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INTEGRATED PROTECTION SCHEME FOR
PUMP-STORAGE HYDROELECTRIC POWER PLANT
Z. Gajić *, J. Menezes *, D. Trišić ¤, M. Čitaković ¤
*ABB AB; SA Products, Sweden, [email protected]¤ PD Drinsko-Limske HPP; Bajina Bašta, Serbia, [email protected]
Keywords: Generator protection, pump-storage hydro unit.
Abstract
This paper describes design of an integrated numerical protection scheme for two pump-storage generator/motor-
transformer units. Regardless of the application complexity,
the complete protection scheme for one unit can be integratedwithin a single numerical multifunctional IED.
1 Introduction
The Bajina Bašta Pump-Storage Plant is located in thevicinity of town Perućac on river Drina. Its two turbinesoperate with a net hydraulic head of approximately 600
meters between an upper reservoir located on the top of Taramountain and the lower lake formed by a dam on Drina river.Each generator/motor-transformer unit has rating of315MVA, 11/242kV, 428.6rpm. In addition to these two unitsanother four 100MVA generators are constructed within the
dam and are used as stand-alone generators.Phase reversal disconnectors are located at the high-voltage
side of the step-up transformer in the 220kV switchyard, asshown in Figure 1. A 220kV substation connecting these units
to the national grid is located 8km away. As a consequencetwo circuit breakers in series are installed on the HV side ofthe step-up transformer in order to secure separation of theunit from the system during fault conditions. Additionally,due to transport limitations, each unit step-up transformer is built by parallel connection of two tanks of 160MVA each.
This plant was put in operation in 1982 when the original protection scheme was designed using discrete
electromechanical relays with induction discs. Due to aging
of the existing equipment new protection scheme is needed.
2 Unit operating modes
The two generator/motor-transformer units have the following particular operating modes which need to be taken inconsideration during design of the integrated protection
scheme with numerical IED:1. Generator operating mode of the unit
2. Pump operating mode of the unit3. Synchronous start [5,6] of the unit into pump mode4. Electrical braking of the synchronous machine for
both generator and pump operating modes
Logical programming capability of the numericalmultifunctional IED [1,3] makes it possible to automatically
detect actual operating condition of the unit and accordinglyadapt relay operation. In the following subsections different
operating modes of the two units will be briefly described.
2.1 Generator and pump operating modes
The main differences between the generator and pump
operating modes are changes in direction of the synchronousmachine rotation and change of direction (i.e. sign) of theactive power flow. Change of the rotation direction
practically causes swapping of the positive and negativesequence quantities measured by the protection scheme. Thismust be taken into consideration during protection schemedesign. Especially numerical generator protection relays can be affected because operation of many protection functionscan be based on current and voltage sequence components.
2.2 Synchronous start
The 315MVA unit is started as a synchronous motor by a
100MVA generator located in the dam, with both unitsinitially at standstill. The necessary switching is performed to
disconnect two machines from the transmission system and toconnect the 100MVA generating unit to the 315MVA pumping unit. For this purpose 89S disconnector is used asshown in Figure 1. Note that the two machines are actuallyinterconnected over short 220kV line. The fields of both unitsare energized and the generator turbine gates are opened to a predetermined position. Both the generator and the motor willaccelerate together. Once the full speed of rotation is achieved
the pump unit is then synchronised with the 220kVtransmission system, at which time the generating unit isdisconnected, and consequently disconnector 89S is opened.
Then the pump is loaded to approximately 300MW.Sometimes this start method is called back-to-back start in theliterature. In this particular plant synchronous start is fullyautomatized and it takes altogether around five minutes to
complete. However its operation shall be supervised by the protection scheme and in case of any malfunction, the two
machines shall be quickly separated.Synchronous start causes linear frequency variations of motorcurrent and voltage signals from 0 to 50Hz as well as linearvoltage magnitude increase from 0% to 100% at machineterminals. Such conditions will have effects on many protection functions. Thus, the IED must be capable to
measure and track the actual power system frequency in order
to ensure proper operation of all protection functionsintegrated with the IED during this start condition.
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~
ROV2 PTOV
59N UN>
STEF PHIZ
59THD U3d/N
T2W PDIF
87O 3Id/I
REG670
CV GAPC
46 I2>
OC4 PTOC
51 3I>
TR PTTR
49 Ith
LEX PDIS
40 Φ<
GOP PDOP
32 P>
GOP PDOP32 P>
OEX PVPH
24 U/f>
UV2 PTUV27 3U<
OV2 PTOV
59 3U>
OC4 PTOC
51 3I>
CC RBRF
50BF 3I> BF
GEN PDIF
87G 3Id/I
Gen/Mot Selection
SA PTUF
81U f<
8km long 220kV OHL
Aux Power
Synch Start
CV GAPC
51/27 I>/U<
CV GAPC
21 Z<
CV GAPC
50AE U</I>
GOP PDOP
32 Q>
GUP PDUP
32 P>
SA PTOF
81O f>Y
Y
OC4 PTOC
87S 3Id>Σ
220kV CB #1
11.5 240kV V
11 110
3 3
kV V
220 100
3 3
kV V
2*160MVA
234.74/11kV
Yd5
315MVA
11kV
428.6rpm
SDD RFUF
60FL
CV MMXU
Meter.
1)
2)
Note:
1) Overcurrent function used as generator diff during starting and el-braking (pickup from 2Hz)
2) Overcurrent function used during back-to-back starting and el-braking (pickup from 2Hz)
EF4 PTOC
51N IN>
89DB
Excitation
Equipment
89G 89P
52-D
El. Braking
Field CB
CV MMXU
Meter.
220kV CB #2 52-R
OC4 PTOC
51/67 3I>
PSP PPAM
78 Ucos
EF4 PTOC
51N IN>
PH PIOC
50 I>>
ROV2 PTOV
59N 3Uo>
SDD RFUF
60FL
GUP PDUP
37 P<
CC RPLD
52PD PD
89S
18000/5A
18000/5A
1200/1A
1200/1A
41
IEC 61850
ANSI IEC
LEGEND:
CV GAPC
27SS 3U<
Figure 1: Application overview for the first generator/motor -transformer unit and new integrated protection scheme
2.3 Electrical braking
A period of time which is required to stop a synchronousmachine, without any additional braking actions, in many
cases can be longer than half an hour. Such prolonged low-speed operation can be dangerous for the machine bearings
due to low oil pressure. Thus, mechanical braking isfrequently used to bring the turbine and rotor of a hydro-generator to a standstill. Such brakes operate on a principle ofmechanical friction which slows down a rotating mass of thegenerator. In case of peak-load and pump-storage power
plants where frequent unit starts and stops are required, themechanical braking does not offer the optimal solution due to
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high maintenance demands. In such cases electric braking isoften used. In this particular case after separation of 315MVAunit from the network its rotational speed reduces naturally to
50% quite quickly, however if no additional actions are takenit will take more than 15 minutes until rotor stops.
In order to speed-up this process electrical braking is applied.When unit speed falls to 50% of the rated speed, disconnector89DB is closed (see Figure 1). This operation effectivelymakes a three-phase short circuit at the machine terminals.Then the field current is applied which is sufficient to induce
80% of the rated current in the stator. These two currents willthen produce a braking torque which will stop the machine
rotor within approximately five minutes. Note that for quitelow speed of rotation, mechanical brakes are also applied.Electrical braking is used in both the generator and the pumpoperating mode.While electrical braking is active, voltage at the machineterminals will be practically zero. This will in effect disable
any frequency tracking features within numerical IED whichis based on voltage measurement [1]. At the same time the
stator current will have almost constant magnitude but withfrequency variation from approximately 25Hz down to 0Hz.Such condition will unquestionably have effect on many protection functions and special means are required to preventrelay unwanted operation and to provide dedicated protectionfunctionality for this particular operating condition.
3 Integrated protection scheme
Connected instrument transformers to the numerical IED are
shown in Figure 1. Statuses of all primary apparatuses, shown
in this figure, are also made available to the IED as double point indications. Finally additional binary signals such as:wicket-closed; speed larger than 80%; synchronous startmode selected and machine stop order are also wired to theIED. Logical programming capability of the IED is then used
in order to derive actual operating mode of the unit. Thisinformation is then used to adjust the operation of various
protection functions integrated within the IED.
3.1 IED protection functionality
This section describes individual features and protectionfunctions integrated into the IED [1,3] for this particular
installation.Frequency tracking is available in the IED and will measureand track actual system frequency by utilizing voltage signalsat the machine terminals. This will enable use of almost all protection functions integrated within IED during all unitoperating modes with exception for electrical braking. During
synchronous start this feature will be fully operational alreadywhen measured voltage has frequency around 9Hz.Differential protections 87G and 87T require no specialtreatment because phase reversal disconnectors are locatedoutside their protection zones (see Figure 1). However, 87Trestraint stage must be blocked during electrical braking andspecial treatment is required during extremely low frequency
condition (i.e. 2Hz-10Hz) when frequency tracking feature isnot fully operational, as described in the next paragraph.
Generator low-frequency differential protection 87S [7] isonly active while machine is in synchronous start or electrical braking operating mode. It is realized by using an overcurrent
function which measures sum of the currents from the twosides of the stator winding. Note that no biasing is required
because external faults are not feasible during these twooperating modes. This function is able to operate fromapproximately 2Hz and it is set to 15% of the machine rating.Machine overcurrent protection 51 is realized by using anovercurrent function with four stages. Two stages are used as
time-delayed backup protection during normal machineoperation. Third instantaneous stage set at 50% of the
machine rating is only active during synchronous start whilethe fourth instantaneous stage set at 125% is only activeduring electrical braking. This function is able to operate fromapproximately 2Hz.Negative sequence protection 46 is realised by using twosequence functions. The first function measures the negative
sequence current and it is only active while machine isrotating as generator. The second function measures the
positive sequence current and it is only active while machineis rotating as motor. Both functions have pickup and timedelay set in accordance with the machine capability.95% stator earth fault protection 59N measuresfundamental frequency voltage at machine neutral point and itis active in all operating modes of the unit.100% stator earth fault protection 59THD is based on third
harmonic differential principle and it is active in all operatingmodes of the unit.80% stator earth fault protection 59N measuresfundamental frequency, open delta voltage at machine
terminals and it is active in all operating modes of the unit.Under-impedance protection 21 has two zones and it is blocked during synchronous start and electrical braking.
Over-current protection with under-voltage seal-in 51/27 has one operating stage and it is blocked during synchronousstart and electrical braking.Loss of excitation protection 40 is based on ph-to-phimpedance measurement and it is blocked during synchronousstart and electrical braking.Fuse failure feature 60FL for 11kV VT is based on ΔI/ΔU
principle and it is blocked while the machine is notsynchronised to the 220kV transmission system.Accidental energising protection 50AE is based on voltage
supervised overcurrent principle but it is blocked duringsynchronous start and electrical braking.Generator thermal overload protection 49 is based on truerms current measurement. It is active in all operating modes.Power functions 32 and 37 are using Arone-connectionwhich insures proper P and Q measurements including
directionality during all operating modes. One under-powerstage, set at 50%, is used for direct tripping in motoroperating mode (loss of power protection), while anotherstage, set at 105%, is used as active, over-power protection in both motor and generator operating modes. Other six stagesare used as inputs into the plant control system.Over-frequency protection 81O is always active.
Under-frequency protection 81U is only active in pumpoperating mode.
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Over-voltage protection 59 measures three ph-to-ph voltagesand it is active in all operating modes.Under-voltage protection 27 measures three ph-to-ph
voltages and it is only active in pump operating mode.Under-voltage protection 27SS measures the maximum ph-
to-ph voltage. It is used as additional protection functionwhich is only active during synchronous start and whenmachine speed exceeds 80%. It shall detect that motorexcitation system has failed to transfer to permanentexcitation supply from the machine terminals. It is set to 50%
with 1s delay.Over-excitation protection 24 is based on ph-to-ph voltage
measurements and it is blocked during electrical braking.Step-up transformer HV side over-current protection 51 is realized by using an overcurrent function with four stages.Two stages are used as time-delayed backup protection duringunit normal operation. Third instantaneous stage set at 75% ofthe transformer rating is only active during synchronous start
with time delay of 0.2s.Step-up transformer HV side earth fault protection 51N is
realized by using a residual overcurrent function with fourstages. Only two stages are used and they are always active.Unit circuit breaker failure protection 50BF is connectedto step-up transformer HV CTs and it can be used to sendinter-trip command to the remote substation in an unlikelyevent of the two 220kV breakers failing to trip.220kV OHL instantaneous over-current protection 50 isset to 9.6kA primary and it is used to instantly trip for anyfault in power plant 220kV switchyard.220kV OHL over-current protection 51/67 is used as backup protection for 8km long 220kV OHL.
220kV OHL earth fault protection 51N is used as backup protection for 8km long 220kV OHL.Pole discordance protection 50PD is used to detect failureof the primary apparatuses to open/close all three poles.
Pole slip protection 78 is connected to 220kV line CTs andVTs outside of the phase reversal disconnectors, whichenables use of positive sequence quantities for this protectionirrespective of the generator or pump operating mode of theunit. Function is based on Ucosφ principle.Fuse failure feature 60FL for 220kV VT is based on
measurement of negative and zero sequence quantities and itis always enabled.
Tripping matrix is designed to emulate existing tripping
arrangements used by discrete electromechanical relays.
3.2 IED metering and monitoring functionality
The IED provides P, Q, S, U, I, f and cosφ measurements at
generator terminals as well as for the 220kV line. Thesemeasurements are shown as on-line service values on thesingle line diagram which is available on the IED built-inHMI, (see Figure 2). This facilitates testing, commissioningand trouble shooting of the integrated protection scheme [4].Built in disturbance recorder and event list provide
information about IED operation during secondary and primary testing [4] as well as during different operating
modes of the unit. Internally calculated quantities such as P,Q, f and differential currents can also be recorded.
Figure 2: SLD with on-line measurements
Programmable LEDs provide quick operator overview about protection function which caused tripping of the unit. The
IED also displays the operating mode of the unit on the built-in HMI as determined by the logic programmed within therelay.
4 Field experience
The integrated protection scheme was put in trial services in
August 2009. Since then, operating experience wascompletely in accordance with expectations. During October
2009 minor modifications to the relay configuration andsettings were performed in order to optimize usage of the built-in disturbance recorder and event list during differentoperating modes of the unit. Additionally function 27SS wasintroduced into the scheme in order to ensure detection offailure within excitation system of the 315MVA motor unit
during synchronous start mode.The following figures come from recordings captured during
unit actual operation. Figure 3 and Figure 4 shows statorcurrent waveforms during electrical braking. Most surprisingwere waveforms for low rotational speeds (see Figure 4)which caused some spurious starting of 87S function.Figures 5 and 6 were captured during synchronous start, when
motor excitation failed to transfer to permanent supply. Atfull speed of rotation motor voltage is below 50% of rated
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(see Figure 6). As a consequence function 27SS wasintroduced to detect such condition.
0 20 40 60 80 100100
50
0
50
100
IL1
IL2
IL3
Gen NP Current Waveforms
Time [ms]
C u r r e n t
[ % ]
Figure 3: Stator currents at the beginning of el. braking
0 500 1 103
1.5 103
100
50
0
50100
IL1
IL2
IL3
Gen NP Current Waveforms
Time [ms]
C u r r e n t [ % ]
Figure 4: Stator currents at the end of el. braking (f<1Hz)
0 20 40 60 80 10040
20
0
20
40
IL1
IL2
IL3
Gen NP Current Waveforms
Time [ms]
C u r r e n t [ % ]
Figure 5: Currents for synch. start with failed excitation
0 20 40 60 80 100100
50
0
50
100
UL1L2
UL2L3
Gen Voltage Waveforms
Time [ms]
V o l t a g e [ % ]
Figure 6: Low voltages for synch. start with failed excitation
Behaviour of the 100% stator earth fault protection 59THD, based on the third harmonic differential measurement [2], isextremely good. Third harmonic voltages have almost
constant relationship irrespective of the actual operating modeof the unit. Figure 7 shows third harmonic voltages captured
on the unit one during pump operating mode.
0 20 40 6020
10
0
10
20
3Uo_TRMUN_NP
Third Harmonic Voltages
Time [ms]
V o l t S e c o n d a r y
Figure 7: Third harmonic voltages in pump mode
5 Conclusion
Bajina Bašta pump-storage plant is crucial for everydayoperation of the Serbian power system. The two units are
typically operated in the generator mode during the day and inthe pump mode during the night. Thus, integrity of the protection scheme for these two units is essential.The new integrated protection scheme is still under trialoperation, which means that the new tripping matrix is
blocked, but its performance is completely satisfactory. Thenext step would be to install the second identical IED to
obtain redundancy, enable the trip matrix and thendecommission the old electromechanical protection scheme.
References
[1] ABB. “Generator Protection IED REG670, TechnicalReference Manual”, 1MRK502013-UEN , (2007).
[2] I. Brnčić, et al. “Adaptive 100% stator earth fault protection based on third harmonic voltagemeasurement”, International Conference on Relay
Protection and Substation Automation of Modern EHV
Power Systems, Moscow – Cheboksary, Russia, (2007).[3] Z. Gajić. “REG670 Installation in RHE Bajina Bašta”,
ABB Doc. No. 1MRG000228 , (2009).[4] Z. Gajić. “Test Report for REG 670 installed on GM1
unit in RHE Bajina Bašta”, ABB Doc. No.1MRG000235, (2009).
[5] IEEE PSRC. “Protective relaying for pumped storage
hydro units rotating machinery protection subcommitteeof the IEEE power system relaying committee”,
Transaction on Power Apparatus and Systems, volume94, pp. 899-907, (1975).
[6] IEEE PSRC. “IEEE Guide for AC Generator Protection”,IEEE Std C37.102™-2006 .
[7] M. Stien. “Generator Protection Application Guide”, ASEA, A03-0211E , (1983).