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IoT/PowerMatcher TE Test Bed

IoT/PowerMatcher TE Test Bed. Presented by Alexander Krstulovic William J. Miller ISO/IEC/IEEE P21451-1-4, Chairman http://www.sensei-iot.org NIST TE Challenge Test Bed Team Leader 05/17/2016. 1. European Testbeds. City 1 & 2. Powermatching. Houthaven. Lochem Energy.

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IoT/PowerMatcher TE Test Bed

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  1. IoT/PowerMatcher TE Test Bed Presented by Alexander Krstulovic William J. Miller ISO/IEC/IEEE P21451-1-4, Chairman http://www.sensei-iot.org NIST TE Challenge Test Bed Team Leader 05/17/2016 1

  2. European Testbeds City 1 & 2 Powermatching Houthaven Lochem Energy Smart Energy Collective VIOS Topsector NL Matrix V Couperus Energy Supply Cooperative KIC InnoEnergy Ecogrid FP7 Hybrid Energy Grid Management Hegrid, KIC ICT Labs

  3. European PM Results • Protocol: • Proof of Concept • Customer engagement • Positive Renewable integration • Wide range of mix of devices • Effective natural scheduling of EV’s • Effective congestion management on Transformer through LMP • Scalability tests • Easy integration of devices through EFI

  4. Goals and Description • Goals • Security in Transactive Energy System • Resiliency in Transactive Energy System • Provide bi-directional data exchange to multiple PowerMatcher nodes secure by ISO/IEC/IEEE P21451-1-4 (Sensei-IoT*). • Expected benefits for utilities include reduced complexity and consumer engagement in better control of their energy usage resulting in cost savings while maintaining grid loads and support of renewable generation • Protocol: • IoT XMPP Interface to PowerMatcher and Energy Flexibility Interfaces (EFI)

  5. Devices- Ecosystem • The devices participating in this energy grid will include: • 1. Time-shifters – appliances or equipment that can be operated on a discretionary basis to take advantage of lowest energy prices. • 2. Buffers – devices that can store energy. • 3. Uncontrolled loads or producers, such as wind and solar generation. • 4. Energy storage in the form of batteries or electric vehicles (Eves). • 5. Projected benefits include giving consumers maximum choice in device decisions; preventing vendor “lock-ins”; and creating an eBay-like energy • Examples: • HVAC, Solar Inverters, Electric Car Rechargers, Ventilation Systems, Lighting and Building Management Systems (BMS) CALL FOR PARNERS

  6. Team Participants and Roles • Erie County – Buffalo, NY USA • to supply test sites and coordinate local actions • Esensors – Buffalo, NY USA • to supply wireless power meters for test bed include development of device drivers • TNO/Alliander – Netherlands • to help integrate IoT XEPs SDK into PowerMatcher • Clayster – Sweden • to supply Provisioning Server • MaCT USA – Washington, DC USA • To provide project management including IPDX.NET data sharing • Universities – to provide link to IPDX.NET for data federation • SUNY/Buffalo State (Buffalo, NY) SUMMER 2016 • Rowan University (Glassboro, NJ) PENDING • University of Ontario Institute of Technology (Oshawa, ON) PENDING

  7. Milestones • Smart City: Erie County (Buffalo, NY) • Determine device locations – May 2016 • Data Analytics - June 2016 • Provisioning Server – May 2016 • PowerMatcher IoT XEPs – June/July 2016 • Integration Testing – August 2016 • Field Testing – September 2016

  8. Network Architecturefor Transactive Energy (TE) 8 Fine-gained demo

  9. Thank You

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