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POWER FACTOR CORRECTION
WISEMAN NENE EIT – ELECTRICAL ESTON SUGAR MILL
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POWER FACTOR CORRECTION
AS A MEANS OF COST SAVINGS
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CONTENT INTRODUCTION OBJECTIVES NATURE OF ELECTRICAL POWER/LOAD
POWER FACTOR THEORY
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ADVANTAGES OF IMPROVED POWER FACTOR
DISADVANTAGES OF LOW POWER FACTOR METHODS OF IMPROVING POWER FACTOR OVERVIEW OF THE SYSTEM SYSTEM BREAKDOWN
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POWER AND COSTS SAVINGS
PROJECT COSTS COSTS RECOVERY PERIOD SAFETY AND MAINTENANCE OF THE SYSTEM CONCLUSION
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INTRODUCTION COSTS SAVINGS IS ONE OF THE MEASURE DRIVERS IN INDUSTRY FOR BUSINESS SUSTAINABILITY POWER FACTOR CORRECTION IS ONE OF THE MEANS THAT CAN BE USED TO REDUCE COSTS
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NATURE OF ELECTRICAL LOAD
Resistive - I and V peaks are simultaneous The angle between the two is zero Inductive - I lags V The angle between the two is negative Capacitive – I leads V The angle between the two is positive
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OBJECTIVES TO INVESTIGATE MEANS OF COST REDUCTION FROM THE ELECTRICAL PERSPECTIVE – (POWER FACTOR CORRECTION)
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POWER FACTOR THEORY PF = ACTIVE POWER / APPARENT POWER = P / S
= kW / kVA ACTIVE POWER (P) = kW APPARENT POWER (S) = kVA
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POWER TRIANGLE
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SYSTEM BEFORE PFC PF = 0.68 Lagging
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DESIRED MINIMUM SYSTEM TRIANGLE
PF = 0.8 Lagging
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NEW SYSTEM POWER TRIANGLE
PF = 0.92 Lagging
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ADVANTAGES OF IMPROVED PF
REDUCED APPARENT POWER PRODUCED IMPROVED PLANT EFFICIENCY ADDITIONAL LOADS CAN BE ADDED TO THE SYSTEM REDUCED OVERLOADING OF CABLES, TRANSFORMERS, SWITCHGEAR, ETC. IMPROVED NETWORK VOLTAGE IMPROVED STARTING TORQUE OF MOTORS
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DISADVANTAGES OF LOW PF
INCREASES ELECTRICITY COSTS CAUSES OVERLOADING OF GENERATORS, TRANSFORMERS AND DISTRIBUTION SYSTEM GREATER VOLTAGE DROPS AND POWER LOSSES LOW EFFICIENCY AND UNNECESSARY WEAR AND TEAR TO INDUSTRIAL ELECTRICAL EQUIPMENT REDUCES LOAD HANDLING OF THE PLANTS’ ELECTRICAL SYSTEM
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METHODS OF IMPROVING POWER FACTOR
SYNCHRONOUS MOTORS STATIC VAR COMPENSATORS STATIC CAPACITORS
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METHODS OF IMPROVING POWER FACTOR
SYNCHRONOUS MOTORS Has long service life Can withstand higher short circuit currents High maintenance and installation costs STATIC VAR COMPENSATORS Fast response system System is very expensive
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STATIC CAPACITORS Simple and easy to install Cannot be repaired
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CONNECTION TO THE NETWORK
Basic connection diagram for static capacitors
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SYSTEM CONFIGURATION 4 x 48kVAr + 3 x 50 kVAr = 342 kVAr
FRONT – END SECTION 4 x 48kVAr + 3 x 50 kVAr = 342 kVAr BACK – END SECTION = 6 x 62.5 kVAr = 375 kVAr
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SYSTEM OPERATION Manual Mode
Uses a selector switch to select a stage Automatic – using Epcos BR6000 PFC Controller Uses a selector switch to automatically select a stage
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POWER AND COSTS SAVINGS
Electrical saving in terms of the power consumed P = kW P = kW @ 0.68 PF , S = 631 kVA And at: @ 0.92 PF, S = kVA STOTAL = SOLD – SNEW = kVA I = S/√3 x 525 = A P = √3 V I Cos θ = kW
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RAND VALUE SAVING (ACTUAL)
Assuming 24 hours/day for /kWh and saving kWh, National grid Power Energy Charge Saving = x 24 x 30 x = R 43,821.89/month
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POWER SAVINGS (BACK-END)
P = kW @ 0.61 PF, SOLD = 1.48 MVA @ 0.8 PF, SNEW = 1.13 MVA STOTAL= SOLD – SNEW = 350 kVA I = S/√3 x 525 = A P = √3 V I Cos θ = 280 kW
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SAVINGS ( RAND-VALUE, BACK-END)
Assuming 24 hours/day for /kWh and saving 280 kW hourly: Energy Charge Saving = 280 x 24 x 30 x = R 81,023.04/month
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OVERALL POWER / COST SAVINGS
For 2010 season Eskom used during crushing=331.3 hrs, [ to ] Electrical Power saved; P FRONT-END = kW P BACK-END = 280 kW Total Power Saved (2010 season) = kW kW = kW = kW x 331.3hrs = MWh = kWh x R /kWh = R 57,446.00
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BUDGET & COSTS RECOVERY PERIOD
Approximately R Source: Electrical Department Budget Recoverable: Within 1 Month on National Grid
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FINAL SYSTEM PICTURES The following pictures shows the installation locations and the results obtained from the front-end section
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CONTROLLER Controller - Epcos BR6000
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CONTROL Auto and Manual Control
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CAPACITOR BANKS
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CONTROL PANELS
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MAIN PANELS
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DISPLAYS With all banks OFF
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WITH 6 BANKS ON .
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PF ALL BANKS ON PF = 0.92 Lagging
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BACK-END SECTION
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SAFETY No unauthorized person should switch the system ON/OFF.
Before opening the capacitor banks panels, make sure the main isolator is off and wait for at least 5minutes for the capacitors to discharge
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CONCLUSION As seen on the pictures in the previous slides, the new system was successful. The power factor was corrected from 0.68 lagging to 0.92 lagging in the front-end and from 0.61 to 0.8 lagging in the back-end section
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CONCLUSION cont. The costs and power savings were significant at MWh during the 4 months period recorded during the 2010 season
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ACKNOWLEDGEMENTS ESTON ENGINEERING TEAM
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THANK YOU!!! ???
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