Metal Oxide Surge Arresters Prof. Dr.-Ing. Volker Hinrichsen Darmstadt University of Technology High Voltage Laboratories
[email protected]
Contents • Arre Arrest ster er ap appl plic icat atio ionn in in gen gener eral al • cons considera iderations tions on prot protectiv ective e chara characteri cteristics stics • Ar Arre rest ster er des desig ignn (stat (statio ionn arre arrest ster ers) s) • por orce cela lain in ho hous used ed • polymer ho housed • Con onffig igur urin ingg arre arresster erss • ele lect ctrric ical al dat ataa • mec echa hannic ical al dat ataa
Contents • Arre Arrest ster er ap appl plic icat atio ionn in in gen gener eral al • cons considera iderations tions on prot protectiv ective e chara characteri cteristics stics • Ar Arre rest ster er des desig ignn (stat (statio ionn arre arrest ster ers) s) • por orce cela lain in ho hous used ed • polymer ho housed • Con onffig igur urin ingg arre arresster erss • ele lect ctrric ical al dat ataa • mec echa hannic ical al dat ataa
Development of Surge Arresters over the past 25 years Internally gapped SiC arresters with porcelain housings 1980
MO arresters without gaps with porcelain housings Æ "state of the art" latest by 1990 MO arresters without gaps with polymeric housings (mv; distribution class)
1990
MO arresters without gaps with polymeric housings (hv; station class)
Technology
2000
Development of Surge Arresters over the past 25 years
1980
Failure Failure Failu re rates rates of of MO MO arresters: arresters: arrest ers: Distribution: 0.1 %/a %/a ... ... 11 %/a %/a (with Distribution: 0.1 (with geographical geographical variations) variations) High-voltage: virtually zero zero High-voltage: virtually Expected Expected Expec ted life life time life time of time of MO MO arresters: arresters: arrest ers: >> 30 30 years? years?
(no (no indication indication for for any any severe severe degradation degradation of of MO MO material material so so far) far) 1990
2000 2003
Market Market share share of of polymer polymerr housed polyme housedMO MO arresters: arresters: arresters:
… 80 % %… … >> 90 90 % % Distribution: 80 n Distribution: o Reason Rea sons: s: par poo pe rmance nce pporc elain in hhous ed ttype ss i Reason Rea sons: s: -- partly partly partly tly poor poorrr perfo poo performa perfo rforma rmance nce of of porc porcela orcela elain in hous housed oused ed type types ypes t a -- benefits benefi ts of polyme ric designs: desig ns: sealing, seal hand benefits benef its of polymeric polymeric polymeric designs: designs: sealing, sealing, ing, handling, handling, handling, ling, u t i overload overload performance performance s s -- cost/price! cost/price! ' y a High-voltage: 30 %, with increasing tendency d Reaso eason ns: - hv user userss mor more e con conse serv rva ative tive o T - higher higher requir requireme ements nts - cost/price!
Typical Arrester Application: Transformer Protection U s = 420 kV
Siemens / VEAG
Special Arrester Application: Protection of an SC Capacitor Bank U s = 550 kV
Special Arrester Application: Line Arresters U s = 245 kV
U s = 800 kV
ABB / AEP
Special Arrester Application: HVDC Valve Protection Arresters U DC = 600 kV
Arrester Application
Fundamentals of Insulation Coordination 5 . u . p / 4 e g a t l o v 3 ) r e v o ( f o 2 e d u t i n g a 1 M
0
Possible voltages without arresters
Withstand voltage of equipment
Voltages limited by arresters Lightning overvoltages (Microseconds)
Switching overvoltages (Milliseconds)
Temporary overvoltages Highest voltage of equipment (Seconds) (Continuously)
Time duration of (over-)voltage
Voltage-Current Characteristic of an MO Arrester ( U s = 420 kV) α ≤
5
I = k ·U α with
α values
α ≤
up to 50
5
1200 1100 1000
V k / e g a t l o v f o e u l a v k a e P
10-kA residual voltage = lightning impulse protection level = 823 kV
900 800 700 600 500 400
4 . 2 r o t c a F
Peak value of rated voltage: √2·U r = √2·336 kV = 475 kV
Peak value of continuous operating voltage: √2·U c = √2·268 kV = 379 kV
300
Peak value of line-to-earth voltage: √2·U s /√3 = √2·242 kV = 343 kV
200 100
Leakage current î res ≈ 100 µA
Nominal discharge current I n = 10 kA
0 10-4
10-2
1 Peak value of current / A
8 decades of magnitude
10 2
10 4
Voltage-Current Characteristic of an MO Arrester ( U s = 420 kV) 400
1,00
300 200
0,50
V 100 k / e 0 g a t l o V-100
0,25
.
Simplified circuit diagram
0,75
Voltage
0,00 -0,25 Current
-200
-0,75
-400
-1,00 0
C V k / e g a t l o V
at U U = U U cc: I I total ≈ 1 mA total ≈
-0,50
-300
R = f(u)
A m / t n e r r u C
5
10 Time / ms
900 800 700 600 500 400 300
15
20
18 16 14 12 10 8 6
Voltage
Current
200 100
4 2
0 -100
0 -2 0
5
10
15
20
25
30
35
A k / t n e r r u C
at î î = I I nn: ûû ≈≈ 825 kV
Voltage-Current Characteristic of an MO Arrester Voltage
Simplified circuit diagram
R = f(u)
C
“Resistive component“
t n e r r u C , e g a t l o V
Total leakage current Time
at U U = U U cc: I I total ≈ 1 mA total ≈ I I capacitive ≈ 1 mA capacitive ≈ î î resistive ≈ 10 µA … 100 µA resistive ≈
MO Resistors Ø 70 mm
Ø 100 mm Ø 58 mm
Ø 48 mm
Ø 78 mm
Ø 41 mm
Ø 32 mm
U -I -
vs. E -J -Characteristics
U U --I I --characteristics characteristics for for different different MO MO resistors resistors
common common E characteristics E --J J --characteristics
LI Protection Characteristics 2 T r av eling w a
v e ef f ec ts
4 m
3
Inductivity of current path ≈1 µH/m (here: L = 10 µH)
1 Currents exceeding I n
Doubling of voltage due to full reflection at "open" end of line
!!!!! •• Voltage Voltageatatarrester arresterterminal terminal might higherthan thanthe theLI LI mightbe behigher protection protectionlevel level
m 5 . 3
•• Voltage Voltageatatterminals terminalsof of equipment equipmenttotobe beprotected protectedare are higher higherthan thanvoltage voltageat atthe the arrester arresterterminal terminal
m 5 . 2
Protective Distance – Model Calculation 1 (U m = 420 kV) Overvoltage surge of s = 800 kV/ µ s
Arrester u pl = 800 kV = const. x = 0
Transformer LIW = 1425 kV ℓ ?==
300 m x =
ℓ
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 00 µs µs
2000 1600
1600
u Arr (x = 0)
kV 1200
1200 800
800 400
400
0 0
-400
0 kV
-1200 x = 0
uu Arr = 0 kV Arr 0 kV
x = ℓ
1200 800 400
x = ℓℓ:: x =
1
1600
-800
x = 0: 0: x =
0,5
uuTr = 0 kV Tr = 0 kV 0
u Tr (x = ℓ)
1,5
2 µs
2,5
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 0,5 0,5 µs µs
2000 1600
1600
u Arr (x = 0)
kV 1200
1200 800
800 400
400
u 1v
0 0
-400
0 kV
-1200 x = 0
uu Arr = u 1v = 400 400 kV kV Arr u1v
x = ℓ
1200 800 400
x = ℓℓ:: x =
1
1600
-800
x = 0: 0: x =
0,5
uuTr = u 1v == 00 kV kV Tr = u1v 0
u Tr (x = ℓ)
1,5
2 µs
2,5
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 11 µs µs
2000 1600
1600
u Arr (x = 0)
kV 1200
1200 800
800
u 1v
400
400
0 0
-400
0 kV
-1200 x = 0
uu Arr = u 1v = 800 800 kV kV Arr u1v
x = ℓ
1200 800 400
x = ℓℓ:: x =
1
1600
-800
x = 0: 0: x =
0,5
uuTr = u 1v == 00 kV kV Tr = u1v 0
u Tr (x = ℓ)
1,5
2 µs
2,5
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 1,5 1,5 µs µs
2000 1600
1600
u Arr (x = 0)
kV 1200
1200
u 1v
800 400
800 400
u 1r
0
u 2v
0
-400
0
0,5
1
1,5
1600
-800
kV
-1200 x = 0
uu Arr = u 1v + uu2v = Arr u1v 2v (1200 – V == 800 800 kV kV (1200 – 400) 400) kkV x = 0: 0: x =
x = ℓ
1200 800 400
uuTr = u 1v ++ uu1r = Tr = u1v 1r (400 800 kV kV (400 ++ 400) 400) kV kV == 800 x = ℓℓ:: x =
0
u Tr (x = ℓ) Increase at double steepness!
2 µs
2,5
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 22 µs µs
2000 1600
1600
u Arr (x = 0)
kV 1200
u 1v
1200
800
800
u 1r
400
400
0 0
-400
0
u 2v
-800
kV
uu Arr = u 1v + uu2v = Arr u1v 2v (1600 – V == 800 800 kV kV (1600 – 800) 800) kkV x = 0: 0: x =
x = ℓ
1200 800 400
uuTr = u 1v ++ uu1r = Tr = u1v 1r (800 1600 kV kV (800 ++ 800) 800) kV kV == 1600
1
1600
-1200 x = 0
0,5
x = ℓℓ:: x =
0
u Tr (x = ℓ)
1,5
2 µs
2,5
Protective Distance – Model Calculation 1 (U m = 420 kV) t t = = 2,5 2,5 µs µs
2000 1600
u 1v
1600
u Arr (x = 0)
kV 1200
1200 u 1r
800
800
400
400
0 u 3v
-400 -800
u 2r
0 0 kV
-1200 x = ℓ
uu Arr = u 1v + uu1r + u 2v + uu3v = Arr u1v 1r + u2v 3v (2000 V == 800 800 kV kV (2000 ++ 400 – 400 – 1200 – 1200 – 400) 400)kkV x = 0: 0: x =
1200 800 400
x = ℓℓ:: x =
1
1600
u 2v
x = 0
0,5
uuTr = u 1v ++ uu1r + u 2v + uu2r = Tr = u1v 1r u2v 2r
(1200 1600 kV kV (1200 ++ 1200 – 1200 – 400 – 400 – 400) 400) kV kV == 1600
0
u Tr (x = ℓ)
1,5
2 µs
2,5
Protective Distance – Model Calculation 2 (U m = 24 kV) Assumptions: • overvoltage surge as a voltage ramp 1 000 kV/µs (1 kV/ns) • arrester limits voltage to 80 kV at its terminals
100
100 Voltage at transformer
90
] V k [ u
80
80
70
70
60 50
Voltage at transformer
90
Voltage at arrester
40
] V k [ u
60 50 40
30
30
20
20
10
10
0
Voltage at arrester
0 0
5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 t [ns]
a) Distance arrester - transformer: 1.5 m (propagation time 5 ns)
0
10 20
30 40
50 60
70 80
90 100 110 120
t [ns]
b) Distance arrester - transformer: 3 m (propagation time 10 ns)
Protective Distance – Estimation (Rule of Thumb) Due to traveling wave effects on the line the protection of the equipment by an arrester can be guaranteed only for short distances between arrester and equipment. Simplified estimation of the protective distance *):
x s
LIWV U pl
(LIWV / 1.15) - U pl x s = · v tw 2·s
s v tw
*) For more detailed information see IEC 60099-5, IEC 60071-1 and IEC 60071-2
protective distance [m] standard rated lightning impulse withstand voltage [kV] LI protection level of the arrester [kV] front steepness of the overvoltage [kV/µs] (in the range of 1000 kV/µs) propagation speed of traveling wave: - 300 m/µs (overhead line) (equals " c 0") - (150 ... 200) m/µs (cable)
Example 1: Distribution network, U m = 24 kV, insulated neutral, arrester of U r = 30 kV: x s =
(125 / 1.15) - 80 2·1000
· 300 =
4.3 m
!!!
Example 2: Transmission network, U m = 420 kV, effectively earthed, arrester of U r = 336 kV: x s =
(1425 / 1.15) - 823 2·1000
· 300 =
62.4 m !!!
Representative Overvoltage (acc. to IEC 60071-2) U rp
= U pl +
adopted return rate 1/a shielding failure rate + back flashover rate 1/a ⋅m
A
L
Lt =
n ( Lsp
+ Lt )
Lsp ... span length in m L ... distances a1 + a2 + a3 + a4 in m n ... number of connected lines A ... factor describing the lightning performance
of the OHL in kV (see next slide)
Note: Note: nn should reasonably be set to n = 11 (if only one one line is = 22 (if two two is connected) connected) or or n n = n = or or more more lines are connected). Assuming nn > 2 could yield too optimistic results that are
not valid in a real failure scenario (e.g. possible loss of lines).
Representative Overvoltage (acc. to IEC 60071-2) Factor A describing the lightning performance of an OHL
[IEC 60071-2]
Representative Overvoltage (acc. to IEC 60071-2) Example: U s = 420 kV
• • • • • • •
U pl = 825 kV; A = 11000 kV (four conductor bundle) L = 30 m Lsp = 400 m
2 lines connected; Shielding failure rate (typ. for Germany; one OHGW): 2.5 per 100 km and year = 2.5·10-5 (a·m)-1 Adopted return rate: 1·10-3 a-1 ≥
= 40 m 2.5 ⋅10−5 A L 11000 kV 30 m U rp = U pl + = 825 kV + ⋅ 2 (400+40) m n Lsp + Lt
Lt
Note Note 1: 1:
=
1 ⋅ 10−3
These equations yield representative representative overvoltages, overvoltages, which are not implicitly implicitly the the real real overvoltages! are not
= 1200 kV Note Note 2: 2: No No effect effect of the the lightning overvoltage amplitude amplitude!
Increase of Protection Voltage by Inductive Voltage Drops Example: outdoor arrester U s = 420 kV U r = 336 kV
4 m
u10kA, 8/20 µs = 823 kV (= U pl) u10kA, 1/2 µs = 872 kV m 5 , 3
Specific inductance of surge current path ≈ 1 µH/m Length of surge current path ≈ 10 m
⇒ Inductance of surge current path ≈ 10 µH m 5 , 2
Steepness of surge current impulse ≈ 10 kA/µs
⇒ Additional inductive voltage drop 100 kV
Arrester Design
Examples of High-Voltage Arresters
Grading Rings – Corona Rings Corona rings
• Beginning with a height of about 1.5 m to 2 m arresters need grading rings for control of voltage distribution along the arrester axis. • Corona rings serve to reduce RIV, usually applied in system voltages of 550 kV and higher.
Grading rings
Examples of Medium-Voltage Arresters
Design of a Porcelain Housed High-Voltage Arrester
Pressure relief vent
O-ring Sulfur cement bonding
Pressure relief diaphragm
MO column
Compression spring Supporting rod (FRP) Fixing plate (FRP) Porcelain housing Aluminum flange
Basic Designs of Polymer Housed High-Voltage Arresters
Porcelain/Type A MO column
Type B1a
Gas
Type B1b
FRP supporting structure
Type B2
Type A "Tube Design" Type Type A A
"tube "tube design" design"
• "conventional" approach (like porcelain type) • gas volume included • separate sealing system • pressure relief vents • outer housing: silicone silicone rubber rubber (SR) (all types: HTV, RTV, LR/LSR)
Porcelain/Type A MO column
Gas
FRP supporting structure
Type A "Tube Design" Top cover plate Flange with venting outlet Sealing ring Pressure relief membrane Compression spring MO resistor column Composite hollow core insulator (FRP tube/ rubber sheds)
Type A "Tube Design" Nearly any desired mechanical strength and energy absorption capability (separate housing, multi-column possible) Safest possible short-circuit performance (closed tube) Single unit arrester up to U m = 300 kV (control of radial fields) Most expensive design Internal partial discharges possible (depending on design) Separate sealing system – risk of sealing deficiencies Æ
The Type A arrester is the typical "special feature" arrester.
Basic designs of polymer housed high-voltage arresters Type B
• no (intentional) gas volume included Type B1 Type Type B1a B1a
"wrapped design" "wrapped "wrapped design" design"
• FRP material directly directly wrapped onto MO stack stack • outer housing slipped over or molded on on (SR, (SR, EPDM, EPDM/SR EPDM/SR blends blends …) Type B1a
MO column
Gas
FRP supporting structure
Type B1a "Wrapped Design" Implementation example 1:
• Fiber glass rovings soaked in uncured epoxy resin or pre-impregnated ribbons are wound crosswise around the MO stack. • They do not fully overlap and form rhombic "windows". • Best compromise between mechanical strength and short-circuit performance must be found. MO column
FRP wrap
main orientation of glass fibers
Type B1a "Wrapped Design" Implementation example 2:
• Full overlapping of the ribbons or pre-impregnated FRP mats with appropriate (crosswise) orientation of the glass fibers • Forms a closed tube (good for mechanical strength, bad for short-circuit performance) • Slots as pre-determined weakened breaking areas
MO column
FRP wrap
main orientation of glass fibers
Example: Ohio Brass
Type B1a "Wrapped Design" Implementation example 3:
• Pre-impregnated FRP mats with axial orientation of the glass fibers • Forms a closed tube, which however easily tears open by the arc in case of short-circuit
MO column
FRP wrap
main orientation of glass fibers
Basic designs of polymer housed high-voltage arresters Type B
• no (intentional) gas volume included Type B1 Type Type B1b B1b
"wrapped design" "wrapped "wrapped design" design"
• FRP material with with distance distance to MO stack • gap filled by other material (solid/semi-solid) • outer housing slipped over or molded molded on (SR, EPDM, EPDM/SR blends …) Type B1b
MO column
Gas
FRP supporting structure
Type B1 "Wrapped Design" Most economical design; lowest market prices Short-circuit performance better than for porcelain Lightweight; easy to handle Limited mechanical strength (diameter of housing, wall thickness) Big differences in performance (e.g. with regard to moisture ingress, short-circuit performance) depending on design variants and implementation Multi-unit arresters even for lower system voltages (radial fields) Æ
The Type B1 arrester is the typical "low cost" arrester.
Basic designs of polymer housed high-voltage arresters Type B
• no (intentional) gas volume included Type Type B2 B2
"cage "cage design" design"
• FRP rods or loops form an open open cage cage around the MO stack • outer housing directly molded onto onto the the MO MO stack stack (silicone rubber)
Type B2
MO column
Gas
FRP supporting structure
Type B2 "Cage Design" 1st sub-variant
Loops
Example: ABB Switzerland
Type B2 "Cage Design" 1st sub-variant
Loops
Type B2 "Cage Design" 2nd sub-variant
Loops + bondage
Example: ABB Sweden
Type B2 "Cage Design" 3rd sub-variant
Rods
Example: Siemens
Type B2 "Cage Design" 3rd sub-variant
Rods
Example: Siemens
Type B2 "Cage Design" Economical design; low market prices Short-circuit performance better than for porcelain Mechanical strength usually higher than for B1 design Lightweight; easy to handle Limited mechanical strength (diameter; mechanical strength of MO blocks) Multi-unit arresters even for lower system voltages (radial fields) ÆThe
Type B2 arrester is a higher performance "low cost" arrester.
Configuring Arresters
System Highest voltage of the system U s Grounding l a c i r t c e l e
Temporary overvoltages (TOV)
Arrester
Environment
Min. MCOV, U c,min → rated voltage U r1 Rated voltage U r MCOV, U c Rated voltage U r2
Lightning current stress
Nominal discharge current
Energy (line discharge, switching overvoltages)
Line discharge class
LIWV, safety margin, distance (protection zone)
LI protection level, SI protection level
Density of lightning strikes, magnitude of lightning strikes
Active part specified
l a c i n a h c e m
Length of housing, number of units, flashover distance (withstand voltages)
Short-circuit current
Mechanical stress (short-circuit current, tensile loads)
Creepage, sheds Diameter, material, length of units (number of units)
Height of erection
Pollution
Seismic stress
Choice of Continuous Operating and Rated Voltage System
(phase-to-phase)
1 3
System
(phase-to-earth)
Arrester
TOV (1 s) TOV (10 s)
Highest system voltage
1-s-voltage
Nominal system voltage
Rated voltage ≥ + 5 % Cont. operating voltage
Note: Nominal system voltage of no interest for configuring an arrester!
1.25
Choice of Continuous Operating and Rated Voltage U r1
= 1.25 · U c,min = 1.25 · (1.05 · U m/√3) U TOV
U r2
= _______ =
1,3
f(t TOV)
Power-frequency vs. time (U -t -) characteristics
1,25
k TOV
1,2 1,15 r
U 1,1 / U = v o
t
k
1,05 1 0,95 0,9 0,85 0,8 0,1
1
10 t
U U
100
1000
/s
is the higher value of U U and U U , rounded up to a multiple of three three
Calculation Example 1 (U m = 550 kV) U m = 550 kV
U 10sec = 1.4 · U m / 3 = 445 kV
Rated Voltage: U c, min = 1.05 · U m/√3 = 333 kV U r1 = 1.25 · U c, min = 416 kV U TOV
445
U r2 = _______ = _______ = 414 kV k TOV 1.075
⇒ U r, min = 417 kV
U r, typ = 420 kV
LIWV = 1550 kV
LD-class = 5
Calculation Example 2 (U m = 24 kV; isolated neutral) U m = 24 kV
U 10sec…1h = U m = 24 kV
Rated Voltage: U c, min = U m = 24 kV U r1 = 1.25 · U c, min = 30 kV U TOV
19.4
U r2 = _______ = _______ = 18.1 kV k TOV 1.075
⇒ U r, min = 30 kV
U r, typ = 30 kV
LIWV = 125 kV
LD-class = ---
System Highest voltage of the system U s Grounding l a c i r t c e l e
Temporary overvoltages (TOV)
Arrester
Environment
Min. MCOV, U c,min → rated voltage U r1 Rated voltage U r MCOV, U c Rated voltage U r2
Lightning current stress
Nominal discharge current
Energy (line discharge, switching overvoltages)
Line discharge class
LIWV, safety margin, distance (protection zone)
LI protection level, SI protection level
Density of lightning strikes, magnitude of lightning strikes
Active part specified
l a c i n a h c e m
Length of housing, number of units, flashover distance (withstand voltages)
Short-circuit current
Mechanical stress (short-circuit current, tensile loads)
Creepage, sheds Diameter, material, length of units (number of units)
Height of erection
Pollution
Seismic stress
Direct Lightning Strokes to Overhead Line Conductors The nominal discharge current I n is a coordination current on which the protective characteristics and thus insulation coordination are based. Question: What is a reasonable value for I n?
To answer this question: what are the highest possible currents of a lightning stroke directly into the overhead line conductor?
Direct Lightning Strokes to Overhead Line Conductors CIGRÉ electro-geometrical model
and r g are the maximum striking distances of a return stroke to the stepped leader. • The higher the stroke current, the higher r c and r g. • I m is the maximum current at and above which no strokes will terminate on the phase conductor:
• r c
1
h+ y ⎡ ⎤ 0.75 ⎢ ⎥ 2 I m ≈ ⎢ 7.1 ⋅ (1 − sin α ) ⎥ ⎢ ⎥ ⎣ ⎦
Examples:
α α = shielding angle
Strokes Strokes between between A A and and B B
h = 60 m, y = 45 m, phase phase conductor conductor
Strokes Strokes between between BB and and C CÆ ground wire wire Æ ground
⇒
I m
α =
30 °
α =
15 °
36 kA
h = 30 m, y = 25 m,
Lightning Stroke and Surge Propagation on a Transmission Line 1
2
1 Lightning stroke: two traveling waves of û = ½ ·Z · î (Example: û = ½ · 350 Ω · 20 kA = 3.5 MV) 2 1st insulator: flashover Example:
• 100 % flashover voltage (negative polarity*)): ud100 ≈ 2100 kV for U m = 420 kV • max. current of propagating wave: î = 2100 kV / 350 Ω = 6 kA
Surge currents are limited to values below 10 kA!
Lightning Impulse Current Stress of Station Arresters Usually, Usually, no no direct direct lightning lightning strokes strokes of of discharge discharge currents currents higher higher than than ≈≈ 20 20 kA kA on on shielded shielded transmission transmission lines lines (all (all other other strokes strokes will will hit hit the the shield shield wire wire or or directly directly the the ground) ground) Currents Currents limited limited by by flashover flashover voltage voltage of of line line insulators insulators and and surge surge impedance impedance of of the the line: line:
î î = ûûflashover Z flashover /Z Examples: Examples: U U mm == 123 Z == 450 ≈ 600 Ω 123 kV, kV, ûûflashover 600 kV, kV, Z 450 Ω flashover ≈
î î = = 1.3 1.3 kA kA
U U mm == 420 Z == 350 ≈ 22 100 Ω 420 kV, kV, ûûflashover 100 kV, kV, Z 350 Ω flashover ≈
î î = = 66 kA kA
LI LIcurrents currentsin inthe thesubstation substationusually usuallybelow below10 10kA kA
System Highest voltage of the system U s Grounding l a c i r t c e l e
Temporary overvoltages (TOV)
Arrester
Environment
Min. MCOV, U c,min → rated voltage U r1 Rated voltage U r MCOV, U c Rated voltage U r2
Lightning current stress
Nominal discharge current
Energy (line discharge, switching overvoltages)
Line discharge class
LIWV, safety margin, distance (protection zone)
LI protection level, SI protection level
Density of lightning strikes, magnitude of lightning strikes
Active part specified
l a c i n a h c e m
Length of housing, number of units, flashover distance (withstand voltages)
Short-circuit current
Mechanical stress (short-circuit current, tensile loads)
Creepage, sheds Diameter, material, length of units (number of units)
Height of erection
Pollution
Seismic stress
Energy Requirements
Two aims:
1) 1) Mechanical Mechanical integrity integrity of of the the MO MO blocks blocks 2) 2) Thermal Thermal stability stability
Energy Requirements
Single impulse energy absorption capability • Energetic overloading (puncture or thermo-mechanical cracking of one or more MO-resistors)
Energy Requirements
Thermal energy absorption capability
Electrical power losses
s e , s n s o o i t l a r p e i s w s o i p d l t a c a i r e t H c e l e
Limit of thermal stability (unstable operating point)
Heat dissipation Normal operation (stable operating point)
Temperature
"Thermal" and "Impulse" Energy Values "Thermal"
"Impulse"
1)
2 long duration current impulses, 1 minute apart Ur for 10 seconds
1 long duration current impulse Uc for 30 minutes
Time
Time
Preheat to 60 ºC max. 100 ms
Energy input by two long duration current impulses 1 minute apart (each impulse 50% of the injected energy); thermal stability required 1)
Note: If no thermal stability has to be guaranteed after
energy injection (i.e. arrester de-energized afterwards) higher energy values are allowed.
Energy input by one long duration current impulse t 4 ms; thermal stability not critical
Thermally Equivalent Prorated Section for Operating Duty Test Current supply Gripping Hard tissue
Gripping
Cork
Test sample
Porcelain
Temperature measurement
Current supply
Choice of Line Discharge Class acc. to IEC 60099-5 IEC 60099-5, 1996-02 Surge Arresters - Part 5: Selection and application recommendations Table 1: L D c la s s
a p p ro x . U m kV
a p p r o x . lin e le n g t h km
app rox. Z Ohm
a p p r o x . o v e r v o l ta g e factor *) p.u.
1
≤ 245
300
450
3 ,0
2
≤ 300
300
400
2 ,6
3
≤ 420
360
350
2 ,6
4
≤ 550
420
325
2 ,4
5
≤ 800
480
300
2 ,4 *)
1 p.u. =√2 x Um/ √3
Line Discharge Class (IEC 60099-4) – Problem of Definition W · (U – U res)) ·· 1/ = U 1/Z W = U res Z ·· T T res · (U LL – U res
Arrester classification
Line discharge class
Surge impedance of the line Z (Ω)
Virtual duration of peak T (µs)
Charging voltage U L (kV d.c.)
10 000 A
1
4,9 U r
2 000
3,2 U r
10 000 A
2
2,4 U r
2 000
3,2 U r
10 000 A
3
1,3 U r
2 400
2,8 U r
20 000 A
4
0,8 U r
2 800
2,6 U r
20 000 A
5
0,5 U r
3 200
2,4 U r
Example: Example:
A kJ/kV (2·2 A MO MO arrester arrester with with resistors resistors of of 44 kJ/kV (2·2 kJ/kV) kJ/kV) energy energy absorption absorption capability capability may may be be specified U res U r r == 2, specified as as aa Class Class 22 arrester arrester if if U 2, res//U but U res U r r == 2.4. but as as aa Class Class 33 arrester arrester if if U 2.4. res//U A U res U r r == 22 needs A Class Class 33 arrester arrester of of U needs res//U resistors kJ/kV (2·3 resistors of of 66 kJ/kV (2·3 kJ/kV). kJ/kV).
System Highest voltage of the system U s Grounding l a c i r t c e l e
Temporary overvoltages (TOV)
Arrester
Environment
Min. MCOV, U c,min → rated voltage U r1 Rated voltage U r MCOV, U c Rated voltage U r2
Lightning current stress
Nominal discharge current
Energy (line discharge, switching overvoltages)
Line discharge class
LIWV, safety margin, distance (protection zone)
LI protection level, SI protection level
Density of lightning strikes, magnitude of lightning strikes
Active part specified
l a c i n a h c e m
Length of housing, number of units, flashover distance (withstand voltages)
Short-circuit current
Mechanical stress (short-circuit current, tensile loads)
Creepage, sheds Diameter, material, length of units (number of units)
Height of erection
Pollution
Seismic stress
LI protection level from U -I -Characteristics U U --I I --characteristics characteristics for for
different different MO MO resistors resistors
= (2.8 ... 3.4)·U U U pl pl = (2.8 ... 3.4)·U cc
û r û c
Calculation Examples 1 + 2 (U m = 550 kV and 24 kV) 1) U m = 550 kV
U 10sec = 1.4 · U m / 3 = 445 kV
LIWV = 1550 kV
LD-class = 5
U r, typ = 420 kV
Rated Voltage: Protection Level:
1550 kV
U 10kA = 420 kV · 2.3 *) = 966 kV
<
__________
1.4
1550 kV ( __________ = 1107 kV ) 1.4
;
*) Typical value for LD class 5, but manufacturer dependant
2) U m = 24 kV
Rated Voltage:
U 10sec…1h = U m = 24 kV
LIWV = 125 kV
LD-class = ---
U r, typ = 30 kV
Protection Level:
125 kV U 10kA = 30 kV · 2.67 *) = 80 kV
<
_________
1.4
125 kV ( _________ = 89 kV ) 1.4
;
Typical Values of Protection Level Standard lightning Lightning impulse impulse withstand protective level upl voltage LIWV kV kV kV 24 Resonant earthed 125 80 123 Resonant earthed 550 370 145 Solidly earthed 650 295 245 Solidly earthed 950 485 420 Solidly earthed 1425 825 550 Solidly earthed 1550 960 U s
Neutral earthing
As a rule of thumb, a factor LIWV/upl ≥ 1.4 offers sufficient protection against lightning overvoltage:
Factor LIWV/upl
1.56 1.49 2.2 1.96 1.73 1.61
LIWV u u pl pl
________ ________
1.4 The voltage at the terminals of the equipment to be protected must not reach values above LIWV/1.15 (K s = 1.15 = safety factor for non-self restoring insulation, acc. to IEC 60071-2)
Protection Level and Stability against Power-Frequency Stress 600
Example: U m = 245 kV, neutral effectively earthed U r = 224 kV u10kA=538 kV
500 400
U r = 198 kV u10kA= 475 kV
] V k [ 300 u
200 1.4 times line-to-earth-voltage 100 Line-to-earth-voltage 0 0,0001
0,001
0,01
0,1
1
10 i [A]
100
1000
10000
100000
Lower LI protection level higher specific power-frequency stress Protection level should be set to reasonable (not necessarily the lowest) values!
System Highest voltage of the system U s Grounding l a c i r t c e l e
Temporary overvoltages (TOV)
Arrester
Environment
Min. MCOV, U c,min → rated voltage U r1 Rated voltage U r MCOV, U c Rated voltage U r2
Lightning current stress
Nominal discharge current
Energy (line discharge, switching overvoltages)
Line discharge class
LIWV, safety margin, distance (protection zone)
LI protection level, SI protection level
Density of lightning strikes, magnitude of lightning strikes
Active part specified
l a c i n a h c e m
Length of housing, number of units, flashover distance (withstand voltages)
Short-circuit current
Mechanical stress (short-circuit current, tensile loads)
Creepage, sheds Diameter, material, length of units (number of units)
Height of erection
Pollution
Seismic stress
Housing Requirements
• Mechanical strength • static and dynamic loads by connected conductors • strength against seismic events • Dielectric strength • Short-circuit performance • Performance under polluted conditions • shed profile • creepage distance • flashover distance • partial heating of active parts • internal partial discharges • hydrophobicity (incl. dynamics of hydrophobicity)
Mechanical Strength of Housing Minimum recommended strength if there are no further requirements (given by conductor loads ÅÆ wind, vibration, short-circuit current forces): System voltage Um
Fmin static
Fmin dynamic min. breaking value
(kV)
(N / lbf)
(N / lbf)
(N / lbf)
≤ 420
400 / 90
1000 / 225
1200 / 270
550
600 / 135
1500 / 337
1800 / 405
800
800 / 180
2000 / 450
2400 / 540
(Table valid for porcelain housed arresters)
• Ratio F dyn / F stat = 2.5 for porcelain housings • Ratio F dyn / F stat for polymer housings not yet definitely established
Pressure Relief of a Porcelain Housed Arrester Unit
1) Puncture and flashover of individual MO resistor(s)
2) Internal arc along the full length of the unit
3) Opening of pressure relief devices and venting of the unit
Pressure Relief of a Cage Design Polymer Housed Arrester Unit 1.
Arrester has failed and gas begins to be expelled through the housing.
2.
The gas streams trigger an external flashover and the internal arc is commutated to the outside
Pressure Relief Test according to IEC 60099-4 Ed. 2 (inf.) Test with high current (rated short-circuit current):
5
10
16
20
31.5
40
50
63
80 kA
(additionally: tests with ≈50% and ≈ 25% of rated short-circuit current)
Basic idea:
Ød
• Explosion not allowed • Thermal breaking allowed (definition: all parts within the circular enclosure)
Arrester unit H Circular enclosure
Test with low current:
600 A ± 200 A
Factors that improve pressure relief performance:
• Short housings • Large gas volume • Fast opening pressure relief devices
h >= 0,4 m
• High mechanical strength (porcelain quality, thickness)
• Favorable short circuit
Ø D = (d + 2H) >= 1,8 m Problems: - how to initiate the failure
current loop
see 37/317/CDV
Influence of the Short Circuit Current Loop i
i
i
i
i i
Porcelain Polymer (with gas volume included) Polymer (without gas volume included)
i
i
worst case
most favorable case
neutral case
favorable case
most favorable case
worst case
most favorable cases
worst case
Examples for Successful Pressure Relief Tests with High Current Test with 63 kA/0,2 s on porcelain housed arrester
Examples for Successful Pressure Relief Tests at High Current Test with 63 kA/0,2 s on polymer housed high-voltage arrester (FRP hollow insulator)
Before test
After test
Examples for Successful Pressure Relief Tests at High Current Test with 63 kA/0,2 s on polymer housed high-voltage arrester (cage design)
Examples for Successful Pressure Relief Tests at High Current Test with 20 kA/0,2 s on polymer housed distribution arrester (cage design)
Short-Circuit Performance – Wrap-Up
• In general, polymer housed arresters tend to offer a "safer" short-circuit performance.
• But not all polymer housed arresters are intrinsically "safe". • Design differences must still be regarded.
Performance under Pollution Conditions Measures against: 1 • Long creepage distance • Optimized shed profile 2 • Few number of units (best: single-unit arrester) Radial filed stress:
3
2
- risk of "internal" partial discharges, degradation of the MO resistors and deterioration of the supporting structure or - risk of puncture in case of the housing directly applied to the MO column Risk of partial heating of the active parts (see Annex F of IEC 60099-4)
1 Risk of external flashover
3 In case of gas volume included: • large distance MO column - housing • no sharp edges at the MO column • MO blocks with stable aging characteristics • internal gas volume free of oxygen • high tracking resistance of supporting structure • use of desiccants In case of no gas volume included: • sufficient thickness of housing • optimized shed profile • high tracking resistance of materials
General: Highrated ratedand andcontinuous continuousoperating operatingvoltage voltage General:High
rather ratherthan thanlow lowprotection protectionlevel levelififpossible possible(leads (leadstoto moderate moderateelectrical electricalstress stressunder undercontinuous continuousoperating operating conditions and improves long term stability) conditions and improves long term stability)
Performance under Pollution Conditions – Radial Field Stress MO column Gas or solid
Conductive layer
Solid t n i , l a i x a
U
Uradial
Summary - Characteristic Values (1): Main Data • Continuous operating voltage (U c/MCOV) • Rated voltage (U r ) • Rated frequency • Rated short-circuit current (I s) • Line discharge class (LD-Class) • Nominal discharge current (I n) (8/20 µs) • LI protection level (U pl) (= residual voltage at I n) Additional: residual voltages for different current shapes and amplitudes
Summary - Characteristic Values (2): Additional Data • Long duration current impulse withstand capability (amplitude, time) • Energy absorption capability (in kJ/kV of U r or U c) • High current impulse capability (4/10 µs) (for distribution arresters) • Temporary overvoltage (TOV) capability (1 s, 10 s, 100 s) • Creepage distance • Dielectric withstand values of the housing • Permissible mechanical headloads (static, dynamic)
Metal Oxide Surge Arresters
Voltage and Temperature Distribution of MO Arresters 1800 1600 1400 1200 ] 1000 m m [ H 800
H= 1200 mm H= 1465 mm H= 1805 mm
600 400 200 0 0,7
0,8
0,9
1
1,1
1,2
1,3
1,4
1,5
U/Umittel U/Umean
⇒ Grading rings necessary for arrester heights > 1.5 m ... 2 m
1,6
Arrester U r = 224 kV, Voltage Distribution, Equivalent Circuit 2200 2000 1800 1600 1400 ] m1200 m [ t h g i e 1000 H
800 600 400 200 0 0,7
0,8
0,9
1
1,1
1,2
1,3
Specified Currents for Residual Voltage Tests on MO Arresters Double exponential current impulses: definition by T / 1 T 2 and î T 1 T 2 î
Front time [µs] Time to half value [µs] Amplitude [kA] from IEC 60060-1
FS UL
T 1 = 1.25 · T
L
R PO
C
Typical test circuit
Specified Currents for Residual Voltage Tests on MO Arresters • Switching current impulse: (30…100)/(2·T 1) µs, î <= 2 kA • Lightning current impulse: 8/20 µs, î <= 40 kA (nominal discharge current I n usually 5, 10 or 20 kA) • High current impulse: 4/10 µs, î <= 100 kA (typical values 65 and 100 kA) • Steep current impulse: 1/<20 µs, î <= 20 kA
Specified Currents for Energy Tests on MO Arresters Long duration current impulse: î <= 2 kA T d
Virtual duration of the peak
T t
Virtual total duration
Standard values of T d: 500, 1000, 2000, 2400, 2800, 3200 µs
from IEC 60060-1 Ln UL
Cn
L1 C1
Typical test circuit
FS PO
Accelerated Aging Procedure Accelerated Aging Test:
• Part of Operating Duty Test acc. to IEC 60099-4 • Quality assurance for running MO production
Test Conditions:
• ϑ = 115 ºC, U = 1,05 ·U c, t = 1000 h (6 weeks) • "actual surrounding medium": Air, N2, SF6, (CO2, N2H2) Accelerated Ag ing T es t ac c. to IEC 99-4 2 1,8 Normal Behaviour
1,6
Aging Resistor
1,4 1,2 o P / P
1 0,8 0,6 0,4 0,2 0 0
5
10
15
20 sqrt (t) [s qrt (h)]
25
30
35
40
Accelerated Aging Tests
Switching Surge Operating Duty Test (IEC 60099-4) 2 long duration current impulses, 1 minute apart
Conditioning 4 groups of 5 impulses at In 8/20 µs, superimposed on 1,2 x Uc
2 high current impulses 100 kA, 4/10 µs
1 minute apart
Ur for 10 seconds
Uc for 30 minutes
Preheat to 60 °C
Cool down to ambient temperature
Time interval not specified
Test evaluation (pass criteria):
max. 100 ms
• Decrease of temperature, power loss, resistive component of the leakage current • No significant change of residual voltage (max. 5%) • No puncture, flashover or cracking of MO blocks
Time
High Current Impulse Operating Duty Test (IEC 60099-4) Conditioning 4 groups of 5 impulses at In 8/20 µs, superimposed on 1,2 x Uc
1 high current 1 high current impulse 4/10 µs impulse 4/10 µs
Ur for 10 seconds Uc for 30 minutes
Time 1 minute apart
Preheat to 60 °C
Cool down to ambient temperature
Time interval not specified
Test evaluation (pass criteria):
max. 100 ms
• Decrease of temperature, power loss, resistive component of the leakage current • No significant change of residual voltage (max. 5%) • No puncture, flashover or cracking of MO blocks