304 Stainless Steel Weight Calculator

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304 Stainless Steel Weight Calculator

Accurate Weight Calculation for 304 Stainless Steel Components

What is the 304 Stainless Steel Weight Calculator?

The 304 stainless steel weight calculator is a specialized tool designed to estimate the mass of components made from 304 grade stainless steel. This calculator simplifies the complex process of determining weight by taking key physical dimensions and the material's density as inputs. It's essential for engineers, fabricators, procurement specialists, and anyone involved in projects utilizing 304 stainless steel, ensuring accurate material estimation for costing, logistics, and structural integrity assessments. Understanding the weight of materials is fundamental in metal fabrication and engineering, directly impacting project budgets, shipping costs, and the structural design of components.

Who should use it:

  • Fabricators and Manufacturers: To estimate raw material needs, optimize cutting, and quote projects accurately.
  • Engineers and Designers: To verify material specifications, calculate loads, and ensure designs meet weight constraints.
  • Procurement and Purchasing Departments: To accurately budget for material purchases and manage inventory.
  • Logistics and Shipping Personnel: To plan transportation and manage shipping weights for compliance and cost-efficiency.
  • DIY Enthusiasts and Hobbyists: For smaller projects where precise material quantity is important.

Common Misconceptions:

  • "All stainless steel weighs the same": Different grades of stainless steel have slightly different densities due to their varying alloy compositions, leading to different weights for the same volume.
  • "Density is a fixed value across all conditions": While density is largely constant, extreme temperature variations can cause minor changes, though for most practical applications, the standard density is used.
  • "Weight calculations are simple multiplication": Complex shapes require breaking down into simpler geometric forms (cubes, cylinders, spheres) before calculation, or using volume displacement principles. Our calculator handles common shapes.

304 Stainless Steel Weight Calculator

Sheet/Plate Rod/Bar Tube (Round) Pipe (Round) Angle Iron
Enter length in mm.
Enter width in mm.
Enter thickness in mm.
Enter length in mm.
Enter diameter in mm.
Enter length in mm.
Enter outer diameter in mm.
Enter wall thickness in mm.
Enter length in mm.
1/2″ 3/4″ 1″ 1 1/4″ 1 1/2″ 2″ 2 1/2″ 3″ 4″ Select the Nominal Pipe Size.
Sch 10 Sch 40 Sch 80 Sch 160 Select the pipe schedule (wall thickness).
Enter length in mm.
Enter size of Leg A in mm.
Enter size of Leg B in mm.
Enter thickness in mm.

Results

Volume:
Density:

Assumptions

Material Density:
Units Used:

Weight = Volume × Density

304 Stainless Steel Weight Calculation Formula & Explanation

The calculation of the weight of a 304 stainless steel component relies on a fundamental principle: Weight = Volume × Density. To accurately determine the weight, we first need to calculate the volume of the component based on its shape and dimensions, and then multiply that volume by the density of 304 stainless steel.

Mathematical Explanation

The general formula is:

Weight = V × ρ

Where:

  • Weight is the mass of the component.
  • V is the geometric volume of the component.
  • ρ (rho) is the density of 304 stainless steel.

The complexity lies in calculating the volume (V) for different shapes:

Volume Formulas for Common Shapes
Shape Formula for Volume (V) Variables
Sheet/Plate V = Length × Width × Thickness L = Length, W = Width, T = Thickness
Rod/Bar (Cylindrical) V = π × (Diameter/2)² × Length D = Diameter, L = Length, π ≈ 3.14159
Tube (Round) V = π × ( (Outer Diameter/2)² – (Inner Diameter/2)² ) × Length OD = Outer Diameter, ID = Inner Diameter, L = Length, π ≈ 3.14159
Pipe (Round) V = π × ( (Outer Diameter/2)² – (Inner Diameter/2)² ) × Length OD = Outer Diameter, ID = Inner Diameter (derived from NPS & Schedule), L = Length, π ≈ 3.14159
Angle Iron V = ( (LegA + LegB – Thickness) × Thickness ) × Length LA = Leg A Size, LB = Leg B Size, T = Thickness, L = Length

The density (ρ) of 304 stainless steel is a material property. For calculations, we typically use an average value.

Variable Explanations and Typical Ranges

Variables Table
Variable Meaning Unit Typical Range / Value
Length (L) The longest dimension of the component. mm (millimeters) Varies widely (e.g., 100 – 6000+)
Width (W) The dimension perpendicular to length for flat shapes. mm (millimeters) Varies widely (e.g., 50 – 2000+)
Thickness (T) The smallest dimension for sheets/plates, or the wall thickness for tubes/pipes. mm (millimeters) Varies widely (e.g., 0.5 – 25+)
Diameter (D) The diameter of a circular cross-section (rods). mm (millimeters) Varies widely (e.g., 3 – 100+)
Outer Diameter (OD) The total diameter of a hollow circular cross-section (tubes, pipes). mm (millimeters) Varies widely (e.g., 10 – 300+)
Inner Diameter (ID) The internal diameter of a hollow circular cross-section. mm (millimeters) Derived from OD and Wall Thickness, or NPS/Schedule.
Leg A Size Length of one leg of an angle profile. mm (millimeters) Varies (e.g., 20 – 150+)
Leg B Size Length of the other leg of an angle profile. mm (millimeters) Varies (e.g., 20 – 150+)
NPS Nominal Pipe Size – a standard designation for pipe size. Inches (converted internally) Common sizes like 1/2″, 1″, 2″, 4″ etc.
Schedule Indicates wall thickness for pipes. N/A e.g., Sch 10, Sch 40, Sch 80
ρ (Density) Mass per unit volume of 304 stainless steel. g/cm³ or kg/m³ (converted internally) Typically 8.0 g/cm³ (or 8000 kg/m³)
Volume (V) The amount of space the component occupies. cm³ or m³ (calculated internally) Depends on dimensions.

The calculator converts all input dimensions to millimeters (mm) for consistency, calculates the volume in cubic millimeters (mm³), and then converts this to cubic centimeters (cm³) for multiplication with the standard density in g/cm³ to yield weight in grams, which is then converted to kilograms (kg) for a more practical unit.

Practical Examples (Real-World Use Cases)

Example 1: Calculating Weight of a Stainless Steel Sheet

A workshop needs to fabricate a custom cover plate from 304 stainless steel. They have a sheet with the following dimensions:

  • Shape: Sheet/Plate
  • Length: 1500 mm
  • Width: 500 mm
  • Thickness: 3 mm

Calculator Inputs:

  • Shape: Sheet/Plate
  • Length: 1500 mm
  • Width: 500 mm
  • Thickness: 3 mm

Calculator Outputs:

  • Volume: 2,250,000 mm³ (or 2250 cm³)
  • Density: 8.00 g/cm³
  • Weight: 18.00 kg

Interpretation: This 1.5m x 0.5m sheet of 3mm 304 stainless steel weighs approximately 18 kilograms. This information is crucial for the purchasing department to order the correct amount of material and for the fabrication team to plan handling and cutting processes.

Example 2: Calculating Weight of a Stainless Steel Pipe Section

A chemical processing plant requires a 2-meter section of 304 stainless steel pipe for a fluid transfer line. The specifications are:

  • Shape: Pipe (Round)
  • Nominal Pipe Size (NPS): 1 1/2″
  • Pipe Schedule: Sch 40
  • Length: 2000 mm

Calculator Inputs:

  • Shape: Pipe (Round)
  • Nominal Pipe Size (NPS): 1 1/2″
  • Pipe Schedule: Sch 40
  • Length: 2000 mm

Calculator Outputs:

  • Outer Diameter: ~48.26 mm (derived from NPS 1 1/2″)
  • Wall Thickness: ~3.73 mm (derived from Sch 40 for 1 1/2″ NPS)
  • Inner Diameter: ~40.80 mm
  • Volume: ~2,597,700 mm³ (or 2597.7 cm³)
  • Density: 8.00 g/cm³
  • Weight: ~20.78 kg

Interpretation: A 2-meter length of 1 1/2″ Schedule 40 304 stainless steel pipe weighs approximately 20.78 kg. This detailed calculation ensures that structural supports are adequately sized, shipping costs are accurately estimated, and the correct quantity is ordered from the supplier.

How to Use This 304 Stainless Steel Weight Calculator

Using our 304 stainless steel weight calculator is straightforward. Follow these steps to get your accurate weight estimation:

  1. Select Component Shape: Choose the correct shape of your 304 stainless steel component from the dropdown menu (Sheet/Plate, Rod/Bar, Tube, Pipe, Angle Iron).
  2. Input Dimensions: Based on the selected shape, enter the relevant dimensions. Ensure you are using the correct units, which are specified as millimeters (mm) for all length, width, thickness, and diameter inputs. For pipe, select the Nominal Pipe Size (NPS) and Schedule.
  3. Review Intermediate Results: As you input dimensions, the calculator will update intermediate values like Volume and Density, providing transparency into the calculation process.
  4. View Primary Result: The main result, the estimated weight of your 304 stainless steel component in kilograms (kg), will be prominently displayed.
  5. Check Assumptions: Review the assumed density of 304 stainless steel used in the calculation (typically 8.0 g/cm³ or 8000 kg/m³).
  6. Copy or Reset: Use the "Copy Results" button to easily transfer the calculation details. If you need to perform a new calculation, click "Reset" to clear all fields and start over.

How to Read Results

The calculator provides:

  • Volume: The calculated geometric volume of the component in cubic millimeters (mm³) and cubic centimeters (cm³).
  • Density: The standard density value used for 304 stainless steel (8.0 g/cm³).
  • Weight: The final estimated weight of the component in kilograms (kg). This is the most critical output for material procurement and logistics.

Decision-Making Guidance

The calculated weight is vital for:

  • Budgeting: Knowing the exact weight helps in estimating the cost of raw materials.
  • Material Sourcing: Ensures you order the precise quantity required, minimizing waste and excess inventory.
  • Logistics Planning: Essential for determining shipping methods, vehicle capacity, and associated costs.
  • Structural Design: Engineers use weight calculations to ensure structures can safely support the load.

Key Factors That Affect 304 Stainless Steel Weight Results

While our calculator provides accurate estimations based on standard values, several factors can subtly influence the actual weight of 304 stainless steel components:

  1. Material Density Variations: Although 8.0 g/cm³ is the standard density for 304 stainless steel, slight variations can occur due to minor differences in alloy composition or manufacturing processes between different mills. This is a minor factor for most applications.
  2. Dimensional Tolerances: Real-world manufacturing doesn't achieve perfect dimensions. Slight deviations from the specified length, width, thickness, or diameter (within industry tolerances) will affect the final volume and thus the weight. Our calculator assumes exact dimensions.
  3. Surface Finish and Coatings: While generally negligible, significant surface treatments or coatings (like passivation layers or specialized finishes) could add a minuscule amount of weight. However, these are typically insignificant compared to the base material weight.
  4. Geometric Complexity: For components with intricate shapes (holes, cutouts, complex curves), the calculator's basic formulas might need to be applied piecewise to different sections or the overall volume calculation might be an approximation. Our calculator uses standard geometric formulas.
  5. Temperature Effects: Material density can change slightly with extreme temperature fluctuations. Stainless steel expands when heated and contracts when cooled. However, for typical ambient temperature calculations, this effect is negligible and not factored into standard weight calculations.
  6. Inclusions or Voids: Though rare in quality-controlled stainless steel, internal voids or non-metallic inclusions could slightly reduce the overall effective density and thus the weight.
  7. Cut Length Accuracy: When ordering or fabricating, the exact length cut can vary slightly. For long pieces, even a small difference in millimeters can add up to a noticeable weight difference.
  8. Wall Thickness Consistency (for Tubes/Pipes): While schedules define minimum wall thickness, actual thickness can vary slightly across the circumference and along the length. This impacts the internal diameter and thus the volume calculation for hollow sections.

For most engineering and procurement purposes, the results from this calculator are highly reliable. However, for extremely critical applications where every gram matters, a direct weighing of the final component is the ultimate verification.

Frequently Asked Questions (FAQ)

  • What is the density of 304 stainless steel used in this calculator? The calculator uses a standard density of 8.0 grams per cubic centimeter (g/cm³), which is equivalent to 8000 kilograms per cubic meter (kg/m³) or approximately 0.289 pounds per cubic inch (lb/in³). This is a widely accepted average value for 304 stainless steel.
  • What units does the calculator use for input and output? Input dimensions (length, width, thickness, diameter) should be provided in millimeters (mm). The output weight is provided in kilograms (kg). Intermediate volume is shown in mm³ and cm³.
  • Can this calculator be used for other stainless steel grades? This calculator is specifically calibrated for 304 stainless steel. Other grades (like 316, 430) have slightly different densities. For those, you would need a calculator specific to that grade or adjust the density input if the calculator allowed it.
  • How accurate are the results? The accuracy depends on the precision of your input dimensions and the consistency of the material density. For standard industrial applications, the results are highly accurate. For highly precise scientific or aerospace applications, actual weighing might be required.
  • What does "NPS" and "Schedule" mean for pipes? NPS stands for Nominal Pipe Size, a set of standard dimensions for pipes used in industrial applications. Schedule (e.g., Sch 40, Sch 80) refers to the wall thickness of the pipe, which varies depending on the NPS to maintain pressure ratings. These are crucial for determining the pipe's actual outer and inner diameters and thus its weight.
  • Does the calculator account for cutouts or holes in the material? No, the calculator uses standard geometric formulas for solid shapes. For parts with significant cutouts or holes, you would need to calculate the volume of the removed material and subtract it from the total volume of the solid shape.
  • What is the difference between a tube and a pipe in the calculator? While both are hollow, "Pipe" often refers to standardized dimensions (NPS, Schedule) used in plumbing and fluid transport, whereas "Tube" typically has dimensions specified by exact Outer Diameter (OD) and Wall Thickness (WT), often used in structural or mechanical applications. Both are calculated using their respective OD, ID, and length.
  • Can I use this calculator for calculating the weight of a finished product made from 304 steel? Yes, provided you can accurately input the final dimensions of the finished product. It's ideal for estimating the raw material needed for fabrication, which directly relates to the final product's weight.

Related Tools and Internal Resources

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var density304 = 8.0; // g/cm³ var scaleFactorMMtoCM = 0.1; // 1 mm = 0.1 cm var scaleFactorMM3toCM3 = 0.001; // 1 mm³ = 0.001 cm³ var scaleFactorGramToKG = 0.001; // 1 gram = 0.001 kg function updateShapeInputs() { var shape = document.getElementById("shape").value; document.getElementById("sheetInputs").style.display = "none"; document.getElementById("rodInputs").style.display = "none"; document.getElementById("tubeInputs").style.display = "none"; document.getElementById("pipeInputs").style.display = "none"; document.getElementById("angleInputs").style.display = "none"; document.getElementById("shapeSpecificParam1Label").textContent = ""; document.getElementById("shapeSpecificParam2Label").textContent = ""; if (shape === "sheet") { document.getElementById("sheetInputs").style.display = "block"; document.getElementById("shapeSpecificParam1Label").textContent = "Length:"; document.getElementById("shapeSpecificParam2Label").textContent = "Width:"; } else if (shape === "rod") { document.getElementById("rodInputs").style.display = "block"; document.getElementById("shapeSpecificParam1Label").textContent = "Length:"; document.getElementById("shapeSpecificParam2Label").textContent = "Diameter:"; } else if (shape === "tube") { document.getElementById("tubeInputs").style.display = "block"; document.getElementById("shapeSpecificParam1Label").textContent = "Length:"; document.getElementById("shapeSpecificParam2Label").textContent = "Outer Diameter:"; } else if (shape === "pipe") { document.getElementById("pipeInputs").style.display = "block"; document.getElementById("shapeSpecificParam1Label").textContent = "Length:"; document.getElementById("shapeSpecificParam2Label").textContent = "Nominal Pipe Size:"; } else if (shape === "angle") { document.getElementById("angleInputs").style.display = "block"; document.getElementById("shapeSpecificParam1Label").textContent = "Length:"; document.getElementById("shapeSpecificParam2Label").textContent = "Leg A Size:"; } calculateWeight(); // Recalculate after changing shape } // Function to get pipe dimensions from NPS and Schedule function getPipeDimensions(nps, schedule) { var dimensions = { outerDiameter: 0, // mm wallThickness: 0 // mm }; var npsMap = { "1/2": { od_inch: 0.840, wall_sch40_inch: 0.109, wall_sch80_inch: 0.147, wall_sch10_inch: 0.065, wall_sch160_inch: 0.187 }, "3/4": { od_inch: 1.050, wall_sch40_inch: 0.113, wall_sch80_inch: 0.154, wall_sch10_inch: 0.065, wall_sch160_inch: 0.218 }, "1": { od_inch: 1.315, wall_sch40_inch: 0.133, wall_sch80_inch: 0.179, wall_sch10_inch: 0.065, wall_sch160_inch: 0.250 }, "1 1/4": { od_inch: 1.660, wall_sch40_inch: 0.140, wall_sch80_inch: 0.200, wall_sch10_inch: 0.065, wall_sch160_inch: 0.273 }, "1 1/2": { od_inch: 1.900, wall_sch40_inch: 0.145, wall_sch80_inch: 0.200, wall_sch10_inch: 0.065, wall_sch160_inch: 0.280 }, "2": { od_inch: 2.375, wall_sch40_inch: 0.154, wall_sch80_inch: 0.218, wall_sch10_inch: 0.065, wall_sch160_inch: 0.307 }, "2 1/2": { od_inch: 2.875, wall_sch40_inch: 0.203, wall_sch80_inch: 0.276, wall_sch10_inch: 0.083, wall_sch160_inch: 0.375 }, "3": { od_inch: 3.500, wall_sch40_inch: 0.216, wall_sch80_inch: 0.300, wall_sch10_inch: 0.109, wall_sch160_inch: 0.432 }, "4": { od_inch: 4.500, wall_sch40_inch: 0.237, wall_sch80_inch: 0.337, wall_sch10_inch: 0.120, wall_sch160_inch: 0.531 } }; var scheduleMap = { "Sch10": "wall_sch10_inch", "Sch40": "wall_sch40_inch", "Sch80": "wall_sch80_inch", "Sch160": "wall_sch160_inch" }; var npsData = npsMap[nps]; var scheduleKey = scheduleMap[schedule]; if (npsData && scheduleKey) { dimensions.outerDiameter = npsData.od_inch * 25.4; // Convert inch to mm dimensions.wallThickness = npsData[scheduleKey] * 25.4; // Convert inch to mm } else { // Fallback or error handling if NPS/Schedule is invalid console.error("Invalid NPS or Schedule provided."); } return dimensions; } function validateInput(value, id, min, max, label, isRequired = true) { var errorElement = document.getElementById(id + "Error"); errorElement.textContent = ""; // Clear previous error if (isRequired && (value === null || value === "")) { errorElement.textContent = label + " is required."; return false; } if (value === "") return true; // If optional and empty, it's valid var numValue = parseFloat(value); if (isNaN(numValue)) { errorElement.textContent = label + " must be a number."; return false; } if (min !== undefined && numValue max) { errorElement.textContent = label + " cannot be greater than " + max + "."; return false; } if (numValue <= 0 && label !== "Wall Thickness" && label !== "Thickness") { // Allow 0 for thickness in some contexts but not others errorElement.textContent = label + " must be a positive value."; return false; } if (label === "Thickness" && numValue <= 0) { errorElement.textContent = label + " must be a positive value."; return false; } if (label === "Wall Thickness" && numValue <= 0) { errorElement.textContent = label + " must be a positive value."; return false; } return true; } function calculateWeight() { // Clear all previous errors var errorElements = document.querySelectorAll('.error-message'); for (var i = 0; i < errorElements.length; i++) { errorElements[i].textContent = ''; } var shape = document.getElementById("shape").value; var volume = 0; var weight = 0; var shapeSpecificParam1Value = null; var shapeSpecificParam2Value = null; var shapeSpecificParam2Label = ""; var isValid = true; // — Input Validation and Value Retrieval — if (shape === "sheet") { var length = document.getElementById("sheetLength").value; var width = document.getElementById("sheetWidth").value; var thickness = document.getElementById("sheetThickness").value; if (!validateInput(length, "sheetLength", 0.1, 10000, "Length")) isValid = false; if (!validateInput(width, "sheetWidth", 0.1, 10000, "Width")) isValid = false; if (!validateInput(thickness, "sheetThickness", 0.01, 1000, "Thickness")) isValid = false; if (isValid) { shapeSpecificParam1Value = parseFloat(length); shapeSpecificParam2Value = parseFloat(width); shapeSpecificParam2Label = "Width:"; var vol_mm3 = parseFloat(length) * parseFloat(width) * parseFloat(thickness); volume = vol_mm3 * scaleFactorMM3toCM3; // Convert to cm³ } } else if (shape === "rod") { var length = document.getElementById("rodLength").value; var diameter = document.getElementById("rodDiameter").value; if (!validateInput(length, "rodLength", 0.1, 10000, "Length")) isValid = false; if (!validateInput(diameter, "rodDiameter", 0.1, 1000, "Diameter")) isValid = false; if (isValid) { shapeSpecificParam1Value = parseFloat(length); shapeSpecificParam2Value = parseFloat(diameter); shapeSpecificParam2Label = "Diameter:"; var radius_mm = parseFloat(diameter) / 2; var vol_mm3 = Math.PI * Math.pow(radius_mm, 2) * parseFloat(length); volume = vol_mm3 * scaleFactorMM3toCM3; } } else if (shape === "tube") { var length = document.getElementById("tubeLength").value; var outerDiameter = document.getElementById("tubeOuterDiameter").value; var wallThickness = document.getElementById("tubeWallThickness").value; if (!validateInput(length, "tubeLength", 0.1, 10000, "Length")) isValid = false; if (!validateInput(outerDiameter, "tubeOuterDiameter", 1, 1000, "Outer Diameter")) isValid = false; if (!validateInput(wallThickness, "tubeWallThickness", 0.1, 1000, "Wall Thickness")) isValid = false; if (isValid) { shapeSpecificParam1Value = parseFloat(length); shapeSpecificParam2Value = parseFloat(outerDiameter); shapeSpecificParam2Label = "Outer Diameter:"; var outerRadius_mm = parseFloat(outerDiameter) / 2; var innerRadius_mm = outerRadius_mm – parseFloat(wallThickness); if (innerRadius_mm <= 0) { document.getElementById("tubeWallThicknessError").textContent = "Wall thickness cannot be greater than or equal to the outer diameter."; isValid = false; } else { var vol_mm3 = Math.PI * (Math.pow(outerRadius_mm, 2) – Math.pow(innerRadius_mm, 2)) * parseFloat(length); volume = vol_mm3 * scaleFactorMM3toCM3; } } } else if (shape === "pipe") { var length = document.getElementById("pipeLength").value; var nps = document.getElementById("pipeNominalSize").value; var schedule = document.getElementById("pipeSchedule").value; if (!validateInput(length, "pipeLength", 0.1, 10000, "Length")) isValid = false; // NPS and Schedule are select, so always valid if present if (isValid) { var pipeDims = getPipeDimensions(nps, schedule); var outerDiameter = pipeDims.outerDiameter; var wallThickness = pipeDims.wallThickness; var innerDiameter = outerDiameter – (2 * wallThickness); shapeSpecificParam1Value = parseFloat(length); shapeSpecificParam2Value = nps + " (Sch " + schedule + ")"; // Display NPS and Schedule combined shapeSpecificParam2Label = "Nominal Pipe Size & Schedule:"; if (outerDiameter === 0 || wallThickness === 0) { // Error handled within getPipeDimensions or implies invalid selection isValid = false; } else if (innerDiameter <= 0) { document.getElementById("pipeScheduleError").textContent = "Invalid NPS/Schedule combination resulting in non-positive inner diameter."; isValid = false; } else { var outerRadius_mm = outerDiameter / 2; var innerRadius_mm = innerDiameter / 2; var vol_mm3 = Math.PI * (Math.pow(outerRadius_mm, 2) – Math.pow(innerRadius_mm, 2)) * parseFloat(length); volume = vol_mm3 * scaleFactorMM3toCM3; } } } else if (shape === "angle") { var length = document.getElementById("angleLength").value; var legA = document.getElementById("angleLegA").value; var legB = document.getElementById("angleLegB").value; var thickness = document.getElementById("angleThickness").value; if (!validateInput(length, "angleLength", 0.1, 10000, "Length")) isValid = false; if (!validateInput(legA, "angleLegA", 1, 1000, "Leg A Size")) isValid = false; if (!validateInput(legB, "angleLegB", 1, 1000, "Leg B Size")) isValid = false; if (!validateInput(thickness, "angleThickness", 0.1, 1000, "Thickness")) isValid = false; if (isValid) { shapeSpecificParam1Value = parseFloat(length); shapeSpecificParam2Value = parseFloat(legA); shapeSpecificParam2Label = "Leg A Size:"; // Area of the angle cross-section = (LegA + LegB – Thickness) * Thickness var area_mm2 = (parseFloat(legA) + parseFloat(legB) – parseFloat(thickness)) * parseFloat(thickness); var vol_mm3 = area_mm2 * parseFloat(length); volume = vol_mm3 * scaleFactorMM3toCM3; } } // — Calculation and Display — if (isValid) { weight = volume * density304; // weight in grams // Update intermediate results document.getElementById("volumeOutput").textContent = volume.toFixed(2) + " cm³"; document.getElementById("densityOutput").textContent = density304.toFixed(2) + " g/cm³"; // Update primary result document.getElementById("weightResult").textContent = weight.toFixed(2) + " kg"; // Update assumption values document.getElementById("assumptionDensityOutput").textContent = density304.toFixed(2) + " g/cm³"; document.getElementById("assumptionUnitOutput").textContent = "Inputs: mm, Output: kg"; // Update shape-specific parameters labels and values var shapeParam1LabelElem = document.getElementById("shapeSpecificParam1Label"); var shapeParam2LabelElem = document.getElementById("shapeSpecificParam2Label"); if (shape === "sheet") { shapeParam1LabelElem.textContent = "Length:"; document.getElementById("shapeSpecificParam1Output").textContent = parseFloat(length).toFixed(0) + " mm"; shapeParam2LabelElem.textContent = "Width:"; document.getElementById("shapeSpecificParam2Output").textContent = parseFloat(width).toFixed(0) + " mm"; } else if (shape === "rod") { shapeParam1LabelElem.textContent = "Length:"; document.getElementById("shapeSpecificParam1Output").textContent = parseFloat(length).toFixed(0) + " mm"; shapeParam2LabelElem.textContent = "Diameter:"; document.getElementById("shapeSpecificParam2Output").textContent = parseFloat(diameter).toFixed(1) + " mm"; } else if (shape === "tube") { shapeParam1LabelElem.textContent = "Length:"; document.getElementById("shapeSpecificParam1Output").textContent = parseFloat(length).toFixed(0) + " mm"; shapeParam2LabelElem.textContent = "Outer Diameter:"; document.getElementById("shapeSpecificParam2Output").textContent = parseFloat(outerDiameter).toFixed(1) + " mm"; } else if (shape === "pipe") { shapeParam1LabelElem.textContent = "Length:"; document.getElementById("shapeSpecificParam1Output").textContent = parseFloat(length).toFixed(0) + " mm"; shapeParam2LabelElem.textContent = "Nominal Pipe Size & Schedule:"; document.getElementById("shapeSpecificParam2Output").textContent = nps + " (Sch " + schedule + ")"; } else if (shape === "angle") { shapeParam1LabelElem.textContent = "Length:"; document.getElementById("shapeSpecificParam1Output").textContent = parseFloat(length).toFixed(0) + " mm"; shapeParam2LabelElem.textContent = "Leg A Size:"; document.getElementById("shapeSpecificParam2Output").textContent = parseFloat(legA).toFixed(1) + " mm"; // Add Leg B and Thickness as additional intermediate outputs if needed if (!document.getElementById("angleLegBResult")) { var legBResultDiv = document.createElement("div"); legBResultDiv.id = "angleLegBResult"; legBResultDiv.innerHTML = "Leg B Size:"; document.querySelector(".intermediate-results").insertBefore(legBResultDiv, document.querySelector(".intermediate-results div:last-child")); } document.getElementById("angleLegBOutput").textContent = parseFloat(legB).toFixed(1) + " mm"; if (!document.getElementById("angleThicknessResult")) { var thicknessResultDiv = document.createElement("div"); thicknessResultDiv.id = "angleThicknessResult"; thicknessResultDiv.innerHTML = "Thickness:"; document.querySelector(".intermediate-results").insertBefore(thicknessResultDiv, document.querySelector(".intermediate-results div:last-child")); } document.getElementById("angleThicknessOutput").textContent = parseFloat(thickness).toFixed(1) + " mm"; } else { // Clear extra fields if not angle if (document.getElementById("angleLegBResult")) document.getElementById("angleLegBResult").remove(); if (document.getElementById("angleThicknessResult")) document.getElementById("angleThicknessResult").remove(); } updateChart(); // Update the chart with new data } else { // Reset results if validation failed document.getElementById("volumeOutput").textContent = "–"; document.getElementById("densityOutput").textContent = "–"; document.getElementById("weightResult").textContent = "–"; document.getElementById("shapeSpecificParam1Output").textContent = "–"; document.getElementById("shapeSpecificParam2Output").textContent = "–"; document.getElementById("assumptionDensityOutput").textContent = "–"; document.getElementById("assumptionUnitOutput").textContent = "–"; if (document.getElementById("angleLegBResult")) document.getElementById("angleLegBResult").remove(); if (document.getElementById("angleThicknessResult")) document.getElementById("angleThicknessResult").remove(); } } function resetCalculator() { document.getElementById("shape").value = "sheet"; document.getElementById("sheetLength").value = "1200"; document.getElementById("sheetWidth").value = "600"; document.getElementById("sheetThickness").value = "2"; document.getElementById("rodLength").value = "1000"; document.getElementById("rodDiameter").value = "10"; document.getElementById("tubeLength").value = "1000"; document.getElementById("tubeOuterDiameter").value = "25"; document.getElementById("tubeWallThickness").value = "1.5"; document.getElementById("pipeNominalSize").value = "1"; document.getElementById("pipeSchedule").value = "Sch40"; document.getElementById("pipeLength").value = "1000"; document.getElementById("angleLength").value = "1000"; document.getElementById("angleLegA").value = "50"; document.getElementById("angleLegB").value = "50"; document.getElementById("angleThickness").value = "5"; updateShapeInputs(); // Update display based on reset shape calculateWeight(); // Recalculate results } function copyResults() { var shape = document.getElementById("shape").value; var shapeName = shape.charAt(0).toUpperCase() + shape.slice(1); if (shapeName === "Sheet") shapeName = "Sheet/Plate"; if (shapeName === "Rod") shapeName = "Rod/Bar"; if (shapeName === "Tube") shapeName = "Tube (Round)"; if (shapeName === "Pipe") shapeName = "Pipe (Round)"; if (shapeName === "Angle") shapeName = "Angle Iron"; var length = ""; var width = ""; var thickness = ""; var diameter = ""; var outerDiameter = ""; var wallThickness = ""; var nps = ""; var schedule = ""; var legA = ""; var legB = ""; if (shape === "sheet") { length = document.getElementById("sheetLength").value; width = document.getElementById("sheetWidth").value; thickness = document.getElementById("sheetThickness").value; } else if (shape === "rod") { length = document.getElementById("rodLength").value; diameter = document.getElementById("rodDiameter").value; } else if (shape === "tube") { length = document.getElementById("tubeLength").value; outerDiameter = document.getElementById("tubeOuterDiameter").value; wallThickness = document.getElementById("tubeWallThickness").value; } else if (shape === "pipe") { length = document.getElementById("pipeLength").value; nps = document.getElementById("pipeNominalSize").value; schedule = document.getElementById("pipeSchedule").value; } else if (shape === "angle") { length = document.getElementById("angleLength").value; legA = document.getElementById("angleLegA").value; legB = document.getElementById("angleLegB").value; thickness = document.getElementById("angleThickness").value; } var volume = document.getElementById("volumeOutput").textContent; var density = document.getElementById("densityOutput").textContent; var weight = document.getElementById("weightResult").textContent; var assumptionDensity = document.getElementById("assumptionDensityOutput").textContent; var assumptionUnits = document.getElementById("assumptionUnitOutput").textContent; var resultString = "— 304 Stainless Steel Weight Calculation —\n\n"; resultString += "Shape: " + shapeName + "\n"; if (length) resultString += "Length: " + length + " mm\n"; if (width) resultString += "Width: " + width + " mm\n"; if (thickness) resultString += "Thickness: " + thickness + " mm\n"; if (diameter) resultString += "Diameter: " + diameter + " mm\n"; if (outerDiameter) resultString += "Outer Diameter: " + outerDiameter + " mm\n"; if (wallThickness) resultString += "Wall Thickness: " + wallThickness + " mm\n"; if (legA) resultString += "Leg A Size: " + legA + " mm\n"; if (legB) resultString += "Leg B Size: " + legB + " mm\n"; if (nps) resultString += "Nominal Pipe Size (NPS): " + nps + "\n"; if (schedule) resultString += "Pipe Schedule: " + schedule + "\n"; resultString += "\n— Results —\n"; resultString += "Calculated Volume: " + volume + "\n"; resultString += "Material Density: " + density + "\n"; resultString += "Estimated Weight: " + weight + "\n"; resultString += "\n— Assumptions —\n"; resultString += "Density Used: " + assumptionDensity + "\n"; resultString += "Units: " + assumptionUnits + "\n"; try { navigator.clipboard.writeText(resultString).then(function() { // Optional: Show a confirmation message var originalText = this.textContent; this.textContent = 'Copied!'; setTimeout(function() { this.textContent = originalText; }.bind(this), 1500); }.bind(arguments.callee.caller.arguments[0].target)).catch(function(err) { console.error('Failed to copy text: ', err); alert('Failed to copy results. Please copy manually.'); }); } catch (e) { console.error('Clipboard API not available: ', e); alert('Clipboard API not available. Please copy results manually.'); } } // — Charting — var chartContext; var weightChart; function setupChart() { var ctx = document.getElementById('weightChart').getContext('2d'); chartContext = ctx; weightChart = new Chart(ctx, { type: 'bar', // Changed to bar for better comparison data: { labels: ['Volume (cm³)', 'Weight (kg)'], datasets: [{ label: 'Calculated Values', data: [0, 0], // Initial data backgroundColor: [ 'rgba(0, 74, 153, 0.6)', // Primary color for Volume 'rgba(40, 167, 69, 0.6)' // Success color for Weight ], borderColor: [ 'rgba(0, 74, 153, 1)', 'rgba(40, 167, 69, 1)' ], borderWidth: 1 }] }, options: { responsive: true, maintainAspectRatio: false, scales: { y: { beginAtZero: true, ticks: { callback: function(value) { if (value % 1 === 0) { // Display integers nicely return value; } else { return value.toFixed(2); // Display decimals with 2 places } } } } }, plugins: { title: { display: true, text: 'Volume vs. Estimated Weight', font: { size: 16 } }, legend: { display: false // Hiding legend as labels are on the axis } } } }); } function updateChart() { if (!weightChart) { setupChart(); } var volumeCm3 = parseFloat(document.getElementById("volumeOutput").textContent.replace(" cm³", "")); var weightKg = parseFloat(document.getElementById("weightResult").textContent.replace(" kg", "")); if (isNaN(volumeCm3)) volumeCm3 = 0; if (isNaN(weightKg)) weightKg = 0; weightChart.data.datasets[0].data = [volumeCm3, weightKg]; weightChart.update(); } // Initial setup document.addEventListener("DOMContentLoaded", function() { updateShapeInputs(); // Set initial shape display calculateWeight(); // Calculate initial results setupChart(); // Setup chart on initial load });

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