Harmonic Solutions in Electrical Systems. Raed Odeh Application Specialist - Power Quality & Electrical Distribution

Harmonic Solutions in Electrical Systems Raed Odeh Application Specialist - Power Quality & Electrical Distribution

Agenda I. Harmonic Basics II.Harmonic Mitigation Solutions III.Case Study 2

Harmonic Basics U I Linear Loads Resistive heaters Lights Induction motors I U Non-linear Loads House hold appliances ( TVs, Microwave, etc.) Induction heaters & welders Lighting equipment with ballasts Variable Speed Drives Office equipment (PCs, Photocopiers, fax,etc.) 3

Harmonic Basics Peak value RMS value Non sinusoidal signal RMS value Fundamental or 1st harmonic 3rd harmonic 5th harmonic 7th harmonic 9th harmonic 4

Harmonic Basics Sinewave of a specific frequency supplied by the utility (a clean sinewave): f(x) = sin(x) plus a 5th Harmonic Sinewave: f(x) = sin(5x) 5 results in a harmonic rich, nonlinear wave shape: f(x) = sin(x) + sin(5x) 5 5

LOAD Harmonic Basics D1 D2 D3 Line 1 Line 2 Line 3 D4 D5 D6 6

Harmonic Basics Why the concern? Current distortion Added heating = reduced capacity Equipment failures Transformers Conductors and cables Nuisance tripping of electronic circuit breakers (thermal overload) Heating proportional to harmonic order in cables Squared effect on transformers & motors V h I h Loads I h Z h 7

Harmonic Basics 8

Harmonic Basics 9

Harmonic Basics 10

Harmonic Basics Why the concern? Voltage distortion Interference with other electronic loads Malfunctions to failure Induces harmonic currents in linear loads i.e. AC motor winding over heating & bearing failures I h AC Motors Loads V h I h Z h 11

Harmonic Basics Zsh Zch Ih Vh = Harmonic voltage Ih = Harmonic current Vs Vh Load Zsh = Source impedance for harmonic current Zch = Cable impedance for harmonic current Vh = Ih * (Zsh + Zch) 12

Harmonic Basics Fundamental Signal + = Total RMS Signal Harmonic Signal 13

Harmonic Basics Interaction with PF caps PF caps interact with all frequencies Overheating of PFC capacitors Tripping of PF protection equipment Capacitor failures Cause resonance Shutdown to damage to electronic equipment 14

Harmonic Mitigation Solutions Every method has its place Every method adds complexity Added costs Added heat losses Additional cooling requirements Larger footprint needs more space Adds installation complexity Additional power cabling Current transformers Application performance may be impacted Too much impedance limits load performance di/dt (Di/Dt) defines speed of change of current over time Generator interaction difficulties 15

Harmonic Mitigation Solutions Applied per device (VFD based discussion) Reduced harmonic designs Passive Line reactors/dc bus chokes/isolation transformers 5 th harmonic filters Broadband filters Multi-pulse transformers/converters Active front end (AFE) converter System solution Active harmonic filter (AHF) 16

Harmonic Mitigation Solutions Reactors/chokes smooth the current shape Reduces the harmonic distortion 17

Harmonic Mitigation Solutions Passive Filters Consist of a large series reactor and shunt harmonics traps The series reactor reduces the thdi and isolates the harmonics traps from the network harmonics. The passive filter offer allows the THDI level to be reduced from 16% to 10%, and down to 5% in combination with inductance Can be used on single or multiple drives 18

Harmonic Mitigation Solutions 12-Pulse Transformers 11 th, 13 th, 17 th, 19 th. Current distortion: 10-12% THDI. Only available at design stage. Requires special transformers. Cancellation at primary side. 18-Pulse Transformers 17 th, 19 th. Current distortion: 5-7% THDI. Only available at design stage. Requires special transformers. Cancellation at primary side. 19

Harmonic Mitigation Solutions 12-Pulse Transformers Phase shifted by 30 Delta 6 pulses rectifier M Drive Star 6 pulses rectifier H5 and H7 attenuated 20

Harmonic Mitigation Solutions Phase shifted by -20 18-Pulse Transformers H5, H7,H11 and H13 attenuated Phase shifted by +20 21

Harmonic Mitigation Solutions Active filters Cancellation of harmonic currents by currents generated in opposition 0A 22

Harmonic Mitigation Solutions Active filters Active Filter Injection At VFD Terminals Source current AS off AS on Order % I fund % I fund Fund 100.000% 100.000% 3 0.038% 0.478% 5 31.660% 0.674% 7 11.480% 0.679% 9 0.435% 0.297% 11 7.068% 0.710% 13 4.267% 0.521% 15 0.367% 0.052% 17 3.438% 0.464% 19 2.904% 0.639% 21 0.284% 0.263% 23 2.042% 0.409% 25 2.177% 0.489% 27 0.293% 0.170% 29 1.238% 0.397% 31 1.740% 0.243% 33 0.261% 0.325% 35 0.800% 0.279% 37 1.420% 0.815% 39 0.282% 0.240% 41 0.588% 0.120% 43 1.281% 0.337% 45 0.259% 0.347% 47 0.427% 0.769% 49 1.348% 0.590% % THD(I) 35.28% 2.67% 23

Harmonic Mitigation Solutions PCC =? THD v % =? THD i % =? THD i % =? K FACTOR =? THD i % =? K FACTOR =? THD v % =? 24

Harmonic Mitigation Case Study Background Issues Induction heaters: 300 kw, 500kW, 800kW SCR control Limited supply 1MVAR Capacitor @11kV High THD v % & THD i % Voltage Notching Low PF Limited supply Resonance @11kV 25

Harmonic Mitigation Case Study THD v % = 20% THD i % = 45% PCC = 11kV THD v % = 20% THD i % = 200% 26

Harmonic Mitigation Case Study 27

Harmonic Mitigation Case Study Solution Line reactors (3-5)% Active Harmonic Filter 900A Result THD v %< 8% THD i %<7% Voltage Notching: eliminated PF =0.98 Lagging Resonance @11kV: eliminated 28

Harmonic Mitigation Case Study 29

Harmonic Mitigation Case Study AHF eliminates at 11 th harmonic order 30

Questions? Thank you! 31