Added rail_holes() function.

Added blower_exit_offset().
Fixed corner shape and exit dimensions.
Updated images and readme.

libtest.scad

@@ -52,6 +52,7 @@ use <tests/circlips.scad>
 use <tests/components.scad>
 use <tests/d_connectors.scad>
 use <tests/displays.scad>
+use <tests/drag_chain.scad>
 use <tests/extrusions.scad>
 use <tests/extrusion_brackets.scad>
 use <tests/fans.scad>
@@ -417,8 +418,12 @@ translate([x4 + 200, belts_y + 58]) {
 
     translate([0, 60])
         opengrab_test();
+
 }
 
+translate([x4 + 175, belts_y, -20])
+    drag_chains();
+
 translate([x4, rails_y + 130])
     rails();
 

printed/drag_chain.scad

@@ -22,13 +22,21 @@
 //!
 //! Each link has a maximum bend angle of 45°, so the mininium radius is proportional to the link length.
 //!
-//! The travel prpoery is how far it can move in each direction, i.e. half the maximum travel if the chain is mounted in the middle of the travel.
+//! The travel property is how far it can move in each direction, i.e. half the maximum travel if the chain is mounted in the middle of the travel.
+//!
+//! The ends can have screw lugs with four screw positions to choose from, specified by a list of two arrays of four bools.
+//! If none are enabled then a child object is expected to customise the end and this gets unioned with the blank end.
+//! If both ends are customised then two children are expected.
+//! Each child is called twice, once with ```$fasteners``` set to 0 to augment the STL and again with ```$fasteners``` set to 1 to add
+//! to the assembly, for example to add inserts.
 //
 
 include <../core.scad>
 use <../utils/horiholes.scad>
 use <../utils/maths.scad>
 
+clearance = 0.1;
+
 function drag_chain_name(type)        = type[0]; //! The name to allow more than one in a project
 function drag_chain_size(type)        = type[1]; //! The internal size and link length
 function drag_chain_travel(type)      = type[2]; //! X travel
@@ -38,6 +46,8 @@ function drag_chain_twall(type)       = type[5]; //! Top wall
 function drag_chain_screw(type)       = type[6]; //! Mounting screw for the ends
 function drag_chain_screw_lists(type) = type[7]; //! Two lists of four bools to say which screws positions are used
 
+function drag_chain_clearance() = clearance; //! Clearance around joints.
+
 function drag_chain_radius(type) = //! The bend radius at the pivot centres
     let(s = drag_chain_size(type))
         s.x / 2 / sin(360 / 16);
@@ -49,8 +59,6 @@ function drag_chain_z(type) = //! Outside dimension of a 180 bend
 function drag_chain(name, size, travel, wall = 1.6, bwall = 1.5, twall = 1.5, screw = M2_cap_screw, screw_lists = [[1,0,0,1],[1,0,0,1]]) = //! Constructor
     [name, size, travel, wall, bwall, twall, screw, screw_lists];
 
-clearance = 0.1;
-
 function drag_chain_outer_size(type) =     //! Link outer dimensions
     let(s = drag_chain_size(type), z = s.z + drag_chain_bwall(type) + drag_chain_twall(type))
         [s.x + z, s.y + 4 * drag_chain_wall(type) + 2 * clearance, z];
@@ -210,9 +218,12 @@ module drag_chain_link(type, start = false, end = false) { //! One link of the c
             translate([floor_x, -os.y / 2 + 0.5,  os.z - bwall])
                 cube([s.x - floor_x - clearance, os.y -1, bwall]);
 
-            if(start || end)
+            if(start || end) {
                 drag_chain_screw_positions(type, end)
                     screw_lug(drag_chain_screw(type), os.z);
+
+                children();
+            }
         }
         if(start || end)
             translate_z(-eps)
@@ -243,7 +254,8 @@ module drag_chain_link(type, start = false, end = false) { //! One link of the c
 //! 1. Clip the links together with the special ones at the ends.
 module drag_chain_assembly(type, pos = 0) { //! Drag chain assembly
     s = drag_chain_size(type);
-    r = drag_chain_radius(type);
+    x = (1 + exploded()) * s.x;
+    r = drag_chain_radius(type) * x / s.x;
     travel = drag_chain_travel(type);
     links = ceil(travel / s.x);
     actual_travel = links * s.x;
@@ -255,31 +267,42 @@ module drag_chain_assembly(type, pos = 0) { //! Drag chain assembly
     points = [                                      // Calculate list of hinge points
         for(i = 0, p = [0, 0, z / 2 + 2 * r]; i < links + 5;
             i = i + 1,
-            dx = p.z > c.z ? s.x : -s.x,
+            dx = p.z > c.z ? x : -x,
             p = max(p.x + dx, p.x) <= c.x ? p + [dx, 0, 0]      // Straight sections
-                  : let(q = circle_intersect(p, s.x, c, r))
-                        q.x <= c.x ? [p.x - sqrt(sqr(s.x) - sqr(p.z - zb)), 0, zb] // Transition back to straight
+                  : let(q = circle_intersect(p, x, c, r))
+                        q.x <= c.x ? [p.x - sqrt(sqr(x) - sqr(p.z - zb)), 0, zb] // Transition back to straight
                                    : q) // Circular section
         p
     ];
     npoints = len(points);
 
     module link(n)                                  // Position and colour link with origin at the hinge hole
-        translate([-z / 2, 0, -z / 2])
-            stl_colour(n % 2 ? pp1_colour : pp2_colour)
-                drag_chain_link(type, start = n == -1, end = n == npoints - 1);
+        translate([-z / 2, 0, -z / 2]) {
+            stl_colour(n < 0 || n == npoints - 1 ? pp3_colour : n % 2 ? pp1_colour : pp2_colour)
+                drag_chain_link(type, start = n == -1, end = n == npoints - 1)
+                    let($fasteners = 0) children();
+            let($fasteners = 1) children();
+        }
 
+    screws = drag_chain_screw_lists(type);
+    custom_start = screws[0] == [0, 0, 0, 0];
+    custom_end   = screws[1] == [0, 0, 0, 0];
+    assert($children == bool2int(custom_start) + bool2int(custom_end), "wrong number of children for end customisation");
     assembly(str(drag_chain_name(type), "_drag_chain")) {
         for(i = [0 : npoints - 2]) let(v = points[i+1] - points[i])
             translate(points[i])
                 rotate([0, -atan2(v.z, v.x), 0])
                     link(i);
 
-        translate(points[0] - [s.x, 0, 0])
-            link(-1);
+        translate(points[0] - [x, 0, 0])
+            link(-1)
+                if(custom_start)
+                    children(0);
 
         translate(points[npoints - 1])
             hflip()
-                link(npoints - 1);
+                link(npoints - 1)
+                    if(custom_end)
+                        children(custom_start ? 1 : 0);
     }
 }

printed/ribbon_clamp.scad

@@ -81,7 +81,7 @@ module ribbon_clamp(ways, screw = screw) { //! Generate STL for given number of
     }
 }
 
-module ribbon_clamp_assembly(ways, screw) pose([55, 180, 25])  //! Printed part with inserts in place
+module ribbon_clamp_assembly(ways, screw = 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);
@@ -117,9 +117,13 @@ module ribbon_clamp_fastened_assembly(ways, thickness, screw = screw) { //! Clam
 
 module ribbon_clamp_20_stl() ribbon_clamp(20);
 module ribbon_clamp_8_2_stl() ribbon_clamp(8, M2_dome_screw);
+module ribbon_clamp_7_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°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°C.
 module ribbon_clamp_8_2_assembly() ribbon_clamp_assembly(8, M2_dome_screw);
+
+//! * Place inserts into the holes and press home with a soldering iron with a conical bit heated to 200°C.
+module ribbon_clamp_7_2_assembly() ribbon_clamp_assembly(8, M2_dome_screw);

readme.md

@@ -296,11 +296,18 @@ Models of radial blowers.
 | ```blower_wall(type)``` | Side wall thickness |
 | ```blower_width(type)``` | Width of enclosing rectangle |
 
+### Functions
+| Function | Description |
+|:--- |:--- |
+| ```blower_casing_is_square(type)``` | True for square radial fans, false for spiral shape radial blowers |
+| ```blower_exit_offset(type)``` | Offset of exit's centre from the edge |
+
 ### Modules
 | Module | Description |
 |:--- |:--- |
 | ```blower(type)``` | Draw specified blower |
 | ```blower_hole_positions(type)``` | Translate children to screw hole positions |
+| ```blower_square(type)``` | Draw a square blower |
 
 ![blowers](tests/png/blowers.png)
 
@@ -309,8 +316,11 @@ Models of radial blowers.
 | ---:|:--- |:---|
 |   1 | ```blower(PE4020)``` |  Blower Pengda Technology 4020 |
 |   1 | ```blower(RB5015)``` |  Blower Runda RB5015 |
+|   4 | ```screw(M2_cap_screw, 8)``` |  Screw M2 cap x  8mm |
 |   3 | ```screw(M3_cap_screw, 20)``` |  Screw M3 cap x 20mm |
 |   2 | ```screw(M4_cap_screw, 25)``` |  Screw M4 cap x 25mm |
+|   1 | ```blower(BL40x10)``` |  Square radial 4010 |
+|   4 | ```washer(M2_washer)``` |  Washer  M2 x 5mm x 0.3mm |
 |   3 | ```washer(M3_washer)``` |  Washer  M3 x 7mm x 0.5mm |
 |   2 | ```washer(M4_washer)``` |  Washer  M4 x 9mm x 0.8mm |
 
@@ -464,8 +474,8 @@ PCB cameras.
 ### Modules
 | Module | Description |
 |:--- |:--- |
-| ```camera(type)``` | Draw specified PCB camera |
-| ```camera_lens(type, offset = 0)``` | Draw the lens stack, with optional offset for making a clearance hole |
+| ```camera(type, show_lens = true)``` | Draw specified PCB camera |
+| ```camera_lens(type, offset = 0, show_lens = true)``` | Draw the lens stack, with optional offset for making a clearance hole |
 
 ![cameras](tests/png/cameras.png)
 
@@ -2697,6 +2707,7 @@ Linear rails with carriages.
 | Function | Description |
 |:--- |:--- |
 | ```carriage_screw_depth(type)``` | Carriage thread depth |
+| ```rail_holes(type, length)``` | Number of holes in a rail given its ```length``` |
 | ```rail_screw_height(type, screw)``` | Position screw taking into account countersink into counterbored hole |
 | ```rail_travel(type, length)``` | How far the carriage can travel |
 
@@ -4548,7 +4559,13 @@ Parametric cable drag chain to limit the bend radius of a cable run.
 
 Each link has a maximum bend angle of 45°, so the mininium radius is proportional to the link length.
 
-The travel prpoery is how far it can move in each direction, i.e. half the maximum travel if the chain is mounted in the middle of the travel.
+The travel property is how far it can move in each direction, i.e. half the maximum travel if the chain is mounted in the middle of the travel.
+
+The ends can have screw lugs with four screw positions to choose from, specified by a list of two arrays of four bools.
+If none are enabled then a child object is expected to customise the end and this gets unioned with the blank end.
+If both ends are customised then two children are expected.
+Each child is called twice, once with ```$fasteners``` set to 0 to augment the STL and again with ```$fasteners``` set to 1 to add
+to the assembly, for example to add inserts.
 
 
 [printed/drag_chain.scad](printed/drag_chain.scad) Implementation.
@@ -4571,6 +4588,7 @@ The travel prpoery is how far it can move in each direction, i.e. half the maxim
 | Function | Description |
 |:--- |:--- |
 | ```drag_chain(name, size, travel, wall = 1.6, bwall = 1.5, twall = 1.5, screw = M2_cap_screw, screw_lists = [[1,0,0,1],[1,0,0,1]])``` | Constructor |
+| ```drag_chain_clearance()``` | Clearance around joints. |
 | ```drag_chain_outer_size(type)``` | Link outer dimensions |
 | ```drag_chain_radius(type)``` | The bend radius at the pivot centres |
 | ```drag_chain_z(type)``` | Outside dimension of a 180 bend |
@@ -5127,7 +5145,7 @@ Clamp for ribbon cable and polypropylene strip.
 | Module | Description |
 |:--- |:--- |
 | ```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_assembly(ways, screw = 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, screw = screw, side = undef)``` | Place children at hole positions |
 | ```ribbon_clamp_holes(ways, h = 20, screw = screw)``` | Drill screw holes |
@@ -6047,11 +6065,11 @@ Global constants, functions and modules. This file is used directly or indirectl
 | ```circle4n(r, d = undef)``` | Circle with multiple of 4 vertices |
 | ```ellipse(xr, yr)``` | Draw an ellipse |
 | ```extrude_if(h, center = true)``` | Extrudes 2D object to 3D when ```h``` is nonzero, otherwise leaves it 2D |
-| ```hflip()``` | Invert children by doing a 180° flip around the Y axis |
+| ```hflip(flip=true)``` | Invert children by doing a 180° flip around the Y axis |
 | ```right_triangle(width, height, h, center = true)``` | A right angled triangle with the 90° corner at the origin. 3D when ```h``` is nonzero, otherwise 2D |
 | ```semi_circle(r, d = undef)``` | A semi circle in the positive Y domain |
 | ```translate_z(z)``` | Shortcut for Z only translations |
-| ```vflip()``` | Invert children by doing a 180° flip around the X axis |
+| ```vflip(flip=true)``` | Invert children by doing a 180° flip around the X axis |
 
 ![global](tests/png/global.png)
 

tests/belts.scad

@@ -39,7 +39,7 @@ module belt_test() {
             screw = find_screw(hs_cs_cap, pulley_bore(pulley));
             insert = screw_insert(screw);
 
-            rotate([0, flip ? 180 : 0, 0]) {
+            hflip(flip) {
                 pulley_assembly(pulley);
                 translate_z(pulley_height(pulley) + pulley_offset(pulley) + screw_head_depth(screw, pulley_bore(pulley)))
                     screw(screw, 20);

utils/core/global.scad

@@ -39,8 +39,8 @@ function r2sides4n(r) = floor((r2sides(r) + 3) / 4) * 4;
 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 vflip(flip=true) rotate([flip ? 180 : 0, 0, 0]) children();                  //! Invert children by doing a 180&deg; flip around the X axis
+module hflip(flip=true) rotate([0, flip ? 180: 0, 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()

vitamins/blower.scad

@@ -22,6 +22,8 @@
 //
 include <../utils/core/core.scad>
 use <../utils/rounded_cylinder.scad>
+use <../utils/quadrant.scad>
+use <screw.scad>
 
 function blower_length(type)      = type[2]; //! Length of enclosing rectangle
 function blower_width(type)       = type[3]; //! Width of enclosing rectangle
@@ -39,8 +41,87 @@ function blower_top(type)         = type[14]; //! Thickness of the top
 function blower_wall(type)        = type[15]; //! Side wall thickness
 function blower_lug(type)         = type[16]; //! Height of the lugs
 
+function blower_casing_is_square(type) = len(blower_screw_holes(type)) > 3; //! True for square radial fans, false for spiral shape radial blowers
+function blower_exit_offset(type) = blower_casing_is_square(type) ? blower_length(type) / 2 : blower_exit(type) / 2; //! Offset of exit's centre from the edge
+
 fan_colour = grey(20);
 
+module blower_fan(type, casing_is_square) {
+    module squarish(s, n) {
+        polygon([
+            for(i = [0 : n]) [i * s.x / n,  s.y + (i % 2) * eps],
+            for(i = [0 : n]) [s.x - i * s.x / n, (i % 2) * eps],
+        ]);
+    }
+
+    depth = blower_depth(type);
+    blade_ir = blower_hub(type) / 2 + 0.5; // slight gap between main part of blades and hub
+    blade_len = casing_is_square
+        ? (blower_bore(type) - 1) / 2 - blade_ir // fan constrained by bore hole
+        : blower_width(type) - blower_axis(type).x- blower_wall(type) - blade_ir; // fan extends to casing
+    blade_thickness = 0.75;
+    blade_count = 25;
+
+    base_offset = 1;
+    translate([blower_axis(type).x, blower_axis(type).y, blower_base(type) + base_offset])
+        linear_extrude(blower_hub_height(type) - 0.5 - blower_base(type) - base_offset, center = false, convexity = 4, twist = -30, slices = round(depth / 2))
+            for(i = [0 : blade_count - 1])
+                rotate((360 * i) / blade_count)
+                    translate([blade_ir, -blade_thickness / 2])
+                        squarish([blade_len, blade_thickness], round(blade_len / 2));
+}
+
+module blower_square(type) { //! Draw a square blower
+    width = blower_width(type);
+    depth = blower_depth(type);
+    wall = blower_wall(type);
+    hole_pitch = (blower_screw_holes(type)[1].x - blower_screw_holes(type)[0].x) / 2;
+    corner_radius = width / 2 - hole_pitch;
+    corner_inset = (width - blower_exit(type)) / 2;
+
+    module square_inset_corners(remove_center = false)
+        difference() {
+            //overall outside
+                square([width, width], center = false);
+
+            if (remove_center) {
+                // cut out the inside, leaving the corners
+                translate([corner_inset + wall, -eps])
+                    square([width - 2 * (wall + corner_inset), width - wall + eps], center = false);
+
+                translate([wall, corner_inset + wall])
+                    square([width - 2 * wall, width - 2 * (wall + corner_inset)], center = false);
+            } else {
+                // cut out the bore for the fan
+                translate(blower_axis(type))
+                    circle(d = blower_bore(type));
+            }
+            // corner inset
+            translate([width / 2, width / 2])
+            for(i = [0 : 3])
+                rotate(i * 90)
+                    translate([-width / 2 - eps, -width/ 2 - eps])
+                        quadrant(corner_inset, corner_inset - corner_radius);
+        }
+
+    base_height = blower_base(type);
+    linear_extrude(base_height)
+        difference () {
+            rounded_square([width, width], corner_radius, center = false);
+
+            blower_hole_positions(type)
+                circle(d = blower_screw_hole(type));
+        }
+
+    translate_z(base_height)
+        linear_extrude(depth - base_height)
+            square_inset_corners(remove_center = true);
+
+    translate_z(depth - base_height)
+        linear_extrude(blower_top(type))
+            square_inset_corners();
+}
+
 module blower(type) { //! Draw specified blower
     length = blower_length(type);
     width = blower_width(type);
@@ -70,55 +151,63 @@ module blower(type) { //! Draw specified blower
 
     vitamin(str("blower(", type[0], "): ", type[1]));
 
+    is_square = blower_casing_is_square(type); // Description starts with square!
     color(fan_colour) {
-        // screw lugs
-        linear_extrude(blower_lug(type), center = false)
-            for(hole = blower_screw_holes(type))
-                difference() {
-                    hull() {
+        if (is_square) {
+            blower_square(type);
+        } else {
+            // screw lugs
+            linear_extrude(blower_lug(type), center = false)
+                for(hole = blower_screw_holes(type))
+                    difference() {
+                        hull() {
+                            translate(hole)
+                                circle(d = blower_screw_hole(type) + 2 * blower_wall(type));
+
+                            translate(blower_axis(type))
+                                circle(d = blower_screw_hole(type) + 2 * blower_wall(type) + 7);
+                        }
                         translate(hole)
-                            circle(d = blower_screw_hole(type) + 2 * blower_wall(type));
+                            circle(d = blower_screw_hole(type));
 
-                        translate(blower_axis(type))
-                            circle(d = blower_screw_hole(type) + 2 * blower_wall(type) + 7);
-                    }
-                    translate(hole)
-                        circle(d = blower_screw_hole(type));
+                        shape(true);
+                }
 
-                    shape(true);
-               }
-        // rotor
-        translate(concat(blower_axis(type), [blower_base(type) + 1]))
-            rounded_cylinder(r = blower_hub(type) / 2, h = blower_hub_height(type) - blower_base(type) - 1, r2 = 1);
+            *%square([length, width]);
 
-        *%square([length, width]);
-
-        // base
-        linear_extrude(blower_base(type))
-            difference() {
-                shape();
-
-                translate(concat(blower_axis(type), [blower_base(type)]))
-                    circle(d = 2);
-           }
-        // sides
-        linear_extrude(depth)
-            difference() {
-                shape();
-
-                offset(-blower_wall(type))
-                    shape(true);
-           }
-
-        // top
-        translate_z(depth -blower_top(type))
-            linear_extrude(blower_top(type))
+            // base
+            linear_extrude(blower_base(type))
                 difference() {
                     shape();
 
                     translate(concat(blower_axis(type), [blower_base(type)]))
-                        circle(d = blower_bore(type));
-               }
+                        circle(d = 2);
+            }
+
+            // sides
+            linear_extrude(depth)
+                difference() {
+                    shape();
+
+                    offset(-blower_wall(type))
+                        shape(true);
+            }
+
+            // top
+            translate_z(depth -blower_top(type))
+                linear_extrude(blower_top(type))
+                    difference() {
+                        shape();
+
+                        translate(concat(blower_axis(type), [blower_base(type)]))
+                            circle(d = blower_bore(type));
+                }
+        }
+        // rotor
+        translate(concat(blower_axis(type), [blower_base(type) + 1]))
+            rounded_cylinder(r = blower_hub(type) / 2, h = blower_hub_height(type) - blower_base(type) - 1, r2 = 1);
+
+        blower_fan(type, is_square);
     }
 }
 

vitamins/blowers.scad

@@ -16,10 +16,16 @@
 // You should have received a copy of the GNU General Public License along with NopSCADlib.
 // If not, see <https://www.gnu.org/licenses/>.
 //
+//                                                   l     w   d   b     s              h   a            s    s                               e    h    b    t    w    l
+//                                                   e     i   e   o     c              u   x            c    c                               x    u    a    o    a    u
+//                                                   n     d   p   r     r              b   i            r    r                               i    b    s    p    l    g
+//                                                   g     t   t   e     e                  s            e    e                               t         e         l
+//                                                   t     h   h         w              d                w    w                                              t
+//                                                   h                                                  h    s                                         t         t
+RB5015 = ["RB5015", "Blower Runda RB5015",           51.3, 51, 15, 31.5, M4_cap_screw, 26, [27.3, 25.4], 4.5, [[4.3, 45.4], [47.3,7.4]],     20,   14,  1.5, 1.3, 1.2, 15];
+PE4020 = ["PE4020", "Blower Pengda Technology 4020", 40,   40, 20, 27.5, M3_cap_screw, 22, [21.5, 20  ], 3.2, [[37,3],[3,37],[37,37]],       29.3, 17,  1.7, 1.2, 1.3, 13];
+BL40x10 =["BL40x10","Square radial 4010",            40,   40,9.5, 27,   M2_cap_screw, 16, [24,   20  ], 2.4, [[2,2],[38,2],[2,38],[38,38]], 30  , 9.5, 1.5, 1.5, 1.1, 1.5];
 
-RB5015 = ["RB5015", "Blower Runda RB5015",           51.3, 51, 15, 31.5, M4_cap_screw, 26, [27.3, 25.4], 4.5, [[4.3, 45.4], [47.3,7.4]], 20, 14, 1.5, 1.3, 1.2, 15];
-PE4020 = ["PE4020", "Blower Pengda Technology 4020", 40,   40, 20, 27.5, M3_cap_screw, 22, [21.5, 20  ], 3.2, [[37,3],[3,37],[37,37]], 29.3, 17, 1.7, 1.2, 1.3, 13];
-
-blowers = [PE4020, RB5015];
+blowers = [BL40x10, PE4020, RB5015];
 
 use <blower.scad>

vitamins/camera.scad

@@ -29,7 +29,7 @@ function camera_lens(type)          = type[4]; //! Stack of lens parts, can be r
 function camera_connector_pos(type) = type[5]; //! The flex connector block for the camera itself's position
 function camera_connector_size(type)= type[6]; //! The flex connector block for the camera itself's size
 
-module camera_lens(type, offset = 0) //! Draw the lens stack, with optional offset for making a clearance hole
+module camera_lens(type, offset = 0, show_lens = true) //! Draw the lens stack, with optional offset for making a clearance hole
     color(grey(20))
         translate(camera_lens_offset(type))
             for(p = camera_lens(type)) {
@@ -39,24 +39,25 @@ module camera_lens(type, offset = 0) //! Draw the lens stack, with optional offs
                 if(size.x)
                     rounded_rectangle(size + [2 * offset, 2 * offset, round_to_layer(offset)], r, center = false);
                 else
-                    translate_z(size.y)
-                        rotate_extrude()
-                            difference() {
-                                square([r, size.z + round_to_layer(offset)]);
+                    if (show_lens)
+                        translate_z(size.y)
+                            rotate_extrude()
+                                difference() {
+                                    square([r, size.z + round_to_layer(offset)]);
 
-                                if(app)
-                                    translate([0, size.z])
-                                        hull() {
-                                            translate([0, -eps])
-                                                square([app.y, eps * 2]);
+                                    if(app)
+                                        translate([0, size.z])
+                                            hull() {
+                                                translate([0, -eps])
+                                                    square([app.y, eps * 2]);
 
-                                            translate([0, -app.z])
-                                                square([app.x, app.z]);
-                                        }
-                            }
+                                                translate([0, -app.z])
+                                                    square([app.x, app.z]);
+                                            }
+                                }
             }
 
-module camera(type) {           //! Draw specified PCB camera
+module camera(type, show_lens = true) {           //! Draw specified PCB camera
     vitamin(str("camera(", type[0], "): ", type[1]));
     pcb = camera_pcb(type);
 
@@ -64,7 +65,7 @@ module camera(type) {           //! Draw specified PCB camera
         pcb(pcb);
 
     translate_z(pcb_thickness(pcb)) {
-        camera_lens(type);
+        camera_lens(type, show_lens = show_lens);
 
         conn = camera_connector_size(type);
         if(conn) {

vitamins/rail.scad

@@ -46,12 +46,15 @@ function carriage_pitch_y(type)      = type[6]; //! Screw hole y pitch
 function carriage_screw(type)        = type[7]; //! Carriage screw type
 function carriage_screw_depth(type)  = 2 * screw_radius(carriage_screw(type)); //! Carriage thread depth
 
+function rail_holes(type, length) = //! Number of holes in a rail given its ```length```
+    floor((length - 2 * rail_end(type)) / rail_pitch(type)) + 1;
+
 module rail_hole_positions(type, length, first = 0, screws = 100, both_ends = true) { //! Position children over screw holes
     pitch = rail_pitch(type);
-    holes = floor((length - 2 * rail_end(type)) / pitch) + 1;
+    holes = rail_holes(type, length);
     for(i = [first : holes - 1 - first])
         if(i < screws || (holes - i <= screws && both_ends))
-            translate([i * pitch - length / 2 + (length - (holes -1) * pitch) / 2, 0, 0])
+            translate([i * pitch - length / 2 + (length - (holes - 1) * pitch) / 2, 0])
                 children();
 }
 
@@ -104,24 +107,27 @@ module carriage(type, rail, end_colour = grey(20), wiper_colour = grey(20)) { //
 
     module carriage_end(type, end_w, end_h, end_l) {
         wiper_length = 0.5;
-        color(wiper_colour) translate_z(-end_l/2) linear_extrude(wiper_length)
+        color(wiper_colour) translate_z(-end_l / 2) linear_extrude(wiper_length)
             difference() {
-                translate([-end_w/2, carriage_clearance(type)])
+                translate([-end_w / 2, carriage_clearance(type)])
                     square([end_w, end_h]);
+
                 cutout();
             }
-        color(end_colour) translate_z(wiper_length-end_l/2) linear_extrude(end_l-wiper_length)
+        color(end_colour) translate_z(wiper_length-end_l / 2) linear_extrude(end_l - wiper_length)
             difference() {
-                translate([-end_w/2, carriage_clearance(type)])
+                translate([-end_w / 2, carriage_clearance(type)])
                     square([end_w, end_h]);
+
                 cutout();
             }
     }
 
-    translate([-(block_l+end_l)/2,0,0])
+    translate([-(block_l + end_l) / 2, 0])
         rotate([90, 0, 90])
             carriage_end(type, end_w, end_h, end_l);
-    translate([(block_l+end_l)/2,0,0])
+
+    translate([(block_l + end_l) / 2, 0])
         rotate([90, 0, -90])
             carriage_end(type, end_w, end_h, end_l);
 }