_resistor(resistor, PTFE20, bare = -10);
+    module heater_components() {
+        translate([resistor_x(heater), -exploded() * 15, 0])
+            rotate([90, 0, 0])
+                 sleeved_resistor(resistor, PTFE20, bare = -10);
+
+        translate([-heater_length(heater) / 2 + resistor_length(thermistor) / 2 - exploded() * 10, thermistor_y(heater), 0])
+            rotate([90, 0, -90])
+                 sleeved_resistor(thermistor, PTFE07, heatshrink = HSHRNK16);
+    }
+
+    rotate(90)
+        translate([-nozzle_x(heater), 0, inset - insulator_length - heater_height(heater) / 2])
+            if(exploded())
+                heater_components();
+            else
+                intersection() {
+                    heater_components();
 
-                    translate([-heater_length(heater) / 2 + resistor_length(thermistor) / 2 - exploded() * 10, thermistor_y(heater), 0])
-                        rotate([90, 0, -90])
-                             sleeved_resistor(thermistor, PTFE07, heatshrink = HSHRNK16);
-                }
-                if(!exploded())
                     if(naked)
                         color("grey") cylinder(r = 12, h = 100, center = true);
                     else
                         cube(1, true);             // hide the wires when not exploded
-            }
-    }
+                }
 }

vitamins/led_meter.scad

@@ -85,7 +85,8 @@ module meter(type, colour = "red", value = "888", display_colour = false) //! Dr
         translate([0, meter_shunt_y(type), size.z])
             vflip()
                 color("#b87333")
-                    wire_link(shunt.y, shunt.x, shunt.z, tail = 2);
+                    not_on_bom()
+                        wire_link(shunt.y, shunt.x, shunt.z, tail = 2);
 }
 
 clearance = 0.1;

vitamins/magnet.scad

@@ -0,0 +1,49 @@
+//
+// NopSCADlib Copyright Chris Palmer 2020
+// 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/>.
+//
+
+//
+//! Cylindrical and ring magnets.
+//
+include <../utils/core/core.scad>
+
+function magnet_od(type)    = type[1]; //! Outer diameter
+function magnet_id(type)    = type[2]; //! Inside diameter if a ring
+function magnet_h(type)     = type[3]; //! Height
+function magnet_r(type)     = type[4]; //! Corner radius
+
+module magnet(type) { //! Draw specified magnet
+    od = magnet_od(type);
+    id = magnet_id(type);
+    h = magnet_h(type);
+    r = magnet_r(type);
+
+    //vitamin(str("magnet(", type[0], "): Magnet ", od, "mm diameter, ", h, "mm high", id ? str(", ", id, "mm bore") : "" ));
+
+    or = od / 2;
+    ir = id / 2;
+    color(silver)
+        rotate_extrude()
+            union() {
+                translate([ir, 0])
+                    rounded_square([or - ir, h], r, center = false);
+                if(!ir)
+                    square([r, h]);
+            }
+
+}

vitamins/magnets.scad

@@ -0,0 +1,30 @@
+//
+// NopSCADlib Copyright Chris Palmer 2020
+// 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/>.
+//
+//
+//! Cylindrical and ring magnets.
+//
+
+//                          od,        id,        h,         r
+MAG8x4x4p2 = ["MAG8x4x4p2", 8,         4.2,       4,         0.5];
+MAG484     = ["MAG484",     inch(1/4), inch(1/8), inch(1/4), 0.5];
+MAG5x8     = ["MAG484",     8,         0,         5,         0.5];
+
+magnets = [MAG8x4x4p2, MAG484, MAG5x8];
+
+use <magnet.scad>

vitamins/opengrab.scad

@@ -24,31 +24,44 @@
 //
 include <../utils/core/core.scad>
 use <../utils/thread.scad>
+use <pcb.scad>
+include <smds.scad>
 
-pitch = 33.8;
+pitch = 33.8 / 2;
 width = 40;
 depth = 18;
 magnet = 4.3;
-pcb = 0.8;
 pillar = 6;
 target = 1;
 pole_w = 2;
 pole_l = 36;
 poles = 15;
 
+pcb = ["", "",        width, width, 0.8, 0, 3.5, 0, "darkgreen", false, [],
+    [     [ 3.45,   19,   0, "button_4p5mm"],
+          [ 2.75,   24.5, 0, "smd_led", LED0805, "green"],
+          [ 2.75,   28.0, 0, "smd_led", LED0805, "red"],
+          [ 28.5,   13,   0, "2p54header", 3, 1, false, undef, true],
+     ]];
+
+
 module opengrab_hole_positions()    //! Position children at the screw positions
-    for(x = [-1, 1], y = [-1, 1])
-        translate([x * pitch / 2, y * pitch / 2, 0])
-            children();
+    let($d = 3.2)
+        for($x = [-pitch, pitch], $y = [-pitch, pitch])
+            translate([$x, $y])
+                children();
 
 module opengrab_side_hole_positions() //! Position children at the two 4mm hole
-    for(side = [-1, 1])
-        translate([side * (width / 2 - 3.5), 0])
-            children();
+    let($d = 4, pitch = width / 2 - 3.5)
+        for($x = [-pitch, pitch])
+            translate([$x, 0])
+                children();
 
-function opengrab_width() = width;              //! Module width
-function opengrab_depth() = depth;              //! Module height
-function opengrab_target_thickness() = target;  //! Target sheet thickness
+function opengrab_width() = width;                               //! Module width
+function opengrab_depth() = depth;                               //! Module height
+function opengrab_target_thickness() = target;                   //! Target sheet thickness
+function opengrab_pcb() = pcb;                                   //! The PCB
+function opengrab_pcb_z() = depth - pillar - pcb_thickness(pcb); //! PCB offset from the front
 
 module opengrab() { //! Draw OpenGrab module
     vitamin("opengrab(): OpenGrab V3 electro permanent magnet");
@@ -65,10 +78,9 @@ module opengrab() { //! Draw OpenGrab module
                 cube([pole_w, pole_l, 1], center = true);
     }
 
-    color("darkgreen")
-        translate_z(depth - pillar - pcb / 2)
-            cube([width, width, pcb], center = true);
-
+    not_on_bom()
+        translate_z(opengrab_pcb_z())
+            pcb(pcb);
 
     translate_z(1)
         opengrab_hole_positions() {
@@ -94,9 +106,9 @@ module opengrab_target() { //! Draw OpenGrab target
                 square([width, width], center = true);
 
                 opengrab_hole_positions()
-                    circle(d = 3.2);
+                    circle(d = $d);
 
                 opengrab_side_hole_positions()
-                    circle(d = 4);
+                    circle(d = $d);
         }
 }

vitamins/panel_meter.scad

@@ -77,7 +77,6 @@ module panel_meter(type) { //! Draw panel mounted LCD meter module
     tab_z = pmeter_tab_z(type);
     pcb = pmeter_pcb(type);
     ap2 = pmeter_inner_ap(type);
-    pcb_h = pmeter_pcb_h(type) - bezel.z;
     buttons = pmeter_buttons(type);
 
     color("#94A7AB")
@@ -146,15 +145,16 @@ module panel_meter(type) { //! Draw panel mounted LCD meter module
                     translate(pmeter_inner_ap_o(type))
                         square([ap2.x, ap2.y], center = true);
                 }
-    if(pcb)
+    if(pcb) {
         vflip()
             translate_z(h - pcb_thickness(pcb) - pmeter_pcb_z(type))
                 pcb(pcb);
 
-    if(pcb_h > 0)
-        %translate_z(-pcb_h / 2 - eps)
-            cube([size.x - 2 * t - eps, size.y - 2 * t - eps, pcb_h], center = true);
-
+        pcb_h = pmeter_pcb_h(type) - bezel.z;
+        if(pcb_h > 0)
+            %translate_z(-pcb_h / 2 - eps)
+                cube([size.x - 2 * t - eps, size.y - 2 * t - eps, pcb_h], center = true);
+    }
     if(buttons)
         for(b = buttons)
             panel_meter_button(b);

vitamins/panel_meters.scad

@@ -41,10 +41,10 @@ DSP5005   = ["DSP5005", "Ruideng DSP5005 Power supply module",                [7
                 [[-25,  9, 0], [ 6.5, 4.5, 1], 0.5,  "yellow"],
                ]];
 
-DSN_VC288PCB = ["", "", 41, 21, 1, 0, 0, 0, "green", false, [], [[ 5,  -3,   0, "jst_xh", 3], ], []];
+DSN_VC288PCB = ["", "", 41, 21, 1, 0, 0, 0, "green", false, [], [[ 5,  -3.525,   0, "jst_xh", 3], ], []];
 
 DSN_VC288 = ["DSN_VC288","DSN-VC288 DC 100V 10A Voltmeter ammeter",            [45.3, 26,   17.4], [47.8, 28.8, 2.5], 0,   [1, 1.8], [36, 18, 2.5], [],            0, 2,
-              [], 0, DSN_VC288PCB, 5];
+              [], 0, DSN_VC288PCB, 5, 0];
 
 panel_meters = [DSN_VC288, PZEM021, PZEM001, DSP5005];
 

vitamins/pcb.scad

@@ -915,7 +915,7 @@ module pcb_component(comp, cutouts = false, angle = undef) { //! Draw pcb compon
     function param(n, default = 0) = len(comp) > n ? comp[n] : default;
     rotate(comp.z) {
         // Components that have a cutout parameter go in this section
-        if(show(comp, "2p54header"))    pin_header(2p54header, comp[4], comp[5], param(6, false), false, cutouts, colour = param(7, undef));
+        if(show(comp, "2p54header"))    pin_header(2p54header, comp[4], comp[5], param(6, false), param(8, false), cutouts, colour = param(7, undef));
         if(show(comp, "2p54boxhdr"))    box_header(2p54header, comp[4], comp[5], param(6, false), cutouts);
         if(show(comp, "2p54socket"))    pin_socket(2p54header, comp[4], comp[5], param(6, false), param(7, 0), param(8, false), cutouts, param(9, undef));
         if(show(comp, "chip"))          chip(comp[4], comp[5], comp[6], param(7, grey(30)), cutouts);
@@ -940,6 +940,7 @@ module pcb_component(comp, cutouts = false, angle = undef) { //! Draw pcb compon
         if(!cutouts) {
             // Components that don't have a cutout parameter go in this section
             if(show(comp, "button_6mm"))    square_button(button_6mm);
+            if(show(comp, "button_4p5mm"))  square_button(button_4p5mm);
             if(show(comp, "microswitch"))   translate_z(microswitch_thickness(comp[4])/2) microswitch(comp[4]);
             if(show(comp, "pcb"))           translate_z(comp[4]) pcb(comp[5]);
             if(show(comp, "standoff"))      standoff(comp[4], comp[5], comp[6], comp[7]);
@@ -953,6 +954,7 @@ module pcb_component(comp, cutouts = false, angle = undef) { //! Draw pcb compon
             if(show(comp, "led"))           led(comp[4], comp[5], 2.6);
             if(show(comp, "pdip"))          pdip(comp[4], comp[5], param(6, false), param(7, inch(0.3)));
             if(show(comp, "ax_res"))        ax_res(comp[4], comp[5], param(6, 5), param(7, 0));
+            if(show(comp, "link"))          wire_link(l = comp[4], h = param(5, 1), d = param(6, 0.8), tail = param(7, 3));
             if(show(comp, "D_plug"))        translate_z(d_pcb_offset(comp[4])) d_plug(comp[4], pcb = true);
             if(show(comp, "molex_hdr"))     molex_254(comp[4]);
             if(show(comp, "jst_xh"))        jst_xh_header(jst_xh_header, comp[4], param(5, false), param(6, "white"), param(7, undef));
@@ -1019,8 +1021,6 @@ module pcb(type) { //! Draw specified PCB
     for(part = pcb_accessories(type))
         vitamin(part);
 
-    pcb_components(type);
-
     color(pcb_colour(type)) linear_extrude(t) difference() {
         if(Len(pcb_polygon(type)))
             polygon(pcb_polygon(type));
@@ -1074,6 +1074,8 @@ module pcb(type) { //! Draw specified PCB
                                             circle(d = 2);
                     }
                 }
+
+    pcb_components(type);
 }
 
 module pcb_spacer(screw, height, wall = 1.8, taper = 0) { //! Generate STL for PCB spacer

vitamins/pcbs.scad

@@ -348,7 +348,7 @@ PI_IO = ["PI_IO", "PI_IO V2",       35.56, 25.4, 1.6, 0,    0,   0, "green", tru
     ], []];
 
 ZC_A0591 = ["ZC_A0591", "ZC-A0591 ULN2003 driver PCB", 35, 32, 1.6, 0, 2.5, 0, "green", false, [[2.25, 3.25], [-2.25, 3.25], [2.25, -3.25], [-2.25, -3.25] ],
-    [ [ 12.25,  8.3,  -90, "jst_xh", 5],
+    [ [ 11.725, 8.3,  -90, "jst_xh", 5],
       [ -6.5,  10,      0, "2p54header", 1, 4],
       [ 20.4,  -4.5,    0, "2p54header", 4, 1],
       [ 20.4,  11,  180, "pdip", 16, "ULN2803AN", true],
@@ -385,6 +385,11 @@ WD2002SJ = ["WD2002SJ", "WD2002SJ Buck Boost DC-DC converter", 78, 47, 1.6, 0, 3
     ],
     []];
 
+MP1584EN = ["MP1584EN", "MP1584EN 3A buck converter", 22, 17, 1.2, 0, 1, [2, 2], "green", false,
+    [[1.75, 1.75], [1.75, -1.75], [-1.75, 1.75], [-1.75, -1.75], [-1.75, -4.4], [-1.75, 4.48], [1.75, -4.4], [1.75, 4.4]],
+    []
+];
+
 PERF80x20 = ["PERF80x20", "Perfboard 80 x 20mm", 80, 20, 1.6, 0, 2.3, 0, "green", true, [[2,2],[-2,2],[2,-2],[-2,-2]], [], [], [5.87, 3.49]];
 
 PERF70x50 = ["PERF70x50", "Perfboard 70 x 50mm", 70, 50, 1.6, 0, 2.3, 0, "green", true, [[2,2],[-2,2],[2,-2],[-2,-2]], [], [], [5.87, 3.49]];
@@ -403,14 +408,14 @@ RAMPSEndstop = ["RAMPSEndstop", "RAMPS Endstop Switch",
         [2, 2, false], [2, 13.5, false], [17, 13.5], [36, 13.5]
     ],
     [
-        [ 12,    8,   -90, "jst_xh", 3, true, "white", "silver"],
+        [ 11.6,  8,   -90, "jst_xh", 3, true, "white", "silver"],
         [ 26.5, 12.75,  0, "microswitch", small_microswitch],
         [ 27.5, 17.5,  15, "chip", 15, 0.5, 4.5, "silver"],
     ],
     []];
 
 
-pcbs = [TP4056, MT3608, RAMPSEndstop, ExtruderPCB, PI_IO, ZC_A0591, RPI0, EnviroPlus, ArduinoUno3, ArduinoLeonardo, Keyes5p1, PSU12V1A, WD2002SJ, RPI3, RPI4, DuetE, Duex2, Duex5, Melzi];
+pcbs = [MP1584EN, TP4056, MT3608, RAMPSEndstop, ExtruderPCB, PI_IO, ZC_A0591, RPI0, EnviroPlus, ArduinoUno3, ArduinoLeonardo, Keyes5p1, PSU12V1A, WD2002SJ, RPI3, RPI4, DuetE, Duex2, Duex5];
 
 perfboards = [PERF74x51, PERF70x50, PERF60x40, PERF70x30, PERF80x20];
 

vitamins/pin_header.scad

@@ -29,13 +29,18 @@ function hdr_pin_width(type)    = type[4];  //! Header pin size
 function hdr_pin_colour(type)   = type[5];  //! Header pin colour
 function hdr_base_colour(type)  = type[6];  //! Header insulator colour
 function hdr_socket_depth(type) = type[7];  //! Socket depth for female housing
+function hdr_box_size(type)     = type[8];  //! Box header outside dimensions
+function hdr_box_wall(type)     = type[9];  //! Box header wall thickness
+function hdr_y_offset(type)     = type[10]; //! Y offset of pins from center of the box
+function hdr_ra_box_offset(type)= type[11]; //! Offset between back of the box and the pins
+function hdr_ra_height(type)    = type[12]; //! Height of right angle connector
 
 module pin(type, length = undef) { //! Draw a header pin
     w = hdr_pin_width(type);
     l = length == undef ? hdr_pin_length(type) : length;
     chamfer = w / 2;
     color(hdr_pin_colour(type))
-        translate_z(l / 2 -hdr_pin_below(type))
+        translate_z(l / 2 - hdr_pin_below(type))
             hull() {
                 cube([w, w, l - 2 * chamfer], center = true);
 
@@ -50,26 +55,37 @@ module pin_header(type, cols = 1, rows = 1, smt = false, right_angle = false, cu
     ra_offset = 2.4;
     width = pitch * rows;
 
-    if(cutout)
+    module cutout()
         dogbone_rectangle([cols * pitch + 2 * panel_clearance, rows * pitch + 2 * panel_clearance, 100], center = false);
+
+    if(cutout) {
+        if(right_angle)
+            translate_z(width / 2)
+                rotate([-90, 0, 180])
+                    cutout();
+        else
+            cutout();
+    }
     else {
         vitamin(str("pin_header(", type[0], ", ", cols, ", ", rows,
                     arg(smt, false, "smt"), arg(right_angle, false, "right_angle"), "): Pin header ", cols, " x ", rows, right_angle ? " right_angle" : ""));
 
         translate_z(smt ? 3.5 - h : 0) {
             for(x = [0 : cols - 1], y = [0 : rows - 1]) {
-                translate([pitch * (x - (cols - 1) / 2), pitch * (y - (rows - 1) / 2), 0])
+                // Vertical part of the pin
+                translate([pitch * (x - (cols - 1) / 2), pitch * (y - (rows - 1) / 2)])
                     if(right_angle)
-                        pin(type, hdr_pin_below(type) + width / 2 + (y - 0.5) * pitch);
+                        pin(type, hdr_pin_below(type) + (y + 0.5) * pitch);
                     else
                         pin(type);
 
                 if(right_angle) {
                     w = hdr_pin_width(type);
+                    // Horizontal part of the pin
                     rotate([-90, 0, 180])
-                        translate([pitch * (x - (cols - 1) / 2), -pitch * (y - (rows - 1) / 2) -width / 2, hdr_pin_below(type) - (y - 0.5) * pitch])
+                        translate([pitch * (x - (cols - 1) / 2), -pitch * (y - (rows - 1) / 2) - width / 2, hdr_pin_below(type) - (y - (rows - 1) / 2) * pitch])
                             pin(type, hdr_pin_length(type) - hdr_pin_below(type) + ra_offset + pitch / 2 + (y - 0.5) * pitch);
-
+                    // corner
                     translate([pitch * (x - (cols - 1) / 2), pitch * (y - (rows - 1) / 2) - w / 2, pitch * (y - (rows - 1) / 2) + width / 2 - w / 2])
                         rotate([0, -90, 0])
                             color(hdr_pin_colour(type))
@@ -78,7 +94,8 @@ module pin_header(type, cols = 1, rows = 1, smt = false, right_angle = false, cu
                                         square(w);
                 }
             }
-            translate([0, right_angle ? -ra_offset - pitch / 2 : 0, right_angle ? width / 2 : 0])
+            // Insulator
+            translate([0, right_angle ? -ra_offset - (rows - 1) * pitch / 2 : 0, right_angle ? width / 2 : 0])
                 rotate([right_angle ? 90 : 0, 0, 0])
                     color(base_colour)
                         linear_extrude(h)
@@ -96,9 +113,11 @@ module pin_header(type, cols = 1, rows = 1, smt = false, right_angle = false, cu
 
 module box_header(type, cols = 1, rows = 1, smt = false, cutout = false) { //! Draw box header
     pitch =  hdr_pitch(type);
+    size = hdr_box_size(type);
     w = cols * pitch + 7.62;
     l = rows * pitch + 3.52;
-    h = 8.7;
+    h = size.z;
+    t = hdr_box_wall(type);
     base = h - 6.4;
 
     if(cutout)
@@ -119,7 +138,7 @@ module box_header(type, cols = 1, rows = 1, smt = false, cutout = false) { //! D
                     difference() {
                         square([w, l], center = true);
 
-                        square([w - 2.4, l - 2.4], center = true);
+                        square([w - t, l - t], center = true);
 
                         translate([0, -l / 2])
                             square([4.5, 4.5], center = true);
@@ -176,7 +195,7 @@ module pin_socket(type, cols = 1, rows = 1, right_angle = false, height = 0, smt
         vitamin(str("pin_socket(", type[0], ", ", cols, ", ", rows, arg(right_angle, false, "right_angle"), arg(height, 0, "height"), arg(smt, false, "smt"),
                                "): Pin socket ", cols, " x ", rows, right_angle ? " right_angle" : ""));
         color(base_colour)
-            translate([0, right_angle ? -ra_offset - pitch / 2 : 0, right_angle ? width / 2 : 0])
+            translate([0, right_angle ? -ra_offset - (rows - 1) * pitch / 2 : 0, right_angle ? width / 2 : 0])
                 rotate([right_angle ? 90 : 0, 0, 0])
                     translate_z(depth / 2)
                         linear_extrude(depth, center = true)
@@ -192,11 +211,11 @@ module pin_socket(type, cols = 1, rows = 1, right_angle = false, height = 0, smt
             for(x = [0 : cols - 1], y = [0 : rows -1]) {
                 if(!smt)
                     translate([pitch * (x - (cols - 1) / 2), pitch * (y - (rows - 1) / 2), 0])
-                        pin(type, hdr_pin_below(type) + width / 2 + (y - 0.5) * pitch);
+                        pin(type, hdr_pin_below(type) + (y + 0.5) * pitch);
 
                 if(right_angle) {
-                    rotate([-90, 0, 0])
-                        translate([pitch * (x - (cols - 1) / 2), -pitch * (y - (rows - 1) / 2) -width / 2, 0])
+                    rotate([-90, 0, 180])
+                        translate([pitch * (x - (cols - 1) / 2), -pitch * (y - (rows - 1) / 2) - width / 2, hdr_pin_below(type) - (y - (rows - 1) / 2) * pitch])
                             pin(type, hdr_pin_below(type) + (y - 0.5) * pitch);
 
                     w = hdr_pin_width(type);
@@ -210,68 +229,98 @@ module pin_socket(type, cols = 1, rows = 1, right_angle = false, height = 0, smt
     }
 }
 
-module jst_xh_header(type, pin_count, right_angle=false, colour, pin_colour) { //! Draw JST XH connector
+module jst_xh_header(type, pin_count, right_angle = false, colour = false, pin_colour = false) { //! Draw JST XH connector
     colour = colour ? colour : hdr_base_colour(type);
     pin_colour = pin_colour ? pin_colour : hdr_pin_colour(type);
-    sizeY = 5.75;
     pitch = hdr_pitch(type);
+    size = hdr_box_size(type) + [(pin_count - 1) * pitch, 0, 0];
+    pinOffsetX = hdr_box_size(type).x / 2;                          // Offset from last pin to box edge
+    wallThickness = hdr_box_wall(type);
+    y_offset = hdr_y_offset(type);
+    ra_box_offset = hdr_ra_box_offset(type);
+    ra_h = hdr_ra_height(type);
+    ra_z = ra_h - size.y / 2;
+    ra_extra = ra_h - size.y;                                   // thicker base for right angle version
+    pinWidth = hdr_pin_width(type);
 
-    module jst_xh_socket(type, pin_count) {
-        socketSizeZ = hdr_socket_depth(type);
-        pinOffsetX = 2.45;
-        sizeY = 5.75;
-        wallThickness = 0.8;
-        size = [pinOffsetX * 2 + (pin_count - 1) * pitch, sizeY, socketSizeZ];
-        translate([-size[0] / 2, -size[1] / 2, 0]) {
-            // the base
-            cube([size[0], size[1], wallThickness]);
-            // the three full sides
-            translate([0, size[1] - wallThickness, 0])
-                cube([size[0], wallThickness, size[2]]);
-            cube([wallThickness, size[1], size[2]]);
-            translate([size[0] - wallThickness, 0, 0])
-                cube([wallThickness, size[1], size[2]]);
-            // the sides with cutouts
-            cube([size[0], wallThickness, 2]);
-            cutoutWidth = 1;
-            cutoutOffset = pinOffsetX - cutoutWidth / 2;
-            cube([cutoutOffset, wallThickness, size[2]]);
-            translate([size[0] - cutoutOffset, 0, 0])
-                cube([cutoutOffset, wallThickness, size[2]]);
-            cube([cutoutOffset, wallThickness, size[2]]);
-            translate([size[0]-cutoutOffset, 0, 0])
-                cube([cutoutOffset, wallThickness, size[2]]);
-            translate([cutoutOffset + cutoutWidth, 0, 0])
-                cube([size[0] - 2 * (cutoutWidth + cutoutOffset), wallThickness, size[2]]);
+    module jst_xh_socket(type, pin_count, ra = false) {
+        module wall() {
+            difference() {
+                square([size.x, size.y], center = true);
+
+                offset(-wallThickness)
+                    square([size.x, size.y], center = true);
+            }
+            if(right_angle)
+                translate([0, size.y / 2 + ra_extra / 2])
+                    square([size.x, ra_extra], center = true);
         }
-    } // end module
 
+        module slots() {
+            cutoutWidth = 1.3;
+            cutoutOffset = pinOffsetX + cutoutWidth / 2 - hdr_pin_width(type) / 2;
+            for(side = [-1, 1])
+                translate([side * (size.x / 2 - cutoutOffset), -size.y / 2 + wallThickness / 2])
+                    square([cutoutWidth, 2 * wallThickness], center = true);
+        }
+
+        linear_extrude(wallThickness)
+            square([size.x, size.y], center = true);                    // the base
+
+        linear_extrude(size.z / 2)                                      // full walls up to the slots
+            wall();
+
+        linear_extrude(size.z)                                          // slotted walls to the top
+            difference() {
+                wall();
+
+                if(type[0] == "jst_xh_header") {
+                    if(pin_count > 2)
+                        slots();
+                    else
+                        hull()
+                            slots();
+
+                    translate([0, -size.y / 2 + 3 * wallThickness / 2])
+                        square([size.x + 1, wallThickness], center = true);
+                }
+
+                if(type[0] == "jst_ph_header") {
+                    translate([0, -size.y / 2 + wallThickness / 2])
+                        square([max((pin_count - 2) * pitch, 1), 2 * wallThickness], center = true);
+
+                    translate([0, -y_offset / 2 - pinWidth / 4])
+                        square([size.x + 1, y_offset + pinWidth / 2], center = true);
+                }
+            }
+    } // end module
 
     color(colour)
         if(right_angle)
-            translate([0, -1, sizeY / 2])
+            translate([0, -ra_box_offset, ra_z])
                 rotate([-90, 0, 180])
-                    jst_xh_socket(type, pin_count);
+                    jst_xh_socket(type, pin_count, true);
         else
-            jst_xh_socket(type, pin_count);
+            translate([0, y_offset])
+                jst_xh_socket(type, pin_count);
 
     color(pin_colour)
         for(x = [0 : pin_count - 1]) {
-            pinWidth = hdr_pin_width(type);
-            verticalPinLength = right_angle ? hdr_pin_below(type) + sizeY / 2 : hdr_pin_length(type);
-            translate([pitch * (x - (pin_count - 1) / 2), 0, 0]) {
+            verticalPinLength = right_angle ? hdr_pin_below(type) + ra_z + y_offset : hdr_pin_length(type);
+            horizontalPinLength = hdr_pin_length(type) - hdr_pin_below(type) + ra_box_offset;
+            translate([pitch * (x - (pin_count - 1) / 2), 0]) {
                 pin(type, verticalPinLength);
 
                 if(right_angle) {
-                    translate([0, -pinWidth / 2,  sizeY / 2 - pinWidth / 2])
+                    translate([0, -pinWidth / 2, ra_z - pinWidth / 2 + y_offset])
                         rotate([0, -90, 0])
                             rotate_extrude(angle = 90, $fn = 32)
                                 translate([0, -pinWidth / 2])
                                     square(pinWidth);
 
-                    translate([0, -sizeY / 2 - 3 * pinWidth / 4, sizeY / 2])
-                        rotate([90,0,0])
-                            pin(type, hdr_pin_length(type) - hdr_pin_below(type));
+                    translate([0, -hdr_pin_below(type), ra_z + y_offset])
+                        rotate([90, 0, 0])
+                            pin(type, horizontalPinLength);
                 }
             }
         }

vitamins/pin_headers.scad

@@ -17,15 +17,16 @@
 // If not, see <https://www.gnu.org/licenses/>.
 //
 
-//                          p     p     b    p     p       b      Socket depth
-//                          i     i     e    i     i       a
-//                          t     n     l    n     n       s
-//                          c           o                  e
-//                          h     l     w    w     c
-//                                                         c
-//
-2p54header = ["2p54header", 2.54, 11.6, 3.2, 0.66, "gold", grey(20), 8.5];
-jst_xh_header = ["JST XH header",2.5,10,3.4, 0.64, "gold", grey(90), 7];
+//                               p     p     b    p     p       b         s    b                 b    p      r     r
+//                               i     i     e    i     i       a         o    o                 o    i      a     a
+//                               t     n     l    n     n       s         c    x                 x    n
+//                               c           o                  e         k                                  b     h
+//                               h     l     w    w     c                      s                 t    y
+//                                                              c         h    z                             o
+//                                                                                                           f
+2p54header    = ["2p54header",   2.54, 11.6, 3.2, 0.66, "gold", grey(20), 8.5, [0,   0,    8.7], 2.4, 0,     0,    0  ];
+jst_xh_header = ["jst_xh_header",2.5,  10,   3.4, 0.64, "gold", grey(90), 0,   [4.9, 5.75, 7],   0.8, 0.525, 0.6,  6.1];
+jst_ph_header = ["jst_ph_header",2.0,   9,   3.4, 0.64, silver, grey(90), 0,   [3.9, 4.5,  6],   0.6, 0.55,  0.25, 4.8];
 
 pin_headers = [ 2p54header ];
 

vitamins/screw.scad

@@ -175,12 +175,15 @@ module screw(type, length, hob_point = 0, nylon = false) { //! Draw specified sc
 
         if(head_type == hs_dome) {
             lift = 0.38;
+            h = head_height - lift;
+            r = min(2 * head_height, (sqr(head_rad) + sqr(h)) / 2 * h); // Special case for M2
+            y = sqrt(sqr(r) - sqr(head_rad));
             color(colour) {
                 rotate_extrude() {
                     difference() {
                         intersection() {
-                            translate([0, -head_height + lift])
-                                circle(2 * head_height);
+                            translate([0, -y + lift])
+                                circle(r);
 
                             square([head_rad, head_height]);
                         }

vitamins/screws.scad

@@ -75,10 +75,11 @@ M5_cap_screw     = ["M5_cap", "M5 cap",         hs_cap,   5, 8.5, 5,    2.5, 4.0
 M6_cap_screw     = ["M6_cap", "M6 cap",         hs_cap,   6, 10,  6,    3.3, 5.0, 24,  M6_washer, M6_nut,   M6_tap_radius,    M6_clearance_radius];
 M8_cap_screw     = ["M8_cap", "M8 cap",         hs_cap,   8, 13,  8,    4.3, 6.0, 28,  M8_washer, M8_nut,   M8_tap_radius,    M8_clearance_radius];
 
-M2_cs_cap_screw  = ["M2_cs_cap","M2 cs cap",    hs_cs_cap,2, 3.8, 0,    0.65,1.27,16,  M2_washer, M2_nut,   M2_tap_radius,    M2_clearance_radius];
+M2_cs_cap_screw  = ["M2_cs_cap","M2 cs cap",    hs_cs_cap,2, 3.8, 0,    0.65,1.3, 16,  M2_washer, M2_nut,   M2_tap_radius,    M2_clearance_radius];
 M3_cs_cap_screw  = ["M3_cs_cap","M3 cs cap",    hs_cs_cap,3, 6.0, 0,    1.05,2.0, 18,  M3_washer, M3_nut,   M3_tap_radius,    M3_clearance_radius];
 M4_cs_cap_screw  = ["M4_cs_cap","M4 cs cap",    hs_cs_cap,4, 8.0, 0,    1.49,2.5, 20,  M4_washer, M4_nut,   M4_tap_radius,    M4_clearance_radius];
 
+M2_dome_screw    = ["M2_dome", "M2 dome",       hs_dome,  2, 3.5, 1.3,  0.6, 1.3, 16,  M2_washer, M2_nut,   M2_tap_radius,    M2_clearance_radius];
 M3_dome_screw    = ["M3_dome", "M3 dome",       hs_dome,  3, 5.7, 1.65, 1.04,2.0, 18,  M3_washer, M3_nut,   M3_tap_radius,    M3_clearance_radius];
 M4_dome_screw    = ["M4_dome", "M4 dome",       hs_dome,  4, 7.6, 2.2,  1.3, 2.5, 20,  M4_washer, M4_nut,   M4_tap_radius,    M4_clearance_radius];
 
@@ -106,14 +107,14 @@ No6_screw        = ["No6", "No6 pan wood",      hs_pan, 3.5, 6.7, 2.2,    0,   0
 No6_cs_screw     = ["No6_cs", "No6 cs wood",    hs_cs,  3.5, 7.0, 0,      0,   0, 0,   M4_washer, false,    No6_pilot_radius, No6_clearance_radius];
 
 screw_lists = [
-[ M2_cap_screw, M2p5_cap_screw, M3_cap_screw, M4_cap_screw, M5_cap_screw, M6_cap_screw, M8_cap_screw],
+[ M2_cap_screw, M2p5_cap_screw, M3_cap_screw,    M4_cap_screw, M5_cap_screw, M6_cap_screw, M8_cap_screw],
 [ 0,            0,              M3_low_cap_screw],
-[ 0,            0,              M3_hex_screw, M4_hex_screw, M5_hex_screw, M6_hex_screw, M8_hex_screw],
-[ 0,            M2p5_pan_screw, M3_pan_screw, M4_pan_screw, M5_pan_screw, M6_pan_screw, No632_pan_screw],
-[ 0,            No2_screw,      No4_screw,    No6_screw,    No6_cs_screw],
+[ 0,            0,              M3_hex_screw,    M4_hex_screw, M5_hex_screw, M6_hex_screw, M8_hex_screw],
+[ 0,            M2p5_pan_screw, M3_pan_screw,    M4_pan_screw, M5_pan_screw, M6_pan_screw, No632_pan_screw],
+[ 0,            No2_screw,      No4_screw,       No6_screw,    No6_cs_screw],
 [ 0,            M2_cs_cap_screw,M3_cs_cap_screw, M4_cs_cap_screw],
-[ 0,            0,              M3_dome_screw, M4_dome_screw],
-[ 0,            0,              M3_grub_screw, M4_grub_screw]
+[ 0,            M2_dome_screw,  M3_dome_screw,   M4_dome_screw],
+[ 0,            0,              M3_grub_screw,   M4_grub_screw]
 ];
 
 use <screw.scad>

vitamins/smd.scad

@@ -62,9 +62,10 @@ module smd_led(type, colour, cutout) { //! Draw an SMD LED with specified ```col
                 intersection() {
                     square([size.x, size.y], center = true);
 
-                    for(end = [-1, 1])
-                        translate([end * size.x / 2, 0])
-                            ring(or = r, ir = r / 2);
+                    union()
+                        for(end = [-1, 1])
+                            translate([end * size.x / 2, 0])
+                                ring(or = r, ir = r / 2);
                 }
 
         color(colour, 0.9)

vitamins/stepper_motor.scad

@@ -23,8 +23,10 @@
 include <../core.scad>
 include <ring_terminals.scad>
 
+include <../vitamins/pin_headers.scad>
 use <../utils/tube.scad>
 use <../utils/thread.scad>
+use <../utils/round.scad>
 use <washer.scad>
 use <rod.scad>
 
@@ -37,9 +39,10 @@ function NEMA_boss_height(type) = type[6]; //! Boss height
 function NEMA_shaft_dia(type)   = type[7]; //! Shaft diameter
 function NEMA_shaft_length(type)= type[8]; //! Shaft length above the face, if a list then a leadscrew: length, lead, starts
 function NEMA_hole_pitch(type)  = type[9]; //! Screw hole pitch
+function NEMA_cap_heights(type) = type[10]; //! Height of the end cap at the corner and the side
+
 function NEMA_holes(type)       = [-NEMA_hole_pitch(type) / 2, NEMA_hole_pitch(type) / 2]; //! Screw positions for for loop
 function NEMA_big_hole(type)    = NEMA_boss_radius(type) + 0.2; //! Clearance hole for the big boss
-
 stepper_body_colour = "black";
 stepper_cap_colour  = grey(50);
 stepper_machined_colour = grey(90);
@@ -52,19 +55,20 @@ module NEMA_outline(type) //! 2D outline
         circle(NEMA_radius(type));
     }
 
-module NEMA(type, shaft_angle = 0) { //! Draw specified NEMA stepper motor
+module NEMA(type, shaft_angle = 0, jst_connector = false) { //! Draw specified NEMA stepper motor
     side = NEMA_width(type);
     length = NEMA_length(type);
     body_rad = NEMA_body_radius(type);
     boss_rad = NEMA_boss_radius(type);
     boss_height =NEMA_boss_height(type);
     shaft_rad = NEMA_shaft_dia(type) / 2;
-    cap = 8;
+    cap = NEMA_cap_heights(type)[1];
+    cap2 = NEMA_cap_heights(type)[0];
     vitamin(str("NEMA(", type[0], "): Stepper motor NEMA", round(NEMA_width(type) / 2.54), " x ", length, "mm"));
-    thread_d = 3;                                                           // Is this always the case?
+    thread_d = 3;                                                       // Is this always the case?
 
     module cap_shape(end)
-        difference() {
+        round(0.5, $fn = 32) difference() {
             intersection() {
                 square([side, side], center = true);
 
@@ -89,15 +93,44 @@ module NEMA(type, shaft_angle = 0) { //! Draw specified NEMA stepper motor
         tube(or = boss_rad, ir =  shaft_rad + 2, h = boss_height * 2); // raised boss
 
         linear_extrude(eps)
-            cap_shape(true);
+            cap_shape(1);
     }
 
-    color(stepper_cap_colour)                                       // aluminium end caps
-        for(end = [-1, 1])
+    pcb_thickness = 1.6;
+    header = jst_ph_header;
+    socket_size = hdr_box_size(header);
+    tabSize = [16, 4, cap - hdr_ra_height(header) - pcb_thickness];
+    color(stepper_cap_colour) {                                     // aluminium end caps
+        for(end = [-1, 1]) {
             translate_z(-length / 2 + end * (length - cap) / 2)
                 linear_extrude(cap, center = true)
                     cap_shape(end);
 
+            translate_z(-length / 2 + end * (length - cap2) / 2)
+                linear_extrude(cap2, center = true)
+                    difference() {
+                        cap_shape(end);
+
+                        circle(body_rad);
+                    }
+        }
+
+        if(jst_connector)
+            translate([-tabSize.x / 2, side / 2, -length])
+                cube(tabSize);
+    }
+
+    if(jst_connector)
+        translate([0, side / 2, -length + cap - hdr_ra_height(header)]) {
+            rotate(180)
+                not_on_bom()
+                    jst_xh_header(header, 6, true);
+
+            translate_z(-pcb_thickness / 2)
+                color("green")
+                    cube([socket_size.x + 5 * 2, tabSize.y * 2, pcb_thickness], true);
+        }
+
     if(show_threads)
         for(x = NEMA_holes(type), y = NEMA_holes(type))
             translate([x, y, -cap / 2])
@@ -111,15 +144,16 @@ module NEMA(type, shaft_angle = 0) { //! Draw specified NEMA stepper motor
                     cylinder(r = shaft_rad, h = shaft + 5);  // shaft
             else
                 not_on_bom()
-                    leadscrew(shaft_rad * 2, shaft.x + 5, shaft.y, shaft.z, center = false)
+                    leadscrew(shaft_rad * 2, shaft.x + 5, shaft.y, shaft.z, center = false);
 
-    translate([0, side / 2, -length + cap / 2])
-        rotate([90, 0, 0])
-            for(i = [0 : 3])
-                rotate(225 + i * 90)
-                    color(["red", "blue","green","black"][i])
-                        translate([1, 0, 0])
-                            cylinder(r = 1.5 / 2, h = 12, center = true);
+    if(!jst_connector)
+        translate([0, side / 2, -length + cap / 2])
+            rotate([90, 0, 0])
+                for(i = [0 : 3])
+                    rotate(225 + i * 90)
+                        color(["red", "blue","green","black"][i])
+                            translate([1, 0, 0])
+                                cylinder(r = 1.5 / 2, h = 12, center = true);
 }
 
 module NEMA_screw_positions(type, n = 4) { //! Positions children at the screw holes

vitamins/stepper_motors.scad

@@ -22,14 +22,14 @@
 //
 
 //                                   corner  body    boss    boss          shaft
-//                     side, length, radius, radius, radius, depth, shaft, length,      holes
-NEMA17  = ["NEMA17",   42.3, 47,     53.6/2, 25,     11,     2,     5,     24,          31 ];
-NEMA17M = ["NEMA17M",  42.3, 40,     53.6/2, 25,     11,     2,     5,     20,          31 ];
-NEMA17M8= ["NEMA17M8", 42.3, 40,     53.6/2, 25,     11,     2,     8,     [280, 8, 4], 31 ];
-NEMA17S = ["NEMA17S",  42.3, 34,     53.6/2, 25,     11,     2,     5,     24,          31 ];
-NEMA16  = ["NEMA16",   39.5, 19.2,   50.6/2, 50.6/2, 11,     2,     5,     12,          31 ];
-NEMA14  = ["NEMA14",   35.2, 36,     46.4/2, 21,     11,     2,     5,     21,          26 ];
-NEMA23  = ["NEMA23",   56.4, 51.2,   75.7/2, 35,   38.1/2, 1.6,   6.35,    24,        47.1 ];
+//                     side, length, radius, radius, radius, depth, shaft, length,      holes, cap heights
+NEMA17  = ["NEMA17",   42.3, 47,     53.6/2, 25,     11,     2,     5,     24,          31,    [11.5,  9]];
+NEMA17M = ["NEMA17M",  42.3, 40,     53.6/2, 25,     11,     2,     5,     20,          31,    [12.5, 11]];
+NEMA17M8= ["NEMA17M8", 42.3, 40,     53.6/2, 25,     11,     2,     8,     [280, 8, 4], 31,    [12.5, 11]];
+NEMA17S = ["NEMA17S",  42.3, 34,     53.6/2, 25,     11,     2,     5,     24,          31,    [8,     8]];
+NEMA16  = ["NEMA16",   39.5, 19.2,   50.6/2, 50.6/2, 11,     2,     5,     12,          31,    [8,     8]];
+NEMA14  = ["NEMA14",   35.2, 36,     46.4/2, 21,     11,     2,     5,     21,          26,    [8,     8]];
+NEMA23  = ["NEMA23",   56.4, 51.2,   75.7/2, 35,   38.1/2, 1.6,   6.35,    24,        47.1,    [8,     8]];
 
 stepper_motors = [NEMA14, NEMA16, NEMA17S, NEMA17M, NEMA17, NEMA23];
 

vitamins/veroboard.scad

@@ -132,8 +132,12 @@ module veroboard(type) { //! Draw specified veroboard with missing tracks and tr
 module vero_components(type, cutouts = false, angle = undef)
     for(comp = vero_components(type))
         vero_grid_pos(type, comp.x, comp.y)
-            translate_z(vero_thickness(type))
-                pcb_component(comp, cutouts, angle);
+            if(comp[3][0] == "-")
+                vflip()
+                    pcb_component(comp, cutouts, angle);
+            else
+                translate_z(vero_thickness(type))
+                    pcb_component(comp, cutouts, angle);
 
 module vero_cutouts(type, angle = undef) vero_components(type, true, angle); //! Make cutouts to clear components