Titanium Pipe Weight Calculator

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Titanium Pipe Weight Calculator: Calculate Weight & Material Needs body { font-family: 'Segoe UI', Tahoma, Geneva, Verdana, sans-serif; background-color: #f8f9fa; color: #333; line-height: 1.6; margin: 0; padding: 0; } .container { max-width: 1000px; margin: 20px auto; padding: 20px; background-color: #fff; border-radius: 8px; box-shadow: 0 2px 10px rgba(0, 0, 0, 0.1); } header { background-color: #004a99; color: #fff; padding: 20px 0; text-align: center; margin-bottom: 20px; border-radius: 8px 8px 0 0; } header h1 { margin: 0; font-size: 2.2em; letter-spacing: 1px; } h2, h3 { color: #004a99; margin-top: 25px; margin-bottom: 10px; border-bottom: 2px solid #e0e0e0; padding-bottom: 5px; } .calculator-section { margin-bottom: 40px; padding: 25px; background-color: #fdfdfd; border: 1px solid #e0e0e0; border-radius: 8px; } .loan-calc-container { display: flex; flex-direction: column; gap: 15px; } .input-group { display: flex; flex-direction: column; gap: 5px; margin-bottom: 15px; } .input-group label { font-weight: bold; color: #004a99; } .input-group input[type="number"], .input-group select { padding: 10px 12px; border: 1px solid #ccc; border-radius: 4px; font-size: 1em; width: 100%; box-sizing: border-box; } .input-group input[type="number"]:focus, .input-group select:focus { border-color: #004a99; outline: none; 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: 0.9em; margin-top: 5px; display: none; /* Hidden by default */ } .error-message.visible { display: block; } .button-group { display: flex; gap: 10px; margin-top: 20px; } button { padding: 12px 20px; border: none; border-radius: 5px; cursor: pointer; font-size: 1em; font-weight: bold; transition: background-color 0.3s ease; } button.calculate-btn { background-color: #28a745; color: white; } button.calculate-btn:hover { background-color: #218838; } button.reset-btn, button.copy-btn { background-color: #6c757d; color: white; } button.reset-btn:hover, button.copy-btn:hover { background-color: #5a6268; } #results-container { margin-top: 30px; padding: 20px; background-color: #e9ecef; border-radius: 8px; border: 1px solid #d3d9e0; } .primary-result { font-size: 1.8em; font-weight: bold; color: #004a99; text-align: center; margin-bottom: 20px; padding: 15px; background-color: #d4edda; border-radius: 5px; border: 1px solid #c3e6cb; } .intermediate-results div, .formula-explanation { margin-bottom: 15px; font-size: 1em; color: #444; } .intermediate-results strong { color: #004a99; } .formula-explanation { font-style: italic; color: #555; background-color: #f1f3f5; padding: 10px; border-left: 3px solid #004a99; } table { width: 100%; border-collapse: collapse; margin-top: 20px; margin-bottom: 30px; } th, td { padding: 10px 12px; text-align: left; border: 1px solid #ddd; } th { background-color: #004a99; color: white; font-weight: bold; } tr:nth-child(even) { background-color: #f2f2f2; } caption { font-size: 1.1em; font-weight: bold; color: #004a99; margin-bottom: 10px; text-align: left; } .chart-container { text-align: center; margin-top: 30px; padding: 20px; background-color: #f1f3f5; border-radius: 8px; border: 1px solid #e0e0e0; } canvas { max-width: 100%; height: auto !important; } .article-section { margin-top: 40px; padding: 25px; background-color: #fff; border-radius: 8px; box-shadow: 0 2px 10px rgba(0, 0, 0, 0.1); } .article-section h2, .article-section h3 { color: #004a99; margin-top: 25px; margin-bottom: 15px; border-bottom: 2px solid #e0e0e0; padding-bottom: 5px; } .article-section p { margin-bottom: 15px; } .article-section ul, .article-section ol { margin-left: 20px; margin-bottom: 15px; } .article-section li { margin-bottom: 8px; } .faq-item { margin-bottom: 15px; } .faq-item strong { display: block; color: #004a99; margin-bottom: 5px; } .internal-links ul { list-style: none; padding: 0; } .internal-links li { margin-bottom: 10px; } .internal-links a { color: #004a99; text-decoration: none; font-weight: bold; } .internal-links a:hover { text-decoration: underline; } .internal-links span { font-size: 0.9em; color: #555; display: block; margin-top: 3px; }

Titanium Pipe Weight Calculator

Titanium Pipe Weight Calculator

The outside diameter of the pipe in millimeters.
The thickness of the pipe wall in millimeters.
The total length of the pipe section in meters.

Calculation Results

— kg
Inner Diameter: — mm
Cross-Sectional Area: — mm²
Volume: — L
The weight is calculated by finding the pipe's volume and multiplying it by the density of titanium. Weight (kg) = Volume (L) × Density (kg/L)

Weight vs. Length for Varying Wall Thickness

Titanium Properties
Property Value Unit
Density of Titanium (Alpha/Beta alloys) 4.506 g/cm³ (or kg/L)

Titanium Pipe Weight Calculator: An Essential Tool for Engineers and Fabricators

Understanding the precise weight of titanium pipes is crucial for a wide range of applications, from aerospace and marine engineering to medical implants and chemical processing. The high strength-to-weight ratio and excellent corrosion resistance of titanium make it a premium material, but its cost necessitates careful material estimation. The titanium pipe weight calculator serves as an indispensable tool for engineers, procurement specialists, and project managers to accurately determine the mass of titanium piping needed for any given project, ensuring efficient material utilization and cost control.

What is a Titanium Pipe Weight Calculator?

A titanium pipe weight calculator is a specialized online tool designed to compute the weight of a titanium pipe section based on its physical dimensions and the material's density. It simplifies complex calculations, allowing users to quickly input key parameters like outer diameter, wall thickness, and length, and receive an immediate, accurate weight estimation. This tool is fundamental for project planning, budgeting, shipping logistics, and structural analysis where the precise mass of titanium components is a significant factor.

Who should use it:

  • Mechanical Engineers
  • Aerospace Engineers
  • Marine Engineers
  • Chemical Process Engineers
  • Project Managers
  • Procurement and Supply Chain Professionals
  • Fabricators and Welders
  • Researchers and Developers

Common Misconceptions:

  • "All titanium is the same weight": While titanium has a standard density, variations can exist between different titanium alloys, though these are generally minor for weight calculations. The primary calculator assumes a common density.
  • "Weight calculations are simple multiplication": Calculating the weight of a hollow cylinder involves determining its volume, which requires accounting for both outer and inner dimensions (or outer diameter and wall thickness), not just linear measurements.
  • "Accuracy isn't critical for small projects": Even for smaller components, precise weight data is vital for performance, balance, and cost-effectiveness, especially when dealing with expensive materials like titanium.

Titanium Pipe Weight Formula and Mathematical Explanation

The calculation of titanium pipe weight relies on fundamental geometric and physical principles. The core idea is to determine the volume of the material used in the pipe and then multiply that volume by the density of titanium.

The formula can be broken down into these steps:

  1. Calculate Inner Diameter: The inner diameter is found by subtracting twice the wall thickness from the outer diameter.
  2. Calculate Cross-Sectional Area: The area of the pipe's wall (the metal part) is the difference between the area of the outer circle and the area of the inner circle.
  3. Calculate Volume: The volume of the pipe material is the cross-sectional area multiplied by the length of the pipe.
  4. Calculate Weight: The final weight is obtained by multiplying the volume by the density of titanium.

Variables and Formula Breakdown:

The primary formula used in the titanium pipe weight calculator is:

Weight (kg) = π × (Outer Diameter² – Inner Diameter²) / 4 × Length (in meters) × Density (kg/m³)

Alternatively, working with millimeters and converting to liters (which is equivalent to cubic decimeters, dm³):

Inner Diameter (mm) = Outer Diameter (mm) – 2 × Wall Thickness (mm)

Cross-Sectional Area (mm²) = π × [(Outer Diameter / 2)² – (Inner Diameter / 2)²]

Volume (mm³) = Cross-Sectional Area (mm²) × Pipe Length (mm)

To convert volume to Liters (dm³), divide by 1,000,000:

Volume (L) = Volume (mm³) / 1,000,000

Finally, convert the density from g/cm³ to kg/L (which are numerically equivalent since 1 cm³ = 1 mL and 1 L = 1000 mL, and 1 kg = 1000 g):

Weight (kg) = Volume (L) × Density (kg/L)

Variables Used in Titanium Pipe Weight Calculation
Variable Meaning Unit Typical Range
Outer Diameter (OD) The measurement across the widest part of the pipe, including the wall. mm 10 – 1000+
Wall Thickness (WT) The thickness of the material forming the pipe wall. mm 1 – 50+
Pipe Length (L) The total linear measurement of the pipe section. m 0.1 – 12+
Inner Diameter (ID) Calculated diameter inside the pipe wall. mm OD – 2*WT
Cross-Sectional Area The area of the metal forming the pipe's wall. mm² Calculated
Volume The total space occupied by the pipe material. L Calculated
Density of Titanium Mass per unit volume of titanium. kg/L (or g/cm³) ~4.506 (for common alloys)
Weight The final calculated mass of the titanium pipe. kg Calculated

Practical Examples (Real-World Use Cases)

Here are a couple of scenarios demonstrating how the titanium pipe weight calculator is used:

Example 1: Aerospace Structural Tubing

An aerospace engineer needs to specify titanium tubing for a structural component in an aircraft. The requirements are:

  • Outer Diameter: 50 mm
  • Wall Thickness: 3 mm
  • Pipe Length: 2 meters

Using the Calculator:

  • Input: OD = 50 mm, WT = 3 mm, Length = 2 m
  • Inner Diameter = 50 – 2*3 = 44 mm
  • Cross-Sectional Area = π * (25² – 22²) ≈ 587.48 mm²
  • Volume = 587.48 mm² * 2000 mm = 1,174,960 mm³ ≈ 1.175 L
  • Weight = 1.175 L * 4.506 kg/L ≈ 5.30 kg

Result Interpretation: The engineer knows that each 2-meter section of this specific titanium pipe will weigh approximately 5.30 kg. This is vital for calculating the total structural weight, determining lifting requirements during assembly, and ensuring the component meets weight limitations for the aircraft. This estimation helps in ordering the correct amount of material, minimizing waste of expensive titanium.

Example 2: Marine Heat Exchanger Piping

A marine engineer is designing a heat exchanger system for a ship and needs to estimate the weight of the titanium piping required. The specifications are:

  • Outer Diameter: 150 mm
  • Wall Thickness: 7 mm
  • Total Pipe Length: 10 meters

Using the Calculator:

  • Input: OD = 150 mm, WT = 7 mm, Length = 10 m
  • Inner Diameter = 150 – 2*7 = 136 mm
  • Cross-Sectional Area = π * (75² – 68²) ≈ 3,393 mm²
  • Volume = 3,393 mm² * 10000 mm = 33,930,000 mm³ ≈ 33.93 L
  • Weight = 33.93 L * 4.506 kg/L ≈ 152.9 kg

Result Interpretation: The total weight for 10 meters of this titanium pipe is approximately 152.9 kg. This figure is important for the overall weight budget of the ship's systems, determining how the piping will be supported, and estimating transportation and installation costs. Accurate weight data prevents overloading and ensures the integrity of the marine structure. This calculation highlights the significant material cost when using titanium for larger industrial applications.

How to Use This Titanium Pipe Weight Calculator

Using the titanium pipe weight calculator is straightforward. Follow these simple steps:

  1. Input Outer Diameter (mm): Enter the external diameter of the titanium pipe into the designated field.
  2. Input Wall Thickness (mm): Provide the thickness of the pipe wall in millimeters.
  3. Input Pipe Length (m): Enter the total length of the pipe section you need to calculate the weight for, in meters.
  4. Calculate: Click the "Calculate Weight" button.

How to Read Results:

  • Primary Result (Weight in kg): This is the highlighted, main output showing the estimated weight of the titanium pipe section in kilograms.
  • Intermediate Values: You'll also see the calculated Inner Diameter, Cross-Sectional Area, and Volume, which provide a deeper understanding of the pipe's geometry.
  • Formula Explanation: A brief description of the underlying calculation method is provided for transparency.
  • Titanium Properties Table: This table confirms the density value used for titanium.
  • Chart: The dynamic chart visualizes how pipe weight changes with length for different wall thicknesses, allowing for quick comparisons.

Decision-Making Guidance:

  • Procurement: Use the calculated weight to order the precise amount of titanium needed, optimizing inventory and minimizing waste.
  • Logistics: Estimate shipping costs and handling requirements based on the total weight.
  • Engineering Design: Verify that the material weight fits within structural and performance specifications.
  • Budgeting: The weight is a direct input for calculating the material cost of the project.

Use the "Reset" button to clear all fields and start over. The "Copy Results" button allows you to easily transfer the calculated weight, intermediate values, and key assumptions to other documents or planning tools.

Key Factors That Affect Titanium Pipe Weight Results

While the calculator provides a precise estimation based on inputs, several real-world factors can subtly influence the actual weight of titanium pipes. Understanding these can lead to even more accurate project planning:

  1. Titanium Alloy Variation: Although the calculator uses a standard density for titanium (approximately 4.506 g/cm³), different alloys (e.g., Grade 2 vs. Grade 5) have slightly varying densities. For highly critical applications, specifying the exact alloy and its precise density is recommended.
  2. Manufacturing Tolerances: Pipe dimensions (diameter and wall thickness) can have manufacturing tolerances. Minor deviations from the nominal dimensions, within industry standards, will result in slight variations in actual weight compared to the calculated value.
  3. Surface Finish and Coatings: While typically negligible for weight calculations, significant surface treatments or applied coatings could add a small amount of mass.
  4. Internal Scavenging/Corrosion: Over long operational periods in corrosive environments, internal or external material loss due to corrosion can reduce the pipe's weight. This calculator provides the *initial* weight.
  5. Temperature Effects: Titanium, like most metals, expands and contracts with temperature. While this primarily affects dimensions, extreme temperature fluctuations could theoretically have a minute impact on density, though this is usually not a concern for standard weight calculations.
  6. Inclusions and Defects: Microscopic inclusions or internal voids within the titanium material, though rare in high-quality products, could lead to slight deviations from the calculated density and thus weight.
  7. Pipe End Preparation: If pipes are cut or prepared (e.g., beveled ends), the removed material will slightly reduce the overall weight from calculations based on full standard lengths.

Frequently Asked Questions (FAQ)

Q1: What is the standard density of titanium used in this calculator?

A: This calculator uses a standard density of 4.506 g/cm³ (or kg/L), which is representative of common commercially pure titanium grades (like Grade 1 or Grade 2) and many titanium alloys.

Q2: Does the calculator account for different titanium alloys?

A: No, this calculator uses a single, representative density for simplicity. While alloy densities vary slightly, the difference is usually minor for most applications. For highly specialized projects, you might need to adjust the density input if a specific alloy's density is known and significantly different.

Q3: Can I input dimensions in inches or other units?

A: Currently, the calculator requires inputs in millimeters (mm) for diameter and thickness, and meters (m) for length. Ensure your measurements are converted to these units before inputting them for accurate results.

Q4: What is the maximum length of pipe the calculator can handle?

A: The calculator can handle standard pipe lengths, but ensure your input is within reasonable engineering limits. For extremely long or custom lengths, simply input the total length in meters.

Q5: How accurate is the weight calculation?

A: The calculation is geometrically accurate based on the inputs provided. The primary source of potential inaccuracy comes from variations in the actual pipe's dimensions and alloy density compared to the standard values assumed.

Q6: What if my pipe has a non-circular shape?

A: This calculator is specifically designed for pipes with a circular cross-section. It will not provide accurate results for square, rectangular, or irregularly shaped titanium profiles.

Q7: How does this weight calculation help in project planning?

A: Accurate weight estimation is critical for structural integrity analysis, determining load-bearing requirements, budgeting for material costs (titanium is expensive), planning shipping and handling logistics, and ensuring overall project feasibility within weight constraints.

Q8: Can I use this calculator for titanium bars or solid rods?

A: No, this calculator is exclusively for hollow pipes. For solid bars or rods, you would use a simpler volume calculation (Area × Length) based on the cross-sectional area of the solid shape.

Related Tools and Internal Resources

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var titaniumDensityKgPerL = 4.506; // Density of Titanium in g/cm³ which is equivalent to kg/L function getElement(id) { return document.getElementById(id); } function setElementText(id, text) { getElement(id).innerHTML = text; } function setElementValue(id, value) { var element = getElement(id); if (element) { element.value = value; } } function getInputValue(id) { var input = getElement(id); if (!input) return NaN; var value = parseFloat(input.value); return isNaN(value) ? NaN : value; } function validateInput(id, value, min, max, errorId, label) { var errorElement = getElement(errorId); if (value === null || isNaN(value)) { errorElement.innerText = label + " is required."; errorElement.classList.add('visible'); return false; } if (value max) { errorElement.innerText = label + " is too high. Please enter a realistic value."; errorElement.classList.add('visible'); return false; } errorElement.innerText = ""; errorElement.classList.remove('visible'); return true; } var weightChart = null; var chartContext = null; function initializeChart() { if (!chartContext) { chartContext = getElement("weightLengthChart").getContext("2d"); } if (weightChart) { weightChart.destroy(); } } function updateChart(inputLength) { initializeChart(); var lengths = []; var weights = []; var intermediateData = []; var od = getInputValue('outerDiameter'); var wt = getInputValue('wallThickness'); if (isNaN(od) || isNaN(wt) || od <= 0 || wt = od / 2) { setElementText("weightLengthChart", "Chart data unavailable due to invalid inputs."); return; } // Determine a realistic range for length for the chart var maxChartLength = inputLength > 0 ? inputLength * 2 : 12; // Use input length or a default max if (maxChartLength < 1) maxChartLength = 1; var minChartLength = 0.1; var step = maxChartLength / 10; if (step < 0.1) step = 0.1; for (var l = minChartLength; l <= maxChartLength; l += step) { lengths.push(l); var currentWeight = calculatePipeWeight(od, wt, l, titaniumDensityKgPerL); weights.push(currentWeight); var innerD = od – 2 * wt; var crossArea = Math.PI * (Math.pow(od / 2, 2) – Math.pow(innerD / 2, 2)); var volume = (crossArea / 1000000) * (l * 1000); // Convert area mm^2 to m^2, then volume m^3 to L intermediateData.push({innerD: innerD.toFixed(2), crossArea: crossArea.toFixed(2), volume: volume.toFixed(3)}); } var chartLabels = lengths.map(function(l) { return l.toFixed(1) + " m"; }); var chartWeights = weights.map(function(w) { return w.toFixed(2); }); weightChart = new Chart(chartContext, { type: 'line', data: { labels: chartLabels, datasets: [{ label: 'Estimated Weight (kg)', data: chartWeights, borderColor: '#004a99', fill: false, tension: 0.1 }] }, options: { responsive: true, maintainAspectRatio: false, scales: { y: { beginAtZero: true, title: { display: true, text: 'Weight (kg)' } }, x: { title: { display: true, text: 'Pipe Length (m)' } } }, plugins: { tooltip: { callbacks: { afterLabel: function(context) { var index = context.dataIndex; var data = intermediateData[index]; return [ " Inner Dia: " + data.innerD + " mm", " Area: " + data.crossArea + " mm²", " Volume: " + data.volume + " L" ]; } } }, legend: { display: true, position: 'top', } } } }); // Manually create a legend if the chart doesn't render one nicely for this setup var legendHtml = '
'; legendHtml += '
'; legendHtml += ''; legendHtml += 'Estimated Weight (kg)'; legendHtml += '
'; legendHtml += '
'; getElement("chartLegend").innerHTML = legendHtml; } function calculatePipeWeight(od, wt, lengthM, density) { if (isNaN(od) || isNaN(wt) || isNaN(lengthM) || isNaN(density) || od <= 0 || wt <= 0 || lengthM <= 0 || density = od / 2) { return NaN; // Wall thickness cannot be half or more of the outer diameter } var innerDiameter = od – 2 * wt; var outerRadius = od / 2; var innerRadius = innerDiameter / 2; // Area of the annulus (pipe wall) in mm² var crossSectionalAreaMm2 = Math.PI * (Math.pow(outerRadius, 2) – Math.pow(innerRadius, 2)); // Convert length from meters to millimeters var lengthMm = lengthM * 1000; // Volume in mm³ var volumeMm3 = crossSectionalAreaMm2 * lengthMm; // Convert volume from mm³ to Liters (1 L = 1000 cm³ = 1,000,000 mm³) var volumeL = volumeMm3 / 1000000; // Calculate weight in kg (density is in kg/L) var weightKg = volumeL * density; return weightKg; } function calculateWeight() { var od = getInputValue('outerDiameter'); var wt = getInputValue('wallThickness'); var length = getInputValue('pipeLength'); var isValid = true; isValid = validateInput('outerDiameter', od, 0, 5000, 'outerDiameterError', 'Outer Diameter') && isValid; isValid = validateInput('wallThickness', wt, 0, 5000, 'wallThicknessError', 'Wall Thickness') && isValid; isValid = validateInput('pipeLength', length, 0, 1000, 'pipeLengthError', 'Pipe Length') && isValid; if (!isValid) { setElementText('primaryResult', '– kg'); setElementText('innerDiameterResult', 'Inner Diameter: — mm'); setElementText('crossSectionalAreaResult', 'Cross-Sectional Area: — mm²'); setElementText('volumeResult', 'Volume: — L'); initializeChart(); // Clear chart on invalid input return; } if (wt >= od / 2) { getElement('wallThicknessError').innerText = "Wall thickness cannot be equal to or greater than half the outer diameter."; getElement('wallThicknessError').classList.add('visible'); setElementText('primaryResult', '– kg'); setElementText('innerDiameterResult', 'Inner Diameter: — mm'); setElementText('crossSectionalAreaResult', 'Cross-Sectional Area: — mm²'); setElementText('volumeResult', 'Volume: — L'); initializeChart(); // Clear chart on invalid input return; } else { getElement('wallThicknessError').innerText = ""; getElement('wallThicknessError').classList.remove('visible'); } var innerDiameter = od – 2 * wt; var outerRadius = od / 2; var innerRadius = innerDiameter / 2; var crossSectionalAreaMm2 = Math.PI * (Math.pow(outerRadius, 2) – Math.pow(innerRadius, 2)); var lengthMm = length * 1000; var volumeMm3 = crossSectionalAreaMm2 * lengthMm; var volumeL = volumeMm3 / 1000000; var weightKg = volumeL * titaniumDensityKgPerL; setElementText('primaryResult', weightKg.toFixed(2) + ' kg'); setElementText('innerDiameterResult', 'Inner Diameter: ' + innerDiameter.toFixed(2) + ' mm'); setElementText('crossSectionalAreaResult', 'Cross-Sectional Area: ' + crossSectionalAreaMm2.toFixed(2) + ' mm²'); setElementText('volumeResult', 'Volume: ' + volumeL.toFixed(3) + ' L'); updateChart(length); // Pass the current length to the chart function } function resetCalculator() { setElementValue('outerDiameter', 100); setElementValue('wallThickness', 5); setElementValue('pipeLength', 6); getElement('outerDiameterError').innerText = ""; getElement('outerDiameterError').classList.remove('visible'); getElement('wallThicknessError').innerText = ""; getElement('wallThicknessError').classList.remove('visible'); getElement('pipeLengthError').innerText = ""; getElement('pipeLengthError').classList.remove('visible'); calculateWeight(); // Recalculate with default values } function copyResults() { var primaryResult = getElement('primaryResult').innerText; var innerDiameterResult = getElement('innerDiameterResult').innerText; var crossSectionalAreaResult = getElement('crossSectionalAreaResult').innerText; var volumeResult = getElement('volumeResult').innerText; var densityInfo = "Titanium Density: 4.506 kg/L"; var resultString = "Titanium Pipe Weight Calculation Results:\n\n"; resultString += primaryResult + "\n"; resultString += innerDiameterResult + "\n"; resultString += crossSectionalAreaResult + "\n"; resultString += volumeResult + "\n"; resultString += densityInfo + "\n\n"; resultString += "Inputs were: \n"; resultString += "Outer Diameter: " + getElement('outerDiameter').value + " mm\n"; resultString += "Wall Thickness: " + getElement('wallThickness').value + " mm\n"; resultString += "Pipe Length: " + getElement('pipeLength').value + " m\n"; // Use a temporary textarea to copy text to clipboard var textArea = document.createElement("textarea"); textArea.value = resultString; textArea.style.position = "fixed"; textArea.style.left = "-9999px"; document.body.appendChild(textArea); textArea.focus(); textArea.select(); try { var successful = document.execCommand('copy'); var msg = successful ? 'Results copied!' : 'Failed to copy results.'; console.log(msg); // Optionally show a temporary message to the user var oldHTML = getElement('results-container').innerHTML; getElement('results-container').innerHTML += '
' + msg + '
'; setTimeout(function(){ getElement('results-container').innerHTML = oldHTML; }, 2000); } catch (err) { console.log('Fallback: Oops, unable to copy: ', err); // Optionally show a temporary message to the user var oldHTML = getElement('results-container').innerHTML; getElement('results-container').innerHTML += '
Failed to copy results.
'; setTimeout(function(){ getElement('results-container').innerHTML = oldHTML; }, 2000); } document.body.removeChild(textArea); } // Set current year for footer document.getElementById("currentYear").textContent = new Date().getFullYear(); // Initialize the chart on page load document.addEventListener('DOMContentLoaded', function() { // Set initial default values setElementValue('outerDiameter', 100); setElementValue('wallThickness', 5); setElementValue('pipeLength', 6); calculateWeight(); // Perform initial calculation with defaults updateChart(getInputValue('pipeLength')); // Update chart with defaults });

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