Panel Session: Experiences from Installations and Pilots Communication Technologies for Smart Grid
Smart Grid Communication Technology Internetization of the energy sector timeline energy industry Fusion or independent development? ICT industry future today SCADA & telecontrol "SCADA & telecontrol" + "IKT" IKT past SCADA & telecontrol IKT 2
Smart Grid Communication Technology Internetization of the energy sector An example for the ongoing merging of the energy - and ICT industry energy industry ICT industry Distribution System Operator (DSO) Combined heat and power unit (CHP) Internet 3
EU-Mandate m/490 History In 2010 the European Commission issued the mandate M/490 Standardization Smart Grid to the standardization bodies CEN, CENELEC and ETSI. The mandate was commissioned with the evaluation of how the Smart Grid might look like. The creation of communication technologies for smart grid was also part of the task. CEN/CENELEC/ETSI Joint Working Group Pre-Phase Smart Grid Co-ordination Group Phase 1 2011-2012 Smart Grid Co-ordination Group Phase 2 2013-2014 Formation (May 2010) JWG Report (Dez 2010) Report 2012 Report 2014 EU-Mandate M/490 (March 2011) Intermediate Report 2013 4
Objective of the mandate m/490 The objective of this mandate is to develop or update a set of consistent standards within a common European framework that integrating a variety of digital computing and communication technologies and electrical architectures, and associated processes and services, that will achieve interoperability and will enable or facilitate the implementation in Europe of the different high level Smart Grid services and functionalities as defined by the Smart Grid Task Force that will be flexible enough to accommodate future developments. Building, Industry, Appliances and Home automation are out of the scope of this mandate; however, their interfaces with the Smart Grid and related services have to be treated under this mandate 5
Scope of the mandate m/490 1. A technical reference architecture, which will represent the functional information data flows between the main domains and integrate many systems and subsystem architectures. 2. A set of consistent standards, which will support the information exchange (communication protocols and data models) and the integration of all users into the electric system operation. 3. Sustainable standardization processes and collaborative tools to enable stakeholder interactions, to improve the two above and adapt them to new requirements based on gap analysis, while ensuring the fit to high level system constraints such as interoperability, security and privacy, etc. and to collect and harmonize use cases 6
Structure of phase 1 (2011-2012) 7
Working groups of phase 1 First Set of Standards (WG FSS) general method for presenting Smart Grid Standards for the European Smart Grid list of (existing) Standards to start with the European Smart Grid Sustainable Processes (WG SP) analysis and harmonization of use cases establishment of a use case management process Reference Architecture (WG RA) Smart Grid Conceptual Model Smart Grid Architecture Model (SGAM) Information Security (WG IS)... and the Smart Grid information and communication system should be inherently secure by design... 8
Structure of phase 2 (2013-2014) 9
Working groups of phase 2 Set of Standards (WG STD) continuation of WG FSS New Applications and Methodology (WG METH) merger of WG Reference Architecture and WG Sustainable Processes Interoperability (WG INT) new Working Group Information Security (WG IS) continuation of WG IS 10
Reports Phase 1 (2011-2012) (Framework Document) A Set of Consistent Standards Sustainable Standardization Processes Smart Grid Reference Architecture (Smart Grid Information Security) Annex F: Communication Architecture Phase 2 (2013-2014) Extended Set of Standards (support Smart Grid deployment) Overview Methodology and its annexes: General Market Model Development, Smart Grid Architecture Model User Manual and Flexibility Management Smart Grid Interoperability and its tool Smart Grid Information Security 11
Annex f: communication architecture Content of the Annex F document communication standards for the Smart Grid generic use cases and related communication architecture examples description of selected communication profiles for the Smart Grid communication communication architecture topologies for the Smart Grid security 12
Annex f: communication architecture An example: IP layered architecture CEN-CENELEC-ETSI Smart Grid Coordination Group (SG-CG) Smart Grid Reference Architecture Annex F, Communication Architecture Brüssel, 2013 13
Open Systems for Energy Services (OS4Es) Project description OS4ES is a EU-founded research project for the development of a cloud-based energy management system. Based on the experience of the participation in the CEN-CENELEC-ETSI Smart Grid Coordination Group (SG-CG), a consortium of nine partners started the project. The partners are from the fields research, engineering, power economy and ICT. It will develop and prototype a generic, nondiscriminatory, multivendor-capability ICTplatform for easy cross-linking of smart grid entities. It perceives no active market role, but supports market role owners with an easy to use middleware for bi-directional energy communication. 14
Open Systems for Energy Services (OS4Es) Visit OS4ES project presentation on the IEEE SmartGridComm 2015 S1-6: Communication and Network Technologies in Smart Grid Day: Thursday, 5. November Time: 11:40 a.m. This project has received funding from the European Union s Seventh Framework Programme for research, technological development and demonstration under grant agreement no. 619302 15
Thank you for your attention Dr.-Ing. Jörg Benze Test und Integration Center (TIC) Tel.: +49 351 2820 2296 Fax: +49 351 2820 4296 E-Mail: joerg.benze@t-systems.com T-Systems Multimedia Solutions GmbH Riesaer Straße 5 D-01129 Dresden (Germany) Web: www.t-systems-mms.com board memberships Standardization E-Energy / Smart Grids DKE 1911.11 Smart Grid Security Smart Grid Coordination Group 16