Circular Hollow Pipe Weight Calculator

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Circular Hollow Pipe Weight Calculator | Calculate Pipe Weight Accurately :root { –primary-color: #004a99; –success-color: #28a745; –background-color: #f8f9fa; –text-color: #333; –border-color: #ccc; –card-background: #fff; –shadow: 0 2px 5px rgba(0,0,0,0.1); } body { font-family: 'Segoe UI', Tahoma, Geneva, Verdana, sans-serif; background-color: var(–background-color); color: var(–text-color); line-height: 1.6; margin: 0; padding: 0; } .container { max-width: 1000px; margin: 20px auto; padding: 20px; background-color: var(–card-background); border-radius: 8px; box-shadow: var(–shadow); } header { background-color: var(–primary-color); color: white; padding: 20px; text-align: center; border-radius: 8px 8px 0 0; margin-bottom: 20px; } header h1 { margin: 0; font-size: 2.2em; } .calculator-section { margin-bottom: 40px; padding: 30px; border: 1px solid var(–border-color); border-radius: 8px; background-color: var(–card-background); box-shadow: var(–shadow); } .calculator-section h2 { text-align: center; color: var(–primary-color); margin-bottom: 25px; font-size: 1.8em; } .input-group { margin-bottom: 20px; display: flex; flex-direction: column; } .input-group label { display: block; margin-bottom: 8px; font-weight: bold; color: var(–primary-color); } .input-group input[type="number"], .input-group select { padding: 12px; border: 1px solid var(–border-color); border-radius: 5px; font-size: 1em; box-sizing: border-box; width: 100%; } .input-group input[type="number"]:focus, .input-group select:focus { outline: none; border-color: var(–primary-color); box-shadow: 0 0 0 2px rgba(0, 74, 153, 0.2); } .input-group .helper-text { font-size: 0.85em; color: #666; margin-top: 5px; } .error-message { color: #dc3545; font-size: 0.8em; margin-top: 5px; height: 1.2em; } .button-group { display: flex; justify-content: space-between; margin-top: 30px; gap: 10px; } .button-group button { padding: 12px 20px; border: none; border-radius: 5px; cursor: pointer; font-size: 1em; transition: background-color 0.3s ease; flex-grow: 1; } .btn-calculate { background-color: var(–primary-color); color: white; } .btn-calculate:hover { background-color: #003366; } .btn-reset, .btn-copy { background-color: #6c757d; color: white; } .btn-reset:hover, .btn-copy:hover { background-color: #5a6268; } #results { margin-top: 30px; padding: 25px; border: 1px solid var(–border-color); border-radius: 8px; background-color: var(–success-color); color: white; text-align: center; box-shadow: var(–shadow); } #results h3 { margin-top: 0; font-size: 1.6em; margin-bottom: 15px; } #results .primary-result { font-size: 2.5em; font-weight: bold; margin-bottom: 15px; } #results .secondary-results div { margin-bottom: 10px; font-size: 1.1em; } #results .formula-explanation { font-size: 0.9em; opacity: 0.8; margin-top: 15px; } table { width: 100%; border-collapse: collapse; margin-top: 20px; margin-bottom: 20px; } th, td { padding: 12px; text-align: left; border: 1px solid var(–border-color); } th { background-color: var(–primary-color); color: white; font-weight: bold; } tr:nth-child(even) { background-color: #e9ecef; } canvas { display: block; margin: 20px auto; border: 1px solid var(–border-color); border-radius: 5px; background-color: var(–card-background); } .chart-caption { text-align: center; font-size: 0.9em; color: #666; margin-top: 10px; } .article-section { margin-top: 40px; padding: 30px; background-color: var(–card-background); border-radius: 8px; box-shadow: var(–shadow); } .article-section h2, .article-section h3 { color: var(–primary-color); margin-bottom: 15px; } .article-section h2 { font-size: 2em; } .article-section h3 { font-size: 1.5em; } .article-section p, .article-section ul, .article-section ol { margin-bottom: 20px; } .article-section ul, .article-section ol { padding-left: 25px; } .article-section li { margin-bottom: 10px; } .article-section a { color: var(–primary-color); text-decoration: none; } .article-section a:hover { text-decoration: underline; } .faq-item { margin-bottom: 15px; } .faq-item .question { font-weight: bold; cursor: pointer; color: var(–primary-color); } .faq-item .answer { margin-top: 8px; display: none; padding-left: 15px; border-left: 3px solid var(–primary-color); } .internal-links-list { list-style: none; padding: 0; } .internal-links-list li { margin-bottom: 15px; } .internal-links-list a { font-weight: bold; } .internal-links-list p { margin-top: 5px; font-size: 0.9em; color: #555; } @media (min-width: 768px) { .button-group { flex-direction: row; } }

Circular Hollow Pipe Weight Calculator

Precision is key for material estimation and project planning.

Calculate Pipe Weight

Enter the outside diameter of the pipe.
Enter the thickness of the pipe wall.
Enter the total length of the pipe section.
Steel (7850 kg/m³) Aluminum (2700 kg/m³) Copper (8960 kg/m³) Cast Iron (7210 kg/m³) Brass (9970 kg/m³) Custom
Select material or enter a custom density.
Metric (kg, m, mm) Imperial (lbs, ft, in) Choose your preferred unit system.

Estimated Pipe Weight

Volume:
Cross-sectional Area:
Linear Density:
Weight = Volume × Density. Volume of a hollow cylinder = π × (OD² – ID²) / 4 × Length. Where ID = OD – 2 × Wall Thickness.

Weight vs. Diameter at Constant Thickness

Hover over bars for exact values.

Material Densities

Material Density (kg/m³)
Steel 7850
Aluminum 2700
Copper 8960
Cast Iron 7210
Brass 9970
Standard densities for common pipe materials.

{primary_keyword}

The {primary_keyword} is a fundamental calculation in engineering, construction, and manufacturing. It quantizes the mass of a tubular component that has a circular cross-section and is hollow. This calculation is crucial for accurately determining material requirements, transportation costs, structural load capacities, and fabrication complexities. Understanding how to calculate the weight of circular hollow pipes ensures that projects remain within budget, adhere to safety standards, and are executed efficiently. Whether you are a structural engineer designing a support beam, a contractor ordering materials for a pipeline, or a fabricator estimating raw material needs, precise weight calculation is indispensable.

Who should use it:

  • Structural Engineers: For load calculations and material specifications.
  • Fabricators and Manufacturers: To estimate raw material needs and production costs.
  • Procurement and Supply Chain Managers: For accurate ordering and logistics planning.
  • Architects: For integrating structural elements into designs.
  • DIY Enthusiasts: For small-scale projects requiring precise material quantities.

Common misconceptions: A frequent misconception is that pipe weight is solely dependent on its outer dimensions. In reality, the wall thickness plays a significantly more critical role in determining the actual material volume and thus the weight. Another error is using a generic density value without considering the specific material of the pipe (e.g., steel vs. aluminum), which can lead to substantial inaccuracies in weight estimations.

{primary_keyword} Formula and Mathematical Explanation

The calculation of a circular hollow pipe's weight is derived from its volume and the material's density. The process involves several steps:

  1. Calculate Inner Diameter (ID): The inner diameter is found by subtracting twice the wall thickness from the outer diameter.
  2. Calculate Cross-Sectional Area: The area of the material itself is determined by finding the area of the outer circle and subtracting the area of the inner hollow circle.
  3. Calculate Volume: The volume of the pipe material is the cross-sectional area multiplied by the pipe's length.
  4. Calculate Weight: Finally, the weight is obtained by multiplying the calculated volume by the density of the pipe's material.

The formula can be expressed as:

Weight = Volume × Density

Where:

Volume = Cross-sectional Area × Length

And:

Cross-sectional Area = (π/4) × (OD² – ID²)

Substituting ID = OD – 2 × Wall Thickness:

Cross-sectional Area = (π/4) × [OD² – (OD – 2 × Wall Thickness)²]

Or, a more direct approach after calculating the inner diameter:

Volume = (π/4) × (Outer Diameter² – Inner Diameter²) × Length

Here's a table detailing the variables used:

Variable Meaning Unit Typical Range
OD (Outer Diameter) Outside Diameter of the pipe mm, inches, meters, feet 10 – 1000+ mm (or equivalent)
ID (Inner Diameter) Inside Diameter of the pipe mm, inches, meters, feet OD – 2 × Wall Thickness
Wall Thickness Thickness of the pipe wall mm, inches 0.5 – 50+ mm (or equivalent)
Length Total length of the pipe section meters, feet 0.1 – 100+ meters (or equivalent)
Density Mass per unit volume of the pipe material kg/m³, lbs/ft³ ~2700 kg/m³ (Aluminum) to ~10000 kg/m³ (Brass)
Volume Total space occupied by the pipe material m³, ft³ Calculated
Weight Total mass of the pipe section kg, lbs Calculated

Practical Examples (Real-World Use Cases)

Let's explore some practical scenarios where calculating the {primary_keyword} is essential.

Example 1: Structural Steel Beam

A construction project requires a hollow steel structural support. We need to determine its weight for load-bearing calculations.

  • Inputs:
  • Outer Diameter (OD): 200 mm
  • Wall Thickness: 8 mm
  • Length: 10 meters
  • Material Density: Steel (7850 kg/m³)
  • Units: Metric

Calculation Steps:

  • Convert units to meters: OD = 0.2 m, Length = 10 m, Wall Thickness = 0.008 m.
  • Calculate Inner Diameter (ID): ID = 0.2 m – 2 * 0.008 m = 0.184 m.
  • Calculate Cross-sectional Area: Area = (π/4) * (0.2² – 0.184²) = (π/4) * (0.04 – 0.033856) = (π/4) * 0.006144 m² ≈ 0.00482 m².
  • Calculate Volume: Volume = 0.00482 m² * 10 m = 0.0482 m³.
  • Calculate Weight: Weight = 0.0482 m³ * 7850 kg/m³ ≈ 378.37 kg.

Result: The estimated weight of the steel pipe section is approximately 378.37 kg. This value is critical for ensuring the structural integrity of the design and for estimating transportation and handling logistics.

Example 2: Aluminum Pipeline Component

For an aerospace application, a hollow aluminum pipe needs its weight calculated to minimize overall system mass.

  • Inputs:
  • Outer Diameter (OD): 4 inches
  • Wall Thickness: 0.25 inches
  • Length: 20 feet
  • Material Density: Aluminum (Standard imperial density is approx. 168.5 lbs/ft³)
  • Units: Imperial

Calculation Steps:

  • Calculate Inner Diameter (ID): ID = 4 inches – 2 * 0.25 inches = 3.5 inches.
  • Convert units to feet: OD = 4/12 ft ≈ 0.333 ft, ID = 3.5/12 ft ≈ 0.292 ft, Length = 20 ft.
  • Calculate Cross-sectional Area: Area = (π/4) * (0.333² – 0.292²) = (π/4) * (0.1109 – 0.0853) = (π/4) * 0.0256 ft² ≈ 0.0201 ft².
  • Calculate Volume: Volume = 0.0201 ft² * 20 ft = 0.402 ft³.
  • Calculate Weight: Weight = 0.402 ft³ * 168.5 lbs/ft³ ≈ 67.7 lbs.

Result: The estimated weight of the aluminum pipe section is approximately 67.7 lbs. This precise figure aids in managing the weight budget for the aerospace system.

How to Use This {primary_keyword} Calculator

Using our {primary_keyword} calculator is straightforward and designed for quick, accurate results. Follow these simple steps:

  1. Enter Pipe Dimensions: Input the Outer Diameter (OD) and Wall Thickness of the pipe. Ensure these values are in consistent units (either metric or imperial, which you select later).
  2. Specify Pipe Length: Enter the total length of the pipe section you need to weigh.
  3. Select Material Density: Choose your pipe's material from the dropdown list. Standard densities for common metals like steel, aluminum, copper, cast iron, and brass are pre-loaded. If your material isn't listed or you have a specific density value, select 'Custom' and enter the precise density in kg/m³ or lbs/ft³ (depending on your unit selection).
  4. Choose Units: Select your preferred unit system: 'Metric' (kilograms, meters, millimeters) or 'Imperial' (pounds, feet, inches). The calculator will convert inputs and display results accordingly.
  5. Calculate: Click the "Calculate Weight" button.

How to read results:

  • Primary Highlighted Result (Total Weight): This is the main output, showing the total estimated weight of the pipe section in your selected units.
  • Intermediate Values: You'll also see the calculated Volume, Cross-sectional Area, and Linear Density (weight per unit length) for reference.
  • Formula Explanation: A brief description of the calculation method is provided for transparency.

Decision-making guidance: Use the calculated weight to compare material costs, plan logistics, verify structural load capacities, and ensure your project specifications are met. If the weight exceeds project requirements or budget, consider alternative materials or pipe dimensions.

Key Factors That Affect {primary_keyword} Results

Several factors influence the accuracy and value of your {primary_keyword} calculation. Understanding these helps in refining estimates and making informed decisions:

  1. Material Density: This is the most significant factor after dimensions. Different metals have vastly different densities (e.g., steel is much denser than aluminum). Using an incorrect density will lead to substantial errors. Always verify the exact material grade and its corresponding density.
  2. Dimensional Accuracy: Precise measurements of Outer Diameter (OD), Wall Thickness, and Length are critical. Even small deviations in these inputs can lead to noticeable differences in the final weight, especially for long pipes or those with thick walls.
  3. Unit System Consistency: Ensure all input dimensions (OD, Wall Thickness, Length) are in the same unit before conversion or calculation. Mixing units (e.g., OD in mm, Length in feet) without proper conversion will result in nonsensical outputs.
  4. Pipe Straightness and Uniformity: The calculator assumes a perfectly straight and uniformly dimensioned pipe. Real-world pipes might have slight variations, bends, or non-uniform wall thickness, which can subtly affect the actual weight.
  5. Manufacturing Tolerances: Pipes are manufactured within specific tolerance ranges for dimensions. These tolerances can mean the actual pipe is slightly larger, smaller, thicker, or thinner than specified, impacting the calculated weight.
  6. External Coatings or Linings: If a pipe has significant external coatings (e.g., thick paint, protective layers) or internal linings (e.g., concrete), their weight is not included in this calculation. For precise inventory or structural analysis, these additional material weights may need to be accounted for separately.
  7. Hollow Core Integrity: The formula assumes a clean, empty hollow core. Obstructions or material within the core would alter the volume calculation.

Frequently Asked Questions (FAQ)

Q1: What is the difference between weight and mass?
Mass is the amount of matter in an object, measured in kilograms (kg) or pounds (lbs). Weight is the force of gravity acting on that mass, measured in Newtons (N) or pounds-force (lbf). In practical engineering and material estimation, "weight" is often used interchangeably with mass, and calculators typically output mass in kg or lbs.
Q2: Does the calculator account for the curvature of the pipe?
Yes, the formula inherently accounts for the circular geometry. The volume calculation is based on the area of the annular cross-section (the ring of material) multiplied by the length, which accurately represents the material volume of a curved hollow cylinder.
Q3: Can I use this calculator for square or rectangular hollow sections?
No, this calculator is specifically designed for circular hollow pipes. Square and rectangular hollow sections require a different formula based on their specific cross-sectional geometry (Length × Width × Wall Thickness × Density).
Q4: What does "Linear Density" mean in the results?
Linear Density refers to the weight of the pipe per unit of length (e.g., kg per meter or lbs per foot). It's a useful metric for quickly estimating the weight of longer or shorter sections of the same pipe without re-entering the length each time.
Q5: How accurate are the standard material densities provided?
The provided densities are standard values for common alloys. Actual densities can vary slightly based on the specific alloy composition, heat treatment, and manufacturing process. For critical applications, it's best to consult the material data sheet from the manufacturer.
Q6: What if my pipe has a very thin wall or a very large diameter?
The calculator uses standard geometric formulas and should handle a wide range of dimensions. Ensure you are using consistent units and that the inputs are physically realistic for pipe manufacturing. Extremely thin walls or large diameters might approach the limits of standard pipe manufacturing, but the calculation itself remains valid.
Q7: Should I use metric or imperial units?
The choice depends on your project's standard or your preference. Metric units (kg, m, mm) are widely used globally in engineering and science. Imperial units (lbs, ft, in) are common in the United States and some other regions. The calculator supports both, ensuring flexibility.
Q8: How does pipe weight affect structural design?
Pipe weight directly contributes to the dead load that a structure must support. Engineers use calculated weights to determine the required strength of supporting elements, foundation designs, and overall structural stability. Incorrect weight estimates can lead to under-designed structures, posing safety risks.
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"mm" : "in"; var lengthBaseUnit = (unitSystem === "metric") ? "m" : "ft"; var densityUnit = (unitSystem === "metric") ? "kg/m³" : "lbs/ft³"; // Validate inputs if (isNaN(od) || od <= 0) { odError.textContent = "Please enter a valid positive outer diameter."; isValid = false; } if (isNaN(thickness) || thickness <= 0) { thicknessError.textContent = "Please enter a valid positive wall thickness."; isValid = false; } if (isNaN(length) || length <= 0) { lengthError.textContent = "Please enter a valid positive length."; isValid = false; } var density = getDensityValue(); if (isNaN(density) || density <= 0) { densityError.textContent = "Please select a valid material or enter a positive custom density."; isValid = false; } var id = od – (2 * thickness); if (id <= 0) { thicknessError.textContent = "Wall thickness is too large for the given outer diameter."; isValid = false; } if (!isValid) { resultsDiv.style.display = "none"; return; } // Unit Conversion for calculations var od_m = convertUnits(od, baseUnit, "m"); var id_m = convertUnits(id, baseUnit, "m"); var length_m = convertUnits(length, lengthBaseUnit, "m"); // Calculate var crossSectionalArea_m2 = (Math.PI / 4) * (Math.pow(od_m, 2) – Math.pow(id_m, 2)); var volume_m3 = crossSectionalArea_m2 * length_m; var weight_kg = volume_m3 * density; // Convert results back to selected units var weight_final = convertUnits(weight_kg, "kg", (unitSystem === "metric" ? "kg" : "lbs")); var volume_final = convertUnits(volume_m3, "m³", (unitSystem === "metric" ? "m³" : "ft³")); var area_final = convertUnits(crossSectionalArea_m2, "m²", (unitSystem === "metric" ? "m²" : "ft²")); var linearDensity_final = weight_final / length; // Use final weight and length for linear density display totalWeightOutput.textContent = weight_final.toFixed(2) + (unitSystem === "metric" ? " kg" : " lbs"); volumeOutput.textContent = volume_final.toFixed(4) + (unitSystem === "metric" ? " m³" : " ft³"); areaOutput.textContent = area_final.toFixed(4) + (unitSystem === "metric" ? " m²" : " ft²"); linearDensityOutput.textContent = linearDensity_final.toFixed(2) + "/" + (unitSystem === "metric" ? "m" : "ft"); resultsDiv.style.display = "block"; updateChart(od, thickness, length, unitSystem, weight_kg, volume_m3); } function updateChart(currentOD, currentThickness, currentLength, unitSystem, currentWeightKg, currentVolumeM3) { var baseUnit = (unitSystem === "metric") ? "mm" : "in"; var lengthBaseUnit = (unitSystem === "metric") ? "m" : "ft"; // Clear previous data chartData.labels = []; chartData.datasets[0].data = []; chartData.datasets[1].data = []; var sampleODs = []; var minOD = 50; // Example minimum OD for chart var maxOD = 300; // Example maximum OD for chart var step = (maxOD – minOD) / 7; // Generate 8 points for (var i = 0; i <= 7; i++) { var odValue = minOD + i * step; sampleODs.push(odValue); } for (var i = 0; i < sampleODs.length; i++) { var odSample = sampleODs[i]; var thicknessSample = currentThickness; // Keep thickness constant for this chart var lengthSample = currentLength; // Keep length constant for this chart var idSample = odSample – (2 * thicknessSample); if (idSample <= 0) continue; // Skip if invalid var odSample_m = convertUnits(odSample, baseUnit, "m"); var idSample_m = convertUnits(idSample, baseUnit, "m"); var lengthSample_m = convertUnits(lengthSample, lengthBaseUnit, "m"); var crossSectionalArea_m2 = (Math.PI / 4) * (Math.pow(odSample_m, 2) – Math.pow(idSample_m, 2)); var volume_m3 = crossSectionalArea_m2 * lengthSample_m; var density = getDensityValue(); // Use the currently selected density var weight_kg = volume_m3 * density; chartData.labels.push(odSample.toFixed(0) + " " + baseUnit); chartData.datasets[0].data.push(weight_kg); chartData.datasets[1].data.push(volume_m3); } var ctx = document.getElementById('weightChart').getContext('2d'); if (chartInstance) { chartInstance.destroy(); } chartInstance = new Chart(ctx, { type: 'bar', data: chartData, options: { responsive: true, maintainAspectRatio: false, scales: { x: { title: { display: true, text: 'Outer Diameter (' + baseUnit + ')' } }, y: { title: { display: true, text: 'Value' }, beginAtZero: true } }, plugins: { tooltip: { mode: 'index', intersect: false } } } }); } function resetCalculator() { document.getElementById("pipeOuterDiameter").value = "100"; document.getElementById("pipeWallThickness").value = "5"; document.getElementById("pipeLength").value = "6"; document.getElementById("materialDensity").value = "7850"; document.getElementById("customDensityInput").style.display = "none"; document.getElementById("customDensityInput").value = ""; document.getElementById("unit").value = "metric"; document.getElementById("pipeOuterDiameterError").textContent = ""; document.getElementById("pipeWallThicknessError").textContent = ""; document.getElementById("pipeLengthError").textContent = ""; document.getElementById("materialDensityError").textContent = ""; document.getElementById("results").style.display = "none"; if (chartInstance) { chartInstance.destroy(); chartInstance = null; } // Re-initialize chart with default values or clear it var ctx = document.getElementById('weightChart').getContext('2d'); ctx.clearRect(0, 0, ctx.canvas.width, ctx.canvas.height); // Clear canvas document.getElementById("chartSection").style.display = "block"; // Ensure chart section is visible updateChart(100, 5, 6, "metric", 0, 0); // Call with sensible defaults to draw empty chart } function copyResults() { var totalWeight = document.getElementById("totalWeightOutput").textContent; var volume = document.getElementById("volumeOutput").textContent; var area = document.getElementById("areaOutput").textContent; var linearDensity = document.getElementById("linearDensityOutput").textContent; var od = document.getElementById("pipeOuterDiameter").value; var thickness = document.getElementById("pipeWallThickness").value; var length = document.getElementById("pipeLength").value; var densitySelected = document.getElementById("materialDensity"); var densityValue = densitySelected.value === "Custom" ? document.getElementById("customDensityInput").value : densitySelected.options[densitySelected.selectedIndex].text; var unit = document.getElementById("unit").value; var copyText = "— Circular Hollow Pipe Weight Calculation —" + "\n\n"; copyText += "Inputs:\n"; copyText += " – Outer Diameter: " + od + " " + (unit === "metric" ? "mm" : "in") + "\n"; copyText += " – Wall Thickness: " + thickness + " " + (unit === "metric" ? "mm" : "in") + "\n"; copyText += " – Length: " + length + " " + (unit === "metric" ? "m" : "ft") + "\n"; copyText += " – Material/Density: " + densityValue + "\n"; copyText += " – Units: " + (unit === "metric" ? "Metric" : "Imperial") + "\n\n"; copyText += "Results:\n"; copyText += " – Total Weight: " + totalWeight + "\n"; copyText += " – Volume: " + volume + "\n"; copyText += " – Cross-sectional Area: " + area + "\n"; copyText += " – Linear Density: " + linearDensity + "\n\n"; copyText += "Formula Used: Weight = Volume × Density. Volume = π/4 × (OD² – ID²) × Length."; navigator.clipboard.writeText(copyText).then(function() { // Success feedback can be added here, e.g., a temporary tooltip or message alert("Results copied to clipboard!"); }, function(err) { console.error('Failed to copy text: ', err); // Error feedback alert("Failed to copy results. Please copy manually."); }); } function toggleFaq(element) { var answer = element.nextElementSibling; if (answer.style.display === "block") { answer.style.display = "none"; } else { answer.style.display = "block"; } } // Handle custom density input visibility document.getElementById("materialDensity").addEventListener("change", function() { var customInput = document.getElementById("customDensityInput"); if (this.value === "Custom") { customInput.style.display = "block"; } else { customInput.style.display = "none"; customInput.value = ""; // Clear custom input if not needed } }); // Initial setup and load document.addEventListener('DOMContentLoaded', function() { resetCalculator(); // Set default values and clear results // Ensure chart area is visible and initially updated document.getElementById('chartSection').style.display = 'block'; // Initial chart render with placeholder data or default values updateChart(100, 5, 6, "metric", 0, 0); });

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