////////////////////////////////////////////////////////////////////// // LibFile: screw_drive.scad // Recess masks for screw heads // Includes: // include // include // FileGroup: Threaded Parts // FileSummary: Masks for Phillips/Torx/etc driver holes. ////////////////////////////////////////////////////////////////////// // Section: Phillips Drive // Module: phillips_mask() // Description: // Creates a mask for creating a Phillips drive recess given the Phillips size. Each mask can // be lowered to different depths to create different sizes of recess. // Arguments: // size = The size of the bit as an integer or string. "#0", "#1", "#2", "#3", or "#4" // --- // anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER` // spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0` // orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP` // Example: // xdistribute(10) { // phillips_mask(size="#1"); // phillips_mask(size="#2"); // phillips_mask(size=3); // phillips_mask(size=4); // } // Specs for phillips recess here: // https://www.fasteners.eu/tech-info/ISO/4757/ function _phillips_shaft(x) = [3,4.5,6,8,10][x]; function _ph_bot_angle() = 28.0; function _ph_side_angle() = 26.5; module phillips_mask(size="#2", $fn=36, anchor=BOTTOM, spin=0, orient=UP) { assert(in_list(size,["#0","#1","#2","#3","#4",0,1,2,3,4])); num = is_num(size) ? size : ord(size[1]) - ord("0"); shaft = _phillips_shaft(num); b = [0.61, 0.97, 1.47, 2.41, 3.48][num]; e = [0.31, 0.435, 0.815, 2.005, 2.415][num]; g = [0.81, 1.27, 2.29, 3.81, 5.08][num]; alpha = [ 136, 138, 140, 146, 153][num]; beta = [7.00, 7.00, 5.75, 5.75, 7.00][num]; gamma = 92.0; h1 = adj_ang_to_opp(g/2, _ph_bot_angle()); // height of the small conical tip h2 = adj_ang_to_opp((shaft-g)/2, 90-_ph_side_angle()); // height of larger cone l = h1+h2; h3 = adj_ang_to_opp(b/2, _ph_bot_angle()); // height where cutout starts p0 = [0,0]; p1 = [adj_ang_to_opp(e/2, 90-alpha/2), -e/2]; p2 = p1 + [adj_ang_to_opp((shaft-e)/2, 90-gamma/2),-(shaft-e)/2]; attachable(anchor,spin,orient, d=shaft, l=l) { down(l/2) { difference() { rotate_extrude() polygon([[0,0],[g/2,h1],[shaft/2,l],[0,l]]); zrot(45) zrot_copies(n=4, r=b/2) { up(h3) { yrot(beta) { down(1) linear_extrude(height=l+2, convexity=4, center=false) { path = [p0, p1, p2, [p2.x,-p2.y], [p1.x,-p1.y]]; polygon(path); } } } } } } children(); } } // Function: phillips_depth() // Usage: // depth = phillips_depth(size, d); // Description: // Returns the depth of the Phillips recess required to produce the specified diameter, or // undef if not possible. // Arguments: // size = size as a number or text string like "#2" // d = desired diameter function phillips_depth(size, d) = assert(in_list(size,["#0","#1","#2","#3","#4",0,1,2,3,4])) let( num = is_num(size) ? size : ord(size[1]) - ord("0"), shaft = [3,4.5,6,8,10][num], g = [0.81, 1.27, 2.29, 3.81, 5.08][num], h1 = adj_ang_to_opp(g/2, _ph_bot_angle()), // height of the small conical tip h2 = adj_ang_to_opp((shaft-g)/2, 90-_ph_side_angle()) // height of larger cone ) d>=shaft || d= h1+h2 ? undef : 2 * tan(_ph_side_angle())*(depth-h1) + g; // Section: Torx Drive // Module: torx_mask() // Usage: // torx_mask(size, l, [center]); // Description: Creates a torx bit tip. // Arguments: // size = Torx size. // l = Length of bit. // center = If true, centers bit vertically. // --- // anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER` // spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0` // orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP` // Examples: // torx_mask(size=30, l=10, $fa=1, $fs=1); module torx_mask(size, l=5, center, anchor, spin=0, orient=UP) { anchor = get_anchor(anchor, center, BOT, BOT); od = torx_outer_diam(size); attachable(anchor,spin,orient, d=od, l=l) { linear_extrude(height=l, convexity=4, center=true) { torx_mask2d(size); } children(); } } // Module: torx_mask2d() // Usage: // torx_mask2d(size); // Description: Creates a torx bit 2D profile. // Arguments: // size = Torx size. // Example(2D): // torx_mask2d(size=30, $fa=1, $fs=1); module torx_mask2d(size) { od = torx_outer_diam(size); id = torx_inner_diam(size); tip = torx_tip_radius(size); rounding = torx_rounding_radius(size); base = od - 2*tip; $fn = quantup(segs(od/2),12); difference() { union() { circle(d=base); zrot_copies(n=2) { hull() { zrot_copies(n=3) { translate([base/2,0,0]) { circle(r=tip, $fn=$fn/2); } } } } } zrot_copies(n=6) { zrot(180/6) { translate([id/2+rounding,0,0]) { circle(r=rounding); } } } } } // Function: torx_outer_diam() // Usage: // diam = torx_outer_diam(size); // Description: Get the typical outer diameter of Torx profile. // Arguments: // size = Torx size. function torx_outer_diam(size) = lookup(size, [ [ 6, 1.75], [ 8, 2.40], [ 10, 2.80], [ 15, 3.35], [ 20, 3.95], [ 25, 4.50], [ 30, 5.60], [ 40, 6.75], [ 45, 7.93], [ 50, 8.95], [ 55, 11.35], [ 60, 13.45], [ 70, 15.70], [ 80, 17.75], [ 90, 20.20], [100, 22.40] ]); // Function: torx_inner_diam() // Usage: // diam = torx_inner_diam(size); // Description: Get typical inner diameter of Torx profile. // Arguments: // size = Torx size. function torx_inner_diam(size) = lookup(size, [ [ 6, 1.27], [ 8, 1.75], [ 10, 2.05], [ 15, 2.40], [ 20, 2.85], [ 25, 3.25], [ 30, 4.05], [ 40, 4.85], [ 45, 5.64], [ 50, 6.45], [ 55, 8.05], [ 60, 9.60], [ 70, 11.20], [ 80, 12.80], [ 90, 14.40], [100, 16.00] ]); // Function: torx_depth() // Usage: // depth = torx_depth(size); // Description: Gets typical drive hole depth. // Arguments: // size = Torx size. function torx_depth(size) = lookup(size, [ [ 6, 1.82], [ 8, 3.05], [ 10, 3.56], [ 15, 3.81], [ 20, 4.07], [ 25, 4.45], [ 30, 4.95], [ 40, 5.59], [ 45, 6.22], [ 50, 6.48], [ 55, 6.73], [ 60, 8.17], [ 70, 8.96], [ 80, 9.90], [ 90, 10.56], [100, 11.35] ]); // Function: torx_tip_radius() // Usage: // rad = torx_tip_radius(size); // Description: Gets minor rounding radius of Torx profile. // Arguments: // size = Torx size. function torx_tip_radius(size) = lookup(size, [ [ 6, 0.132], [ 8, 0.190], [ 10, 0.229], [ 15, 0.267], [ 20, 0.305], [ 25, 0.375], [ 30, 0.451], [ 40, 0.546], [ 45, 0.574], [ 50, 0.775], [ 55, 0.867], [ 60, 1.067], [ 70, 1.194], [ 80, 1.526], [ 90, 1.530], [100, 1.720] ]); // Function: torx_rounding_radius() // Usage: // rad = torx_rounding_radius(size); // Description: Gets major rounding radius of Torx profile. // Arguments: // size = Torx size. function torx_rounding_radius(size) = lookup(size, [ [ 6, 0.383], [ 8, 0.510], [ 10, 0.598], [ 15, 0.716], [ 20, 0.859], [ 25, 0.920], [ 30, 1.194], [ 40, 1.428], [ 45, 1.796], [ 50, 1.816], [ 55, 2.667], [ 60, 2.883], [ 70, 3.477], [ 80, 3.627], [ 90, 4.468], [100, 4.925] ]); // Section: Robertson/Square Drives // Module: robertson_mask() // Usage: // robertson_mask(size, [extra]); // Description: // Creates a mask for creating a Robertson/Square drive recess given the drive size as an integer. // The width of the recess will be oversized by `2 * $slop`. Note that this model is based // on an incomplete spec. https://www.aspenfasteners.com/content/pdf/square_drive_specification.pdf // We determined the angle by doing print tests on a Prusa MK3S with $slop set to 0.05. // Arguments: // size = The size of the square drive, as an integer from 0 to 4. // extra = Extra length of drive mask to create. // ang = taper angle of each face. Default: 2.5 // $slop = enlarge recess by this twice amount. Default: 0 // Example: // robertson_mask(size=2); // Example: // difference() { // cyl(d1=2, d2=8, h=4, anchor=TOP); // robertson_mask(size=2); // } module robertson_mask(size, extra=1, ang=2.5) { assert(is_int(size) && size>=0 && size<=4); Mmin = [0.0696, 0.0900, 0.1110, 0.1315, 0.1895][size]; Mmax = [0.0710, 0.0910, 0.1126, 0.1330, 0.1910][size]; M = (Mmin + Mmax) / 2 * INCH; Tmin = [0.063, 0.105, 0.119, 0.155, 0.191][size]; Tmax = [0.073, 0.113, 0.140, 0.165, 0.201][size]; T = (Tmin + Tmax) / 2 * INCH; Fmin = [0.032, 0.057, 0.065, 0.085, 0.090][size]; Fmax = [0.038, 0.065, 0.075, 0.095, 0.100][size]; F = (Fmin + Fmax) / 2 * INCH; h = T + extra; Mslop=M+2*$slop; down(T) { intersection(){ Mtop = Mslop + 2*adj_ang_to_opp(F+extra,ang); Mbot = Mslop - 2*adj_ang_to_opp(T-F,ang); prismoid([Mbot,Mbot],[Mtop,Mtop],h=h,anchor=BOT); cyl(d1=0, d2=Mslop/(T-F)*sqrt(2)*h, h=h, anchor=BOT); } } } // vim: expandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap