include include include // Guitar_Scale_Length_mm = 610; // millimetres, slightly over 24inch (609.6mm) Jaguar scale, should be fine for guitar and u-bass // assert(fret_scale_length(0) == 610); // Make sure the function correctly uses our changed global CF_Tube_Len = 420; // Convenient Amazon size, longer would be better of course but prices are important CF_Tube_OD = 5.0; // Outer Diameter CF_Tube_ID = 3.0; CF_Square_Width = 6.0; CF_Square_ID = 5.0; // Inner diameter, sadly doesn't fit the tubes cyl_hd_fn = $preview ? 32 : 512; cyl_ld_fn = $preview ? 24 : 72; module CF_Tube() { // Align +y rotate([0, 0, 90]) render() difference() { rotate([0, 90, 0]) cylinder(h=CF_Tube_Len, d=CF_Tube_OD, $fn=cyl_hd_fn); rotate([0, 90, 0]) cylinder(h=CF_Tube_Len, d=CF_Tube_ID, $fn=cyl_ld_fn); } } module CF_Square() { rotate([0, 0, 90]) render() difference() { translate([0, -CF_Square_Width/2, -CF_Square_Width/2]) cube([CF_Tube_Len, CF_Square_Width, CF_Square_Width]); rotate([0, 90, 0]) cylinder(h=CF_Tube_Len, d=CF_Square_ID, $fn=cyl_ld_fn); } } // Philippians 4:8 // Gideon (ShinKaiYaku07) 真実な, 尊ぶべき, 正しい, 清い, 愛すべき, 評判の良い, 徳とされる, 称賛に値する // ShinKaiYaku65 最後に、兄弟たち。すべての真実なこと、すべての誉れあること、すべての正しいこと、すべてのきよいこと、すべての愛すべきこと、すべての評判の良いこと、そのほか徳と言われること、称賛に値することがあるならば、そのようなことに心を留めなさい。 // I swapped 愛 and 評判 because 12th fret should be the biggest marker, and having only 15 as a 2char marker would be too disorienting // going with 良 for 21 fret_inlays = [[3, "真"], [5, "尊"], [7, "正"], [9, "清"], [12, "評判"], [15, "愛"], [17, "徳"], [19, "賛"], [21, "良"], [24, "主イエス"]]; module neck(string_spacing=18, string_margin=4.5, num_strings=3, target_neck_thickness=15, scallop_depth=3, num_frets=24, fret_width=2.4, filler=false) { fw2 = fret_width/2; neck_length = fret_scale_length(0)+fw2; neck_width = (num_strings-1)*string_spacing + string_margin*2; module neck_stock() { angle_excess = asin((scallop_depth+fw2)/target_neck_thickness); a0 = 90-angle_excess; a1 = 270+angle_excess; rotate([-90, 0, 0]) linear_extrude(neck_length) polygon([for (i = [0:300]) let(a=lerp(a0, a1, i/300.0)) [neck_width*0.5*sin(a), -target_neck_thickness*cos(a)]]); } module scallop(fret) { x0 = fret_scale_length(fret-1) - fw2; x1 = fret_scale_length(fret) + fw2; xmid = lerp(x0, x1, 0.5); // Radius it? arc = arc_points([[x0, scallop_depth], [x1, scallop_depth], [xmid, 0]]); // echo(arc); rotate([90, 0, 90]) linear_extrude(neck_width, center=true) polygon(arc); } module scallops() { for (fret = [0:num_frets]) { scallop(fret); } } module fret_bumps() { for (fret = [0:num_frets]) { translate([0, fret_scale_length(fret), scallop_depth]) rotate([0, 90]) cylinder(d=fret_width, h = neck_width, center = true, $fn=200); } } module fret_inlays() { for (num_text = fret_inlays) { fret = num_text[0]; if (fret <= num_frets) { x0 = fret_scale_length(fret-1); x1 = fret_scale_length(fret); diff = x0 - x1; translate([0, lerp(x0, x1, 0.5), -0.5]) linear_extrude(30) text(text = num_text[1], font = JP_Serif_Font, halign = "center", valign = "center", size = clamp(2, diff-fret_width*2-2, 10)); } } } module fret_side_markers() { for (num_text = fret_inlays) { fret = num_text[0]; if (fret <= num_frets) { x0 = fret_scale_length(fret-1); x1 = fret_scale_length(fret); diff = x0 - x1; rotate([0, -90, 0]) translate([0, x1, neck_width/2-3]) linear_extrude(50) rotate(-35) text(text = str(fret), font = JP_Serif_Font, halign = "right", valign = "center", size = 5); } } } if (filler) { // Somewhat placeholder for now difference() { neck_stock(); scallop(25); translate([-neck_width, 0, scallop_depth]) cube([neck_width*2, Guitar_Scale_Length_mm*3, target_neck_thickness*3]); translate([-neck_width, 0, 0]) cube([neck_width*2, (fret_scale_length(25)+fret_scale_length(24))/2, target_neck_thickness*3]); } } else { render() difference() { neck_stock(); scallops(); fret_inlays(); fret_side_markers(); translate([-neck_width, 0, scallop_depth]) cube([neck_width*2, Guitar_Scale_Length_mm*3, target_neck_thickness*3]); } intersection() { fret_bumps(); neck_stock(); } } } module tailpiece(string_spacing=18, string_margin=4.5, num_strings=3, target_neck_thickness=15, scallop_depth=3, fret_width=2.4*6) { fw2 = fret_width/2; neck_length = 84; neck_width = (num_strings-1)*string_spacing + string_margin*2 + 6 + 6; module neck_stock() { angle_excess = asin((scallop_depth+fw2)/target_neck_thickness); a0 = 90-angle_excess; a1 = 270+angle_excess; rotate([-90, 0, 0]) linear_extrude(neck_length) polygon([for (i = [0:300]) let(a=lerp(a0, a1, i/300.0)) [neck_width*0.5*sin(a), -target_neck_thickness*cos(a)]]); } module scallop(fret) { x0 = fret_scale_length(fret-1) - fw2; x1 = fret_scale_length(fret) + fw2; xmid = lerp(x0, x1, 0.5); // Radius it? arc = arc_points([[x0, scallop_depth], [x1, scallop_depth], [xmid, 0]]); // echo(arc); rotate([90, 0, 90]) linear_extrude(neck_width, center=true) polygon(arc); } module fret_bumps() { translate([0, neck_length-fw2, scallop_depth]) rotate([0, 90]) cylinder(d=fret_width, h=neck_width, center = true, $fn=200); } module differences() { t_offset = -30; //2.7; t_z = -25; //-23; module tuner() { hole_r = 3; bend_r = 24 + hole_r + 10; fn=72; rotate([90, -90, 90]) UBassTuner(from_below=true, from_side=true); // translate([35,16,0]) cylinder(h=10-t_z, d=7, $fn=72); translate([36-7,7,1]) for (a = [10:89]) { hull() { translate([a/9, bend_r-bend_r*sin(a), bend_r*cos(a)]) sphere(hole_r, $fn=fn); translate([(a+1)/9, bend_r-bend_r*sin(a+1), bend_r*cos(a+1)]) sphere(hole_r, $fn=fn); translate([7, bend_r-bend_r*sin(a+1), bend_r*cos(a+1)]) sphere(hole_r, $fn=fn); } } } translate([t_offset, 49, t_z]) tuner(); mirror([1,0,0]) translate([t_offset, 27, t_z]) tuner(); translate([t_offset, 5, t_z]) tuner(); for (i = [-1:2:1]) translate([i*15, 0, -4]) cf_tube(neck_length, 0, tolerance=0.4); translate([0, 0, -10]) cf_tube(neck_length, 0, tolerance=0.4); } thick = 34; render() difference() { color([1,1,1,0.7]) translate([-neck_width/2, 0, -thick]) round_cube([neck_width, neck_length, thick], 4); differences(); } // color([1,1,1,0.3]) neck_stock(); } module cf_tube(x1, x2, tolerance = 0.3, VLH = false) { tolerance = tolerance + (VLH ? 0.3 : 0); translate([0, x2, 0]) rotate([-90,0,0]) cylinder(h=x1-x2, d=CF_Tube_OD+tolerance, $fn=360); hull() { translate([0, x2]) rotate([-90,0,0]) cylinder(h=0.2, d=CF_Tube_OD*1.2+tolerance, $fn=360); translate([0, x2+5]) rotate([-90,0,0]) cylinder(h=0.2, d=CF_Tube_OD+tolerance, $fn=360); } hull() { translate([0, x1]) rotate([-90,0,0]) cylinder(h=0.2, d=CF_Tube_OD*1.2+tolerance, $fn=360); translate([0, x1-5]) rotate([-90,0,0]) cylinder(h=0.2, d=CF_Tube_OD+tolerance, $fn=360); } } module cf_square(x1, x2, tolerance = 0.2, taper_x1 = true, taper_x2 = true) { x = CF_Square_Width+tolerance; translate([-x/2, x2, -x/2]) cube([x, x1-x2, x]); if (taper_x1) { hull() { translate([0, x1, 0]) cube([x*1.2, 0.2, x*1.2], center=true); translate([0, x1-5, 0]) cube([x, 0.2, x], center=true); } } if (taper_x2){ hull() { translate([0, x2, 0]) cube([x*1.2, 0.2, x*1.2], center=true); translate([0, x2+5, 0]) cube([x, 0.2, x], center=true); } } } module fret_tube(from_fret, to_fret, fret_width=2.4) { fw2 = fret_width/2; x0 = fret_scale_length(0)+fw2; x1 = fret_scale_length(from_fret) + ((from_fret==0) ? fw2 : (-fw2)); x2 = fret_scale_length(to_fret)-fw2; render() difference() { neck(fret_width=fret_width); for (i = [-1:2:1]) translate([i*15, 0, -4]) cf_tube(x1, x2); for (i = [-1:2:1]) translate([i*7.5, 0, -7]) cf_square(x1, x2); translate([0, 0, -10]) cf_tube(x1, x2); translate([-50, 0, -50]) cube([100, x2, 100]); translate([-50, x1, -50]) cube([100, x0-x1, 100]); // αβγδεζ rotate([90, 0, 0]) linear_extrude((x2+0.3)*2, center=true) text(text = "01β", font = "Deja Vu Sans", halign = "center", valign = "center", size = 4); } } module fret_tube_filler(from_fret, to_fret, fret_width=2.4, belthole_length=140, VLH=true) { fw2 = fret_width/2; x0 = fret_scale_length(0)+fw2; x1 = fret_scale_length(from_fret) + ((from_fret==0) ? fw2 : (-fw2)); x2 = (to_fret < 100) ? (fret_scale_length(to_fret)-fw2) : 0; render() difference() { neck(fret_width=fret_width, filler=true); for (i = [-1:1]) translate([i*15, 0, (i==0)?(-10):(-4)]) cf_tube(x1, x2, VLH=VLH); translate([-50, 0, -50]) cube([100, x2, 100]); translate([-50, x1, -50]) cube([100, x0-x1, 100]); // Add a belt hole arc = arc_points([[16, -20], [-16, -20], [0, -4]]); belthole_r = 2.5; belthole_fn = 72; belthole_x0 = x1-belthole_r-5; belthole_x1 = belthole_x0 - belthole_length; render() for (i = [0:len(arc)-2]) { hull() { translate([arc[i][0], belthole_x0, arc[i][1]]) sphere(belthole_r, $fn=belthole_fn); translate([arc[i+1][0], belthole_x0, arc[i+1][1]]) sphere(belthole_r, $fn=belthole_fn); translate([arc[i][0], belthole_x1, arc[i][1]]) sphere(belthole_r, $fn=belthole_fn); translate([arc[i+1][0], belthole_x1, arc[i+1][1]]) sphere(belthole_r, $fn=belthole_fn); } } // αβγδεζ t = "01β.β"; translate([0,0,-3.5]) rotate([90, 0, 0]) linear_extrude((x2+0.3)*2, center=true) text(text = t, font = "Deja Vu Sans", halign = "center", valign = "center", size = 4); translate([0,x1-0.3,-3]) rotate([90, 0, 180]) linear_extrude((0.3)*2, center=true) text(text = t, font = "Deja Vu Sans", halign = "center", valign = "center", size = 4); } } module headpiece(string_spacing=18, string_margin=4.5, num_strings=3, target_neck_thickness=15, scallop_depth=3, fret_width=2.4) { headpiece_length = 36; cf_square_length = 32; fw2 = fret_width/2; x0 = fret_scale_length(0)+fw2; neck_width = (num_strings-1)*string_spacing + string_margin*2; bend_radius = 24; module stock() { angle_excess = asin(scallop_depth/target_neck_thickness); a0 = 90-angle_excess; a1 = 270+angle_excess; translate([0, x0, 0]) rotate([-90, 0, 0]) linear_extrude(headpiece_length) polygon([for (i = [0:300]) let(a=lerp(a0, a1, i/300.0)) [neck_width*0.5*sin(a), -target_neck_thickness*cos(a)]]); } module string_tubes(tolerance = 1.0) { string_thicknesses = [4.9, 4.2, 3.0]; module string_tube(diameter, fn=36) { hole_r = diameter/2; bend_r = bend_radius + hole_r; union() { for (a = [0:89]) { hull() { translate([0, bend_r*sin(a), bend_r*cos(a)]) sphere(hole_r, $fn=fn); translate([0, bend_r*sin(a+1), bend_r*cos(a+1)]) sphere(hole_r, $fn=fn); } } hull() { translate([0, bend_r*sin(90), bend_r*cos(90)]) sphere(hole_r, $fn=fn); translate([0, bend_r*sin(90), -target_neck_thickness]) sphere(hole_r, $fn=fn); } } }; for (i = [0:num_strings-1]) { string_diameter = string_thicknesses[i] + tolerance; x = -neck_width/2 + string_margin + (i*string_spacing); translate([x, x0+2, -bend_radius+scallop_depth]) string_tube(string_diameter); } } difference() { stock(); string_tubes(); for (i = [-1:2:1]) translate([i*7.5, 0, -7]) cf_square(x0+cf_square_length, x0, taper_x1=false); // αβγδεζ translate([0, x0+headpiece_length, -5]) rotate([90, 0, 180]) linear_extrude(0.3, center=true) text(text = "01β.γ", font = "Deja Vu Sans", halign = "center", valign = "center", size = 4); } } module bridge(string_spacing=18, string_margin=4.5, num_strings=3, target_neck_thickness=15, scallop_depth=3, fret_width=2.4) { piece_length = 16; cf_square_length = 32; fw2 = fret_width/2; x0 = 0; neck_width = (num_strings-1)*string_spacing + string_margin*2; bend_radius = 24; string_thicknesses = [4.9, 4.2, 3.0]; module stock() { angle_excess = asin(scallop_depth/target_neck_thickness); a0 = 90-angle_excess; a1 = 270+angle_excess; translate([0, x0, 0]) rotate([-90, 0, 0]) linear_extrude(piece_length) polygon([for (i = [0:300]) let(a=lerp(a0, a1, i/300.0)) [neck_width*0.5*sin(a), -target_neck_thickness*cos(a)]]); intersection() { r = 14; translate([0,8,scallop_depth]) rotate([18, -90, 0]) scale([1,0.2,1]) cylinder(r=r, h=neck_width*1.5, center=true, $fn=72); a0 = -90; a1 = 90; translate([0, x0, 0]) rotate([-90, 0, 0]) linear_extrude(piece_length) polygon([for (i = [0:300]) let(a=lerp(a0, a1, i/300.0)) [neck_width*0.5*sin(a), -target_neck_thickness*cos(a)*3]]); } } module string_tubes(tolerance = 1.0) { module string_tube(diameter, fn=36) { hole_r = diameter/2; bend_r = bend_radius + hole_r; union() { for (a = [0:89]) { hull() { translate([0, bend_r*sin(a), bend_r*cos(a)]) sphere(hole_r, $fn=fn); translate([0, bend_r*sin(a+1), bend_r*cos(a+1)]) sphere(hole_r, $fn=fn); } } hull() { translate([0, bend_r*sin(90), bend_r*cos(90)]) sphere(hole_r, $fn=fn); translate([0, bend_r*sin(90), -target_neck_thickness]) sphere(hole_r, $fn=fn); } } }; for (i = [0:num_strings-1]) { string_diameter = string_thicknesses[i] + tolerance; x = -neck_width/2 + string_margin + (i*string_spacing); // translate([x, x0+2, -bend_radius+scallop_depth]) string_tube(string_diameter); translate([x, 0, scallop_depth+string_diameter/2+8]) rotate([-90,0,0]) cylinder(d=string_diameter, h=20, $fn=72); } } // string_tubes(); difference() { stock(); string_tubes(); for (i = [-1:1]) translate([i*15, 0, (i==0)?(-10):(-4)]) cf_tube(piece_length+0.1, x0-0.1, VLH=false); // αβγδεζ translate([0, x0+piece_length, -5]) rotate([90, 0, 180]) linear_extrude(0.3, center=true) text(text = "01β", font = "Deja Vu Sans", halign = "center", valign = "center", size = 4); } } module Nylon6String() { fsl_mm = fret_scale_length(0); echo(str("Making a Nylon 6 String with scale length ", fsl_mm, "mm = ", fsl_mm/25.4, "in")) assert(fret_scale_length(0) == Classical_Short_Scale_mm); // Make sure the function correctly uses our changed global num_frets = 20; num_strings = 6; // 56mm wide neck string_spacing = 10; // 50mm E to e string_margin = 3; // +6 scallop_depth = 2; target_neck_thickness = 22; // neck(num_frets=num_frets, num_strings=num_strings, string_margin=string_margin, string_spacing=string_spacing); module CF_Span() { CF_Square(); translate([0, 140, CF_Square_Width]) CF_Square(); translate([0, 280, CF_Square_Width*2]) CF_Square(); } color([0.4, 0.5, 0.5]) translate([ 12, -40, -16]) CF_Span(); color([0.4, 0.5, 0.5]) translate([-12, -40, -16]) CF_Span(); CF_Tube(); %neck(num_frets=num_frets, num_strings=num_strings, string_margin=string_margin, string_spacing=string_spacing, scallop_depth=scallop_depth, target_neck_thickness=target_neck_thickness); // Debug markers to aid part slicing eyeballing for (i = [150:250:1000]) { %translate([50,i,0]) union() {text(str(i, "mm")); cube([50, 1, 1], center=true);} } } // echo(fret_scale_length(0) - fret_scale_length(8)); // 225.724 // echo(fret_scale_length(8) - fret_scale_length(24)); // 240.335 // fret_tube(0, 8); // //translate([30, 0, 0]) // fret_tube(8, 24); // headpiece(); // UBassTuner(); // fret_tube_filler(24, 100); // tailpiece(); // bridge(); Guitar_Scale_Length_mm = Classical_Short_Scale_mm; // Nylon6String(); difference() { translate([-15, -60, 0]) cube([50, 120, 13]); translate([0, 55, 8]) rotate([180,0,0]) NylonTuner(); }