bare/claude-opus-4-0 / tier-3-butt-hinge
success tier 3
bare (claude opus 4)
render
// Butt hinge parameters
leaf_width = 25;
leaf_height = 30;
leaf_thickness = 2;
pin_diameter = 4;
pin_length = 32;
knuckle_outer_diameter = 8;
knuckle_inner_diameter = 4.6;
knuckle_height = 6;
num_knuckles = 5;
// Screw hole parameters
screw_hole_diameter = 3.2;
countersink_diameter = 6;
countersink_depth = 1;
screw_spacing = 8;
// Pin (centered on Y-axis)
color("Silver")
translate([0, -1, 0])
cylinder(h = pin_length, d = pin_diameter, $fn = 32);
// Left leaf (x < 0)
color("DarkGray")
translate([0, 0, 0])
union() {
// Flat plate
translate([-leaf_width, 0, -leaf_thickness/2])
cube([leaf_width - knuckle_outer_diameter/2, leaf_height, leaf_thickness]);
// Knuckles (positions 0, 2, 4)
for (i = [0, 2, 4]) {
translate([0, i * knuckle_height, 0])
difference() {
cylinder(h = knuckle_height, d = knuckle_outer_diameter, $fn = 32);
cylinder(h = knuckle_height, d = knuckle_inner_diameter, $fn = 32);
// Cut half cylinder
translate([knuckle_outer_diameter/2, 0, 0])
cube([knuckle_outer_diameter, knuckle_height, knuckle_height], center = true);
}
}
// Screw holes
for (i = [0, 1, 2]) {
translate([-leaf_width * 0.6, leaf_height/2 + (i - 1) * screw_spacing, 0])
difference() {
cylinder(h = 0.01, d = 0.01); // Dummy for union
// Countersink
translate([0, 0, leaf_thickness/2 - countersink_depth])
cylinder(h = countersink_depth, d1 = screw_hole_diameter, d2 = countersink_diameter, $fn = 32);
// Through hole
translate([0, 0, -leaf_thickness/2 - 0.1])
cylinder(h = leaf_thickness + 0.2, d = screw_hole_diameter, $fn = 32);
}
}
}
// Right leaf (x > 0)
color("DarkGray")
translate([0, 0, 0])
union() {
// Flat plate
translate([knuckle_outer_diameter/2, 0, -leaf_thickness/2])
cube([leaf_width - knuckle_outer_diameter/2, leaf_height, leaf_thickness]);
// Knuckles (positions 1, 3)
for (i = [1, 3]) {
translate([0, i * knuckle_height, 0])
difference() {
cylinder(h = knuckle_height, d = knuckle_outer_diameter, $fn = 32);
cylinder(h = knuckle_height, d = knuckle_inner_diameter, $fn = 32);
// Cut half cylinder
translate([-knuckle_outer_diameter/2, 0, 0])
cube([knuckle_outer_diameter, knuckle_height, knuckle_height], center = true);
}
}
// Screw holes
for (i = [0, 1, 2]) {
translate([leaf_width * 0.6, leaf_height/2 + (i - 1) * screw_spacing, 0])
difference() {
cylinder(h = 0.01, d = 0.01); // Dummy for union
// Countersink
translate([0, 0, leaf_thickness/2 - countersink_depth])
cylinder(h = countersink_depth, d1 = screw_hole_diameter, d2 = countersink_diameter, $fn = 32);
// Through hole
translate([0, 0, -leaf_thickness/2 - 0.1])
cylinder(h = leaf_thickness + 0.2, d = screw_hole_diameter, $fn = 32);
}
}
}
// Apply screw holes to leaves
difference() {
union() {
// Left leaf base
color("DarkGray")
translate([-leaf_width, 0, -leaf_thickness/2])
cube([leaf_width - knuckle_outer_diameter/2, leaf_height, leaf_thickness]);
// Right leaf base
color("DarkGray")
translate([knuckle_outer_diameter/2, 0, -leaf_thickness/2])
cube([leaf_width - knuckle_outer_diameter/2, leaf_height, leaf_thickness]);
}
// Left leaf screw holes
for (i = [0, 1, 2]) {
translate([-leaf_width * 0.6, leaf_height/2 + (i - 1) * screw_spacing, 0]) {
// Countersink
translate([0, 0, leaf_thickness/2 - countersink_depth])
cylinder(h = countersink_depth + 0.1, d1 = screw_hole_diameter, d2 = countersink_diameter, $fn = 32);
// Through hole
cylinder(h = leaf_thickness + 1, d = screw_hole_diameter, center = true, $fn = 32);
}
}
// Right leaf screw holes
for (i = [0, 1, 2]) {
translate([leaf_width * 0.6, leaf_height/2 + (i - 1) * screw_spacing, 0]) {
// Countersink
translate([0, 0, leaf_thickness/2 - countersink_depth])
cylinder(h = countersink_depth + 0.1, d1 = screw_hole_diameter, d2 = countersink_diameter, $fn = 32);
// Through hole
cylinder(h = leaf_thickness + 1, d = screw_hole_diameter, center = true, $fn = 32);
}
}
}
// Knuckles
color("DarkGray") {
// Left leaf knuckles
for (i = [0, 2, 4]) {
translate([0, i * knuckle_height, 0])
difference() {
translate([-knuckle_outer_diameter/2, 0, 0])
cube([knuckle_outer_diameter/2, knuckle_height, knuckle_outer_diameter/2]);
cylinder(h = knuckle_height, d = knuckle_inner_diameter, $fn = 32);
}
}
// Right leaf knuckles
for (i = [1, 3]) {
translate([0, i * knuckle_height, 0])
difference() {
translate([0, 0, 0])
cube([knuckle_outer_diameter/2, knuckle_height, knuckle_outer_diameter/2]);
cylinder(h = knuckle_height, d = knuckle_inner_diameter, $fn = 32);
}
}
} パラメータ (13) —
スライダを動かすと openscad-wasm で再レンダリング
iteration chain
各 iteration step は独立した benchmark run です。parentRunId で前段にリンクします。
→ children (1)
prompt
OpenSCAD で、家具用の小型バット蝶番(butt hinge)を作ってください。 3 つのパーツ(左板、右板、ピン軸)が組み合わさって動作する完成品を、 「開いた状態(180°)」で 1 つの SCAD ファイルに配置して出力します。 寸法と配置: - 板(leaf)2 枚: 30mm × 25mm × 厚さ 2mm の鉄板形状 - 縦 30mm の辺がピン軸に沿う(ヒンジ軸方向) - 横 25mm の辺が回転で開く方向に伸びる - ピン軸: 直径 4mm の円柱、長さ 32mm(両端 1mm ずつ knuckle から飛び出す) - knuckle(筒部): 縦 30mm を 5 等分(各 6mm)に区切り、左板に 3 個・右板に 2 個を 互い違いに配置(左板は外側 2 個 + 中央 1 個、右板は中間 2 個) - knuckle 外径 8mm、内径はピン軸 + 0.3mm クリアランス(= 4.6mm 穴) - 左板と右板はピン軸を共有して回転可能。180° 開いた状態で、両板の 平らな面が同一平面に来るように配置する - 各板の knuckle から離れた側に、M3 用の皿穴を 3 個ずつ (穴ピッチは板の縦方向に 8mm 間隔、皿穴は表面から見て直径 6mm × 深さ 1mm のテーパ + 直径 3.2mm の貫通穴) 座標系: - ピン軸の中心線を Y 軸に重ねる(ピン軸は +Y 方向) - 板の平らな面は Z 軸に直交し、左板が x<0 側、右板が x>0 側に伸びる(180° 開) - knuckle は X=0 を中心とし、Y 方向に 6mm ずつ並ぶ 完成したコード全体を ```openscad ... ``` のフェンスで囲んで出力してください。 コードのみで、追加の説明は不要です。