FACTSFLEX Forming Future Grids

Forming Future Grids

FACTSFLEX Forming Future Grids

Forming Future Grids

MU360

Process Interface Unit

MU360 is the Process Interface Unit (PIU) with analog and binary interfaces for full switchyard modeling, control and digitalization over IEC 61850 and IEC 61869 standards & protocols such as Sampled Value (SV) and GOOSE.

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Manuals

Software

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Manuals

Software

MU360

Process Interface Unit

B105 Dual Gas GIS

Gas-Insulated Substations 245 kV, up to 63 kA, 4000 A Compatible with SF₆ or g³ gas

The B105g SF₆-free GIS is part of GRiDEA, our portfolio of solutions designed to accelerate the decarbonization of the grid. Its design is grounded in more than 50 years of field experience in SF₆ and eight years in g³ technology as insulating and switching medium. Our B105 Dual Gas GIS bay – compatible with either SF₆ or g³ gas – meets the challenges of 245 kV networks for onshore and offshore power generation and transmission, as well as energy-intensive industry applications.

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B105 Dual Gas GIS

Gas-Insulated Substations 245 kV, up to 63 kA, 4000 A Compatible with SF₆ or g³ gas

Multilin C30

Read more about Multilin C30

Static Synchronous Compensator

Provides reactive power compensation with improved operational voltage range and small footprint

GE Vernova's utility grade Static Synchronous Compensator (STATCOM) solution is a custom designed system to be installed on transmission grids. It provides grid operators with reactive power compensation and improved range of operational voltage with a faster response time and a smaller footprint than traditional SVC solutions.

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Static Synchronous Compensator

Provides reactive power compensation with improved operational voltage range and small footprint

GE Vernova's STATCOM utilizes highly dynamic VSC based compensators, which when compared to SVC solutions, provides improved range of operational voltage, with higher reactive output at lower system voltage and robust recovery support under severe system disturbances and provides a smaller footprint. Key features of STATCOM System include:

Usually connected to High Voltage (HV) grid via a step down power transformer
Always a symmetrical power rating in the inductive and capacitive operating regions
Hybrid solutions available for increased power rating including: STATCOM, plus
- Thyristor Switched Components,
- Mechanically Switched components
- or Static Var Compensator (SVC)
Reduced footprint compared to a classical SVC solution

Basic STATCOM Configuration and Main Components

GE Vernova provides an extensive portfolio of feasibility and network studies, project management skills, engineering capabilities, equipment, installation services and long term maintenance contracts, delivering an integrated and robust system providing utilities with the following competitive advantages:

Model based design

Model based design provides rapid technical responsiveness to the customer, from planning support and project execution to commissioning
Intuitive graphical interface provides fast, automatic, and error free code generation from control models, ensuring a greater level of confidence to the customer
Ease of integration to Control System software with Power System modeling tools such as PSCAD, providing the most accurate representation of system performance for planning and troubleshooting analysis
Advanced Digital Control based on open VPX offers future-proof higher control execution speed with higher controller-internal (backplane) data rates, and scale up without sacrificing speed
Supported components/technologies are the same state-of-the art used in commercial applications – with wider knowledge community, support, documentation. The physical size of VPX rack is half the size of the VME

System flexibility to ensure optimized performance

Open rack structure including unique modular valve design that facilitates a safe and clean maintenance environment, including individual access to control cards, DC capacitors and rechargeable bypass switch providing easier access and higher availability than containerized solutions
Based on large scale HVDC VSC valve design principles and standards, utilizing the most advanced MMC architecture with system redundancy through the valve, cooling system, P&C and passive optical network communication system
DC capacitor, which includes both a pressure switch and relief valve for safety, is rated 2 to 3 times more than competitive offerings, leading to much improved system performance during transient events and fault ride through capacity

Manufacturing excellence and deep domain technical expertise

Over 50 years' experience with over 380 global shunt compensation installations ranging from small industrial to large utility projects, in diverse applications and extreme environmental conditions
GE Vernova supports the entire value chain with a full range of competencies, eliminating project and logistical complexities of multiple vendor projects
Valves are produced in our state-of-the-art HVDC facility that is specifically designed for manufacturing and testing of VSC technology
All major STATCOM components are vertically integrated within advanced manufacturing facilities, certified to ISO 9001:2015 Environmental Standards, ISO 4001 and OHSAS 18001

An unrivaled DC voltage source for a better STATCOM

The function of a STATCOM system is to provide reactive compensation to the grid when it is needed most, during fault and transient conditions. GE Vernova's STATCOM solution is the only commercial solution that uses a 7mF capacitor as its DC voltage source for stabilizing the grid, nearly 2 to 3 times larger than competing solutions.

Operational Advantage of the GE Vernova STATCOM Solution

The operational advantages of this design decision can be clearly seen in the two figures below. When a three phase fault is introduced just after 0.2 seconds, the STATCOM current contribution with the larger, 7mF capacitor is nearly perfect, resuming it's steady state current profile within 25ms of fault inception.

Typical STATCOM Solution

By contrast, by modeling the performance of a typical STATCOM solution that would use a smaller, 3.5mF capacitor. The STATCOM current contribution is significantly impacted during the fault and takes nearly 4 times longer, or 100ms to recover upon fault clearing, and then goes through another 50ms of undesirable transient overshoots. Such transients, contrary to the objective of the STATCOM, produces more instability during and after the fault condition.

Using a larger capacitance provides more stored energy, delivering better fault ride through capability by delivering stable full current for a longer time duration.

GE Vernova's approach to STATCOM control systems represent the latest in design methodology by utilizing a powerful Model-Based Design approach. With this approach the STATCOM control system software is built using a core library of complex control algorithms that represents over 50 years of FACTS experience within GE Vernova, key features include:

Graphical Interface

Model Based Design utilizes a graphical interface for the design stage and translation of control models with automatic code generation for all testing and verification stages. With this approach, GE Vernova has enhanced the quality, reliability, and maintainability of the Advanced Digital Control system for STATCOMs.

Secure Remote Access

The control system can be remotely accessed via Internet using secured protocol. It allows remote monitoring (using the built-in real-time monitoring function) and fault detection including diagnostic. To fulfill modern remote control interfacing requirements, the control platform supports an extensive set of industry standard protocols including IEC® 61850, DNP3 and IEC 60870. Custom protocols can be implemented as an option.

Built-in Monitoring, Self Diagnostics & Event Logger

Extensive self diagnostic capabilities are built-in to maximize reliability, any degradation of performances or fault of components is pinpointed in real-time and can be easily replaced. When availability is at stake, the control system is configured in a dual lane redundancy concept which allows for the highest availability. A built-in event logger with automatic time stamping of 1 millisecond resolution and a synchronized transient fault recorder with up to 10µs sampling will allow for post event detailed analysis by experts.

Proven Technology

Based on commercial off-the-shelf (COTS) hardware, the control platform runs on VPX military technology and meets all the requirements of the Flexible AC Transmission System (FACTS) market. Depending on the application complexity, the control platform consists of single or multiple racks, interconnected by high speed serial fiber optic interfaces. The fiber optic interface enables the boards in different racks to communicate with each other as if they were installed in the same rack without any software change.

Project Management Approach

GE Vernova's project management approach follows a well-established set of processes and procedures that have resulted in the highest on-time delivery in the industry. GE Vernova has the people, process and rigor that customers require for the planning and execution of complex projects, including defined processes for the definition, analysis, design, implementation and post service support that is required for successful projects.

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Accessories

Test Blocks

Accessories

Test Blocks

PDP components

Delivering actionable intelligence for improved reliability and efficiency

Sales of the ILMS offering has been discontinued

PDP components

Delivering actionable intelligence for improved reliability and efficiency

Sales of the ILMS offering has been discontinued

Overview

The Multilin Intelligent Line Monitoring System is an end-to-end line monitoring solution with advanced analytics that provides actionable intelligence to distribution utilities to improve the reliability and efficiency of their networks.

Analytical Applications

Feeder visualization
Fault detection, location and analysis and maintenance prioritization (Multilin X-NET)
Dynamic line rating calculation and analysis (Multilin T-NET)

Line Sensors

Provides periodic time synchronized measurements to facilitate improved situational awareness and operations:
- Electrical current, both amplitude and phase
- Conductor surface temperature
Detects fault conditions facilitating rapid identification and notification

Sensor Network Gateway (SNG)

Acts as a communications gateway for distribution network and weather information critical for supporting advanced applications
Equipped with a GPS transceiver that synchronizes the entire system, enabling GE Vernova’s advanced analytics
Provides multiple options for communications backhaul to analytical applications providing installation flexibility

Key Benefits

Extended visibility into the distribution network
Reduced cost of ownership with GE Vernova’s sensors designed for easy installation on live networks
Designed to meet the challenges of capturing faults in both low and high impedance grounding treatments
Advanced analytical applications enabled by GE Vernova’s patented time synchronized data
Remote firmware upgrade enabling further application development and compliance with regulatory and operational requirements
Time synchronized measured data in DNP3 format

Fault Detection, Location and Analysis Application (X-NET Software)

Test Caption

The advanced analytics delivered by the X-NET application are designed to meet the challenges of capturing faults in both low and high impedance grounding treatments. The Intelligent Line Monitoring System delivers the necessary field visibility and advanced analytics to capture and report the location of ground and phase to phase faults as well as cross country faults in high impedance grounding schemes.

Fault Detection, Location & Analysis

Monitors the distribution network 24/7 for events and faults
Automatically filters events from faults based on utility defined configuration to avoid nuisance reports
Identifies fault location alerting operators visually and notifying repair crews via email and SMS messaging
Provides a cycle by cycle plot of fault activity

Maintenance Prioritization

The X-NET Software enables the utility to effectively prioritize maintenance expenditure by:

Maintaining a database of events to facilitate identification of repetitive incidences, comparison of feeder performance and definition of preventive maintenance programs
Graphically depicting outage history for each feeder section

The X-NET Application enables utilities to:

Target where to spend maintenance funds based on performance instead of age of assets
Direct field crews to feeder sections where maintenance is needed
Guide maintenance work required by the nature and frequency of feeder faults indicated by frequent re-closer activity
Categorize maintenance required based upon repetitive transients indicative of:
- The need for tree trimming
- Salt build-up
- Equipment degradation

Power Transformers Bushings

OIP technology

Oil to air transformer bushings, for the connection to the HV transmission or distribution system

36-1200 kV	52-170 kV	25-765 kV
PNO	PSO	PAO

Oil to SF₆ for the connection to the SF₆ metal enclosed bus ducts

72,5-1050 kV

POBO

Oil to oil for the connection to the HV cables

72,5-1050 kV

PCTO

RIP technology

Resin Impregnated Paper transformer bushings

24-550 kV	72,5-245 kV	24-52 kV	72,5-420 kV
PNR Oil to air application	PCTR Oil to oil application	PTFR/PTHR Oil to air transformer bushings	POBR Oil to SF₆ application

Power Generator Bushings

RIP technology

Generator High Current RIP bushing up to 30 kV-45000 A
PGFR

Wall Bushings

Gas insulated technology air to air

up to 800 kV AC & DC applications
PWS (AC solution) and PWHS (DC solution)

OIP Technology

Up to 420 kV - PWO

DC converters bushings

Hybrid technology for DC converter bushings (OIP + SF₆ up to 1,100 kV; RIP + SF₆ above 420 kV)

PHI

GIS bushings

Up to 550 kV

PABS

Technical Specifications

MULTI-SERVICE PLATFORM
	Purpose-built, modular in design with layers of redundancy
	Hot swap of all redundant components without service interruptions
	Utility hardened ensure security and dependability
	Non-blocking architecture

WIDE AREA NETWORK (WAN) OPTIONS
Optical WAN	Capacity	24Gbps
	Number of 10G Optical WAN ports	2, SFP+, (up to 80km)
	Number of 1G Optical WAN ports \| 4, SFP

NETWORK MANAGEMENT
Management	Device management	embedded Management System (eMS)
	Network management	Optional Advanced NMS
	High availability mode	1+1 protected
	Console port	USB
	Inbound / Outbound interfaces	CLI, WebUI (HTTPS), SNMPv3 *, NetConf

PERFORMANCE
	CORE Hardware protection	1+1, 20G bypass
	Processors	Dual, Dedicated separately for Data (DP) & Management (eM) plane
	Transport Protocol	MPLS-TP, RFC 5654
	Encapsulation	WAN-Interface Sublayer (WIS) (on/off)
	Quality of service	IEEE 802.1p/q with priority queues and priority scheduling
	Node transit delay	< 30 μs
Switching	Capacity	66G
	Fabric	Redundant
Backplane	Passive	Yes
Client services	TDM and Ethernet	TDM: Emulated TDM over PSN (CESoPSN,SAToP) Ethernet: E-Line, E-Tree and E-LAN Ethernet Virtual Connections, configurable max frame size (up to 12,000 bytes), 32k MAC addresses per node
Packetizer	T1/E1/CBUS TDM ports	8
Synchronization	WAN Synchronization method	SyncE
	Internal Modes	Headend with SSM, Freerun
	Accuracy	4.6ppm
	External modes	2KHz, 10MHz, 1PPS, GPS *
	Quality	SSM, ESMC *
Timing	Timing Protocols	NTP, IEEE 1588v2 (telecom and power) *
	Accuracy	1us, Grandmaster (1588v2) *
OAM	Fault Detection	LDI, 256 HW-assisted BFD per CORE
	Protection Switching	1+1: <3 ms on fiber break, ~0 ms on CORE module extraction 1:1: <16 ms on fiber break, <50 ms on CORE module extraction

SECURITY
Security	EtherWAN encryption engine	6 independent encryption engines, Optionally enabled on each WAN port *
	Encryption	AES 256
	Authentication	SHA 256
	Key distribution	Public/Private, User configurable rolling key frequency *
	Access Control	Role-based
	User Authentication	RADIUS
	Accounting	Syslog (local)
	Federal Information Processing Standard	140-2

CERTIFICATION
Industry Compliance	SAFETY, UL, EU, CSA	UL 60950-1, ETSI EN/IEC 60950-1, CAN/CSA C22.2, RCM (Australia)
	Conducted and Radiated emissions	FCC Part 15B, CISPR/EN 55022, EN 300 386, VCCI, AS/NZS CISPR 22, CNS13438, and KN 22
	Immunity	EN 55024, EN 300 386 and KN 24
	Power Substation	IEEE 1613 (no cooling fans)
	Hardening	IEEE 1613 (no cooling fans), SWC, EMI, RFI & ESD
Environmental	Operating Temperature	-20°C to + 60°C
	Storage Temperature	-40°C to +70°C, IEC60068-2
	Humidity, %RH	5 - 95%, non-condensing
	Altitude	3000m
	Earthquake	NEBS ITL GR-63-CORE Issue 4*
	RoHS	RoHS / WEEE

POWER MANAGEMENT
Power	DC	48/130 VDC (ungrounded or +ve grounded), isolated inputs, hot swappable
	AC	120/240 VAC, 50/60 Hz, hot swappable
	Redundant	Yes
	Consumption	160W, Overcurrent protection at 180W per power supply

ACCESS CARD INTERFACES
Access Card interfaces	Number of Access slots	16
	Hot swappable	Yes
	4 x GigE slots	3
	EF-4A	4 x 1G/FE fiber ports, SFP, per-port configurable native VLAN ID
	EC-4A	4 x 10/100/1000 Mbps copper ports, RJ-45, per-port configurable native VLAN ID
	GigE slots	6, using EF-4A and EC-4A units
	TDM slots	4 (16 if xTDM-8A cards are used)
	T1E1-4A	4 x T1/E1 ports, RJ-48c, G.704, G.706, G.826 E1 formats: PCM30/CAS, PCM31/CCS, Unframed
	CBUS-4A card	4x CBUS ports, RJ-48C
	xTDM-8A	8 x T1/E1 ports (G.704, G.706, G.826) or 4 x CBUS ports, RJ-48c *
	64kbps slots	10
	C3794-1A	1 x IEEE C37.94, mmf/smf, N x 64 kbps (N=1…12), SFP, LC connector
	C3794-4A	4 x IEEE C37.94, mmf/smf, N x 64 kbps (N=1…12), SFP, LC connector
	DR-1A	1 x RS-232/V.24/V.28 (up to 38.4 kbps) or 1x G.703 64 kbps codirectional
	DR-4A	4 x RS-232/V.24/V.28 (up to 38.4 kbps) or 1 x G.703 64 kbps codirectional
	G703D-4A	4 x G.703 64 kbps codirectional
	DTT-2A	2 x DTT Tx/Rx @48VDC. 130VDC, 250VDC

GridNode Microgrid Solution Functions

Control Functions

Customer Benefits Include:
Autonomous Control and Flexibility

Planned And Unplanned Islanding

Ability to transition between the Grid-connected mode and Islanded mode

Resynchronization

Ability to seamlessly transition from the Islanded mode to the Grid-connected mode

Power Exchange at POI

Ability to dispatch microgrid resources in order to manage power flow at the POI

Frequency Control

Coordinate dispatch of various DERs to control the frequency of the island and control power flow during Grid Connected Mode

Power Factor Management

Ability to dispatch microgrid resources to manage power factor at a reference point (e.g., POI)

PV Firming

Ability to provide a firm the PV output on a real time basis

Voltage and Frequency Support

Ability to dispatch microgrid resources in order to support the Voltage or Frequency of the Grid

Load Sharing

Ability to control microgrid resources to regulate feeder voltage or the voltage at a reference point on the grid

Reserve Capacity Management

Managing the reserved capacity of the microgrid to enhance remaining life of the island

Voltage Control

Coordinate dispatch of various DERs to control the voltage of the island and control power flow during Grid Connected Mode

PV Curtailment

Ability to curtail PV output to manage the power generation of the microgrid

Load Forecasting

Ability to generate a day-ahead load forecast for optimal dispatch planning

Optimization Functions

Customer Benefits Include:
Energy savings, renewables enablement, emissions reduction

Optimal Dispatch

Simplified/easy to use mode based DER optimal dispatch function
Optimization Modes: Economics, Priority, Max Time of Life and Peak Shaving
Incorporates load and renewable generation forecast
Incorporates Grid Pricing
Manages Reserve Capacity and BESS State of Charge
Ability to consider Power Export and Grid Services

Microgrid Energy Management System (MEMs)

Customer Benefits Include:
Ability to actively manage, schedule, plan, and monitor your optimal dispatch plan

Energy Optimization Platform

Optimization Modes: Economic Dispatch, Peak Shaving, Minimize Emissions, Minimize Grid, Maximize Time of Life, and Maximize Renewables
Provides a day-ahead (24hr) schedule, with 15min granularity
Incorporates load and renewable generation forecasts
Incorporates Grid Pricing
Optimizes across DERs and Loads
Manages Reserve Capacity and Battery SOC (Hard and Soft Limits)
Provides Event Based Optimization changes
Ability to compare various optimization scenarios prior to activating
Ability to consider Power Export and inclusion of grid services

Advanced Functions

Customer Benefits Include:
System Reliability

Seamless Unplanned Islanding (FLS)

Ability to perform adaptive fast load shedding to facilitate seamless unplanned islanding for reliability-centric microgrids

Market Participation

Customer Benefits Include:
Revenue Generation and Renewables Enablement

Market Participation

Ability to integrate your system into the energy markets

Services

GE Vernova's engineering and consulting services team provides a wide range of capabilities to assist you with implementing your microgrid project.

Our dedicated team of experienced engineers can provide end-to-end solutions or specific activities based on the specific project requirements. From new installations to understanding the best way to upgrade an existing system, GE Vernova’s engineering team has been trusted to analyze, design and implement modern power systems. Our broad range of services include activities such as:

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Markets Served

GE Vernova's Projects teams serve a number of different market verticals including:

Utility Transmission Substations

GE Vernova leads the North American industry in successful completion of sophisticated and critical electric transmission projects varying from 69kV to 500kv. Typical project types include:

Greenfield substations
Capacity upgrades
Bay additions
Transformer and circuit breaker change-outs
Bus reconfiguration and expansion (BAAH, Ring Bus)
SCADA and protection and control upgrades

Industrial Substations

GE Vernova's solution is specifically engineered to provide the highest reliability possible, including redundant service if required. GE Vernova has extensive design and construction experience in building new or upgrading existing industrial substations including:

Oil & Gas
LNG/Petrochemical
Metals & Mining
Steel/paper/cement

Utility Distribution Substations

GE Vernova offers a wide variety of distribution substation solutions, varying from 12kV to 69kV, that incorporate the latest GE Vernova technologies and a modular design that allows for standardization and scalability to cover small, medium and large distribution substations upgrades. Typical project types include:

Greenfield substations
Transformer and circuit breaker change-outs
SCADA and protection and control upgrades

Renewable Substations
(Wind & Solar)

GE Vernova provides Electrical Balance of Plant (EBoP) for wind and solar grid interconnect with a full line of solutions, products and services to support the development, design, installation and operations of renewable generation facilities. GE Vernova has designed and constructed nearly 10% of the wind generation connected to the North American grid.

Multi-year Upgrade Programs

GE Vernova provides multiyear programs to utilities and customers for a range of project types. A program approach is generally used for a group of projects that have a set criteria, common goals or anticipated results. For example, a customer may need to replace specific equipment or upgrade systems at multiple substations over an extended period of time. Typical project types can include:

Protection and control hardware upgrades
New or existing communications and SCADA upgrades
Replacement of specific switchyard equipment, including transformer and circuit breaker change-outs

Modular Protection and Control System

GE Vernova's Modular Protection and Control System provides a flexible and fully integrated modular solution set comprised of engineering, design, manufacturing assembly, wiring, testing and commissioning support for protection and control of power system applications. The system is built on an advanced GE Vernova product base and features seamless integration with legacy and multi-vendor devices and systems.

For more information on GE Vernova’s modular Protection and Control system, visit the Packaged Solutions webpage.

Packaged Solutions for a Wide Range of Applications

Generation

Fully integrated sub-system solutions for protection and control of generators with sizes ranging from tens of KWs to hundreds of MWs

Transmission

Pre-designed modular protection, control and automation solutions for transmission system assets such as transmission lines, bus-bars, large transformers and capacitor banks

Distribution

Expandable modular solutions for assets within a distribution substation, e.g. transformers, breakers, cap-banks, and assets outside the 'substation fence', e.g. reclosers

Power Utilization and Automation

A wide variety of modular metering, automation, industrial process protection and control solutions for commercial and industrial customers

Generator Protection and Control Solution

Leverages advanced GE Vernova protection relays
Fully integrated, tested packaged solution
High quality workmanship and accelerated delivery cycles

Advanced Bus Protection and Control Solution

Pre-designed, configurable advanced protection schemes
Bus differential protection and control package
Engineered solutions for custom transmission applications

Pre-designed Distribution Solutions

Pre-designed modular protection and control solutions for distribution applications such as feeder, transformer and breaker
Designed for indoor or outdoor applications
Library of modular designs for common distribution applications

Automation and Industrial Solutions

Customized RTU solutions for variety of applications
Supported by large host and IvED protocol libraries
Fully configured, factory tested solutions

Specialized Technology Applications

Gas Insulated Switchgear Substations

GE Vernova provides Gas Insulated Switchgear (GIS) Substations ranging from 69kV to 500kV for utilities and industrial customers with a full complement of primary and secondary equipment, services and solutions to build and retrofit electrical infrastructure. GE Vernova's compact and modular design minimizes the installation footprint.

IEC 61850 Process Bus Solution

With the unique Multilin™ HardFiber Brick solution, GE Vernova offers customers an alternative to traditional copper wired substation designs that significantly reduces installation costs. This enabling technology creates a reliable high-speed network with the ability to connect and transmit data from the substation to an Advanced Distribution Management System (ADMS) or Energy Management System (EMS). The Multilin HardFiber Brick solution complies to the IEC 61850 global industry standard

Modular Control Buildings

GE Vernova provides electric utility and industrial customers with Modular Control Buildings intended for use in transmission and distribution substations. The Modular Control Building is manufactured in a controlled environment. The panels are wired and cabled to an intertie box that accepts the field cables from the switchyard equipment. The entire building and panels are pretested at the factory and shipped to site to be set on piers or a slab foundation.

F35g

SF6-FREE: g3-Gas-Insulated Substation up to 145 kV

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F35

Gas-Insulated Substations up to 170 kV

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B105

Gas-Insulated Substations up to 245 kV

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B105 Dual Gas GIS

Gas-Insulated Substations 245 kV, up to 63 kA, 4000 A Compatible with SF6 or g³ gas

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T155 Dual Gas

Ready for future SF6 gas regulations

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T168

Gas-Insulated Substations up to 550 kV

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T210

Gas-Insulated Substations up to 800 kV

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GCB Portfolio

Equipment for Power Plants from 50 to 200 MW

FKG2S without enclosure

Generator circuit breaker for power plants from 50 to 150 MW

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FKG2S

Generator circuit breaker for power plants from 50 to 150 MW

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FKG2M

Generator circuit breaker for power plants from 100 to 200 MW

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Equipment for Power Plants from 150 to 450 MW

FKG1N without enclosure

Generator circuit breaker for power plants from 150 to 300 MW

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FKG1N

Generator circuit breaker for power plants from 200 to 300 MW

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FKG1F

Generator circuit breaker for power plants from 300 to 450 MW

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FKGA2

Generator circuit breaker for power plants from 200 to 450 MW

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