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1
© SEL 2019
Protection Basics 101
What Are We Protecting?
2
Lightning Strikes Create Faults
3
4
Arcing Evidence on Pole Ground
Flashed C-Phase Insulator With
Melted Balloon Material
5
Snake Causes Breaker to Fail
Flashed Insulators
6
When Primary Met Secondary
Bϕ
H3J1 J2
Aϕ
H2
Cϕ
H1
Control
Cabinet
Digital Relay
Extra Slack
in CT Cable
Junction Box Scorched
7
Arc Flash During Commissioning
Culprit Found!
8
Typical Short-Circuit Type Distribution
Single-phase-to-ground 70–80%
Phase-to-phase-to-ground 10–17%
Phase-to-phase 8–10%
Three-phase 2–3%
Power System Protection Requirements
Reliability Selectivity Speed Simplicity Economics
9
• Protection system will perform correctly
• Protection system will operate for in-zone
problems (dependability)
• Protection system will not operate for out-of-zone
problems (security)
Reliability
• Ability of protection system to disconnect minimal
amount of system
• Ability to isolate problem in shortest amount of time
Selectivity
10
• Hazards to humans, equipment damage, and
stability problems are minimized when equipment is
isolated faster
• Speed and selectivity are frequently at odds –
allowing for additional delay before tripping gives
better selectivity
Speed
Simplicity
Reliability increases when protection
systems are kept simple
11
Protection system should provide greatest amount of
protection, commensurate with components being
protected, for minimum total cost
Economics
• Correct performance
• Incorrect performance
▪ Failure to trip
▪ False tripping (misoperation)
Protection Performance Classification
12
• Fuses
• Automatic reclosers
• Sectionalizers
• Circuit breakers
• Protective relays
Protective Devices
• Protective
• Regulating
• Reclosing and synchronism check
• Monitoring
• Auxiliary
Relay Classification
13
IEEE C37.2 Device Numbers
51 Time-overcurrent relay
50 Instantaneous overcurrent relay
67 Directional overcurrent relay
21 Distance relay
87 Differential relay
52 Circuit breaker
Protective Relaying System
52
Relay
DC
Supply
Communications
Channel
DC
Supply
Circuit Breaker
Current
Transformers
(CTs)
Voltage
Transformers
(VTs)
14
Protective Relays
• Monitor
• Detect
• Report
• Trigger
Circuit Breakers
• Interrupt
• Isolate from
abnormal condition
Protection System Elements
CTs
• Current scaling
• Isolation
VTs
• Voltage scaling
• Isolation
Instrument Transformers
15
IPIS
H
VS ZB
Why Does a CT Saturate?C
urr
en
t
Time
Asymmetrical Saturation
b c d e f g h i j
IS IP
a
16
DC Tripping Circuit
DC Station
Battery SI Relay
Contact
Relay
Circuit
Breaker
52a
(+)
–
SI
52
TC
Circuit Breaker
Transmission
Line
Single Bus
Transformer
Distribution
Lines
Motor M
Generator
Ring Bus
Example Power System
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Circuit Breaker
Transmission
Line
Single Bus
Transformer
Distribution
Lines
Motor M
Generator
Ring Bus
Example Power System
Overlapping Zones. No Gaps. Ever.
52
52
Protection
Zone B
Protection
Zone B
To Zone B
Relays
To Zone B
Relays
Protection
Zone A
Protection
Zone A
To Zone A
Relays
To Zone A
Relays
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Circuit Breakers
Dead-Tank Breaker Live-Tank Breaker
Backup Protection
A C D E
B F
T
1 2 5 6 11 12
3 4 7 8 9 10
Breaker 5 Fails
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Remote Backup
A C D E
B F
T
1 2 5 6 11 12
3 4 7 8 9 10
Breaker 5 Fails
Remote Backup Trips
Local Backup
A C D E
B F
T
1 2 5 6 11 12
3 4 7 8 9 10
Breaker 5 Fails
Local Backup
Trips
20
Instantaneous (50) and Time-Overcurrent (51)
CharacteristicsSTD
TD
Curve Shape
t
I
Istd Iinst
Ipu
Overcurrent Relay Coordination
Setting
S1
EI
Z
M
F Load
Load
Load
Relay
Relay
Load or Fault Current
21
Distance Relay
Relay designed to operate when ( )A L1 AV 0.8 Z I
21 Three-Phase
Bolted Fault
L
d
IA, IB, IC
VA, VB, VC
Mho Characteristic
X
R
F2
1 2 3 4 5 6
F1
F2
F1
Directional Impedance
Relay Characteristic
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Quadrilateral Characteristic
X
R
Zone 3
Zone 2
Zone 1
RG1 RG2 RG3
XG1
XG2
XG3
TANGG
Distance Relay Timing and Coordination
Zone 1 is instantaneous
Operation Time
A B C
Zone 1
Zone 2
Zone 3
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Why Is Distance Not Enough?
Zone 1S
Zone 1R
High-Speed
Line Clearing
Time-Delayed Clearing at One End
S R
• Direction comparison
blocking (DCB)
• Permissive overreaching
transfer trip (POTT)
• Directional comparison
unblocking (DCUB)
• Direct underreaching
transfer trip (DUTT)
• Permissive
underreaching transfer
trip (PUTT)
Typical Protection Pilot Schemes
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• Advantages
▪ High bandwidth
▪ High reliability
▪ Noise immunity
▪ Safety
• Disadvantages
▪ Cost (offset by
shared use)
▪ Rerouting (SONET)
Communications ChannelsOptical Fiber
• Advantages
▪ Power line noise immunity
▪ Not affected by faults
• Disadvantages
▪ Placement
▪ Weather
Communications ChannelsMicrowave
25
• Advantages
▪ Low cost
▪ Interference immunity
▪ No license required
▪ Not affected by faults
• Disadvantage –
low bandwidth
Communications ChannelsSpread-Spectrum Radio
• Advantage – reliable • Disadvantages
▪ Low bandwidth
▪ Affected by power
line noise
▪ Affected by faults
Communications ChannelsPower Line Carrier
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• Advantages
▪ Low installation cost
▪ Dedicated channel
• Disadvantages
▪ Ongoing cost
▪ Low reliability
▪ Short range
Communications ChannelsTelephone Lines
• Proprietary
• On / off
• Frequency shift keying (FSK)
Modulation Techniques
27
DUTT Logic
S R
Zone 1S
Zone 1R
TX
RX
Trip SZone
1S
TX
RX
Trip RZone
1R
• Underreaching Zone 1 elements send tripping signal
▪ Limited fault resistance coverage
▪ Immunity to current reversals
• Scheme trips without supervision – susceptible to
misoperation with noisy channels
DUTT Scheme
28
PUTT Logic
S R
Zone 1S
Zone 2R
TX
RX
Trip SZone 1S
TX
RX
Trip R
Zone 2SZone 1R
Zone 2S
Zone 1R
Zone 2R
• Underreaching Zone 1 elements send tripping signal
▪ Limited fault resistance coverage
▪ Immunity to current reversals
• Overreaching Zone 2 elements trip on receipt of signal,
making PUTT scheme more secure than DUTT scheme
PUTT Scheme
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POTT Logic
S R
Zone 2S
Zone 2R
TX
RX
Trip SZone
2S
TX
RX
Trip RZone
2R
DCB Logic
S R
Zone 2S
Zone 2R
TX
RX
Trip S
Zone
2S
CTD
0
TX
RX
Trip R
Zone
2R
CTD
0
Zone 3S Zone 3R
Zone 3S
Zone 3R
30
Differential Overcurrent
51
Differential OvercurrentExternal Fault
51
31
Differential OvercurrentInternal Fault
51
51
Effect of CT Saturation
5/_0
5/_0
5/_0
3/_30
32
Percentage Differential Protection Principle
Protected
Equipment
CTR CTR
Relay
I1 I2
= +1 2IOP I I
( )= +1 2IRT 0.5 • I I
Percentage Restraint Characteristic
IOP
Multip
les o
f T
ap
Multiples of TapIRT
IRS1
SLP1
SLP2Operate
Region
Restraint
Region
U87P
O87P
= +1 2IOP I I
( )= +1 2IRT k • I I
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Adaptive Slope
Slope 1
Internal Fault
IRST
IOP
Slope 2
External Fault
Restrain
Operate
87P
87Z
Trip Alarm
OUT1
OUT2
86
Trip and Short
87 Input
High-Impedance Differential Protection
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How Many Relays for One Line?
3 phase + 3 ground + auxiliaries
1 relay has it all, and much more!Digital Relay
• Multifunction devices
• Negative-sequence element
• Low-burden devices
• Programmable logic; very flexible
• Automatic self-tests
• Greater sensitivity due to high-accuracy metering
Microprocessor-Based Relay Advantages
35
The Good Old Days?
I wonder
where the
problem is…
Root Cause Found!
36
Digital Relay I/O Scheme
Computer-Based
Relay (digital)
Computer
Communications
Analog Inputs
Discrete Inputs
Auxiliary Inputs
(ac or dc)
Dry Contact Outputs
(trip and alarm)
Live Outputs
Digital Relay Architecture
Microprocessor
RAM ROM / PROM EEPROM
Discrete
Output
Subsystem
Operation
Signaling
Analog Input
Subsystem
Discrete Input
Subsystem
Analog-to-
Digital (A/D)
Conversion
Tripping
Outputs
Communications
Ports
37
Signal Path for Microprocessor-Based Relays
Analog
Low-Pass
Filter
A/D
Conversion
Digital
Cosine
Filter and
Phasor
Magnitude
and
Impedance
CT
PT
A/D Conversion
A/D
Analog Signal Digital Signal
00000001
00000101
00001001
00100100
10010000
:.
Input Output
38
Nonfiltered Signal
(samples)
Filtered Signal
(samples)
Digital Filtering
Digital Filtering
Phasor Samples:
Magnitude and Angle
Versus Reference
| I |
qReference
Phasor Calculation
Filtered Signal
(samples)
Phasor Calculation
39
Logic
A
B
C
D
EA
B
DC
E
–
(+)
E = A AND B OR C OR NOT D
Equation Implemented
Programmable Logic
Digital Relay Algorithm
Read Present Sample k
Digital Filtering
Phasor Calculation
Protection Methods
Relay Logic
Modify if
Required
Trip Order
No Trip
40
• Phasors depend on sinusoidal steady state
• Faults change the network
• We want to determine where … fast!
• We want to determine sinusoidal steady state and
filter out everything else
• Shorter windows make us faster but less accurate
It Takes a Cycle to Catch a CycleO
pe
ratin
g T
ime
in C
ycle
s
Fault Location in Percent of Set Reach
Line-to-Ground Fault, SIR = 1.0
Modern Distance Relays: 8–16 ms
0 10 20 30 40 50 60 70 80 900
0.5
1
1.5
100
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– 0 – 0 0 10 20 30 40–
–
–
0
2
4
Loca
l C
urr
en
t (A
)
–
–
0
2
4R
em
ote
Cu
rren
t (A
)
Time (ms)
Traveling Waves Bring Information Fast
42
– 0 – 0 0 10 20 30 40–
–
–
0
2
4
Loca
l C
urr
en
t (A
)
–
–
0
2
4
Rem
ote
Cu
rren
t (A
)
Time (ms)
Traveling Waves Bring Information Fast
Internal Phase Fault (100 km, 400 kV)
BC fault at 50 km
TW32 0.1 ms
TD3 2.1 ms
TD21 3.7 ms
TW87 0.9 ms
Fault Location =
49.993 km
kV
A
0
200
400
–200
–400
0
4,000
8,000
–4,000
–8,000
TWDDTW32FTD32F
TW87PKPTD21P
TRIP
–5 ms 0 ms 5 ms 10 ms 15 ms 20 ms 25 ms 30 ms
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One-Second Power System ViewkV
A
0
–400
–800
400
800
0
400
800
–400
–800–200 ms 0 ms 200 ms 400 ms 600 ms
One-Cycle Power System View
kV
A
0
–200
–400
200
400
0
400
800
–400
–800–10 ms 0 ms 10 ms 20 ms 30 ms–20 ms
44
One-Millisecond Power System ViewkV
A
0
–200
–400
200
400
0
400
800
–400
–800–1 ms –0.5 ms 0 ms 1 ms 1.5 ms–1.5 ms 0.5 ms
Submillisecond Power System View
kV
A
0
–200
–400
200
400
0
400
800
–400
–800–1 ms –0.5 ms 0 ms 1 ms 1.5 ms–1.5 ms 0.5 ms
600
45
One-Microsecond Power System View!kV
A
0
–200
–400
200
400
0
400
800
–400
–800–20 μs 0 μs 40 μs 60 μs–40 μs 20 μs
600
This Is Only the Beginning
We’ll all learn more about
the power system!
46
Thank You!
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