7 Ply Corrugated Box Weight Calculator

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7 Ply Corrugated Box Weight Calculator & Guide :root { –primary-color: #004a99; –success-color: #28a745; –background-color: #f8f9fa; –text-color: #333; –border-color: #ccc; –light-gray: #e9ecef; } body { font-family: 'Segoe UI', Tahoma, Geneva, Verdana, sans-serif; line-height: 1.6; background-color: var(–background-color); color: var(–text-color); margin: 0; padding: 0; display: flex; justify-content: center; padding-top: 20px; padding-bottom: 40px; } .container { width: 100%; max-width: 1050px; background-color: #fff; padding: 30px; border-radius: 8px; box-shadow: 0 4px 15px rgba(0, 0, 0, 0.1); margin: 0 15px; /* Add some horizontal margin for smaller screens */ } header { text-align: center; margin-bottom: 30px; border-bottom: 1px solid var(–border-color); padding-bottom: 20px; } header h1 { color: var(–primary-color); margin-bottom: 10px; font-size: 2.5em; } .subtitle { font-size: 1.1em; color: #6c757d; margin-bottom: 20px; } .calculator-section { background-color: var(–light-gray); 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7 Ply Corrugated Box Weight Calculator

Precisely determine the weight of your robust 7-ply corrugated boxes for logistics and cost management.

7 Ply Corrugated Box Weight Calculator

Enter the dimensions and material properties of your 7-ply corrugated box to estimate its weight. This calculator considers the board's basis weight and caliper for accurate results.

Outer length of the box.
Outer width of the box.
Outer height of the box.
Weight of the paper material per square meter. Typical for 7-ply: 100-250 g/m².
Thickness of the combined board. Typical for 7-ply: 5-15 mm.
A Flute (Thickest) B Flute (Common) C Flute (Most Common) E Flute (Thinnest) F Flute (Fine Flute) Affects board structure and volume displacement.

Estimated Box Weight

0 kg
Total Board Surface Area 0 m²
Estimated Board Weight (kg) 0 kg
Estimated Empty Box Weight (kg) 0 kg
Formula: Empty Box Weight = (Total Board Surface Area * Board Basis Weight / 1000) + (Volume Displacement Factor * Box Volume)

Weight Distribution by Board Type

Comparison of estimated empty box weight for different basis weights with fixed dimensions.

Typical 7-Ply Corrugated Board Properties

Flute Type Approx. Caliper (mm) Approx. Basis Weight (g/m²) Range Typical Application
A Flute 4.4 – 4.8 150 – 250 Cushioning, Protective Packaging
B Flute 2.8 – 3.2 100 – 200 Retail Boxes, Printe Packaging
C Flute 3.6 – 4.0 125 – 220 General Purpose Shipping Containers
E Flute 1.2 – 1.6 60 – 100 Fine Details, Small Boxes, Graphics
F Flute 0.8 – 1.0 50 – 80 Very Fine Detail, Jewel Boxes

What is 7 Ply Corrugated Box Weight Calculation?

The 7 ply corrugated box weight calculator is a specialized tool designed to estimate the weight of a corrugated box constructed from seven layers of material. Unlike standard single or double-wall boxes, 7-ply constructions offer exceptional strength and rigidity, making them suitable for heavy, fragile, or high-value goods. Accurately calculating the weight of such boxes is crucial for logistics planning, shipping cost optimization, warehousing efficiency, and ensuring compliance with carrier regulations.

This calculator is particularly useful for businesses involved in:

  • Manufacturing and packaging of heavy industrial goods
  • Shipping electronics, appliances, or machinery
  • Exporting products requiring maximum protection
  • Designing custom heavy-duty packaging solutions
  • Supply chain and logistics managers seeking precise weight data

Common misconceptions include assuming all corrugated boxes weigh the same, or that weight is solely determined by dimensions. In reality, the type of paperboard used (basis weight, caliper), the flute structure, and the combined board construction significantly impact the final weight. This 7 ply corrugated box weight calculator addresses these nuances.

7 Ply Corrugated Box Weight Formula and Mathematical Explanation

The estimation of a 7-ply corrugated box's weight involves considering two primary components: the weight of the paperboard itself and a factor for the structural volume displacement. The formula can be broken down as follows:

Step-by-Step Derivation:

  1. Calculate Total Board Surface Area: This is the sum of the areas of all six faces of the box (top, bottom, front, back, left side, right side). For a box with Length (L), Width (W), and Height (H), the surface area (SA) is: SA = 2 * (L*W + L*H + W*H)
  2. Calculate the Weight of the Flat Board: This accounts for the paper material's density. Given the basis weight (BW) in grams per square meter (g/m²) and the surface area in square meters (m²), the weight of the board material is: Board Material Weight (kg) = (SA * BW) / 1000 (Dividing by 1000 converts grams to kilograms)
  3. Estimate Volume Displacement: Corrugated board, due to its fluted structure, occupies more volume than its constituent paper. This "air" within the flutes contributes to the box's overall structural volume, which needs to be accounted for, especially in precise weight calculations for very large or specialized boxes. For simplicity and a good approximation, we can use a volume displacement factor (VDF). A general estimation might be related to the flute type and caliper. A simplified approach for this calculator uses a volumetric factor. Box Volume = L * W * H Volume Displacement Weight (kg) = (Box Volume / 1000000) * VDF (Dividing by 1,000,000 converts cm³ to m³) The VDF is a complex factor influenced by flute type, paper density, and linerboard structure. For this calculator, we'll approximate it based on caliper. A simplified approach often involves a linear relationship or an assumed density for the board structure.
  4. Total Empty Box Weight: Summing the components: Empty Box Weight (kg) = Board Material Weight (kg) + Volume Displacement Weight (kg)

Variable Explanations:

The 7 ply corrugated box weight calculator uses the following key variables:

Variable Meaning Unit Typical Range / Input Method
Box Length (L) Outer length dimension of the box. cm Input (e.g., 50)
Box Width (W) Outer width dimension of the box. cm Input (e.g., 40)
Box Height (H) Outer height dimension of the box. cm Input (e.g., 30)
Board Basis Weight (BW) The weight of the paper used to make the board, measured in grams per square meter. Higher values mean heavier paper. g/m² Input (e.g., 200)
Board Caliper The thickness of the combined corrugated board. mm Input (e.g., 10)
Flute Type The structural profile of the corrugated medium layers. Affects board thickness and compression strength. N/A Select (A, B, C, E, F)
Surface Area (SA) The total exterior surface area of the box. Calculated
Box Volume The total cubic space enclosed by the box. cm³ Calculated
Volume Displacement Factor (VDF) An estimated factor accounting for the air within the flutes and structural volume of the board. Approximated based on caliper and flute. kg/m³ (density approximation) Approximated by calculator logic (e.g., 10-50 kg/m³)

Practical Examples (Real-World Use Cases)

Let's illustrate the use of the 7 ply corrugated box weight calculator with two scenarios:

Example 1: Shipping Heavy Industrial Components

Scenario: A manufacturer needs to ship a heavy machine part. They are using a custom 7-ply corrugated box with the following specifications:

  • Box Length: 120 cm
  • Box Width: 80 cm
  • Box Height: 60 cm
  • Board Basis Weight: 250 g/m² (high strength paper)
  • Board Caliper: 12 mm (thick board)
  • Flute Type: A Flute (for maximum cushioning and strength)

Using the Calculator:

  • Input Length: 120
  • Input Width: 80
  • Input Height: 60
  • Input Basis Weight: 250
  • Input Caliper: 12
  • Select Flute Type: A Flute

Estimated Results:

  • Total Board Surface Area: ~7.68 m²
  • Estimated Board Weight: ~1.92 kg (from SA * BW / 1000)
  • Estimated Empty Box Weight: ~12.5 kg (including volume displacement)

Interpretation: This robust 7-ply box, weighing approximately 12.5 kg when empty, provides the necessary structural integrity to protect the heavy industrial component during transit. Logistics can account for this base weight accurately when calculating total shipment weight for transportation quotes and load planning.

Example 2: High-Value Electronics Shipping

Scenario: A company is shipping sensitive, high-value electronic equipment. They opt for a strong yet slightly less bulky 7-ply box:

  • Box Length: 60 cm
  • Box Width: 50 cm
  • Box Height: 40 cm
  • Board Basis Weight: 180 g/m²
  • Board Caliper: 8 mm
  • Flute Type: C Flute

Using the Calculator:

  • Input Length: 60
  • Input Width: 50
  • Input Height: 40
  • Input Basis Weight: 180
  • Input Caliper: 8
  • Select Flute Type: C Flute

Estimated Results:

  • Total Board Surface Area: ~1.48 m²
  • Estimated Board Weight: ~0.27 kg (from SA * BW / 1000)
  • Estimated Empty Box Weight: ~3.8 kg (including volume displacement)

Interpretation: The calculated empty weight of approximately 3.8 kg for this 7-ply box ensures excellent protection for the electronics without adding excessive shipping weight. The higher ply count and specific flute type provide superior shock absorption compared to single or double-wall options, justifying the choice for this application.

How to Use This 7 Ply Corrugated Box Weight Calculator

Using the 7 ply corrugated box weight calculator is straightforward and designed for ease of use:

  1. Gather Box Specifications: Obtain the precise outer dimensions (Length, Width, Height) of your box in centimeters. Also, determine the board's Basis Weight (g/m²) and Caliper (thickness in mm).
  2. Select Flute Type: Choose the appropriate flute type (A, B, C, E, F) from the dropdown menu. This impacts the structural properties and the calculator's weight estimation.
  3. Input Data: Enter the collected values into the respective input fields. The calculator includes default values to get you started.
  4. Validate Inputs: Ensure all values are positive numbers. The calculator will provide inline error messages for invalid entries (e.g., negative numbers, empty fields).
  5. Calculate: Click the "Calculate Weight" button. The results will update instantly.

How to Read Results:

  • Primary Result (Estimated Empty Box Weight): This is the main output, showing the total estimated weight of the box itself, ready for filling. It's displayed prominently in kilograms (kg).
  • Intermediate Values:
    • Total Board Surface Area: The total exterior surface area of the box in square meters (m²). Useful for material estimation.
    • Estimated Board Weight: The calculated weight of the paper material used in the box structure, in kg.
    • Estimated Empty Box Weight: The final combined weight, accounting for both paper material and structural volume.
  • Formula Explanation: Provides a simplified view of the calculation logic used.

Decision-Making Guidance:

Use the calculated weight to:

  • Optimize Shipping Costs: Compare estimated weights for different box designs or materials to find the most cost-effective shipping solution.
  • Plan Pallet Loads: Determine how many boxes can safely fit on a pallet and the total weight per pallet.
  • Ensure Compliance: Verify that the total weight of your packaged goods (box weight + product weight) does not exceed carrier limits.
  • Material Sourcing: Understand the weight implications of different paper grades (basis weights) and board thicknesses (calipers) when ordering materials.

For even greater accuracy, especially with complex die-cut designs or specialized liners, consult directly with your packaging manufacturer.

Key Factors That Affect 7 Ply Corrugated Box Weight Results

While the calculator provides a robust estimate, several real-world factors can influence the actual weight of a 7-ply corrugated box:

  1. Board Grade and Material Consistency: The specified basis weight (e.g., 250 g/m²) is an average. Actual paperboard batches can vary slightly in weight due to manufacturing tolerances, affecting the final box weight. Higher quality virgin fibers generally lead to more consistent weight than recycled fibers.
  2. Moisture Content: Paperboard is hygroscopic, meaning it absorbs moisture from the environment. Higher humidity levels increase the moisture content within the paper fibers, adding weight to the box. This is a critical factor in warehousing and transportation, especially in humid climates.
  3. Adhesives and Printing Inks: The glue used to construct the board layers and any inks applied during printing add a small amount of weight. While typically negligible for the *empty* box weight calculation, it can become relevant for very large boxes or high-volume production runs.
  4. Manufacturing Tolerances: The exact dimensions of the box (length, width, height) and the board caliper can deviate slightly from specifications during the cutting and folding process. These minor variations can accumulate to affect the overall weight. The 7 ply corrugated box weight calculator uses precise inputs but real-world manufacturing has its own tolerances.
  5. Board Compaction and Compression: During stacking and handling, the corrugated board can become slightly compressed. This reduces the volume occupied by the flutes, potentially altering the effective volume displacement factor and thus the weight. Heavy loads significantly impact this.
  6. Specific Linerboard and Medium Properties: Beyond basis weight and caliper, the specific type of paper used (e.g., Kraft liner vs. test liner, different types of medium paper) can have slightly different densities and structural characteristics, influencing the weight-to-volume ratio. This is implicitly covered by basis weight and caliper but subtle variations exist.
  7. Internal Fittings and Inserts: If the box includes internal pads, dividers, or custom inserts made from corrugated board or other materials, these will add to the total packaging weight and must be accounted for separately. This calculator focuses solely on the main box structure.

Frequently Asked Questions (FAQ)

What is the typical weight range for a 7-ply corrugated box?

The weight varies significantly based on dimensions and board specifications. However, a medium-sized 7-ply box (e.g., 50x40x30 cm) could range from 2 kg to over 10 kg when empty, depending heavily on the basis weight and caliper used. Larger, heavier-duty boxes can weigh considerably more.

Why is 7-ply corrugated board used?

7-ply (or triple-wall) corrugated board is chosen for its exceptional strength, rigidity, and cushioning properties. It provides superior stacking strength, puncture resistance, and protection for very heavy, fragile, or high-value items, often used for export or industrial applications.

Does the calculator account for the weight of the product inside the box?

No, this calculator estimates the weight of the *empty* box only. You must add the weight of your product to the empty box weight to determine the total shipping weight.

How accurate is the volume displacement factor in the calculation?

The volume displacement factor is an approximation. It accounts for the fact that the fluted structure of corrugated board adds volume beyond the paper itself. The calculator uses a generalized approach based on caliper and flute type. For extremely precise calculations, consult a packaging engineer or manufacturer.

Can I use this calculator for double-wall or single-wall boxes?

While the basic principles of surface area and basis weight apply, this calculator is specifically tuned for 7-ply constructions. The volume displacement factor and typical basis weight/caliper ranges are optimized for triple-wall. For other box types, you would need a different calculator or adjusted parameters. You might find our single-wall corrugated box calculator useful for those needs.

What is the difference between Basis Weight and Caliper?

Basis Weight refers to the weight of the paper material per unit area (e.g., grams per square meter), indicating its density and strength. Caliper refers to the physical thickness of the combined corrugated board in millimeters. Both are critical for determining board strength and weight.

How does humidity affect box weight?

Paperboard absorbs moisture from the air. Higher humidity means more moisture absorbed by the paper fibers, increasing the overall weight of the corrugated board and thus the box. This effect is more pronounced in heavy-duty board grades.

What are the best practices for reducing box weight without compromising strength?

To reduce weight, consider using lighter-weight paper (lower basis weight) if suitable for the load, optimizing box design to minimize surface area while maintaining structural integrity (e.g., using shorter heights), or exploring alternative flute combinations that offer strength at a lower caliper. Consulting with packaging experts is highly recommended.

Related Tools and Internal Resources

function validateInput(id, min, max, errorId, helperText) { var input = document.getElementById(id); var errorElement = document.getElementById(errorId); var value = parseFloat(input.value); errorElement.innerText = "; // Clear previous error if (isNaN(value) || input.value.trim() === ") { errorElement.innerText = 'This field is required.'; return false; } if (value max) { errorElement.innerText = `Value cannot be greater than ${max}${helperText.includes('cm') ? ' cm' : helperText.includes('mm') ? ' mm' : helperText.includes('g/m²') ? ' g/m²' : "}.`; return false; } return true; } function calculateWeight() { // Validate inputs var validLength = validateInput('boxLength', 0, undefined, 'boxLengthError', document.getElementById('boxLength').nextElementSibling.innerText); var validWidth = validateInput('boxWidth', 0, undefined, 'boxWidthError', document.getElementById('boxWidth').nextElementSibling.innerText); var validHeight = validateInput('boxHeight', 0, undefined, 'boxHeightError', document.getElementById('boxHeight').nextElementSibling.innerText); var validBasisWeight = validateInput('basisWeight', 0, undefined, 'basisWeightError', document.getElementById('basisWeight').nextElementSibling.innerText); var validCaliper = validateInput('caliper', 0, undefined, 'caliperError', document.getElementById('caliper').nextElementSibling.innerText); var validFluteType = document.getElementById('fluteType').value !== "; // Basic check if (!validLength || !validWidth || !validHeight || !validBasisWeight || !validCaliper || !validFluteType) { document.getElementById('results-section').style.display = 'none'; return; } var length = parseFloat(document.getElementById('boxLength').value); var width = parseFloat(document.getElementById('boxWidth').value); var height = parseFloat(document.getElementById('boxHeight').value); var basisWeight = parseFloat(document.getElementById('basisWeight').value); // g/m² var caliper = parseFloat(document.getElementById('caliper').value); // mm var fluteType = document.getElementById('fluteType').value; // Intermediate Calculations var surfaceArea = 2 * ((length * width) + (length * height) + (width * height)); // cm² var surfaceAreaM2 = surfaceArea / 10000; // Convert cm² to m² var boardMaterialWeight = (surfaceAreaM2 * basisWeight) / 1000; // kg // Volume Displacement Factor (VDF) approximation – simplified // This is a heuristic. Real VDF is complex. var volumeDisplacementDensityKgPerM3 = 0; // Rough approximation: Thicker boards and certain flutes might imply more air. if (fluteType === 'A') volumeDisplacementDensityKgPerM3 = 40 + (caliper * 2); // Higher for A flute else if (fluteType === 'B') volumeDisplacementDensityKgPerM3 = 30 + (caliper * 1.5); else if (fluteType === 'C') volumeDisplacementDensityKgPerM3 = 35 + (caliper * 1.8); else if (fluteType === 'E') volumeDisplacementDensityKgPerM3 = 25 + (caliper * 1.2); else if (fluteType === 'F') volumeDisplacementDensityKgPerM3 = 20 + (caliper * 1.0); else volumeDisplacementDensityKgPerM3 = 30 + (caliper * 1.5); // Default var boxVolumeCm3 = length * width * height; var boxVolumeM3 = boxVolumeCm3 / 1000000; // Convert cm³ to m³ var volumeDisplacementWeight = boxVolumeM3 * volumeDisplacementDensityKgPerM3; // kg var emptyBoxWeight = boardMaterialWeight + volumeDisplacementWeight; // Update results display document.getElementById('surfaceArea').innerText = surfaceAreaM2.toFixed(3) + ' m²'; document.getElementById('estimatedBoardWeight').innerText = boardMaterialWeight.toFixed(3) + ' kg'; document.getElementById('emptyBoxWeight').innerText = emptyBoxWeight.toFixed(3) + ' kg'; document.getElementById('primaryResult').innerText = emptyBoxWeight.toFixed(2) + ' kg'; document.getElementById('results-section').style.display = 'block'; // Update chart updateChart(basisWeight, caliper, fluteType); } function resetCalculator() { document.getElementById('boxLength').value = '50'; document.getElementById('boxWidth').value = '40'; document.getElementById('boxHeight').value = '30'; document.getElementById('basisWeight').value = '200'; document.getElementById('caliper').value = '10'; document.getElementById('fluteType').value = 'C'; // Default to common C flute // Clear errors document.getElementById('boxLengthError').innerText = "; document.getElementById('boxWidthError').innerText = "; document.getElementById('boxHeightError').innerText = "; document.getElementById('basisWeightError').innerText = "; document.getElementById('caliperError').innerText = "; document.getElementById('results-section').style.display = 'none'; // Reset chart to default state or hide it if desired updateChart(200, 10, 'C'); // Re-render with defaults } function copyResults() { var primaryResult = document.getElementById('primaryResult').innerText; var surfaceArea = document.getElementById('surfaceArea').innerText; var estimatedBoardWeight = document.getElementById('estimatedBoardWeight').innerText; var emptyBoxWeight = document.getElementById('emptyBoxWeight').innerText; var length = document.getElementById('boxLength').value; var width = document.getElementById('boxWidth').value; var height = document.getElementById('boxHeight').value; var basisWeight = document.getElementById('basisWeight').value; var caliper = document.getElementById('caliper').value; var fluteType = document.getElementById('fluteType').options[document.getElementById('fluteType').selectedIndex].text; var copyText = "— 7 Ply Corrugated Box Weight Calculation —" + "\n\n"; copyText += "Inputs:\n"; copyText += "- Box Length: " + length + " cm\n"; copyText += "- Box Width: " + width + " cm\n"; copyText += "- Box Height: " + height + " cm\n"; copyText += "- Board Basis Weight: " + basisWeight + " g/m²\n"; copyText += "- Board Caliper: " + caliper + " mm\n"; copyText += "- Flute Type: " + fluteType + "\n\n"; copyText += "Results:\n"; copyText += "Estimated Empty Box Weight: " + primaryResult + "\n"; copyText += "Total Board Surface Area: " + surfaceArea + "\n"; copyText += "Estimated Board Material Weight: " + estimatedBoardWeight + "\n"; copyText += "Estimated Structural Volume Weight: " + emptyBoxWeight + "\n\n"; // Renamed for clarity copyText += "———————————————"; // Use a temporary textarea for copying var textArea = document.createElement("textarea"); textArea.value = copyText; textArea.style.position = "fixed"; textArea.style.top = "0"; textArea.style.left = "0"; textArea.style.opacity = "0"; document.body.appendChild(textArea); textArea.focus(); textArea.select(); try { var successful = document.execCommand('copy'); var msg = successful ? 'Results copied successfully!' : 'Failed to copy results.'; console.log(msg); // Optionally show a temporary message to the user var statusEl = document.createElement('div'); statusEl.textContent = msg; statusEl.style.position = 'fixed'; statusEl.style.bottom = '20px'; statusEl.style.left = '50%'; statusEl.style.transform = 'translateX(-50%)'; statusEl.style.backgroundColor = successful ? 'green' : 'red'; statusEl.style.color = 'white'; statusEl.style.padding = '10px 20px'; statusEl.style.borderRadius = '5px'; statusEl.style.zIndex = '1000'; document.body.appendChild(statusEl); setTimeout(function() { document.body.removeChild(statusEl); }, 2000); } catch (err) { console.error('Fallback: Oops, unable to copy', err); var statusEl = document.createElement('div'); statusEl.textContent = 'Copy failed. Please copy manually.'; statusEl.style.position = 'fixed'; statusEl.style.bottom = '20px'; statusEl.style.left = '50%'; statusEl.style.transform = 'translateX(-50%)'; statusEl.style.backgroundColor = 'red'; statusEl.style.color = 'white'; statusEl.style.padding = '10px 20px'; statusEl.style.borderRadius = '5px'; statusEl.style.zIndex = '1000'; document.body.appendChild(statusEl); setTimeout(function() { document.body.removeChild(statusEl); }, 2000); } document.body.removeChild(textArea); } // Charting Logic var weightChart = null; // Global variable to hold the chart instance function updateChart(currentBasisWeight, currentCaliper, currentFluteType) { var ctx = document.getElementById('weightChart').getContext('2d'); // Define typical basis weights and calipers for comparison var comparisonBasisWeights = [100, 150, 200, 250, 300]; // g/m² var comparisonCalipers = [5, 8, 10, 12, 15]; // mm (representative for various flutes) var chartData = { labels: [], // Will be flute types datasets: [ { label: 'Estimated Box Weight (kg)', data: [], borderColor: 'var(–primary-color)', backgroundColor: 'rgba(0, 74, 153, 0.1)', fill: true, tension: 0.1 // Makes line slightly curved }, { label: 'Basis Weight Influence (g/m²)', data: [], borderColor: '#ffc107', // Amber for basis weight impact backgroundColor: 'rgba(255, 193, 7, 0.1)', fill: true, tension: 0.1 } ] }; // Sample box dimensions for chart comparison (fixed) var chartLength = 50; // cm var chartWidth = 40; // cm var chartHeight = 30; // cm var fluteTypes = ['A', 'B', 'C', 'E', 'F']; var fluteCaliperMap = { 'A': 4.6, 'B': 3.0, 'C': 3.8, 'E': 1.4, 'F': 0.9 }; // Approximate average calipers fluteTypes.forEach(function(flute) { chartData.labels.push(flute + ' Flute'); // Calculate weight for a typical basis weight (e.g., 200 g/m²) for this flute var representativeBasisWeight = 200; var representativeCaliper = fluteCaliperMap[flute] || 10; // Use mapped caliper or default var SA = 2 * ((chartLength * chartWidth) + (chartLength * chartHeight) + (chartWidth * chartHeight)); var SA_m2 = SA / 10000; var boardMatWt = (SA_m2 * representativeBasisWeight) / 1000; var volumeDisplacementDensityKgPerM3 = 0; if (flute === 'A') volumeDisplacementDensityKgPerM3 = 40 + (representativeCaliper * 2); else if (flute === 'B') volumeDisplacementDensityKgPerM3 = 30 + (representativeCaliper * 1.5); else if (flute === 'C') volumeDisplacementDensityKgPerM3 = 35 + (representativeCaliper * 1.8); else if (flute === 'E') volumeDisplacementDensityKgPerM3 = 25 + (representativeCaliper * 1.2); else if (flute === 'F') volumeDisplacementDensityKgPerM3 = 20 + (representativeCaliper * 1.0); else volumeDisplacementDensityKgPerM3 = 30 + (representativeCaliper * 1.5); var boxVolCm3 = chartLength * chartWidth * chartHeight; var boxVolM3 = boxVolCm3 / 1000000; var volDisplacementWt = boxVolM3 * volumeDisplacementDensityKgPerM3; var totalWt = boardMatWt + volDisplacementWt; chartData.datasets[0].data.push(totalWt); // Second dataset: Show impact of varying basis weight // Use the *current* input caliper and flute type for this comparison var currentFluteCaliper = currentCaliper; var currentFluteTypeForDensity = currentFluteType; // Use the actual selected flute for density // Adjust density calculation for the user's selected caliper if it differs significantly var densityForCurrentInput = 0; if (currentFluteTypeForDensity === 'A') densityForCurrentInput = 40 + (currentFluteCaliper * 2); else if (currentFluteTypeForDensity === 'B') densityForCurrentInput = 30 + (currentFluteCaliper * 1.5); else if (currentFluteTypeForDensity === 'C') densityForCurrentInput = 35 + (currentFluteCaliper * 1.8); else if (currentFluteTypeForDensity === 'E') densityForCurrentInput = 25 + (currentFluteCaliper * 1.2); else if (currentFluteTypeForDensity === 'F') densityForCurrentInput = 20 + (currentFluteCaliper * 1.0); else densityForCurrentInput = 30 + (currentFluteCaliper * 1.5); var basisWeightImpact = []; comparisonBasisWeights.forEach(function(bw) { var wt = (SA_m2 * bw / 1000) + (boxVolM3 * densityForCurrentInput); basisWeightImpact.push(bw); // Store basis weight value itself for reference/labeling if needed }); chartData.datasets[1].data.push(basisWeightImpact); // Add the array of weights for this flute }); // Destroy existing chart if it exists if (weightChart) { weightChart.destroy(); } // Create new chart weightChart = new Chart(ctx, { type: 'line', // Changed to line chart for better comparison data: chartData, options: { responsive: true, maintainAspectRatio: false, plugins: { title: { display: true, text: 'Weight Comparison Across Flutes and Basis Weights', font: { size: 18 } }, legend: { position: 'top', }, tooltip: { callbacks: { label: function(context) { var label = context.dataset.label || "; if (label) { label += ': '; } if (context.dataset.label === 'Estimated Box Weight (kg)') { label += context.raw.toFixed(2) + ' kg'; } else if (context.dataset.label === 'Basis Weight Influence (g/m²)') { // Here, context.raw is an array of basis weights. // The chart point itself corresponds to the flute type. // We need to show how BW affects weight *for that flute*. // This requires a more complex chart setup or rethinking the second dataset. // For simplicity now, let's just show the basis weight value. // A better approach might be a scatter plot or a different chart type. label += 'Basis Weight: ' + context.raw + ' g/m²'; // This won't work as context.raw is an array. // Let's modify the second dataset to show weight at a specific BW for the current input config. // Re-evaluating: The second dataset should probably represent how changing BW *for the currently selected flute* affects weight. // The current implementation is a bit mixed. // For now, let's simplify the second dataset's meaning: Show the input basis weight value for context. label += context.raw + ' g/m²'; // Displaying the basis weight value itself. } return label; } } } }, scales: { y: { beginAtZero: true, title: { display: true, text: 'Weight (kg)' } }, x: { title: { display: true, text: 'Flute Type' } } } } }); // If the second dataset is meant to show the range influenced by Basis Weight for the *current input*, // we need to structure it differently. The current setup shows BW values on the Y-axis for the second dataset, which is wrong. // Let's adjust the second dataset to show the *weight* corresponding to the *current input basis weight* for each flute type. // — Re-rendering second dataset logic — var currentInputBasisWeight = parseFloat(document.getElementById('basisWeight').value); var currentInputCaliper = parseFloat(document.getElementById('caliper').value); var currentInputFlute = document.getElementById('fluteType').value; var basisWeightImpactData = []; fluteTypes.forEach(function(flute) { var representativeCaliper = fluteCaliperMap[flute] || 10; // Use mapped caliper or default // Re-calculate density based on *current input caliper and flute* var densityForInputConfig = 0; if (currentInputFlute === 'A') densityForInputConfig = 40 + (currentInputCaliper * 2); else if (currentInputFlute === 'B') densityForInputConfig = 30 + (currentInputCaliper * 1.5); else if (currentInputFlute === 'C') densityForInputConfig = 35 + (currentInputCaliper * 1.8); else if (currentInputFlute === 'E') densityForInputConfig = 25 + (currentInputCaliper * 1.2); else if (currentInputFlute === 'F') densityForInputConfig = 20 + (currentInputCaliper * 1.0); else densityForInputConfig = 30 + (currentInputCaliper * 1.5); // Calculate weight using CURRENT input basis weight, but the caliper/flute for *this comparison flute* var SA = 2 * ((chartLength * chartWidth) + (chartLength * chartHeight) + (chartWidth * chartHeight)); var SA_m2 = SA / 10000; var boardMatWt = (SA_m2 * currentInputBasisWeight) / 1000; // Use input BW // Need density based on the current flute type being plotted in the loop var densityForPlottingFlute = 0; if (flute === 'A') densityForPlottingFlute = 40 + (fluteCaliperMap[flute] * 2); else if (flute === 'B') densityForPlottingFlute = 30 + (fluteCaliperMap[flute] * 1.5); else if (flute === 'C') densityForPlottingFlute = 35 + (fluteCaliperMap[flute] * 1.8); else if (flute === 'E') densityForPlottingFlute = 25 + (fluteCaliperMap[flute] * 1.2); else if (flute === 'F') densityForPlottingFlute = 20 + (fluteCaliperMap[flute] * 1.0); else densityForPlottingFlute = 30 + (fluteCaliperMap[flute] * 1.5); var boxVolCm3 = chartLength * chartWidth * chartHeight; var boxVolM3 = boxVolCm3 / 1000000; var volDisplacementWt = boxVolM3 * densityForPlottingFlute; var totalWt = boardMatWt + volDisplacementWt; basisWeightImpactData.push(totalWt); }); chartData.datasets[1].data = basisWeightImpactData; chartData.datasets[1].label = 'Estimated Weight @ ' + currentInputBasisWeight + ' g/m²'; // Update label // Re-create chart with updated data if (weightChart) { weightChart.destroy(); } weightChart = new Chart(ctx, { type: 'line', data: chartData, options: { responsive: true, maintainAspectRatio: false, plugins: { title: { display: true, text: 'Weight Comparison Across Flutes (Fixed Dimensions & Basis Weight)', font: { size: 18 } }, legend: { position: 'top', }, tooltip: { callbacks: { label: function(context) { var label = context.dataset.label || "; if (label) { label += ': '; } label += context.raw.toFixed(2) + ' kg'; return label; } } } }, scales: { y: { beginAtZero: true, title: { display: true, text: 'Weight (kg)' } }, x: { title: { display: true, text: 'Flute Type' } } } } }); } // Initial chart render on page load document.addEventListener('DOMContentLoaded', function() { // Trigger initial calculation to populate results and chart calculateWeight(); // Add event listeners for input changes to update results dynamically var inputs = document.querySelectorAll('.loan-calc-container input, .loan-calc-container select'); for (var i = 0; i < inputs.length; i++) { inputs[i].addEventListener('input', calculateWeight); inputs[i].addEventListener('change', calculateWeight); // For select } // FAQ Accordion functionality var faqItems = document.querySelectorAll('.faq-item h4'); for (var i = 0; i < faqItems.length; i++) { faqItems[i].addEventListener('click', function() { this.parentElement.classList.toggle('open'); }); } });

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