Secure and reliable electricity network operation

Power Transmission and Distribution Energy Automation Secure and reliable electricity network operation Siemens AG, PTD SE PT, 2006

The electrical network from source-to-sink Generation Transport Distribution Loads Page 2

Changing energy market environment kwh Distribution company Transmission company Generation company Business processes Subsidiary Trader Communication Local generation Service provider Power exchange Change of energy market environment, e.g. industry restructuring, competition Business process optimization, e.g. new communication channels, Web Pressure on prices and cost together with the trend to more automation Increased value of information, especially with regard to real-time information Stronger customer focus Technology innovation Page 3

Focus of an innovative energy management Quality of supply Minimum interruptions & high product quality Comprehensive network monitoring Automation Quality management On-line network security analysis Sufficient reserve scheduling for power plants Customer satisfaction Good offerings (Product, Quantity, Quality, Price, Services) Outage management Optimal Load Management Network analyses and optimization Single Point of entry for multiple resources Economy & efficiency Low costs & sustainable profit Network automation Optimal energy production and trading balance Mobile operation Optimized operation (Workflow, ) Efficient IT integration and usage Optimal Total Cost of Ownership Page 4

Workflow from day-ahead preparation to settlement Day -Ahead -Actions Forecast demand Forecast market price Planning of maximum profit Deal Entry Financial and Risk Checks Fix Generation Schedules Intraday -Actions Day -Before -Actions Intraday Market participation Control delivery of net power and ancillary Monitor obligatory or agreed reserves Emergency counter measures Archive Schedules & Delivery Values Perform settlement calculation Day- Ahead- Actions Intraday-Actions Day-Before-Actions Forecast demand Buy (allocate) reserves Control energy balance Emergency counter measures Intraday Market participation Archive Schedules & Delivery Values Perform settlement calculation Page 5

Modular component architecture UI Domain Web Infrastructure Control Center Desktops Decentralized Desktops System Management Data Management Application Domain Load Forecast & Archive Management Scheduling... E/G/W/DH Applications Distribution & Transmission Network Analysis Real-Time Domain Data Management Domain Base System Domain Communication Domain System Services SCADA- Functionality Data Model (CIM based) Configuration Parameter (HW / SW) OPC Interface Automation Technology Process Interface IEC, DNP, 61850,... ICCP CIM DNP ICCP Common Information Model Distributed Network Protocol Inter-control Center Communications Protocol OPC OLE SCADA OLE for Process Control Object Linking and Embedding Supervisory Control and Data Acquisition Page 6

Application portfolio and addressed market segments ET RM ES Energy Trading Risk Management Energy Sales, Customer Management Trading Generation ES ET SA PA RM ITS DW HFD ITS Interchange Transaction SA Scheduling Applications PA Power Applications TNA Transmission Network Applications DTS Dispatcher Training Simulator SCADA CFE UI BS FA DTS CA SCADA SDM Tools TNA MS DNA VVC OMS CMS OFR NTLO Transmission TCS CFE CA SCADA MS Distribution FISR DNA VVC FISR OMS CMS TCS OFR NTLO BS SDM UI DW HFD FA Communication Front-End Communication Apps Supervisory Control Multi-site Base System Source Data Management User Interface Data Warehouse Historical and Future Data Forecast Applications Distribution Network Application Volt/Var Control Fault Isolation/System Restoration Outage Management Crew Management System Trouble Call System Optimal Feeder Reconfiguration Non-Technical Losses Page 7

Supervisory Control and Data Acquisition (SCADA) External Communication SCADA Wireless Alarming RTU, ICCP, ELCOM 90, OPC Applications Historical Information System Energy Accounting Alarming Telecontrol Monitoring Page 8

Power Transmission and Distribution Power Transmission and Distribution Supervisory Control and Data Acquisition (SCADA) Functions Control Device operations Data Acquisition Event & Alarm Processing Limit Monitoring of analog and counter values (8 limits) Interlocks Processing Real-time Data Calculations Marking & Tagging Real-time Accumulator Processing (RAP) Switching Control Procedure Execution Source Value Topology Management Selection Monitoring Processing (SPM) Supervisory Control Page 9

Transmission services Transmission Grid Analysis Applications Dispatcher Power Flow State Estimator Network Parameter Adaptation Security Analysis Outage Scheduler Security Analysis Lookahead Fault Calculations Transmission Network Sensitivity Grid Optimisation Applications Optimal Power Flow Voltage Scheduler Security Constrained Economic Dispatch Page 10

Distribution Services Distribution Management System (DMS) Page 11

Generation Services Control Area Power Applications Load Frequency Control Generation Area Production Cost Monitoring Consumers Consumers Consumers Schedules Consumers Consumers Generating Units Schedules Consumers Consumers Consumers Economic Dispatch Reserve Monitoring Page 12

Generation Services Load forecast functions Power Transmission and and Distribution Page 13

Generation Services Planning and Trading Horizons Power Transmission and and Distribution stochastic 5-20 years 1-5 years 1-2 years Expansion Planning Long-Term Planning Long-Term Bilateral Trading Maintenance Scheduling Resource Optimization deterministic Short-Term Day-Ahead 1-7 days Planning Trading Real-Time 1-15 minutes Dispatch Trading online Control Hydro Thermal Coordination Trade Optimizing Scheduler Short-Term Trade Evaluation Economic Dispatch Automatic Generation Control Page 14

Multiple Energy Resource Optimization (MERO) Example of a German utility Primary Resources Coal Gas Oil Boiler Waste heat Boiler Heating 40-100 [t/h] Steam turbine HP: 30-60 [t/h] LP 4-8 [t/h] 10-75 [MW] Gas turbine Generator ~ 3-6 [MW] ~ 5-25 [MW] 15-25 [MW] Secondary Resources Electricity Gas Electricity Potable Water 45-100 [MW] House load Water pumps District Heating Potable Water Page 15

Energy automation system services System management functions: Start-up and Shutdown functions Redundancy and System Recovery functions Backup & Restore functions User Administration and Security Project Data Management functions License Management functions Diagnosis functions Page 16

Communication Solutions Communications Front End (CFE) Base Functions Data Acquisition Data Preprocessing Time Processing Error Messages and Quality Flags Start-up Procedure Line-Level Redundancy Listening Mode Connection of Data Concentrator Page 17

Communication Components Spectrum PowerCC (SCADA, Applications) DDS CFE DDS ELCOM ICCP OPC RTU Communication Front End Data Distribution Service ELectricity utilities COMmunication Inter-control Center Communication Protocol OLE for Process Control Remote Terminal Unit DDS CFE DDS OPC DDS ICCP ELCOM From/to other CCs Different Telecontrol Protocols IEC 101, 104 SINAUT8-FW, others Gateway-Solutions SICAM PAS, Advanced RTU Automation protocols (SIMATIC NET via TCP/IP for long distance, Profibus only for short distance) Other Protocols Parallel Interface to Process Profibus Station bus Telecontrol: RTUs Industry Automation: SIMATIC S5, -S7 Station equipment: Protection,... Substation Process: Switch Gear, Infrastructure, Protection,... Page 18

Communications Front End (CFE) Spectrum PowerCC Communication Example Power System Object Server (PSOS) Real Time Server UI Client Spectrum PowerCC LAN Communications Front-End 1 (CFE 1) Communications Front-End 2 (CFE 2) Router Real-Time Data LAN to RTU to RTU Router to RTU to RTU RTU WAN RTU Configuration with 2 redundant CFE subsystems and different RTU interface connections Page 19

Communication Services Protocols Power Transmission and and Distribution Communication Protocols (Standard) IEC 60870-5-101 (Master) IEC 60870-5-104 (Master) DNP 3.0 / DNP 3.0i CDC Type II Siemens SINAUT 8FW L&G TG 800 L&G TG 8979 L&G TG 065 IEC 61850 IEC 60870-5-103 INDACTIC 35 Modbus L&G TG 6000 RP 570/571 Communication Protocols (Project-specific) Conitel 2020 INDACTIC 33 Siemens FW 535 SEAB-1F Page 20

Elcom Interface (ELC) Spectrum PowerCC ELCOM (ELectricity( utilities COMmunication), an Open and Standardized Protocol for Process Data Exchange between remote control centers (ELCOM as introduced standard in more Nordic countries) Highlights Internationally accepted de facto standard for inter control center communication services Real time data exchange Multi vendor supported Page 21

Protocols ELCOM-90 (Electricity utilities communication) (IEC 870-6 TASE.1) ISO layer model: Application layer: ELCOM-90 Presentation layer: ELCOM-90 Session layer: empty Transport layer: TCP Network layer: IP Link/physical layer e.g.: IEEE 802.2 / IEEE 802.3, Ethernet, Token Ring, X.25, ATM, Frame Relay Page 22

Protocols ICCP (Inter-control Centre Communication Protocol) (IEC 870-6 TASE.2) Open and Internationally Standardized Protocol for Inter Control Centre Communication with real-time data exchange ICCP Data Exchange Spectrum Spectrum PowerCC PowerCC (Local (Local Control Control Center) Center) Spectrum Spectrum PowerCC PowerCC (Remote (Remote Control Control Center) Center) Other Other Utilities Utilities (Non-Siemens (Non-Siemens System) System) WAN (or permanent lines) Non-utility Non-utility Generators Generators Power Power Pools Pools Regional Regional Control Control Centers Centers Page 23

OPC - The universal and flexible Interface Client / Server Architecture OPC-Client Communication Device Application OPC-Interface COM/ DCOM (external via TCP/IP) OPC-Interface Device specific Protocol Communication Device OPC-Server Page 24

Benefits of communication standards Communication standards to ensure interoperability, efficient engineering, commissioning and secure operation IEC 61970 EMS Server IEC 61968 DMS Control Centre 1 IEC 62210 Substation PU EC, EDI ISO 9735 IEC 62195 TR IEC 60870-5-101, -104, IEC 60870-6 (TASE.2), IEEE P1525, ELCOM 90, DNP3 IEC 60870-5-101, IEC 60870-5-104, IEEE P1525, DNP3 IEC 61850 IEEE P1525 IEC 60870-5 DNP3 Pole-Top Market Participant IEC 60870-6 (TASE.2), ELCOM 90, DNP3, IEC 60870-5-101, -104 PU IEC 61107 IEC 62056 IEC 60870-5-102 Control Centre 2 IEC 60870-5-101, -104, IEC 60870-6 (TASE.2), ELCOM 90, DNP3 Metering Billing Pow er Plant PV Plant influencable loads/ DSM solutions Substation 1 IEC 61850 IEC 61850 IEC 61850 IEC 61850 Market Participant Energy Management Control System Centre IEC 61850 IEC 61850 IEC 61850 IEC 61850 communication grid Substation 2 IEC 61850 IEC 61850 IEC 61850 (IEC 61400-25) IEC 61850 G Pow er Plant CHP Wind Plant Pole-Top Metering CT CT VT VT Billing (IEC 60834, IEEE 1565) Substation Current communication standards IEC 61850 Goal for future communication - Use of different physical and link layers Page 25

Specific Mapping SCSM 1 IEC 61850 and its mapping opportunities IEC 61850 is the up to date, world wide accepted communication standard Mapping the data model and the services to different ISO/OSI layers Application ACSI SCSM 2 Application layer 7 Abstract Interface SCSM n Physical, Data Link, Network, Transport, Session, Presentation Layer 1-6 Key features of the standard: 1. Separation of data and communication technology - keep the information (application) free from any information exchange method and communication network 2. Communication stacks may be exchanged following the state of the art in communication technology - one specific mapping defined to MMS and Ethernet TCP/IP - generally the standard is open for other transmission media like PLC or radio transmission communication stacks 3. Information models can be easily extended - further extension planned i.e. for wind power plants, distributed power stations, and water power stations Page 26

IT integration concept Page 27

Information Model Management Graphic Designer & Auto Display Builder Power Transmission and and Distribution Fully integrated and extended WinCC Graphics Designer MS Windows look and feel World map concept with a 32 layer drawing pane for vector-oriented display design Station C Station D layer 1 network level Station A zooming Station B Station A layer 2 subnetwork level zooming Station B 110kV layer 3 station level zooming zooming 0A 230A Transformer 1 Transformer 2 Transformer 110kV/20kV Next inspection 06.09.1993 Station Station B A Transformer 1 1 layer 4 feeder level Page 28

Spectrum PowerCC Base System Power Transmission and and Distribution Typical redundant Spectrum PowerCC System Configuration - UI Client Workplaces - UI Client Workplaces Redundant LAN -PSOS -AAS 2m * Remote Workplace -Web UI -Web TS -UI client PSTN 2m PSOS/AAS Server RTS Server -RTS CS Server -CFE CS Server -CFE * Remote Workplace -Web UI CS RTS CFE AAS PSOS UI-Client TS Communication System Real-time (SCADA) Processing Communication Front End Advanced Application Server e.g. HIS Archive Real Time Database Operator Workstation Terminal Server Page 29

Application Socket Concept of integrated Applications IEC 61970 / 61968 supports the use of components from different vendors The traditional Plug-Compatibility as Key for IT-Integration in Utilities Power Transmission and and Distribution CIM-based Data Model Comm. Inf. Model Manager Training Simulator Spectrum PowerCC Trouble Call Mgmt. Customer Care IEM Integration Bus = Middleware + Meta Data Model IEM Archive GIS Workforce Management Outage Mgmt. IEM Information Exchange Model Page 30

Discussion I would like to invite you to a discussion about Requirements and Deficits and Trends Page 31

Different Levels of security mechanism Control Centre Level Control Centre Protection and Interlocking Substation 1 Substation 2 Station Level Field Level Device Level Page 32