Transcript data - CBIP
IRWIN BARNETO, ABB INDIA LTD., CIGRE NOV. 2013 The role of Communication systems for Smart transmission Agenda Typical power utility communication infrastructure Application requirements on communication network performance Technologies for the Utilities Core Network ,Trends Conclusion Introduction PTN & Utility Communication Networks Today… the development of telecommunication technologies is driven by the needs of public telecom operators and corporate networks. However…. The communication requirement(s) of utility networks and Public Telecom Networks (PTN) vary significantly. Typical power utility communication infrastructure Substation Control Centre Power Plant SDH/ SONET PLC Administration Wide Area Network (WAN) ISDN SDH/ SONET Regional Office DATA ISDN SHDSL Twisted pair | DATA PDH Design parameters Typical requirements for a Power Utility.. Dependability- always the highest Security- the highest possible Transmission time- the minimum possible Transmission Bandwidth- not very critical/ not very high Transmission media- Fiber/ Microwave/ PLCC/ VSAT MTBF & Availability- no compromise Design considerations 1. Environmental Consideration Electrically hostile environment, where electromagnetic interference’s are a common phenomenon Stringent EMC (Electromagnetic Compatibility) directives of IEC & EN Operating Temperature: quite extensive For example: IEC 61000-4-12 standard (damped oscillatory waves) is simulating high voltage breakers and is not executed for telecom equipments. IEC 61000-4-4 standard (fast transient test) is simulating relay contacts and is only tested with insufficient low values for telecom equipments. Application requirements Utilities mission in the focus Power utility need to reliably transmit and distribute electrical energy Various applications help the utility to ensure the reliable energy transmission and distribution Some of them are mission critical Requiring real time communication Requiring predictable and constant communication channels The utility communication network helps to achieve reliable energy transmission and distribution and accordingly it needs to fulfil the requirements defined by the applications without compromise Requirements for utility communication Application requirements 2 wire Requirement for huge variety of different interfaces Requirement for utility specific interfaces such as Teleprotection Highest requirements for communication channel availability Real time data channels for mission critical applications Channel supervision for mission critical services (e.g. Teleprotection) contact RS-232 multiplexing Ethernet IEEE C37.94 Delay times Wrong channel routing Traditional SCADA Systems are using RS232 protocol in polling mode Point-Multipoint functionality on data interfaces required Prevailing Technologies TeleProtection Electrical Telecom Cables Fibreoptic Cables / OPGW Data Communication eqpt. Speech Communication eqpt. Power Line Carrier Communication Speech TeleProtection Data Radio Prevailing Technologies Communication Media Media & Technology • PLC: Power Line Carrier • DLC: Distribution Line Carrier • Coaxial Cables and Services • Voice • FAX • X.25, Frame Relay • Pilot (copper) wire • Radio Relay Link (Micro wave) • Optical fibres • UHF / VHF Radio Technology • Satelite Wireless communication PDH, SDH, DWDM Mobile Telephony FDDI LAN: Ethernet, Token Ring Gigabit Ethernet ATM xDSL: ADSL, HDSL, VDSL • Modem • E-Mail • Video Surveillance • Video Conferencing • TeleWorking • Telemetry • Data • Scada • Tele Protection • Management SDH introduced To overcome PDH shortcomings, ITU-T defined a new transmission standard: The SDH Synchronous Digital Hierarchy to … access 2Mbit/s signals in any level of a data stream have an integrated network management channel with routing functionality in every network element standardise the complete technology including - frame formats, - multiplexing schemes - synchronisation allow bit-rates of up to 10 GBit/s in one signal Why SDH? A robust Communication Network is the key for a reliable Powergrid operation Network Management Benefits - Path management - Standard management channel Multi-vendor networks Improved protection Network simplification - Access signal from the largest Multiplexed signal Network optimisation - Distributed bandwidth management Reduced over-all cost Not a PDH replacement Increased revenues through Improved services Differentiation of service offering Survivable networks Reduced operating cost Improved network utilisation communication networks for power utilities Present situation • SDH proved its capabilities for reliable communication infrastructure with highest availability figures Real time communication supported Predictable communication channel Symmetrical delay times Low jitter/ wander Synchronous system Highest availability of data channels Redundant channel routing with fast switchover times PDH/ SDH is perfectly fitting to the real time requirements of utilities mission critical applications such as Teleprotection Packet Switched Networks Drivers Growing usage of IEC 60870-5-104 protocol Today's SCADA communication uses increasingly the IEC 608705-104 (IEC 104) ...has been published some years ago (IEC104 in 2000) established standard …is an up-to-date standardized SCADA protocol guarantees interoperability offers also spontaneous communication (instead of polling) bandwidth optimized solution requires less HW in the control centre allows to build up price optimized solution for small systems The same also applies for DNP3 over IP protocol Packet Switched Networks Drivers Additional applications trend towards Ethernet Additional Ethernet based applications Video over IP (CCTV) IT infrastructure can be used for Video surveillance Cost optimised systems Intrusion Detection System Fire Detection System Access Control System ICCP Links between Control Centres Packet Switched Networks Drivers Additional applications trend towards Ethernet Traditional substation services required a whole bunch of different type of interfaces, such as RS-232, V.11, G.703, 2/4 wire voice channels…. Due to the wide deployment of Ethernet technologies in industrial automation environment also substation applications are moving more and more towards Packet Switched solutions (Ethernet/ IP) Power Line Carrier Communication(PLCC) System (16 …) 40 kHz 100 104 108 500 kHz Line Trap (DLTC) Coupling Capacitor (CC) or Capacitor Voltage Transformer (CVT) Coupling Filter (MCD 80) Voice RTU (SCADA) Line Trap Application of PLC: Transmission of voice, data (RTU) and protection signals (from IEDs) Coupling Capacitor (CC) or Capacitor Voltage Transformer (CVT) CF Coupling Filter Voice Data Data Full duplex Protection Protection PLCC Terminal PLCC Terminal IED = Intelligent Electronic Device (i.e. digital protective relay) DPLC applications “Switching/Routing“ LAN – Coupling without external router is possible LAN 2 LAN 1 DPLC DPLC Power Line 9.6 – 256 kbps Substation A Substation B Fall-back / fall-forward supported Speed adapts to link condition Challenges for smarter grid networks Selecting the right network technology to avoid stranded assets AMI network solutions deliver sufficient capacity for meter reading – but can’t support network requirements for other smart grid applications Some utilities select an AMI network solution without considering future application and network needs Cyber security threats are real and will continue to evolve over time Selecting a network communications strategy Traditional approach Network per project Strategic approach Layered communications architecture Supports for current plus future smart grid apps Minimizes incremental spend for additional field applications Build/pay as you go SCADA AMI Distribution Automation Field data applications,… Finding the Right Balance Application Requirements Technologies Bandwidth PLCC Transmission time FIBRE- PDH/SDH Security and Dependability MICROWAVE Availability IP EMI/EMC VSAT Conclusion It is important that a utility can take the decision for the correct technology based on application requirements and communication network performance and not… … based on equipment and technology availability Migration scenarios Flexibility on technology Step by step migration General considerations Utility grade design (EMC, EMI, Temperature) No Varying Life cycles Maintenance effort © ABB Group April 13, 2015 | Slide 23