Formula to Calculate Pipe Weight

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Pipe Weight Calculator & Formula Explained

Accurately calculate the weight of pipes using our specialized calculator. Understand the underlying formula, explore practical examples, and get expert insights into factors influencing pipe weight for your engineering and procurement needs.

Pipe Weight Calculator

Enter the outside diameter of the pipe.
Enter the thickness of the pipe wall.
Enter the total length of the pipe.
Carbon Steel (approx. 7850 kg/m³) Stainless Steel (approx. 7870 kg/m³) Aluminum (approx. 2700 kg/m³) Titanium (approx. 8960 kg/m³) PVC (approx. 1040 kg/m³) Custom
Select the pipe material or enter a custom density.
Enter density in kg/m³ or lb/ft³.
Metric (kg, m) Imperial (lb, ft)
Choose your preferred unit system.

Calculation Results

–.–
–.–

Volume (m³ or ft³)

–.–

Inner Diameter (m or ft)

–.–

Wall Area (m² or ft²)

Formula Used: The weight of a pipe is calculated by finding the volume of the material in the pipe wall and multiplying it by the material's density.

Weight = (Volume of Pipe Wall) × (Material Density)

Volume of Pipe Wall = π × ( (Outer Diameter / 2)² – (Inner Diameter / 2)² ) × Length
Inner Diameter = Outer Diameter – (2 × Wall Thickness)

Pipe Weight Calculation Summary

Pipe Weight:

Formula Used: Weight = (Volume of Pipe Wall) × (Material Density)

Volume of Pipe Wall: π × ( (Outer Diameter / 2)² – (Inner Diameter / 2)² ) × Length

Inner Diameter: Outer Diameter – (2 × Wall Thickness)

Key Assumptions:

Pipe Weight per Unit Length
Parameter Value Unit
Outer Diameter
Wall Thickness
Pipe Length
Material Density
Calculated Pipe Weight

What is Pipe Weight Calculation?

The calculation of pipe weight is a fundamental process in engineering, procurement, and construction (EPC) industries. It involves determining the mass of a specific length of pipe based on its dimensions (outer diameter, wall thickness, length) and the density of the material from which it is made. Accurate pipe weight calculations are crucial for several reasons, including material estimation, cost budgeting, structural load calculations, transportation logistics, and ensuring compliance with project specifications.

Who should use it: Engineers (mechanical, civil, structural), project managers, procurement specialists, estimators, construction supervisors, and anyone involved in projects where piping systems are a significant component. This includes industries such as oil and gas, chemical processing, water treatment, power generation, and infrastructure development.

Common misconceptions: A common misconception is that pipe weight is solely dependent on its outer diameter and length, overlooking the critical role of wall thickness and material density. Another is that all pipes of the same nominal size weigh the same, which is incorrect as different schedules (wall thicknesses) exist for each nominal size. The formula to calculate pipe weight is precise, but its application requires careful attention to units and material properties.

Pipe Weight Formula and Mathematical Explanation

The formula to calculate pipe weight is derived from basic geometric principles and the definition of density. It essentially quantizes the volume of the material forming the pipe and multiplies it by the material's mass per unit volume.

Derivation Steps:

  1. Determine the Cross-Sectional Area of the Pipe Wall: This is the area of the metal that makes up the pipe's structure. It's calculated by subtracting the area of the inner circle from the area of the outer circle.
    Area of Outer Circle = π × (Outer Diameter / 2)²
    Area of Inner Circle = π × (Inner Diameter / 2)²
    Area of Pipe Wall = Area of Outer Circle – Area of Inner Circle
    Area of Pipe Wall = π × [ (Outer Diameter / 2)² – (Inner Diameter / 2)² ]
  2. Calculate the Inner Diameter: The inner diameter is found by subtracting twice the wall thickness from the outer diameter.
    Inner Diameter = Outer Diameter – (2 × Wall Thickness)
  3. Calculate the Volume of the Pipe Wall: This is achieved by multiplying the cross-sectional area of the pipe wall by the length of the pipe.
    Volume of Pipe Wall = Area of Pipe Wall × Pipe Length
  4. Calculate the Pipe Weight: Finally, multiply the volume of the pipe wall by the density of the pipe material.
    Pipe Weight = Volume of Pipe Wall × Material Density

Variable Explanations:

The core formula to calculate pipe weight relies on understanding these key variables:

Variable Meaning Unit Typical Range
OD (Outer Diameter) The measurement across the outside of the pipe. meters (m) or feet (ft) 0.01 m to 1 m (or larger for large industrial pipes)
WT (Wall Thickness) The thickness of the pipe material. meters (m) or feet (ft) 0.001 m to 0.02 m (or larger)
L (Pipe Length) The total length of the pipe section being considered. meters (m) or feet (ft) 1 m to 12 m (standard lengths), can be longer.
ρ (Material Density) The mass per unit volume of the pipe's material. kg/m³ or lb/ft³ 1040 kg/m³ (PVC) to 19300 kg/m³ (Tungsten)
ID (Inner Diameter) The measurement across the inside of the pipe. Calculated: ID = OD – 2*WT meters (m) or feet (ft) Dependent on OD and WT
V (Volume) The total volume occupied by the pipe material. Calculated: V = π * ((OD/2)² – (ID/2)²) * L m³ or ft³ Calculated value
W (Pipe Weight) The final calculated mass of the pipe. kilograms (kg) or pounds (lb) Calculated value

It's critical to ensure all units are consistent before applying the formula to calculate pipe weight. Using a pipe weight calculator can streamline this process.

Practical Examples (Real-World Use Cases)

Understanding the formula to calculate pipe weight is best illustrated with practical scenarios:

Example 1: Calculating Weight for a Carbon Steel Pipeline

A project requires a 12-meter section of carbon steel pipe with an outer diameter (OD) of 168.3 mm (0.1683 m) and a wall thickness (WT) of 7.11 mm (0.00711 m). The density of carbon steel is approximately 7850 kg/m³.

Inputs:

  • OD = 0.1683 m
  • WT = 0.00711 m
  • Length = 12 m
  • Density = 7850 kg/m³

Calculations:

  1. Inner Diameter (ID) = 0.1683 m – (2 * 0.00711 m) = 0.1683 m – 0.01422 m = 0.15408 m
  2. Cross-Sectional Area = π * [ (0.1683/2)² – (0.15408/2)² ] m²
                                       = π * [ (0.08415)² – (0.07704)² ] m²
                                       = π * [ 0.0070814 – 0.0059352 ] m²
                                       = π * 0.0011462 m² ≈ 0.003601 m²
  3. Volume = 0.003601 m² * 12 m ≈ 0.04321 m³
  4. Weight = 0.04321 m³ * 7850 kg/m³ ≈ 339.2 kg

Result: The calculated weight for this 12-meter section of carbon steel pipe is approximately 339.2 kg. This figure is vital for lifting equipment selection and transportation planning.

Example 2: Estimating Weight for an Aluminum Pipe in Imperial Units

For an industrial application, a 20-foot length of aluminum pipe is needed with an OD of 4.5 inches (0.375 ft) and a wall thickness of 0.25 inches (0.02083 ft). The density of aluminum is approximately 168.5 lb/ft³.

Inputs:

  • OD = 0.375 ft
  • WT = 0.02083 ft
  • Length = 20 ft
  • Density = 168.5 lb/ft³

Calculations:

  1. Inner Diameter (ID) = 0.375 ft – (2 * 0.02083 ft) = 0.375 ft – 0.04166 ft = 0.33334 ft
  2. Cross-Sectional Area = π * [ (0.375/2)² – (0.33334/2)² ] ft²
                                       = π * [ (0.1875)² – (0.16667)² ] ft²
                                       = π * [ 0.035156 – 0.027779 ] ft²
                                       = π * 0.007377 ft² ≈ 0.023177 ft²
  3. Volume = 0.023177 ft² * 20 ft ≈ 0.46354 ft³
  4. Weight = 0.46354 ft³ * 168.5 lb/ft³ ≈ 78.07 lb

Result: The estimated weight for this 20-foot aluminum pipe is approximately 78.07 lb. This helps in planning material handling and structural support.

How to Use This Pipe Weight Calculator

Our Pipe Weight Calculator is designed for ease of use and accuracy. Follow these simple steps to get your weight calculation:

  1. Enter Dimensions: Input the Outer Diameter (OD), Wall Thickness (WT), and Pipe Length (L). Ensure you use consistent units (either meters or feet).
  2. Select Material Density: Choose your pipe material from the dropdown list. The calculator automatically populates the corresponding density. For materials not listed, select "Custom" and enter the exact density value. Don't forget to specify the units (kg/m³ or lb/ft³) if you enter a custom value, although the calculator primarily uses the selected system units for density.
  3. Choose Units: Select your preferred unit system (Metric or Imperial) using the dropdown. This will ensure all input prompts and output results are displayed in your chosen units.
  4. Calculate: Click the "Calculate Weight" button. The calculator will instantly display the primary result: the Total Pipe Weight.
  5. Review Intermediate Values: Below the main result, you'll find key intermediate values like the Volume of the pipe material, the calculated Inner Diameter, and the Wall Cross-Sectional Area. These provide further insight into the calculation.
  6. Interpret Results: The calculated weight is essential for procurement orders, structural analysis, and logistical planning. Use the table and chart for a quick visual overview and comparison.
  7. Copy or Reset: Use the "Copy Results" button to easily transfer the summary to reports or documents. Click "Reset" to clear all fields and start a new calculation.

By following these steps, you can confidently utilize the formula to calculate pipe weight for any project requirement.

Key Factors That Affect Pipe Weight Results

While the formula to calculate pipe weight is straightforward, several factors can influence the final result and its practical application:

  1. Material Density Variations: Although standard densities are used (like those found in pipe material specifications), the actual density of metal alloys can vary slightly due to manufacturing processes, specific alloy compositions, and temperature. Higher density materials like steel will result in significantly heavier pipes than lighter materials like aluminum or plastics, even for identical dimensions.
  2. Dimensional Tolerances: Manufacturing processes have inherent tolerances for outer diameter and wall thickness. A pipe might be slightly larger or thicker than specified, leading to a slightly higher weight. Conversely, undersized or thinner pipes will weigh less. These variations are critical in large-scale projects where cumulative weight differences can be substantial.
  3. Pipe Schedule and Standards: Pipes are often classified by "schedule" (e.g., Sch 40, Sch 80), which denotes specific wall thicknesses for given nominal pipe sizes. Using the correct schedule is paramount. A Sch 80 pipe will be considerably heavier than a Sch 40 pipe of the same nominal size due to its thicker wall. Adhering to industry standards (like ASTM, ASME, API) ensures consistency.
  4. Internal Coatings and Linings: Some pipes are lined with materials (like cement, rubber, or specialized polymers) for corrosion resistance or flow improvement. These linings add to the overall weight, which is not typically captured by the basic formula calculating the weight of the pipe material itself.
  5. External Coatings: Similar to internal linings, external coatings (e.g., epoxy, galvanization, insulation) add weight. If precise weight is critical, these additional layers must be factored in, often requiring separate calculations or manufacturer data.
  6. Temperature Effects: While density values are usually provided at standard ambient temperatures, materials expand or contract with significant temperature changes. This can slightly alter dimensions (and thus volume and weight), though the effect is often negligible for most practical engineering calculations unless dealing with extreme temperature ranges.
  7. Threaded Ends or Beveled Ends: Pipes designed for specific joining methods might have variations at the ends. Beveled ends have slightly less material removed than threaded ends, which involve machining to create threads. This can cause minor variations in weight at the pipe ends.

Frequently Asked Questions (FAQ)

What is the standard formula to calculate pipe weight?
The standard formula is: Pipe Weight = π × ( (OD² – ID²) / 4 ) × Length × Density, where ID = OD – 2*WT. This calculates the volume of the pipe wall material and multiplies it by the material's density.
How do I convert between Metric and Imperial units for pipe weight calculation?
Ensure all input dimensions (OD, WT, Length) are in the same unit system (e.g., all in meters or all in feet) and that the density matches that system (kg/m³ or lb/ft³). Our calculator handles this conversion automatically when you select your preferred units.
Does the calculator account for corrosion allowance?
The standard formula to calculate pipe weight, and thus this calculator, primarily focuses on the nominal dimensions provided. It does not inherently account for corrosion allowance. For pipes expected to corrode, you might need to calculate weight based on maximum expected wall thickness after corrosion or add a margin based on project specifications.
What is the difference between pipe weight and pipe load?
Pipe weight refers to the mass of the pipe itself. Pipe load is a broader term that includes the weight of the pipe, plus the weight of its contents (fluid, gas), any insulation, external attachments, and dynamic forces acting on it. The calculated pipe weight is a component of the total pipe load.
Why is pipe weight important for structural design?
Structural engineers need to know the pipe weight to calculate the loads imposed on supporting structures (like pipe racks, bridges, or building elements). This ensures the supports are adequately designed to bear the weight safely without failure. Accurate weight estimation prevents over-engineering (costly) or under-engineering (unsafe).
Can I calculate the weight of a hollow tube using this calculator?
Yes, a hollow tube is essentially a pipe. As long as you have the outer diameter, wall thickness, length, and material density, this calculator can accurately determine its weight. The principles of the formula to calculate pipe weight apply broadly to cylindrical hollow sections.
What density should I use for a custom material?
You should use the specific density value provided by the material manufacturer or found in reliable engineering handbooks for that specific alloy or material grade. Ensure the density unit (kg/m³ or lb/ft³) is consistent with the dimensional units you are using.
How accurate are the standard density values provided?
The standard density values provided are typical approximations for common materials. Actual densities can vary slightly based on the precise alloy composition, manufacturing methods, and temperature. For highly critical applications demanding utmost precision, consult specific material certifications or conduct material testing.

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var pipeWeightChartInstance = null; // Global variable to hold chart instance function getElement(id) { return document.getElementById(id); } function updateUnits() { var selectedUnits = getElement('units').value; var odInput = getElement('outerDiameter'); var wtInput = getElement('wallThickness'); var lenInput = getElement('pipeLength'); var densitySelect = getElement('pipeMaterialDensity'); var customDensityInput = getElement('customDensity'); var densityUnitSpan = getElement('tableDensityUnit'); // Assuming this exists or we add it if (selectedUnits === 'metric') { odInput.placeholder = "e.g., 0.1683 (m)"; wtInput.placeholder = "e.g., 0.00711 (m)"; lenInput.placeholder = "e.g., 12 (m)"; getElement('tableODUnit').innerText = 'm'; getElement('tableWTUnit').innerText = 'm'; getElement('tableLenUnit').innerText = 'm'; getElement('tableWeightUnit').innerText = 'kg'; densityUnitSpan.innerText = 'kg/m³'; // Reset dropdowns to default metric values if possible or prompt user if (densitySelect.value === "" || densitySelect.value === "2700" || densitySelect.value === "1040") { // Imperial defaults if applicable densitySelect.value = "7850"; // Default to Carbon Steel (Metric) getElement('customDensityGroup').style.display = 'none'; } customDensityInput.value = ""; // Clear custom input } else { // Imperial odInput.placeholder = "e.g., 0.375 (ft)"; wtInput.placeholder = "e.g., 0.02083 (ft)"; lenInput.placeholder = "e.g., 20 (ft)"; getElement('tableODUnit').innerText = 'ft'; getElement('tableWTUnit').innerText = 'ft'; getElement('tableLenUnit').innerText = 'ft'; getElement('tableWeightUnit').innerText = 'lb'; densityUnitSpan.innerText = 'lb/ft³'; // Adjust density options or prompt user. Densities are in kg/m³ so need conversion. // For simplicity, let's keep the values and assume the user knows to convert or we add conversion logic. // A better approach would be to store both metric and imperial densities or convert on the fly. // For this example, let's adjust placeholders and assume conversion is handled by the calculator logic or user. // Let's assume the density values in options are kg/m^3. Need to convert to lb/ft^3. // 1 kg/m³ ≈ 0.062428 lb/ft³ // Update density options' internal values if needed or just use the display text. // For now, rely on the calculator logic to convert density based on selected unit system. if (densitySelect.value === "" || densitySelect.value === "7850" || densitySelect.value === "7870" || densitySelect.value === "8960" || densitySelect.value === "1040") { densitySelect.value = "2700"; // Default to Aluminum (if it's typically used in imperial) – Or keep it generic. Let's default to a common imperial context or custom. getElement('customDensityGroup').style.display = 'none'; } customDensityInput.value = ""; } // Trigger recalculation after unit change updateCalculator(); } function validateInput(value, id, min, max, label) { var errorElement = getElement(id + 'Error'); var numericValue = parseFloat(value); errorElement.innerText = "; // Clear previous error if (value.trim() === ") { errorElement.innerText = label + ' is required.'; return false; } if (isNaN(numericValue)) { errorElement.innerText = 'Please enter a valid number for ' + label + '.'; return false; } if (numericValue max) { errorElement.innerText = label + ' cannot be greater than ' + max + '.'; return false; } return true; } function getDensityValue() { var densitySelect = getElement('pipeMaterialDensity'); var customDensityInput = getElement('customDensity'); var selectedUnits = getElement('units').value; var densityKgM3 = 0; if (densitySelect.value === "") { var customValue = parseFloat(customDensityInput.value); if (isNaN(customValue) || customValue = od / 2) { getElement('wallThicknessError').innerText = 'Wall thickness cannot be greater than or equal to half the outer diameter.'; return; } var id = od – (2 * wt); if (id <= 0) { getElement('wallThicknessError').innerText = 'Resulting inner diameter is not valid. Check OD and Wall Thickness.'; return; } var pi = Math.PI; var outerRadius = od / 2; var innerRadius = id / 2; var crossSectionalArea = pi * (Math.pow(outerRadius, 2) – Math.pow(innerRadius, 2)); var volume = crossSectionalArea * length; var weightKg = volume * densityKgM3; // Always calculate in kg first var finalWeight; var displayVolume; var displayID; var displayArea; var densityUnit; if (selectedUnits === 'metric') { finalWeight = weightKg; displayVolume = volume; displayID = id; displayArea = crossSectionalArea; densityUnit = 'kg/m³'; getElement('tableODUnit').innerText = 'm'; getElement('tableWTUnit').innerText = 'm'; getElement('tableLenUnit').innerText = 'm'; getElement('tableWeightUnit').innerText = 'kg'; } else { // Imperial units // Convert dimensions to feet if they were entered in inches (assuming common scenario) // The input placeholders suggest meters/feet, so let's assume user input IS in feet if Imperial is selected. // If user enters mm or inches, explicit conversion is needed. For now, assume direct input in feet. // Convert kg to lb (1 kg ≈ 2.20462 lb) finalWeight = weightKg * 2.20462; // Convert m³ to ft³ (1 m³ ≈ 35.3147 ft³) displayVolume = volume * 35.3147; // Convert m to ft (1 m ≈ 3.28084 ft) displayID = id * 3.28084; // Convert m² to ft² (1 m² ≈ 10.7639 ft²) displayArea = crossSectionalArea * 10.7639; densityUnit = 'lb/ft³'; getElement('tableODUnit').innerText = 'ft'; getElement('tableWTUnit').innerText = 'ft'; getElement('tableLenUnit').innerText = 'ft'; getElement('tableWeightUnit').innerText = 'lb'; } getElement('mainResult').innerText = finalWeight.toFixed(2); getElement('volumeResult').innerText = displayVolume.toFixed(4); getElement('innerDiameterResult').innerText = displayID.toFixed(4); getElement('crossSectionalAreaResult').innerText = displayArea.toFixed(4); // Update table getElement('tableOD').innerText = od.toFixed(4); getElement('tableWT').innerText = wt.toFixed(4); getElement('tableLen').innerText = length.toFixed(2); getElement('tableDensity').innerText = (selectedUnits === 'metric' ? densityKgM3 : densityKgM3 / 16.0185).toFixed(2); // Show density in selected units getElement('tableWeight').innerText = finalWeight.toFixed(2); // Update copy target content getElement('copyMainResult').innerText = finalWeight.toFixed(2) + (selectedUnits === 'metric' ? ' kg' : ' lb'); getElement('copyIntermediateResults').innerHTML = 'Volume: ' + displayVolume.toFixed(4) + (selectedUnits === 'metric' ? ' m³' : ' ft³') + " + 'Inner Diameter: ' + displayID.toFixed(4) + (selectedUnits === 'metric' ? ' m' : ' ft') + " + 'Wall Cross-Sectional Area: ' + displayArea.toFixed(4) + (selectedUnits === 'metric' ? ' m²' : ' ft²') + "; var densityValueForDisplay = densitySelect.value === "" ? customDensityInput.value : densitySelect.options[densitySelect.selectedIndex].text; var densityUnitForDisplay = densitySelect.options[densitySelect.selectedIndex].getAttribute('data-unit') || densityUnit; if (selectedUnits === 'imperial' && densitySelect.value !== "") { // Convert displayed density unit if needed (approximate) var baseDensity = parseFloat(densitySelect.value); // kg/m3 if (!isNaN(baseDensity)) { densityValueForDisplay = (baseDensity * 0.062428).toFixed(2); densityUnitForDisplay = 'lb/ft³'; } else { densityValueForDisplay = "N/A"; densityUnitForDisplay = 'lb/ft³'; } } else if (selectedUnits === 'metric' && densitySelect.value !== "") { densityValueForDisplay = densitySelect.options[densitySelect.selectedIndex].text.split('(')[0].trim(); densityUnitForDisplay = 'kg/m³'; } getElement('copyAssumptions').innerHTML = 'Outer Diameter: ' + od.toFixed(4) + (selectedUnits === 'metric' ? ' m' : ' ft') + " + 'Wall Thickness: ' + wt.toFixed(4) + (selectedUnits === 'metric' ? ' m' : ' ft') + " + 'Pipe Length: ' + length.toFixed(2) + (selectedUnits === 'metric' ? ' m' : ' ft') + " + 'Material Density: ' + densityValueForDisplay + ' (' + densityUnitForDisplay + ')'; updateChart(od, id, length, selectedUnits); } function updateCalculator() { var densitySelect = getElement('pipeMaterialDensity'); var customDensityGroup = getElement('customDensityGroup'); var customDensityInput = getElement('customDensity'); if (densitySelect.value === "") { customDensityGroup.style.display = 'flex'; // Use flex to match input-group layout customDensityInput.setAttribute('required', 'true'); } else { customDensityGroup.style.display = 'none'; customDensityInput.removeAttribute('required'); customDensityInput.value = ""; // Clear custom input when not used } // Perform validation on input fields even if button isn't clicked yet var odInput = getElement('outerDiameter'); var wtInput = getElement('wallThickness'); var lenInput = getElement('pipeLength'); var odError = getElement('outerDiameterError'); var wtError = getElement('wallThicknessError'); var lenError = getElement('pipeLengthError'); // Basic validation check for immediate feedback if (odInput.value.trim() !== " && isNaN(parseFloat(odInput.value))) odError.innerText = 'Please enter a valid number.'; else if (odInput.value.trim() === ") odError.innerText = 'Outer Diameter is required.'; else odError.innerText = "; if (wtInput.value.trim() !== " && isNaN(parseFloat(wtInput.value))) wtError.innerText = 'Please enter a valid number.'; else if (wtInput.value.trim() === ") wtError.innerText = 'Wall Thickness is required.'; else wtError.innerText = "; if (lenInput.value.trim() !== " && isNaN(parseFloat(lenInput.value))) lenError.innerText = 'Please enter a valid number.'; else if (lenInput.value.trim() === ") lenError.innerText = 'Pipe Length is required.'; else lenError.innerText = "; // Recalculate if all fields have potentially valid (non-error) content, or just update chart data if possible if (odError.innerText === " && wtError.innerText === " && lenError.innerText === " && getDensityValue() !== null) { calculatePipeWeight(); } else { // Clear results if inputs are invalid to prevent showing stale data getElement('mainResult').innerText = '–.–'; getElement('volumeResult').innerText = '–.–'; getElement('innerDiameterResult').innerText = '–.–'; getElement('crossSectionalAreaResult').innerText = '–.–'; getElement('tableOD').innerText = '–'; getElement('tableWT').innerText = '–'; getElement('tableLen').innerText = '–'; getElement('tableDensity').innerText = '–'; getElement('tableWeight').innerText = '–'; updateChart([], [], [], getElement('units').value); // Clear chart } } function resetCalculator() { getElement('outerDiameter').value = '168.3'; // Example OD in mm, will be converted to m by updateUnits or input logic getElement('wallThickness').value = '7.11'; // Example WT in mm getElement('pipeLength').value = '6'; // Example Length in m var selectedUnits = getElement('units').value; if (selectedUnits === 'metric') { getElement('outerDiameter').value = '0.1683'; getElement('wallThickness').value = '0.00711'; getElement('pipeLength').value = '6'; } else { getElement('outerDiameter').value = '0.552'; // Approx 168.3mm in ft getElement('wallThickness').value = '0.0233'; // Approx 7.11mm in ft getElement('pipeLength').value = '19.69'; // Approx 6m in ft } getElement('pipeMaterialDensity').value = '7850'; // Carbon Steel (Metric) getElement('customDensity').value = "; getElement('customDensityGroup').style.display = 'none'; getElement('units').value = 'metric'; // Reset to metric updateUnits(); // Update UI elements based on reset units updateCalculator(); // Recalculate with reset values } function copyResults() { var copyText = getElement('copy-target').innerText; var textArea = document.createElement("textarea"); textArea.value = copyText; document.body.appendChild(textArea); textArea.select(); try { document.execCommand("copy"); alert("Results copied to clipboard!"); } catch (err) { console.error("Unable to copy results.", err); alert("Failed to copy results. Please copy manually."); } document.body.removeChild(textArea); } function toggleFaq(element) { var parent = element.parentElement; parent.classList.toggle('open'); } function updateChart(od, id, length, units) { var canvas = getElement('pipeWeightChart'); if (!canvas) return; var ctx = canvas.getContext('2d'); if (pipeWeightChartInstance) { pipeWeightChartInstance.destroy(); // Destroy previous chart instance } var maxPipeLength = 15; // Maximum length to show on chart var stepLength = maxPipeLength / 10; var lengths = []; for (var l = stepLength; l <= maxPipeLength; l += stepLength) { lengths.push(parseFloat(l.toFixed(2))); } var pipeWeights = []; var volumes = []; var densityKgM3 = getDensityValue(); if (densityKgM3 === null || od <= 0 || id <= 0 || od <= id) { // Do not draw chart if inputs are invalid ctx.clearRect(0, 0, canvas.width, canvas.height); // Clear canvas return; } lengths.forEach(function(len) { var pi = Math.PI; var outerRadius = od / 2; var innerRadius = id / 2; var crossSectionalArea = pi * (Math.pow(outerRadius, 2) – Math.pow(innerRadius, 2)); var volume = crossSectionalArea * len; var weightKg = volume * densityKgM3; if (units === 'imperial') { pipeWeights.push(weightKg * 2.20462); // Convert to lb volumes.push(volume * 35.3147); // Convert to ft³ } else { pipeWeights.push(weightKg); // Keep as kg volumes.push(volume); // Keep as m³ } }); var unitLabelWeight = units === 'metric' ? 'kg' : 'lb'; var unitLabelVolume = units === 'metric' ? 'm³' : 'ft³'; pipeWeightChartInstance = new Chart(ctx, { type: 'line', data: { labels: lengths.map(function(l) { return l.toString(); }), datasets: [{ label: 'Pipe Weight (' + unitLabelWeight + ')', data: pipeWeights, borderColor: '#004a99', backgroundColor: 'rgba(0, 74, 153, 0.1)', fill: true, tension: 0.1 }, { label: 'Material Volume (' + unitLabelVolume + ')', data: volumes, borderColor: '#28a745', backgroundColor: 'rgba(40, 167, 69, 0.1)', fill: true, tension: 0.1 }] }, options: { responsive: true, maintainAspectRatio: true, scales: { x: { title: { display: true, text: 'Pipe Length (' + (units === 'metric' ? 'm' : 'ft') + ')' } }, y: { title: { display: true, text: 'Value (' + unitLabelWeight + ' / ' + unitLabelVolume + ')' } } }, plugins: { title: { display: true, text: 'Pipe Weight and Volume vs. Length' }, tooltip: { mode: 'index', intersect: false, } }, hover: { mode: 'nearest', intersect: true } } }); } // Initialize the calculator on page load window.onload = function() { // Set initial values in metric getElement('outerDiameter').value = '0.1683'; // 168.3 mm getElement('wallThickness').value = '0.00711'; // 7.11 mm getElement('pipeLength').value = '6'; // 6 meters getElement('pipeMaterialDensity').value = '7850'; // Carbon Steel getElement('units').value = 'metric'; updateUnits(); // Apply initial unit settings calculatePipeWeight(); // Perform initial calculation };

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