Integrating Distributed Resources into Distribution Planning and Operations R&D Priorities Mark McGranaghan Jason Taylor Electric Power Research Institute CIRED Workshop 2016 Helsinki Theme 2: Resilient distribution system planning and operation June 14, 2016
The Vision for a Resilient Distribution System as part of the Integrated Grid Power System that is Highly Flexible, Resilient and Connected and Optimizes Energy Resources integratedgrid.epri.com 2
10 Industry Priorities for the Distribution System in the Integrated Grid 1. Architecture for the Integrated Grid 2. Distribution Planning 3. Distribution Operations 4. Reliability and Resiliency 5. Integrating DER 6. Integrating the Customer 7. Communications Infrastructure 8. Data Integration and Data Analytics 9. Cyber Security 10.Learning from Demonstrations 3
1. Architecture for the Integrated Grid Enterprise interoperability GIS as foundation Open application platforms Telecommunications infrastructure DER integration Cyber security 4
2. Distribution Planning Hosting capacity Models that support distributed controls Advanced technologies (e.g., voltage management) Customer models Evaluating non-wires solutions Probabilistic methods 5
3. Distribution Operations Workforce management Automation Voltage optimization Fault management Operator interfaces Real time simulation platform Integrated T&D Operations Model-based management and model integration (GIS) MDMS OMS Sensors, Switches, Capacitors, Regulators GIS Enterprise Integration System Controller SCADA & Field Networks PV ES EV/PEV Local Controller 1 Etc. Local Controller N Controllable LOADS ISO/RTO Markets Third-Party Local Controller Aggregator 6
4. Reliability and Resiliency Distribution grid resilience Automation investments Asset management Technologies Sensors, advanced monitoring and analytics Role of distributed resources in grid investment strategies Role of Microgrids Optimizing investments economics 7
Applicable Value (p.u.) 5. Integrating DER Technologies Architecture Models for planning Interconnection and integration standards Role of energy storage HC1 HM1 HM2 HC3 HC2 Must Trip HM3 HM4 Ride-Through or Trip is Allowed 1.0 p.u. HM5 HC4 Communications Ride-Through LC5 Ride-Through or Trip is Allowed LC6 Economics LC3 LC4 LM4 LM5 LC1 LC2 LM2 Must Trip LM3 Energy Storage Integration Council (ESIC) LM1 Event Duration Transportation Infrastructure Working Council 8
6. Integrating the Customer Understanding the customer Electrification opportunities Customer services Customer model of the future Communications Role of AMI Internet of things, cloud services, cyber security and privacy 9
7. Communications Infrastructure Requirements vs. applications (use cases) Technology developments Role of fiber Shared infrastructure and services Business models Cyber security 10
8. Data Integration and Analytics Sensors and asset management Integration of external data Unmanned Airborne Vehicle Customer Input (Social Media) Field Crews AMI Field Crews Dispatched ( to Repair and Restore ) AMI data analytics Synchrophasors Satellite Data management Information models Data Integration and Data Analytics Network model management Asset Registry System SCADA System Geographical Information System (GIS) Outage Management System (OMS) Incident Command Center ( Prioritizes and Dispatches ) 11
9. Cyber Security Metrics Risk analysis Access management Threat and vulnerability analysis Cyber security maturity model Situational awareness Supply chain management Incident response Security for customer integration and the IOT 12
10. Learning from Demonstrations and Pilots ComEd and Partners Moving Forward on Bronzeville s Community of The Future 13
An Integrated Grid Integration of: Electricity, Telecommunications, and Customer Local Energy Networks The Integrated Grid Enables Optimization of Local and Central Resources with Customer Needs 14
Together Shaping the Future of Electricity 15