2024年7月15日发(作者：缪邃)

Operation Guide

for Renewable Energy Applications

Visit us at

Important

Please read this manual immediately on receipt of the battery before unpacking and installing. 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

eyes

Read

instructions

Electrical

hazard

Electrolyte is

corrosive

Danger

Clean all acid splash in eyes

or on 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,

avoid short circuit. Do not place tools or items on top of

the battery.

Recycle scrap

batteries.

Contains lead.

1. Specific Attributes

The specific attributes of this type of battery, for renewable

energy applications, are as follows:

• High cycling (one “cycle” consists of a discharge, of any

depth, followed by a recharge)

• Fast recharge capability

• Deep discharge recovery

• Low rate of self-discharge

• No addition of water required during service life

SuperSafe

®

SBS

®

XC are designed for renewable energy

applications where the battery must undergo repeated cycling

with daily depths of discharge of up to 35% of capacity C

120

(such as rural settlements, communications systems and

lighting systems).

3. Features & Benefits

• Excellent deep discharge recovery and cyclability

• Up to 6,000 cycles at 20% depth of discharge and 1,500

cycles to 60% Depth of Discharge (DoD)

• Vertical or horizontal installation (see SuperSafe SBS XC

Installation, Operation and Maintenance Manual for further

information)

• No topping-up required

4. General Operation Instructions

4.1 Capacity

Capacity is the number of ampere hours (Ah) a battery can

supply for a specific current and an end of discharge voltage.

Capacity varies with the discharge time, discharge rate and

temperature.

The nominal capacity of SuperSafe SBS XC monoblocs and

cells for renewable energy applications is given as follows:

Capacity

(Ah)

C

120

4.2 Discharge Rate:

Current

(A)

l

120

Discharge

Period

(Hours)

120

End Voltage

(Vpc)

1.85V

2. Monobloc/Cell Design

The SuperSafe SBS XC monoblocs and cells consist of:

• Positive plates - Thin Plate Pure Lead (TPPL) grid technology

for long cycle life and efficient recharging

• Negative plates - provide a perfect balance with the positive

plates to ensure optimum recombination efficiency

• Separators – low resistance microporous glass fibre mat

separator with high absorption and stability

• Containers and lids - in UL94 V-0 rated flame-retardant PC/

ABS material, highly resistant to shock and vibration

• Electrolyte - high grade dilute sulphuric acid fully absorbed

into separator material to prevent spillage in case of

accidental damage

• Dual-seal terminal design to prevent leakage over the

product life

• Self-regulating pressure relief valves - prevent ingress of

atmospheric oxygen

• Flame Arrestors – built into each bloc/cell for operational

safety

This is the ratio of discharge current divided by battery

capacity.

4.3 Depth of Discharge (DoD):

This is the capacity removed from the battery compared to total

capacity. It is expressed as a percentage. The battery will be

sized for solar applications with a DoD < 80% for the autonomy

required.

2

4.4 Daily Cycle

The battery is normally used with a daily cycle - charge during

the day hours and discharge during night hours. Typically, the

daily discharge usage is between 2 and 20% DoD.

4.5 Effect of Temperature on Capacity

If the ambient temperature deviates from 25°C, a correction

factor must be applied to the published rating in order to

optimise the service life (see Figure 1 below).

Effect of Temperature on the 20 hour Discharge Performance

Shown as a Percentage of Normal Capacity @ 25ºC

140

120

C

º

5

2

100

@

e

c

n

80

a

m

r

o

f

r

60

e

P

%

40

20

0

-40 -30 -20 -10 0 10 20 30 40 50

Figure 1

Temperature (ºC)

4.6 Operating Temperature Range

The recommended operating temperature range for optimum

life and performance is between 20°C to 25°C. SuperSafe

®

SBS

®

range -40°C to +50°C. In order to maintain mechanical

XC monoblocs/cells can be operated in the temperature

integrity of the plastic components, the battery temperature

in operation should not exceed +50°C. Note, operation of

batteries at higher temperatures will reduce life expectancy. All

technical data relates to the rated temperature of +25°C.

4.7 Storage

Monoblocs and cells lose capacity when standing on open-

circuit because of parasitic chemical reactions. The high purity

of the materials used in the construction of SuperSafe SBS XC

batteries results in a very low rate of self-discharge, delivering

up to 2 years shelf life at 20°C before a refresh charge is

required.

The self-discharge rate of SuperSafe XC monoblocs and cells

is a function of the temperature. See below for the rate of self-

discharge at various temperatures:

Monthly self-discharge

rate

1.25%1.76% 2.5% 5%

Batteries should be stored in a cool, dry area. Note that high

temperature increases the rate of self-discharge and reduces

storage life. The following table gives the maximum storage

time before a refresh charge is required and the recommended

OCV audit intervals, at the given average storage ambient

temperature:

Temperature

(°C / °F)

Storage Time

(Months)

OCV Audit Interval

(Months)

+10 / +504812

+15 / +593412

+20 / +682412

+25 / +77176

+30 / +96126

+35 / +958.53

+40 / +10463

4.8 Refreshing Charge

Blocs and cells must be given a refreshing charge:

4.8.1 when the OCV approaches 2.10Vpc, or

4.8.2

occurs first.

when the maximum storage time is reached, whichever

Charge the monoblocs or cells at a constant voltage equivalent

to 2.40Vpc with minimum 0.1

hours.

C10

Amps current for a period of 24

4.9 Installation and Ventilation

The electrical protective measures and the accommodation

and ventilation of the battery installation must be carried out in

accordance with IEC 62485-2, and applicable “local/national”

standards, rules and regulations.

The battery should be installed in a clean, dry area.

Whatever your application, SuperSafe SBS XC batteries can be

mounted in any orientation except inverted. For the installation

of cells in the horizontal position, the instructions below must

be complied with.

-

+

+ -

+ -

•

•

Do not use terminal posts to lift or handle cells.

Ensure that the stand runners are located under the

•

container rather than the lid and/or lid/container seal.

Always ensure that the arrow on the lid of each unit is

pointing in vertical orientation.

3

Avoid placing the battery in a hot place or in front of a window

(no direct sunlight). Battery racks are recommended for proper

installation.

The positive terminal is identified by a “+” symbol on each

monobloc/cell. Install the batteries in accordance with the

instructions and/or layout drawing, taking care to ensure

correct terminal location and polarity.

Check that all contact surfaces are clean. Tighten terminal

fasteners, taking care to use the correct torque loading. The

fastener torque value is indicated on the product label. Fit the

covers supplied for protection against short circuit.

Follow the polarity to avoid short circuiting of monoblocs/cells.

A loose connector can cause erratic battery performance and

possible damage to the battery and/or personal injury.

4.10 Commissioning Charge

5. Cyclic Operation

5.1 Cyclic Performance

The graph below shows cycling capability of SuperSafe SBS

XC products:

Typical Number of Cycles as a Function of Depth

in Unreliable Grid Applications

of Discharge in Unreliable Grid Applications

14000

13000

12000

Typical Number of Cycles as a Function of Depth of Discharge

N

u

m

b

e

r

o

f

C

y

c

l

e

s

11000

10000

9000

8000

7000

6000

5000

4000

3000

2000

1000

0

10

The initial charge is extremely important as it will condition the

battery service life. So, the battery must be fully recharged to

ensure that it is in an optimum state of charge.

Case 1: Using a constant voltage charger. Cells here will need

to be recharged at a constant voltage of between 2.35 and

2.40 Vpc (maximum) at 25°C for a minimum of 24 hours with a

current limited to 0.01

C10

Amps. Temperature compensation for

charge voltage should be applied at the rates shown below:

+10 / +50

+20 / +68

+25 / +77

+30 / +96

+40 / +104

2.44

2.40

2.38

2.36

2.32

N

u

m

b

e

r

o

f

C

y

c

l

e

s

Depth of Discharge (%)

Figure 2

Depth of Discharge (%)

5.2 Discharging

Do not over-discharge the battery. This can be avoided by

including a Low Voltage Disconnect (LVD) switch in the circuit

or by disconnecting the battery from the load when the end

discharge voltage is reached. As a rule, installations will be

equipped with a regulator whose voltage threshold values will

protect against deep discharge:

Discharge Time

(Hours)

10

Low Voltage

Alarm

Disconnect

Voltage (LVD)

5.3 Charging

1.96Vpc

1.93Vpc

120

1.96Vpc

1.93Vpc

240

1.99Vpc

1.96Vpc

Case 2: With no external source available for recharging.

Connect the battery to the solar panel regulator and leave at

rest for 1 to 2 weeks. For this charge, set the regulator to the

values outlined in the charging section.

4.11 End-of-Charge Reading

The table hereafter gives an indication of the state of charge of

blocs and cells from a reading of open circuit voltage.

State of Charge (%)

100

90

80

70

Voltage

(Vpc)

2.17

2.15

2.12

2.10

The high charge acceptance of the TPPL technology used in

SuperSafe

®

SBS

®

XC is suited for applications which require

a fast time to repeat duty. In such applications the voltage

regulator should be set at 2.35Vpc to 2.40Vpc at 25°C.

Once fully charged the voltage can revert to float voltage with

temperature compensation as required. There are a number

of methods that can be utilised to control the recharge and

determine, when using fast charge, that full state of charge is

obtained such as Current Absorption and Ah Counting.

Based on current absorption, the recharge can be stopped

when current being absorbed by the battery reaches

0.01

C10

Amps. At this point a timer can be set/activated to

deliver an additional 1 hour of charge.

4

Ah counting can be used to control the recharge (i.e.103%

of discharged Ah is returned/115% in terms of Wh returned)

using a device with accuracy ±1% of the expected current

range. However, inaccuracies associated with equipment

calibration and/ or controller algorithm accuracy can lead to

drift in determining the true state of charge (SoC), meaning

that periodic equalisation charge and recalibration of SoC is

required.

Where Current Absorption Rate or Ah counting is used to

control the recharge, the battery voltage can be maintained

at a constant of 2.35Vpc to 2.40Vpc provided that the battery

temperature is controlled at or below +50°C.

Where the voltage cannot be adjusted to values >2.40Vpc to

compensate for temperatures below 20°C, the time to full state

of charge will increase.

The voltage/temperature compensation is +3mV/°C/Cell for a

temperature lower than 20°C (77°F) (the reference temperature

being 20°C) and -3mV/°C/Cell for a temperature higher than

20°C.

6. Service Life

Under normal operating conditions, the battery lifetime largely

depends on the temperature and depths of discharge. The

service life in cycling applications is based on the number of

years with a daily depth of discharge and can never exceed

the design life of 12 years at 20°C.

See Number. of Cycles vs DoD graph, Figure 2, and an

example of a SuperSafe

®

SBS

®

XC battery at 25°C:

of Discharge

Daily Depth

Number of Cycles

Estimated Life

(%DoD)

at 25ºC

Expectancy

(Years)

303,6009.8

7. Maintenance

SuperSafe SBS XC monoblocs and cells are VRLA batteries

and do not have to be topped up with water.

• Do not open the valve. Opening could cause lasting

damage to the battery and is prohibited.

• The containers and lids should be kept dry and free from

dust. Cleaning must be undertaken with a damped cotton

cloth without additives and without man-made fibres or

addition of cleaning agents, never use abrasives or solvents.

• Do NOT use any type of oil, solvent, detergent, petroleum

based solvent or ammonia solution to clean the battery

containers or lids.

• Discharge any possible static electricity from clothes by

touching an earth connected part.

8. Data Recording

It is recommended that, as a minimum, the following

information is recorded by means of regular data logging,

which the user must make available to EnerSys

®

warranty claim.

to validate any

1) Records of the commission charge.

2) T

(DoD) of each cycle.

he number of cycles performed and the depth of discharge

3) T

Ah in and Ah out, or Wh in and Wh out.

he duration of each charge and discharge cycle, and the

4) F

50 cycles.

ull details of the recharge voltage/current profile for the last

5) A

temperatures, recorded at regular intervals throughout

full history of the ambient and battery surface

battery operation and life.

6) T

the start/stop of the battery discharge, the start/stop of the

he time and date of each event. An event is defined as

battery recharge, the start/stop of any input power source.

9. Disposal

SuperSafe SBS XC products are recyclable. End of life

batteries must be packaged and transported according to

prevailing transportation rules and regulations. End of life

batteries must be disposed of in compliance with local and

national laws by a licensed battery recycler.

5

EnerSys World Head-

quarters

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 6508 1780

Contact:

©2020 EnerSys. All rights reserved. Trademarks and logos are the property of EnerSys and its affiliates unless otherwise noted. Subject to revisions without prior notice. E.&O.E.

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1

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2

0

2024年7月15日发(作者：缪邃)

Operation Guide

for Renewable Energy Applications

Visit us at

Important

Please read this manual immediately on receipt of the battery before unpacking and installing. 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

eyes

Read

instructions

Electrical

hazard

Electrolyte is

corrosive

Danger

Clean all acid splash in eyes

or on 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,

avoid short circuit. Do not place tools or items on top of

the battery.

Recycle scrap

batteries.

Contains lead.

1. Specific Attributes

The specific attributes of this type of battery, for renewable

energy applications, are as follows:

• High cycling (one “cycle” consists of a discharge, of any

depth, followed by a recharge)

• Fast recharge capability

• Deep discharge recovery

• Low rate of self-discharge

• No addition of water required during service life

SuperSafe

®

SBS

®

XC are designed for renewable energy

applications where the battery must undergo repeated cycling

with daily depths of discharge of up to 35% of capacity C

120

(such as rural settlements, communications systems and

lighting systems).

3. Features & Benefits

• Excellent deep discharge recovery and cyclability

• Up to 6,000 cycles at 20% depth of discharge and 1,500

cycles to 60% Depth of Discharge (DoD)

• Vertical or horizontal installation (see SuperSafe SBS XC

Installation, Operation and Maintenance Manual for further

information)

• No topping-up required

4. General Operation Instructions

4.1 Capacity

Capacity is the number of ampere hours (Ah) a battery can

supply for a specific current and an end of discharge voltage.

Capacity varies with the discharge time, discharge rate and

temperature.

The nominal capacity of SuperSafe SBS XC monoblocs and

cells for renewable energy applications is given as follows:

Capacity

(Ah)

C

120

4.2 Discharge Rate:

Current

(A)

l

120

Discharge

Period

(Hours)

120

End Voltage

(Vpc)

1.85V

2. Monobloc/Cell Design

The SuperSafe SBS XC monoblocs and cells consist of:

• Positive plates - Thin Plate Pure Lead (TPPL) grid technology

for long cycle life and efficient recharging

• Negative plates - provide a perfect balance with the positive

plates to ensure optimum recombination efficiency

• Separators – low resistance microporous glass fibre mat

separator with high absorption and stability

• Containers and lids - in UL94 V-0 rated flame-retardant PC/

ABS material, highly resistant to shock and vibration

• Electrolyte - high grade dilute sulphuric acid fully absorbed

into separator material to prevent spillage in case of

accidental damage

• Dual-seal terminal design to prevent leakage over the

product life

• Self-regulating pressure relief valves - prevent ingress of

atmospheric oxygen

• Flame Arrestors – built into each bloc/cell for operational

safety

This is the ratio of discharge current divided by battery

capacity.

4.3 Depth of Discharge (DoD):

This is the capacity removed from the battery compared to total

capacity. It is expressed as a percentage. The battery will be

sized for solar applications with a DoD < 80% for the autonomy

required.

2

4.4 Daily Cycle

The battery is normally used with a daily cycle - charge during

the day hours and discharge during night hours. Typically, the

daily discharge usage is between 2 and 20% DoD.

4.5 Effect of Temperature on Capacity

If the ambient temperature deviates from 25°C, a correction

factor must be applied to the published rating in order to

optimise the service life (see Figure 1 below).

Effect of Temperature on the 20 hour Discharge Performance

Shown as a Percentage of Normal Capacity @ 25ºC

140

120

C

º

5

2

100

@

e

c

n

80

a

m

r

o

f

r

60

e

P

%

40

20

0

-40 -30 -20 -10 0 10 20 30 40 50

Figure 1

Temperature (ºC)

4.6 Operating Temperature Range

The recommended operating temperature range for optimum

life and performance is between 20°C to 25°C. SuperSafe

®

SBS

®

range -40°C to +50°C. In order to maintain mechanical

XC monoblocs/cells can be operated in the temperature

integrity of the plastic components, the battery temperature

in operation should not exceed +50°C. Note, operation of

batteries at higher temperatures will reduce life expectancy. All

technical data relates to the rated temperature of +25°C.

4.7 Storage

Monoblocs and cells lose capacity when standing on open-

circuit because of parasitic chemical reactions. The high purity

of the materials used in the construction of SuperSafe SBS XC

batteries results in a very low rate of self-discharge, delivering

up to 2 years shelf life at 20°C before a refresh charge is

required.

The self-discharge rate of SuperSafe XC monoblocs and cells

is a function of the temperature. See below for the rate of self-

discharge at various temperatures:

Monthly self-discharge

rate

1.25%1.76% 2.5% 5%

Batteries should be stored in a cool, dry area. Note that high

temperature increases the rate of self-discharge and reduces

storage life. The following table gives the maximum storage

time before a refresh charge is required and the recommended

OCV audit intervals, at the given average storage ambient

temperature:

Temperature

(°C / °F)

Storage Time

(Months)

OCV Audit Interval

(Months)

+10 / +504812

+15 / +593412

+20 / +682412

+25 / +77176

+30 / +96126

+35 / +958.53

+40 / +10463

4.8 Refreshing Charge

Blocs and cells must be given a refreshing charge:

4.8.1 when the OCV approaches 2.10Vpc, or

4.8.2

occurs first.

when the maximum storage time is reached, whichever

Charge the monoblocs or cells at a constant voltage equivalent

to 2.40Vpc with minimum 0.1

hours.

C10

Amps current for a period of 24

4.9 Installation and Ventilation

The electrical protective measures and the accommodation

and ventilation of the battery installation must be carried out in

accordance with IEC 62485-2, and applicable “local/national”

standards, rules and regulations.

The battery should be installed in a clean, dry area.

Whatever your application, SuperSafe SBS XC batteries can be

mounted in any orientation except inverted. For the installation

of cells in the horizontal position, the instructions below must

be complied with.

-

+

+ -

+ -

•

•

Do not use terminal posts to lift or handle cells.

Ensure that the stand runners are located under the

•

container rather than the lid and/or lid/container seal.

Always ensure that the arrow on the lid of each unit is

pointing in vertical orientation.

3

Avoid placing the battery in a hot place or in front of a window

(no direct sunlight). Battery racks are recommended for proper

installation.

The positive terminal is identified by a “+” symbol on each

monobloc/cell. Install the batteries in accordance with the

instructions and/or layout drawing, taking care to ensure

correct terminal location and polarity.

Check that all contact surfaces are clean. Tighten terminal

fasteners, taking care to use the correct torque loading. The

fastener torque value is indicated on the product label. Fit the

covers supplied for protection against short circuit.

Follow the polarity to avoid short circuiting of monoblocs/cells.

A loose connector can cause erratic battery performance and

possible damage to the battery and/or personal injury.

4.10 Commissioning Charge

5. Cyclic Operation

5.1 Cyclic Performance

The graph below shows cycling capability of SuperSafe SBS

XC products:

Typical Number of Cycles as a Function of Depth

in Unreliable Grid Applications

of Discharge in Unreliable Grid Applications

14000

13000

12000

Typical Number of Cycles as a Function of Depth of Discharge

N

u

m

b

e

r

o

f

C

y

c

l

e

s

11000

10000

9000

8000

7000

6000

5000

4000

3000

2000

1000

0

10

The initial charge is extremely important as it will condition the

battery service life. So, the battery must be fully recharged to

ensure that it is in an optimum state of charge.

Case 1: Using a constant voltage charger. Cells here will need

to be recharged at a constant voltage of between 2.35 and

2.40 Vpc (maximum) at 25°C for a minimum of 24 hours with a

current limited to 0.01

C10

Amps. Temperature compensation for

charge voltage should be applied at the rates shown below:

+10 / +50

+20 / +68

+25 / +77

+30 / +96

+40 / +104

2.44

2.40

2.38

2.36

2.32

N

u

m

b

e

r

o

f

C

y

c

l

e

s

Depth of Discharge (%)

Figure 2

Depth of Discharge (%)

5.2 Discharging

Do not over-discharge the battery. This can be avoided by

including a Low Voltage Disconnect (LVD) switch in the circuit

or by disconnecting the battery from the load when the end

discharge voltage is reached. As a rule, installations will be

equipped with a regulator whose voltage threshold values will

protect against deep discharge:

Discharge Time

(Hours)

10

Low Voltage

Alarm

Disconnect

Voltage (LVD)

5.3 Charging

1.96Vpc

1.93Vpc

120

1.96Vpc

1.93Vpc

240

1.99Vpc

1.96Vpc

Case 2: With no external source available for recharging.

Connect the battery to the solar panel regulator and leave at

rest for 1 to 2 weeks. For this charge, set the regulator to the

values outlined in the charging section.

4.11 End-of-Charge Reading

The table hereafter gives an indication of the state of charge of

blocs and cells from a reading of open circuit voltage.

State of Charge (%)

100

90

80

70

Voltage

(Vpc)

2.17

2.15

2.12

2.10

The high charge acceptance of the TPPL technology used in

SuperSafe

®

SBS

®

XC is suited for applications which require

a fast time to repeat duty. In such applications the voltage

regulator should be set at 2.35Vpc to 2.40Vpc at 25°C.

Once fully charged the voltage can revert to float voltage with

temperature compensation as required. There are a number

of methods that can be utilised to control the recharge and

determine, when using fast charge, that full state of charge is

obtained such as Current Absorption and Ah Counting.

Based on current absorption, the recharge can be stopped

when current being absorbed by the battery reaches

0.01

C10

Amps. At this point a timer can be set/activated to

deliver an additional 1 hour of charge.

4

Ah counting can be used to control the recharge (i.e.103%

of discharged Ah is returned/115% in terms of Wh returned)

using a device with accuracy ±1% of the expected current

range. However, inaccuracies associated with equipment

calibration and/ or controller algorithm accuracy can lead to

drift in determining the true state of charge (SoC), meaning

that periodic equalisation charge and recalibration of SoC is

required.

Where Current Absorption Rate or Ah counting is used to

control the recharge, the battery voltage can be maintained

at a constant of 2.35Vpc to 2.40Vpc provided that the battery

temperature is controlled at or below +50°C.

Where the voltage cannot be adjusted to values >2.40Vpc to

compensate for temperatures below 20°C, the time to full state

of charge will increase.

The voltage/temperature compensation is +3mV/°C/Cell for a

temperature lower than 20°C (77°F) (the reference temperature

being 20°C) and -3mV/°C/Cell for a temperature higher than

20°C.

6. Service Life

Under normal operating conditions, the battery lifetime largely

depends on the temperature and depths of discharge. The

service life in cycling applications is based on the number of

years with a daily depth of discharge and can never exceed

the design life of 12 years at 20°C.

See Number. of Cycles vs DoD graph, Figure 2, and an

example of a SuperSafe

®

SBS

®

XC battery at 25°C:

of Discharge

Daily Depth

Number of Cycles

Estimated Life

(%DoD)

at 25ºC

Expectancy

(Years)

303,6009.8

7. Maintenance

SuperSafe SBS XC monoblocs and cells are VRLA batteries

and do not have to be topped up with water.

• Do not open the valve. Opening could cause lasting

damage to the battery and is prohibited.

• The containers and lids should be kept dry and free from

dust. Cleaning must be undertaken with a damped cotton

cloth without additives and without man-made fibres or

addition of cleaning agents, never use abrasives or solvents.

• Do NOT use any type of oil, solvent, detergent, petroleum

based solvent or ammonia solution to clean the battery

containers or lids.

• Discharge any possible static electricity from clothes by

touching an earth connected part.

8. Data Recording

It is recommended that, as a minimum, the following

information is recorded by means of regular data logging,

which the user must make available to EnerSys

®

warranty claim.

to validate any

1) Records of the commission charge.

2) T

(DoD) of each cycle.

he number of cycles performed and the depth of discharge

3) T

Ah in and Ah out, or Wh in and Wh out.

he duration of each charge and discharge cycle, and the

4) F

50 cycles.

ull details of the recharge voltage/current profile for the last

5) A

temperatures, recorded at regular intervals throughout

full history of the ambient and battery surface

battery operation and life.

6) T

the start/stop of the battery discharge, the start/stop of the

he time and date of each event. An event is defined as

battery recharge, the start/stop of any input power source.

9. Disposal

SuperSafe SBS XC products are recyclable. End of life

batteries must be packaged and transported according to

prevailing transportation rules and regulations. End of life

batteries must be disposed of in compliance with local and

national laws by a licensed battery recycler.

5

EnerSys World Head-

quarters

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 6508 1780

Contact:

©2020 EnerSys. All rights reserved. Trademarks and logos are the property of EnerSys and its affiliates unless otherwise noted. Subject to revisions without prior notice. E.&O.E.

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