Maintaining Backup Battery Systems for Maximum Usage and Reliability

maintaining-backup-battery-systems-for-maximum-usage-and-reliability

Fluke BT521 Battery Analyzer with lead probes

Standby battery backup systems play a critical role in keeping essential operations functional in the event of a utility outage.

Facilities like data centers, hospitals, airports, utilities, oil and gas facilities, and railways can’t operate without 100 percent backup power reliability. Even standard commercial and manufacturing facilities have backup power systems for their emergency systems, alarms and controls, emergency lighting, steam and fir control systems.

Most backup power systems use an uninterruptable power supply (UPS) and a string of batteries. The UPS backs up the digital control system (DCS) to keep control of plant operations until systems can be safely shut down or until the auxiliary generator kicks on.

Although most batteries used in modern day UPS systems are “maintenance free,” they are still susceptible to deterioration from corrosion, internal shorts, sulphation, dry-out, and seal failure. This article outlines best practices for keeping these “battery banks” at optimum performance, so that if an outage does occur, the backup is ready.

maintaining-backup-battery-systems-for-maximum-usage-and-reliability
Fluke BT521 Battery Analyzer with lead probes

Top two indicators of battery health

1. Internal battery resistance

Internal resistance is a life-span test, not a capacity test. Battery resistance stays relatively flat up until the end of life draws near. At that point, internal resistance increases and battery capacity decreases. Measuring and tracking this value helps identify when a battery needs replacing.

Only use a specialized battery tester designed to measure battery resistance while the battery is in service. Read the voltage drop on the load current (conductance) or the AC impedance. Both results will be in ohmic values.

A single ohmic measurement is of little value without context. Best practice requires measuring ohmic values over months and years, each time comparing them to previous values on record to create a base line.

2. Discharge testing

Discharge testing is the ultimate way to discover the true available capacity of a battery but can be complicated to perform. In discharge testing, a battery is connected to a load and discharged over a specified period. During this test period, current is regulated, and a constant known current is drawn while voltage is measured periodically. Details of the discharge current, the specified time period for discharge testing, and the capacity of the battery in ampere hours can be calculated and compared to the manufacturers’ specification. For example, a 12V 100-amp hour battery may require a discharge current of 12A for an eight-hour period. A 12V battery would be discharged when the terminal voltage is 10.5V.

Batteries cannot support critical loads during and immediately after a discharge test. Transfer critical loads to a different battery bank until well after the test is complete and then reconnect a temporary comparably sized load to the batteries under test. In addition, before conducting the test, prepare a cooling system to compensate for a rise in ambient temperature. When large batteries discharge, they release a significant amount of energy expended as heat.

Healthy batteries should maintain a capacity above 90% of the manufacturer’s rating; most manufacturers recommend replacing the battery if it falls below 80%. When conducting battery tests, look for these indicators of failure:

  • Drop in capacity of more than 10% compared to the baseline or previous measurement
  • 20% or more increase in impedance compared to baseline or previous
  • Sustained high temperatures, compared to baseline and manufacturer’s specs
  • Degradation in plate condition

How to conduct standard battery tests

  1. Float voltage
    • Isolate the battery or batteries from the charging system and the load.
    • Measure the individual cell voltage or string using a digital multimeter or battery analyzer such as on a monthly basis.
  2. Charger output
    • Measure the charger output voltage at the charger output terminals using a digital multimeter or battery analyzer such as the Fluke 500 Series Battery Analyzer on a monthly basis.
    • Observe the output current shown on the charger current meter or use an appropriate dc current clamp meter. Measure monthly.
  3. DC float current
    • Refer to manufacturer’s specifications for approximate values for expected float currents.
    • Use an appropriate dc current clamp meter to measure expected float current on a monthly basis.
  4. Internal ohmic values
    • Use a battery analyzer such as the Fluke 500 Series to measure the individual battery ohmic values on a quarterly basis.
    • Establish reference values and maintain in the battery database.

Contact COMTEST on + 010 595 1821 or sales@comtest.co.za or www.comtest.co.za

for more information on Fluke 500 series battery maintenance systems, or for technical or seminar information, demonstrations or to locate your nearest authorized dealer.

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