stationary battery sizing - ieee
TRANSCRIPT
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Stationary Battery SizingStationary Battery Sizing
Presented by:Lesley Varga, P.E.
Quality Standby Services, LLC1649 Sands Place, SE, Suite C
Marietta, GA 30067(770) 916-1747
IEEE IAS Atlanta Chapter
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Safety First!
Basic PPE
Safety First!
Basic PPE Personal Protective Equipment –example:
– Goggles and face shields, eye protection– Acid-resistance gloves– Protective aprons– Emergency eye-wash and safety showers– Bicarbonate soda and water for neutralization
(mixed to the ratio of 1 lb. to 1 gallon)– Insulated tools– Class C fire extinguisher
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Personal Protective EquipmentPersonal Protective Equipment
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WARNING !!!WARNING !!!
GAS PRODUCED BY THIS BATTERY CAN BE EXPLOSIVE. PROTECT EYES WHEN AROUND
BATTERY. PROVIDE ADEQUATE VENTILATION SO HYDROGEN GAS ACCUMULATION IN THE
BATTERY AREA DOES NOT EXCEED ONE PERCENT BY VOLUME. DO NOT SMOKE, USE OPEN FLAME OR CREATE SPARKS NEAR THE
BATTERY.
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WARNING !!!WARNING !!!
THE BATTERY CONTAINS SULFURIC ACID WHICH CAN CAUSE SEVERE BURNS. IN
CASE OF SKIN CONTACT WITH ELECTROLYTE, REMOVE CONTAMINATED CLOTHING AND FLUSH AFFECTED AREAS
THOROUGHLY WITH WATER. IF EYE CONTACT HAS OCCURRED, FLUSH FOR A MINIMUM OF 15 MINUTES WITH LARGE
AMOUNTS OF RUNNING WATER AND SEEK IMMEDIATE MEDICAL ATTENTION.
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WARNING !!!WARNING !!!
SHOCK HAZARD – DO NOT TOUCH UNINSULATED BATTERY
CONNECTORS OR TERMINALS. BE SURE TO DISCHARGE STATIC
ELECTRICITY FROM TOOLS AND TECHNICIAN BY TOUCHING A GROUNDED SURFACE IN THE
VICINITY OF THE BATTERIES BUT AWAY FROM THE CELLS AND FLAME
ARRESTERS.
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LampsRelaysBreaker
Coils
Switchgear and Control DC systemSwitchgear and Control DC system
AC→DC24, 48, 125 or
240 VDC
VAC1Φ or 3Φ
Charger/Rectifier+ -
Battery
SwitchgearControls
MotorsPumpsValves
DC Loads
“125VDC” Bus: 133.8 VDCTypical Float Voltage
Inverter
DC→AC
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LampsRelaysBreaker
Coils
System One Line - AC Input LostSystem One Line - AC Input Lost
AC→DC24, 48, 125 or
240 VDC
VAC1Φ or 3Φ
Charger/Rectifier+ -
Battery
SwitchgearControls
MotorsPumpsValves
DC Loads
Inverter
DC→AC
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UtilityAC
Input
Transfer Sw
Generator
AC→DCRect. #1
AC→DCRect. #n
AC→DCRect. #n+1
Battery
Bus Work
PowerBoard
Distribution to Loads
+ -
Telecom DC System“48 VDC” Bus: 54.2 VDC
Typical Float Voltage
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UtilityAC
Input
Transfer Sw
Generator
AC→DCRect. #1
AC→DCRect. #n
AC→DCRect. #n+1
Battery
Bus Work
PowerBoard
Distribution to Loads
+ -
Telecom DC System -AC Input Lost“48 VDC”: 54.2 VDCTypical Float Voltage
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UtilityAC
Input
Transfer Sw
Generator
AC→DCRect. #1
AC→DCRect. #n
AC→DCRect. #n+1
Battery
Bus Work
PowerBoard
Distribution to Loads
+ -
Telecom DC System – AC Lost, Generator On Line
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UtilityAC Input
Transfer Switch
Generator
RectifierAC→DC
InverterDC→AC
UPS
+ -
Battery
Typical UPS System
Loads
“480 VDC Bus”: 540 VDC Float
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UtilityAC Input
Transfer Switch
Generator
RectifierAC→DC
InverterDC→AC
UPS
+ -
Battery
UPS System –Utility LostBefore Generator
Loads
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Utility AC
GeneratorUPS Battery 480 Volt 240
cells
LOADS
UPS
Switchgear
Switchgear Battery125 V/48 V
Engine Starting Battery
24 volt
InverterRectifier
Telecom Equip
48 VDCTelecom Battery
48 V /24 cells
Batteries in Mission Critical Applications
Emergency Lighting
EmergencyLightingBattery
Transfer Switch
Fire Pump Fire Pump Batteries
Substation Battery125 volt
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Definition of a CellDefinition of a Cell
Cell: A unit part consisting of two dissimilar electrodes immersed in an electrolyte; One lead acid cell is 2 volts nominalOne nickel cadmium cell is 1.2 volts nominal
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String: An energy storage system consisting of two or more series connected cells up to the required system voltage
Definition of a String
Lead Acid“125 Vdc” = 58-60 cells
Typical Float = 130-134Vdc
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Nickel Cadmium“125 Vdc” = 90-96 cells
Typical Float =130 -134 Vdc
Definition of a String
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Battery BasicsBattery Basics
Separators
2 Volts
PositivePlate
NegativePlate
Within the cell the plates are connected in parallel. If each positive plate is 100 Amp Hours in capacity, the cell is 300 Amp Hour .
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Battery BasicsBattery Basics Series connection of Cells
– Start with Cell # 1 Positive, connecting from a negative terminal on cell #1 to a positive terminal on adjacent cell (typical connection within a battery string)
– Add up the cell voltage, but the Amp-hour stays the same
– Example: Two 6V-25Ahr units connected in series = 12 Volt, 25 Amp-hour
Cell #1………. Cell # n
+ - + - + - + -
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Battery BasicsBattery Basics
Parallel connection– Connecting from a positive
terminal on one battery to a positive terminal on another battery
– Sum the Capacity of each string (Watts or Amp Hours); the voltage remains the same
– Example: Two 6V-25 Amp hour units connected in parallel = System: 6 Volts, 50 Amp-hours
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Lead Acid BatteryLead Acid Battery
Lead dioxide Positive plate, PbO2
Metallic sponge lead Negative plate, Pb
Immersed into an electrolyte of Water & Sulfuric Acid, H2SO4
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Types of Lead Acid BatteryTypes of Lead Acid BatteryVented Lead Acid (“VLA”)
– Also called Flooded or Wet – Lead-Calcium (most common), Lead-
Antimony, Low Antimony (“lead selenium”)and Pure Lead
Valve Regulated Lead Acid (“VRLA”)– Also called Sealed (not maintenance free)– Lead Calcium – Pure Lead– AGM design
(Absorbed Glass Mat) – Gel design
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Post
Strap
Plate
VentCover
Container
Lead Acid Cell ComponentsLead Acid Cell Components
Separator
2 Volt VRLAVLA (Flooded)
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Lead Acid Grids and PlatesLead Acid Grids and Plates
Negative PlateGrid Positive
Plate
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26
Separator: prevents electrical contact between the positive and negative plates while maintaining sufficient electrolyte to sustain capacity
Flooded: micro porous separator– Grooved design to allow freeliquid and gas movement within cell– Provides prevention from shorts– Glass mat may be used
VRLA: “absorbent glass mat” wrapspositive and negative plates
– AGM– Gel
SEPARATORSSEPARATORS
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Telecom Battery Low Rate/Long
Duration
UPS Battery High Rate/Short
Duration
Switchgear BatteryGeneral Purpose
Step LoadsNominal 8 hr discharge rate
Nominal 15 min. discharge rate
Combination of long & short duration rates
Thicker pos plates Thinner pos plates Moderately thick plates
Plates farther apart Plates very close Moderate plate center
High electrolyte to plate ratio
Low electrolyte to plate ratio
Moderate electrolyte to plate ratio
Minimal cycling Improved cycling Moderate cycling
Poor high rates Very good high rates Reliable high rates
Good long rates Poor long rates Reliable long rates
Lead Acid Battery Design DifferencesLead Acid Battery Design Differences
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Nickel Cadmium BatteryNickel Cadmium Battery
Nickel positive plateCadmium negative plate Immersed into an electrolyte of
Potassium Hydroxide (alkaline)
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Nickel Cadmium Design DifferencesNickel Cadmium Design Differences
LLow rate of discharge
MMedium rate of
discharge
HHigh rate of discharge
Cell type L M H
Railway X X X
Emergency lightning X
Telecommunication X X
Industrial X X X
Photovoltaic X
Diesel start X
UPS X X X
Utility Equipment X X X
Emergency supply X X X
Alarm equipment X
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Nickel Cadmium - Internal ConstructionNickel Cadmium - Internal ConstructionL
Low Rate of Discharge
MMedium Rate of
Discharge
HHigh Rate of Discharge
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IEEE Standards, Guides, PracticesIEEE Standards, Guides, Practices IEEE Std 485 -2010: Sizing, Stationary Lead Acid IEEE Std 1184-2006: Batteries for UPS Systems IEEE Std 1189 -2007: Selection & Sizing VRLA IEEE Std 1115-2014: Sizing Nickel Cadmium
Additional System Considerations:1375 – Protection of Battery Systems1578 – Spill Containment 1491 – Monitoring Systems1635 – Guide to Ventilation design 1657 –Personnel Qualifications for Install & Maint946 – Design of DC Auxiliary Power Systems for
Generating Stations (charger sizing)
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General Sizing ConsiderationsGeneral Sizing Considerations
The battery must supply the DC power when:
1. The load on the dc system exceeds the maximum output of the charger
2. The output of the charger is interrupted3. The AC power is lost (may result in
greater dc power demand than item 2.)
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Define the System LoadsDefine the System Loads
Continuous – energized throughout the duty cycle
Noncontinuous - energized only during a portion of the duty cycle, defined duration
Momentary - short duration loads not exceeding 1 minute at any occurrence.– Lead Acid: considered a full minute,1 minute– Nickel Cadmium: for loads < 1 sec, consider
1 second
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Define Load & ApplicationDefine Load & Application
Steady Loads – typically Telecom, “long duration” 8 hour backupsKVA/KW Loads – typically UPS, “high rate, short duration” 15 minutes, KVA/KW ratingsStep Loads –Switchgear & Control –Utility Applications – “step loads” -combination of high rates and long duration
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Load ClassificationLoad ClassificationThe loads applied to the battery are
either:– Constant power (inverters, dc/dc power
supplies)
– Constant resistance (dc motor starting, relays, contactors, lights)
– Constant current (running dc motors)
For Sizing purposes, loads are treated as Constant Power or Constant Current
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Selection Factors to be ConsideredSelection Factors to be ConsideredPhysical characteristics of the cellsPlanned life of the installationFrequency and depth of dischargeCharging characteristicsMaintenance requirementsCell orientation requirementsVentilation requirementsSeismic characteristicsSpill management
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Battery Size – Nominal RatingBattery Size – Nominal Rating
Ampere-hour: 8 hour capacity of a lead acid storage battery (in the US)
– The quantity of electricity that the battery can deliver in amp-hours at the 8 hour rate.
– Example: a “2000 Ampere Hour” battery will provide 250 amps for 8 hours to 1.75 volts per cell (2000/8 = 250 amps continuously for 8 hours)
Nickel Cadmium: 5 hour or 10 hour or 20 hour rate
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Battery Size – Constant Power Rating
Battery Size – Constant Power Rating
UPS batteries are rated in Watts or kW– kW/cell x number of cells = kWb
For a specified time period to a specified end voltage, e.g.15 minutes to 1.67 volts per cell
Battery is typically sized for full load of the UPS system
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Important Sizing ConsiderationsImportant Sizing ConsiderationsOperating Temperature
– Affects the available capacity– Size for the lowest expected
temperature– At high temperatures use the rated
capacity for 77° F– High temperature affects battery life– Cold temperature affects battery
capacity– For Nickel Cadmium- see manufacturer
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Temperature Correction FactorsTemperature Correction FactorsFrom IEEE Std 485-2010
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Important Sizing ConsiderationsImportant Sizing Considerations
Aging Margin – LEAD ACID:– Replacement criteria = 80% of rated
capacity.– Battery is defined at end of life at 80%
capacity– The initial rated capacity of the
battery should be at least 125 percent (1.25 aging factor) of the load expected at the end of its service life.
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Important Sizing ConsiderationsImportant Sizing Considerations Aging – NICKEL CADMIUM:
– No defined end of life point– Capacity gradually decreases (linear)– 1.25 margin is typically used– Aging margins of 1.10 – 1.40 may apply
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Important Sizing ConsiderationsImportant Sizing Considerations
Initial Capacity– Batteries may have less than rated
capacity when delivered. Unless 100 % capacity upon delivery is specified, the initial capacity can be as low as 90% of rated capacity (per IEEE-485)
– Typical UPS and Switchgear batteries ship at 100%; Telecom at 90%
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Important Sizing ConsiderationsImportant Sizing Considerations
Nickel Cadmium
– For the float application (telecom, switchgear, UPS), make sure to use the data based on Constant Potential Float Charging.
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Important Sizing ConsiderationsImportant Sizing Considerations
Design margin– It is prudent to provide a capacity
margin to the battery sizing for unforeseen additions to the dc system and less than optimum operating conditions.
– Typical design margins are 10-15%.
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Battery SizeBattery Size Factors governing battery size:
– Maximum system voltage– Minimum system voltage– Correction factors (e.g. aging, temperature)– Duty cycle
If cells of sufficiently large capacity are not available, then two or more strings may be connected in parallel. The capacity of such a battery is the sum of the capacities of the strings.
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Number of CellsNumber of Cells
The maximum and minimum allowable system voltage (“voltage window”) determines the number of cells in the battery.
When the battery voltage is not allowed to exceed a given maximum system voltage the number of cells will be limited by the cell voltage required for satisfactory charging.
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Maximum Voltage48 Volt Telecom Example
Maximum Voltage48 Volt Telecom Example
Number of cells =Maximum system voltage
Max cell voltage required for charging
Given: 2.33 volts per cell required for equalize chargingMaximum allowable system voltage = 56 V and 54 V
56 V = 24 cells2.33 Vpc
54 V = 23 cells2.33 Vpc
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Minimum Voltage Telecom ExampleMinimum Voltage Telecom Example
Minimum battery voltage equals the minimum system voltage plus the cable voltage drop
Minimum system voltage at the equipment: 42 VDCAllowable voltage drop from battery to load: 2 VDCMinimum battery voltage: (42 + 2) = 44 VDC
Minimum battery voltage = minimum cell voltageNumber of cells
Given: the minimum allowable battery voltage is 44 Volts and the maximum number of cells is 24 or 23:
44V = 1.83 volts per cell24 cells44V = 1.91 volts per cell
23 cells
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Maximum VoltageSwitchgear ExampleMaximum Voltage
Switchgear ExampleNumber of cells =
Maximum system voltagecell voltage required for charging
Given: 2.33 volts per cell required for equalize chargingMaximum allowable system voltage either 140 V or 135 V
140 V = 60.08 cells: use 60 cells2.33 Vpc
135V = 57.94 cells: use 58 cells2.33 Vpc
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Minimum Voltage Switchgear ExampleMinimum Voltage
Switchgear ExampleMinimum battery voltage equals the
minimum system voltage plus the cable voltage drop
Minimum system voltage at the equipment: 103 VDCAllowable voltage drop from battery to load: 2 VDCMinimum battery voltage: (103 + 2) = 105 VDC
Minimum battery voltage = minimum cell voltageNumber of cells
Given: the minimum allowable battery voltage is 105 Volts and the maximum number of cells is 60 or 58:
105V = 1.75 volts per cell60 cells
105V = 1.81 volts per cell58 cells
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Maximum VoltageUPS Example
Maximum VoltageUPS Example
Number of cells =Maximum system voltage
cell voltage required for charging
Given: 2.38 volts per cell (1.250 sp. gr.) and 2.33 vpc (1.215 sp.gr.) required for equalize charging
Maximum allowable system voltage: 576 VDC
576 V = 240 cells2.38 Vpc
576 V = 247 cells: (typical 240-244 cells)2.33 Vpc
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Minimum Voltage UPS ExampleMinimum Voltage UPS ExampleMinimum battery voltage equals the
minimum system voltage plus the cable voltage drop
Minimum system voltage at the UPS equipment: 396 VDCAllowable voltage drop from battery to UPS: 4 VDCMinimum battery voltage: (396 + 4) = 400 VDC
Minimum battery voltage = minimum cell voltageNumber of cells
Given: the minimum allowable battery voltage is 400 Volts and the maximum number of cells is 244
400V = 1.67 volts per cell240 cells
400V = 1.64 volts per cell244 cells
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Sizing Example: TelecomSizing Example: Telecom
Constant Current loadsSizing for:– Load = 400 Amps for 8 hours– 24 cells, battery end voltage 1.75 vpc– Aging margin: 1.25– Design margin: 1.10– Temperature factor at 77°F: 1.00
= 400 x 1.25 x 1.10 x 1.0 = 550 Amps continuously for 8 hours to 1.75 vpc:
4,400 Ampere hour battery
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Sizing Example: UPS BatterySizing Example: UPS Battery
UPS Specifications require a 300 kW Battery (kWb) for 15 minutes, 240 cells, 400 Vdc end voltage (1.67 vpc):
– The lowest ambient temperature: 65°F– Battery must be sized for 300 kW at end of life
– 300 kWb x 1.080 (temp correction) x 1.25 (aging margin for 300 kW at end of life)
= 300 x 1.080 x 1.25 x = 405 kWb
– Select a battery that will provide 405 kW
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1.250 Specific GravityDischarge Rates in kW per Cell to 1.67Vpc at 25°C (77°F)
1.250 Specific GravityDischarge Rates in kW per Cell to 1.67Vpc at 25°C (77°F)
Type TIME
5 10 11 12 13 14 15 16 17 18 19 20 DXC-5B 0.908 0.758 0.735 0.713 0.693 0.673 0.653 0.634 0.616 0.599 0.582 0.567
DXC-7B 1.350 1.124 1.091 1.059 1.029 1.000 0.971 0.943 0.917 0.891 0.866 0.843
DXC-9B 1.785 1.483 1.437 1.395 1.355 1.317 1.280 1.245 1.212 1.179 1.148 1.117
DXC-11B 2.154 1.891 1.832 1.774 1.718 1.663 1.610 1.560 1.512 1.467 1.425 1.385
DXC-13B 2.585 2.239 2.166 2.096 2.028 1.964 1.903 1.845 1.791 1.740 1.691 1.645
DXC-15B 3.016 2.580 2.493 2.410 2.331 2.256 2.185 2.120 2.057 1.999 1.944 1.893
DXC-17B 3.447 2.908 2.808 2.712 2.622 2.538 2.459 2.387 2.319 2.255 2.195 2.139 1.900 1.707
Example: UPS System requires a 405 kWb (300kWb EOL), 240 cells for 15 minutes to 400 VDC (400/240cells = 1.67 volts per cell); 405/240 cells = 1.688 kW/cellSelect the DXC-13B at 1.903 kW/c x 240 cells = 456 kWb
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When Battery kW (“kWb”) is UnknownBut UPS kVA is Known
When Battery kW (“kWb”) is UnknownBut UPS kVA is Known
Battery kWb = kVA x p.fefficiency of inverter
kVA = kVA is the Inverter output or loadp.f. = the power factor Efficiency = the efficiency of the inverter
Battery kW = kW/cell X 1.25 for EOL Sizing# of Cells
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Sizing Example: Switchgear & Control / Utility
Sizing Example: Switchgear & Control / Utility
Duty Cycle
– Combination of continuous, noncontinuous and momentary loads
– All loads expressed in constant Current or constant Power
– Time span of the duty cycle is determined by the requirements/design
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Sizing Example: Switchgear & Control
Sizing Example: Switchgear & Control
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Sizing Example: Switchgear & Control
Sizing Example: Switchgear & Control
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Example: Substation Battery Duty Cycle
Example: Substation Battery Duty Cycle
100
AMPS
45
2min 1 239
Hours 1 2 3 4Time
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EnerSys Battery Sizing Program“BSP”
EnerSys Battery Sizing Program“BSP”
Register on-line at:
http://www.enersysreservepower.com/
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Engineer, Furnish and InstallEngineer, Furnish and InstallStandby Power Products for the Utility,
UPS and Telecom Applications Application and System Design
– Registered Electrical PE– Technicians with Electrical Contractor Licenses
Installation Services Start-up Service and Inspection Battery Load Testing Maintenance Contracts 24 Hour Emergency Service Battery Recycling/Disposal
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