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T&DProtection & Control
MiCOM P433, P435, P437Distance Protection Devices
MiCOM P433, P435, P437Distance Protection
Devices
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Application and scope
The MiCOM P433, P435 andP437 Distance Protection Devicesare used
for selective short-circuitprotection, ground fault protection(UK:
earth fault) and overloadprotection in medium, high andextra high
voltage systems. Thesystems can be operated as solidlygrounded, low
impedancegrounded (UK: solidlyearthed/resistance earthed),resonant
grounded (UK: PetersenCoil) or insulated neutral systems.
The devices have the followingcommon main functions: Fault
detection logic using
Overcurrent Undervoltage Under-impedance with load
blinding Neutral overcurrent and/or
neutral displacement voltage Distance protection with
Polygonal or circular trippingcharacteristics
Six distance zones Zone 1 extension Timer stages per zone and
two
additional back-up timer stages Directional voltage memory
Measuring circuit monitoring Back-up overcurrent time
protection Protective signaling (channel
aided scheme logic) Auto-reclosing control Definite time
overcurrent
protection, 4 stages Inverse time overcurrent
protection, 1 stage, directional
Over/undervoltage protection Over/underfrequency protection
Thermal overload protection Switch-on-to-fault protection Circuit
breaker failure protection Limit value monitoring Programmable
scheme logic.
The P433 and P435 distanceprotection devices have thefollowing
additional main functionsespecially for ground fault detectionand
direction determination inPetersen Coil grounded or
insulatedneutral power systems:
Directional power protection Ground fault direction
determination using steady statevalues
Transient ground fault directiondetermination (optional)
Ground fault protection signaling Ground fault tripping
The P435 and P437 distanceprotection devices have thefollowing
additional main functionsfor use in HV/EHV power systems:
Power swing blocking Auto-reclosing control (single and
three pole) Automatic synchronism check
(optional) Ground fault (short circuit)
protection (UK: Directional earthfault protection, DEF)
Ground fault (short circuit)protection signaling (UK: DEFscheme
logic)
All main functions are individuallyconfigurable and can be
disabledor enabled by the user as desired.By means of a straight
forward
configuration procedure, the usercan adapt the device flexibly
to thescope of protection required ineach particular application.
Due tothe powerful, freely configurablelogic of the device,
specialapplications can beaccommodated.
In addition to the features listedabove, as well as
comprehensiveself monitoring, the following globalfunctions are
available in thedevices:
Parameter subset selection (4 alternative setting groups)
Operating data recording (time tagged signal logging)
Overload data acquisition
Overload recording (time tagged signal logging)
Ground fault data acquisition
Ground fault recording (time tagged signal logging)
Measured fault data
Fault recording (time tagged signal loggingtogether with
disturbancerecording of all measuredsignals: phase and residual
2
MiCOM P433, P435, P437Distance Protection Devices
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3current, phase-ground voltages,neutral displacement and
busbarreference voltage)
The P433/435/437 are ofmodular design. The pluggablemodules are
housed in a robustaluminium case and electricallyconnected via an
analogue and adigital bus printed circuit board.
The nominal currents or nominalvoltages, respectively of
themeasuring inputs, can be set withthe help of function
parameters.
The nominal voltage range of theoptical coupler inputs is 24 to
250Vdc without internal switching.
The auxiliary voltage input for thepower supply is a wide
rangedesign with a nominal voltagerange of 48 to 250V dc and 100to
230V ac. An additional versionis available for the lower
nominalvoltage range of 24 to 36V dc.
All output relays are suitable forboth signals and trip
duties.
The optional PT 100 input is leadcompensated, balanced and
linearised for PT 100 resistancethermometers per IEC 60751.
The optional 0 to 20mA inputprovides open circuit and
overloadmonitoring, zero suppressiondefined by a setting, plus the
optionof linearising the input variable via20 adjustable
interpolation points.
Two freely selected measuredsignals (cyclically updatedmeasured
operating data andstored measured fault data) can beoutput as a
load independent directcurrent via the two optional 0 to20mA
outputs. The characteristicsare defined via 3
adjustableinterpolation points allowing aminimum output current
(4mA, forexample) for receiver side opencircuit monitoring, knee
pointdefinition for fine scaling and alimitation to lower nominal
currents(10mA, for example).
Where sufficient output relays areavailable, a freely
selectedmeasured variable can be output inBCD-coded form via
contacts.
Control and display
Local control panel
17 LED indicators, 12 of whichallow freely configurable
functionassignment
PC interface
Communication interface(optional).
Information exchange is via thelocal control panel, PC
interfaceand the optional communicationinterface. Using this
informationinterface, the devices can beintegrated with substation
controlsystems or telecontrol systems.
Figure 1: Functional overview
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Phase selective undervoltagedetection (V).
Undervoltage and under-impedancedetection can be
enabledseparately.
All fault detection measurementelements operate
simultaneously.
Inrush stabilisation
The operate function of overcurrentdetection can be stabilised
underinrush conditions if desired. The ratio of the second
harmoniccomponent of the phase currents tothe fundamental serves as
thecriterion. This stabilisation is eitherphase selective or
effective acrossall three phases depending on thechosen
setting.
Fuse failure monitoring
A failure of the measuring voltagecaused by a short circuit or
linebreaks in the secondary circuit, canbe detected by the internal
fusefailure monitoring function. In thisevent, the distance
protectionfunction will automatically beblocked and if appropriate,
theback-up overcurrent time protectionfunction will be
activated.
Phase selection
P433 and P435 devices evaluatethe distance decision only for
onefault loop. This loop is selecteddepending on the fault
typedetermined by the fault detectionlogic and the set loop
preference.
P437 devices evaluate the distancedecision for all fault loops.
These loops are selected dependingon the fault type determined by
thefault detection logic and whereapplicable to the set
looppreference, eg. if only phase-phaseloop should be evaluated in
case ofphase-phase ground faults.
Directional voltage memory
Directional determination requires avoltage memory for the
followingreasons:
Measuring voltage is too smallfor short fault distances
Transients in the presence ofcapacitive voltage transformers
Protection of series compensatedlines.
To eliminate these problems, thedistance protection devices
areequipped with a voltage memorywith continuous writing of
thephase-phase voltage VAB into a ringmemory as long as the voltage
andfrequency conditions are satisfied.
The directional determinationelement can access the
voltagememory when the measuredvoltages fall below a set
value.Frequency compensation allows thememory to be used as a
validdirectional reference for up to 2seconds after fault
inception.
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Figure 2:Fault detection characteristic(Setting values: see
address list)
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5Distance and directionaldetermination
For measured angles within therange 45 to +135, a forward
direction decision isissued, for angles outside thisrange, a
backward directiondecision ensues. The distancedecision is obtained
by comparingthe measured impedance with theset polygonal or
circular trippingcharacteristic (see Figure 3).
Six independent distance zones canbe set in total. Each zone can
beset as forward directional,backward directional or nondirectional
to suit requirements.
Additional zone extension factorsfor phase-phase and
phase-groundloops may be set for zone 1. Zoneextension is
controlled by integratedfunctions such as auto-reclosingcontrol,
protective signaling or byan external signal.
With the P433 and P435, the fourthzone can be used as a
specialzone depending on the setoperating mode, eg. to allow
auto-reclosing only on the overhead linesection in cable/line
systems or tocompensate the bundle conductoreffect. With the P437,
the sixthzone is permanently measured andcould be used in user
definedscheme logic.
Tripping timer stages
Each of the distance zones isassigned a settable timer
stage.Additional timers serve asdirectional and
non-directionalback-up timer stages, respectively.Once the back-up
timer stages haveelapsed, the tripping decisionproceeds independent
of distancemeasurement.
All timer stages are initialised whena fault is detected. All
tripping timerstages can be used separately.
Mutual compensation
When protecting parallel lines, caremust be taken for the effect
ofmutual coupling of the lines in thezero sequence system. The
P437could optionally be equipped withan additional CT input to
measurethe residual current of the parallelline. This current can
be taken intoaccount by the calculation of theground fault loop
impedances,depending on a settable ratio of theresidual currents of
the two lines.
Power swing blocking (P435 and P437 only)
Power sings between generatorsdue to severe load variations
orsystem faults, may cause measuredimpedances to enter
distancezones. To avoid incorrect tripping,the devices measure the
ratedchange of power over a two cyclewindow to implement blocking
forthe duration of the swing.
Switch-on-to-fault protection
Closing of a circuit breaker mightinadvertently lead to a short
circuitfault due to a maintenance groundclamp not yet removed,
forexample.
The function switch-on-to-faultprotection provides for
anundelayed protective trippingduring a settable time after amanual
close command has beenissued. Depending on the operatingmode,
either a trip command withinitialisation of the fault
detectionlogic or a zone extension ofdistance protection according
to theset zone extension factors results.
Measuring circuit monitoring
The voltage measuring circuits needto be monitored for short
circuitsand line breaks. In preference, theauxiliary contact of the
voltagetransformer m.c.b. is used to blockthe voltage dependent
protectionfunction in the event of a shortedmeasuring circuit.
Additionally,internal monitoring can be activatedso as to check for
plausibility of themeasured zero sequence andnegative sequence
components ofcurrent and voltage. If voltageunbalance is diagnosed
then all
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Figure 3:Tripping characteristic Zone 1(Setting values: see
address list)
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6voltage dependent protectivefunctions such as
distancemeasurement are blockedautomatically.
Furthermore, negative sequencecurrent and voltage are
monitoredfor compliance with set limit values.If the limit value is
exceeded for aset period of time then a signal isissued.
Current unbalance monitoring canbe used to implement functions
suchas circuit breaker pole discrpancy.
Back-up overcurrent timeprotection
When a fault occurs in the voltagemeasuring circuit,
distancemeasurement is no longer possible.In this case, a one stage
back-upovercurrent time protection function(BUOC) can be
enabledautomatically. Activation of the auto-reclose control
function is optionalduring BUOC operation.
Back-up overcurrent time protectionstarting can be blocked by
inrushstabilisation if desired (seeDistance Protection).
Channel aided scheme logic
Protective signaling
The distance reach is usually set tovalues below 100% line
length soas to avoid overlapping of adjacentsubstations. Protective
signaling(teleprotection scheme logic)extends the reach of
protection to100% by a logic operation on thesignals transmitted by
the remotesubstation.
Protective signaling can beoperated using one of the
followingschemes shown in the table below.
With P437 phase selective signaltransmission is possible.
Where required, the followingadditional features can
beactivated:
Weak infeed trip logic
Echo
Transient blocking
Frequency monitoring (de-blocking)
A test send signal can be triggeredvia any of the device
interfaces.
Automatic synchronism check(P435 and P437 only/optional)
This function can be used inconjunction with automatic ormanual
(re)closure. In non radialnetworks this ensures that reclosurewill
proceed only if the synchronismconditions are met.
Auto-reclosing control
The internal auto-reclosing control(ARC) capabilty depends on
thedevice type:
P433: only 3 pole
P435: 1/3 pole, start dependent
P437: 1/3 pole, trip dependent.
ARC cycles with an high speedreclosure (HSR) and up to
ninesubsequent time delay reclosures(TDR) are possible. HSR and
TDRare independently configurable. For special cases, tripping
prior toan HSR or TDR can be delayed.Triggering of the ARC function
viabinary inputs (tripping by aprotective device operating
inparallel) can be effected.
Single pole tripping of the P435and P437 devices is possible
withsingle phase faults (1pG) andisolated two phase faults (2p).
Via three binary inputs, the phaseselective tripping signals of
aprotective device operating inparallel, can be used for
aplausibility check of the devicesown tripping decision.
HSR and TDR reclosures arecounted and signaled separately.
Test HSR can be triggered via anyof the device interfaces.
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7Tripping time characteristics of Inverse Time Overcurrent
Protection
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Ground fault (short circuit)protection (P435 and P437 only)
In the event of single phase faultswith high fault contact
resistances,conventional distance algorithmsmay not be sufficiently
sensitive.This fault condition is covered bythe device with a
highly sensitiveintegrated back-up protectionfunction, namely a
zero sequencepower directional protectionfunction using current and
voltageof the zero sequence network forfault and directional
determination.When the set operate values VNG>and IN> are
exceeded, detectionand selective clearance of singlepole faults can
be performed.
Ground fault (short circuit) protection signaling (P435 and P437
only)
In order to achieve high speedtripping by the ground fault
(short circuit) protection function, thedevice is equipped with
asupplementary ground fault (short circuit) protection
signallinglogic. The operating mode of thislogic function is in
parallel to andindependent of the protectivesignalling function of
distanceprotection. The only limitationswould result if a
commontransmission channel is used.
The following operating modes aresupported:
Signal comparison releasescheme
Signal comparison blockingscheme
The following functions can beactivated as required to suit
theindividual application:
Weak infeed trip logic
Echo
Transient blocking
Frequency monitoring
A test send signal can be triggeredvia any of the device
interfaces.
Definite time overcurrentprotection
A four stage definite timeovercurrent protection (DTOC)function
can be activated in parallelto distance protection. Three separate
measuring elementsare available for this purpose:
Maximum phase current
Negative sequence current
Residual current
Starting of the phase and negativesequence current stages can
beblocked by inrush stabilisation (seedistance protection) if
desired.
Inverse time overcurrentprotection
The single stage inverse timeovercurrent protection
(IDMT)function operates with threeseparate measuring elements:
Maximum phase current
Negative sequence current
Residual current
For the individual measuringelements, the user can select from
amultitude of tripping characteristics(see table below).
The IDMT protection function can beoperated in directional mode.
The directional decision can eitherbe accepted from the
distancemeasuring element or can beformed from the negative
sequencecurrent and voltage.
Starting of the phase and negativesequence current stages can
beblocked by inrush stabilisation ifrequired (see distance
protection).
No. Tripping time characteristic Constants and formulae (t in
s)(k = 0.01 to 10.00) a b c R
0 Definite time t = k
Per IEC 60255-31 Normally inverse 0.14 0.022 Very inverse 13.5
1.002 Extremely inverse 80 2.004 Long time inverse 120 1.00
Per ANSI/IEEE C37.112 Trip Release5 Moderately inverse 0.0515
0.0200 0.1140 4.856 Very inverse 19.6100 2.0000 0.4910 21.607
Extremely inverse 28.2000 2.0000 0.1217 29.10
Per ANSI Trip Release8 Normally inverse 8.9341 2.0938 0.17966
9.009 Short time inverse 0.2663 1.2969 0.03393 0.5010 Long time
inverse 5.6143 1.0000 2.18592 15.75
Not per standard11 RI type inverse
Not per standard11 RXIDG type inverse
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8Over/undervoltage protection
The over/undervoltage timeprotection function evaluates
thefundamental wave of the phasevoltages and neutral
displacementvoltage, as well as the positivesequence voltage and
negativesequence voltage obtained from thefundamental wave of the
threephase-ground voltages. Two definite time delay
overvoltagestages each are provided forevaluation of the
neutraldisplacement voltage and negativesequence voltage. Two
additionaldefinite time delay undervoltagestages each are provided
forevaluation of the phase voltagesand positive sequence
voltage.
Phase voltage evaluation can beperformed using either the
phase-phase voltages or the phase--ground voltages as desired.For
evaluating the neutraldisplacement voltage, the user maychoose
between the neutraldisplacement voltage formedinternally from the
three phase-ground voltages and theneutral displacement voltage
formedexternally (from the open deltawinding of the voltage
transformer,for example) via the fourth voltagemeasuring input.
Over/underfrequencyprotection
Over/underfrequency protectionhas four stages. Each of these
canbe operated in one of the followingmodes:
Over/underfrequency monitoring
Over/underfrequency monitoringcombined with
differentialfrequency gradient monitoring(df/dt) for system
decouplingapplications
Over/underfrequency monitoringcombined with medium
frequencygradient monitoring
(f/t) for load sheddingapplications
Directional power protection
(P433 and P435 only)
The directional power protectionmonitors exceeding active
andreactive power limit, power dropand reversal of direction
atunsymmetrically operated lines.Evaluation of the power
isperformed using the fundamentalwave of the three phase
currentsand of the three phase-groundvoltages.
Thermal overload protection
Using this function, thermaloverload protection for
lines,transformers and stator windings ofHV motors can be realized.
The highest of the three phasecurrents serves to track a first
orderthermal replica according to IEC 60255-8. The tripping time
isdetermined by the set thermal timeconstant of the protected
objectand the set tripping level tripdepending on the
accumulatedthermal load p:
A warning signal can be issued inaccordance with the set
warninglevel warning.
Circuit breaker failureprotection
With the trip command, a timerstage is started for the
monitoring ofthe circuit breaker action. If thetimer elapses due to
the persistenceof the general starting, a circuitbreaker failure
signal is issued.This serves to issue a second tripcommand (retrip)
or, according tothe users choice, to tripneighbouring protection
device(upstream breaker).
The input of a circuit breakerfailure signal via an
appropriatelyconfigured binary input while thegeneral starting
persists, effects anundelayed trip command.
Ground fault directiondetermination using steadystate
values(P433 and P435 only)
The ground fault direction isdetermined by evaluating theneutral
displacement voltage (eg. from the open delta winding ofthe voltage
transformer) and theresidual current (eg. from a corebalance or
window type currenttransformer). The directional characteristic can
beset to suit the method of systemgrounding (cos measured
forPetersen Coil and sin circuit forinsulated neutral). In the cos
circuit, the adjustable sector anglealso has an effect so that
faultydirection decisions (resulting, forinstance, from the phase
angle errorof the current and voltagetransformers) can be
suppressedeffectively. Operate sensitivity andsector angle can be
set separatelyfor the forward and backwarddirection,
respectively.
Alternatively, an evaluation basedon current only can be
performed.In this case, only the magnitude ofthe filtered residual
current is usedas ground fault criterion.
Both procedures operate with eitherthe filtered fundamental or
the fifthharmonic component in accordancewith the chosen
setting.
Transient ground faultdirection determination(P433 and P435
only/optional)
The ground fault direction isdetermined by evaluating theneutral
displacement voltage,calculated from the three phase--ground
voltages and theneutral current on the basis of thetransient ground
fault measuringprocedure. The direction decision islatched. The
user may select eithermanual or automatic resetting aftera set time
delay.
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9Limit monitoring
A multitude of currents, voltagesand the measured temperature
aremonitored to aid operation of theprotected line. This function
is notintended to be used for protectionpurposes, as it has an
inherent onesecond delay.
For example, for the 3-phasecurrents, the phase-ground
voltagesand the phase-phase voltages thehighest and lowest value
isdetermined. These are evaluatedusing an operate value and
timedelay set by the user. Thereby, thesecurrents and voltages can
bemonitored for exceeding an upperlimit or falling below a lower
limit.
Programmable logic
User configurable logic enables theuser to set-up logic
operations onbinary signals within a frameworkof Boolean equations.
By means ofa straightforward configurationprocedure, any of the
protectiondevice signals can be linked bylogic OR or AND operations
withthe possibility of additionalnegation operations.
The output signal of an equationcan be fed into a further,
higherorder equation as an input signal,thus leading to a set of
interlinkedBoolean equations.
The output signal of each equationis fed to a separate timer
stage withtwo timer elements each and achoice of operating modes.
Thus theoutput signal of each equation canbe assigned a freely
configurabletime characteristic.
The two output signals of eachequation can be configured to
eachavailable input signal after logic ORlinking. The user
configurable logicfunction is then able to influence theindividual
functions without externalwiring (block, reset, trigger,
forexample).
Via non-storable continuous signals,monostable trigger signals
andbistable stored setting/resettingsignals, the Boolean equations
canbe controlled externally via any ofthe devices interfaces.
Global functions
Functions operating globally allowthe adaptation of the
devicesinterfaces to the protected powersystem, offer support
duringcommissioning and testing,providing continuously
updatedinformation on the operation, aswell as valuable analysis
resultsfollowing events in the protectedsystem.
Clock synchronization
The devices incorporate an internalclock with a resolution of
1ms. All events are time tagged basedon this clock, entered in
therecording memory appropriate totheir significance and signalled
viathe communication interface.Alternatively, two
externalsynchronisation signals can be used according to the
selectedcommunication protocol: using one of the protocols
MODBUS,DNP3.0, IEC 60870-5-103 or IEC 60870-5-101 the device will
besynchronised by a time telegramfrom a higher level
substationcontrol system or in any other case,it will be
synchronised using theIRIG-B signal input. The internalclock will
then be adjustedaccordingly and operate with anaccuracy of 10ms if
synchronisedvia protocol and 1ms ifsynchronised via IRIG-B
signal.
Parameter subset selection
The function parameters for settingthe protection functions are,
to alarge extent, stored in fourindependent parameter
subsets.Switching between these alternativesetting groups is
readily achievedvia any of the devices interfaces.
Operating data recording
For the continuous recording ofprocesses in system operation or
ofevents, non-volatile ring memoryentries are provided. The
relevantsignals, each fully tagged with dateand time at signal
start and signalend, are entered in chronologicalsequence. Included
are controlactions such as enabling ordisabling of functions as
well aslocal control triggering for testingand resetting. The onset
and end ofevents in the network, as far asthese represent a
deviation fromnormal operation (overload, groundfault or short
circuit, for example)are recorded.
Overload data acquisition
Overload situations in the networkrepresent a deviation from
normalsystem operation and can bepermitted for a brief period
only.The overload protection functionsenabled in the protection
andcontrol units recognise overloadsituations in the system and
providefor acquisition of overload datasuch as the magnitude of
theoverload current, the relativeheating during the
overloadsituation and its duration.
Overload recording
While an overload conditionpersists in the network, the
relevantsignals, each fully tagged with dateand time at signal
start and signalend, are entered into a non-volatilememory in
chronological sequence.The measured overload data, fullytagged with
the date and time ofacquisition, are also entered. Up toeight
overload situations can berecorded. If more than eightoverload
situations occur withoutinterim memory clearance then theoldest
overload recording isoverwritten.
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10
Ground fault data acquisition
While a ground fault in a networkwith isolated neutral or
resonantgrounding represents a system fault,it is usually
nevertheless possible, inthe first instance, to continue
systemoperation without restrictions. The ground fault
determinationfunctions enabled in the protectiondevice recognise
ground faults inthe system and provide for theacquisition of the
associated groundfault data such as, the magnitude ofthe neutral
displacement voltageand the ground fault duration.
Ground fault recording
While a ground fault conditionpersists in the power system,
therelevant signals, each fully taggedwith date and time at signal
startand signal end, are entered into anon-volatile memory
inchronological sequence. The measured ground fault data,fully
tagged with the date and timeof acquisition, are also entered. Up
to eight ground faults can berecorded. If more than eight
groundfaults occur without interim memoryclearance then the oldest
groundfault recording is overwritten.
Fault data acquisition
A short circuit within the network isdescribed as a fault. The
shortcircuit protection functions enabledin the devices recognise
shortcircuits within the system andtrigger acquisition of the
associatedmeasured fault data such as, themagnitude of the short
circuitcurrent and the fault duration. As acquisition time, either
the endof the fault or the start of the tripcommand can be
specified by theuser. Triggering via an externalsignal is also
possible. The acquisition of the measuredfault data is performed in
themeasuring loop selected by theprotective device and
providesimpedances and reactances as wellas current, voltage and
anglevalues. The fault distance isdetermined from the measured
shortcircuit reactance and is read outwith reference to the set
100%value of the protected line section.The fault location is
output eitherwith each general starting or onlywith a general
startingaccompanied by a trip (accordingto the users choice).
Fault recording
Fault recording comprises event anddisturbance recording along
withthe stored fault measurands. Whilea fault condition persists in
thepower system, the relevant signals,each fully tagged with date
andtime at signal start and signal end,are entered into a
non-volatilememory in chronological sequence.The measured fault
data, fullytagged with the date and time ofacquisition, are also
entered.Furthermore, the sampled values ofall analogue input
variables such asphase currents and phase-groundvoltages are
recorded during afault. Up to eight faults can berecorded. If more
than eight faultsoccur without interim memoryclearance then the
oldest faultrecording is overwritten.
Self monitoring
Comprehensive self monitoringprocedures within the devicesensure
that internal hardware orsoftware errors are detected and donot
cause malfunctions of theprotective devices.
As the auxiliary voltage is turnedon, a functional test is
carried out.Cyclic self monitoring tests are runduring operation.
If test resultsdeviate from the default value thenthe corresponding
signal is enteredinto the non-volatile monitoringsignal memory. The
result of thefault diagnosis determines whethera blocking of the
protection devicewill occur or whether a warningonly is issued.
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11
Control
All data required for operation ofthe protection and control
unit areentered from the integrated localcontrol panel. Data
important forsystem management is also read outfrom here. The
following tasks canbe handled via the local controlpanel:
Readout and modification ofsettings
Readout of cyclically updatedmeasured operating data andstate
signals
Readout of operating data logsand of monitoring signal logs
Readout of event logs (afteroverload situations, ground faultsor
short circuits in the powersystem)
Resetting of the unit andtriggering of further controlfunctions
designed to supporttesting and commissioning tasks
The local control panel shown inFigure 4 comprises the local
controlelements and functions describedbelow.
Display
(1) The integrated local controlpanel has an LCD display with4 x
20 alphanumericcharacters.
17 LED indicators are provided forsignal display.
(2) 5 LED indicators arepermanently assigned tosignals.
(3) The remaining 12 LED indicatorsare available for
freeassignment by the user. A separate adhesive label isprovided
for user definedlabeling of these LED indicatorsaccording to the
chosenconfiguration.
Menu tree
(4) By pressing the cursor keysand guided by the
LCD display, the user moveswithin a plain text menu. All setting
parameters andmeasured variables as well asall local control
functions arearranged in this menu which isstandardised for all
systemdevices. Changes to the settingscan be prepared and
confirmedby means of the ENTER key
which also serves to triggerlocal control functions. In theevent
of erroneous entries, exitfrom the EDIT MODE withrejection of the
entries ispossible at any time by meansof the CLEAR key . Whenthe
EDIT MODE is not activated,pressing the CLEAR key has theeffect of
resetting theindications. Pressing the READkey provides direct
accessto a preselected point in themenu.
Type label and PC interface
(5) The upper covering flap islabeled with the device
typedesignation. Located under theflap is the type
identificationlabel with information on theorder number, serial
numberand the nominal electricalvalues.
(6) Located under the lowercovering flap is the serialinterface
for connecting a PC.
(7) To prevent unauthorizedopening of the lower flap, it canbe
sealed using the attachedeyelets.
1
2
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3
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Figure 4: Local control panel
Measured value panels
The configuration of the localcontrol panel allows the
installationof measured value Panels on theLCD display. The Panels
areautomatically displayed for certainoperation conditions of the
system.Priority increases from normaloperation to operation
underoverload conditions and finally tooperation following a short
circuit inthe system. The protection devicethus provides the
measured valuedata relevant for the prevailingconditions.
Password protection
Access barriers protect the entermode in order to guard
againstinadvertent or unauthorisedchanging of parameters
ortriggering of control functions
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12
Mechanical design
The device is supplied in two casedesigns.
Surface mounting case
Flush mounting case
With both case designs, connectionis via threaded terminal ends
withthe option of either pin terminal orring terminal
connection.
Two 40TE flush mounted cases canbe combined to form a complete19
mounting rack.
Figure 5 shows the modularhardware structure of the devices.The
plug-in modules can becombined to suit individualrequirements. The
device itself canidentify the fitted modules. During each startup,
the numberand type of fitted modules areidentified and checked
forcompliance with the permissibleconfigurations. As as function of
thecomponents actually fitted, thecorresponding
configurationparameters are then enabled forapplication.
Transformer module T
The transformer module converts themeasured currents and
voltages tothe internal processing levels andprovides for
electrical isolation.
Processor module P
The processor module performs theanalogue/digital conversion of
themeasured variables as well as alldigital processing tasks.
Transient ground faultevaluation module N
The optional transient ground faultmodule evaluates the
measuredvariables according to the transientground fault evaluation
scheme.
Local control module L
The local control moduleencompasses all control and
displayelements as well as a PC interfacefor running the operating
program.The local control module is locatedbehind the front panel
andconnected to the processor modulevia a ribbon cable.
Communication module A
The optional communication moduleprovides a serial
informationinterface for the integration of theprotection and
control unit into asubstation control system. The communication
module isplugged into the processor module.
Bus modules B
Bus modules are printed circuitboards (PCBs) without any
activecomponents. They provide theelectrical connection between
theother modules. Two types of busmodules are used, namely
theanalogue and the digital bus PCB.
Binary I/O modules X
The binary I/O modules areequipped with optical couplers
forbinary signal input as well as outputrelays for the output of
signals andcommands or combinations ofthese.
Analogue module Y
The analogue module is fitted witha PT 100 input, a 20 mA input
andtwo 20 mA outputs. One outputrelay each is assigned to two 20 mA
outputs. Additionally, fouroptical coupler inputs are
available.
Power supply module V
The power supply module ensuresthe electrical isolation of the
deviceas well as providing the powersupply. Depending on the
chosendesign version, optical couplerinputs and output relays
areprovided in addition.
H @
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Figure 5: Hardware structure
-
13
Technical data
General data
DesignSurface mounting case suitable for wall installation
orflush mounting case for 19 cabinets and for controlpanels
Installation positionVertical 30
Degree of protectionPer DIN VDE 0470 and EN 60529 or IEC
60529.IP 52; IP 20 for the rear connection area of the
flushmounting case.
WeightCase 40T: max. 7 kgCase 84T: max. 11 kg
DimensionsSee dimensions
Terminal connection diagramsSee Location and connections
TerminalsPC interfaceDIN 41652 connector (X6), type D-Sub, 9
pin.
Communication interface Optical plastic fibres (X7 and X8):
F-SMA interface per DIN 47258 or IEC 60874-2 per plastic
fibresorBFOC-(ST) interface 2.5 per DIN 47254-1 or IEC 60874-10 per
glass fibreorLeads (X9, X10):Threaded terminal ends M2 for wire
cross sections up to 1.5mm2
IRIG-B interface (X11)BNC plug
Current measuring inputsThreaded terminals for pin terminal
connection:
Threaded terminal ends M5, self centering with wire protection
for conductor cross sections of 4mm2orThreaded terminals for ring
terminal connection:In preparation
Other inputs and outputsThreaded terminals for pin terminal
connection:
Threaded terminal ends M3, self centering withwire protection
for conductor cross sections of 0.2to 2.5mm2orThreaded terminals
for ring terminal connection:In preparation
Creepage distances and clearancesPer EN 61010-1 and IEC
60664-1Pollution degree 3 working voltage 250V overvoltage category
III, impulse test voltage 5kV
TestsType testTests according to EN 60255-6 or IEC 60255-6
EMCInterference suppressionPer EN 55022 or IEC CISPR 22, Class
A
1 MHz burst disturbance testPer EN 60255-22-1 or IEC 60255-22-1,
Class III Common mode test voltage: 2.5kVDifferential test voltage:
1.0kVTest duration: > 2s, Source impedance: 200
Immunity to electrostatic dischargePer EN 60255-22-2 or IEC
60255-22-2, Level 3 Contact discharge, single discharges: >
10Holding time: > 5s, Test voltage: 6kV Test generator: 50 to
100M, 150pF/330
Immunity to radiated electromagnetic energyPer EN 61000-4-3 and
ENV 50204, Level 3 Antenna distance to tested device:
> 1m on all sidesTest field strength, freq. band 80 to
1000MHz:
10V/mTest using AM: 1kHz /80%Single test at 900 MHz: AM
200Hz/100%
Electrical fast transient or burst requirementsPer IEC
60255-22-4Test severity level 4Rise time of one pulse: 5nsImpulse
duration (50% value): 50nsAmplitude: 4kV/2kV, resp.Burst duration:
15ms, Burst period: 300msBurst frequency: 2.5kHzSource impedance:
50
Surge immunity testPer EN 61000-4-5 or IEC 61000-4-5, Level
4Testing of power supply circuitsunsymmetrically/symmetrically
operated linesOpen circuit voltage front time/time to half
value:
1.2/50s, Short circuit current front time/time to half
value:
8/20s, Amplitude: 4/2kV, Pulse frequency: > 5/minSource
impedance: 12/42
Immunity to conducted disturbances inducedby radio frequency
fieldsPer EN 61000-4-6 or IEC 61000-4-6, Level 3Disturbing test
voltage: 10V
Power frequency magnetic field immunityPer EN 61000-4-8 or IEC
61000-4-8, Level 4Frequency: 50Hz, Test field strength: 30A/m
Alternating component (ripple) in dc auxiliaryenergizing
quantityPer IEC 60255-1112%
InsulationVoltage testPer IEC 60255-5 or EN 610102kV ac, 60sFor
the voltage test of the power supply inputs, directvoltage (2.8kV
dc) must be used. The PC interfacemust not be subjected to the
voltage test.
Impulse voltage withstand testPer IEC 60255-5Front time: 1.2s,
Time to half value: 50sPeak value: 5kV, Source impedance: 500
Mechanical robustnessVibration testPer EN 60255-21-1 or IEC
60255-21-1Test severity class 1Frequency range in operation:
10 to 60Hz, 0.035mm, 60 to 150Hz, 0.5gFrequency range during
transport:
10 to 150Hz, 1 g
Shock response and withstand test, bumptestPer EN 60255-21-2 or
IEC 60255-21-2Test severity class 1Acceleration: 5g/15g, Pulse
duration: 11ms
Seismic testPer EN 60255-21-3 or IEC 60255-21-3Test procedure A,
Class 1Frequency range:
5 to 8Hz, 3.5mm/1.5mm8 to 35Hz, 10/5m/s2,
3 x 1 cycle
Routine testTests per EN 60255-6 or IEC 60255-6
Voltage testPer IEC 60255-52.2kV ac, 1s For the voltage test of
the power supply inputs, directvoltage (2.8kV dc) must be used. The
PC interfacemust not be subjected to the voltage test.
Additional thermal test100% controlled thermal endurance test,
inputs loaded
Environmental conditionsAmbient temperature rangeRecommended
temperature range:
5C to +55C or +23F to +131FLimit temperature range:
25C to +70C or 13F to +158F
Ambient humidity range 75% relative humidity (annual mean), up
to 56 days at 95% relative humidity and 40C, condensation not
permissible
Solar radiationAvoid exposure of the front panel to direct
solarradiation.
RatingsMeasurement inputsNominal frequency fnom: 50 and 60Hz
(settable)Operating range: 0.95 to 1.05fnomOver/Underfrequency
protection: 40...70Hz
CurrentNominal current Inom: 1 and 5A (settable)Nominal
consumption per phase: < 0.1 VA at InomLoad rating:
continuous: 4 Inomfor 10s: 30 Inomfor 1s: 100 Inom
Nominal surge current: 250 InomVoltageNominal voltage Vnom: 50
to 130V ac (settable)Nominal consumption per phase:
< 0.3VA at Vnom = 130V acLoad rating: continuous 150V ac
Binary signal inputsNominal auxiliary voltage Vin,nom:
24 to 250V dcOperating range: 0.8 to 1.1Vin,nom
with a residual ripple of up to 12% of Vin,nomPower consumption
per input:
Vin = 19 to 110V dc: 0.5W 30%Vin > 110V dc: Vin x 5mA 30%
Output relaysRated voltage: 250V dc, 250V acContinuous current:
5AShort duration current: 30A for 0.5sMaking capacity: 1000W (VA)
at L/R = 40msBreaking capacity:
0.2A at 220V dc and L/R = 40ms4A at 230V ac and cos = 0.4
Analogue inputs and outputsDirect current inputInput current: 0
to 26mAValue range: 0.00 to 1.20 Idc,nom (Idc,nom = 20mA)Maximum
permissible continuous current: 50mAMaximum permissible input
voltage: 17VInput load: 100Open circuit monitoring: 0 to 10mA
(adjustable)Overload monitoring: > 24.8mAZero suppression: 0.000
to 0.200 Idc,nom (adjustable)
Resistance thermometer:Only PT 100 permitted, mapping curve per
IEC 60751Value range: 40 to +215C
(equivalent to 40 to +419F)3 wire configuration: max. 20 per
conductor.Open and short circuited input permitted.Open circuit
monitoring:
> +215C (or > +419F) and < 40C (or < 40F)
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14
Direct current outputOutput current: 0 to 20mAMaximum
permissible load: 500Maximum output voltage: 15V
Power supplyNominal auxiliary voltageVA,nom: 48 to 250V dc and
100 to 230V acor VA,nom: 24V dc (depends on ordering)
Operating rangefor direct voltage: 0.8 to 1.1 VA,nomwith a
residual ripple of up to 12% of VA,nomfor alternating voltage: 0.9
to 1.1 VA,nomNominal consumptionat VA = 220V dc/maximum number of
modules fitted:In case 40TE:
Initial position approx.: 13WActive position approx.: 29W
In case 84TE:Initial position approx.: 13WActive position
approx.: 37W
Start-up peak current< 3A, duration 0.25ms
Stored energy time 50ms for interruption of VA 220 dc
PC interfaceTransmission rate: 300 to 115,200 baud
(settable)
Communication interfaceProtocol can be switched between: IEC
60870-5-103, IEC 60870-5-101, MODBUS, DNP 3.0Transmission rate: 300
to 38400 baud (settable)
Wire leadsPer RS 485 or RS 422, 2kV isolation Distance to be
bridged:
peer-to-peer link: max. 1200mmulti-endpoint link: max. 100m
Plastic fibre connectionOptical wavelength: typ. 660 nmOptical
output: min. 7.5 dBmOptical sensitivity: min. 20 dBmOptical input:
max. 5 dBmDistance to be bridged: max. 45m1)
Glass fibre connection G 50/125Optical wavelength: typ. 820
nmOptical output: min. 19.8 dBmOptical sensitivity: min. 24
dBmOptical input: max. 10 dBmDistance to be bridged: max.
400m1)
Glass fibre connection G 62,5/125Optical wavelength: typ. 820
nmOptical output: min. 16 dBmOptical sensitivity: min. 24
dBmOptical input: max. 10 dBmDistance to be bridged: max.
1400m1)
IRIG-B interfaceFormat B122 Amplitude modulated, 1kHz carrier
signal BCD time of year code
1) Distance to be bridged for optical outputs and inputs that
areequal on both ends, taking into account a system reserve of3dB
and typical fibre attenuation.
Typical characteristic dataMain functionMinimum output pulse for
a trip command:
0.1 to 10s (settable)Output pulse for a close command:
0.1 to 10s (settable)
Distance protectionMinimum fault detection time: 12msFault
detector reset time 30ms 10ms Directional sensitivity:
up to 2s after fault detection: 2s after fault detection and for
switching on to fault: 200 mV 10%
Shortest tripping time: P433/P435: approx. 19msP437: approx.
16ms
Fault detection and measurement resetting ratio: 0.95
Overcurrent time protectionShortest tripping time: approx.
25msStarting reset time approx. 25ms Starting and measurement
resetting ratio: 0.95
Over/undervoltage protectionShortest tripping time: approx.
40msStarting reset time approx. 30ms Starting resetting ratio:
settable hyterisis 1...10%
Deviations of the operate valuesReference conditionsSinusoidal
signals with nominal frequency fnom, totalharmonic distortion 2%,
ambient temperature 20C and nominal auxiliary voltage
VA,nomDeviationDeviation relative to the set value under
referenceconditions
Distance protectionFault detector V, VNG>>: 3%Fault
detector I>, I>>, IN
Setting range 0.1 to 0.25 Inom: 5%Setting range > 0.25 Inom:
3%
Fault detector Z< at k = 0, 30, 60, 90: 5%Impedance
measurement Z<
Deviation at K = 0, 90: 3%Deviation at K = 30, 60: 5%
Directional determination: 3
Measuring circuit monitoring Operate values Ineg, Vneg: 3%
Back-up DTOC protectionOperate value I>: 3%
Overcurrent time protection Operate values I>, IN>: 5%
Over/undervoltage protection Operate values V: 3%
Over/underfrequency protection Operate values f: 3%
Directional power protection Operate values V: 3%
Ground fault direction determination Using steady state values
Operate values VNG>, IN.act, IN.reac, IN>: 3%Sector angle:
1
Thermal overload protectionOperate value : 5%
Deviations of the timer stagesReference conditionsSinusoidal
signals with nominal frequency fnom, total harmonic distortion 2%,
ambient temperature 20C and nominal auxiliary voltage
VA,nomDeviationDeviation relative to the setting under
referenceconditions
Definite time stages1% +20...40ms
Inverse time stages5% +10 to 25ms (measured variable greater
than 2 Iref)for IEC characteristic extremely inverse and for
thermaloverload protection:7.5% + 10 to 20ms
Deviations in measured dataacquisitionReference
conditionsSinusoidal signals with nominal frequency fnom,
totalharmonic distortion 2%, ambient temperature 20C and nominal
auxiliary voltage VA,nomDeviationDeviation relative to the relevant
nominal value underreference conditions
Operating dataCurrents/measuring inputs: 1%Voltages/measuring
input: 0.5%Currents/internally calculated: 2% Voltages/internally
calculated: 2%Active and reactive power: 2%Load angle: 1Frequency:
10mHz
Fault dataShort circuit current and voltage: 3%Short circuit
impedance and fault location: 5%
Internal clockWith free running internal clock: < 1
min./monthWith external synchronization
via protocol, synch. interval 1 min: < 10msvia IRIG-B signal
input: 1ms
Resolution in fault data acquisitionTime resolution20 sampled
values per period
Phase currentsDynamic range: 100 Inom or 25 Inom
(settable)Amplitude resolution
at Inom = 1A: 6.1mA rms. or 1.5mA rms.at Inom = 5A: 30,5mA rms.
or 7.6mA rms.
Residual currentsDynamic range: 16 IE,nomAmplitude
resolution
at Inom = 1A: 0.89mA rms.at Inom = 5A: 4.9mA rms.
VoltagesDynamic range: 150VAmplitude resolution: 9,2 mV rms
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15
Address list
Function parameters
Global functionsPC link (PC):Command blocking:
No/YesSig./meas.val.block.: No/Yes
Communication link (COMM1):Command block. USER:
No/YesSig./meas.block.USER: No/Yes
Binary and analogue output (OUTP):Outp.rel.block USER:
No/Yes
Main function (MAIN):Device on-line: No (= off) /Yes (= on)Time
switching: Standard time/Daylight saving timeTest mode USER:
No/YesNominal frequ. fnom: 50Hz/60HzRotary field: Clockwise
rotation/Anti-clockwise rot.Inom CT prim.: 1..10000AIN,nom CT
prim.: 1....10000AVnom VT prim.: 0.1....1000.0kVVNG,nom V.T. prim.:
0.1....1000.0kVInom device: 1.0A/5.0AIN,nom device: 1.0A/5.0AVnom
VT sec.: 50...130VVNG,nom VT sec.: 50...130VDynamic range I:
Highest range/Sensitive rangeConn. meas. circ. IP:
Standard/OppositeConn. meas. circ. IN: Standard/OppositeMeas. value
rel. IP: 0.000...0.200 InomMeas. value rel. IN: 0.000...0.200
IEnomMeas. value rel. V: 0.000...0.200VnomMeas. val. rel. VNG:
0.000...0.200 Vne,nomSettl. t. IP,max,del: 0.1... 15.0...60.0
minFct.assign. block. 1: see selection tableFct.assign. block. 2:
see selection tableTrip cmd.block. USER: No/YesFct.assig.trip
cmd.1: see selection tableFct.assig.trip cmd.2: see selection
tableMin.dur. trip cmd. 1: 0.10...10.00sMin.dur. trip cmd. 2:
0.10...10.00sClose cmd.pulse time: 0.10...10.00sRC inh.by CB cl.:
No/YesFct. assign. fault: see selection table
Parameter subset selection (PSS):Control via USER:
No/YesParam.subs.sel. USER:
Parameter subset 1Parameter subset 2Parameter subset 3Parameter
subset 4
Keep time: 0.000...65.000s /Blocked
Selfmonitoring (SFMON):Fct. assign. warning: see selection
table
Fault recording (FT_RC):Fct. assig. trigger: see selection
tablePre fault time: 1...50 periodsPost fault time: 1...50
periodsMax. recording time: 5...750 periods
Main functionsMain function (MAIN):Neutral point treat.:
Low imped. groundingIsol./res.w.start.PGIsol./res.w/o st.
PGShort durat. ground.
Phase priority 2pG: Phase-to-phase loopPhase-to-ground loopC
before A acyclicA bef. B bef. C cyclA before C acyclicC bef. B bef.
A cyclB before A acyclicA before B acyclicC before B acyclicB
before C acyclic
Transfer for 1p: Ground/P or G =f(Imed,Imax)Op. mode rush
restr.:
WithoutNot phase selectivePhase selective
I> lift rush restr.: 5.0...20.0 Inom/BlockedRush
I(2*fn)/I(fn): 10...35%/Blocked
Distance protection (DIST):Enabled USER: No/YesCVT
stabilization: No/Yes(P437 only): Zone extens. For 1pG: No/Yes
Power swing blocking (PSB): (P435/P437 only)Enabled USER:
No/YesThreshold value: 1...50%Operate delay: 0.06...1.00sRelease
delay: 0.06...1.00s
Measuring circuit monitoring (MCMON): Enabled USER:
No/YesCurrent monitoring: No/YesIneg>: 0.10...1.00 ImaxOp. mode
volt. mon.:
VnegVneg with curr. enabVneg w.CB cont.enab.
Operate delay: 0.00...10.00sFF, V enabled USER: No/YesVpos, FF:
0.01VnomVneg, FF: 0.01...0.50 InomOperate delay FF, V:
0.00...10.00s
(P435/P437 only):FF,Vref enabled USER No/Yes Oper. delay FF,
Vref: 0.00...10.00s
Back-up overcurrent protection (BUOC): Enabled USER:
No/YesOperating mode:
Without ARCWith ARC, 3p HSRWith ARC, 1/3p HSR (P435/P437
only)
Switch-on-to-fault protection (SOTF):Enabled USER:
No/YesOperating mode:
Trip with starting/Trip with overreachManual close timer:
0.00...10.00s
Protective signaling (PSIG):Enabled USER: No/Yes
Autoreclosing control (ARC):Enabled USER: No/Yes
Automatic synchonism check (ASC):Enabled USER: No/Yes
Ground fault (short circuit) protect. (GFSC): (P435/P437
only)Enabled USER: No/YesIN>: 0.002...0.500 InomVNG>:
0.015...0.500VnomAngle phiG: 0...90Start. oper. delay:
0.00...10.00sStart. releas. delay: 0.00...10.00st1 (forward):
0.00...60.00s/Blocked
t2 (backward): 0.00...60.00s/Blockedt3 (non-directional):
0.00...60.00s/BlockedCriteria tS active:
Blocked/forward/non-directionalOperating mode tS: VNG
dependent/IN dependentIref,N: 0.01...0.80
Inom/BlockedCharacteristic N:
Definite TimeIEC Standard InverseIEC Very InverseIEC Extr.
InverseIEC Long Time Inv.IEEE Moderately Inv.IEEE Very InverseIEEE
Extremely Inv.ANSI Normally Inv.ANSI Short Time Inv.ANSI Long Time
Inv.RI Type InverseRXIDG Type Inverse
Factor kt,N: 0.05...10.00
Ground fault (short circuit) protectionsignaling (GSCSG):
(P435/P437 only)Enabled USER: No/YesOperating mode:
Signal comp. release/Signal comp. block.Channel mode:
Independent channel/Common channelTrip mode:
1/3p pole trip w.HSR3p pole trip w.HSR3p pole trip w/o.HSR
Tripping time: 0.00...10.00s/BlockedRelease time send:
0.00...10.00stBlock: 0.00...10.00sBlock. sig. nondir.: No/YesEcho
on receive: No/YesOperate delay echo: 0.00...10.00s/BlockedPulse
duration echo: 0.00...10.00stBlock echo: 0.00...10.00sWeak infeed
trip:
No/With directional r./With VNG> releaseOp.delay weak infeed:
0.00...10.00s/BlockedFrequency monitoring: No/Yes
Definite time overcurrent protection (DTOC): Enabled USER:
No/Yes
Inverse time overcurrent protection (IDMT):Enabled USER:
No/Yes
Thermal overload protection (THERM):Enabled USER: No/YesIref:
0.10...4.00 InomFactor kP: 1.05...1.50 Time const. 1 (>Ibl):
1...1000 minTime const. 2(
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16
Ground fault direction determination usingsteady state values
(GFDSS):(P433/P435 only)Enabled USER: No/YesOperating mode:
Steady state power/Steady state currentOper. mode GF (pow.):
cos phi circuit/sin phi circuitEvaluation VNG:
Calculated/MeasuredMeasuring direction: Standard/OppositeVNG>:
0.02...1.00Vnom(/3)tVNG>: 0.02...10.00sf/fnom (pow.meas.):
1/5f/fnom (curr.meas.): 1/5IN,act>/IN,reac> LS: 0.003...1.000
IN,nomSector angle LS: 80...89Operate delay LS:
0.00...100.00s/BlockedRelease delay LS:
0.00...10.00sIN,act>/IN,reac> BS: 0.003...1.000 IN,nomSector
angle BS: 80...89Operate delay BS: 0.00...100.00s/BlockedRelease
delay BS: 0.00...10.00sIN>: 0.003...1.000 IN,nomOperate delay
IN: 0.00...100.00s/BlockedRelease delay IN: 0.00...10.00s
Ground fault tripping (GFTRP): (P433/P435 only)Enabled USER:
No/Yes
Ground fault protection signaling (GFSIG): (P433/P435
only)Enabled USER: No/YesOperate delay: 0.00...10.00sSend reset
time: 0.00...10.00sdc loop op. mode:
Transm.relay break c/Transm.relay make co
Transient ground fault directiondetermination (TGFD):(P433/P435
only)Enabled USER: No/YesEvaluation VNG: Sum (VA-B-C-G)
/MeasuredMeasurem. direction: Standard/OppositeVNG>:
0.15...0.50Vnom(/3)Operate delay: 0.05...1.60sIN,p>: 0.10...0.50
InomBuffer time: 0...1200s/Blocked
Limit value monitoring (LIMIT):Enabled USER:
No/YesI>:/I>>:/I:/tI:/U:/tU:/U:/tU: 0.010...1.000
Unom/BlockedtU>: /tU>>: 1...1000s/Blocked
with I = ldcIin:I>:/I>>:/I:/tI:/T:/tT (Ibl) high r.
PSx: 0.10...1.00 InomI> (Ibl) sens. r.PSx: 0.05...1.00
InomOperat. mode V< PSx:
W/o V< startingWith V< start. PGWith V< start.PG,PP
V< PSx: 0.10...0.90Vnom(/3)Operat. mode Z< PSx:
W/o Z< startingWith Z< starting P-GWith Z<
start.PG,PP
Xfw PSx:/Rfw,PG PSx:/Rfw,PP PSx:/Zfw,PG PSx:/Zfw,PP PSx:
0.1...300.0 at Inom = 1.0A0.02...60.00 at Inom = 5.0A
Zbw/Zfw PSx: 0.10...4.00 Z evaluation PSx:
ZPG=VPG/(IP + kG*IN) /ZPG=VPG/2*IPIN> high range PSx:
0.10...2.00 InomIN> sens. range PSx: 0.05...2.00 InomtIN>
PSx: 0.000...0.500sVNG> PSx: 0.02...1.00VnomVNG>> PSx:
0.20...1.00VnomtVNG>> PSx: 0.000...60.000sCharacteristic PSx:
Circle/Polygonvalid for y = 1 to 6:
Xy (polygon) PSx: Ry,PG (polygon) PSx: Ry,PP (polygon) PSx:
0.10...200.00 at Inom = 1.0A0.02...40.00 at Inom = 5.0A
y (polygon) PSx: 40...90y (polygon) PSx: 20...20Zy (circle)
PSx:
0.05...200.00 at Inom = 1.0A0.01...40.00 at Inom = 5.0A
y (circle) PSx: 10...90Arc comp. circle PSx: No/Yesvalid for y =
1 to 7:
Direction Ny PSx: Forward /Backward/Non-directional
Oper.val.Vmemory PSx: 0.01...1.00Vnomvalid for y = 1 to 8:
ty PSx: 0.00...10.00s/Blockedkze,PG HSR PSx: 1.00... 450.00
kze,PP HSR PSx: 1.00...450.00 kze,PG TDR PSx: 1.00...450.00 kze,PP
TDR PSx: 1.00...450.00 t1,ze PSx: 0.00...10.00s/BlockedAbs. value
kG PSx: 0.00...8.00 Angle kG PSx: 180...180
(P435/P437 only): Op. mode zone 4 PSx:
Normal1p:Z1/t1(3p)3p:Z1/t4Section cable - lineSection line -
cableComp.bundle cond.eff1p:Z1/t1, 3p:Z1/t4
(P435/P437 only):Trip zone 1 PG PSx: 1 pole/3 pole Trip zone 1
PP PSx:
1 pole leading phase1 pole trailing phase3 pole
(P437 only):Meas. start. 1pG PSx: PG loops/noneMeas. start. 2pG
PSx: PG loops/PP loopMeas. start. 3pG PSx: PG loops/PP loops
Backup overcurrent protection (BUOC): I> PSx: 0.50...8.00
InomtI> PSx: 0.00...10.00s/BlockedIN> PSx: 0.10...2.00
InomtIN> PSx: 0.00...10.00s/Blocked
Protective signaling (PSIG):Enable PSx: No/YesOperating mode
PSx:
WithoutDir.trans.trip.underPUTTZone extensionRelease
schemeBlocking schemeDC loop operat. modeReverse
interlockingDirection comparison
Tripping time PSx: 0.00...10.00s/BlockedRelease t. send PSx:
0.00...10.00sDC loop op. mode PSx:
Transm.relay break c/Transm.relay make coEcho on receive
PSx:
WithoutOn receiveOn receive & V RRC PSx:
0.40...0.90Vnom(/3)Reclaim time PSx: 1.00...600.00sBlock. time int.
PSx: 1...600sBlock. time ext. PSx: 0...600sZone ext.dur. RC
PSx:
Without/Following HSR/AlwaysParallel trip PSx:
Without functionParall. bloc.w/o initParall. bloc.w. init
(P435/P437 only):Operative time 2 PSx: 0.00...10.00sHSR oper.
mode PSx:
1 pole / 1/3 pole / 3 poleTrip time HSR PSx:
0.00...10.00s/BlockedDead time 1p PSx: 0.10...600.00sDead time max
PSx: 0.10...600.00s
(P437 only):Operating mode 2 PSx:
Trip dependent/Start dependentTDiscrim PSx: 0.10...600.00s
Automatic synchonism check (ASC):(P435/P437 only):Enable PSx:
No/YesActive for HSR PSx: No/YesActive for TDR PSx: No/YesActive
for RRC PSx: No/YesClos.rej.w.block PSx: No/YesOperative time PSx:
0.00...60.00sOperating mode PSx:
Voltage checked
-
17
Sync. checkedVolt./sync. checked
Op.mode volt.chk.PSx: Vref but not VV but not VrefNot V and not
VrefNot V or not VrefVref & Z1 but not V
V> volt.check PSx: 0.10...0.80Vnom(/3)V< volt. check PSx:
0.10Vnom(/3)tmin volt. check PSx: 0.00...10.00sMeasurement loop
PSx:
Loop A-G/B-G/C-G/A-B/B-C/C-AV> sync. check PSx:
0.40...1.20Vnom(/3)Delta Vmax PSx: 0.02...0.40VnomDelta fmax PSx:
0.01...1.00HzDelta phi max PSx: 5...100Phi offset PSx:
180...180tmin sync. check PSx: 0.00...10.00s
Ground fault (short circuit) protect. (GFSC): (P435/P437
only)Enable PSx: No/Yes
Ground fault (short circuit) protectionsignaling (GSCSG):
(P435/P437 only)Enable PSx: No/Yes
Definite time overcurrent protection (DTOC):Enable PSx:
No/Yesvalid for y = > to >>>>:
I y PSx: 0.10...20.00 InomtI y PSx: 0.00...30.00s/BlockedIneg y
PSx: 0.10...20.00 InomtIneg y: 0.00...30.00s/BlockedIN y:
0.10...20.00 InomtIN y: 0.00...30.00s/Blocked
Inverse time overcurrent protection (IDMT):Enable PSx:
No/Yesvalid for y = P or neg or N:
Iref,y PSx: 0.01...4.00 Inom/BlockedCharacteristic y PSx:
Definite TimeIEC Standard InverseIEC Very InverseIEC Extr.
InverseIEC Long Time Inv.IEEE Moderately Inv.IEEE Very InverseIEEE
Extremely Inv.ANSI Normally Inv.ANSI Short Time Inv.ANSI Long Time
Inv.RI-Type InverseRXIDG-Type Inverse
Factor kt,y PSx: 0.05...10.00 Reset y PSx:
Without delay/Delayed as per char.Direction y PSx:
Forward directionalBackward directionalNon-directional
Direct. meas. y PSx: Neq.sequ. Vneg, Ineg/Distance Zone4
Op. w/o volt. PSx: Non-directional/Blocked
Over/undervoltage protection (V):Enable PSx: No/YesOperating
mode PSx: Delta/StarEvaluation VNG PSx: Calculated/MeasuredV>
PSx: 0.20...1.50Vnom(/3)/BlockedV>> PSx:
0.20...1.50Vnom(/3)/BlockedtV> PSx: 0.00...100.00s/BlockedtV>
3 pole PSx: 0.00...100.00s/BlockedtV>> PSx:
0.00...100.00s/BlockedV< PSx: 0.20...1.50Vnom(/3)/BlockedV>
PSx: 0.20...1.50Vnom/3/BlockedtVpos> PSx:
0.00...100.00s/BlockedtVpos>> PSx: 0.00...100.00s/Blocked
Vpos< PSx: 0.20...1.50Vnom/3/BlockedVpos> PSx:
0.20...1.50Vnom/3/BlockedtVneg> PSx:
0.00...100.00s/BlockedtVneg>> PSx:
0.00...100.00s/BlockedVNG> PSx:
0.02...1.00Vnom(/3)/BlockedVNG>> PSx:
0.02...1.00Vnom(/3)/BlockedtVNG> PSx:
0.00...100.00s/BlockedtVNG>> PSx:
0.00...100.00s/BlockedtTransient PSx: 0.00...100.00s/BlockedHyst. V
meas. PSx: 1...10%Hyst. V deduc. PSx: 1...10%
Over/underfrequency protection (f):Enable PSx: No/Yesvalid for y
= 1 ... 4
Oper. mode fy PSx:f f with df/dtf w. Delta f/Delta t
fy PSx: 40.00...70.00Hz/Blockedtfy PSx:
0.00...10.00s/Blockeddfy/dt PSx: 0.1...10.0Hz/s/BlockedDelta fy
PSx: 0.01...5.00Hz/BlockedDelta ty PSx: 0.04...3.00s
Directional power protection (P):(P433/P435 only)Enabled PSx:
No/Yesvalid for y = > or >> or
-
18
Dimensions
7>3?:J
733?:J
74>?:J
97;?>
9>9?8
98=?9
9:3?7
97;?>9:;?8
993?5
733?:
:?=747?;
7:5
784
7::?>9=;
Figure 6: Dimensional drawings for case 40TE
Surface mounted case 40TE
Flush mounted case 40TE with panel cutout
-
19
:?=
>7=?=
7:5
784
9:3?7
7>3?:J
733?:J
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9:5?=
94>?5
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9:;?8
993?5
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Figure 7: Dimensional drawings for case 84TE
Surface mounted case 84TE
Flush mounted case 84TE with panel cutout
-
20
Location and connections
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Figure 8: Location diagrams
-
21
.
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Figure 10: Connection example P433 (application in MV system
with isolated/compensated neutral)
Figure 11: Connection example P437 (application in HV system
with double circuit line)
Note: When using P1 - P2 and S1 - S2 identifications for the
terminal polarity of CTs, the dot shown identifies the P1 and
S1terminals
-
23
Ordering information
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-
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Route de Sartrouville, BP58, 78230 Le Pecq Cedex, FranceTel: +33
(0) 134 80 79 00 Fax: +33 (0) 134 80 79 13 Email:
[email protected] Internet: www.tde.alstom.com
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thereof are trademarks and service marks of ALSTOM.MiCOM is a
registered trademark of ALSTOM. Other names mentioned, registered
or not, are the property of their respective companies.
Our policy is one of continuous development. Accordingly the
design of our products may change at any time. Whilst every effort
is made to produce up to date literature, this brochure shouldonly
be regarded as a guide and is intended for information purposes
only. Its contents do not constitute an offer for sale or advice on
the application of any product referred to in it.
We cannot be held responsible for any reliance on any decisions
taken on its contents without specific advice. P43
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ectro
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ours
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