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Trial Weight Calculation Balancing Calculator

Single-plane static and dynamic balancing tool for rotating machinery maintenance.

Step 1: Initial Vibration Measurement (Run 1)

Initial Amplitude (Units: mils, mm/s, or IPS)

Vibration magnitude before adding weights.

Please enter a positive number.

Initial Phase Angle (Degrees)

Measured phase angle (0-360°).

Step 2: Trial Weight Parameters

Trial Weight Mass (grams or oz)

Mass of the test weight added to the rotor.

Weight must be positive.

Trial Weight Angle (Degrees)

Location where the trial weight was attached.

Step 3: Vibration with Trial Weight (Run 2)

Resulting Amplitude

Vibration magnitude after adding trial weight.

Please enter a positive number.

Resulting Phase Angle (Degrees)

New phase angle (0-360°).

Required Correction Weight

0.00 units @ 0°

(Add this weight to balance the rotor)

Influence Coefficient

0.00 / unit

Effect Vector Magnitude

0.00

Effect Vector Angle

0°

Formula: Correction = -(Initial Vector) / (Influence Vector)

Vector Diagram (Polar Plot)

Blue: Initial Vib | Red: With Trial Weight | Green: Correction Location

Table 1: Detailed breakdown of the single-plane balancing vectors used in the trial weight calculation balancing process.
Parameter	Magnitude	Angle (Phase)
Initial Vibration (O)	–	–
Vibration with Trial (O+T)	–	–
Trial Weight (T)	–	–
Calculated Correction	–	–

What is Trial Weight Calculation Balancing?

Trial weight calculation balancing is a fundamental procedure in vibration analysis and mechanical maintenance used to correct mass imbalances in rotating machinery. It involves the "Influence Coefficient Method," where a known weight (trial weight) is added to a rotor to observe how the system responds. By comparing the initial vibration vector to the vibration vector after adding the weight, technicians can mathematically derive the exact mass and angular location needed to counteract the inherent imbalance.

This method is critical for facility managers and reliability engineers. Unbalanced rotors cause excessive vibration, leading to bearing failure, structural fatigue, and energy inefficiency. This process is commonly applied to industrial fans, blowers, cooling towers, and electric motors.

Trial Weight Calculation Balancing Formula and Mathematical Explanation

The mathematics behind trial weight calculation balancing relies on vector algebra using polar coordinates. Vibration measurements consist of an amplitude (how rough it is) and a phase angle (where the heavy spot is).

The process solves for the "Influence Vector" ($H$), which represents the system's sensitivity to unbalance.

The Core Formulas:

Vector O (Original): Initial vibration reading.
Vector O+T (Combined): Vibration reading with trial weight.
Vector T (Trial): The trial weight vector (mass and angle).
Effect Vector (E): $E = (O+T) – O$ (Vector Subtraction). This represents the vibration caused purely by the trial weight.
Influence Coefficient (H): $H = E / T$ (Vector Division). This tells us how much vibration 1 unit of weight causes at 0 degrees.
Correction Vector (C): $C = -O / H$. The weight needed to create a vibration equal and opposite to the original unbalance.

Table 2: Key variables in the single-plane balancing equation.
Variable	Meaning	Common Units	Typical Range
$A_o$	Initial Vibration Amplitude	mils, mm/s, IPS	0.01 – 10.0+
$\theta_o$	Initial Phase Angle	Degrees	0° – 360°
$W_t$	Trial Weight Mass	grams, oz	Depends on rotor size
$H$	Influence Coefficient	Vib Unit / Mass Unit	System dependent

Practical Examples (Real-World Use Cases)

Example 1: Industrial Exhaust Fan

A maintenance technician measures an exhaust fan vibrating at 5.5 mils at 120°. To balance it, they attach a 10 gram trial weight at 45°. The new vibration reading is 3.2 mils at 90°.

Using the trial weight calculation balancing method, the calculator determines the effect of that 10g weight. The logic subtracts the initial vector from the second vector to isolate the trial weight's effect. The final result indicates a correction weight of approximately 7.4 grams at 285° is required to nullify the original vibration.

Example 2: Cooling Tower Driveshaft

A driveshaft shows 0.8 IPS at 30°. A trial weight of 50 grams is added at 180°. The vibration shifts to 0.6 IPS at 150°.

The significant shift in phase angle indicates the trial weight was effective. The calculation reveals the system is sensitive, and the correction weight will likely be smaller than the trial weight but placed at a different angle relative to the heavy spot.

How to Use This Trial Weight Calculation Balancing Calculator

Record Initial State: Measure the "As-Found" vibration amplitude and phase angle using your vibration analyzer/tachometer. Enter these into Step 1.
Install Trial Weight: Stop the machine and securely attach a trial weight of known mass at a known angle. Ensure safety protocols (Lock-out/Tag-out) are followed. Enter the mass and angle into Step 2.
Record Trial State: Restart the machine and measure the new vibration amplitude and phase. Enter these into Step 3.
Read Results: The calculator immediately provides the "Required Correction Weight" and angle.
Verify: Remove the trial weight, install the calculated correction weight, and run the machine again to verify vibration levels are within ISO tolerance.

Key Factors That Affect Trial Weight Calculation Balancing Results

To ensure accuracy when using trial weight calculation balancing, consider these factors:

Linearity of the System: The formula assumes the machine reacts linearly. If the stiffness changes with speed or amplitude (non-linear), the calculated correction may not be perfect.
Speed Stability: Readings must be taken at the exact same RPM for both runs. Even a 1% speed change can alter phase angles significantly near resonance.
Trial Weight Size: The trial weight must be heavy enough to change the vibration (amplitude or phase) by at least 30% or 30°, but not so heavy that it damages the machine.
Phase Angle Accuracy: Phase errors are the most common source of balancing failure. Ensure your tachometer trigger is stable and the reflective tape is clean.
External Vibration: Ensure no other machines are transmitting vibration to the unit being balanced, as this adds "noise" to the vector calculation.
Safety & Fastening: If a trial weight flies off, the calculation is void and safety is compromised. Always double-check mechanical fastening.

Frequently Asked Questions (FAQ)

What if the calculated weight is too heavy to install?

You can split the correction weight into two smaller weights placed at available locations, or drill out material at the opposite side (180° away) to achieve the same effect.

Can I use this for two-plane balancing?

No. This calculator is for single-plane balancing (static imbalance). Two-plane balancing requires cross-effect calculations and simultaneous readings at two bearings.

Why did my vibration increase after adding the correction weight?

This usually happens if the trial weight was not removed before adding the correction weight, or if the angle was measured in the wrong direction (against rotation vs. with rotation).

How large should the trial weight be?

A rule of thumb is $F = 1.77 \times (W/R)$, where F is force and W is rotor weight. Practically, try to generate a force equal to 10% of the rotor static weight.

Does the unit of measurement matter?

No, as long as you are consistent. If you use mils for amplitude, the result is based on mils. If you use grams for weight, the result is in grams.

What is the "Influence Coefficient"?

It is a vector describing how the rotor responds to unbalance. It defines how much vibration (amplitude and phase lag) is created per unit of mass.

What is a "dummy" trial weight?

Sometimes used in software to simulate a run, but for this physical calculator, you need real data from a physical trial run.

Is trial weight calculation balancing applicable to flexible rotors?

It is most effective for rigid rotors operating below their first critical speed. Flexible rotors often require multi-plane balancing.

Related Tools and Internal Resources

Single Plane Balancing Formula Guide – Deep dive into the vector math derivation.
Vibration Analysis Tools – Suite of calculators for frequency and harmonics.
Rotor Dynamics 101 – Understanding critical speeds and resonance.
Professional Balancing Services – When to call an expert for onsite balancing.
Industrial Maintenance Guide – Best practices for prolonged asset life.
Predictive Maintenance Software – Automate your vibration data collection.

// Helper: Convert Degrees to Radians function toRad(deg) { return deg * (Math.PI / 180); } // Helper: Convert Radians to Degrees function toDeg(rad) { var deg = rad * (180 / Math.PI); if (deg < 0) deg += 360; return deg % 360; } // Helper: Polar to Cartesian function polarToCart(r, thetaDeg) { var thetaRad = toRad(thetaDeg); return { x: r * Math.cos(thetaRad), y: r * Math.sin(thetaRad) }; } // Helper: Cartesian to Polar function cartToPolar(x, y) { var r = Math.sqrt(x*x + y*y); var thetaRad = Math.atan2(y, x); return { r: r, theta: toDeg(thetaRad) }; } function calculateBalancing() { // 1. Get Inputs var origAmp = parseFloat(document.getElementById('origAmp').value); var origPhase = parseFloat(document.getElementById('origPhase').value); var trialWeight = parseFloat(document.getElementById('trialWeight').value); var trialAngle = parseFloat(document.getElementById('trialAngle').value); var runAmp = parseFloat(document.getElementById('runAmp').value); var runPhase = parseFloat(document.getElementById('runPhase').value); // Validation var isValid = true; if (isNaN(origAmp) || origAmp < 0) { document.getElementById('err-origAmp').style.display = 'block'; isValid = false; } else { document.getElementById('err-origAmp').style.display = 'none'; } if (isNaN(trialWeight) || trialWeight <= 0) { document.getElementById('err-trialWeight').style.display = 'block'; isValid = false; } else { document.getElementById('err-trialWeight').style.display = 'none'; } if (isNaN(runAmp) || runAmp < 0) { document.getElementById('err-runAmp').style.display = 'block'; isValid = false; } else { document.getElementById('err-runAmp').style.display = 'none'; } if (!isValid) return; // 2. Logic Implementation (Vector Algebra) // Vector O (Original Vibration) var O = polarToCart(origAmp, origPhase); // Vector R (Run 2 Vibration = O + T_effect) var R = polarToCart(runAmp, runPhase); // Vector T (Trial Weight Location) – Note: This is the weight vector, not vibration // We use this to scale the influence. var T_weight = polarToCart(trialWeight, trialAngle); // Effect Vector E = R – O (Vector Subtraction) // This is the VIBRATION change caused by the trial weight var E = { x: R.x – O.x, y: R.y – O.y }; // Influence Coefficient H = E / T_weight (Complex Division) // H = (E_mag / T_mag) @ (E_angle – T_angle) var E_polar = cartToPolar(E.x, E.y); var H_mag = E_polar.r / trialWeight; var H_angle = E_polar.theta – trialAngle; // Correction Weight C = -O / H // C = (O_mag / H_mag) @ (O_angle – H_angle + 180) // The 180 comes from the negative sign var corr_mag = origAmp / H_mag; var corr_angle = origPhase – H_angle + 180; // Normalize angle corr_angle = (corr_angle % 360); if (corr_angle < 0) corr_angle += 360; // 3. Update UI document.getElementById('correctionResult').innerHTML = corr_mag.toFixed(2) + ' units @ ' + corr_angle.toFixed(0) + '°'; document.getElementById('influenceCoeff').innerHTML = H_mag.toFixed(3) + ' / unit'; document.getElementById('effectVector').innerHTML = E_polar.r.toFixed(2); document.getElementById('effectAngle').innerHTML = E_polar.theta.toFixed(0) + '°'; // Update Table document.getElementById('tblOrigAmp').innerText = origAmp; document.getElementById('tblOrigPhase').innerText = origPhase + '°'; document.getElementById('tblRunAmp').innerText = runAmp; document.getElementById('tblRunPhase').innerText = runPhase + '°'; document.getElementById('tblTrialWt').innerText = trialWeight; document.getElementById('tblTrialAng').innerText = trialAngle + '°'; document.getElementById('tblCorrWt').innerText = corr_mag.toFixed(2); document.getElementById('tblCorrAng').innerText = corr_angle.toFixed(0) + '°'; // 4. Update Chart drawChart(O, R, polarToCart(corr_mag, corr_angle)); } function drawChart(O, R, C) { var canvas = document.getElementById('vectorChart'); if (!canvas.getContext) return; var ctx = canvas.getContext('2d'); var w = canvas.width; var h = canvas.height; var cx = w / 2; var cy = h / 2; // Clear ctx.clearRect(0, 0, w, h); // Calculate Scale var maxVal = Math.max( Math.sqrt(O.x*O.x + O.y*O.y), Math.sqrt(R.x*R.x + R.y*R.y), Math.sqrt(C.x*C.x + C.y*C.y) / 2 // Scale correction down slightly visually if huge ); var scale = (w / 2 – 40) / (maxVal || 1); // Draw Grid ctx.beginPath(); ctx.strokeStyle = '#e0e0e0'; ctx.lineWidth = 1; ctx.arc(cx, cy, (w/2 – 40), 0, 2 * Math.PI); ctx.arc(cx, cy, (w/2 – 40) * 0.66, 0, 2 * Math.PI); ctx.arc(cx, cy, (w/2 – 40) * 0.33, 0, 2 * Math.PI); ctx.stroke(); // Draw Crosshairs ctx.beginPath(); ctx.moveTo(cx, 10); ctx.lineTo(cx, h-10); ctx.moveTo(10, cy); ctx.lineTo(w-10, cy); ctx.stroke(); // Function to draw vector function drawVector(x, y, color, label) { var screenX = cx + x * scale; var screenY = cy – y * scale; // Canvas Y is inverted ctx.beginPath(); ctx.strokeStyle = color; ctx.lineWidth = 3; ctx.moveTo(cx, cy); ctx.lineTo(screenX, screenY); ctx.stroke(); // Arrowhead var angle = Math.atan2(cy – screenY, screenX – cx); ctx.beginPath(); ctx.fillStyle = color; ctx.moveTo(screenX, screenY); ctx.lineTo(screenX – 10 * Math.cos(angle – Math.PI/6), screenY + 10 * Math.sin(angle – Math.PI/6)); ctx.lineTo(screenX – 10 * Math.cos(angle + Math.PI/6), screenY + 10 * Math.sin(angle + Math.PI/6)); ctx.fill(); // Label ctx.fillStyle = '#333'; ctx.font = '12px Arial'; ctx.fillText(label, screenX + 10, screenY); } drawVector(O.x, O.y, 'blue', 'Init (O)'); drawVector(R.x, R.y, 'red', 'Trial (R)'); // Correction vector (green) drawVector(C.x, C.y, 'green', 'Correction'); } function resetCalculator() { document.getElementById('origAmp').value = 5.5; document.getElementById('origPhase').value = 120; document.getElementById('trialWeight').value = 10; document.getElementById('trialAngle').value = 45; document.getElementById('runAmp').value = 3.2; document.getElementById('runPhase').value = 90; calculateBalancing(); } function copyResults() { var txt = "Trial Weight Balancing Results:\n"; txt += "Correction Weight: " + document.getElementById('correctionResult').innerText + "\n"; txt += "Influence Coeff: " + document.getElementById('influenceCoeff').innerText + "\n"; txt += "Inputs:\n"; txt += "Orig Vib: " + document.getElementById('origAmp').value + " @ " + document.getElementById('origPhase').value + " deg\n"; txt += "Trial Wt: " + document.getElementById('trialWeight').value + " @ " + document.getElementById('trialAngle').value + " deg\n"; txt += "Run 2 Vib: " + document.getElementById('runAmp').value + " @ " + document.getElementById('runPhase').value + " deg"; var tempInput = document.createElement("textarea"); tempInput.value = txt; document.body.appendChild(tempInput); tempInput.select(); document.execCommand("copy"); document.body.removeChild(tempInput); var btn = document.querySelector('.btn-copy'); var originalText = btn.innerText; btn.innerText = "Copied!"; setTimeout(function(){ btn.innerText = originalText; }, 2000); } // Init window.onload = function() { calculateBalancing(); };