Wing Weight Calculator | Calculate Wing Weight for Aircraft & RC Models :root { –primary: #004a99; –secondary: #003366; –success: #28a745; –light: #f8f9fa; –border: #dee2e6; –text: #212529; –shadow: 0 4px 6px rgba(0,0,0,0.1); } * { box-sizing: border-box; margin: 0; padding: 0; } body { font-family: -apple-system, BlinkMacSystemFont, "Segoe UI", Roboto, Helvetica, Arial, sans-serif; line-height: 1.6; color: var(–text); background-color: var(–light); } .container { max-width: 960px; margin: 0 auto; padding: 20px; } /* Header */ header { background: var(–primary); color: white; padding: 2rem 0; margin-bottom: 2rem; text-align: center; } header h1 { font-size: 2.5rem; margin-bottom: 0.5rem; } header p { font-size: 1.1rem; opacity: 0.9; } /* Calculator Styles */ .calculator-wrapper { background: white; border-radius: 8px; box-shadow: var(–shadow); padding: 2rem; margin-bottom: 3rem; border: 1px solid var(–border); } .calc-header { margin-bottom: 1.5rem; border-bottom: 2px solid var(–primary); padding-bottom: 0.5rem; } .input-section { margin-bottom: 2rem; } .input-group { margin-bottom: 1.25rem; } .input-group label { display: block; font-weight: 600; margin-bottom: 0.5rem; color: var(–secondary); } .input-group input, .input-group select { width: 100%; padding: 0.75rem; border: 1px solid var(–border); border-radius: 4px; font-size: 1rem; transition: border-color 0.2s; } .input-group input:focus, .input-group select:focus { outline: none; border-color: var(–primary); box-shadow: 0 0 0 3px rgba(0, 74, 153, 0.1); } .helper-text { font-size: 0.85rem; color: #6c757d; margin-top: 0.25rem; } .error-msg { color: #dc3545; font-size: 0.85rem; margin-top: 0.25rem; display: none; } .button-group { display: flex; gap: 1rem; margin-bottom: 2rem; } button { padding: 0.75rem 1.5rem; border: none; border-radius: 4px; font-size: 1rem; font-weight: 600; cursor: pointer; transition: background 0.2s; } .btn-reset { background: #e2e6ea; color: var(–text); } .btn-reset:hover { background: #dbe0e5; } .btn-copy { background: var(–success); color: white; flex-grow: 1; } .btn-copy:hover { background: #218838; } /* Results */ .results-section { background: #f1f3f5; padding: 1.5rem; border-radius: 6px; border-left: 5px solid var(–primary); } .main-result { text-align: center; margin-bottom: 1.5rem; } .main-result h3 { color: var(–secondary); font-size: 1.1rem; text-transform: uppercase; letter-spacing: 1px; margin-bottom: 0.5rem; } .result-value { font-size: 2.5rem; font-weight: 700; color: var(–primary); } .intermediate-grid { display: flex; flex-direction: column; gap: 1rem; margin-bottom: 1.5rem; } .int-item { display: flex; justify-content: space-between; align-items: center; padding: 0.5rem 0; border-bottom: 1px solid #e9ecef; } .int-item strong { color: var(–secondary); } .formula-box { background: white; padding: 1rem; border-radius: 4px; font-size: 0.9rem; color: #495057; margin-top: 1rem; border: 1px solid var(–border); } /* Table & Chart */ .data-visuals { margin-top: 2rem; } .chart-container { width: 100%; height: 300px; background: white; border: 1px solid var(–border); border-radius: 4px; padding: 10px; margin-bottom: 2rem; position: relative; } table { width: 100%; border-collapse: collapse; margin-bottom: 1rem; background: white; } th, td { padding: 12px; text-align: left; border-bottom: 1px solid var(–border); } th { background-color: var(–primary); color: white; } caption { caption-side: bottom; font-size: 0.85rem; color: #6c757d; padding: 10px 0; text-align: left; } /* Content Section */ article { background: white; padding: 2.5rem; border-radius: 8px; box-shadow: var(–shadow); margin-top: 3rem; } h2 { color: var(–primary); margin-top: 2rem; margin-bottom: 1rem; font-size: 1.8rem; border-bottom: 1px solid #eee; padding-bottom: 0.5rem; } h3 { color: var(–secondary); margin-top: 1.5rem; margin-bottom: 0.75rem; font-size: 1.4rem; } p { margin-bottom: 1.25rem; text-align: justify; } ul, ol { margin-bottom: 1.25rem; padding-left: 1.5rem; } li { margin-bottom: 0.5rem; } .faq-item { margin-bottom: 1.5rem; } .faq-question { font-weight: 700; color: var(–primary); margin-bottom: 0.5rem; display: block; } footer { text-align: center; padding: 3rem 0; margin-top: 3rem; color: #6c757d; border-top: 1px solid var(–border); } .resource-list { list-style: none; padding: 0; } .resource-list li { margin-bottom: 1rem; } .resource-list a { color: var(–primary); font-weight: 600; text-decoration: none; } .resource-list a:hover { text-decoration: underline; } @media (max-width: 600px) { header h1 { font-size: 2rem; } .calculator-wrapper { padding: 1rem; } .result-value { font-size: 2rem; } }

Wing Weight Calculator

Professional Aerospace & RC Weight Estimation Tool

Estimate Wing Mass

Wing Span (m)

Total length from wingtip to wingtip.

Please enter a positive value.

Mean Chord (m)

Average width of the wing from leading to trailing edge.

Please enter a positive value.

Airfoil Thickness (%)

Maximum thickness as a percentage of the chord (e.g., 12 for 12%).

Enter a value between 1 and 50.

Material Density (kg/m³) Balsa Wood (Light) – 160 kg/m³ EPS Foam (RC) – 30 kg/m³ XPS Foam (Blue/Pink) – 50 kg/m³ Carbon Fiber Composite – 1600 kg/m³ Aluminum 7075 – 2700 kg/m³ Custom Density

Density of the primary construction material.

Structure Solidity (%)

Percentage of wing volume that is solid material (e.g., 100% for solid foam, 15% for ribbed).

Enter a percentage between 1 and 100.

Estimated Wing Weight

0.00 kg

Wing Planform Area: 0.00 m²

Approx. Wing Volume: 0.00 m³

Material Mass (Solid): 0.00 kg

Formula Used: Weight ≈ (Span × Chord) × (Chord × Thickness% × 0.7) × Density × (Solidity/100)

Solidity Sensitivity Analysis

Weight Breakdown Estimation

Estimated distribution of weight based on typical structural ratios for the selected construction type.
Component	Est. Percentage	Est. Mass (kg)

What is Calculate Wing Weight?

The process to calculate wing weight is a fundamental step in aerospace engineering and aeromodelling design. It involves determining the total mass of an aircraft's lifting surface based on its geometry, material properties, and internal structural composition. Accurate weight estimation is critical because the wing must be strong enough to support the fuselage and payload while being light enough to ensure efficient flight characteristics.

Whether designing a General Aviation (GA) aircraft, a UAV, or a radio-controlled (RC) plane, understanding how to calculate wing weight allows designers to optimize the "Strength-to-Weight" ratio. Engineers use this calculation to predict the aircraft's Center of Gravity (CG) and determine the necessary lift coefficient required for takeoff.

Common misconceptions include assuming wings are solid blocks of material or that surface area alone determines weight. In reality, the internal structure (ribs, spars, skin thickness) and the airfoil's volume play the most significant roles in the final mass.

Wing Weight Formula and Mathematical Explanation

To calculate wing weight accurately without complex CAD software, engineers often use a geometric volume estimation method adjusted by a solidity factor. The core logic relies on determining the volume of the wing and applying the density of the construction materials.

The Geometric Approximation Formula

The simplified formula used in our calculator is derived as follows:

Weight = Volume × Material Density × Solidity Factor

Where Volume is approximated by treating the wing as a prism with an airfoil cross-section:

Volume ≈ Span × Mean Chord × (Mean Chord × ThicknessRatio) × AirfoilShapeFactor

Variables Table

Key variables used in wing weight estimation.
Variable	Meaning	Unit	Typical Range
b	Wing Span	meters (m)	0.5m (RC) – 30m+ (Transport)
c	Mean Chord	meters (m)	0.1m – 3.0m
t/c	Thickness Ratio	Percentage (%)	8% (Fast) – 18% (Slow/Cargo)
ρ (rho)	Density	kg/m³	30 (Foam) – 2700 (Aluminum)
η (eta)	Solidity/Fill Factor	Percentage (%)	10% (Built-up) – 100% (Solid Core)

Practical Examples (Real-World Use Cases)

Example 1: RC Glider (Balsa Built-up Wing)

An RC hobbyist wants to calculate wing weight for a new thermal glider. The wing uses a rib-and-spar construction method.

Span: 2.0 meters
Mean Chord: 0.2 meters
Thickness: 10%
Material: Balsa Wood (160 kg/m³)
Solidity: 15% (Mostly air inside, just ribs and covering)

Result: The calculated weight would be approximately 0.13 kg (130 grams). This confirms the glider will be lightweight and suitable for catching thermals.

Example 2: Foam Core UAV Wing

A university team is designing a drone with a solid foam core wing reinforced with tape.

Span: 1.5 meters
Mean Chord: 0.3 meters
Thickness: 14%
Material: XPS Foam (50 kg/m³)
Solidity: 100% (Solid block cut with hot wire)

Result: The wing volume is substantial due to the thickness and solid core. The estimated weight is roughly 0.66 kg (660 grams) excluding the motor mount, which helps the team size their servo motors correctly.

How to Use This Wing Weight Calculator

Enter Geometry: Input the total Wing Span and the Mean Chord (average width). If you have a tapered wing, calculate the average of the root and tip chords.
Set Thickness: Input the airfoil thickness percentage. Thicker wings create more lift but add volume and drag.
Select Material: Choose a preset material like Balsa or Foam, or select "Custom" to enter a specific density.
Estimate Solidity:
- Use 90-100% for solid foam wings.
- Use 15-25% for built-up balsa wings (ribs and covering).
- Use 5-10% for hollow molded composite wings.
Analyze Results: Use the "Copy Results" button to save the data for your design log. Check the chart to see how reducing solidity (hollowing out the wing) could save weight.

Key Factors That Affect Calculate Wing Weight Results

When you calculate wing weight, several physical and design factors influence the final number. Understanding these can help you optimize your aircraft design.

1. Aspect Ratio

High aspect ratio wings (long and skinny like a glider) are structurally more demanding. To prevent bending, they often require heavier spars, effectively increasing the "Solidity" factor required to maintain structural integrity.

2. Material Selection

The choice between Balsa (160 kg/m³) and Aluminum (2700 kg/m³) is drastic. However, aluminum is much stronger, allowing for much thinner skins (lower solidity). A balsa wing might be 20% solid, while an aluminum wing might effectively be only 2% solid volume due to hollow construction.

3. Airfoil Thickness

A thick wing (e.g., 18%) has much more internal volume than a thin wing (e.g., 8%). While a thick wing is lighter to build structurally (due to better leverage for the spar), the geometric volume increases, which can increase the weight if using a solid core.

4. Structural Load Factor (G-Loading)

Wings designed for aerobatics (high G-force) need internal reinforcements. This increases the solidity factor. A Piper Cub wing is lighter per square meter than an F-16 wing partly because the F-16 must withstand 9G maneuvers.

5. Manufacturing Technique

A "bagged" composite wing might use excess epoxy resin, adding unnecessary weight. This is represented in the calculator by increasing the material density or the solidity percentage slightly to account for glue weight.

6. Taper Ratio

Tapered wings (narrower at the tip) reduce the volume and weight at the tips, which reduces the structural moment at the root. This allows for a lighter spar structure overall compared to a rectangular wing of the same area.

Frequently Asked Questions (FAQ)

Does this calculator account for the weight of servos and motors?

No. This tool is designed to calculate wing weight for the airframe structure only. You must add the weight of electronics, wiring, and propulsion systems separately to get the All-Up Weight (AUW).

How do I calculate Mean Chord for a tapered wing?

For a simple trapezoidal wing, the Mean Aerodynamic Chord (MAC) is roughly the average of the Root Chord and Tip Chord: (Root + Tip) / 2.

Why is the solidity factor so important?

Wings are rarely solid blocks. A "built-up" wing is mostly air. If you ignore solidity and calculate based on solid volume, your weight estimate will be 5 to 10 times too high.

Can I use this for real aircraft like a Cessna?

This calculator provides a geometric estimation useful for preliminary design. Certified aircraft weight requires strict adherence to manufacturer data and regulatory weighing procedures.

What is a good target wing loading?

For RC trainers, 4-6 kg/m² (converted to oz/sq ft) is good. For fast jets, it can be much higher. The lighter the wing structure calculated here, the more payload you can carry.

Does airfoil shape affect weight?

Yes. A "flat bottom" airfoil generally has more volume than a symmetrical one of the same thickness percentage. We use a shape factor of 0.7 as a general average.

How does carbon fiber affect the calculation?

Carbon is heavy (high density) but extremely strong. You would select a high density but a very low solidity factor (e.g., 2-5%) because the skins can be paper-thin.

Why use metric units?

Aerospace engineering predominantly uses metric units for simplified calculations of mass and density. However, 1 kg ≈ 2.2 lbs if you need to convert.

Related Tools and Internal Resources

Wing Loading Calculator – Determine if your aircraft has enough wing area for its weight.
CG (Center of Gravity) Calculator – Find the balance point using your new wing weight data.
Airfoil Section Database – Compare thickness ratios of standard NACA airfoils.
Thrust to Weight Ratio Calculator – Check if your motor is powerful enough.
RC Plane Flight Time Calculator – Estimate battery duration based on weight and drag.
Material Density Chart – Comprehensive list of aerospace material densities.

// Global variable to store current chart instance var weightChart = null; // Initialize logic window.onload = function() { calculateWingWeight(); }; function updateDensity() { var select = document.getElementById("materialSelect"); var customInput = document.getElementById("customDensity"); if (select.value === "custom") { customInput.style.display = "block"; // Do not overwrite custom input value immediately so user can type } else { customInput.style.display = "none"; customInput.value = select.value; } calculateWingWeight(); } function calculateWingWeight() { // 1. Get Inputs var span = parseFloat(document.getElementById("wingSpan").value); var chord = parseFloat(document.getElementById("meanChord").value); var thicknessPct = parseFloat(document.getElementById("thicknessRatio").value); var densitySelect = document.getElementById("materialSelect").value; var density = (densitySelect === "custom") ? parseFloat(document.getElementById("customDensity").value) : parseFloat(densitySelect); var solidity = parseFloat(document.getElementById("solidityFactor").value); // 2. Validate var hasError = false; if (isNaN(span) || span <= 0) { document.getElementById("err-wingSpan").style.display = "block"; hasError = true; } else { document.getElementById("err-wingSpan").style.display = "none"; } if (isNaN(chord) || chord <= 0) { document.getElementById("err-meanChord").style.display = "block"; hasError = true; } else { document.getElementById("err-meanChord").style.display = "none"; } if (isNaN(thicknessPct) || thicknessPct 50) { document.getElementById("err-thicknessRatio").style.display = "block"; hasError = true; } else { document.getElementById("err-thicknessRatio").style.display = "none"; } if (isNaN(solidity) || solidity 100) { document.getElementById("err-solidityFactor").style.display = "block"; hasError = true; } else { document.getElementById("err-solidityFactor").style.display = "none"; } if (hasError) return; // 3. Logic // Wing Area (Planform) var area = span * chord; // Airfoil approximate cross-sectional area // Approx area of airfoil = Chord * Thickness * ShapeFactor(0.7 for standard subsonic airfoils) var actualThickness = chord * (thicknessPct / 100); var shapeFactor = 0.7; var crossSectionArea = chord * actualThickness * shapeFactor; // Total Geometric Volume (if solid) var volume = crossSectionArea * span; // Effective Volume based on Solidity var effectiveVolume = volume * (solidity / 100); // Weight = Volume * Density var weight = effectiveVolume * density; // Solid Mass (Comparison if it were 100% solid) var solidMass = volume * density; // 4. Update UI document.getElementById("resultWeight").innerHTML = weight.toFixed(2) + " kg"; document.getElementById("resultArea").innerHTML = area.toFixed(2) + " m²"; document.getElementById("resultVolume").innerHTML = effectiveVolume.toFixed(4) + " m³"; document.getElementById("resultSolidMass").innerHTML = solidMass.toFixed(2) + " kg"; // Update Table updateTable(weight); // Update Chart updateChart(volume, density, solidity, weight); } function updateTable(totalWeight) { var tbody = document.getElementById("breakdownTableBody"); tbody.innerHTML = ""; // Heuristic breakdown for display purposes // Assuming: Spar takes significant load, Ribs/Core take volume, Skin takes surface var sparPct = 35; var skinPct = 45; var ribsPct = 20; var sparWeight = totalWeight * (sparPct / 100); var skinWeight = totalWeight * (skinPct / 100); var ribsWeight = totalWeight * (ribsPct / 100); var rows = [ { name: "Spars & Structural Core", pct: sparPct, val: sparWeight }, { name: "Skin / Covering", pct: skinPct, val: skinWeight }, { name: "Ribs / Internal Formers", pct: ribsPct, val: ribsWeight } ]; for (var i = 0; i < rows.length; i++) { var tr = document.createElement("tr"); tr.innerHTML = "" + rows[i].name + "" + "" + rows[i].pct + "%" + "" + rows[i].val.toFixed(2) + ""; tbody.appendChild(tr); } } function updateChart(volume, density, currentSolidity, currentWeight) { var canvas = document.getElementById("weightChart"); var ctx = canvas.getContext("2d"); // Reset canvas ctx.clearRect(0, 0, canvas.width, canvas.height); // Fit canvas to container canvas.width = canvas.parentElement.offsetWidth; canvas.height = canvas.parentElement.offsetHeight; var width = canvas.width; var height = canvas.height; var padding = 40; // Data Series: Weight vs Solidity (0% to 100%) // We will plot a line var dataPoints = []; var maxWeight = volume * density; // at 100% solidity for (var s = 0; s <= 100; s += 10) { var w = volume * density * (s / 100); dataPoints.push({ x: s, y: w }); } // Draw Axes ctx.beginPath(); ctx.strokeStyle = "#dee2e6"; ctx.lineWidth = 1; // Y Axis ctx.moveTo(padding, padding); ctx.lineTo(padding, height – padding); // X Axis ctx.lineTo(width – padding, height – padding); ctx.stroke(); // Labels ctx.fillStyle = "#6c757d"; ctx.font = "12px Arial"; ctx.textAlign = "center"; ctx.fillText("Solidity (%)", width / 2, height – 10); ctx.save(); ctx.translate(10, height / 2); ctx.rotate(-Math.PI / 2); ctx.textAlign = "center"; ctx.fillText("Weight (kg)", 0, 0); ctx.restore(); // Plot Line ctx.beginPath(); ctx.strokeStyle = "#004a99"; ctx.lineWidth = 3; var plotWidth = width – (padding * 2); var plotHeight = height – (padding * 2); for (var i = 0; i < dataPoints.length; i++) { var point = dataPoints[i]; var px = padding + (point.x / 100) * plotWidth; var py = (height – padding) – (point.y / maxWeight) * plotHeight; if (i === 0) ctx.moveTo(px, py); else ctx.lineTo(px, py); } ctx.stroke(); // Highlight Current Point var cx = padding + (currentSolidity / 100) * plotWidth; var cy = (height – padding) – (currentWeight / maxWeight) * plotHeight; ctx.beginPath(); ctx.fillStyle = "#28a745"; ctx.arc(cx, cy, 6, 0, 2 * Math.PI); ctx.fill(); // Tooltip text for current point ctx.fillStyle = "#000"; ctx.textAlign = "left"; var textY = cy – 10; if(textY < 20) textY = cy + 20; // prevent clipping top ctx.fillText("Current: " + currentWeight.toFixed(2) + "kg", cx + 10, textY); } function resetCalculator() { document.getElementById("wingSpan").value = 1.5; document.getElementById("meanChord").value = 0.25; document.getElementById("thicknessRatio").value = 12; document.getElementById("materialSelect").value = "160"; document.getElementById("customDensity").style.display = "none"; document.getElementById("solidityFactor").value = 20; calculateWingWeight(); } function copyResults() { var w = document.getElementById("resultWeight").innerText; var a = document.getElementById("resultArea").innerText; var span = document.getElementById("wingSpan").value; var chord = document.getElementById("meanChord").value; var text = "Wing Weight Calculator Results:\n" + "——————————–\n" + "Total Weight: " + w + "\n" + "Wing Area: " + a + "\n" + "Span: " + span + " m\n" + "Mean Chord: " + chord + " m\n" + "——————————–\n" + "Generated by AeroCalc Tools"; var tempInput = document.createElement("textarea"); tempInput.value = text; document.body.appendChild(tempInput); tempInput.select(); document.execCommand("copy"); document.body.removeChild(tempInput); var btn = document.querySelector(".btn-copy"); var originalText = btn.innerText; btn.innerText = "Copied!"; setTimeout(function(){ btn.innerText = originalText; }, 2000); }