SMART GRID INTEROPERABILITY PANEL WINTER 2012 FACE-TO-FACE IRVING, TEXAS  DEC. 3-6, 2012 T&D DEWG Webconference December 3, 2012.

Slides:



Advertisements
Similar presentations
NAESB Smart Grid Task Force PAP 03 Update Robert B. Burke – NAESB Task Force Co-Chair Jim Northey.
Advertisements

Demand Response: The Challenges of Integration in a Total Resource Plan Demand Response: The Challenges of Integration in a Total Resource Plan Howard.
Impact of Smart Grid, ICT on Environment and Climate Change David Su Advanced Network Technologies National Institute of Standards and Technology ITU Symposium.
Planning, optimization and regulatory issues
The future Role of VPPs in Europe Pan European Balancing Market: EU-FP7-Project eBadge Workshop on DSM Potentials, Implementations and Experiences 20 th.
Development and Operation of Active Distribution Networks: Results of CIGRE C6.11 Working Group (Paper 0311) Dr Samuel Jupe (Parsons Brinckerhoff) UK Member.
Dynamic Distribution Grids © 2012 San Diego Gas & Electric Company. All trademarks belong to their respective owners. All rights reserved. Neal Bartek.
AMI & Grid Data Analytics & Analysis Management Platform Page  1 What does this platform offer? Our tool is a next generation grid management software.
Reliability Software1 Reliability Software Minimum requirements & Best practices Frank Macedo - FERC Technical Conference July 14, 2004.
PAP 14 Working Session. PAP 14 Agenda PAP 14 Background Scope Redefinition Discussion –Existing PAP 14 Objectives –Strategies for Prioritizing Prioritizing.
Xanthus Consulting International Smart Grid Cyber Security: Support from Power System SCADA and EMS Frances Cleveland
Integrating Multiple Microgrids into an Active Network Management System Presented By:Colin Gault, Smarter Grid Solutions Co-Authors:Joe Schatz, Southern.
SMART GRID INTEROPERABILITY PANEL WINTER 2012 FACE-TO-FACE IRVING, TEXAS  DEC. 3-6, 2012 PAP8/14 Webconference December 4, 2012.
Frankfurt (Germany), 6-9 June 2011 Coordination between TSOs and DSOs – a necessity for system planning and operation Dr. Ralph Pfeiffer Amprion GmbH 1.
©2012 | Commercial in Confidence | Proprietary to Ventyx, An ABB Company NYISO Real-time Market Presentation to ERCOT METF – April 26, 2012 Confidential.
GREDOR - GREDOR - Gestion des Réseaux Electriques de Distribution Ouverts aux Renouvelables Real-time control: the last safety net Journée de présentation.
EPRI Smart Grid Demonstration and CIM Standards Development
Aidan Tuohy Technical Leader/Project Manager, EPRI ERCOT Emerging Technology Working Group (ETWG) 09/24/2014 Transmission System Considerations for Integrating.
Smart Grid & Microgrid R&D
1 ISO/RTO Council Wholesale Demand Response Projects & OpenADR David Forfia.
SGOC-UCI Smart Grid Focused Use Cases for Transmission and Distribution Operations Nokhum Markushevich Smart Grid Operations Consulting (UCI associated)
American Electric Power (AEP) Virtual Power Plant Simulator (VPPS) Tom Jones, Manger – Corporate Technology Development American Electric Power Grid-InterOp.
Jerry FitzPatrick, NIST Chair Wednesday, May 26. Introduction - IKB PAP8 PAP14 DEWG Charter What should the T&D DEWG be doing? T&D DEWG or T and D DEWGs?
Supervisory Systems.
SMART GRID INTEROPERABILITY PANEL WINTER 2012 FACE-TO-FACE IRVING, TEXAS  DEC. 3-6, 2012 TECHNOLOGY ADOPTION AND THE VALUE OF INDUSTRY COLLABORATION William.
2015 World Forum on Energy Regulation May 25, 2015
DOE’s Smart Grid R&D Needs Steve Bossart Energy Analyst U.S. Department of Energy National Energy Technology Laboratory Materials Challenges in Alternative.
Review of progress and future work SQSS Sub Group 2 August 2006 DTI / OFGEM OFFSHORE TRANSMISSION EXPERTS GROUP.
Costs of Ancillary Services & Congestion Management Fedor Opadchiy Deputy Chairman of the Board.
Applying the Distribution System in Grid Restoration/NERC CIP-014 Risk Assessment Srijib Mukherjee, Ph.D., P.E. UC Synergetic.
Al Hefner (NIST Lead) Frances Cleveland (Technical Champion)
SMART GRID INTEROPERABILITY PANEL TRANSMISSION AND DISTRIBUTION DEWG F2F MEETING December 5, 2011.
FirstEnergy / Jersey Central Power & Light Integrated Distributed Energy Resources (IDER) Joseph Waligorski FirstEnergy Grid-InterOp 2009 Denver, CO November.
Barcelona– May 2003 CIRED’2003 Beta session 4a: Distributed Generation Controllability of DG helps managing Distribution Grids J. A. Peças Lopes
Common Information Model and EPRI Smart Grid Research
1 OpenADR Taskforce Chair – Albert Chiu Co-chair – Ed Koch Technical Editors – Bruce Bartell, Gerald Gray.
Project 3.4 Integrated Data Management and Portals Dr. Hassan Farhangi, Dr. Ali Palizban, Dr. Mehrdad Saif, Dr. Siamak Arzanpour,
Doc.: IEEE /0047r1 Submission SGIP Liaison Report to IEEE Following the SGIP (2.0) Inaugural Conference Nov 5-7, 2013 Date:
ConEdison & PG&E/Marin – Interoperability James McCray – COO/CMO November 13 Grid-Interop T&D Session.
Frankfurt (Germany), 6-9 June 2011 Smart Grid Protection in China Wu Guopei Guangzhou Power Supply Bureau Guangdong Power Grid, China.
What’s Next in Transitioning to a Modern Grid Steve Bossart, Senior Energy Analyst IEEE EnergyTech 2013 May 23, 2013 Cleveland, Ohio.
Lead from the front Texas Nodal 1 Texas Nodal Energy Management System Requirement Documents December 5, 2006 Jay Dondeti EMS Project.
EMS User’s Group Presented By Margaret Goodrich Project Consultants, LLC Presented to EMS User’s Group Austin, TX September.
Brussels Workshop Use case 3 11/09/2015 Mario Sisinni.
PJM© Demand Response in PJM 2009 NASUCA Mid-Year Meeting June 30, 2009 Boston, MA Panel: Price Responsive Demand – A Long-Term Bargain.
IEEE Activities in Smart Grid & Green Technologies Dr. Bilel Jamoussi South Africa 26 October 2009.
REAL TIME BALANCING OF SUPPLY AND DEMAND IN SMART GRID BY USING STORAGE, CONTROLLABLE LOADS AND SMART GENERATIONS Abdulfetah Shobole, Dr. Arif Karakaş.
Steady State Analysis Of A Microgrid Connected To A Power System
Transatlantic Workshop on Electric vehicles and Grid Connectivity November 17 th, 2010 Brussels, Belgium Eric Simmon.
Next-Generation Grid Communication for Residential PEVs (EPC )
CEC Project “Distribution System Aware Vehicle to Grid Services for Improved Grid Stability and Reliability” Sunil Chhaya Principal Investigator.
Demand Response Analysis and Control System (DRACS)
Role of Account Management at ERCOT 2006 TAC Subcommittee Review ERCOT Board February 21, 2006.
Smart Grid Vision: Vision for a Holistic Power Supply and Delivery Chain Stephen Lee Senior Technical Executive Power Delivery & Utilization November 2008.
Planning the Networked Grid Transmission Planning J.E.(Jeff) Billinton Manager, Regional Transmission - North Building the Networked Electricity Grid –
Economic Evaluation Program for Transmission Planning in Competitive Power Market LEE, SANG-HO Fusion Technology Research Lab. K-EMS Development.
This project has received funding from the European Union’s Horizon2020 research and Innovation programme under grant agreement No
4/16/2010 Regional Planning Group Meeting Long-Term Planning Study of the ERCOT Interconnection Warren Lasher Manager, System Assessment.
A smart grid delivers electricity from suppliers to consumers using two-way digital technology to control appliances at consumers' homes to save energy,
Agenda TSOG 8th November
Subteam 1a Competitive Solicitations Framework Working Group Meeting
Breakout Session on Smart Grid Data Analytics
ISO New England System R&D Needs
Building a Sustainable Energy Future
Planning Tools Overview

EU-IPA12/CS02 Development of the Renewable Energy Sector
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Smart Grid Overview] Date Submitted: [13.
Integrated Distribution Planning Process
Planning Tools Overview
Presentation transcript:

SMART GRID INTEROPERABILITY PANEL WINTER 2012 FACE-TO-FACE IRVING, TEXAS  DEC. 3-6, 2012 T&D DEWG Webconference December 3, 2012

WINTER 2012 FACE-TO-FACE IRVING, TEXAS T&D DEWG Meeting Agenda – NIST/SGIP Update – Jerry  SG International Cooperation Workshop: Korea & U.S. – December 7, Irving TX  SGIP 2.0  PAP12, PAP8/14 Update  DRGS Update TnD DEWG Activities  MultiSpeak Catalog of Standards Artifacts – Gary McNaughton Transmission Bus Load Model (TBLM) (Nokhum Markushevich) Emerging Topics - Alarms and Event Management over the Smart Grid Next Meeting – Wednesday, December 17, 4:00 PM Eastern

WINTER 2012 FACE-TO-FACE IRVING, TEXAS PAP Updates PAP12 Update  IEEE , IEEE “Standard for Electric Power Systems Communications - Distributed Network Protocol (DNP3)”  IEEE “IEEE Draft Standard for Exchanging Information Between Networks Implementing IEC and IEEE Std 1815 (Distributed Network Protocol - DNP3)” PAP8  IEEE “Application integration at electric utilities - System interfaces for distribution management - Part 3: Interface for network operations”  UML Model of MultiSpeak PAP14  IEEE C “Standard for Common Format for Event Data Exchange (COMFEDE) for Power Systems”  IEEE PSRC H5 Committee working on guidelines titled; “A common format for configuration of Intelligent Electronic Devices (IED’s)”

WINTER 2012 FACE-TO-FACE IRVING, TEXAS MultiSpeak Catalog of Standards Artifacts – Gary McNaughton SGIP CoS – Standards Information Form Criteria and Analysis Report: MultiSpeak Specification SGIP CoS - Development Process Statement: MultiSpeak Specification Next Steps

SMART GRID INTEROPERABILITY PANEL WINTER 2012 FACE-TO-FACE IRVING, TEXAS  DEC. 3-6, 2012 UPDATE ON THE USE CASE FOR THE TRANSMISSION BUS LOAD MODEL (TBLM) Nokhum Markushevich Smart Grid Operations Consulting

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Information Exchange between T&D Domains 6 T&G devices Subst. LTC, Shunts, SVC DMS DOMA VVWO FLIR Emerg. apps AMI processor DER/ES processor DR processor PEV processor Load model Processor Secondary Processor TBLM Processor TBLM Topology model PMU SCADA EMS SE CA OPF/SCD ED Pre-arm Islanding Restora- tion ……… RAS DSCADA Data Control Distribution domain T&G domains

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Scenarios for TBLM Use Cases 1. Develop aggregated DER capability curves for TBLM 2. Develop aggregated model of dispatchable load for TBLM 3. Develop aggregated real and reactive load-to-voltage dependencies 4. Develop aggregated real and reactive load-to-frequency dependencies 5. Develop aggregated real and reactive load dependencies on Demand response control signals 6. Develop aggregated real and reactive load dependencies on dynamic prices 7. Adapt aggregated real and reactive load models to current weather conditions 8. Develop aggregated real and reactive load dependencies on ambient conditions and time for the short-term forecast of the aggregated load 9. Develop models of overlaps of different load management functions, which use the same load under different conditions. 10. Assess the degree of uncertainty of TBLM component models. 11. Develop Virtual Power Plant (VPP) Model 12. Determine the possible shifting of load from/to the transmission bus 13. Determine the abnormal states of the TBLM after major power system emergencies 7

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Develop Virtual Power Plant (VPP) Model

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Definition of VPP* A virtual power plant (VPP) aggregates the capacity of many DGs, Demand Response, and Energy Storage (Megawatts and Negawatts). VPP creates a single operating profile from a composite of the parameters of each DER that should incorporate the impact of the network on their aggregate output. As any large-scale generator, the VPP can be used to facilitate DER trading in various energy markets and can provide services to support transmission and distribution system management. * Based on “Flexible Electricity Networks to Integrate the Expected Energy Evolution, by J. Corera Iberdrola and J. Maire. 9

WINTER 2012 FACE-TO-FACE IRVING, TEXAS VPP model as a component of TBLM Consists of distributed resources from the same transmission bus It is represented, at the distribution-transmission interfaces, as an aggregated profile which includes the influence of the local network on the VPP output. It also represents the composite DER cost and operating characteristics. The model of VPP provides the system operator with visibility of energy resources connected to the distribution network, allowing distributed generation and demand to contribute to transmission system management. VPP can also facilitate the use of distributed resource capacity in the distribution networks, e.g., for FLISR and/or IVVWO. 10

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Basic inputs for the VPP DER inputs for the localized (technical) VPP  Operating schedule  Bids & Offers / marginal cost to adjust position  Operating parameters Other inputs:  Real-time local network status  Loading conditions  Network constraints 11

WINTER 2012 FACE-TO-FACE IRVING, TEXAS VPP actions based on the input data 12 Commercial VPP Technical VPPDMS 1. Initial Input 5. Corrections 2. Initial model 6. Final model 3. Constraints, requests 4. Adjustments to constraints, requests TBLM 7. Final VPP model & adjusted other components of TBLM.

WINTER 2012 FACE-TO-FACE IRVING, TEXAS DMS actors involved in VPP modeling for the TBLM DER Data Management System DER model processor Load Model Processor Load Management System Distribution Operation Modeling and Analysis to determine the impact of VPP on distribution operations: adequacy, power quality, efficiency, and operational constraints Integrated Volt/var/Watt control application to determine the impact and availability on Volt/var/Watt optimization Distribution Contingency Analysis to determine the impact on reliability TBLM developer application to adjust other TBLM components. 13

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Determine the possible shifting of load from/to transmission bus

WINTER 2012 FACE-TO-FACE IRVING, TEXASNarrative For the most of the transmission buses, a portion of the load fed from the bus can be transferred to other busses without violations of the operational limits. Such transfer may change the economics of both transmission and distribution operations (changes of LMPs, losses, of volt/var control benefits, etc.). The efficiencies of these changes may be in conflicts with each other, e.g., the LMPs may reduce, while the losses in distribution can increase. 15

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Narrative (cont.) In some cases a reallocation of loads among transmission buses is needed as preventive and even corrective measures in case of a contingency. There may be several alternatives for the shifts of load from one bus to other buses. The alternatives may differ by the amount of load that can be shifted and by the economic and reliability results. The alternatives of load shifting change with the change of the customer loads, DER operations, and current DR statuses. Hence, the available load shifts should be updated in the near- real time fashion. 16

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Objective of the scenario Determine all plausible alternatives of load that can be shifted from/to the transmission bus Provide the EMS with the distribution-side economic and reliability results of the shifts of load To be used by EMS to improve overall efficiency and reliability. 17

WINTER 2012 FACE-TO-FACE IRVING, TEXAS DMS actors involved DMS Data Management Systems DMS Topology Model processor DMS multi-level feeder reconfiguration application in short- term look-ahead study mode to determine all technically feasible alternatives DMS IVVO application to determine the changes in the efficiency of distribution operations under the new configurations DMS contingency analysis for the reconfigured circuits (to assess the change in the reliability) TBLM developer application. 18

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Determine the abnormal states of the TBLM after major power system emergencies

WINTER 2012 FACE-TO-FACE IRVING, TEXASNarrative After the development of the emergency situation is stopped, and the system is in a quasi-steady-state condition, there are  disconnected customers (life-support systems),  disconnected DER, and microgrids,  activated demand response,  disabled demand response means  discharged energy storage devices,  abnormal volt/var parameters due to IVVWO in emergency mode,  abnormal circuit connectivity, etc. All these abnormalities have their prices, constraints, and restoration priorities. 20

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Narrative (cont.) Different orders of restoration to the normal states of different components have different impacts on the restoration process.  Restoration of some components may impact the states of other components. For instance, restoration of some disconnected loads may reduce the voltage below the limits, which will force the IVVWO to increase the overall voltage and by this to increase the load even more. The cold load pickup should also be determined. Transmission operations in the after-emergency state may also impose constraints on the restoration in distribution, e.g.,  Reduced loading limits of a transmission interface  Limited generation reserve, etc. 21

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Objective of the scenario To inform the transmission and distribution control systems about the post-emergency states of the different component in the distribution system to define the appropriate priorities of restoration To take into account the transmission-side constraints for prioritization of distribution restoration. 22

WINTER 2012 FACE-TO-FACE IRVING, TEXAS DMS actors involved DMS Data Management Systems DMS Topology Model processor to determine and analyze the after-emergency topology (disconnected elements, abnormal states) Load Model processor (different net load patterns due to backup generators, cold load pickup, etc.) DER Model processor (abnormal states and modes of operations) Load Management System (states of DR) Distribution Operation Modeling and Analysis for after-emergency situational awareness DMS multi-level feeder reconfiguration application in short-term look-ahead study mode to determine the topology restoration alternatives DMS IVVO application to adjust Volt/var/Watt parameters to the restoration alternatives TBLM developer application 23

WINTER 2012 FACE-TO-FACE IRVING, TEXASConclusions. New object models, attributes, and information exchanges should be developed to accommodate the following transmission and distributing operational needs:  Integrating Virtual Power Plants into distribution systems and serving higher-level control areas  Shifting of load from one transmission bus to others for transmission operation purposes  Restoration of normal operations after major power system emergencies. 24

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Future work on TBLM Completion of the development of the TBLM use case Development of a list of possible new object models Development of a list of possible new information exchanges Update of the Distribution Grid Management use cases to accommodate the development and utilization of the TBLM Development of use cases for EMS applications with integration of the TBLM. 25

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Questions? Thank you!

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Emerging Topics - Alarms and Event Management over the Smart Grid IEEE C “Standard for Common Format for Event Data Exchange (COMFEDE) for Power Systems”

WINTER 2012 FACE-TO-FACE IRVING, TEXAS Next TnD Webmeeting Next Meeting – Wednesday, December 17, 4:00 PM Eastern