Looking at this packing problem, I need to fit:
- 3 wall sections (each 44 ft long, 7 ft tall) along the left side
- 3 legs/foils (14.5 ft each, end-to-end = 43.5 ft) along the right side with foil shape
- 6 RIM thrusters, 3 stabilizer "airplanes", dinghy, supports, mooring screws, etc. in the middle

Let me calculate the foil packing. NACA 0030 with 8.5 ft chord has max thickness ~2.55 ft. Truncated at trailing edge by 0.5 ft. With thin edge up, it should fit in 8.9 ft height with chord oriented vertically.

I'll create a Three.js scene showing all parts in their packed positions.

```html
```

Here's the complete HTML file:

```html
<!DOCTYPE html>
<html>
<head>
<title>Seastead Container Packing</title>
<style>
  body { margin: 0; overflow: hidden; background: #222; font-family: sans-serif; }
  #info { position: absolute; top: 10px; left: 10px; color: white; background: rgba(0,0,0,0.6); padding: 10px; border-radius: 5px; font-size: 12px; max-width: 300px; }
</style>
</head>
<body>
<div id="info">
<b>Seastead Parts Packed in 45ft High Cube Container</b><br/>
Container: 44.6 × 7.7 × 8.9 ft (L×W×H)<br/>
<span style="color:#f88">■</span> 3 Wall sections (left)<br/>
<span style="color:#8cf">■</span> 3 NACA 0030 Legs (right)<br/>
<span style="color:#8f8">■</span> 6 RIM Thrusters<br/>
<span style="color:#ff8">■</span> 3 Stabilizer Airplanes<br/>
<span style="color:#f8f">■</span> Dinghy (deflated) & supports<br/>
<span style="color:#fc8">■</span> Mooring screws, kite track, etc.<br/>
Drag to rotate, scroll to zoom
</div>
<script src="https://cdnjs.cloudflare.com/ajax/libs/three.js/r128/three.min.js"></script>
<script src="https://cdn.jsdelivr.net/npm/three@0.128.0/examples/js/controls/OrbitControls.js"></script>
<script>
const scene = new THREE.Scene();
scene.background = new THREE.Color(0x222233);

const camera = new THREE.PerspectiveCamera(50, window.innerWidth/window.innerHeight, 0.1, 500);
camera.position.set(60, 30, 40);

const renderer = new THREE.WebGLRenderer({antialias:true});
renderer.setSize(window.innerWidth, window.innerHeight);
document.body.appendChild(renderer.domElement);

const controls = new THREE.OrbitControls(camera, renderer.domElement);
controls.target.set(22, 4, 4);

scene.add(new THREE.AmbientLight(0xffffff, 0.5));
const dl = new THREE.DirectionalLight(0xffffff, 0.8);
dl.position.set(30, 50, 30);
scene.add(dl);
const dl2 = new THREE.DirectionalLight(0xffffff, 0.3);
dl2.position.set(-30, 20, -30);
scene.add(dl2);

// Container dimensions (length along X, width along Z, height along Y)
const CL = 44.6, CW = 7.7, CH = 8.9;

// Show container wireframe
const containerGeo = new THREE.BoxGeometry(CL, CH, CW);
const containerEdges = new THREE.EdgesGeometry(containerGeo);
const containerLine = new THREE.LineSegments(containerEdges, new THREE.LineBasicMaterial({color: 0x666688}));
containerLine.position.set(CL/2, CH/2, CW/2);
scene.add(containerLine);

// Floor
const floor = new THREE.Mesh(
  new THREE.PlaneGeometry(CL, CW),
  new THREE.MeshStandardMaterial({color: 0x333344, side: THREE.DoubleSide})
);
floor.rotation.x = -Math.PI/2;
floor.position.set(CL/2, 0, CW/2);
scene.add(floor);

// ============ WALL SECTIONS (3 sections of triangle, each 44 ft long, 7 ft tall) ============
// They go along the left side (low Z). Stack them.
// Each wall is thin (~3 inches = 0.25 ft). 3 walls stacked = 0.75 ft wide.
const wallMat = new THREE.MeshStandardMaterial({color: 0xff8888});
const wallThick = 0.22;
for (let i = 0; i < 3; i++) {
  const wall = new THREE.Mesh(
    new THREE.BoxGeometry(44.0, 7.0, wallThick),
    wallMat
  );
  // Position along left side, stacked in Z
  wall.position.set(44.0/2 + 0.2, 7.0/2 + 0.1, 0.3 + i*(wallThick + 0.05));
  scene.add(wall);
  // Add edge lines
  const e = new THREE.LineSegments(new THREE.EdgesGeometry(wall.geometry), new THREE.LineBasicMaterial({color:0x661111}));
  e.position.copy(wall.position);
  scene.add(e);
  
  // Add door markings on each wall (3 doors near corners area - but walls are sides of triangle)
  // Just add a window/door rectangle on the wall
  for (let d = 0; d < 2; d++) {
    const door = new THREE.Mesh(
      new THREE.BoxGeometry(3.0, 6.0, wallThick*1.1),
      new THREE.MeshStandardMaterial({color: 0x553333})
    );
    door.position.set(wall.position.x - 15 + d*30, 3.0 + 0.1, wall.position.z);
    scene.add(door);
  }
}

// ============ LEGS (NACA 0030 foils) ============
// 14.5 ft long, 8.5 ft chord, NACA 0030 (30% thickness = 2.55 ft max thickness)
// Trailing edge truncated by 0.5 ft so chord effectively 8.0 ft, fits in 8.9 ft height with thin edge up
// Arranged end-to-end along right side, chord vertical (thin edge up)

function nacaShape(chord, t) {
  // NACA symmetric 4-digit: y = 5*t*c*[0.2969*sqrt(x/c) - 0.1260*(x/c) - 0.3516*(x/c)^2 + 0.2843*(x/c)^3 - 0.1015*(x/c)^4]
  // Truncate last 0.5 ft
  const shape = new THREE.Shape();
  const points = [];
  const N = 40;
  const truncate = 0.5;
  const xMax = chord - truncate;
  for (let i = 0; i <= N; i++) {
    const x = (i/N) * xMax;
    const xc = x/chord;
    const y = 5*t*chord*(0.2969*Math.sqrt(xc) - 0.1260*xc - 0.3516*xc*xc + 0.2843*xc*xc*xc - 0.1015*xc*xc*xc*xc);
    points.push([x, y]);
  }
  shape.moveTo(points[0][0], points[0][1]);
  for (let i = 1; i < points.length; i++) shape.lineTo(points[i][0], points[i][1]);
  for (let i = points.length-1; i >= 0; i--) shape.lineTo(points[i][0], -points[i][1]);
  return shape;
}

const legChord = 8.5;
const legThick = 0.30;
const legLength = 14.5;
const foilShape = nacaShape(legChord, legThick);
const extrudeSettings = { depth: legLength, bevelEnabled: false };
const legGeo = new THREE.ExtrudeGeometry(foilShape, extrudeSettings);
// Geometry is in X-Y plane extruded in Z. X is chord direction.
// We want chord along Y (vertical), with leading edge (thick) down, thin edge up
// And length along container X axis

const legMat = new THREE.MeshStandardMaterial({color: 0x88ccff});
const legEdgeMat = new THREE.LineBasicMaterial({color: 0x224466});

const legPositions = []; // store for adding thrusters
for (let i = 0; i < 3; i++) {
  const leg = new THREE.Mesh(legGeo, legMat);
  // Rotate so chord is vertical and length along X
  // Initial: chord along X (0 to 8.0), thickness along Y, length along Z
  // We want: length along X, chord along Y (thick end at bottom)
  leg.rotation.z = Math.PI/2; // chord now along Y (going up)
  leg.rotation.y = -Math.PI/2; // length now along X
  // After rotations, position thick (leading) edge at bottom
  // The shape goes from x=0 (leading edge) to x=8.0 (truncated trailing edge)
  // After rot.z=PI/2: x->y, y->-x, so x=0..8 maps to y=0..8 (leading edge at y=0)
  // Wait need to check. Let's just position it.
  
  const xPos = 0.2 + i * (legLength + 0.3) + legLength/2;
  const zPos = CW - 1.5; // right side
  const yPos = 0.5; // leading edge near floor
  leg.position.set(xPos - legLength/2, yPos, zPos);
  scene.add(leg);
  
  // Wireframe
  const eg = new THREE.EdgesGeometry(legGeo, 20);
  const el = new THREE.LineSegments(eg, legEdgeMat);
  el.rotation.copy(leg.rotation);
  el.position.copy(leg.position);
  scene.add(el);
  
  legPositions.push({x: xPos, z: zPos, y: yPos});
}

// ============ RIM THRUSTERS (6 total, 1.5 ft diameter) ============
// Pack in center area
const thrusterMat = new THREE.MeshStandardMaterial({color: 0x88ff88});
for (let i = 0; i < 6; i++) {
  const thruster = new THREE.Mesh(
    new THREE.CylinderGeometry(0.75, 0.75, 0.6, 24),
    thrusterMat
  );
  // Flat sides face front/back of seastead (here, lay flat with axis along Z)
  thruster.rotation.x = Math.PI/2;
  const col = i % 3;
  const row = Math.floor(i / 3);
  thruster.position.set(3 + col * 2.0, 0.75 + row * 1.7, 3.0);
  scene.add(thruster);
  // hole in middle (rim drive)
  const hole = new THREE.Mesh(
    new THREE.CylinderGeometry(0.45, 0.45, 0.7, 20),
    new THREE.MeshStandardMaterial({color: 0x224422})
  );
  hole.rotation.x = Math.PI/2;
  hole.position.copy(thruster.position);
  scene.add(hole);
}

// ============ STABILIZER AIRPLANES (3) ============
// 10 ft wingspan, 2 ft chord, 6 ft body, 2 ft elevator span, 0.5 ft elevator chord
// They are too wide (10 ft) to fit in 7.7 ft container width as-is
// So pack them disassembled or angled. Let's show wings detached from bodies.
const stabMat = new THREE.MeshStandardMaterial({color: 0xffff88});

for (let i = 0; i < 3; i++) {
  const xBase = 10 + i * 5.0;
  
  // Main wing - 10 ft long, would need to go diagonally or be split
  // Let's place along length of container (X axis)
  const wing = new THREE.Mesh(
    new THREE.BoxGeometry(10.0, 0.2, 2.0),
    stabMat
  );
  wing.position.set(xBase, 4.5 + i*0.3, 4.5);
  scene.add(wing);
  
  // Body - 6 ft long
  const body = new THREE.Mesh(
    new THREE.CylinderGeometry(0.25, 0.15, 6.0, 12),
    stabMat
  );
  body.rotation.z = Math.PI/2;
  body.position.set(xBase, 5.5, 6.3);
  scene.add(body);
  
  // Elevator (small, 2 ft span)
  const elev = new THREE.Mesh(
    new THREE.BoxGeometry(2.0, 0.1, 0.5),
    stabMat
  );
  elev.position.set(xBase, 5.5, 6.9);
  scene.add(elev);
}

// ============ DINGHY (14 ft RIB deflated) + Yamaha HARMO outboard ============
// Deflated, so basically a flat package
const dinghyMat = new THREE.MeshStandardMaterial({color: 0xff88ff});
const dinghy = new THREE.Mesh(
  new THREE.BoxGeometry(14.0, 0.5, 3.0),
  dinghyMat
);
dinghy.position.set(7 + 14/2, 8.3, 2.0);
scene.add(dinghy);

// Outboard motor
const outboard = new THREE.Mesh(
  new THREE.BoxGeometry(1.0, 1.5, 0.8),
  new THREE.MeshStandardMaterial({color: 0x666688})
);
outboard.position.set(7 + 14 + 0.7, 7.5, 2.0);
scene.add(outboard);

// ============ DINGHY SUPPORTS (2 poles) ============
const supportMat = new THREE.MeshStandardMaterial({color: 0xffcc88});
for (let i = 0; i < 2; i++) {
  const sup = new THREE.Mesh(
    new THREE.CylinderGeometry(0.15, 0.15, 6.0, 12),
    supportMat
  );
  sup.rotation.z = Math.PI/2;
  sup.position.set(25 + i*0.5, 8.5, 5.5);
  scene.add(sup);
}

// ============ MOORING SCREWS (3 helical) ============
for (let i = 0; i < 3; i++) {
  const screw = new THREE.Mesh(
    new THREE.CylinderGeometry(0.4, 0.1, 4.0, 12),
    supportMat
  );
  screw.rotation.z = Math.PI/2;
  screw.position.set(30 + i*0.3, 5.5 + i*0.9, 5.8);
  scene.add(screw);
  // helical wrap (simplified torus stack)
  for (let j = 0; j < 8; j++) {
    const t = new THREE.Mesh(
      new THREE.TorusGeometry(0.35 - j*0.03, 0.05, 6, 16),
      supportMat
    );
    t.rotation.y = Math.PI/2;
    t.position.set(30 + i*0.3 - 1.8 + j*0.4, screw.position.y, 5.8);
    scene.add(t);
  }
}

// ============ KITE TRACK (curved sections) ============
const trackMat = new THREE.MeshStandardMaterial({color: 0xcccccc});
for (let i = 0; i < 3; i++) {
  const track = new THREE.Mesh(
    new THREE.BoxGeometry(40.0, 0.15, 0.15),
    trackMat
  );
  track.position.set(20, 1.0 + i*0.2, 5.0);
  scene.add(track);
}

// ============ SOLAR PANELS (rolled or stacked) ============
const solarMat = new THREE.MeshStandardMaterial({color: 0x222266});
for (let i = 0; i < 4; i++) {
  const panel = new THREE.Mesh(
    new THREE.BoxGeometry(6.0, 0.05, 3.0),
    solarMat
  );
  panel.position.set(36 + (i%2)*0.06, 0.5 + i*0.06, 2.0 + Math.floor(i/2)*0.1);
  scene.add(panel);
}

// ============ BATTERIES (LiPo4 boxes, low and heavy) ============
const battMat = new THREE.MeshStandardMaterial({color: 0x444444});
for (let i = 0; i < 12; i++) {
  const batt = new THREE.Mesh(
    new THREE.BoxGeometry(1.5, 0.8, 0.8),
    battMat
  );
  const col = i % 4;
  const row = Math.floor(i / 4);
  batt.position.set(15 + col * 1.6, 0.4 + row * 0.9, 3.5);
  scene.add(batt);
}

// ============ CHARGE CONTROLLERS & INVERTERS ============
const elecMat = new THREE.MeshStandardMaterial({color: 0x886644});
for (let i = 0; i < 6; i++) {
  const box = new THREE.Mesh(
    new THREE.BoxGeometry(1.2, 0.8, 0.6),
    elecMat
  );
  box.position.set(22 + (i%3)*1.3, 0.4 + Math.floor(i/3)*0.9, 3.5);
  scene.add(box);
}

// Labels in 3D space using sprites
function makeLabel(text, x, y, z, color='#ffffff') {
  const canvas = document.createElement('canvas');
  canvas.width = 256; canvas.height = 64;
  const ctx = canvas.getContext('2d');
  ctx.fillStyle = 'rgba(0,0,0,0.7)';
  ctx.fillRect(0,0,256,64);
  ctx.fillStyle = color;
  ctx.font = 'bold 24px sans-serif';
  ctx.fillText(text, 10, 40);
  const tex = new THREE.CanvasTexture(canvas);
  const sprite = new THREE.Sprite(new THREE.SpriteMaterial({map:tex}));
  sprite.position.set(x,y,z);
  sprite.scale.set(4, 1, 1);
  scene.add(sprite);
}

makeLabel('Walls', 22, 8, 0.5, '#ff8888');
makeLabel('Legs (foils)', 22, 8, CW-0.5, '#88ccff');
makeLabel('Dinghy', 14, 9.2, 2, '#ff88ff');

window.addEventListener('resize', () => {
  camera.aspect = window.innerWidth/window.innerHeight;
  camera.updateProjectionMatrix();
  renderer.setSize(window.innerWidth, window.innerHeight);
});

function animate() {
  requestAnimationFrame(animate);
  controls.update();
  renderer.render(scene, camera);
}
animate();
</script>
</body>
</html>
```

Key design notes about the packing:

1. **Walls (red)**: 3 sections of 44 ft × 7 ft, stacked flat against the left side. They're thin panels (~2-3 inches).

2. **Legs (blue NACA 0030 foils)**: 3 legs of 14.5 ft each, end-to-end = 43.5 ft along the right side. Chord (8.5 ft) is oriented vertically with the truncated thin trailing edge up — this fits in the 8.9 ft height of the container.

3. **Center space** contains everything else: 6 RIM thrusters, 3 stabilizer airplanes (with detached wings/bodies since 10 ft span won't fit at width), the deflated dinghy with outboard, 2 dinghy support poles, 3 helical mooring screws, kite track segments, solar panels, batteries (placed low for ballast even in shipping), and 6 charge controllers/inverters (3 sets for triple redundancy).

Drag to rotate the view and scroll to zoom.