Steel Weight Chart Calculator

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Steel Weight Chart Calculator: Calculate Steel Rod & Bar Weight :root { –primary-color: #004a99; –success-color: #28a745; –background-color: #f8f9fa; –text-color: #333; –border-color: #ddd; –card-background: #ffffff; –error-color: #dc3545; } body { font-family: 'Segoe UI', Tahoma, Geneva, Verdana, sans-serif; background-color: var(–background-color); color: var(–text-color); margin: 0; padding: 0; display: flex; justify-content: center; padding-top: 20px; padding-bottom: 40px; } .main-container { width: 100%; max-width: 1050px; margin: 0 auto; padding: 20px; background-color: var(–card-background); border-radius: 8px; box-shadow: 0 4px 12px rgba(0, 0, 0, 0.1); } header { text-align: center; padding-bottom: 30px; border-bottom: 1px solid var(–border-color); margin-bottom: 30px; } header h1 { color: var(–primary-color); margin-bottom: 10px; } header p { font-size: 1.1em; color: #555; } .calculator-section { margin-bottom: 40px; padding: 30px; background-color: #fff; border-radius: 8px; box-shadow: inset 0 2px 6px rgba(0,0,0,0.05); 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Steel Weight Chart Calculator

Accurately calculate the weight of steel materials for your projects.

Steel Weight Calculator

Round Bar Square Bar Flat Bar Angle Bar (Equal Legs) H-Beam (Standard) I-Beam (Standard) Round Tube Square Tube Select the shape of the steel.
Enter the main dimension (e.g., diameter for round, width for square/flat).
Enter the second dimension (e.g., thickness for flat/angle).
Enter the length of the steel piece.
Enter the total length in meters.

Calculation Results

0.00 kg
Volume 0.00 cm³
Cross-Sectional Area 0.00 cm²
Steel Density 7.85 g/cm³
Formula: Weight = Volume × Density. Volume is calculated based on steel shape and dimensions.

Weight vs. Length Comparison

Steel Weight Chart Reference (Common Sizes)

Steel Type Dimension 1 (mm) Dimension 2 (mm) Length (m) Weight (kg)

What is a Steel Weight Chart Calculator?

A steel weight chart calculator is a specialized online tool designed to help engineers, fabricators, construction professionals, and DIY enthusiasts quickly and accurately determine the weight of various steel components. Steel weight charts are fundamental in many industries for material estimation, cost calculation, structural analysis, and logistics planning. Instead of manually consulting complex tables or performing tedious calculations, this calculator provides instant results based on user-defined parameters.

Who Should Use It?

The steel weight chart calculator is invaluable for a wide range of professionals and hobbyists:

  • Structural Engineers: For calculating dead loads, optimizing material usage, and ensuring structural integrity.
  • Fabricators and Welders: To estimate material costs, plan workshop layout, and manage inventory.
  • Construction Project Managers: For budgeting, procurement, and coordinating material delivery.
  • Architects: To understand the physical properties and weight implications of steel structures.
  • Machinists: For calculating stock needed and machining allowances.
  • DIY Enthusiasts: For smaller projects where precise material quantities are important.

Common Misconceptions

One common misconception is that all steel has the same density. While the industry standard is around 7.85 g/cm³ (or 7850 kg/m³), slight variations can occur depending on the specific alloy and manufacturing process. Another misconception is that weight calculation is always straightforward; the shape of the steel (e.g., I-beam vs. round bar) significantly impacts how dimensions translate to volume and thus weight.

Steel Weight Chart Calculator Formula and Mathematical Explanation

The core principle behind the steel weight chart calculator is a straightforward physics equation: the weight of an object is its volume multiplied by its density.

The Formula

Weight = Volume × Density

The complexity lies in accurately calculating the 'Volume' based on the specific shape and dimensions of the steel being measured.

Variable Explanations

  • Volume (V): The amount of three-dimensional space occupied by the steel. This is the most variable part of the calculation, depending on the steel's shape. Units are typically cubic centimeters (cm³) or cubic meters (m³).
  • Density (ρ): The mass of steel per unit volume. For most common steel alloys, this is a constant value.

Calculating Volume for Different Steel Shapes

The calculator dynamically applies the correct geometric formula for volume based on the selected 'Steel Type':

  • Round Bar: Cylinder. Volume = π × (Diameter/2)² × Length
  • Square Bar: Cube/Rectangular Prism. Volume = Width × Width × Length
  • Flat Bar: Rectangular Prism. Volume = Width × Thickness × Length
  • Angle Bar (Equal Legs): Two rectangular prisms forming an 'L' shape. Volume = [ (Leg Width × Leg Width) – (Leg Width – Thickness)² ] × Length. Or approximated as: (2 × Leg Width × Thickness – Thickness²) × Length
  • H-Beam / I-Beam: Complex shapes requiring summing volumes of rectangular sections (flanges and web). A simplified calculation often uses standard formulas or approximations based on overall dimensions and web/flange thickness, or references shape-specific data.
  • Round Tube: Hollow Cylinder. Volume = π × (Outer Diameter/2)² × Length – π × (Inner Diameter/2)² × Length = π × Length × ((Outer Diameter² – Inner Diameter²) / 4)
  • Square Tube: Hollow Square Prism. Volume = (Outer Width² × Length) – (Inner Width² × Length) = Length × (Outer Width² – Inner Width²)

The calculator converts all input dimensions to a consistent unit (e.g., millimeters to centimeters) before calculation to ensure accuracy.

Variables Table

Variable Meaning Unit Typical Range / Value
Diameter / Width Main dimension of the steel profile mm 0.1 – 1000+
Height / Thickness Secondary dimension (if applicable) mm 0.1 – 500+
Length Length of the steel piece m 0.1 – 100+
Volume Calculated space occupied by the steel cm³ Varies greatly
Density (ρ) Mass per unit volume of steel g/cm³ ~7.85 (constant for common steel)
Weight Final calculated mass kg Varies greatly

Practical Examples (Real-World Use Cases)

Example 1: Calculating Weight for Structural Steel Beams

A construction company is ordering steel beams for a new building. They need to know the total weight of 10 pieces of standard I-beams.

  • Steel Type: I-Beam (Standard)
  • Input Dimension 1 (Depth): 300 mm
  • Input Dimension 2 (Flange Width): 150 mm
  • Input Dimension 3 (Flange Thickness): 10 mm
  • Input Dimension 4 (Web Thickness): 7 mm
  • Length: 12 meters per beam
  • Number of Pieces: 10

Calculation Steps (Simplified for Illustration):

  1. The calculator determines the cross-sectional area of the I-beam. For a standard I-beam, this involves calculating the area of the two flanges and the web.
  2. Area = (2 × Flange Width × Flange Thickness) + (Web Thickness × (Depth – 2 × Flange Thickness))
  3. Area = (2 × 150 mm × 10 mm) + (7 mm × (300 mm – 2 × 10 mm))
  4. Area = 3000 mm² + (7 mm × 280 mm) = 3000 mm² + 1960 mm² = 4960 mm²
  5. Convert area to cm²: 4960 mm² / 100 = 49.60 cm²
  6. Convert length to cm: 12 m × 1000 mm/m = 12000 mm = 1200 cm
  7. Calculate Volume: Volume = Area × Length = 49.60 cm² × 1200 cm = 59520 cm³
  8. Calculate Weight: Weight = Volume × Density = 59520 cm³ × 7.85 g/cm³ = 467232 g
  9. Convert weight to kg: 467232 g / 1000 = 467.23 kg per beam.
  10. Total Weight for 10 beams: 467.23 kg/beam × 10 beams = 4672.3 kg

Result: Each 12-meter I-beam weighs approximately 467.23 kg. The total order of 10 beams is 4672.3 kg. This information is crucial for transport planning and structural load calculations.

Example 2: Estimating Weight for Round Steel Bars

A workshop needs to determine the weight of a batch of 50 round steel bars for manufacturing purposes.

  • Steel Type: Round Bar
  • Diameter: 25 mm
  • Length: 3 meters per bar
  • Number of Pieces: 50

Calculation Steps:

  1. Calculate the radius: Radius = Diameter / 2 = 25 mm / 2 = 12.5 mm
  2. Calculate the cross-sectional area: Area = π × Radius² = π × (12.5 mm)² ≈ 3.14159 × 156.25 mm² ≈ 490.87 mm²
  3. Convert area to cm²: 490.87 mm² / 100 = 4.91 cm²
  4. Convert length to cm: 3 m × 1000 mm/m = 3000 mm = 300 cm
  5. Calculate Volume: Volume = Area × Length = 4.91 cm² × 300 cm = 1473 cm³
  6. Calculate Weight: Weight = Volume × Density = 1473 cm³ × 7.85 g/cm³ = 11573.05 g
  7. Convert weight to kg: 11573.05 g / 1000 = 11.57 kg per bar.
  8. Total Weight for 50 bars: 11.57 kg/bar × 50 bars = 578.5 kg

Result: Each 3-meter round steel bar (25mm diameter) weighs approximately 11.57 kg. The total weight for 50 bars is 578.5 kg. This helps in managing inventory and ensuring sufficient raw material.

How to Use This Steel Weight Chart Calculator

Using the steel weight chart calculator is simple and intuitive. Follow these steps to get accurate weight estimations:

Step-by-Step Instructions

  1. Select Steel Type: Choose the shape of your steel component from the 'Steel Type' dropdown menu (e.g., Round Bar, Square Bar, I-Beam).
  2. Enter Dimensions: Input the relevant dimensions for the selected steel type.
    • For simple shapes like Round Bar, you'll enter Diameter and Length.
    • For Flat Bar or Angle Bar, you might need to enter Width, Thickness, and Length.
    • For I-Beams or complex tubes, additional dimensions like Flange Width, Flange Thickness, Web Thickness, or Outer/Inner Diameters might be required. The calculator will dynamically show the necessary input fields.
    All dimensions should be entered in millimeters (mm) unless otherwise specified (Length is in meters).
  3. View Results: As you enter the values, the calculator will instantly update the 'Volume', 'Cross-Sectional Area', and the final 'Weight' in kilograms (kg). The standard steel density used (7.85 g/cm³) is also displayed.
  4. Analyze the Chart and Table: Explore the dynamic chart for visual comparisons of weight across different lengths and the reference table for common sizes.
  5. Copy Results: Use the 'Copy Results' button to easily transfer the calculated weight, volume, area, and key assumptions to your reports or documents.
  6. Reset: If you need to start over or try different values, click the 'Reset' button to return the calculator to its default settings.

How to Read Results

  • Main Result (Weight): This is the primary output, showing the total weight of the steel piece in kilograms (kg).
  • Volume: Displays the calculated volume in cubic centimeters (cm³). This is an intermediate step in determining weight.
  • Cross-Sectional Area: Shows the area of the steel's profile in square centimeters (cm²).
  • Steel Density: Confirms the standard density value used for the calculation (7.85 g/cm³).

Decision-Making Guidance

The accurate weight information provided by the calculator aids in several critical decisions:

  • Procurement: Ensure you order the correct quantity of steel.
  • Budgeting: Estimate material costs more precisely.
  • Logistics: Plan for transportation weight limits and handling requirements.
  • Structural Design: Accurately input dead loads into structural analysis software.

Understanding the weight helps prevent costly over-ordering or under-stocking of materials.

Key Factors That Affect Steel Weight Results

While the calculator uses precise formulas, several real-world factors can influence the actual weight of steel and should be considered:

  1. Steel Alloy Composition: Although 7.85 g/cm³ is standard, different steel alloys (e.g., stainless steel, high-carbon steel) can have slightly different densities. Always verify if working with non-standard alloys.
  2. Manufacturing Tolerances: Steel is manufactured within specified tolerance ranges for dimensions. Slight variations in diameter, thickness, or width can lead to minor deviations in the final weight.
  3. Surface Finish and Coatings: Processes like galvanizing or painting add a thin layer of material, increasing the overall weight slightly. Mill scale on hot-rolled steel can also add minor weight.
  4. Length Variations: Just as with cross-sectional dimensions, the length of steel stock can also have manufacturing tolerances, affecting the total weight.
  5. Temperature Expansion: Steel expands when heated and contracts when cooled. While usually negligible for weight calculations at ambient temperatures, significant temperature fluctuations could theoretically alter dimensions slightly.
  6. Internal Structure/Voids: While steel is generally solid, extremely specialized or defective materials might have internal variations. For standard structural steel, this is not a concern.
  7. Unit Conversions: Inaccurate conversion between units (e.g., mm to meters, grams to kilograms) is a common source of error if calculations are done manually or if input data is inconsistent. The calculator manages these conversions internally.

Frequently Asked Questions (FAQ)

What is the standard density of steel used in this calculator?
This calculator uses the standard industry density for steel, which is approximately 7.85 grams per cubic centimeter (g/cm³) or 7850 kilograms per cubic meter (kg/m³).
What units should I use for the dimensions?
Please enter the cross-sectional dimensions (like diameter, width, height, thickness) in millimeters (mm). The length should be entered in meters (m). The output weight will be in kilograms (kg).
Does the calculator account for different steel grades (e.g., Mild Steel, Stainless Steel)?
The calculator uses a standard density applicable to most common carbon steels. While different steel grades can have slightly varying densities, the difference is often minor for general estimation purposes. For highly precise calculations involving specific alloys, you may need to consult material-specific density data.
How accurate is the weight calculation for I-beams and H-beams?
The accuracy for I-beams and H-beams depends on the specific profile dimensions used. The calculator employs standard geometric formulas. For non-standard or custom profiles, it's best to cross-reference with manufacturer data or use more detailed structural software.
Can I calculate the weight of a hollow steel section?
Yes, the calculator includes options for 'Round Tube' and 'Square Tube'. You will need to input both the outer and inner dimensions (or wall thickness) along with the length.
What if my steel shape is not listed?
The calculator covers the most common steel shapes. For less common profiles (e.g., hexagonal bars, special structural shapes), you would need to calculate the cross-sectional area manually using appropriate geometric formulas and then use the principle: Weight = Area × Length × Density.
How does the calculator handle length units?
The 'Length' input field specifically requires the length in meters (m). This simplifies input for common construction lengths (e.g., 6m, 12m). The internal calculations convert this to centimeters for volume computation.
Can this calculator be used for cost estimation?
Yes, by knowing the weight and the cost per unit weight (e.g., cost per kg), you can easily estimate the material cost for your steel requirements.

Related Tools and Internal Resources

var steelTypeSelect = document.getElementById('steelType'); var dimension1Input = document.getElementById('dimension1'); var dimension2Input = document.getElementById('dimension2'); var dimension3Input = document.getElementById('dimension3'); var lengthInput = document.getElementById('length'); var resultsSection = document.getElementById('results-section'); var mainResultSpan = document.getElementById('main-result'); var volumeResultSpan = document.getElementById('volume-result'); var areaResultSpan = document.getElementById('area-result'); var densityResultSpan = document.getElementById('density-result'); var weightChartCanvas = document.getElementById('weightChart'); var chartInstance = null; var steelDensity = 7.85; // g/cm³ function validateInput(inputElement, errorElementId) { var errorElement = document.getElementById(errorElementId); var value = parseFloat(inputElement.value); var isValid = true; if (isNaN(value)) { errorElement.textContent = "Please enter a valid number."; errorElement.classList.add('visible'); isValid = false; } else if (value 0) { var weightGrams = volumeCm3 * steelDensity; var weightKg = weightGrams / 1000; mainResultSpan.textContent = weightKg.toFixed(2) + ' kg'; volumeResultSpan.textContent = volumeCm3.toFixed(2) + ' cm³'; areaResultSpan.textContent = areaCm2.toFixed(2) + ' cm²'; densityResultSpan.textContent = steelDensity.toFixed(2) + ' g/cm³'; resultsSection.style.display = 'block'; } else { resultsSection.style.display = 'none'; } populateTable(); // Update table on calculation updateChart(); // Update chart on calculation } function resetCalculator() { document.getElementById('steelType').value = 'round_bar'; document.getElementById('dimension1′).value = '20'; document.getElementById('dimension2′).value = '10'; document.getElementById('dimension3').value = "; // Clear beams dimension document.getElementById('length').value = '6'; // Reset error messages document.getElementById('dimension1-error').textContent = ""; document.getElementById('dimension1-error').classList.remove('visible'); document.getElementById('dimension2-error').textContent = ""; document.getElementById('dimension2-error').classList.remove('visible'); document.getElementById('dimension3-error').textContent = ""; document.getElementById('dimension3-error').classList.remove('visible'); document.getElementById('length-error').textContent = ""; document.getElementById('length-error').classList.remove('visible'); updateCalculator(); resultsSection.style.display = 'none'; } function copyResults() { var weight = mainResultSpan.textContent; var volume = volumeResultSpan.textContent; var area = areaResultSpan.textContent; var density = densityResultSpan.textContent; var type = document.getElementById('steelType').options[document.getElementById('steelType').selectedIndex].text; var dim1 = document.getElementById('dimension1').value; var dim2 = (document.getElementById('dimension2-group').style.display !== 'none') ? document.getElementById('dimension2').value : 'N/A'; var dim3 = (document.getElementById('dimension3-group').style.display !== 'none') ? document.getElementById('dimension3').value : 'N/A'; var length = document.getElementById('length').value; var textToCopy = "Steel Weight Calculation Results:\n\n" + "Steel Type: " + type + "\n" + "Dimension 1: " + dim1 + " mm\n"; if (dim2 !== 'N/A') { textToCopy += "Dimension 2: " + dim2 + " mm\n"; } if (dim3 !== 'N/A') { textToCopy += "Dimension 3 (Web Thickness): " + dim3 + " mm\n"; } textToCopy += "Length: " + length + " m\n\n" + "——————————–\n" + "Main Result (Weight): " + weight + "\n" + "Volume: " + volume + "\n" + "Cross-Sectional Area: " + area + "\n" + "Steel Density Used: " + density + "\n" + "\nFormula: Weight = Volume × Density"; if (navigator.clipboard && window.isSecureContext) { navigator.clipboard.writeText(textToCopy).then(function() { alert('Results copied to clipboard!'); }).catch(function(err) { console.error('Failed to copy: ', err); // Fallback for older browsers or non-secure contexts copyToClipboardFallback(textToCopy); }); } else { copyToClipboardFallback(textToCopy); } } function copyToClipboardFallback(text) { var textArea = document.createElement("textarea"); textArea.value = text; textArea.style.position = "fixed"; // Avoid scrolling to bottom textArea.style.opacity = "0"; document.body.appendChild(textArea); textArea.focus(); textArea.select(); try { var successful = document.execCommand('copy'); var msg = successful ? 'successful' : 'unsuccessful'; alert('Fallback: Copying text command was ' + msg); } catch (err) { console.error('Fallback: Oops, unable to copy', err); alert('Could not copy text. Please select and copy manually.'); } document.body.removeChild(textArea); } function populateTable() { var tableBody = document.getElementById('weight-table-body'); tableBody.innerHTML = "; // Clear existing rows var commonSizes = { round_bar: [ {d1: 10, l: 6}, {d1: 16, l: 6}, {d1: 20, l: 6}, {d1: 25, l: 12}, {d1: 32, l: 12} ], square_bar: [ {d1: 10, l: 6}, {d1: 16, l: 6}, {d1: 25, l: 6}, {d1: 30, l: 12}, {d1: 40, l: 12} ], flat_bar: [ {d1: 50, d2: 6, l: 6}, {d1: 75, d2: 8, l: 6}, {d1: 100, d2: 10, l: 12}, {d1: 150, d2: 12, l: 12} ], angle_bar: [ {d1: 30, d2: 3, l: 6}, {d1: 40, d2: 4, l: 6}, {d1: 50, d2: 5, l: 12}, {d1: 75, d2: 8, l: 12} ], h_beam: [ // Example standard H-beam profiles (use typical dimensions) {d1: 100, d2: 50, d3: 5, l: 12}, // Depth, Flange Width, Web Thickness {d1: 150, d2: 75, d3: 6, l: 12}, {d1: 200, d2: 100, d3: 7, l: 12}, {d1: 250, d2: 125, d3: 8, l: 12} ], i_beam: [ // Example standard I-beam profiles (use typical dimensions) {d1: 100, d2: 50, d3: 5, l: 12}, // Depth, Flange Width, Web Thickness {d1: 150, d2: 75, d3: 6, l: 12}, {d1: 200, d2: 100, d3: 7, l: 12}, {d1: 250, d2: 125, d3: 8, l: 12} ], tube_round: [ {d1: 20, d2: 2, l: 6}, {d1: 32, d2: 3, l: 6}, {d1: 48, d2: 4, l: 12}, {d1: 60, d2: 5, l: 12} ], tube_square: [ {d1: 25, d2: 2, l: 6}, {d1: 40, d2: 3, l: 6}, {d1: 50, d2: 4, l: 12}, {d1: 75, d2: 5, l: 12} ] }; var names = { round_bar: "Round Bar", square_bar: "Square Bar", flat_bar: "Flat Bar", angle_bar: "Angle Bar", h_beam: "H-Beam", i_beam: "I-Beam", tube_round: "Round Tube", tube_square: "Square Tube" }; var sizesToDisplay = commonSizes[steelTypeSelect.value] || []; for (var i = 0; i < sizesToDisplay.length; i++) { var size = sizesToDisplay[i]; var row = tableBody.insertRow(); var cellType = row.insertCell(); var cellD1 = row.insertCell(); var cellD2 = row.insertCell(); var cellD3 = row.insertCell(); // For beams var cellL = row.insertCell(); var cellWeight = row.insertCell(); cellType.textContent = names[steelTypeSelect.value]; cellD1.textContent = size.d1 + " mm"; if (size.d2 !== undefined) { cellD2.textContent = size.d2 + " mm"; } else { cellD2.textContent = "-"; } if (size.d3 !== undefined && (steelTypeSelect.value === 'h_beam' || steelTypeSelect.value === 'i_beam')) { cellD3.textContent = size.d3 + " mm (Web)"; } else { cellD3.textContent = "-"; } cellL.textContent = size.l + " m"; // Recalculate weight for table entries to ensure consistency var tempVolumeCm3 = 0; var tempAreaCm2 = 0; var lCm = size.l * 100; switch (steelTypeSelect.value) { case 'round_bar': var diameterCm = size.d1 / 10; var radiusCm = diameterCm / 2; tempAreaCm2 = Math.PI * radiusCm * radiusCm; break; case 'square_bar': var widthCm = size.d1 / 10; tempAreaCm2 = widthCm * widthCm; break; case 'flat_bar': var widthCm = size.d1 / 10; var thicknessCm = size.d2 / 10; tempAreaCm2 = widthCm * thicknessCm; break; case 'angle_bar': var legWidthCm = size.d1 / 10; var thicknessCm = size.d2 / 10; tempAreaCm2 = (2 * legWidthCm * thicknessCm) – (thicknessCm * thicknessCm); break; case 'h_beam': case 'i_beam': var depthCm = size.d1 / 10; var flangeWidthCm = size.d2 / 10; var webThicknessCm = size.d3 / 10; var typicalFlangeThicknessRatio = 0.5; // Consistent with calculator logic var flangeThicknessCm = flangeWidthCm * typicalFlangeThicknessRatio; tempAreaCm2 = (flangeWidthCm * flangeThicknessCm * 2) + (webThicknessCm * (depthCm – 2 * flangeThicknessCm)); break; case 'tube_round': var outerDiameterCm = size.d1 / 10; var wallThicknessCm = size.d2 / 10; var outerRadiusCm = outerDiameterCm / 2; var innerRadiusCm = outerRadiusCm – wallThicknessCm; tempAreaCm2 = Math.PI * (outerRadiusCm * outerRadiusCm – innerRadiusCm * innerRadiusCm); break; case 'tube_square': var outerWidthCm = size.d1 / 10; var wallThicknessCm = size.d2 / 10; var innerWidthCm = outerWidthCm – 2 * wallThicknessCm; tempAreaCm2 = (outerWidthCm * outerWidthCm) – (innerWidthCm * innerWidthCm); break; } tempVolumeCm3 = tempAreaCm2 * lCm; var tempWeightGrams = tempVolumeCm3 * steelDensity; cellWeight.textContent = (tempWeightGrams / 1000).toFixed(2) + " kg"; } } function updateChart() { var ctx = weightChartCanvas.getContext('2d'); // Destroy previous chart instance if it exists if (chartInstance) { chartInstance.destroy(); } var lengths = [1, 3, 6, 9, 12, 15]; // Sample lengths in meters var weights = []; var currentType = steelTypeSelect.value; var d1 = parseFloat(dimension1Input.value); var d2 = parseFloat(dimension2Input.value); var d3 = parseFloat(dimension3Input.value); // For beams var isValid = true; if (!validateInput(dimension1Input, 'dimension1-error')) isValid = false; if (document.getElementById('dimension2-group').style.display !== 'none' && !validateInput(dimension2Input, 'dimension2-error')) isValid = false; if (document.getElementById('dimension3-group').style.display !== 'none' && !validateInput(dimension3Input, 'dimension3-error')) isValid = false; if (!isValid || isNaN(d1) || d1 <= 0) { // Handle invalid primary inputs for chart generation // Maybe display a message or clear the chart return; } for (var i = 0; i 400 ? weightChartCanvas.parentElement.clientWidth * 0.8 : weightChartCanvas.parentElement.clientWidth * 0.95; // Responsive width weightChartCanvas.width = canvasWidth; weightChartCanvas.height = canvasHeight; var barWidth = (canvasWidth * 0.8) / lengths.length * 0.7; // 70% of available space for bar var barGap = (canvasWidth * 0.8) / lengths.length * 0.3; // 30% for gap var chartAreaX = canvasWidth * 0.1; // Left margin var chartAreaY = canvasHeight * 0.1; // Top margin var chartHeightArea = canvasHeight * 0.8; // Usable height var chartWidthArea = canvasWidth * 0.8; // Usable width ctx.clearRect(0, 0, canvasWidth, canvasHeight); // Clear previous drawing // Y-axis labels and line ctx.font = '12px Arial'; ctx.fillStyle = '#555'; ctx.textAlign = 'right'; var numYLabels = 5; for (var i = 0; i <= numYLabels; i++) { var yValue = maxWeight * (1 – i / numYLabels); var yPos = chartAreaY + chartHeightArea * (i / numYLabels); ctx.fillText(yValue.toFixed(1) + ' kg', chartAreaX – 10, yPos); ctx.beginPath(); ctx.moveTo(chartAreaX, yPos); ctx.lineTo(chartAreaX + chartWidthArea, yPos); ctx.strokeStyle = '#eee'; ctx.stroke(); } // X-axis labels and line ctx.textAlign = 'center'; ctx.textBaseline = 'top'; for (var i = 0; i < lengths.length; i++) { var xPos = chartAreaX + barGap / 2 + i * (barWidth + barGap) + barWidth / 2; ctx.fillText(lengths[i] + ' m', xPos, chartAreaY + chartHeightArea + 10); ctx.beginPath(); ctx.moveTo(xPos, chartAreaY + chartHeightArea); ctx.lineTo(xPos, chartAreaY + chartHeightArea + 5); ctx.strokeStyle = '#ccc'; ctx.stroke(); } // Bars ctx.fillStyle = 'rgba(0, 74, 153, 0.7)'; // Primary color for (var i = 0; i 0) { ctx.fillRect(xPos, yPos, barWidth, barHeight); } } // Chart title and legend ctx.fillStyle = '#004a99'; ctx.font = 'bold 16px Arial'; ctx.textAlign = 'center'; ctx.fillText('Weight vs. Length for Selected Steel Type', canvasWidth / 2, 20); var legend = document.getElementById('chart-legend'); var dim1Label = document.querySelector('#dimension1-group label').textContent.replace('(mm)', ").trim(); var dim2Label = (document.getElementById('dimension2-group').style.display !== 'none') ? document.querySelector('#dimension2-group label').textContent.replace('(mm)', ").trim() : "; var dim3Label = (document.getElementById('dimension3-group').style.display !== 'none') ? document.querySelector('#dimension3-group label').textContent.replace('(mm)', ").trim() : "; legend.innerHTML = ' Weight for ' + document.getElementById('steelType').options[document.getElementById('steelType').selectedIndex].text + ': ' + dim1Label + '=' + dimension1Input.value + ' mm' + (dim2Label ? ', ' + dim2Label + '=' + dimension2Input.value + ' mm' : ") + (dim3Label ? ', ' + dim3Label + '=' + dimension3Input.value + ' mm' : "); chartInstance = { // Store a simple object to simulate chart instance for destroy method destroy: function() { ctx.clearRect(0, 0, canvasWidth, canvasHeight); // Clear canvas on destroy } }; } function toggleFaq(element) { var item = element.parentElement; item.classList.toggle('open'); } // Initial calculations and setup document.addEventListener('DOMContentLoaded', function() { updateCalculator(); calculateWeight(); populateTable(); updateChart(); }); // Update chart dynamically on window resize window.addEventListener('resize', function() { // Debounce or throttle this if performance becomes an issue updateChart(); });

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