How to Test Load Cells: A Comprehensive Guide

Electronic force measuring systems are the backbone of countless industries, ensuring precision in commerce, trade, and manufacturing. At the heart of these systems lies the load cell—a critical component that must remain accurate and reliable to maintain operational efficiency. Whether as part of routine maintenance or in response to performance issues, understanding how to test a load cell is essential for making informed decisions about repairs or replacements.

Why Do Load Cells Fail?

Load cells operate by converting force into electrical signals, which are then processed by control devices like amplifiers or tension control units. These signals are displayed as numeric values on digital indicators, providing precise measurements. However, the environments in which load cells function can be demanding, exposing them to conditions that may compromise their performance.

Common Causes of Load Cell Failure:

• Overloading: Exceeding the scale’s capacity can deform the load cell or cause shock loading.
• Power Surges: Electrical surges can disrupt the load cell’s functionality.
• Environmental Factors: Moisture, chemical spills, or other contaminants can infiltrate the system and cause damage.

Signs of Load Cell Malfunction:

• Inability to reset or calibrate
• Inconsistent or unreliable readings
• Failure to register weights or tension
• Random zero balance drifts
• Complete loss of readings

Troubleshooting Load Cells

When a load cell system behaves erratically, start by inspecting for physical damage or obvious issues. Check for worn cables, loose connections, or faulty wiring to the tension indicator panel. If these checks don’t resolve the issue, proceed with diagnostic testing using a high-quality digital multimeter (minimum 4.5-digit resolution). Key tests include:

1. Zero Balance Test
2. Insulation Resistance Test
3. Bridge Integrity Test

1. Zero Balance Test

This test identifies physical damage such as overloads, shock loads, or material fatigue. Follow these steps:

• Ensure the load cell is in a “no load” condition.
• Connect the input terminals to an excitation or input voltage.
• Measure the output voltage using a millivoltmeter.
• Divide the output voltage by the input voltage to calculate the zero balance in mV/V.
• Compare the result to the original calibration certificate or datasheet. A mismatch indicates damage to the load cell.

2. Insulation Resistance Test

This test checks for electrical leakage caused by moisture or corrosion:

• Disconnect the load cell from the junction box and connect all leads (input and output) together.
• Use a megohmmeter to measure insulation resistance between:
  • The connected leads and the load cell body
  • The cable shield and the load cell body
  • The cable shield and the connected leads
• Readings should exceed 5000 MΩ. Lower values suggest electrical leakage, while extremely low readings indicate a short circuit.

3. Bridge Integrity Test

This test evaluates the input and output resistance of the load cell:

• Use an ohmmeter to measure resistance across input and output leads.
• Compare the results to the original datasheet specifications.
• The difference between input and output resistance should not exceed 5 Ω. Larger discrepancies may indicate broken or shorted wires caused by shock loads, vibration, or extreme temperatures.

4. Shock Resistance Test

To test shock resistance:

• Connect the load cell to a stable power supply and monitor the output with a voltmeter.
• Gently apply a mild shock load to the load cell or roller.
• Observe the readings for stability and ensure they return to the original zero balance. Erratic readings may point to failed electrical connections or damage to the strain gauge adhesive layer.

Conclusion

Load cells are indispensable for accurate force measurement, but their reliability depends on regular testing and maintenance. By performing these diagnostic tests, you can quickly identify issues and determine whether to repair or replace the load cell. A proactive approach to load cell testing ensures your systems remain efficient and dependable, minimizing downtime and maximizing performance.