1 / 14

Theme 2 Planning, optimization and regulatory issues Geza Joos, McGill University

Theme 2 Planning, optimization and regulatory issues Geza Joos, McGill University. Definition/features – microgrid. Geographically delimited Connected to the main grid at one point fed from one substation May operate islanded Includes distributed generation (DG)

eris
Télécharger la présentation

Theme 2 Planning, optimization and regulatory issues Geza Joos, McGill University

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Theme 2 Planning, optimization and regulatory issues Geza Joos, McGill University

  2. Definition/features – microgrid • Geographically delimited • Connected to the main grid at one point • fed from one substation • May operate islanded • Includes distributed generation (DG) • renewables (inverter interfaced): wind, solar • fossil fuel based (synchronous generators): CHP • Includes an energy management system • controlling power exchanges, generation and load • with storage and demand response

  3. Distributed generation – renewables • Generation close to the load – siting • Advantages/benefits • Green energy – reduced environmental impact • Enhanced reliability and flexibility • Energy cost – competiveness (generated/delivered) • New issues/differences • Output variability – energy and power (ramp rates) • Not schedulable/controllable – must run at MPPT • Impacts – power quality (voltage variations, ramp rates) • Grid integration and operational impact (loading, faults) • Responsibility – maintenance, faulted operation

  4. Microgrid implementation issues • Business proposition for the microgrid owner • Economic justification – kW cost, reliability, resiliency • Participation in market/energy supply • Ownership • Private/IPP • Utility • Role and benefit for utilities • Grid support – impact on the transmission system • Role in power system restoration • Operational/regulatory issues • Responsibilities and jurisdiction – right to disconnect

  5. Expected developments – smart grids • Smarter distributed energy resources (DER) • More communications between DER • New grid topologies • from point to point (generation to load) to distribution supply points, • from radial to looped • Active DER – voltage/Var regulation • Note: not all of the smart distribution grid technologies are necessary/applicable to smart microgrids

  6. Issues addressed in Theme 2 • Business case • Justifying the setting up of a new microgrid, optimizing operation, configuring existing distribution systems into microgrids, regulatory issues • Energy supply security • Load management and demand response • Making better use of the energy resources • Case studies – benchmarks, typical systems and use cases

  7. Application examples/justification • Isolated/offline microgrids • Remote communities – reducing the cost of electric energy, reliability, environment impact – Canada north • Remote and movable military bases – supply security • Industrial, community and commercial microgrids • Large campuses – GHG reduction (green energy), energy independence – grid support and energy exchanges – BCIT • Military bases – alternative energy supply, benefits of storage (EVs)

  8. Projects and personnel in Theme 2 • Cost-benefits framework – secondary benefits and ancillary services • Lead: G Joos, McGill University • HQPs: 2 MEng and 1 PhD (equivalent full time); total trained: 3 MEng, 2 PhD • Energy and supply security considerations • Lead: R Iravani, University of Toronto • HQPs: 2 MEng and 1 PhD (equivalent full time); total trained: 2 MEng, 4 PhD

  9. Theme 2 projects and personnel • Demand response technologies and strategies – energy management and metering • Lead: K Bhattacharya, University of Waterloo • HQPs: 2 MEng and 1 PhD (equivalent full time); total trained: 5 MEng, 3 PhD • Integration design guidelines and performance metrics • Organization to be determined

  10. Solutions and deliverables • Methodology for cost-benefit analysis of microgrids (P2.1) • Application to remote communities • Microgrids energy management (P2.2) • Quantification of impacts and benefits of the microgrid and electrically-close multiple microgrids • Demand response (P2.3) • Load models, taking into account temporal and locational electricity prices, for demand management

  11. Linkages – Industrial network partners • NRCan • P2.1 – remote communities, business cases (on going) • P2.3 – demand response (on going) • Hydro-Quebec/IREQ • P2.1 – remote communities (on going) • BC Hydro • P2.1 – business cases (discussions) • Hydro One • P2.3 – demand response management (on going) • Schneider Electric • P2.3 – demand response controller (potential)

  12. Linkages – Industrial network partners • CYME • P2.2 – network simulation • P2.4 – benchmarks and use cases (potential) • Manitoba HVDC • P2.2 – network simulation, BCIT microgrid (on going) • P2.4 – benchmarks and use cases (potential)

  13. Linkages – other themes/researchers • Theme 1 • P2.1 with P1.4 – remote communities (on going) • P2.1 with P1.1 – control of DER (on going) • Theme 3 • P2.1 with P3.4 – operation of the grid (discussions) • P2.2 with P3.2 – operation of microgrid (potential) • P2.1 with P3.2 – energy management (potential) • Within Theme 2 • P2.1 with P2.3 – demand response (potential) • P2.2, P2.2 with P2.4 – models, benchmarks (potential)

  14. Relevance to Canadian industry/utility • Deliverables include • Methodologies for evaluating business cases • Control approaches for the operation microgrids – DER control and energy management • Configuration of microgrids and interaction between microgrids – evaluation towards an intelligent distribution grid • Differences with other jurisdictions • Distribution system configuration (single phase feeders) • Urban, rural and remote microgrids have differing requirements • European microgrid solutions do not generally apply

More Related