12 dessai epri sandia - pge vvo pilot
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Transcript of 12 dessai epri sandia - pge vvo pilot
Smart Grid Pilot Projects Volt VAR Optimization 1
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Volt VAR Optimization Smart Grid Pilot at PG&E EPRI / Sandia PV Systems Symposium Rustom Dessai, PE – PG&E Emerging Grid Technologies
May 10, 2016
Smart Grid Pilot Projects Volt VAR Optimization 2
PG&E Smart Grid VVO Background
Objective - evaluate VVO’s ability to: 1. Enhance grid monitoring & control 2. Grid efficiencies and Conservation Voltage Reduction 3. Accommodate growing distributed generation
Scope – Lab Test (Phase 1) then Field Trial (Phase 2) on 14 feeders • Pilot two competing vendors
• Extensive testing completed at PG&E ATS Facility
• Varying DG penetration (ranging from 2% – 35%: nameplate / peak)
Preliminary* results to date from 12 feeders: • Summer 2015: 0.1% energy savings • Fall 2015: 2.2% energy savings • Cumulative Energy Reduction: 1.5%
• Cumulative Average CVRf: 0.9
* Results will be refined through course of pilot as new data and analysis methods are introduced
Smart Grid Pilot Projects Volt VAR Optimization 3
VVO Technology Overview
• VVO incorporates sensing, communications and computing to more tightly control voltage delivered to customers
• Reducing voltage drives energy efficiency through Conservation Voltage Reduction (CVR) – reducing delivered voltage reduces energy consumption without sacrificing device/appliance performance & customer satisfaction
• Has the promise to deliver: • 1-2% reduction in energy demand and consumption • Improved voltage control on circuits with high DG penetration
120V
126V
114V
Line Capacitor Line Regulator Substation LTC Customer Load
Distributed Generation
Original Voltage
Voltage with VVO
Smart Grid Pilot Projects Volt VAR Optimization 4
Vendor Selection for the VVO Pilot PG&E’s Key Requirements for VVO • Must function with a balanced model (rather than unbalanced w/ phasing) • Must minimize initial configuration and maintenance, preferably by leveraging an
existing network model (preferably GIS or DMS) maintaining an additional network model and manual configuration/maintenance processes are a last resort
• Must support increased distributed generation penetration • Must utilize or integrate with existing operator interfaces (either DMS, SCADA or PI)
Strategies to Guide VVO Vendor Selection • Leverage existing assets • Maximize customer benefits • Manage future grid complexity
• Provide path to DMS/EMS integration • Minimize Total Cost of Ownership
PG&E Pilot VVO Vendors1 Selected through RFP, Benchmarking, and Demos • Measurement based systems – not requiring unbalanced models
• Different strategies: Secondary (AMI) vs Primary / Set point vs tap control • Perceived ability to handle increasing grid complexity relative to field • Existing installations at other utilities
(1) PG&E will reassess the marketplace when choosing a vendor for a wide-scale deployment of VVO
Smart Grid Pilot Projects Volt VAR Optimization 5
PG&E DTY Testing Facility
UIQ System
Distribution Test Yard
Meter Simulator AMI Head End
Test VVO SCADA
Network Model
Meter Farm
PG&E utilized the distribution test yard (DTY) to simulate circuit responses to VVO operation, allowing evaluation of vendor solution performance prior to field deployment.
Smart Grid Pilot Projects Volt VAR Optimization 6
DG Penetration Increases on VVO Circuits: 2013 - 2016
• Original VVO feeder selection analysis done near end of 2013 • Observed significant increases in DG penetration on VVO feeders in short span (<3
years) of pilot
0%
5%
10%
15%
20%
25%
30%
35%
40%
A-1101 A-1102 A-1103 P-2101 P-2102 P-2103 B-1114 B-1115 B-1116 W-2104 W-2105 W-2106 D-1102 D-1104
VVO Feeder DG Penetration Increases
DG / Peak Load 2013 DG / Peak Load 2016
Smart Grid Pilot Projects Volt VAR Optimization 7
Reverse power seen at feeder and regulators
Feeder Head Regulator
Smart Grid Pilot Projects Volt VAR Optimization 8
Reverse Power VVO Vendor Strategy Progression through Pilot
No strategy Disable VVO
Ride-through reverse power for
co-gen regs, disable otherwise
Vendors not allowed out of test phase
Caused certain systems to trip
regularly around midday
Works well for PG&E’s VVO circuits,
no issues so far
Smart Grid Pilot Projects Volt VAR Optimization 9
VVO’s Effect on Woodward 2106 (has high DG Penetration > 25% of load) No issues with 2 On days, some issues with 3 Off days
VVO On
VVO Off
VVO On
VVO Off
VVO Off
• VVO team will continue studying VVO’s impact on voltage in presence of PV • Currently testing one VVO vendor’s strategy to use irradiance forecast to hedge
voltage against PV variability
Smart Grid Pilot Projects Volt VAR Optimization 10
• Found existing voltage unbalance on feeders during summer severely limited VVO functionality
• Analysis of frequent AMI voltage readings can help weed out feeders that may have existing issues with voltage or voltage unbalance
• As part of the VVO pilot, PG&E enabled 15 min / hourly voltage reads on 1 million meters to analyze how this data may inform VVO feeder selection
Lessons Learned: Feeder Screening
Aug 25 Aug 26 Aug 27 Aug 28
VVO On
VVO Disables
VVO On
VVO Disables
126 120 114
Sept 29 Sept 30 Oct 1 Oct 2
126
120
114
VVO Off
VVO On
VVO Off
VVO On
Sum
mer
201
5 Fa
ll 20
15
Smart Grid Pilot Projects Volt VAR Optimization 11
Lessons Learned: Value from Proactive Issue Identification and Resolution • Configured Tableau and PI screens as tools to monitor AMI voltages and SCADA
data to identify issues proactively and find resolutions • Almost all issues related to secondary problems, but also used to adjust existing
settings on field equipment, and to confirm VVO settings
T-man replaces service drop to customer and resolves problem before customer notices issue
Smart Grid Pilot Projects Volt VAR Optimization 12
Exploring value of Smart Inverters for VVO
Modeling (complete)
• How can VVO control of Smart Inverters improve VVO performance?
• What value could VVO extract from “VARs at night”?
Lab Testing (in progress)
• What “VVO friendly” power factor and Volt-Var settings deliver safe “no fight” conditions in the field
Field Trial (later in 2016)
• Collaborate with 3rd party installers to have Smart Inverters installed in Q2 2016, adjust power factor and Volt-Var settings to improve VVO benefits
Smart Grid Pilot Projects Volt VAR Optimization 13
Large DG
Dinuba Sub
Complex with concentrated DG • > 100 circuit miles • 5 line voltage regulators • 23% DG penetration1
• Three large DGs: 2 x 1 MW, 1 x 0.7 MW VVO Go Live in Jan 2016 drove interest in predicting performance
(1) Measured as DG capacity / feeder peak load. At time study began, additional DG connection has raised penetration to 34% as of January 2016
Dinuba
Dinuba 1104 studied due to challenging voltage control conditions
Smart Grid Pilot Projects Volt VAR Optimization 14
Case 2: Traditional VVO Case 3: VVO plus SI P.F. control
Charts below show comparison of VVO savings metrics Case 1 (No VVO) at varying DG penetration levels
VVO control of SI can deliver line loss reduction at low DG penetration, and energy delivery savings at higher penetrations
0%
2%
4%
6%
8%
10%
23% 47% 70% 94%DG Penetration
Daytime (8 am – 6 pm)
VARs at Night
0%
2%
4%
6%
8%
10%
23% 45% 68% 91%
0%
3%
6%
9%
12%
15%
23% 47% 70% 94%0%
3%
6%
9%
12%
15%
23% 45% 68% 91%
Energy Delivery Savings*
Line Loss Reduction*
*Results should be deemed as a general guideline regarding potential VVO benefits. It is recommended that further analyses be conducted for a larger sample of feeders with varying topologies, voltage levels, customer densities, customer types, etc.
NOTE: Larger % savings does not necessarily correlate to larger magnitude of energy delivered savings because overall energy delivered decreases in magnitude as penetration increases.
Smart Grid Pilot Projects Volt VAR Optimization 15
DG as Part of VVO – Technical Analysis Results
Case 1: No VVO, PV-DG operates at unity power factor
Case 2: VVO controls LTC, Regs, and Caps, PV-DG operates at unity power factor
Case 3: VVO controls LTC, Regs, Caps, and DG smart inverter power factor (0.95 lead, unity, or 0.95 lag)
*Results should be deemed as a general guideline regarding potential VVO benefits. It is recommended that further analyses be conducted for a larger sample of feeders with varying topologies, voltage levels, customer densities, customer types, etc.
Smart Grid Pilot Projects Volt VAR Optimization 16
VVO Pilot Smart Inverter Field Trial
• Adjust Smart Inverter P.F. and Volt-VAR settings to evaluate impact to VVO performance
Follow technology and regulatory development to automate use of Smart Inverters
• DERMS EPIC Technology Demonstration in late 2016
• Follow ADMS / VVO / DERMS technology developments
• California Distributed Resources Plan – locational value of Smart Inverters?
GRID of THINGS
Next Steps for SI
Smart Grid Pilot Projects Volt VAR Optimization 17
Post-Pilot Deployment
• 2017-2019 GRC proposed $84M deployment on 228 feeders (7% of PG&E’s system)
• Presently forecasting a benefit-cost ratio of 1.2 – 2.0, and will be updating forecast in May
• Plan dependent on PG&E’s SCADA and DMS plans – Deployment of VVO would be tightly integrated with DMS enabling automated configurations and reconfigurations
• PG&E is not tied to piloted vendors, and will reassess the VVO vendor market place for deployment vendor
Smart Grid Pilot Projects Volt VAR Optimization 18
Questions?
Questions?