AEG PS431
March 29, 2017 | Author: XiaUrRehman | Category: N/A
Short Description
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Description
PS 431 Time-Overcurrent Protection Device
T&D
Numerical Time-Overcurrent Protection with Definite -Time and Inverse -Time Characteristics PS 431 time-overcurrent protection devices are used for selective short-circuit protection in high-voltage networks. The networks can be operated with impedance neutral grounding, with resonant grounding or with an isolated neutral.
1 PS 431 in case for wall surface or panel flush mounting
The PS 431 time-overcurrent protection device has the following features: ❑ Four-pole measurement (A, B, C, N) ❑ Phase-selective phase current timer stage with DTOC and IDMT characteristics (IDMT can be set to normally inverse, very inverse, extremely inverse, long time ground fault or RI inverse) ❑ Time-lag high set phase current timer stage ❑ Residual current timer stage with DTOC and IDMT characteristics (IDMT can be set to normally inverse, very inverse, extremely inverse, long time ground fault or RI inverse) ❑ Time-lag high set residual current timer stage ❑ Tripping matrix ❑ Optional latching of the individual tripping criteria ❑ Possibility of reverse interlocking ❑ Circuit-breaker failure protection The protection functions listed above are complemented by comprehensive selfmonitoring and fault diagnosis. In addition, the PS 431 is equipped with the following supplementary functions: ❑ Measuring circuit monitoring ❑ Operating data measurement ❑ Event counting ❑ Fault data acquisition ❑ Fault logging
The PS 431 is constructed with a multifunctional case design that is equally well suited to wall surface mounting or panel flush mounting due to the reversible terminal blocks and reversible mounting brackets. The auxiliary voltage for the power supply can be separately switched internally from 110-250 V DC to 24-60 V DC. The binary signal inputs may be operated with control voltages of 24-250 V DC. Current measurement inputs having a frequency range of 45-65 Hz, input transducers with 1 A and 5 A taps, and the surface-mounting design provide for optimum use and versatility without variance. The PS 431 has the following inputs and outputs: ❑ 4 current measurement inputs ❑ 2 binary signal inputs (optical couplers) with freely configurable function assignment ❑ 4 output relays with freely configurable function assignment Control and display: ❑ Local control panel ❑ 8 LED indicators, including 6 with freely configurable function assignment ❑ PC interface Parameters may be set either from the local control panel or through the PC interface, as desired.
PS 431 Time-Overcurrent Protection Device
Functions
Definite or Inverse Time-Delay Short-Circuit Protection The PS 431 time-overcurrent protection device is generally equipped with four current measurement inputs A, B, C and N. DTOC Mode In DTOC mode (Definite Time Overcurrent), PS 431 has the following overcurrent timer stages: ❑ Phase-selective phase current timer stage I>/tI> ❑ Residual current timer stage IN>/tIN> ❑ High set phase current timer stage I>>/tI>> ❑ High set residual current timer stage IN>>/tIN>> The effect of the timer stages measuring in the ground path on the general starting signal and therefore on the start of a fault record can be suppressed, if desired. Formation of the general trip command by the residual current timer stages is then automatically disabled.
IDMT Mode
Tripping Matrix and Latch
Reverse Interlocking
In the IDMT (inverse definite minimum time) mode the phase current timer stage tI> and/or the residual current timer stage tIN> are delayed by an inverse time lag. The other stages and functions correspond to the DTOC mode.
The tripping matrix is used to decide which of the individual overcurrent timer stages shall participate in forming the general trip command. The phase-selective phase current timer stage is permanently assigned to the general trip command; this cannot be changed. Another matrix is used to determine which of the individual tripping criteria shall result in latching of the general trip command.
The individual overcurrent timer stages can be blocked externally by way of two independent signals. In this connection it is possible by using the selection matrix to determine which of the timer stages shall be included in the blocking. This makes it possible to add on a feature such as reverse interlocking, for example (”busbar protection with starting the corresponding scan”).
For inverse-time delay the following tripping time characteristics can be selected: ❑ Normally inverse ❑ Very inverse ❑ Extremely inverse ❑ Long time ground fault ❑ RI inverse The mode, base current, characteristic type and characteristic factor can be set independently for the phase current timer stage and the residual current timer stage.
All threshold operate values and lag times can be set independently. 2 Inverse-time characteristics Normally inverse 0.14 s t = characteristic · ––––––––––– (I /Iref)0.02 – 1 factor Very inverse t = characteristic factor
13.5 · ––––––––––– s (I /I ref) – 1
Extremely inverse t = characteristic factor
80 s · ––––––––––– (I /Iref)2 – 1
Long time ground fault t = characteristic factor
120 · ––––––––––– s (I /I ref) – 1
RI inverse t = characteristic factor
2
1 · ––––––––––– s 0.236 0.339 – ––––– (I /Iref)
The function of circuit breaker failure protection is also considered in the tripping matrix and in the matrix for setting the latching function.
PS 431 Time-Overcurrent Protection Device
Functions (continued)
Cir cuit Br eaker Failur e Circuit Breaker Failure Pr otection Protection
Measuring Cir cuit Circuit Monitoring
When the trip command is issued a timer stage for monitoring the circuit breaker is also started. When this timer stage has elapsed due to a sustained general starting condition, then the circuit breaker failure signal is issued.
Measuring circuit monitoring of the phase currents is based on the principle of maximum allowable magnitude unbalance. In this case the arithmetic difference between the maximum and minimum phase currents as referred to the maximum phase current is compared with the set threshold operate value. With the appropriate settings it is also possible to monitor the phase currents even with an economy-type CT connection (CTs in only two phases).
The input of a circuit breaker failure signal through an appropriately configured binary input brings about a non-delayed trip command if the general starting signal is present.
Operating Data Measur ement Measurement The PS 431 time-overcurrent protection device acquires the following measured operating data and updates them at approximately 1 s intervals, as long as a fault is not being processed at the time: ❑ Maximum value of the three phase currents ❑ Phase currents ❑ Residual current
Event Counting
Self-Monitoring
The following events are counted by the PS 431 timeovercurrent protection device: ❑ Tripping on faults ❑ Faults ❑ Warning entries
Extensive monitoring routines in the PS 431 ensure that internal hardware or software faults will not lead to malfunctioning of the protective relaying system. When the auxiliary voltage VA is turned on, a function test is carried out. Cyclic self-monitoring tests are run during operation. If test results deviate from the default value, a fault signal is issued. The result of fault diagnosis determines whether a protective blocking will occur or whether only a warning will be issued. The faults diagnosed in conjunction with self-monitoring are stored in a memory (monitoring signal memory). The contents of the monitoring signal memory can be read from the local control panel.
Fault Data Acquisition After the end of a general starting condition, the following measured fault data are acquired: ❑ Running time ❑ Short-circuit current Fault Logging Protection signals at the time of a fault are stored in chronological order. A total of five faults with a maximum of 64 start/end signals each, can be held in a circular memory - the signal memory. If more than five faults occur and no faults have been erased in the interim, the oldest fault record will be overwritten. A four-digit resettable counter identifies the individual faults by serial number. The fault records can be read from the local control panel.
The measured data are displayed as r.m.s. values and are normalized to the corresponding nominal value of the protection device.
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PS 431 Time-Overcurrent Protection Device
Design
Mechanical Design
Local Contr ol Panel Control
The PS 431 consists of an aluminum case with reversible connector blocks and adjustable side brackets. The case can be used for wall surface mounting or for panel flush mounting, as desired. In either case the unit is connected by threaded terminal ends.
The integrated local control panel comprises two 4-digit, 7-segment LCD displays and six function keys. The settings, signals and measured variables are numerically coded. This code is called the address and is displayed in the lower 4-digit 7-segment display. Access barriers safeguard against accidental or unauthorized changing of settings.
The processor module carrying the local control panel is mounted directly on the rear of the removable front panel. It is connected to the combined I/O (input/output) module by a flat connecting cable. The I/O module contains the voltage supply, the input transformers, the output relays, and the optical couplers for the binary inputs. In the front panel are windows for the display and label strips located behind them. The keyboard for the integrated local control panel is also located in the front panel.
Eight LED indicators are provided for visual signaling. The first two have permanent signal assignments, while the other six can be configured as desired (see Page 9). The control panel has two label strips. The strip on the left is used to label the LED indicators, and the strip on the right provides a visual record of frequently performed control steps. Both strips can be replaced and labeled by the user as desired.
Figure 4 on Page 10 shows the case and mounting dimensions.
3 Local control panel
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PS 431 Time-Overcurrent Protection Device
Technical Data
Notices
General Data
Type Tests
Type Tests (continued)
Manufacturer’s Conformity Statement The product designated as ”PS 431 Time-Overcurrent Protection Device” has been developed and manufactured in conformity with the international standard series EN 60255-6 and in accordance with the provisions of the Low Voltage Directive issued by the European Community.
Design Case suitable for wall surface mounting or panel flush mounting.
All tests according to EN 60255-6 and DIN 57435 Teil 303
Insulation
Membership in ALPHA AEG and the company that manufactures our measurement and protective relays, Hartmann & Braun, are members of the low-voltage equipment testing and certification association called ALPHA (Frankfurt am Main, Germany). ALPHA promotes independent responsibility on the part of the manufacturer and the assurance of high product quality through basic process specifications for equipment inspection and testing in compliance with applicable standards. When certain conditions are met, ALPHA also issues officially recognized product certificates if required. Furthermore, ALPHA is working toward international recognition of conformity declarations and certificates. DQS Certificate The internationally recognized, independent and impartial association for the certification of quality assurance systems, DQS (Deutsche Gesellschaft zur Zertifizierung von Qualitätssicherungssystemen), has awarded AEG the DQS certificate, thereby certifying that AEG has introduced and uses a state-of-the-art quality assurance system that complies with all requirements stated in EN ISO 9001 that apply to its products and services.
Installation Position Vertical ± 30° Degree of Protection IP 51 according to DIN VDE 0470 and EN 60259 or IEC 529 Weight 3.4 kg Dimensions See Page 10 Terminal Connection Diagram See Page 10 PC Interface DIN 41652 connector, type Submin-D, 9-pin. A special connecting cable is required for electrical isolation. Terminals Threaded terminal ends M4, self-centering with wire protection for conductor cross-sections of 0.5 to 6 mm2 or 2 x 2.5 mm2 Creepage Distances and Clearances Per IEC 255-5, series C
Electromagnetic Compatibility (EMC) Interference suppression According to EN 55022 and DIN VDE 0878 Part 3, class B 1 MHz burst disturbance test According to IEC 255 Part 22-1, class III Common mode test voltage: 2.5 kV Differential test voltage: 1.0 kV Test duration: > 2 s Source impedance: 200 Ω Immunity to electrostatic discharge According to EN 60801 Part 2, severity level 3 Contact discharge, Single discharges: > 10 Holding time: > 5 s Test voltage: 6 kV Test generator: 50 to 100 MW, 150 pF/330 Ω Immunity to radiated electromagnetic energy According to ENV 50140, level 3 Antenna distance to tested device: > 1 m on all sides Test field strength, frequ. band 80 to 1000 MHz: 10 V/m Test using AM: 1 kHz / 80 % Single test at 900 MHz: AM 200 Hz /100 % Electrical fast transient / burst requirements According to IEC 801-4, test severity level 3 Rise time of one pulse: 5 ns Impulse duration (50% value): 50 ns Amplitude: 2 kV / 1 kV Burst duration: 15 ms Burst period: 300 ms Source impedance: 50 Ω Surge immunity test According to IEC 1000-4-5, test level 3 Testing of power supply circuits, unsymmetrically / symmetrically operated lines Open-circuit voltage front time / time to half-value: 1.2 / 50 ms Short-circuit current front time / time to half-value: 8 / 20 ms Amplitude: 1 / 2 kV Pulse frequency: > 5 / min Source impedance: 12 / 42 Ω Immunity to conducted disturbances induced by radio frequency fields According to IEC 65A/ 77B (Sec) 145/110, test level 2 Disturbing test voltage: 3 V
Voltage test According to IEC 255-5 2 kV AC, 60 s For the voltage test of the power supply inputs, direct voltage (2.8 kV DC) must be used. The PC interface must not be subjected to the voltage test. Impulse voltage withstand test According to IEC 255-5 Front time: 1.2 µs Time to half-value: 50 µs Peak value: 5 kV Source impedance: 500 Ω Mechanical Robustness Vibration test According to IEC 255-21-1, test severity class 1 Frequency range, in operation: 10 to 60 Hz, 0.035 mm, 60 to 150 Hz, 0.5 g Frequency range, during transport: 10 to 150 Hz, 1 g Shock response and withstand test, bump test According to IEC 255-21-2, test severity class 1 Acceleration: 5 g/15 g Pulse duration: 11 ms Seismic test According to EN 60255-21-3, test procedure A, class 1 5 to 8 Hz, 3.5/1.5 mm, 8 to 35 Hz, 10/5 m/s2 3 × 1 cycle
Routine Tests All tests according to EN 60255-6 and DIN 57 435 Part 303 Additional thermal test 100 % controlled thermal endurance test, inputs loaded
Environmental Conditions Allowable ambient temperatures Operating temp.: – 5 °C to + 55 °C Storage temp.: – 25 °C to + 55 °C Shipping temp.: – 25 °C to + 70 °C Ambient humidity range Relative humidity to preclude any condensation; 45 to 75 % (annual mean)
Power frequency magnetic field immunity According to EN 61000-4-8, level 4 Frequency: 50 Hz Test field strength: 30 A/m Alternating component (ripple) in d.c. auxiliary energizing quantity of measuring relays According to IEC 255-11 12%
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PS 431 Time-Overcurrent Protection Device
Technical Data (continued)
Inputs and Outputs
Information Output
Settings
Measurement Inputs
Operating Data Measurement
Global Function Parameters
Current Nominal current I nom: 1 and 5 A (terminal choice)
Max. phase current I P,max: 0.00-18.00 I nom
Increments 0.01
Phase currents I A: 0.00-18.00 Inom 0.00-18.00 Inom I B: 0.00-18.00 I nom I C:
General Starting without I N> or IN>> with IN> or IN>>
0.01 0.01 0.01
Residual current I N: 0.00-3.50 Inom
0.01
Nominal consumption per phase: < 0.3 VA at Inom Load rating: continuous: 4 Inom for 10 s: 30 Inom for 1 s: 100 Inom Frequency Nominal frequency f nom: 50 or 60 Hz Operating range: 45 to 65 Hz Binary Signal Inputs Equipment: 2 optical coupler inputs (freely configurable) Function assignment: see Page 9 Nominal V In,nom : 24-250 V DC Operating range: 0.8-1.1 VIn,nom with a residual ripple of up to 12% of V In,nom Power consumption per input: 35 mA ± 30% at V In, nom = 24 V DC 15 mA ± 30% at V In,nom = 48 V DC 4 mA ± 30% at VIn,nom = 60-250 V DC Output Relays Equipment: 4 output relays (freely configurable)
Event Counting Number of trip commands: 0 to 9999 Number of faults: 0 to 9999
– Fault Data Acquisition Increments Running time: 0.00-99.99 s Short-circuit current: 0.00-36.00 I nom
0.01 0.01
Fault Logging Up to 5 faults are stored, then the oldest fault is erased. Up to 64 signals per fault can be stored, subsequent signals trigger the overflow indication.
Trip Command 1/2 tI> tI> CBF tIN> tI> tI> tIN> CBF tI> tI>> tI> tI>> CBF tI> tI>> tIN> tI> tI>> tIN> CBF Latching 1/2 without latching CBF tIN> tIN> CBF tI>> tI>> CBF tI>> tIN> tI>> tIN> CBF tI> tI> CBF tIN> tI> tI> tIN> CBF tI> tI>> tI> tI>> CBF tI> tI>> tIN> tI> tI>> tIN> CBF Trip Command 2/2 without tIN>> with tIN>> Latching 2/2 without latching at tIN>> with latching at tIN>> Blocking E1 without block
Function assignment: see Page 9
tIN>> tIN> tIN> tIN>>
Contact rating
tI>> tI>> tIN>> tI>> tIN> tI>> tIN> tIN>>
Rated voltage: 300 V DC, 250 V AC Continuous current: 5 A Short-time current: 30 A for 0.5 s Making capacity: 1000 W (VA) at L/R = 40 ms Breaking capacity: 0.2 A at 220 V DC and L/R = 40 ms 4 A at 230 V AC and cos ϕ = 0.4 Local Control Panel Input or output of protection data: via six keys and two 4-digit displays State and fault signals: 8 LED indicators (2 permanently assigned, 6 freely configurable) Function assignment: see Page 9 PC Interface Transmission speed: 4800 baud A special PC connecting cable is required for connecting to a PC (see Page 12).
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tI> tI> tI> tI> tI> tI> tI> tI>
tIN>> tIN> tIN> tIN>> tI>> tI>> tIN>> tI>> tIN> tI>> tIN> tIN>>
Blocking E2 See selection for blocking E1 Mode for Current Timer Stages Definite-time-lag (DTOC) Inverse-time-lag (IDMT)
Definite-Time Overcurrent Protection (DTOC) Phase Current Threshold operate value I>: Increments: 0.4-4.0 Inom 0.1 Delay time tI>: 0.00-9.99 s 10.0-99.9/∞ s
Increments: 0.01 0.1
Threshold operate value I>>: Increments: 0.1 0.4-40.0/∞ Inom Delay time tI>>: 0.00-9.99 s
Increments: 0.01
Residual Current Threshold operate value IN>: Increments: 0.05 0.05-2.00/∞ Inom Delay time tI N>: 0.00-9.99 s 10.0-99.9/∞ s
Increments: 0.01 0.1
Threshold operate value IN>>:Increments: 0.05 0.10-8.00/∞ Inom Delay time tI N>>: 0.00-9.99 s 10.0-99.9/∞ s
Increments: 0.01 0.1
Inverse Definite Minimum Time Overcurrent Protection (IDMT) Phase Current Base current IB : 0.40-4.00 Inom
Increments: 0.01
Characteristic factor: 0.10-1.00 Inom
Increments: 0.05
Characteristic type: Normally inverse Very inverse Extremely inverse Long time ground fault RI inverse Threshold operate value I>>: Increments: 0.1 0.4-40.0/∞ Inom Delay time tI>>: 0.00-9.99 s
Increments: 0.01
Residual Current Base current I NB or Threshold operate value I>: Increments: 0.01 0.04-0.40/∞ Inom 0.01 0.08-0.80/∞ Inom Characteristic factor: 0.10-1.00 Inom
Increments: 0.05
Characteristic type: Normally inverse Very inverse Extremely inverse Long time ground fault RI inverse Delay time tI N>: 0.00-9.99 s 10.0-99.9/∞ s
Increments: 0.01 0.1
Threshold operate value IN>>: Increments: 0.05 0.10-8.00/∞ Inom Delay time tI N>>: 0.00-9.99 s 10.0-99.9/∞ s
Increments: 0.01 0.1
PS 431 Time-Overcurrent Protection Device
Technical Data (continued)
Settings (continued) Circuit Breaker Failure Protection tCBF: 0.00-9.99/∞ s; increments: 0.01 Measuring-Circuit Monitoring Mode: without IA , IB IA , IB , I C Imcm >: 0.25-0.50 IPmax; increments: 0.05 tmcm: 0.00-9.99s; increments: 0.01 0.0-99.9/∞ s; increments: 0.1
Typical Characteristic Data
Deviations
Reset time from 2-fold threshold operating value to 0: ≤ 25 ms
Threshold Operate Values, PhaseCurrent Stages Deviation when I < 0.2 Inom: ± 15% Deviation when I ≥ 0.2 I nom: ± 5% Variation at 20°C ± 20 K: ± 2.5% Variation at V A,nom ± 20%: ± 1% Variation at f nom ± 5%: ± 5%
Resetting ratio: ≥ 0.95 Minimum output pulse for trip command: 100 ms
Power Supply
Time-Overcurrent Protection
1)
Threshold Operate Values, Residual Current Stages Deviation: ± 5% Variation at 20°C ± 20 K: ± 2.5% Variation at V A,nom ± 20%: ± 1% Variation at f nom ± 5%: ± 5%
Nominal auxiliary voltage VA,nom: 24-60 V DC and (internally switchable) 110-250 V DC / 100-230 V AC 3) Operating range for direct voltage: 0.8 to 1.1 Vnom with a residual ripple of up to 12% of V A,nom For alternating voltage: 0.9-1.1 V A,nom Nominal consumption: approx. 5 W at VA = 220 V DC
Delay Time of Definite-Time-Delayed Stages Deviation: ± 1% or ± 30 ms Variation at 20°C ± 20 K: ± 1% Delay Time of Inverse-Time-Delayed Stages Deviation: ± 7.5% Variation at 20°C ± 20 K: ± 2.5% Variation at V A,nom ± 20%: ± 1% Variation at f nom ± 5%: ± 5% Operating Data Measurement2) Currents IA , I B, I C, IN each > 0.4 I nom Deviation: ± 5% Variation at 20°C ± 20 K: ± 2.5% Variation at V A,nom ± 20%: ± 1% Variation at f nom ± 5%: ± 5% Fault Data Acquisition2) Short-circuit current > 0.4 Inom : Deviation: ± 5% Variation at 20°C ± 20 K: ± 2.5% Variation at V A,nom ± 20%: ± 1% Variation at f nom ± 5%: ± 5%
1)
Deviations referred to the set value with sinusoidal measured variables, total harmonic distortion ≤ 2%, ambient temperature 20°C, and nominal auxiliary voltage V A,nom
2)
Deviations referred to the respective nominal value with sinusoidal measured variables, total harmonic distortion ≤ 2%, ambient temperature 20°C, and nominal auxiliary voltage V A,nom
3)
V A,nom = 230 V AC only for units with a corresponding indication on the type identification label (beginning with hardware version 302)
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PS 431 Time-Overcurrent Protection Device
Signal List
Signal Inputs
LED Indicators
Output Relays
Abbreviations for Function Groups
The signal inputs allow intervention in the Protection sequence. Each input can be set for one of the signals given in Table 1. However, a given signal may be assigned to only one input. The signal names refer to the ”active” state of the input signal. Each input can be set as follows: active = low signal or active = high signal.
Two LED indicators on the local control panel have permanently assigned signals (Table 2a). The other six LED indicators are freely configurable and can be assigned any of the signals listed in Table 2b.
The output relays are freely configurable and can be assigned any of the signals listed in Table 3. Any signal can also be assigned to more than one free output relay for contact multiplication purposes.
CBF:
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All relays are operated in an energize-on-signal arrangement (‘open-circuit function’, the make contact is closed when the signal is present) except for the case where an output relay is configured for the signal ”MAIN: Blocked/ faulty.” In this case the relay operates in an normallyenergized arrangement (‘closed-circuit function’) and the break contact is closed for the blocked/faulty condition.
Circuit breaker failure protection
DTOC: Definite-time overcurrent protection IDMT:
Inverse definite minimum time overcurrent protection
MAIN: Main function MON: Self-monitoring
PS 431 Time-Overcurrent Protection Device
Signal List (continued)
Table 1: Freely Configurable Signal Inputs
Table 2a: Permanently Configured LED Indicators
Table 2b: Freely Configurable LED Indicators
Table 3: Freely Configurable Output Relays
Input Function Group
Indi- Funccator tion Group
Indi- Funccator tion Group
Re-
U1 U2
Signal
Without function MAIN: Block outp. rel. EXT E1 block. EXT E2 block. EXT Reset latch. + indic. Reset latch. EXT Reset indicat. EXT CBF: Input EXT
H1 H2
MON: MAIN:
Signal
Warning Blocked/faulty
H3 H4 H5 H6 H7 H8
Signal
Without function MAIN: Trip command E1 block. EXT E2 block. EXT IDMT/ DTOC: Starting I> or Iref> Starting I>> Starting A Starting B Starting C Starting GF Gen. starting tI>> elapsed tI> or tI>> tIN> elapsed tIN>> elapsed tIN> or tIN>> tIref elapsed inv. tINref elapsed inv. CBF: MON:
Input EXT tCBF elapsed
lays
Function Group
K1 K2
Without function
K3 K4
Signal
MAIN: Trip command Blocked/faulty IDMT/ DTOC: Starting I> or Iref> Starting I>> Starting GF Gen. starting tI>> elapsed tI> or tI>> tIN> elapsed tIN>> elapsed tIN> or tIN>> tIref elapsed inv. tINref elapsed inv. CBF:
tCBF elapsed
MON:
tmcm Warning
DTOC: tI> elapsed def.
tmcm
DTOC: tI> elapsed def.
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PS 431 Time-Overcurrent Protection Device
Dimensional Drawing and Terminal Connection Diagram
20.6
20.6
4 Dimensional drawing and panel cutout
X3
36
X1
18
6.4
300
281 +1
R
256 +1
E
279
y
289
x
294.2
PS 431
254
299
294.2
F
Æ
X3
309
19
X6
1
X1
65.6
48.6
6.4
+
125 - 0.5
9
125
+ 0.5
93
162.5 -
175.6 Surface-mounting
172
Flush-mounting
Surface-mounting
Panel cut-out and mounting frame outline
5 Terminal connection diagram LED Indicators
Power Supply X1 L+ 13
Aux. voltage VA 2)
U100
L– 14
Meas. Inputs A1 A2 A3 B1 B2 B3 C1 C2 C3 N1 N2 N3
X1 1 (1 A) 2 (5 A) 3 4 (1 A) 5 (5 A) 6 7 (1 A) 8 (5 A) 9 10 (1 A) 11 (5 A) 12
T1 T2
X1 15 16 17 18
3) Internal interface, voltage test is prohibited
10
Blocked/Faulty
H3
IDMT/DTOC: Starting A 1)
H4
IDMT/DTOC: Starting B 1)
H5
IDMT/DTOC: Starting C 1)
H6
IDMT/DTOC: Starting GF 1)
H7
IDMT/DTOC: tI> V tI>> 1)
H8
IDMT/DTO
C: tIN> V tIN>> 1)
Output Relays
U1
K1
U2 K2
X6 D1 2 D2 3 E2 5
PS 431
K3
11801.DS4
2) L+ und L- circuit may be tested only with 2.8 kV DC to ground
1)
Warning
MAIN:
T4
PC Interface 1) Freely configurable (see signal list on page 9); signals as per factory setting are entered in the diagram
MON:
H2
T3
Signal Inputs MAIN: Reset latch.+indic. 1) L+ L– MAIN: Block. outp. rel. EXT 1) L+ L–
H1
K4
X3 36 35 33 32 34 31 30 28 27 29 26 25 23 22 24 20 19 21
MAIN:
Trip command 1)
IDMT/DTOC: Gen. starting 1)
1)
Main:
Blocked/Faulty 1)
11800.DS4
!
PS 431 Time-Overcurrent Protection Device
Connection Example
6 PS 431 connection example
A B LED Indicators
Power Supply
C
X1 L+ 13
Aux. voltage VA 2)
H1 U100
L– 14
H2 H3 H4
Meas. Inputs
L+ L– L+ L–
X1 15 16 17 18
H5 H6
T1
H7 H8
T2 T3 T4
Signal Inputs
Output Relays
U1
K1
U2 K2
PC Interface X6 D1 2 D2 3 E2 5
PS 431
K3
11801.DS4
1)
K4
X3 36 35 33 32 34 31 30 28 27 29 26 25 23 22 24 20 19 21
11802.ds4
A1 A2 A3 B1 B2 B3 C1 C2 C3 N1 N2 N3
X1 1 (1 A) 2 (5 A) 3 4 (1 A) 5 (5 A) 6 7 (1 A) 8 (5 A) 9 10 (1 A) 11 (5 A) 12
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PS 431 Time-Overcurrent Protection Device
Ordering Information
Numerical time-overcurrent protection device with inverse-time and definitetime characteristics Case for panel surface or flush mounting 4-pole measurement (A, B, C, N)
AEG Energietechnik GmbH Bereich Schutz- und Schaltanlagenleittechnik System Protection and Control Lyoner Straße 44-48 D-60528 Frankfurt P.O. Box 71 01 07 D-60491 Frankfurt Phone +49 69 6632 1521 Fax +49 69 6632 2548
Designs
Order No.
PS 431 Wall-mounting case with 36 terminals for wall surface mounting for panel flush mounting with cover frame
89431-0- 1 1 2 3 3 1 0 89431-0- 2 1 2 3 3 1 0
AEG Starkstromanlagen Dresden GmbH Bereich Schutz- und Schaltanlagenleittechnik System Protection and Control Königsbrücker Straße 124 D - 01099 Dresden P.O. Box 10 03 60 D-01073 Dresden Phone +49 351 820 3360 Fax +49 351 820 3366
Extension No. (append to order no.)
User-selection of IDMT or DTOC mode Phase-selective overcurrent timer stage and starting signals Time-lag high set phase current and high set residual current stages Tripping matrix
Nominal current Inom : Phase current inputs 1 A, residual current input 5 A Nominal frequency fnom : 50 Hz and 60 Hz Nominal auxiliary voltage for power supply V A,nom: 24-60 V DC and 110-250 V DC or 100-230 V AC 1) Nominal auxiliary voltage for signal inputs V In,nom: 24-250 V DC
Optional latching of individual tripping criteria
Additional Options
Circuit breaker failure protection
Labeling and documentation in English
Option of reverse interlocking
Accessories
Measuring circuit monitoring Operating data measurement
PC connecting cable (2.5 m) FPCC parameter setting program
-598
255 002 096 251 254 271
Event counting Fault data acquisition
1)
Range selection via plug-in jumper, factory setting underlined.
Fault logging Comprehensive self-monitoring
Integrated local control panel 8 LED indicators (6 freely configurable) PC interface
SLTS.06.04185PDF/0597EN · Ti
4 output relays (freely configurable)
Subject to modifications · Printed in Germany
2 signal inputs (freely configurable)
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