1 / 30

Enabling Data Infrastructure for Utility Sustainability

John Lacy November 8, 2010. Enabling Data Infrastructure for Utility Sustainability. Enabling Smart Grid components. Generation Transmission & Distribution Meters Hardware Consumers Smart Infrastructure. Smart Smart Smart Smart Smart.

nitara
Download Presentation

Enabling Data Infrastructure for Utility Sustainability

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. John Lacy November 8, 2010 Enabling Data Infrastructure for Utility Sustainability

  2. Enabling Smart Grid components • Generation • Transmission & Distribution • Meters • Hardware • Consumers • Smart Infrastructure Smart Smart Smart Smart Smart – “The Enabler”

  3. Data, Data, Dataand more Data

  4. Meter Data Volumes – Yesterday, Today, and Tomorrow.

  5. Beyond AMI: Example Data Flows Asset Information Second or SCADA 1 - n Sub - second Mobile GIS PI WMS daily reads Dispatch AMR collected daily 30 minute collected hourly Metered Feeder Data 30 minute Near - real time DMS collected hourly transformer kW , OMS device loading , voltages , etc . 5 minute reads continuously Feeder Amps and Circuit other SCADA Data AnalysisTool 15 minute / hourly 15 minute / hourly C & I Interval Access to all data Distribution Planning n AMI 5 minute / hourly ( Future ) Access to all data Distribution Operations Access to all data Field Engineering Financial Systems of Source devices will evolve Record with new technologies and ( data streams not Accounting CIS cost effectiveness included in this scenario ) IED Access to all data § CBM 15 minute Asset Management / collected daily Substations HAN Capacitor Control Multi - year history and reporting System flexibility for analysis such as : § PF / Voltage / Var § DG § Loss Manual Monthly § Load Substation Reads Multi - year history and real and near real - time data for : § Capacitor Operations § DG Status Multi - year history and real and near Various data granularity real - time data for : and delivery frequencies § PF / Voltage / Var Analysis that will increase over time § Capacitor Operations

  6. Smart Infrastructure - “The Enabler” • DATA MANAGEMENT INFRASTRUCTURE is ESSENTIAL • Need a home for all this data – accessible & highly available • Underpins and supports the entire Smart Grid • Connectivity to disparate devices and data sources • Data collection at original resolution – milliseconds to minutes • Liberate data from secure, locked down proprietary systems • Data analysis – ad hoc, event based, in real time • Transformation to information for decision support • Scalable – to millions of meters and values • Extensible – to other databases, applications • Communications – robust, fast, bidirectional

  7. Smart Generation • Multiple Control systems’ data aggregated to improve unit and plant performance

  8. Phase Angle Jumping - Grid Stability Notice frequency is relatively stable 5:10 PM 5:00 PM Phase Angle difference Continuing to grow. Diff 120⁰ 60⁰

  9. Substation Dashboard Level 3 – Asset View

  10. 13 of top 15 Owner/Operatorsusing PI to Manage Wind Farms Source: Emerging Energy Research

  11. Value Propositions • Turbine Manufacturer Warranty Management • “Fox Watching the Hens” • “Bathtub Curve” Implications for LTSA Concept • Need: Focus on Top-Ten Sources • Increasing kWh produced – Wind Farm Operations • Turbine Availability • Turbine Operating Efficiency • Increasing value of kWh produced – Utility Operations • Improving utility integration (forecasting and scheduling) • Improving market value of power (real-time info to power marketing/trading floor) • VAR/Grid Stability Management • “Intangibles” – Corporate Requirements • Enterprise Integration, • Separation of Process Control Network from User/Enterprise • Regulatory & Reporting • Technology Risk Management – Perception and Reality

  12. Asset Management Value PropositionTurbine Production Example • A typical utility scale wind farm may have 30 to 200 Turbines • Large owners (e.g. Iberdrola – 3500MWs) may have thousands of turbines • A single percentage point gain/loss of “in-market” availability (e.g. turbines available to operate when the wind is blowing) for • Iberdrola Total Fleet would result • in a 1st Year ROI/loss of $4.3MUSD. • NPV over 5 Years = $13.5MUSD @ 18% Discount Rate • Based on US prices, power rate in Spain is .07 to .10/kWh produced • For a Single Wind Farm of 150MWs: • In a 1st year ROI of $185,000 • NPV over 5 years = $576,000 @ 18% Discount Rate

  13. Asset Hierarchy (Tree): • Allowing expansion/collapse • Project drill down capability

  14. Geographic Status map: • Color-coded • “Rollovers” showing windspeed & project output, # of faulted turbines or state change • Project drill down capability

  15. Real Time KPI Dashboard: • Availability, Capacity, etc • Color coded with drill down capability

  16. YTD Financial Meters: • Revenue vs Budget • Commercial Availability

  17. Trend Data: • Market Prices

  18. Defined KPIs per region/project, color coded with drill down capability: • Financial • Production • Operations

  19. Historical Work order Detail: • ???

  20. Wind farm status: • Color-coded • Project drill down capability

  21. Active Faults Window: • Detailed wind farm faults

  22. MTD Power Generation Chart: • Expected vs Delivered

  23. Work order Detail: • Historical view of work orders • Ability to drill down to item details

  24. Real time Operations • Turbine Graphic • Turbine Details

  25. Power Curve Chart: • Actual Output vs Manufacturer

  26. Excel Based Reporting

  27. Turbine Performance – DLES Example

  28. “Roll-up” Mechanism: Net KWh Roll-Up • Key Points • Each trend shown is aggregated load (kWh) up to the next higher trend from an individual meter, transformer, line segment, breaker and sub. • If you overlay the Distribution SCADA load, the difference would be losses or leakage • The physical model (CIM) allowing the aggregation and roll-up of individual loads • End to end visibility – integrating meter and distribution system(s) operational data All AMI meters summed to one distribution transformer All distribution transformers summed to circuit segment Load on meter data Total feeders summed to sub Circuit segment summed up to feeder 28

  29. Utility Landscape

More Related