400 likes | 569 Vues
The Framework and Roadmap for Smart Grid. A Presentation by David Sorensen of WestCAMP at the September 13 th Meeting of PNCECE in Spokane. Some Background on NIST ’ s Role in Smart Grid.
E N D
The Framework and Roadmap for Smart Grid A Presentation by David Sorensen of WestCAMP at the September 13th Meeting of PNCECE in Spokane
Some Background on NIST’s Role in Smart Grid NIST has been responsible for establishing the Smart Grid Interoperability Standards, including cybersecurity (George Arnold). NIST (the National Institute of Standards and Technology)has worked closely with DOE (the Department of Energy). Input has been sought from hundreds of organizations, agencies, universities, etc. NIST has funded this activity to date.
Some Background on NIST’s Role in Smart Grid (cont.) • A Smart Grid Interoperability Panel (SGIP) is being formed to manage the standards beginning in 2013. • There are about 20 major organizations such as IEEE & NEMA that will be serving on the panel. • SGIP membership will range from ~$500 for individuals to ~25,000 for major corporations.
Some Background on NIST’s Role in Smart Grid (cont.) A Smart Grid Interoperability Standards activities have been under way for 3 years . In January of 2012, release 2.0 of the NIST Framework and Roadmap for Smart Grid Interoperability Standards was issued. The following slides outline some details of the more than 200 page framework and roadmap.
NIST Framework and Roadmap for Smart Grid Interoperability Standards, Release 2.0 Office of the National Coordinator for Smart Grid Interoperability, Engineering Laboratory in collaboration with Physical Measurement Laboratory and Information Technology Laboratory
Table of Contents • 1. Purpose and Scope ..................................... 14 • 2. Smart Grid Visions ...................................... 27 • 3. Conceptual Architectural Framework .............. 38 • 4. Standards Identified for Implementation ......... 60 • 5. Smart Grid Interoperability Panel (SGIP)........ 142 • 6. CybersecurityStrategy................................ 167 • 7. Framework for Smart Grid Interoperability Testing and Certification............................................. 177 • 8. Next Steps ............................................... 192 • 9. Appendix: List of Acronyms ........................ 199 • 10. Appendix: Specific Domain Diagrams .......... 208
Anticipated Smart Grid Benefits A modernized national electrical grid: Improves power reliability and quality Optimizes facility utilization and averts construction of backup (peak load) power plants Enhances capacity and efficiency of existing electric power networks Improves resilience to disruption Enables predictive maintenance and “self-healing” responses to system disturbances Facilitates expanded deployment of renewable energy sources Accommodates distributed power sources
Anticipated Smart Grid Benefits (cont.) Automates maintenance and operation Reduces greenhouse gas emissions by enabling electric vehicles and new power sources Reduces oil consumption by reducing the need for inefficient generation during peak usage periods Presents opportunities to improve grid security Enables transition to plug-in electric vehicles and new energy storage options Increases consumer choice Enables new products, services, and markets and consumer access to them
Driver Layer Description
Figure 3-1. Interaction of Actors in Different Smart Grid Domains through Secure Communication
For Release 2.0, a standard, specification, or guideline is evaluated on whether it: • Is well-established and widely acknowledged as important to the Smart Grid. • Is an open, stable, and mature industry-level standard developed in a consensus process from a standards development organization (SDO). • Enables the transition of the legacy power grid to the Smart Grid. • Has, or is expected to have, significant implementations, adoption, and use. • Is supported by an SDO or standards- or specification-setting organization (SSO) such as a users group to ensure that it is regularly revised and improved to meet changing requirements and that there is a strategy for continued relevance. • Is developed and adopted internationally, wherever practical. • Is integrated and harmonized, or there is a plan to integrate and harmonize it with complementing standards across the utility enterprise through the use of an industry architecture that documents key points of interoperability and interfaces. * • Enables one or more of the framework characteristics as defined by EISA or enables one or more of the six chief characteristics of the envisioned Smart Grid.† • Addresses, or is likely to address, anticipated Smart Grid requirements identified through the NIST workshops and other stakeholder engagement. ‡ • Is applicable to one of the priority areas identified by FERC o Demand Response and Consumer Energy Efficiency; o Wide Area Situational Awareness; o Electric Storage; o Electric Transportation; o Advanced Metering Infrastructure; o Distribution Grid Management; o Cybersecurity; and o Network Communications. and NIST: *Energy Independence and Security Act of 2007 [Public Law No: 110-140] Title XIII, Sec. 1305. † U.S. Department of Energy, Smart Grid System Report, July 2009. ‡ Federal Energy Regulatory Commission, Smart Grid Policy, 128 FERC ¶ 61,060 [Docket No. PL09-4-000] July 16, 2009. See http://www.ferc.gov/whats-new/comm-meet/2009/071609/E-3.pdf . Guiding Principles for Identifying Standards for Implementation For Release 2.0, a standard, specification, or guideline is evaluated on whether it: • Is well-established and widely acknowledged as important to the Smart Grid. • Is an open, stable, and mature industry-level standard developed in a consensus process from a standards development organization (SDO). • Enables the transition of the legacy power grid to the Smart Grid. • Has, or is expected to have, significant implementations, adoption, and use. • Is supported by an SDO or standards- or specification-setting organization (SSO) such as a users group to ensure that it is regularly revised and improved to meet changing requirements and that there is a strategy for continued relevance. • Is developed and adopted internationally, wherever practical. • Is integrated and harmonized, or there is a plan to integrate and harmonize it with complementing standards across the utility enterprise through the use of an industry architecture that documents key points of interoperability and interfaces.
Guiding Principles for Identifying Standards for Implementation • Enables one or more of the framework characteristics as defined by EISA or enables one or more of the six chief characteristics of the envisioned Smart Grid. • Addresses, or is likely to address, anticipated Smart Grid requirements identified through the NIST workshops and other stakeholder engagement. • Is applicable to one of the priority areas identified by FERC and NIST: o Demand Response and Consumer Energy Efficiency; o Wide Area Situational Awareness; o Electric Storage; o Electric Transportation; o Advanced Metering Infrastructure; o Distribution Grid Management; o Cybersecurity; and o Network Communications.
Focuses on the semantic understanding layer of the GWAC stack,* which has been identified as most critical to Smart Grid interoperability. • Is openly available under fair, reasonable, and non-discriminatory terms. • Has associated conformance tests or a strategy for achieving them. • Accommodates legacy implementations. • Allows for additional functionality and innovation through: o Symmetry – facilitates bidirectional flows of energy and information. o Transparency – supports a transparent and auditable chain of transactions. o Composition – facilitates building of complex interfaces from simpler ones. o Extensibility – enables adding new functions or modifying existing ones. o Loose coupling – helps to create a flexible platform that can support valid bilatera land multilateral transactions without elaborate prearrangement.** o Layered systems – separates functions, with each layer providing services to the layer above and receiving services from the layer below. o Shallow integration – does not require detailed mutual information to interact with other managed or configured components.
Smart Grid Interoperability PanelPriority Action Plan 0 Meter Upgradeability Standard 1 Role of IP in the Smart Grid 2 Wireless Communications for the Smart Grid 3 Common Price Communication Model 4 Common Schedule Communication Mechanism 5 Standard Meter Data Profiles 6 Common Semantic Model for Meter Data Tables 7 Electric Storage Interconnection Guidelines 8 CIM for Distribution Grid Management 9 Standard DR and DER Signals 10 Standard Energy Usage Information
Smart Grid Interoperability PanelPriority Action Plan (cont.) • 11 Common Object Models for Electric Transportation • 12 Mapping IEEE 1815 (DNP3) to IEC 61850 Objects • 13 Harmonization of IEEE C37.118 with IEC 61850 and Precision Time Synchronization • 14 Transmission and Distribution Power Systems Model Mapping • 15 Harmonize Power Line Carrier Standards for Appliance Communications in the Home • 16 Wind Plant Communications • 17 Facility Smart Grid Information Standard • 18 Smart Energy (SEP) Profile 1.X to 2.0 Transition • 19 Wholesale Demand Response (DR) Communication Protocol • 20 Green Button Energy Service Provider (ESPI) Evolution
To date, the Standards subgroup has produced detailed reports that contain analysis and recommendations for improvements in the following standards: Association of Edison Illuminating Companies (AEIC) Metering Guidelines; American National Standards Institute (ANSI) C12.1: American National Standard for Electric Meters Code for Electricity Metering; ANSI C12.18: : American National Standard Protocol Specification for ANSI Type 2 Optical Port; ANSI C12.19: American National Standard For Utility Industry End Device Data Tables; ANSI C12.21: American National Standard Protocol Specification for Telephone Modem Communication; ANSI C12.22: American National Standard Protocol Specification For Interfacing to Data Communication Networks; International Electrotechnical Commission (IEC) 60870-6/ Telecontrol Application Service Element (TASE).2/
Inter-Control Centre Communications Protocol (ICCP): Control Center to Control Center Information Exchanges; IEC 61850: Communications Networks and Systems for Power Utility Automation; IEC 61968: Common Information Model (CIM) and Messaging Interfaces for Distribution Management; IEC 61970: Energy Management System Application Program Interface (EMS-API) (also referred to as the “Common Information Model for Wires Models”); IEC 62351: Power Systems Management and Associated Information Exchange - Data and Communications Security, Parts 1 through 7; North American Energy Standards Board (NAESB) Energy Usage Information; National Electrical Manufacturers Association (NEMA) Upgradeability Standard (NEMA SG AMI 1-2009);
Organization for the Advancement of Structured Information Standards (OASIS) Web Services (WS)-Calendar; Role of Internet Protocol Suite (IPS) in the Smart Grid, an Internet Engineering Task Force (IETF)-proposed document; SAE J1772-TM: Society of Automotive Engineers (SAE Electric Vehicle and Plug in Hybrid Electric Vehicle Conductive Charge Coupler; SAE J2847/1: Communication between Plug-in Vehicles and the Utility Grid; SAE J2836/1: Use Cases for Communication between Plug-in Vehicles and the Utility Grid; Institute of Electrical and Electronic Engineers (IEEE) C37.238/D5.7, Draft Standard Profile for Use of IEEE Std. 1588 Precision Time Protocol in Power System Applications; International Electrotechnical Commission (IEC) 61850-90-5, Use of IEC 61850 to Transmit Synchrophasor Information According to IEEE C37.118; and IEEE 1588, IEEE Standard for a Precision Clock Synchronization Protocol for Networked Measurement and Control Systems.
Figure 3-1. Interaction of Actors in Different Smart Grid Domains through Secure Communication
The Smart Grid Interoperability Panel (SGIP) Governing Board voted on July 10, 2012 to support the new business sustainment plan for the SGIP. The plan outlines the SGIP's transition to a self-sustaining not-for-profit legal entity that will continue its partnership with the government, a move that NIST envisioned when it established the SGIP in 2009.
The decision represents a major milestone in the implementation of the Smart Grid Interoperability Framework coordinated by NIST in carrying out its responsibilities under the Energy Independence and Security Act of 2007.
"NIST supports the plan and commends the SGIP and its leadership in taking this important step forward," said George Arnold, the National Coordinator for Smart Grid Interoperability. "NIST intends to continue undiminished its engagement in the SGIP at both technical and leadership levels."
Figure 3-1. Interaction of Actors in Different Smart Grid Domains through Secure Communication
The Future The Smart Grid Program is not a 1 or 2 year activity. It will take 20 or 30 years to fully mature. As it gets implemented, we will realize new and better way to accomplish its objectives and there will continue to be significant improvement in tools, technologies and methods. We need to consider seriously what part we want to play. What are our specific strengths and weaknesses? What can we do better than many others? What are some unique needs of the program that we can specifically address? Now is the time to plan for our future participation in the Smart Grid Progarm.