Véronique Beauvois, Ir. 2015-2016 · 2015-09-15 · Title: 2_EMC_Coupling_Disturbances_PQ.ppt...
Transcript of Véronique Beauvois, Ir. 2015-2016 · 2015-09-15 · Title: 2_EMC_Coupling_Disturbances_PQ.ppt...
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Coupling modes
Véronique Beauvois, Ir. 2015-2016
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General problem in EMC = a trilogy
Source (disturbing)
Victim (disturbed)
• lightning • electrostatic discharges • motors, converters • etc.
• receivers • sensors • amplifiers • µC • etc.
propagation Coupling modes
• conducted (I / U) • radiated (cables, slot, shielding defect,…)
Parameters • Amplitude • Spectrum
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General solution in EMC = a trilogy
Source (disturbing)
Victim (disturbed) propagation
Coupling mode
To act on the source (not always possible) To act on the victim
(increasing immunity – reducing susceptibility)
To reduce the efficiency of the coupling mode
= frequently only solution
or different combined solutions
Remark : reciprocity (to improve emission frequently improve also immunity)
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1st step: to identify the disturbing elements
Protections
Ä for inter-system Ä for intra-system
= source & victim inside the same system
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Power supply
Envelop
1
2
3 Control/ Communication
To identify the disturbing elements, the coupling paths, …
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To add elements/components to reduce some effects
Power supply
Envelop
1
2
3 Control/ Communication
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The coupling modes between source and victim could be classified according to: • Common mode • Differential mode
Differential mode (DM) (or symetrical) : current is on one conductor in one direction and in phase opposition on the second conductor (e.g. power supply, RS-485, CAN, USB).
Coupling modes
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Common Mode (CM) (or asymetrical or longitudinal) : current on both conductors in the same direction.
The EM disturbances are weakly coupled in DM as conductors are nearby. On the other hand, in CM, current could be induced by an external field.
Coupling modes
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How to measure CM and DM? With a current clamp
CM
DM
Coupling modes
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Conversion between DM and CM Related to the parasitic impedances of different values
Origin? When 2 conductors have a different impedance regarding earth (parasitic capacitors) If ZA=ZB, there is no voltage accross RL due to ICM If ZA≠ZB, Vcharge(CM)= ICM.(ZA-ZB)
Coupling modes
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A. Common impedance coupling (conducted coupling) = common conductor
Solutions: • to decrease Z (coupling) • to decrease ip (source)
Considering a conductor AB, impedance Z(f) (≠0) :
ip
Coupling modes
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A. Common impedance coupling (conducted coupling) = common conductor
Coupling modes
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A. Common impedance coupling (conducted coupling) = common conductor
Coupling modes
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B. Inductive Coupling
The circulation of a current in a conductor creates a magnetic field, which could couple with a nearby circuit, and induced a voltage. Solutions: • source: to decrease dB/dt • victim: to decrease S or modify orientation (n and B perpendicular, B // loop) • coupling: to increase distance or add a magnetic screen
Coupling modes
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External disturbance
To reduce S loop
Coupling modes
B. Inductive Coupling
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Inductive diaphony
Δis > B > ip V=L2di2/dt+Mdi1/dt
Coupling modes
B. Inductive Coupling
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VN = - M x dIL/dt
Coupling modes
B. Inductive Coupling
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C. Capacitive Coupling
dU/dt > E electric field could couple with a nearby conductor and generate a voltage Solutions: • source: to reduce dU/dt • coupling: to increase distance
Coupling modes
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Capacitive diaphony
C. Capacitive Coupling
Coupling modes
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V = CC x dVL/dt x (Zin // RS) Impedance of victim circuit to ground
C. Capacitive Coupling
Coupling modes
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Input impedance?
Electric coupling increases with ZIN growing whereas magnetic coupling decreases.
For the same reason, magnetic coupling is related to circuits with low input impedance as electric coupling to high input impedance.
Coupling modes
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Relationship distance - L and C
Coupling modes
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D. Radiated Coupling
• H-field (field to loop) • E-field (field to conductor)
Coupling modes
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D. Radiated Coupling 1. Electromagnetic field of short electric dipole
Conductor length l with a current Io
l <<< λ of the field
So Io is constant on l
Coupling modes
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1. Electromagnetic field of short electric dipole
Electromagnetic fields (in spherical coordinates) is evaluated at an observation point P at a distance r from the origin:
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We have to consider 3 cases: - r >> λ/(2π) or kr >> 1
far-field - r << λ/(2π) or kr << 1
near-field - r ≈ λ/(2π) or kr ≈ 1
intermediate zone
1. Electromagnetic field of short electric dipole
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Far-field For θ=0°, no electromagnetic wave, consider θ=90° (maximum of radiation):
Caracteristic Impedance
1. Electromagnetic field of short electric dipole
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Near-field
1. Electromagnetic field of short electric dipole
Caracteristic Impedance
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1. Electromagnetic field of short electric dipole
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Consider a loop with Io
Coupling modes
D. Radiated Coupling 2. Electromagnetic field of magnetic dipole
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2. Electromagnetic field of magnetic dipole
Electromagnetic fields (in spherical coordinates):
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Far-field (r >> λ/(2π) ) For θ=90°:
2. Electromagnetic field of magnetic dipole
Caracteristic Impedance
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Near-field (r << λ/(2π) )
2. Electromagnetic field of magnetic dipole
Caracteristic Impedance
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2. Electromagnetic field of magnetic dipole
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D. Radiated Coupling Wave impedance of electromagnetic field
E/H is called wave impedance. It is an important parameter as it determines the couplign efficiency ot this wave with a structure, and the efficiency of a shielding structure. In far-field (r>>λ/2π), plane wave, E and H are decreasing in the same proportion with distance. Z is a constant and in air 377Ω. In near-field (r<<λ/2π), Z is determined by the characteristics of the source.
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D. Radiated Coupling
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D. Radiated Coupling Far-field – near-field
Rayleigh criterion This criterion is related to the radiating diagram of an antenna, too large to be considered as a ponctual source. To consider a far-field condition as acceptable, it is needed that the phase shift of the components of the radiated field from the 2 ends of the antenna is small, regarding λ. We have a criterion related to λ and maximum dimension D of antenna:
d > 2D²/λ
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Disturbances and Power Quality
Véronique Beauvois, Ir. 2015-2016
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Definition of a disturbance
An electromagnetic phenomenon susceptible to degrade the performances of an apparatus or system.
© Groupe Schneider
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Types of disturbances - Classification
• frequency: L.F. / H.F. • conducted / radiated • narrowband / broadband • duration (t): permanent, repetitive, transient, random • common mode/differential mode
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Frequency: L.F. / H.F.
• 0≤f ≤…1 MHz • conducted • f > 30MHz
• radiated
Types of disturbances - Classification
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Conducted Voltage/current
Radiated Electric/Magnetic fields
Types of disturbances - Classification
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Narrowband (disturbance bandwidth < receiver’s one) Broadband (disturbance bandwidth > receiver’s one)
Types of disturbances - Classification
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Common Mode – Differential Mode
Types of disturbances - Classification
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L.F. & conducted >> Power Quality 3-phase systems
Types of disturbances
Parameters? • frequency (50 Hz) • amplitude (V) • waveshape (sinusoidal) • symetry (phase shift 120°)
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1. Frequency – Deviation
Frequency variations are very small (less than 1 %) in the European network (mesh). Consequently, very few problems for electronic equipement. In a small isolated network (e.g. island or emergency power system) , the situation is different. Some process need a very precise control of speed and frequency variation could disturb.
Types of disturbances
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2. Amplitude 2.1 Voltage dips and short interruptions Voltage dips could be related to short-circuit in the network or at the customer premises (defaults, atmospheric problems, …). In this case only drop of voltages more than 10 % are considered (otherwise they are voltage fluctuations). Definition of voltage dip [EN 50160] : quick reduction of power supply at a value between 90 and 1 % of the nominal voltage, followed by a recovering very soon. Duration from 10 ms to 1 min., by definition. Short interruptions [EN 50160] : reduction of power supply under 1 % of the nominal voltage. Short : less than 3 minutes. Consequences : some equipment could stop, if the depth and duration are over certain limits (according to the sensitivity of the load).
Types of disturbances
Uref
ΔU
Δt
Voltage dip Short interruption
Uref-10%
U(t)
Urms
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2. Amplitude 2.1 Voltage fluctuations / Flicker In some installations, quick variations of power (produced or consumed) could be observed (welding, wind turbines, arc furnaces, air conditioning, …). This could lead to voltage variations. Flicker [EN 50160] : visible change in brightness of a lamp due to rapid fluctuations in the voltage of the power supply. The voltage drop is generated over the source impedance of the grid by the changing load current of an equipment (frequent starting of an elevator motor, air conditioning systems, arc furnaces, welding machines, …). Effects in the band 0.5-25Hz. Major consequences on lamps. Standards EN 61000-3-3 (I < 16A) EN 61000-3-11 (16A < I < 75A)
Types of disturbances
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3. Waveshape 3.1 Harmonics / Interharmonics Harmonics: components of frequencies which are multiple of fundamental (50Hz) and create a distortion of the sinusoidal waveshape. Interharmonics: components which are non integer multiples of fundamentals (very rare, arc furnaces, static frequency converters for low speed applications and cycloconverters, e.g. cement crushers). K.fm +/- k.fo (fm is mains frequency and fo for output frequency).
Types of disturbances
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Harmonics
We have seen that a periodic signal could be represented by a sum of sinus with different amplitudes and phases, with frequency multiple integer of fundamental (frequency f). Harmonics.
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Origin? All non linear loads are associated with a non sinusoidal current
and generates harmonics
Harmonics
Sources? inverters, choppers, dc-dc converters
• rectifiers • speed controllers
• frequency converters • dimmers • lighting
• Induction heating systems • Saturated magnetic circuits
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Consequences?
Harmonics
Heating (motors, transformers, cables, …)
Losses (transformers) Saturation (transformers)
Additional torque components (motors) Resonance (Q compensation capacitors)
Homopolar compenents (H3) Defaults (power electronics, IT, relays, controlers, …)
…
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3. Waveshape 3.2 Transient Overvoltages: related to the release of low voltage apparatus, inductive loads, capacitor banks start (Q compensation) and fuse fusion. Sinusoidal damped overvoltages: some actions on the medium voltage network as a breaker opening or closing, switches disconnection, … may cause a voltage variation which excites the line with a very short pulse with a short rise time. The consequence is a damped sinus.
Types of disturbances
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3. Waveshape 3.2 Transient Burst
Types of disturbances
0…200MHz…
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3. Waveshape 3.2 Transient Surge
Types of disturbances
0…100MHz…
4kV Normalized waveshape Voltage 1,2/50µs Current 8/20µs
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4. Symmetry / Unbalance Dissymmetry in the network are very small. The main problem is the one-phase loading in a 3-phase network, and the repartition of those loads. Consequences: additional heating and flickering problems.
Types of disturbances
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Types of disturbances
DEFINITION OF POWER QUALITY (PQ)Power Quality = Voltage Continuity + Voltage Quality
Voltage Quality• frequency - deviations• magnitude - deviations
- dips & short interruptions- flicker
• waveform - (inter)harmonics• symmetry - unbalance
Voltage Continuity(Reliability of Supply)- long interruptions
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Power Quality - Examples
Véronique Beauvois, Ir. 2015-2016
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A. Harmonics – Neutral and cables diameter
Harmonic 3 in phase Ø Sum is not zero Ø Sum in neutral : 3 x Iphase Ø Heating Ø Destruction risk Ø Diameter of cabling should be adapted (same for 3k multiples)
One of the major effects due to harmonics is the increasing of RMS currents in the mains.
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Distorsion rate I1 225A I3 183A 81.3 % I5 152A 67.6 % I7 118A 52.4 % Iph = 348A (1.55 x I1) (RMS of harmonics) In = 3 x 183A = 549A (2.44 x I1) Phases: 225A > 70mm² with Hn 150mm² (385A) Neutral > 35mm² with Hn 300mm² (615A) Based on R.G.I.E.
A. Harmonics – Neutral and cables diameter
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B. Eco light
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B. Eco light
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C. LED
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D. Generators – Renewable Energy