992481‐6700‐D‐E‐MC‐0012
CALCULO DE CARGABILIDAD EN
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
SHOUGANG HIERRO PERÚ S.A.A.
PROYECTO: PROYECTO: AMPLIACIÓN A MPLIACIÓN DE OPERACIONES MINA Y PLANTA PLA NTA DE BENEFICI B ENEFICIO O CONTRATO DE EPC Nº 14: 14: “SE EL HIERRO, LÍNEA DE TRANSMISIÓN 220 kV” CALCULO DE CARGABILIDAD EN TRANSFORMADORES DE MEDIDA
Documento No.: 992481-6700-D-E-MC-0012
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11/09/13 11/09/13
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02/09 /09/13 /13
APROBACIÓN IÓN
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CALCULO DE CARGABILIDAD EN TRANSFORMADORES DE MEDIDA
992481‐6700‐D‐E‐MC‐0012
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
ÍNDICE 1
INTRODUCCIÓN ................................................................................................................... ..................................................................................................................... 3 1.1 OBJET BJETIVO IVO...................................................................................................... ....................................................... 3 1.2 AL ALCANCES.... ...... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .... .. 3 1.3 NORMAS APLIC APLICA ABLES BLES................................................................................................ ........................................ 3
2
CARACTERISTICAS GEOGRAFICAS ................................................................................. 3
3
CARACTERÍSTICAS DEL SISTEMA ELÉCTRICO .............................................................. 3
4
SELECCIÓN DE TRANSFORMADORES DE CORRIENTE ................................................. 4 4.1 4.2 4.3 4.4
5
CORRIENTE DEL PRIMARIO DEL TRANSFORMADOR .................................................................................... 4 CORRIENTE DEL SECUNDARIO DEL TRANSFORMADOR ............................................................................. 5 CARGABILIDAD DE LOS TRANSFORMADORES DE CORRIENTE ................................................................. 5 CARA CARACT CTER ERÍSTICA ÍSTICAS S DE LOS TRANS TRANSFO FORM RMAD ADOR ORES ES DE CORR CORRIENT IENTE E ....... .......... ...... ....... ....... ...... ...... ...... ...... ...... ...... ...... ...... ...... ...... ...... ...... ....... 6
SELECCIÓN DE TRANSFORMADORES DE TENSIÓN ...................................................... 6 5.1 5.2 5.3
RELACIÓN DE TRANSFORMACIÓN ................................................................................................................... 6 CARGABILIDAD DE LOS TRANSFORMADORES DE TENSIÓN ....................................................................... 6 CARACTERÍSTICAS DE LOS TRANSFORMADORES DE TENSIÓN ............................................................... 7
6
CONCLUCIONES................................................................................................................... 7
7
ANEXOS
........................................................................................ 7 ....................................................................................
CALCULO DE CARGABILIDAD EN
992481‐6700‐D‐E‐MC‐0012
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
CALCULO DE CARGABIL IDAD EN TRANSFORMADORES DE MEDIDA
1 INTRODUCCIÓN 1.1
OBJETIVO
El desarrollo de este documento tiene como objetivo, determinar las características de los transformadores de corriente y tensión para la subestación El Hierro en 220 kV. 1.2
ALCANCES
El alcance del presente informe comprende: Desarrollo de la memoria de cálculo An Anexos de los los cálcu lculos los
1.3
NORMAS APLICABLES
Para establecer las características de los equipos de medición de la subestación, se empleará la norma IEC 185 “Current Transformer”. 2 CARACTERISTICAS GEOGRAFICAS La S.E. El Hierro se encuentra ubicada en el asiento minero Marcona - Shougang (Mina - San Nicolás), Provincia de Nazca, Departamento de Ica. El área del Proyecto está comprendida al interior de la zona de influencia de la Nueva Planta Beneficio. Las características climatológicas y geográficas en el área del proyecto, son las siguientes: Alt Altu ura : 114 msnm Temperatura Temperatura Mínima : 5 °C Temperatura Temperatura Máxima Máxima : 40 ° C Contaminaci Contaminación ón Ambiental Ambiental : Muy Muy severa carácter salino salino Humedad Humedad relati relativa va media : 50%/90%
3 CARACTERÍSTICAS DEL SISTEMA ELÉCTRICO Las características del sistema eléctrico son las siguientes: Cuadro Nº: 1 Características del Sistema Tensión Nominal Frecuencia asignada Puesta a tierra tierra Número Número de fases Tensión asignada del equipos (kV) Tensión de operación del sistem sistema a (kV)
220kV 220kV 60 Sólido 3 245 220
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
Tensión Nominal Tensión asignada soportada al impulso tipo tipo rayo (kV) Corriente de cortocircuit cortocircuito o prevista prevista en el sistem sistema a (kA) Distancia Distancia de fuga mínima, (mm/kV (mm/kV fase tierra): tierra): Identificación Identificación de fases
220kV 220kV 1050 11,5 kA 55 R, S y T
4 SELECCIÓN DE TRANSFORMADORES DE CORRIENTE 4.1
CORRIENTE DEL PRIMARIO DEL TRANSFORMADOR
El procedimiento empleado para la selección de la corriente del primario del transformador de potencia es el siguiente: Cálculo de la corriente de carga por el Transformador de Corriente (I1). La selección de la corriente de carga del Transformador de corriente de las celdas de salida y llegada de Línea se calcula con el flujo de carga máxima que pasará por dicho transformador de corriente. La fórmula empleada para el cálculo de la corriente es la siguiente:
I1= S/(√3xV) Donde: S: Potencia Total de consumo V: Tensión de operación del Sistema
Para Validar la corriente calculada y que el transformador de corriente no se sature ante eventos de cortocircuito, se calcula la corriente máxima por el devanado del primario La fórmula empleada para el cálculo de la corriente es el siguiente: I2= Icc/(N) Donde: I2: Corriente máxima a soportar por el TC sin saturarse N: Es el número de veces la corriente nominal previsto para el error del TC de protección; para nuestro caso es 5p20; entonces N=20.
Cuadro Nº: Nº: 2 Corrientes de Cortoci rcuit o de Diseño Subest ación ació n El Hierro
2014 2015 2016 2025
Corriente Máxim a en 220 kV 4.887 4.998 5.62 5.62 8.5 Considerando un incremento de la corriente de cortocircuito del 50%, por el crecimiento del sistema, se tiene 1.5x5.62=8.43 kA; considerándose 8,5 kA y que corresponde a la proyección a 11 años del sistema. De ambas corrientes determinadas I1 y I2 se selecciona el mayor valor normalizado para corriente en el primario del transformador de corriente. En el cuadro siguiente se presenta el resumen de las corrientes calculadas y seleccionadas:
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
Cuadro Nº: Nº: 3 Selecció Selecció n del Primario Primario del Transfor mador de Corriente Tensión
Corriente Corriente de Saturación
Corriente de Carga Carga
I primario
(kV)
I2
I1
Calculada Seleccion ada
Descripción Bahía Salida
220
Icc (kA)
(A)
MVA
(A)
(A)
(A)
8,50
425
264
694
694
1200-600
La potencia máxima a transmitir en la bahía de salida de llegada de la SE Marcona, corresponde a la potencia de los dos transformadores de potencia de 220/22,9kV los cuales son de 132MVA cada uno, haciendo un total de 264MVA y en 220kV, 694A, esta vendría a ser la corriente de carga en la condiciones de máxima carga. Por otro lado la corriente de cortocircuito al año 2016 es de 5.62kA, con un incremento del 50%, sería 8,50kA, y esto nos da una corriente de 425A. 4.2
CORRIENTE DEL SECUNDARIO DEL TRANSFORMADOR
La norma IEC 185 “Current Transformer” estandariza las intensidades nominales en el secundario a valores de 1 y 5 A. La corriente en el secundario de los transformadores se ha elegido 1 A, pues permite menores valores de potencias en los transformadores de medida. 4.3
CARGABILIDA D DE L OS TRANSFORMADORES TRANSFORMADORES DE CORRIENTE
La cargabilidad de los núcleos de los transformadores de corriente se obtiene sumando los consumos totales que se originan desde el borne del transformador hasta el relé o medidor, tales como; consumo de los relés, consumo del cable de conexión. La potencia en estado normal de consumo del transformador de corriente se calcula conforme a la siguiente ecuación: P
( Rr 2 xRc xL ) xI S 2 VA.
Simplificando: Burdentotal
Rr Burden
2 xBurden Rc VA.
Dónde: Burden total: Potenci Potencia a Total Total de consumo por la impedancia equivalente en bornes del TC. Rr: Resistencia del Relé de protección o equipo de medida. Rc: Resistencia del cable, ohm/m; se considera un cable N2XSY 4x4 mm² L: Longitud del cable desde el transformador de corriente hasta el gabinete, en metros. Is : Corriente que circula en el devanado secundario (1 A )
En el cuadro siguiente se presenta el burden total de los Transformadores de corriente y la cargabilidad del Transformador. Cuadro N° 3 Cargabilidad de los Transformadores de Corriente Descripción
Tensión (kV)
L o n g i tu d Ca bl bl e " L" L" (m )
o hm hm /m /m
Bahía Llegada
220
60.00
0.0050
Rc o hm hm (to ta ta l) l)
0.2970
Rr Bu rd rd en en (VA) Bu rd rd en en (VA)
0.2970
1 5.00
Bu r d e n To ta ta l
Co r r te . Se cd cd . Is (A)
Po t-Tr a f VA
Cargab.
15.59
1.00
30
51. 98%
Notas: El valor de Rr se tomó considerando el IED de mayor carga (ver anexo 7.0). Los IEDs considerados son los siguientes: - Relé de protección REC 670 (tanto principal como respaldo). - Medidor de energía ION 7650.
Según la norma IEC 185 para asegurar la precisión de los transformadores el burden debe de estar entre el 25 % y el 100 % del burden total, validándose que el transformador opera correctamente.
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4.4
S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
CARACTERÍSTICAS DE LOS TRANSFORMADORES DE CORRIENTE
En el cuadro siguiente se presenta las características de los transformadores de corriente: Cuadro N° 4 Características de los Transformador es de Corriente
Descripción Bahía Llegada
Tensión
Relación Relación de Transformación
(kV) 220
Potencia
Clase
(VA) 4x30 VA
1200-600/1-1-1-1 1200-600/1-1-1-1
Medición 1xCl 0,2
Protección 3x5P20
5 SELECCIÓN DE TRANSFORMADORES DE TENSIÓN 5.1
RELACIÓN DE TRANSFORMACIÓN
La relación de transformación de los transformadores de tensión es seleccionada con la tensión nominal del sistema y las tensiones normalizadas de los equipos, para nuestro caso es 115V. Cuadro N° 5 Relación de Transfor Transformación mación de los Transform adores de Tensión Tensión
5.2
Descripción
Tensión (kV)
Bahía Llegada
220
Relación Relación d e Transformación
CARGABILIDAD CARGABILIDA D DE LOS L OS TRANSFORMADORES TRANSFORMADORES DE TENSIÓN
La cargabilidad de los núcleos de los transformadores de tensión se obtiene sumando los consumos totales que se originan desde el borne del transformador hasta el relé o medidor, tales como; consumo de los relés, consumo del cable de conexión. La potencia en estado normal de consumo del transformador se calcula conforme la siguiente ecuación: P
Vs
2
( Rr 2 xRc xL)
VA.
Simplificando: Burdentotal
Rr Burden
2 xBurden Rc VA.
Dónde: Burden total: Potencia Potenci a Total de consumo consumo por la impe impedancia dancia equivalente en bornes del TT Rr: Resistencia del Relé de protección Rc: Resistencia del cable, ohm/m; se considera un cable N2XSY 4x4 mm² L: Longitud del cable desde el transformador de tensión hasta el gabinete, en metros. Vs : Tensión en el el devanado secundario secundario 115/√3
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En el cuadro siguiente se presenta el burden total de los Transformadores Transformadores de tensión y la cargabilidad cargabilidad del Transformador: Transformador: Cuadro N° 6 Cargabilidad de los Transformadores de Tensió Tensiónn Descripción Bahía Llegada
Tensión (kV) 220
L o n g i tu d Ca b l e " L" L" (m )
o h m /m /m
60.00
0.0050
Rc o h m (to ta l )
0.2970
Rr Bu r d e n (VA) Bu r d e n (VA)
0.0672
15.00 15
Bu r d e n To ta l
Te n si o n Se cd . (V)
Po t-Tr a f VA
Cargab.
15.13
66.40
30
50. 45%
Notas: El valor de Rr se tomó considerando el IED de mayor carga (ver anexo 7.0). Los IEDs considerados son los siguientes: - Relé de protección REC 670 (tanto principal como respaldo). - Medidor de energía ION 7650.
Según la norma IEC 186 para asegurar la precisión de los transformadores el burden debe de estar entre el 25 % y el 100 % del burden total. 5.3
CARACTERÍSTICAS DE LOS TRANSFORMADORES DE TENSIÓN
En el el cuadro siguiente se presenta el resumen resumen de característi características cas de los transformadores d de e tensión del proyecto: Cuadro N° 7 Características de los Transformador es de Tensión Descripción
Tensión (kV)
Bahía Llegada
220
Relación Relación de Transfor mación
Potencia
Clase
(VA)
Medición Medición Protección
2x50 VA 1xCl 0,2
1x3P
6 CONCLUCIONES De lo visto anteriormente los transformadores de medición cumplen con los requerimientos de carga que se colocarán en sus bornes (relés y medidor multifunción) 7 ANEXOS 7.1 7.2 7.3
Cuadro resumen Medidor Medidor multif ultifunción unción ION 7650 IED controlador REC670 REC670
CALCULO DE CARGABILIDAD EN TRANSFORMADORES DE MEDIDA
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
AN ANEXO 7.1: CUADRO RESUMEN
CARGABILIDAD TRANSFORMADORES DE CORRIENTE
Descripción Bahía Llegada
Tensión (kV) 220
Long itud Cab l e " L" L" (m ) 60.00
o h m /m 0.0050
Rc o h m (t o t a l ) 0.2970
Rr B u r d en (VA) B u r d en (VA ) 0.2970 15 15.00
B u r d en To t al 15.59
Co r r t e. Sec d . Is (A ) 1.00
Po t -Tr af VA 30
Cargab.
B u r d en To t al 15.13
Ten s i o n Sec d . (V) 66.40
Po t -Tr af VA 30
Cargab.
51.98%
Rr: Burden del IED; Relé, medidor, analizador Rc: Resistencia del cable, ohm/m; se considera un cable N2XSY 4x4 mm² L: Longitud del cable desde el transformador de corriente hasta el gabinete, en metros. Is : Corriente que circula en el devanado secundario (1A )
CARGABILIDAD TRANSFORMADORES DE TENSION Descripción Bahía Llegada
Tensión (kV) 220
Long itud Cab l e " L" L" (m ) 60.00
o h m /m 0.0050
Rc o h m (t o t a l ) 0.2970
Rr B u r d en (VA ) B u r d en (VA ) 0.0672 15 15.00
Rr: Burden del IED; Relé, medidor, analizador Rc: Resistencia del cable, ohm/m; se considera un cable N2XSY 4x4 mm² L: Longitud del cable desde el transformador de tensión hasta el gabinete, en metros. Vs : Tensión en el devanado secundario
Características Características de los Transformadores de Corriente Clase
Descripción
Tensión (kV)
Relación de Transformación
Potencia (VA)
Med ic ic ió ió n
Pr ot ot ec ec ci ci ón ón
Bahía 220
220
1200-600/1-1-1-1
4x30 VA
1xCl 0,2
3x5P20
Potencia (VA)
Med ic ic ió ió n
Pr ot ot ec ec ci ci ón ón
2x50 VA
1xCl 0,2
1x3P
Características Características de los Transformadores de Tensión
Descripción
Tensión (kV)
Bahía 220
220
Relación de Transformación
Clase
50.45%
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S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
AN ANEXO 7.2: MEDIDO IDOR MULTIFUNCIÓN ION 7650
7550 | 7650 TRAN option
Fe a t u r e s Su m m a r y
A p p l i ca c a t i o n s Su Su m m a r y Compliance Monitoring Use the ION 7650 meter to summarize power quality measurements into simple pass/fail indicators. Monitor compliance with international standards such as EN50160, IEC 61000-4-7 (harmonics), and IEC 61000-4-15 (flicker). Or configure the unit for IEEE 519-1992, IEEE 1159 and SEMI F47. Integrated display model
I n t e l l ig ig e n t M e t e r i n g a n d Co n t r o l D e v i c e s
Disturbance Analysis Maintain revenue revenue accuracy at the regular measurement measurement range while simultaneously capturing large-scale disturbances other meters can miss. Discover the sources of power quality events, harmonics, sags and swells. Analyze problems; avoid repeat interruptions.
Used at key distribution points and sensitive loads, the ION® 7550 and ION ® 7650 meters offer unmatched functional funct ionality ity including including advanced power quality analysis coupled with revenue accuracy, multiple communications options, web compatibility, and control capabilities.
Cost Allocation and Billing Determine cost centers, identify demand control opportunities and check energy consumption patterns.
The meters come with an extensive selection of pre-configuredd data screens and measurements that y ou pre-configure can use right out of the box or customize to fit your unique requirements.
Load Studies/Circuit Optimization Determine the capacity of your electric network and run at peak efficiency. Perform load trending.
For an enterprise energy management solution, the meters can be integrated with our ION EEM software, ION Enterprise® software, or other energy management and SCADA systems via multiple communication channels and protocols. Patented ION technology lets you customize metering or analysis functions at your workstation, without any hard-wiring. Just graphically link a few drag-and-drop icons, or select default setups, and you're ready to go. Not all features listed are available with every model. Please refer to the detailed descriptions within for a complete list of feature availability availability..
Demand and Power Factor Control Avoid penalties with automated load shedding, scheduling, peak shaving or capacitor bank control.
Equipment Monitoring and Control Improve process yields and extend equipment life. Extensive analog and digital I/O enables system monitoring and control. Preventative Maintenance Preventative Set up alarms to warn of pending problems. Log events and alarms for all critical conditions. Integrated Utility Metering Collect, scale, and log water, air, gas, electricity, and steam readings from connected meters or transducers, and deliver the information to head-end systems. Instrument Transformer Correction Use the meter's ITC feature to correct for less accurate transformers, saving money and improving accuracy.
Measurements Exceeds Class 0.2 revenue accuracy frequency,, Instantaneous 3-phase voltage, current, frequency power factor Energy: bi-directional, absolute, net, time-of-use, loss compensation Demand: rolling block, predicted, thermal Harmonics: individual and total harmonic distortion up to the 63rd (511th in software) Transient sient detection: 17us at 60Hz, Tran (20us at 50Hz) and sag/swell recording Internet-Enabled Communications ® WebMeter, MeterM@il allow distribution of metered data and alarms over the Internet Optional built-in modem with ModemGate allows modem access for 31 other devices 10Base-T or 10Base-FL Ethernet port option with EtherGate allows for direct data transfer from Ethernet to RS-485 Twoo RS-485 ports, one switchable to RS-232 Tw One ANSI Type 2 front panel optical port Modbus RTU/TCP and DNP 3.0 support Modbus Master support On-Board Data Logging Scheduled or event-driven logging Sequence-of-events, min/max, waveform, faults, and transient logging Setpoints for Control and Alarms Setpoint on any parameter or condition 1 second or 1/2 cycle operation Inputs and Outputs Standard format includes 8 digital inputs, 3 Form C relay outputs (electromechanical) for control functions, and 4 Form A digital outputs (solid state) for pulse functions Also available with 8 additional digital inputs, 4 analog outputs, and/or 4 analog inputs Multi-user, Multi-level Security Access to meter information can be controlled and customized for up to 16 designated users with security levels ranging from read access up to administrative rights.
7550 | 7650 Energy Display
Fr o n t P a n e l D i s p l a y The meters offer unique, easy-to-read 3 / x 4 / inch (87 x 112mm) LCD display screens with bright back lighting and adjustable contrast. They can show TOU, harmonics, event logs, phasors, and instantaneouss power parameters. A selection of instantaneou character sizes enhance visibility under difficult lighting conditions or at long distances. It provides a user-friendly interface with a screen-based menu system to configure meter settings and an extensive choice of pre-configured display screens for common applications. 12
Peak demand with date and time-stamp
Metering Energy The meters are fully bi-directional and monitor energy in four quadrants. They provide active, reactive and apparent energy parameters and can integrate any instantaneous power parameter to supply measurements like:
The meter’s display system reliability in nines, (e.g. 99.99% up-time).
12
kWh delivered and received kWh, kVARh, kVAh net (delivered - received) kWh, kVARh, kVAh total (delivered + received) kVARh, kVAh delivered and received Volt-hours and Amp-hours Integration of any instantaneous measurement
Energy registers can be logged automatically on a programmed schedule. Demand The meters support all standard demand calculation methods, including block, rolling block, thermal (exponential), and predicted demand. They can measure demand on any instantaneous value and record peak (maximum) and minimum demand with date and time-stamps to the second. Peak dema demand nd registers can be reset manually (password protected) or logged and reset automatically on a programmed schedule. Measurements include:
Display kWh usage trends directly on the meter ’s front panel
kW, kVAR, kVA demand, min/max Amps, Volts demand, min/max Demand on any instantaneous measurement
Trending Both meters offer access to historical data right at the front panel. The meters display display,, trend and continuously update historical data with date and timestamps for up to four parameters simultaneously simultaneously.. Instantaneous
Both meters provide a choice of high accuracy, 1 second or high-speed, 1/2 cycle measurements, including true RMS, per phase and total for: Voltage and current (kVAR) Active power (kW) and reactive power (kVAR) Apparent power (kVA)
2
Power factor factor and and frequency
Voltage and current unbalance
Phase reversal
Time-Of-Use The meters offer comprehensive time-of-use (TOU) metering. A 20 year calendar is configurable in accordance with virtually any utility tariff structure. TOU register values can be automatically recorded at user-specified time intervals, at pre-scheduled dates and times, or when internal or external events occur. Transformer/Line Loss Compensation
Flexible compensation methods Easy configuration Updated every second Available through all supported protocols Instrument Transformer Correction
The meters provide high-accuracy instrument transformer correction, allowing you to use lower-accuracy, lower-cost transformers while retaining high-accuracy transformer function.
P o w e r Q u a l iti t y M e t e r i n g Compliance Monitoring* EN 50160 compliance monitoring
IEC 61000-4-7 harmonics and inter-harmonics** IEC 61000-4-15 flicker CBEMA/ITIC IEEE 519 and IEEE 1159
Waveform Recording The meters can simultaneously capture all voltage and current channels.
Sub-cycle disturbance capture The maximum number of cycles for contiguous waveform capture is 214,000 (based on 16 samples/cycle x 96 cycles and the largest capacity of meter memory) Up to 512 samples/cycle standard, 1024 samples/cycle optional with the ION 7650 Up to 256 samples/cycle with the ION 7550 Dynamic range: Voltage inputs - 16 bits effective; Current inputs - 19 bits effective
Measure Up-time Using Nines The current electricity supply infrastructure can typically provide electricity with 99.9% reliability reliability,, (3 nines or 8.8 hours downtime a year). However, any disruption is unacceptable for businesses in the digital economy that can require up to 99.9999999% (9 nines or 2 cycles downtime per year) to effectively run their business model. Measure the number of nines of reliability with the ION 7550 and ION 7650. Out-of-Limit Detection Detect, record, and report the specifics of voltage or current imbalances and loss, frequency/power factor variations, over and undervoltages, etc. * Available only on ION 7650 ** Compliant with input signals up to 59kHz
Performance Indicators The meters can be configured to monitor a wide range of utility performance indicators, including:
Total outage time (in seconds) Out-of-tolerance duration for total harmonic distortion, voltage, frequency, frequency, power factor and hundreds of other definable indices
Harmonic Distortion Metering Complete harmonic distortion metering, recording and real-time reporting, up to the 63 rd harmonic (511 th for ION 7650 via ION Enterprise software) for all voltage and current inputs.
Individual harmonics (including magnitude, phase and inter-harmonics for the ION 7650) Total even harmonics and total odd harmonics Total harmonics (even + odd) K-factor,, Crest factor K-factor
Symmetrical Components* Zero, negative and positive sequences including phase and magnitude for voltage and current inputs. Identify harmful voltage and current unbalances in equipment before they cause damage. Sag/Swell Detection The ION 7550 and ION 7650 meters sag/swell capture capability can help you analyze the severity/potential impact of sags and swells. ’
Magnitude and duration data suitable for plotting on voltage tolerance curves Per-phase triggers triggers for waveform recording or control operations
Coincident Min/Max Recording Log the values of key parameters or equipment conditions coincident with an extreme condition, complete with date/time stamping. For example, record all feeder voltages and currents at the moment a peak demand condition occurs. Time Synchronization and GPS A real-time clock allows internal events and data records to be date-stamped and time-stamped to millisecond resolution. The clock can be synchronized to any one of three sources:
The meter 's internal crystal (+/- 5ppm @ 0° to 40°C, 32° to 104°F ) The line frequency of the electrical network being metered, which is accurate to 3 seconds per month (+/- 1 ppm) An external GPS receiver with an accuracy of +/- 1 millisecond
L o g i c , M a t h a n d Co Co n t r o l Perform on-board calculations on any measured value, calculate true quantities from pulse inputs (e.g. BTUs) and calculate transformer loss compensation values. You can also implement r eal-time billing schemes. Mathematical Functions Define formulas using the following operators:
Arithmetic (+, x, -, ÷)
Comparison (>, <, =, ≥, ≤, ≠)
Transient Capture* The ION 7650 meter can detect and record sub-cycle transients as short as 17us at 60Hz (20us at 50Hz)
Logical ( AND, OR, NOT, TRUE, FALSE, IF)
Trigonometric ( SIN, COS, TAN, ASIN, ACOS, ATAN)
Math (PI, SQRT, POWER, SUM, SUMSQ, AVG, RMS, LOG10, LN, MAX, MIN)
Data and Event Recording
Programmable Logic and Setpoints 24 setpoints can be set for 1-second or 1/2-cycle operation and can be triggered by any over or under condition. Setpoints can trigger:
Load Profiling The ION 7550 and ION 7650 meters incorporate 800 channels via 50 data recorders. Channel assignments are configurable for historical trend recording of energy, demand, voltage, current, power quality, or any other measured parameter. Trigger recorders based on time interval, calendar schedule, alarm/event condition, or manually.
Vector diagram with magnitude and phase angle can help reduce installation time
The serial port used for GPS time synchronization is dedicated exclusively as a GPS input.
The meters provide 5MB (up to 10MB factory option) of configurable, nonvolatile memory for waveform, event and log storage.
Multiple display formats are available, including bar graphs with min/max indicators
Audible (through software) and visible alarms Modem/pager dial-back Data logging Waveform recording with control over pre-event and post-event capture Relay control Clearing and reset functions Relative setpoints
View THD and individual harmonics through the f ront panel display screen
Built-in Web server provides browser access to extensive real-time meter data
High-Speed Data Recording High-speed “burst” recording (as fast as 1/2-cycle intervals) stores detailed characteristics of disturbances or outages. Trigger recording by a user-defined setpoint, or from external equipment. Gated recording logs data only during the critical event so that memory is conserved. * Available only on ION 7650
3
7550 | 7650 So f t w a r e I n t e g r a t io n Extensive communication capabilities enable the meters to be easily integrated into Power Measurement’s software or with other energy management and distributionn control systems. distributio ION® EEM Software The meters can be integrated with ION ® EEM software, an enterprise level software suite that satisfies a full spectrum of energy management needs, from operational cost reductions to procurement support to cost allocation, benchmarking and budgeting. ION Enterprise® Software The met meters ers are com compat patibl iblee wit withh our Win Window dows-b s-base asedd ION Enterprise operations software, which displays real-time and logged data and offers manual control/configuration capabilities. It provides enterprise-wide data sharing in a secure networked environment. ION Setup Software Both meters are further enhanced by free ION Setup for Windows, a user-friendly setup assistant and software solution that displays real-time data from your power monitoring devices and provides device configuration capabilities.
Modbus Master The meters can read and write data to Modbus slave devices through a designated serial port. This powerful feature allows meters to collect data from Modbus devices, process it, then deliver condensed information in a variety of ways. Modbus Master read ability lets you acquire data from nearby low-cost meters, which can be filed in on-board memory, presented on the graphical display or monitored using built-in setpoints.
Modbus Master write capability lets you perform functions such as controlling remote I/O points, resetting setpoint or configuration parameters on PLCs, and simple data exchange with other information systems.
I n t e r n e t Co Co n n e c t i v i t y MeterM@il® Meters equipped with an Ethernet port can automatically email alarm notifications or scheduled system-status updates. MeterM@il messages can be received like any email message, at a workstation, cell phone, pager or PDA. Data logs can also be sent on an event-driven or scheduled basis via email, while conveniently accommodating firewall restrictions. WebMeter® An on-board Web server, combined with an Ethernet port, offers quick and easy access to real-time energy and basic power quality information without special software. Built-in web pages display a range of energy and basic power quality information through any web-enabled device and even support basic meter configuration tasks. XML Compa Compatibil tibility ity The meters can also exchange information using industry-standard XML format. Its simple machine-readable format supports easy integration with custom reporting, spreadsheet, database and other applications.
Communications Multi-Port, Multi-Protocol Access Simultaneous communication on up to 4 ports provides secure data sharing with a variety of energy management systems using a choice of communication standards and protocols. RS-232/RS-485 Port Selectable between RS-232 and RS-485
Protoc Pro tocols ols:: ION, ION, DNP 3.0, 3.0, Modbu Modbuss RTU, RTU, GPS, EtherGate, ModemGate, or Modbus Master Baudd rate: Bau rate: 300 bps to 115, 115,20 2000 bps bps
RS-485 Port Pro Protoc tocols ols:: ION ION,, DNP 3.0, 3.0, Modbu Modbuss RTU, RTU, GPS, EtherGate, ModemGate, or Modbus Master
Baudd rate: Bau rate: 300 bp bpss to 57, 57,600 600 bps
Infrared Data Port The ANSI Type 2 compliant optical port can download real-time data to a portable PC.
Protocols Protoc ols:: ION, ION, Modbu Modbuss RTU, RTU, DNP DNP 3.0 3.0 Baud rate: 1200 bps to 19,200 bps
Internal Modem Available internal telephone modem features fast connect time and ModemGate, a gateway letting up to 31 additional devices share a meter ’s internal modem via the remaining serial ports.
Protocols Protoc ols:: ION, ION, Modbus Modbus RTU RTU and and DNP 3.0 3.0 Baud Ba ud rat rate: e: Up to to 33.6 33.6 kbp kbpss
Ethernet Port Optional 10Base-T or 10Base-FL port offers direct access through an Ethernet LAN/WAN and features EtherGate, which permits the direct transfer of data between an Ethernet network and up to 62 devices via the meter’s two serial ports.
Protocols: Protocol s: TCP/IP TCP/IP, ION, ION, Modbus Modbus TCP TCP, DNP 3.0, 3.0, Telnet NTP, DNS, and SMTP Baud Ba ud ra rate te:: Up to 10 Mb Mbps ps
Interoperability Concurrent communications ability via multiple protocols allows you to use the advanced features of either meter to extend an existing Modbus, DNP or ION software network. Logs and real-time values are also available through Modbus. UTS Software Support The meters are fully compatible with UTS software platforms including MV-90, MVP, MVRS, MVLT and MVCOMM, and offer a direct Ethernet connection to MV-90. Flash-Based Firmware Perform upgrades via communications without removing the meter from the site. 4
I n p u ts / O ut p u t s
Dimensions
Standard digital and optional analog I/O let you monitor a wide range of conditions, such as flow rates, RPM, fluid levels, oil pressures and transformer temperatures. You can output energy pulses to an RTU or perform equipment control operations. The ION 7550 can also be ordered in an optional, dedicated Remote Terminal Unit (RTU) configuration. Please see the ION 7550 RTU Option datasheet for more information.
Front view
Front view, TRAN model
Side view
Side view, TRAN model
Rear view
Rear view, TRAN model
Digital Inputs/Outputs 8 digital inputs can monitor status or count pulses from external “volts free ” dry contact
4 solid state output ports and 3 on-board relays can be controlled automatically by internal setpoints or manually via a communications port
Analog Inputs/Outputs Either meter can be equipped with an optional analog I/O card featuring:
8 digital inputs 4 analog inputs accepting 0 to 1mA or 0 to 20mA (scalable from 4 to 20mA) 4 analog outputs accepting -1 to 1mA or 0 to 20mA (scalable from 4 to 20mA) 4 analog inputs accepting 0 to 20mA and 4 analog output accepting 0 to 20mA 4 analog inputs accepting accepting 0 to 1mA and 4 analog outputs accepting -1 to 1mA
Contact Power Measurement for I/O combinations supported.
T h e Po Po w e r o f I O N The meters are based on our patented object-oriented ION technology,, which ensures the longevity of your technology metering solution because it can adapt as your needs change and lets you take advantage of our ongoing advances in technology.
®
The measurements and other functions of both meters are provided by ION modules. You can quickly add or rearrange functions with drag-and-drop icons and a few clicks of a mouse. Imagine new features and build them with ION.
Mounting The meters can be panel-mounted in a single DIN standard 186mm x 186mm cutout.
Bezel size: 192mm x 192mm (DIN)
A distance of 160mm (6 1 / 2 inches) clearance is required behind the panel (plus allowance for connectors and cables)
An adapter plate is available to facilitate the conversion from our 3000 series meters to the ION 7550 and ION 7650 meters. Please contact us for more information.
TRAN models have no integrated display and can be flush-mounted against any flat surface. * Available only on ION 7650
5
7550 | 7650 Ex a m p l e Co n n e c t i o n s
M e a s u r e m e n t S p ec e c if i f i ca c a t i o n s †
4-Wire Wye (Direct Connection)
Parameter
Accuracy ± (%reading)
Voltage (L-L) (L-N) Frequency Current (I1, I2, I3) Current (I4, I5) kW, kVAR, kVA kWh, kVARh, kVAh KW, KVA Demands Power Factor (at Unity PF) Harmonics (to 40th)# Harmonics (to 63rd) K Factor Crest Factor Symmetrical Components#
1 second 0.1% ±0.005Hz 0.1% 0.4% class 0.2* class 0.2* class 0.2* 0.2% IEC 61000-4-7 1% Full Scale 5% Full Scale 1% Full Scale Voltage: 0.2% FS**, Current: 0.4% FS**
† Refer to User's Manual for valid measurement ranges
NOTE: Fuse is required if power is supplied from an ungrounded
3-Wire Delta (2 PTs and 2 CTs)
* Refer to Compliance section on page 7 # ION ION 7650 only
Not applicable for NICT meters, contact factory for measurement specifications
** FS = Full Scale
Display resolution meets or exceeds accuracy.
U s er e r P r o g r a m m a b l e L o g Ca C a p a c iti t y - Example Configurations: ION 7550
DataA Waveforms
500 Events 1.5 years 180B
ION 7650
500 Events 3.1 years 180B
A 16 parameters recorded every 15 minutes B 30 waveforms on 6 channels at the maximum sampling rate
Specifications
500 Events 1.3 years 360C
C 30 waveforms on 12 channels with any selectable format (for example, 6 channels are 512 samples per cycle for 4 cycles and 6 channels are 32 samples per cycle for 54 cycles)
NOTE: Fuse is required if power is supplied from an ungrounded
Connections Installation 4-Wire Wye, 3-Wire Wye, 3-Wire Delta, Direct Delta and single phase systems 4 voltage and 5 current inputs All inputs pass ANSI/IEEE C37.90-1989 surge withstand and fast transient tests Voltage and Current Inputs Autoranging 57V through 347V LN/600V LL inputs No PTs needed for Wye systems up to 347/600VAC Standard 5 to 20A current inputs Optional 1A current inputs Low voltage current probe option
6
Control Power The meters ’ standard power supply has a voltage range of 85 to 240VAC and 110 to 330VDC, and can be powered from a dedicated fused feed. An optional low voltage DC power supply with a 20 to 60VDC range is also available.
Inputs: V1, V2, V3, V4, VREF Rated input: 347 LN/600 LL VAC RMS Overload: 1500VAC RMS continuous Dielectric withstand: 2500VAC RMS, 60Hz for 1 minute Impedance: 5M Ω /phase (phase-Vref) Fault capture: 1200 Vpeak
- Starting current: 0.001A RMS - Fault capture: 17.5A (instantaneous) peak - Max. voltage: 600V RMS (CAT III IEC61010-1) - Overload: 50A RMS for 1 second, non-recurring - Dielectric withstand: 2500VAC, 60Hz for 1 minute - Burden: 0.015VA per phase (at 1A)
Current Inputs Inputs: I1, I2, I3, I4, I5 Stand andard ard Current Current Transformer Transformers: s:
Standard Current Curren t Range: Range: - Rated nominal: 5A, 10A, and/or 20A (ANSI current class 2 & 10) - Starting current: 0.005A RMS
- Impedance: 0.015 Ω Currentt Probe Curren Probes with AC Voltag Voltagee Output Output
Rated inputs: 1V RMS
Overload: 5.5V (CAT I IEC 61010-1)
Impedance: 220k Ω max. 2 options:
- Current Probe Inputs for use with 0-1 VAC current probes. Probes sold separately. Accuracy depends on probe specs
- Fault capture: 70A (instantaneous) peak - Max. voltage: 600V RMS (CAT III IEC61010-1) - Overload: 500A RMS for 1 second, non-recurring
- Current Probe Inputs with 3 calibrated Universal Technic Tech nic 10A clamp-on CTs, meeting IEC 61036 accuracy
- Dielectric withstand: 2500VAC, 60Hz for 1 minute - Burden: 0.05VA per phase (at 5A) - Impedance: 0.002 Ω/ phase (phase-Vref)
Optional Op tional Current Current Range: - Rated nominal: 1A, 2A, 5A, and/or 10A (ANSI current class 10 & 20)
Voltage Inputs
500 Events 2.9 years 360C
Digital Inputs
8 Inputs: S1-S8, SCOM Self-excited, dry contact sensing, no external voltage required
Minimum pulse width: 1ms
Maximum pulse rate: 20 pulses/sec. Timing resolution: 1ms
Update rate‡ : 1/2 cycle (after timing resolution)
Isolation: 300Vpeak for 10s, 60Hz Max rated voltage 120VDC (external excitation)
Electromechanical Electromechanic al Relays
Communications
3 Form C relays: R1 - R3 Form C contacts: NO, K, NC
Serial Ports
1 RS-232/485 and 1 additional RS-485 port
NO, K and NC are abbreviations for "Normally Open," "Common," and "Normally Closed" - they correspond to terminals R11, R12, and R13 respectively on r elay #1.
Protocols: ION, DNP 3.0, Modbus RTU, GPS, EtherGate, ModemGate, Modbus Master Baud rate: RS-232 - 300bps to 115,200bps Baud rate: RS-485 - 300bps to 57,600bps
Standards Compliance Accuracy
Independent Compliance with IEC62053-22 0.2S, 1A and 5A tested by KEMA*
Complies with ANSI C12.20, Class 10 & Class 20 Complies with Measurement Canada AE-1021*
Rated voltage: 250VAC / 30VDC
Rated load at rated voltage:
ANSI Type 2 Optical Port
- Resistive: 10A AC/DC
- Inductiv Inductive: e: 7.5A (AC, PF = 0.4) / 5A (DC, L/R = 7ms)
Interface: ANSI Type 2 Optical Port Baud rates: 1200-19,200bps
Max. voltage: 380VAC / 125VDC
Duplex: Half
MOV protection: 300V max between NO and NC
Protocols: ION 2.0, Modbus RTU, DNP 3.0
Products meet or exceed the accuracy requirements of the standards listed. All products tested internally by Power Measurement. Some products tested by third-party laboratory. Due to form factor of some meters, not all ANSI/IEC compliance tests may apply. Contact Power Measurement for further clarification.
Max. load at max. voltage: 0.2A (DC) / 3A (AC)
Location: Front of Meter
Safety/Construction
Turn-on time: 15ms max.
Internal Modem
Turn-off Turnoff time: 5ms max.
Isolation: 5,000VAC for 1 minute
Data rate: 300bps - 33.6kbps (V (V.3.4, .3.4, V.32 bis, V.32, V.22 bis, V.22 A/B, V.23, V.21, Bell 212A, Bell 103)
Lifetime:
Automatic data rate detection is supported
- 10,000,000 operations (no load)
Error correction: V.42 LAPM, MNP 2-4, MNP 10
- 100,000 operations (rated voltage and load)
Data compression: V.42 bis/MNP 5
Update rate‡: 1/2 cycle or 1 second
Interface: RJ11 (tip and ring)
Governmental approvals: FCC P68 (USA), Industry Canada CS-03, CTR21 (Austria, Belgium, Denmark, Finland, France, Germany, Greece, Iceland, Ireland, Italy, Luxembourg, Netherlands, Norway, Portugal, Spain, Sweden, Switzerland, UK)
Solid State Outputs
4 Form A outputs: D1-D4
Maximum voltage: 30VDC Maximum current: 80mA
Isolation: Optically isolated. Max. 5000V RMS isolation (UL:E64380) Update rate: 1/2 cycle or 1 second
Ethernet Port
Protocols: TCP/IP, Telnet, ION, Modbus TCP, DNP 3.0
Interface: IEEE 802.3-1993, ISO/IEC 8802-3:1993 (Ethernet) 10Base-T or 10Base-FL (optional)
10Base-T:
Analog Outputs (optional)
Outputs: 4: AO1 - AO4
Signal type: DC current
Range: 0-20mA (scalable 4-20) or -1-1mA (scalable 0-1) Driving capability: 500 Ohms (20mA) or 10k Ohms (1mA)
Accuracy: +/-0.2% of full scale
Update rate‡: 1/2 cycle or 1 second Isolation: 750V to earth
Analog Inputs (optional)
Inputs: 4: AI 1 to AI 4
Signal type: DC Current Range: 0 to 20mA (scalable 4 to 20), or 0 to 1mA
Input impedance impedance:: 24 Ohms (20mA), (20mA), or 475 Ohms (1mA)
Accuracy: +/-0.2% of full scale Update rate: 1 second
Isolation: 750V to earth
Common mode: Max. 400k Ohms (channel to channel)
Power Supply
Standard: AC: 85 to 240VAC (+/-10%), 47 to 63Hz; DC: 110 to 300VDC (+/-10%) Burden: Typical 15VA, Max 35VA
Optional: Low Voltage DC Power Supply Optional: Rated inputs: DC: 20 to 60VDC (+/- 10%) Burden: Typical 12VA, Max 18VA
Dielectric withstand: 2000VAC RMS, 60Hz for 1 min. Ride-through: Min: 100ms (6 cycles at 60Hz at 96VAC), 200ms (12 cycles at 60Hz at 120VAC), 800ms (48 cycles at 60Hz at 240VAC)
- Cabling: Unshielded twisted pair cable, 0.5mm (24 AWG), max. length 110yds (100m) - Connector: RJ45
- Isolation: Transformer isolated, min. isolation voltage: 1500VAC RMS/2250VDC 10Base-FL: - Cabling: Fiber optic cable, 62.5/125um nominal, wavelength 850nm, max. length 2190yds (2000m) - Connector: ST (male) - Isolation: Optical
Environmental Conditions Operating temp: -20°C to +70°C (no formation of ice) (-4°F to 158°F) Low Voltage DC Power Supply: -20°C to 50°C (-4°F 122°F) Storage: -40°C to +85°C (-40°F to 185°F) Humidity: 5% to 95% non-condensing Shipping 7.1 lbs / 3.2 kg 17 x 10 x 11 inches (0.98 cu. ft.) 40.8 x 24 x 27.9 cm (0.0235 cu. m)
IEC1010-1 (EN61010-1) Safety requirements for electrical equipment for measurement, control and laboratory use
CSA C22.2 No 1010-1 Safety requirements for electrical equipment for measurement, control and laboratory use Canadian Standards Association
UL 61010B-1 Measuring, Testing and Signal Generation Equipment
Electromagnetic Electromagnet ic Immunity
IEEE C.37-90.1-1989 IEEE Standard Surge Withstand Capability (SWC) Tests for Protective Relays and Relay Systems (ANSI) (All inputs except for the network communication port) IEC1000-4-2 (EN61000-4-2/IEC801-2) Electrostatic Discharge
IEC1000-4-3 (EN61000-4-3/IEC801-3) Radiated EM Field Immunity
IEC1000-4-4 (EN61000-4-4/IEC801-4) Electric Fast Transient
IEC1000-4-5 (EN61000-4-5/IEC801-5) Surge Immunity
IEC1000-4-6 (EN61000-4-6/IEC801-6) Conducted Immunity IEC1000-3-2 (EN61000-3-2) Limits for harmonic currents emissions (equipment input current < 16 amps per phase)
IEC1000-3-3 (EN61000-3-3) Limitation of voltage fluctuations and flicker in low voltage supply systems for equipment with rated current < 16 amps
EN50082-2 Electromagnetic Compatibility, immunity standards for industrial environment
Electromagnetic Electromagnet ic Emissions
FCC Part 15 Subpart B, Class A Digital Device, Radiated Emissions
EN55011 (CISPR 11) Radiated/Conducted Emissions for industrial, scientific and medical (ISM) equipment
EN55022 (CISPR 22) Radiated/Conducted Emissions for information technology (IT) equipment
EN61000-6-4 (EN50081-2) Electromagnetic Compatibility, emissions standards for industrial environment
Display Type: FSTN Liquid Crystal Display (LCD) Resolution: 320 x 240 pixels (1/4 VGA) Temperature: Tempera ture: Operating range -20°C to +70°C (-4°F to 158°F) Backlight: LED
* Pending
7
7550 | 7650 Some features are optional. To identify standard and optional features, please see the ‘Product Order Forms’ at www.pwrm.com.
Features and Options List
ION 7550
ION IO N 76 7650 50
Power, Energy, and Demand Voltage/current per phase, average, unbalance Power: real, reactive, apparent, power factor, frequency Energy: bi-directional, total, import, export, net Demand: block, rolling block, thermal, predicted
Power Quality Sag/Swell monitoring Symmetrical components: zero, positive, negative Transient detection, microseconds† Harmonics: individual, even, odd, total up to Harmonics: magnitude, phase and inter-harmonics Sampling rate, maximum samples per cycle Flicker, (harmonics to EN50160, IEC 6100-4-7/4-15) Configurable for IEEE 519 - 1992, IEEE159, SEMI Uptime in number of nines
63rd 256
17 63rd 40th 1024
Logging and Recording Standard memor y capacity Maximum optional memory capacity Min/max logging for any parameter Historical logs, maximum # of channels Waveform logs, maximum # of cycles Timestamp resolution in seconds Historical trend information via front panel display GPS time synchronization
5MB 10MB
5MB 10MB
800 96 0.001
800 96 0.001
1 1 1 1 1
1 1 1 1 1
4 4 16 4 3
4 4 16 4 3
M e e t t h e W o r l d L ea ea d e r Power Measurement is the leading provider of enterprise energy management systems for energy suppliers and consumers worldwide. Our ION ® web-ready software and intelligent intelli gent electronic electronic devices devices comprise compris e a complete, real-time information and control network that supports billing for complex energy contracts and helps improve power quality, reduce energy costs and keep operations running enterprise-wide, 24 hours a day. Our reputation for unparalleled value, quality and service is based on over two decades of innovation and experience.
Worldwide Headquarters 2195 Keating Cross Rd. Saanichton, BC, Canada V8M 2A5 Tel:l: 1-250-652-7100 Fax: 1-250-652-0411 Te email:
[email protected] Europe Schulstrasse 6 91320 Ebermannstadt, Germany Tel.l. +49 (0) 9194-724 765 Te Fax +49 (0) 9194-724 766 email:
[email protected]
Communications and I/O RS-232/485 ports RS-485 ports Ethernet ports ANSI Type 2 Infrared optical port Internal modem 3-port DNP 3.0 through serial, modem, Ethernet and I/R ports Modbus RTU slave on serial, modem and I/R ports Modbus RTU Master on serial ports Modbus TCP through Ethernet EtherGate, data transfer between Ethernet & RS-485 ModemGate, data transfer between internal modem & RS-485 MeterM@il, logged data and alarms via e-mail WebMeter, on board web server Analog inputs Analog outputs Digital status inputs Digital status outputs (standard) Relay outputs (standard)
Setpoints, Alarming, and Control Setpoints, minimum response time Setpoints, number of Math, logic, trig, log, linearization formulas Single & multi-condition alarms Call-out on alarms
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For the most up to date information, go to
www.pwrm.com Toll free 1-866-466-7627
USA and Canada only Revision Date: January 2006 © 2006 Power Measurement. Printed in Canada 70100-0173-02 ION, ION Enterprise, ION 7550, ION 7650, MeterM@ail, WebMeter, EtherGate, ModemGate are trademarks of Power Measurement. All other trademarks are property of their respective owners. Any reproduction or re-transmission in whole or in part of this work is expressly prohibited without the prior consent of Power Measurement. Information contained herein is subject to change without notice. Any technical assistance provided by this Power Measurement document for system design or configuration shall be deemed to be a proposal and not a recommendation. The responsibility for determining the feasibility of such proposals rests with the original purchaser and should be tested by the original purchaser.
Revenue Metering & Standards ANSI C12.16 accuracy compliant ANSI C12.20 0.2 compliant, Class 10 & 20 IEC 62053-22 0.2S compliant, 1 & 5A* IEC 62053-22 0.5S compliant 1 & 5A* Measurement Canada approved* MV-90 supported Transformer/line Loss Compensation Instrument Transformer Correction frequency,, 20us for 50 Hz line frequency † For 60 Hz line frequency
YOUR YOU R LOC LOCAL AL REPRESENTATIVE
*Certification Pending
Certificate No. 002188
CALCULO DE CARGABILIDAD EN
992481‐6700‐D‐E‐MC‐0012
TRANSFORMADORES DE MEDIDA
Fecha:
Rev. B
Setiembre 2013
Página: 10 de 10 Descripción:
S.E.EL HIERRO Y LÍNEA DE TRANSMISIÓN 220 kV
AN ANEXO 7.3: IED IED CONTROLADOR REC670
Bay Bay cont contro roll IED IED REC REC 670 670
Buyer's Guide Open Configuration 1MRK 1MRK 511 511 154-BE 154-BEN N Revision: G, Page 18
Tec h n i c al d ata
Gen er al Definitions Reference value: The specified value of an influencing factor to which are referred the characteristics of the equipment. Nominal range: The range of values of an influencing quantity (factor) within which, under specified conditions, conditions, the equipment meets the specified requirements. requirements. Operative range: The range of values of a given energizing quantity for which the equipment, under specified conditions, is able to perform its intended functions according to the specified requirements. requirements.
Energizing quantities, rated values and limits An alo g i np uts ut s Table 6: Qu an t i t y
TRM - Ene Energi rgizi z ing ng qua quanti ntitie ties, s, rate rated d value values s and and limi limits ts Rat ed v al u e
Current
Ir = 1 or 5 A
Operative range
(0.02-100) x I r
Permissive overload
4 × Ir cont. 100
Burden
×
No m i n al r an g e (0.2-40)
×
Ir
Ir for 1 s *)
< 0.25 VA at I r = 1 or 5 A
Ac voltage
U r = 110 V
Operative range
(0–340) V
Permissive overload
420 V cont.
Burden
< 0.2 VA at 220 V
Frequency
f r = 50/60 Hz
0.5–288 V
450 V 10 s < 0.1 VA at 110 V ± 5%
*)
max. 350 A for 1 s when COMBITEST test switch is included.
Tab l e 7: Qu an t i t y :
MIM - m A in in p u t m o d u l e
Input range
Rat ed v al u e:
No m i n al r an g e:
± 5, ± 10, ± 20mA
-
0-5, 0-10, 0-20, 4-20mA Input resistance
R in = 194 Ohm
Power consumption
-
each mA-board
≤ 4
W
each mA input
≤ 0.1
W
Au xi li ary DC vol tage tag e Tab l e 8: Qu an t i t y
PSM - Po w er er s up up p ly ly m od od ul ul e Rat ed v al u e
Auxiliary dc voltage, EL (input) Power consumption Auxiliary DC power power in-rush
EL = (24 - 60) V
No m i n al r an g e EL ± 20%
EL = (90 - 250) V
EL ± 20%
50 W typically
-
< 5 A during 0.1 0.1 s
-
Binary inputs and outputs Tab l e 9: Qu an t i t y
B IM - B i n ar y in in p u t mo mo d u l e Rat ed v al u e
No m i n al r an g e
Binary inputs
16
-
DC voltage, RL
RL24 (24/40) V
RL ± 20%
RL48 (48/60) V
RL ± 20%
RL110 (110/125) V
RL ± 20%
RL220 (220/250) V
RL ± 20%