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Understanding of Harmonics in Power Distribution System

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Understanding of Harmonics in Power Distribution System Dr. Adel. M. Sharaf Department of Electrical & Computer Engineering University of New Brunswick – PowerPoint PPT presentation

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Title: Understanding of Harmonics in Power Distribution System


1
Understanding of Harmonics in Power Distribution
System
  • Dr. Adel. M. Sharaf
  • Department of Electrical Computer Engineering
  • University of New Brunswick

2
Outline
  • Power System Harmonics?
  • Why Harmonics are Troublesome?
  • Nonlinear Loads Producing Harmonic Currents
  • Harmonic Distortion?
  • Negative Effects of Sustained Harmonics
  • Mitigation of the Effects of Harmonics
  • Evaluation of AC Power System Harmonics?
  • Conclusions
  • References

3
What are Power System Harmonics?
  • Harmonic a mathematical definition, generally
    used when talking about Integral orders of
    Fundamental frequencies
  • Power system harmonics currents or voltages with
    frequencies that are integer multiples
    (h0,1,2,N) of the fundamental power frequency
    1
  • 1st harmonic 60Hz
  • 2nd harmonic 120Hz
  • 3rd harmonic 180Hz

  • Figure 1 2



4
How are Harmonics Produced ?
  • Power system harmonics presenting deviations
    from a perfect sinusoidal-waveform (voltage or
    current waveform).
  • The distortion comes from a Nonlinearity caused
    by saturation, electronic-switching and nonlinear
    electric loads, Inrush/Temporal/Arc/Converter/Limi
    ter/Threshold Type Loads.

  • Figure 2 1

5
Why Bother about Harmonics?
  • 50-60 of all electrical Ac Systems in North
    America operate with non-linear type loads
  • Power-Quality-PQ Issues Problems
  • Damage to Power Factor Correction capacitors
  • Waveform Distortion can create SAG/SWELL/NOTCHING/
    RINGING/
  • All can cause damage effects to consumer loads
    and power systems due to Over-Current/Over-Voltage
    or Waveform Distortion
  • Additional Power/Energy Losses

6
Loads Producing Harmonic Currents
  • Electronic lighting ballasts/Controls
  • Adjustable speed Motor-Drives
  • Electric Arc Welding Equipment
  • Solid state Industrial Rectifiers
  • Industrial Process Control Systems
  • Uninterruptible Power Supplies ( UPS )systems
  • Saturated Inductors/Transformers
  • LAN/Computer Networks

7
Current vs. Voltage Harmonics
  • Harmonic current flowing through the AC Power
    System impedance result in harmonic voltage-drop
    at the load bus and along the Feeder!!
  • Figure 3 3

8
How to Quantify Harmonic Distortion?
  • Total Harmonic Distortion-THD the contribution
    of all harmonic frequency Currents/Voltages to
    the fundamental current. 3
  • The level of THD-for Current or Voltage is
    directly related to the frequencies and
    amplitudes of the Offending Quasi-Steady State
    persistent Harmonics.
  • Individual Distortion Factor-(DF)-h quantify
    Distortion at h harmonic-order

9
Calculation of THD
  • THD Ratio of the RMS of the harmonic content to
    the RMS of the Fundamental 3

  • (Eq-1)
  • Current THD-I

  • (Eq-2)
  • Voltage THD-V

  • (Eq-3)

10
Negative Effects of Harmonics
  • Overheating and premature failure of distribution
    transformers 1
  • Increasing iron and copper losses or eddy
    currents due to stray flux losses
  • Overheating and mechanical oscillations in the
    motor-load system 1
  • Producing rotating magnitude field, which is
    opposite to the fundamental magnitude field.
  • Overheating and damage of neutral ground
    conductors 2
  • Trouble sustained type Harmonics 3rd, 9th, 15th
  • A 3-phase 4-wire system single phase harmonic
    will add rather than cancel on the neutral
    conductor
  • Malfunction/Mal-Operation of Sensitive
    Tele-control and Protection Relaying

11
Negative Effects of Harmonics (cont d)
  • False or spurious Relay operations and trips of
    circuit breakers 2
  • Failure of the Firing/Commutation circuits, found
    in DC motor-drives and AC drives with silicon
    controlled rectifiers (SCR-Thyristor) 1
  • Mal-Operation instability of voltage regulator
    1
  • Power factor correction capacitor failure 1
  • Reactance (impedance)-Zc of a capacitor bank
    decreases as the frequency increases.
  • Capacitor bank acts as a sink for higher harmonic
    currents.
  • The System-Series and parallel Resonance can
    cause dielectric failure or rupture the power
    factor correction capacitor failure due to
    Over-Voltages Over-Currents.

12
Harmonics and Parallel Resonance Circuit
  • Harmonic currents produced by variable speed
    motor-drives can be amplified up to 10-15 times
    in parallel resonance circuit formed by the
    capacitance bank and network inductance 5
  • Amplified/intensified harmonic currents leading
    to internal overheating of the capacitor unit.
  • Higher frequency currents causing more losses
    than 60hz currents having same amplitude
  • Figure 4 Parallel resonance circuit
    and its equivalent circuit 5

13
Harmonics and Series Resonance Circuit
  • The voltage of upstream AC Network can be also
    distorted due to series/parallel resonance
    formed by capacitance of the capacitor bank and
    System/load inductance Ca cause high harmonic
    current circulation through the capacitors 5
  • Parallel Resonance can also lead to high voltage
    distortion.

Figure 5 Series resonance circuit and its
equivalent circuit 5
14
Measure Equipments of Harmonics
  • Digital Oscilloscope
  • Wave shape, THD and Amplitude of each
    harmonic
  • True RMS Multi-Meter
  • Giving correct readings for distortion-free
    sine waves and typically reading low when the
    current waveform is distorted
  • Use of Harmonic Meters-Single Phase or three
    Phase

  • Figure 6 True RMS Multi-Meter 3

15
Standards for Harmonics LimitationIEEE/IEC
  • IEEE 519-1992 Standard Recommended Practices
    and Requirements for Harmonic Control in
    Electrical Power Systems (Current Distortion
    Limits for 120v-69kv DS)
  • Table 1
    Current Harmonic Limits 4


Ratio Iscc / Iload Harmonic odd numbers (lt11) Harmonic odd numbers (gt35) THD-i
lt 20 4.0 0.3 5.0
20 - 50 7.0 0.5 8.0
50 - 100 10.0 0.7 12.0
gt1000 15.0 1.4 20.0
16
Standard of Harmonics Limitation (contd)
  • IEEE 519-1992 Standard Recommended Practices and
    Requirements for Harmonic Control in Electrical
    Power Systems (Voltage Distortion Limits)
  • Table 2
    Voltage Harmonic Limits 4

Bus Voltage Voltage Harmonic limit as () of Fundamental THD-v ()
lt 69Kv 3.0 5.0
69 - 161Kv 1.5 2.5
gt 161 Kv 1.0 1.5
17
Mitigation Of Harmonics 1
  • Ranging from variable frequency motor- drive to
    other nonlinear loads and equipments
  • Power System Design
  • Limiting the non-linear load penetration to 30
    of the maximum transformers capacity
  • Limiting non-linear loads to 15 of the
    transformers capacity, when power factor
    correction capacitors are installed.
  • Avoiding/Detuning resonant conditions on the AC
    System



  • (Eq-4)
  • hr resonant frequency as a multiple
    of the fundamental frequency
  • kVAsc short circuit current as the
    point of study
  • kVARc capacitor rating at the system
    voltage

18
Mitigation the Effects of Harmonics 1 (contd)
  • Delta-Delta and Delta-Wye Transformers
  • Using two separate utility feed transformers with
    equal non-linear loads
  • Shifting the phase relationship to various
    six-pulse converters through cancellation
    techniques
  • Figure 7 Delta-Delta and
    Delta-Wye Transformers 1

19
Mitigation the Effects of Harmonics 1 (contd)
  • Isolation-Interface Transformers
  • The potential to voltage match by stepping up
    or stepping down the system voltage, and by
    providing a neutral ground reference for nuisance
    ground faults
  • The best solution when utilizing AC or DC drives
    that use SCR/GTO/SSR.. as bridge rectifiers
  • Line Isolation-Reactors
  • More commonly used for their low cost
  • Adding a small reactor in series with capacitor
    bank forms a Blocking series Filter.
  • Use diode bridge rectifier as a front end to
    avoid severe harmonic power quality problems

20
Mitigation the Effects of Harmonics 1 (contd)
  • Harmonic-Shunt or Trap Filters
  • Used in applications with a high non-linear ratio
    to system to eliminate harmonic currents
  • Sized to withstand the RMS current as well as the
    value of current for the harmonics
  • Providing true distortion power factor correction
  • Figure 8 Typical
    Harmonic Trap Filter 1

21
Harmonic Trap Filters (contd)
  • Tuned to a specific harmonic order such as the
    5th, 7th, 11th, etc to meet requirements of IEEE
    519-1992 Standard
  • The number of tuned filter-branches depends on
    the offending steady-state harmonics to be
    absorbed and on required reactive power level to
    be compensated

Figure 9 Typical Filter Capacitor Bank
5
22
Harmonics Filter Types 6
  • Isolating harmonic current to protect electrical
    equipment from damage due to harmonic voltage
    distortion
  • Passive Filter-Low cost
  • Built-up by combinations of capacitors, inductors
    (reactors) and resistors
  • most common and available for all voltage levels
     
  • Active Power Filter APF
  • Inserting negative phase compensating harmonics
    into the AC-Network, thus eliminating the
    undesirable harmonics on the AC Power Network.
  • APF-Used only for for low voltage networks

23
Harmonic Filter Types (contd) 7
  • Unified Switched Capacitor Compensator USCS
  • The single line diagram (SLD) of the
    utilization (single-phase) or (three-phase-
    4-wire) feeder and the connection of the Unified
    Switched- Capacitor Compensator (USCS) to the
    Nonlinear-Temporal Inrush /Arc type Loads or
    SMPS-Computer/LAN-Network loads.



  • Figure 10 7

24
Harmonics Filter Types (contd) 7
  • The USCS is a switched/modulated capacitor bank
    using a pulse-width modulated (PWM/SPWM)
    Switching Strategy. The switching device uses
    either solid state switch SSR-(IGBT or GTO).

  • Figure 11 7

25
Need To Evaluate System Harmonics? 1
  • The application of capacitor banks in systems
    where 20 or more of the load includes other
    harmonic generating equipment.
  • The facility has a history of harmonic related
    problems, including excessive capacitor fuse
    operation or damage to sensitive
    metering/relaying/control equipment.
  • During the Planning/Design stage of any facility
    comprising capacitor banks and nonlinear
    harmonic generating equipment.

26
When to Evaluate System Harmonics? 1 (contd)
  • In facilities where restrictive Electric Power
    Utility Company Standards/Guidelines limit the
    harmonic injection back into their system to very
    small magnitudes.
  • Industrial/Commercial Plant expansions that add
    significant harmonic generating nonlinear type
    equipment operating in conjunction with capacitor
    banks.
  • When coordinating and planning to add any
    emergency standby generator as an
    alternate/renewable power source

27
Conclusions
  • The harmonic distortion principally comes from
    Nonlinear-Type Loads.
  • The application of power electronics is causing
    increased level of harmonics due to Switching!!
  • Harmonic distortion can cause serious
    Failure/Damage problems.
  • Harmonics are important aspect of power operation
    that requires Mitigation!!
  • Over-Sizing and Power Filtering methods are
    commonly used to limit Overheating Effects of
    Sustained Harmonics.

28
References
  • 1 www-ppd.fnal.gov/EEDOffice-w/Projects/CMS/LVPS
    /mg/8803PD9402.pdf
  • 2 www.pge.com/docs/pdfs/biz/power_quality/power_
    quality_notes/harmonics.pdf
  • 3 www.metersandinstruments.com/images/power_meas
    .pdf
  • 4http//engr.calvin.edu/PRibeiro_WEBPAGE/IEEE/ie
    ee_cd/chapters/CHAP_9/c9toc/c9_frame.htm
  • 5 www.nokiancapacitors.com.es/.../EN-TH04-11_
    2004- Harmonics_and_Reactive_Power_Compensation_in
    _Practice.pdf
  • 6http//rfcomponents.globalspec.com/LearnMore/Co
    mmunications_Networking/RF_Microwave_Wireless_Comp
    onents/Harmonic_Filters
  • 7 A.M. Sharaf Pierre Kreidi, POWERQ UALITYE
    NHANCEMEUNSTI NGA UNIFIEDSW ITCHED CAPACITOCRO
    MPENSATOR, CCECE 2003 - CCGEI 2003, Montreal,
    Mayimai 2003
  • 0-7803-7781-8/03/17.00 0 2003 IEEE

29
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