Enersys SuperSafe SBS XL Batteries Instruction Manual
- June 4, 2024
- EnerSys
Table of Contents
Installation, Operation and
Maintenance Manual
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Important
Please read this manual immediately upon receipt of the battery before
unpacking and installing it. Failure to comply with these instructions will
render any warranties null and void.
Care for your safety
No smoking, no naked flames, no sparks
** Shield’s eyes
Read instructions
Electrical hazard
Electrolyte is corrosive
Danger
Clean all acid splashes in the eyes or on the skin with plenty of clean water.
Then seek medical help. Acid on clothing is to be washed with water
Warning: Risk of fire, explosion, or burns. Do not disassemble, heat
above 60°C (140°F), or incinerate. Metallic parts under voltage are present on
the battery, avoiding short circuits. Do not place tools or items on top of
the battery.
** Recycle scrap batteries. Contains lead.
Handling
SuperSafe® SBS XL blocs and cells are supplied in a charged condition and are
capable of extremely high short-circuit currents. Take care to avoid short-
circuiting terminals of opposite polarity.
Keep flames away
In case of an accidental overcharge, a flammable gas can leak off the safety
vent.
Discharge any possible static electricity from clothes by touching an earth
connected part.
Tools
Use tools with insulated handles.
Do not place or drop metal objects on the battery.
Remove rings, wristwatches, es, and articles of clothing with metal parts that
may come into contact with the battery terminals.
California Proposition 65 Warning – Battery posts, terminals, and related
accessories contain lead and lead compounds, chemicals are known to the State
of California to cause cancer and reproductive harm. Wash hands after
handling.
Receiving
Upon receipt of the shipment, check the contents for damage and against the packing slip. Immediately inform EnerSys of any damaged or missing items. EnerSys ® is not responsible for shipping damage or shortages that the receiver does not report to the carrier.
Storage
2.1. Storage Conditions and Time
If a battery cannot be immediately installed it should be stored in a clean,
cool, and dry area. During storage blocs and cells lose capacity through self-
discharge. High temperatures increase the rate of self-discharge and reduce
the storage life.
The chart below shows the relationship between open-circuit voltage (OCV) and
storage time at various temperatures.
The maximum storage times before a refresh charge is required and recommended open circuit voltage audit intervals are:
Temperature (°C / °F)| Storage Time (Months)| OCV Audit Intervals
(Months)
---|---|---
+10 / +50| 48| 12
+15 / +59| 34| 12
+20 / +68| 24| 12
+25 / +77| 17| 6
+30 / +86| 12| 6
+35 / +95| 8.5| 3
+40 / +104| 6| 3
Blocs/cells must be given a refresh charge when the OCV approaches the
equivalent of 2.10 Volts per cell or when the maximum storage time is reached,
whichever occurs first.
2.2. Refresh Charge
Charge at a constant voltage equivalent to 2.29 – 2.40Vpc with a minimum of
0.1C10 Amps available for a period of 24 hours.
2.3. Commissioning Charge
Before commencing operation, the battery must be given a commissioning charge.
The batteries should be charged using constant voltage with a minimum charge
current of 0.1C10 Amps with no load connected to the battery. Either of the
following methods can be used:
- Charge for 96 hours at the recommended float voltage of 2.29Vpc at 20°C / 68°F or
- Charge for 24 hours at the recommended boost charge voltage of 2.40Vpc at 20°C / 68°F. The battery will then be switched over to float charging, maintaining the battery under floating voltage for 24 hours before any discharge test.
Battery Location
The battery compartment/room must have adequate ventilation to limit hydrogen accumulation. Batteries must be installed in accordance with the IEC 62485-2 standard and any other local/national laws and regulations.
Installation
SuperSafe SBS XL batteries are designed for stable grid float applications
(non-cyclic applications). 12V blocs can be installed on their base or
horizontally on their longest side whilst 2V cells can be mounted in any
orientation except inverted.
With regards to the installation of 2V cells in horizontal orientation
specifically, the instructions below must be complied with:
- Do not use terminal posts to lift or handle cells.
- Do not install the cells in such a way that the box-lid seal is resting on a runner.
- Always ensure that the arrow on the lid of each unit is pointing in a vertical orientation.
Each bloc/cell is supplied with terminal/connector fasteners.
The positive terminal is identified by a “+” symbol on each bloc/cell.
Install the batteries in accordance with the instructions and/or layout
drawing, taking care to ensure the correct terminal location and polarity.
Connect the blocs/cells with the connectors and fasteners provided. The
fastener torque value is indicated on the product label.
Place the insulating covers in position immediately after tightening the
fasteners.
Operation
Optimum performance and service life are achieved at a temperature of 20/25°C (68/77°F). The operating temperature range is as follows:
- SBS XL 2V cells: -40°C to +50°C (-40°F to +122°F)
- SBS XL 12V blocs: -40°C to +65°C (-40°F to +149°F).
5.1. Standby / Float Operation
Constant voltage chargers are recommended. The charging voltage should be set
at the equivalent of 2.29Vpc at 20°C (68°F) or 2.275Vpc at 25°C (77°F). The
recommended float voltage temperature compensation is:
- +3mV per cell per °C below 20°C
- –3mV per cell per °C above 20°C
The minimum charging voltage, at any temperature, is 2.21Vpc.
5.2. Charging Current
Due to the very low internal resistance, SuperSafe® SBS XL batteries will
accept unlimited current during recharge but for cost and practical purposes
in float applications where recharge time to repeat duty is not critical, the
rectifier current can be limited to the load plus 0.1C10 Amps.
5.3. Discharging
Batteries must not be left in a discharged condition after supplying the load
but must immediately return to recharge mode.
Failure to observe these conditions may result in greatly reduced service
life.
Accidental deep discharging
For optimum operation, the minimum voltage of the system should be related to
the duty as follows:
| Duty | Minimum end voltage |
|---|---|
| 5 min ≤ t ≤ 1h | 1.65V |
| 1h ≤ t ≤ 5h | 1.70V |
| 5h ≤ t ≤ 8h | 1.75V |
| 8h ≤ t ≤ 20h | 1.80V |
In order to protect the battery, it is advisable to have system monitoring and
low voltage cut-out.
The deep discharge will produce a premature deterioration of the battery and a
noticeable reduction in the life expectancy of the battery.
Effect of temperature
The temperature has an effect on the battery capacity. With increased
operating temperature the capacity increases; likewise with decreasing
temperature the capacity decreases.
Maintenance
In practice, the user usually specifies the maintenance schedule based on site
criticality, location, and manpower. However, the following may be used as a
suggested maintenance schedule. Typically, the maintenance frequency for
standard VRLA batteries is scheduled every 6 months. However, as a result of
the increased design life inherent in the SBS XL range, this interval
frequency can be extended to deliver additional Total Cost of Ownership (TCO)
benefit, particularly during the early period of service. As the battery
approaches 80% of the intended service it would be beneficial to increase the
frequency of maintenance.
Keep a logbook to record values, power outages, discharge tests, etc.
- Measure the battery string voltage. If necessary, adjust the float voltage to the correct value.
- Measure individual bloc/cell voltages. After six months of operation, blocs/cells should be within 5% of the voltage value during float charge, as specified in chapter 5.1.
- Check the ambient temperature in the immediate environment.
- Inspect for contamination by dust, and loose or corroded connections.
If necessary, isolate the string/bloc/cell and clean it with a damp soft
cloth.
Warning: Do NOT use any type of oil, solvent, detergent, or petroleum-based
solvent or ammonia solution to clean the battery containers or lids. These
materials will cause permanent damage to the battery container and lid and
will invalidate the warranty.
State of health monitoring
Typically a load test can be carried out once a year.
Capacity discharge testing is considered as the only true guide to the state
of health but can be complemented by the use of Ohmic measurement trending
e.g. Conductance.
- A discharge test should only be carried out on a fully charged battery.
- For a new battery, a discharge test should only be carried out after the commissioning charge is completed as specified in section 2.3.
Ensure the battery is fully recharged before capacity testing and always
complete a full discharge test (partial discharges can lead to false
assessment of the state of health).
The best practice is to define the discharge test based on the application in
terms of the load, autonomy or what is practical. The load and end-of-
discharge voltage should be based on published performance literature.
Depending on the operating temperature a compensation correction factor may be
required.
Log individual bloc/cell voltage throughout the duration of the test at
regular intervals.
Following the capacity test, the battery should be fully recharged in
accordance with the instructions in section 5.
Ohmic measurements
The correct way to use Ohmic readings is as a trending tool over time to
detect potentially weak or troublesome blocs/cells in a VRLA battery string in
float in service. When the string is first installed and stabilized, a set of
“initial” Ohmic readings should be taken. Since at this time there may still
be some significant variations bloc to bloc/cell to cell in a state of charge,
separator acid content, recombination efficiency, etc. it is not unusual for
these initial readings to be typically ± 50% of the mean. If some blocs/ cells
exceed this, it would be judicious to equalize charge the string and do a
capacity test.
After the string has been in service for about 6 months, the previously
mentioned variations tend to normalize. At this point, another set of Ohmic
readings should be taken and used as the “baseline” readings. At this point,
the blocs/cells should be typically within ± 30% of the average.
These individual “baseline” readings will serve as a reference for trending
purposes for comparison to readings taken later in the battery’s life. On a
yearly basis, Ohmic readings should be taken, recorded, and compared to the
baseline readings. If a bloc/cell or battery Ohmic reading varies more than
50% from the baseline value, the battery should be further evaluated to
determine the cause. A performance or capacity test should be part of this
evaluation.
Disposal
SuperSafe SBS XL batteries are recyclable. Scrap batteries must be packaged
and transported in accordance with prevailing transportation rules and
regulations.
Scrap batteries must be disposed of in compliance with local and national laws
by a licensed or certified lead acid battery recycler.
EnerSys World Headquarters
2366 Bernville Road, Reading,
PA 19605, USA
Tel: +1-610-208-1991
+1-800-538-3627| EnerSys EMEA
EH Europe GmbH,
Baarerstrasse 18,
6300 Zug
Switzerland| EnerSys Asia
152 Beach Road,
Gateway East Building #11-08,
Singapore 189721
Tel: +65 6416 4800
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of EnerSys and its affiliates unless otherwise noted. Subject to revisions
without prior notice. E. &O.E.
Contact:………………..
Publication No. APAC-EN-IOM-SS-SBSXL -0421
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