Power Factor and Reactive Power - Power Systems Engineering ...

Power Factor and Reactive Power Ward Jewell Wichita State University Power Systems Engineering Research Center (pserc.org)

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Energy to lift a 5 pound weight 2 feet high: 2 ft x 5 lb = 10 ft-lb = 0.0000038 kWh = 0.0033 “calories” (which are actually kcal)

Value at 10.3 cents per kWh: (average residential US price, summer 2006)

0.000039 cents PSERC

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As dragline bucket lowers, motors generate, return electricity to source

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Induction motor with no load 800

energy to motor

735.249

power (watts)

600

400

200

p ( t)

0 energy from motor

0

200

400

− 465.196 600

0 0

0.002

0.004

0.006

0.008

0.01

0.012

t

0.014

time (seconds)

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0.016

0.018 0.017

Induction motor 800 735.249

power (watts)

600

average power: 130 watts

400

200

p ( t) 0

200

400

− 465.196 600

0

0.002

0

0.004

0.006

0.008

0.01

0.012

0.014

0.016

t

0.018 0.017

time (seconds)

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Incandescent lights 350 306.8

power (watts)

300

250

average power: 150 watts

200

p ( t) 150

100

50 0 0

0 0

0.002

0.004

0.006

0.008

0.01

0.012

t

0.014

time (seconds)

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0.016

0.018 0.017

0

Incandescent Lights

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Induction motor with no load

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Lights and Motor Power

Current

Voltage

Incandescent lights

0.15 kW

1.3 A

118.0 V

Induction motor with no load

0.13 kW

5.1 A

117.7 V

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Why do the Volts and Amps matter?

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Motors and Resistance Heat: 100 MW Customer voltage

Power lost in wires

Resistance Heat

12.3 kV

1.0 MW

Motors

11.7 kV

2.3 MW

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Incandescent Lights

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Incandescent lights power: Power = 118 V x 1.3 A = 153 W = 0.15 kW = power measured by meter

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Incandescent Lights

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Induction motor with no load

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Induction motor power: 117.7 V x 5.1 A = 600 W? = 0.6 kW? NOT the power measured by meter

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Induction motor with no load

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Define some new values: Apparent power = volts x amps For the motor: 117.7 V x 5.1 A = 600 VA = 0.6 kVA VA: volt-ampere PSERC

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Define some new values: Power Factor = Average (“real”) (kW) power Apparent (kVA) power For the motor: pf = 0.13 kW / 0.60 kVA pf = 0.22

VI2 – average power2 2

2

( 0.60kVA) − ( 0.13kW) = 0.59 kVAR

0.58 kVAR

reactive power = 0.58 kVAR

reactive power =

Appa rent p ower =

Define some new values: the power triangle for the motor:

0.60 kVA

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VAR: volt-ampere reactive real power = 0.13 kW PSERC

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Induction motor with no load

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Lights and Motor Real Reactive Apparent Power Current Voltage power factor power Power Incandescent lights

0.15 kW

0 kVAR

0.15 kVA

1.0

1.3 A

118.0 V

Induction motor with no load

0.13 kW

0.58 kVAR

0.60 kVA

0.22

5.1 A

117.7 V

Note: the motor’s reactive power will stay near its no-load value of 0.58 kVAR as its load and real power (and thus apparent power and power factor) vary from no load to full load. PSERC

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Power factor and reactive power are indicators of „ „

power losses in wires voltage drop between supply and load

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Typical Power Factors Induction motor

0.7-0.8

Resistance heat

1.0

Incandescent lights

1.0

Fluorescent lights

0.6-1.0

Battery Chargers

0.6-1.0

Computers

0.5-1.0

Variable Speed Motor Drives

0.5-1.0

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Power factor: lagging or leading?

Most loads with lower power factor are inductive. Current lags voltage. Power factor is “lagging.”

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Induction motor with no load

voltage

current

3.6 ms

Current lags voltage by about 3.6 milliseconds

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Another way to calculate power factor

16.7 ms

3.6 ms

One 60 Hz cycle = 1/60 seconds = 16.7 ms PSERC

Another way to calculate power factor: “displacement” power factor (3.6 ms / 16.7 ms) x 360 degrees = 77 degrees current lags voltage by 77 degrees cosine (77 degrees) = 0.22 power factor is 0.22 lagging pf = cos θ θ = angle between voltage and current PSERC

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Incandescent lights

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Current and voltage are “in phase.”

Incandescent lights: displacement power factor: angle between voltage and current = 0 degrees pf = cos(0 degrees) = 1.0

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true power factor: pf = 0.15 kW / 0.15 kVA pf = 1.0

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If voltage and current are sinusoidal displacement pf (DPF) = true pf (PF)

lights

motor

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Correcting (increasing) power factor

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Capacitors to improve power factor: capacitors release energy when inductors consume 1.2 1

Capacitor current

0.5

iL( t) 0 ic ( t)

Inductor current

0.5

1 − 1.2 0

0.002

0.004

0.006

0.008

0

0.01 t

0.012

0.014

0.016

0.018 0.017

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Induction motor with power factor correction capacitor

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Induction motor with power factor correction capacitor Real Reactive Apparent power power power

Power factor

Current Voltage

Induction motor

0.13 kW

0.58 kVAR

0.60 kVA

0.22

5.1 A

117.7 V

Induction motor with capacitors

0.13 kW

0.11 kVAR

0.18 kVA

0.96

1.5 A

118.4 V

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Wire losses: motors with capacitors Customer voltage

Power lost in wires

Motors

11.7 kV

2.3 MW

Motors with power factor correction capacitor

12.3 kV

1.0 MW

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Incandescent lights with power factor correction capacitor

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Incandescent lights with power factor correction capacitor

Incandescent lights Lights with capacitors

Real Reactive Apparent power power power 0.15 0 kVAR 0.15 kVA kW 0.15 kW

0.64 kVAR

0.66 kVA

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Power factor 1.0

0.23 leading

Current Voltage 1.3 A

118.0 V

5.5 A

119.9 V

Wire losses: lights with capacitors Customer voltage

Power lost in wires

Resistance heat

12.3 kV

1.0 MW

Resistance heat with power factor correction capacitors

13.0 kV

2.0 MW

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Leading power factor Current leads voltage in a capacitor. Too much capacitance causes low leading power factor. (just as bad as low lagging power factor)

Leading power factor causes high voltage and increased wire losses. Use the correct amount of capacitance. (more is not better)

Switch capacitors off when motors are off (just put capacitor on same switch as motor) PSERC

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If voltage and current are sinusoidal displacement pf = true pf

lights

motor PSERC

If waveform is not sinusoidal: PC voltage and current

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If waveform is not sinusoidal: PC voltage and current

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Harmonic distortion

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Low power factor caused by harmonic distortion cannot be corrected by capacitors Harmonic currents are not accompanied by harmonic voltage, so average (real) power in harmonics is almost zero. pf = average power / apparent power decreases PSERC

Common harmonic loads „ „ „ „ „ „

computers motor drives battery chargers rectifiers induction heaters arc furnaces

To correct low power factor caused by distorted current waveforms, the harmonic currents must be filtered. PSERC

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Capacitors can make harmonic distortion worse:

Lights with power factor correction capacitor

This is rare, but should be considered in the presence of harmonic loads

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Summary „

„ „

„ „ „ „

Induction motors and other inductive equipment load the electric power system differently than incandescent lights and resistive heaters Power Factor and Reactive Power are indicators of power lost in wires and reduced customer voltage Low displacement power factor caused by induction motors (and other inductive loads) can be corrected with power factor correction capacitors Power factor correction capacitors must be sized properly Power factor correction capacitors cost much less than utility power factor charges and will eliminate those charges Power factor correction capacitors should be disconnected when motors are disconnected Low harmonic power factor is corrected with filters, not capacitors. Capacitors may make it worse.

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Ward Jewell 316.978.6340 [email protected] pserc.org (slides are posted under “presentations”)

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