ups / inverter batterys product details and application engineering
DESCRIPTION
By Mr. A S NagrajTRANSCRIPT
UPS/INVERTER BATTERS PRODUCT DETAILS AND APPLICATION ENGINEERING
- A.S.NAGARAJ
V.P.TECHNICAL
What is an inverter? An inverter is an electrical device that converts direct
current (DC) to alternating current (AC); the converted AC can be at any required voltage and frequency with the use of appropriate switching, and control circuits
Specifications and standards: IS 13369 Stationary lead - acid batteries (with tubular
positive) in mono block containers
Sizing CalculationsExample of Load Calculations Suppose you were to run a microwave oven for 10 minutes a day, which draw about 1000
Watts, despite their size. To keep it simple, think of the inverter as electrically transparent. In other words, the 1000 Watts required to run the oven come directly from the batteries as if it were a 12 VDC microwave. Taking 1000 Watts from a 12-Volt battery requires the battery to deliver approximately 84 Amps.
(1000 Watts ÷ 12 Volts = 84 Amps) A full-sized refrigerator draws about 2 Amps at 120 Volts AC. By multiplying 2 Amps x 120
Volts, you find out the refrigerator uses 240 Watts. The batteries will need to deliver 20 Amps to run the refrigerator
(240 Watts/12 Volts = 20 Amps). Typically, refrigerators operate about 1/3 of the time (1/3 "duty cycle"), or 8 hours a day.
Therefore, the A.H. drain will be 160 A.H.
(8 hours x 20 Amps = 160 A.H.). After the load and running time is established, the battery bank size can be calculated. The
first calculation is to divide the load (in Watts) by 10 for a 12-Volt system or by 20 for a 24-Volt system resulting in the number of Amps required from the battery bank.
Example of Input Calculations
1. Total Watts = 1000 W
2. Amps from 12-Volt battery = 1000 ÷ 10 = 100 Amps DC
3. Amps from 24-Volt battery = 1000 ÷ 20 = 50 Amps DC
Next, the number of DC Amps must be multiplied by the time in hours that the load is to operate.
Example of Amp-Hour Calculations
If the load is to operate for 3 hours:
For a 12-Volt battery: 100 Amps DC x 3 hours = 300 A.H.
For a 24-Volt battery: 50 Amps DC x 3 hours = 150 A.H.
Now, the proper type and amount of batteries must be selected. Traction batteries, (also called deep cycle or golf cart type), should be used in order to be able to handle the repeated discharge/charge cycles that are required.
Battery Selection Chart
Electrical LoadTV
Recommended Inverter rating(VA)
Wattage Battery Voltage
Recommended Power Build battery (In AH) For backup of
1 2 3 4 5
1 Fan + 1 Tube light 150-200 190 12 16 32 48 63 79
2 Fans + 1 Tube light 200-250 310 12 26 52 78 103 129
2 Fans + 2 Tube Lights 300-350 380 12 32 63 95 127 158
1 Fan + 1 Tube light + TV 250-300 390 12 33 65 98 130 163
2 Fans + 1 Tube light + TV 350-400 510 12 43 85 128 170 213
3 Fans + 3 Tube Lights 400-450 570 12 48 95 143 190 238
TV 200FAN 120
TUBE LIGHT 70
General Wattage:
Basic parts of inverter
Take any Inverter and you will find the 3 basic parts Charger Unit Control Unit Inverter Unit
How The Charger Circuit works
The Charger Unit coupled with Electronic Circuit charges the Battery till it is fully charged. An electronic overcharge cut out stops further charging of Battery thus preventing damage to the Battery.
The example could be just as in any Water Tank. Once the water gets filled up to a specific mark, the BALL COCK stops water inflow. This is a mechanical phenomenon.
In Inverter similar action is achieved electronically.
How control circuits work A Control unit is responsible for all the activities of Charger and Inverter
Circuits. It is just like a Mini Computer that acts automatically through the set of desired commands.
It directs the Charger Circuit to charge the Battery during Mains presence. It starts Inverter Circuit upon power failure.
Battery Models for Inverters
Model NominalVoltage
Rated Capacity (AH) at 27oC Dimensions Dry wt.(Kgs.)
Wet wt.(Kgs.)
Acid Vol. (Ltrs)20 hr 10 hr 5 hr 3 hr 2 hr 1 hr L*B*H(mm)
S T Series-Standard Tubular Batteries
80ST 12V 75 60 50 43 38 30 410*172*245 18 28 8
100ST 12V 100 80 67 57 51 40 512*210*250 28 41.5 12
120ST 12V 120 100 80 68 61 48 518*273*255 33 45 10.8
E T Series-Tall Tubular batteries
120 ET 12V 120 100 80 68 61 48 502*185*380 32 57.4 21
150 ET 12V 150 120 101 86 77 60 502*185*380 37 61.8 20.5
180 ET 12V 180 145 121 103 92 72 502*185*380 43 66.5 19.2
200 ET 12V 200 160 134 114 102 80 502*185*380 53.5 74.6 18
PRODUCT CLASS Vs APPLICATION MATRIXIT SERIES TUBULAR
IS 13369 - 1992
YES YES YES
T SERIES TUBULAR
IS 13369 - 1992 YES YES YES
F SERIES FLAT IS 13369 - 1992 YES YES YES
ZIP ET SERIES TUBULAR
IS 13369 - 1992 YES YES YES
ZIP T SERIES TUBULAR
IS 13369 - 1992 YES YES YES
ZIP F SERIES INVERTER
IS 13369 - 1992 YES YES YES
STATIONARY TUBULAR
IS 1651 YES YES YES
HR EL SERIES IS 1651 YES YES YES
HR SERIES IS 1651 YES YES YES
AUTOMOTIVE IS 14257 - 1995 YES YES
PRODUCT CLASS
SPECIFICATION INVERTER SOLAR UPS RAILWAYS S & T
SLI DG START
APPLICATION
PR
OD
UC
T
CLA
SS
PRODUCT CLASS Vs TARGETED MARKETPRODUCT CLASS
BRAND JAR & COVER
NOMINAL RATING
MODEL CAP ( Ah)
FAST MOVING SLOW MOVING
TARGET APPLICATION
ZIP T SERIES TUBULAR
ZIP TUBULAR 36 MONTHS WARRANTY PP C10 20 T
40 T60 T80 T100 T100 TB120 TUNIK
20406080100105120105
FAST MOVE
FAST MOVE
SLOWSLOWSLOWSLOW
SLOW
SLOW
INVERTERUPSSOLAR
ZIP F SERIES INVERTER
ZIP LOW MAINTENANCE PP C10 100 F
130 F150 F180 F
100120150180
SLOWSLOWSLOWSLOW
INVERTERUPSSOLAR
PRODUCT CLASS Vs TARGETED MARKETPRODUCT CLASS BRAND JAR &
COVERNOMINAL RATING
MODEL CAP ( Ah)
FAST MOVING SLOW MOVING
TARGET APPLICATION
IT SERIES TUBULAR
CAPTAIN PP C20 1200 IT1500 IT1800 IT2000 IT
120150180200
FAST MOVEFAST MOVE
SLOWSLOW
INVERTERUPSSOLAR
T SERIES TUBULAR
JUMBO GOLD PP C10 20 T40 T60 T80 T100 T100TB120 TUNIK
20406080100105120105
FAST MOVE
FAST MOVE
SLOWSLOWSLOWSLOW
SLOW
SLOW
INVERTERUPSSOLAR
F SERIES FLAT JUMBO SILVER PP C10 100 F130 F150 F180 F
100120150180
SLOWSLOWSLOWSLOW
INVERTERUPSSOLAR
ZIP ET SERIES TUBULAR
ZIP 42 MONTHS WARRANTY
PP C20 120 ET150 ET180 ET200 ET
120150180200
FAST MOVEFAST MOVE
SLOWSLOW
INVERTERUPSSOLAR
PRODUCT CLASS Vs TARGETED MARKETPRODUCT CLASS
BRAND JAR & COVER
NOMINAL RATING
MODEL CAP ( Ah)
FAST MOVING SLOW MOVING
TARGET APPLICATION
STATIONARY TUBULAR
IRS SERIES HR C10 PBS 20PBS 40PBS 60PBS 80PBS 100PBS 120PBS 150PBS 200PBS 300PBS 400PBS 500PBS 600PBS 700PBS 800PBS 900PBS 1000
204060801001201502003004005006007008009001000
FAST MOVE
FAST MOVE
FAST MOVE
SLOWSLOWSLOW
SLOW
SLOW
SLOWSLOWSLOWSLOWSLOWSLOWSLOWSLOW
1) TRAIN LIGHTING2) SOLAR3) ELECT RICITYBOARDS
PRODUCT CLASS Vs TARGETED MARKETPRODUCT CLASS
BRAND JAR & COVER
NOMINAL RATING
MODEL CAP ( Ah)
FAST MOVING SLOW MOVING
TARGET APPLICATION
HR EL SERIES HR C20 80 EL100 EL120 EL140 EL
80100120140
SLOWSLOWSLOWSLOW
INVERTERUPSSOLAR
HR SERIES HR C10 40 HR60 HR80 HR100 HR120 HR150 HRJ180 HRJ200 HRJ
406080100120150180200
SLOWSLOWSLOWSLOWSLOWSLOWSLOWSLOW
INVERTERUPSSOLAR
PRODUCT CLASS Vs TARGETED MARKETPRODUCT CLASS BRAND JAR & COVER NOMINAL
RATINGMODEL CAP
( Ah)
FAST MOVING
SLOW MOVING
TARGET APPLICATION
AUTOMOTIVE TRUCK MASTER PP C20 NS 40
N-50N-70N-88 TRN-100N-120N-150N-180N-200
36607588100120150180200
FAST MOVE
FAST MOVE
FAST MOVE
SLOWSLOW
SLOWSLOW
SLOWSLOW
AUTOMOTIVE & DG STARTING
Pricing
Description 150 120 100 80
BOM Price 4.67 5.61 5.70 6.45
Overheads 1 1 1 1
Profit Margin 0.75 0.75 0.75 0.75
Economic selling priceESP/Basic
6.42 7.36 7.45 8.20
Example for pricing calculation:
Model
Basic Price for Distributor
/OEM
Distributer/OEM Price with Vat @
13.5%
Distributer /OEM Margin
10%
Distributer /OEM price with Margin
10%
Dealer basic with VAT
13.5%
Dealer Margin(35%)(MRP)
MRP with VAT 13.5%
20ST 1200 1362 136 1498 1700 2296 260640ST 2400 2724 272 2996 3401 4591 521160ST 3600 4086 409 4495 5101 6887 781780ST 4560 5176 518 5693 6462 8723 9901
100ST 5700 6470 647 7116 8077 10904 12376120ST 6840 7763 776 8540 9693 13085 14851
Models wise price/AH for N-series:
BOM ET SERIES
PRICE CALCULATION SHEET
COMPETITOR SURVEY FOR INVERTER BATTERIES
COMPETITORS SURVEY EXIDE SOUTHERN LUMINOUS OKAYA SU-KAM RELICEL EASTMAN – ADDO ORCHID
EXIDE INVERTER BATTERIES INVARED 300, 400,500,500+ with capacities of 80 Ah, 506 Ah, 506 ah, 506 ah
respectively is rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr) INVAQUEEN 300, 450, 500+, 500+MF with capacities of 90ah, 135 Ah, 150 Ah,
150 ah respectively is rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr) INVA GOLD 500( THE PREMIUM AKKUMULATOREN) with capacity of 150 Ah
rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr) INVATUBULAR IT 500i with capacity of 150 Ah rated at C 20 @ 27 Deg C upto
1.75 ECV ( 1.280 Sp.gr) INVATUBULAR IT400, 500,550,650 with capcities of 110Ah, 150 ah, 165 Ah,
200 Ah respectively is rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr) INVAFLAT 1800, 2000 with capacities of 180 Ah, 200 Ah with capcities of
110Ah, 150 ah, 165 Ah, 200 Ah respectively is rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr)
INVASAFE 250, 600, 800 with capacities of 60 Ah, 150 ah, 200 ah respectively is rated at C 20 @ 27 Deg C upto 1.75 ECV ( 1.280 Sp.gr)
LUMINOUS INVERTER BTY DETAILS
TYPE NOMINAL VOLTAGE
CAPACITY @ C20
LENGTH WIDTH HEIGHT ELECTROLYTE VOLUME
AH mm mm mm Litres
ILT 18000 12 150 518 275 265 14.50
ILT 22000 12 180 518 275 265 17.40
ILTT 18000 12 150 500 187 430 19.30
SUKAM INVERTER BTY DETAILS – NO SPEC REFERENCE
S.No Battery Type Volts Capacity @ C20
Dimensions
AH mm L(mm) W(mm) H(mm)
1 SBT 1500 12 150 503 191 410
2 SBT 1800 12 180 503 191 410
RELICEL INVERTER BTY DETAILS – BIS 13369 - 1992
S.No
Model Voltage
RATED CAPACITY ( Ah @ 27 Deg C ) Dimensions ( mm ) Bty Weight(Kgs)
Acid Volume ( Lites)
20 Hr
10 Hr 5 Hr 3 Hr 2 Hr 1 Hr L W H Dry Wet
1 REL 100T 12 100 80 67 57 51 40 513 215 250 23 39 13.2
2 REL 120T 12 120 100 83 72 64 50 513 215 250 28 44 12.7
3 REL 135T 12 135 115 96 82 71 56 515 275 270 34 52 15
4 REL 135T 12 150 120 100 86 76 60 518 275 265 37 55 14.5
RELICELL STANDARD TUBULAR BATTERIES
RELICELL TALL TUBULAR BATTERIESS.No
Model Voltage RATED CAPACITY ( Ah @ 27 Deg C ) Dimensions ( mm ) Bty Weight(Kgs)
Acid Volume ( Lites)
20 Hr
10 Hr 5 Hr 3 Hr 2 Hr 1 Hr L W H Dry Wet
1 REL 120XLTT 12 125 100 83 72 64 50 452 180 390 31 49 14.5
2 REL 150XLTT 12 150 120 100 86 76 60 452 180 390 37 55 14
3 REL 190XLTT 12 190 150 125 108 95 75 505 190 415 44 65 20.8
4 REL 210XLTT 12 220 180 150 129 114 90 505 190 415 52 71 18
SOUTHERN BATTERIES – HI POWER TUBULAR BATTERIES – NO SPEC REFTYPE CAP @ 10
Hr @ 27 Deg C
Discharge Current @ 10 Hr rate to an ECV 1.80
OVERALL DIMENSIONS ACID VOLUME
AH AMPS L( mm) W(mm) H(mm) Litres
12 V RANGE
6SB 20 UPS 20 2 510 222 260 126SB 40 UPS 40 4 510 222 260 11.46SB 60 UPS 60 6 510 222 260 11
6SB 80 UPS 80 8 510 280 265 14.1
6SB 100 UPS 100 10 510 280 265 13.8
6SB 120 UPS 120 12 510 280 265 12.5
SOUTHERN BATTERIES – HI POWER XL TUBULAR BATTERIES – NO SPEC REFTYPE CAP @ 10
Hr @ 27 Deg C
Discharge Current @ 10 Hr rate to an ECV 1.80
OVERALL DIMENSIONS ACID VOLUME
AH AMPS L( mm) W(mm) H(mm) Litres
12 V RANGE
6SB 80 UPS 80 8 440 185 410 12.46SB 100 UPS 100 10 440 185 410 12.66SB 120 UPS 120 12 440 185 410 11.8
6SB 130 UPS 130 13 440 185 410 11.5
SOUTHERN BATTERIES – HI POWER XL SUMO TUBULAR BATTERIES – NO SPEC REFTYPE CAP @ 10
Hr @ 27 Deg C
Discharge Current @ 10 Hr rate to an ECV 1.80
OVERALL DIMENSIONS ACID VOLUME
AH AMPS L( mm) W(mm) H(mm) Litres
12 V RANGE
12V150AH 150 15 510 244 432 2512V180AH 180 18 510 244 432 2412V200AH 200 20 510 244 432 23.5
12V220AH 220 22 510 244 432 22
12V240AH 240 24 510 244 432 21.5
Power Build catalogue
Test Reports
Distributer & Dealer policy
PLEASE PROVIDE CLAUSE WISE COMPLIANCE AND REMARKS TO THE POINTS GIVEN BELOW ON YOUR COMPANY LETTER HEAD WITH AUTHORISED SIGNATORY AND COMPANY STAMP BEFORE SIGNING THE CONTRACT
Dt 05.02.2011 DOCUMENT No : Mktg / 01 / 11-12
PBB (POWERBUILD BATTERIES) DISTRIBUTOR POLICY
1) Depending on the market, the distributor deposits the amount, for which fixed bank interest
for the current year will be paid by PBB at the end of the year.
2) He gets a credit for 30 days; however 40 days post dated cheque to be provided against
proforma invoice.
3) He assures monthly quantities for which PBB will plan and dispatch
4) 1 % of the basic total billing will be spent on the advertisements (promotional expenses).
The actual expenses incurred for advertisement and promotional expenses shall be
reimbursed by PBB on production of original bills.
5) The distributor shall submit all the company registration certificates along with sales tax,
VAT returns
6) Geographical periphery has to be clearly defined
7) In case he employs a sub-distributor under clear intimation to PBB.
8) Generally 3 to 4 districts will be handled by one sub-distributor.
9) Under one sub-distributor may be 5 to 10 dealers can be there depending on market
conditions
10) He should have sufficient godown facility with initial charging
11) The tenure of the contract will be one year, renewable every year depending mutual
consent and performance from both sides.
UPS (Uninterrupted Power Supply)
What about UPS (Uninterrupted Power Supply) An Uninterruptible Power Supply (UPS) is a device connected between the power source and a computer to ensure that electrical flow is not interrupted. UPS devices use batteries to keep the computer running for a period of time after a power failure
The UPS consists of three main components:1) Rectifier: Stores line power in the battery after converting the AC power into DC power. Power disruptions only affect the battery charging process because the battery is being charged by the rectifier.2) Battery: Stores the power for use when the power source is interrupted, and determines the length of time the UPS will support your equipment.3) Inverter: Converts the battery DC power into AC power for the equipment. The inverter supplies continuous power to the computer just as the battery provides uninterrupted power to the inverter.
Executive Summary At its most basic, a UPS is designed to provide backup power to support continuing operation of electrical or electronic devices in the event of a power failure. Today’s UPS systems usually also provide some level of power conditioning and protection against fluctuations in voltage from the grid.
There are four types of UPS architectures in use today: 1.Online or Double Conversion2. Line Interactive 3. Offline (Standby) 4. Controlled Ferro-resonant (CFR).
•
1. Offline (Standby) UPS
typical offline backup power supply will continuously provide power with some filtering (typically the same as on a surge protection power strip) from the utility. When utility power fails, the device will start its internal inverter, and then mechanically transfer from utility power to inverter output. Pros Low cost: can be widely implemented in an organization Small size: unobtrusive Simple design: little or no training required to understand full functionality Cons No power conditioning Slow transfer time Simple battery charger may shorten battery life and increase recharge time Limited additional functionality may not meet enterprise needs Short back-up time
2. Line Interactive During normal operation, the Line Interactive UPS takes utility power and passes it through a transformer with various tap selections on the output. When utility power is high, the Line Interactive UPS selects a tap to lower (buck) the output voltage. Similarly, when the utility voltage is low, the UPS selects a tap to increase (boost) the output voltage. Pros Low Cost Sine Wave Output Wider Input Range Buck & Boost regulation Efficient Surge Protection EMI/RFI/Noise Suppression
Cons Minimal Load Protection 4-6 ms transfer time Spike and surge protection components degrade over time
3.Controlled Ferro Resonant UPS A Controlled Ferro Resonant UPS operates in the same manner as a line interactive UPS, however its transformer can hold the voltage on the load side long enough for the inverter to begin providing input power, eliminating transfer time. It also provides complete isolation from input to output, protecting against all kinds of noise. Pros Best spike & surge protection with complete output isolation. Zero transfer time On-Line Power 100% Power Conditioning Input Power Factor Correction Better Output Flexibility Longer Service Life Expectancy
Cons Larger/Heavier Higher Heat Output More Expensive Can be problematic with power factor corrected loads1
4.Online (Double Conversion) The Online or Double Conversion UPS continuously rectifies incoming AC power to DC power to supply the internal DC bus of the UPS. The output inverter takes the DC power and produces regulated AC power to support the critical load. During an outage, the inverter continues to operate, drawing power from the batteries and the load sees no transfer time. Pros Zero transfer time Excellent surge and noise suppression Constant voltage output. 100% Power Conditioning Input Power Factor Correction Cons Higher Heat Output More Expensive Lower Efficiency No Neutral Conditioning Low MTBF Higher battery TCO
Types of battery Technologies
Although energy reserve technologies such as fuel cells, flywheels, and Nickel Cadmium batteries are being explored, today data center and network room UPS systems almost exclusively use Lead acid batteries with one of the following three Technologies: Vented (flooded or wet cell) - The oldest of the technologies is the flooded (or vented) cell. Commonly used in automotive and marine applications, this technology is predominantly used in UPS applications above 500 kVAValve Regulated (VRLA) - VRLA batteries have been utilized for approximately 20 years. This technology offers a higher power density and lower capital costs than traditional flooded cell solutions. VRLA batteries are typically deployed within power systems rated below 500kVA. Modular Battery Cartridges (MBC) - MBC battery technology was introduced several years ago. This solution utilizes modular, multi-cell VRLA cartridges arranged in a parallel-series architecture that allows for easy installation and replacement.
Installation requirements as a function of battery technology
Flooded VRLA MBC
Site specific battery rack/frame design Yes Varies No
Mechanical assembly required at site Yes Varies No
Site specific engineering required Yes Varies No
Field Wiring (electrical connections) Yes Varies No
Hazardous material per DOT regulations Yes No No
Acid filling required Yes No No
Potential Shock hazard when handled Yes Yes No
Life Expectancy Life expectancy varies with battery type. Flooded cell systems traditionally enjoy long lifetimes provided that they are regularly maintained and serviced. VRLAs and MBCs are sealed systems that do not require or even permit the maintenance needed on flooded batteries. As a result, the lifetime of these battery types is significantly shorter than flooded cell systems. as shows the battery lifetime expectations.
Life expectancy Flooded VRLA Large
VRLA Medium
VRLA Small
MBC
Design Life 20 Years 20 Years 7-10 Years 5 Years 7-10 Years
Expected lifetime 15 Years 7-13 Years 5 Years 3 Years 3-5 Years
Failure modes
Internal and external components of avalve-regulated lead-acid (VRLA) battery.
Battery cell short due to positive grid growth oxidation
What is thermal runaway?Thermal runaway occurs when the heat generated in a lead-acid cell exceeds its ability to dissipate that heat, which can lead to an explosion, especially in sealed cells. The heat generated in the cell may occur without any warning signs and may be caused by overcharging, excessive charging, internal physical damage, internal short circuit or a hot environment.
Simplified Illustration of Power Conversion Steps
Operating principles 1 Single static DC UPS unit This basic DC UPS set-up shall be considered as the minimum requirement for a secured DC power source. It shall also be used to build up more complex multi-unit architectures.
2 Parallel redundant static DC UPS unit A parallel redundant system shall comprise at least two DC UPS units, which are paralleled at the output through blocking diodes. This allows a significant increase of the system’s availability and improves the total power capability in regard to overloads and short circuits.
S.No PARAMETER DESCRIPTION VALUE UNITS REMARKS
1 SYSTEM WATTAGE RATING 5000 WATTS
2 SYSTEM VOLTAGE 48 VOLTS
3 DISCHRAGE CURRENT 104 AMPS
=Sys Wattage Rating / Sys Volts
4 END CELL VOLTAGE 1.9 VOLTS
5 MIN AMBIENT TEMP 10 Deg C
6 BACK UP TIME 120 MINUTES
7 AGEING FACTOR 1.25
8 SAFETY FACTOR 1.1
9 TEMP CORRECTION FACTOR 1.19
10 BATTERY CAPACITY 330Ah
TEMP CORRECTION FACTOR TABLE
CELL TEMP ( Deg C ) CORRECTION FACTOR
-5 1.52
0 1.39
10 1.19
25 1
30 0.96
40 0.89
50 0.85
METHOD 1 (Recommended for UPS Application)
FORMULA CALCULATION
BTY CAP = Rated cap at 27 Deg C X Ageing Factor X Temp Correction Factor X Safety Factor
BTY CAP= 330 X 1.25 X 1.19 X 1.1
=540Ah
METHOD 2 (Recommended for Sub- Station Applications)
FORMULA CALCULATION
BTY CAP = Discharge Current X K - Factor X Ageing Factor X Temp Correction Factor X Safety Factor
BTY CAP= 104 X 3.23 X 1.25 X 1.19 X 1.1
=550Ah
K-FACTORS at 27OC)
DISCHARGE TIME (MINUTES)
END CELL VOLTAGE
1.90V 1085V 1.80V 1.75V 1.70V 1.60V
5 0.74 0.68 0.67 0.64 0.57 0.52
10 0.92 0.85 0.83 0.79 0.69 0.67
15 1.08 1.02 0.97 0.93 0.84 0.78
30 1.44 1.03 1.29 1.22 1.14 1.11
60 1.96 1.85 1.75 1.69 1.59 1.56
120 3.23 2.99 2.86 2.74 - -
180 4.26 3.92 3.77 3.64 - -
300 6.67 6.25 5.88 5.71 - -
480 9.52 9.09 8.33 8 - -
600 11.76 10.53 10 10 - -