EPRI Intelligrid / Smart Grid Demonstration Joint Advisory Meeting March 3, 2010

EPRI Intelligrid / Smart Grid Demonstration Joint Advisory Meeting March 3, 2010 Community Energy Storage Presentation & Simulation Results Thomas J. Walker Emeka Okafor 1 Energy Storage Applications in Utilities 2 1

Matching Storage Options to Utility Needs Storage Technologies Charts from www.electricitystorage.org Utility Applications 3 The Evolution of the Electric Utility System Before Smart Grid: One-way power flow, simple interactions After Smart Grid: Two-way power flow, multi-stakeholder interactions 4 Adapted from EPRI Presentation by Joe Hughes NIST Standards Workshop April 28, 2008 2

Smart Grid Enables Energy Storage But where is the best location/size for the storage? Adapted from EPRI Presentation by Joe Hughes NIST Standards Workshop April 28, 2008 5 Energy Storage Options Grid Storage Options 1- System Level 2- Substation Level 3- Grid Edge Strategically Placed (100 MWs / minutes to hours) At Substations or Near Large Customers (Few MWs / 4-6 hours) Small scale (CES) Fleet (100 s of 25 kw units with several hours of discharge) Flywheels Li-ion (or other) Fixed NaS Transportable Li-ion Trailers Flow Batteries Non EV-Approved Batteries Li-ion (Compact & Efficient) Lead Acid (low cost) Flow Batteries EV-approved Batteries (safer & commodity cost) New EV-type Batteries Used EV Batteries (Limited Life but Low Cost) 6 3

AEP s s 1 ST Substation Battery This First Utility-Scale NAS Project was Partially Funded by DOE/Sandia 2006 1MW, 7.2 MWh of NaS battery Deferred New Substation 46 kv bus 46kV/12kV Transformer 12/16/20 MVA 12 kv bus Voltage Regulator Tyler Mountain Feeder North Charleston Feeder West Washington Feeder Chemical Station Charleston, W.VA. AEP S&C NGK 7 AEP 2006 Project Peak Shaving Scheduled trapezoidal Charge & Discharge profiles Improved the feeder load factor by 5% (from 75% to 80%) Reduced the oil temperature of the 20MVA supply transformer by about 4 degrees C 2006 + 1.2 MW Charge -1.0 MW Discharge Three Successful Years of Peak Shaving 2007 2008 8 4

AEP Storage 2010 11MW, 75MWh 1 MW, 7.2 MWh installed in 2006 Deferred substation upgrades 3-2MW,14.4 MWH Commissioned in 2009 Implemented Load Following Demonstrated Islanding 4MW, 25MWh substation will be on-line in March 2010 The New Islanding feature is Partially Funded by DOE/Sandia 9 Load Following Peak Shaving Circuit Demand 10 5

Live Islanding Experience NaS Storage Site : Balls Gap, Milton, WV Outage Date: Dec 18, 2009 Outage Cause: Heavy snow Island Size: 25 Customers (small area) Time to island customers: 2 min. Power Outage Duration: 2 Days Time to Exit Island: 6 sec. (not Synchronized) Average Island Load: 167 kw 11 To Optimize Storage Need an energy storage system with the following FOUR key features: 1. Very Close to Customers Backup Power, Buffer Customer Renewables 2. Grid-Connected Load Leveling, Volt / VAR support 3. Utility-Operated Load Diversity (multiple customers on one storage) Improved Safety Optimizing Grid Performance 4. Utility-Owned Standardization & Commodity Pricing Socializing the Cost 12 6

Locational Value of Electricity Storage 765 kv 345 kv 138 kv 69 kv 4 to 34 kv 480 V 120 V 240 V Storage Value Pumped Hydro (Central) Devaluators: No Backup High Security Risk Less effect on losses NaS (Substation) Devaluators: Complex Islanding Storage Size & Location Medium Security Risk CES (Community) Devaluators: Aesthetics Residential Devaluators: Safety Concerns No Load Diversity No Cost Sharing Little Grid Benefits No Standardization Central Units Distributed Units 13 Migratory Path of Energy Storage AEP Graphics adapted from an EPRI Presentation by Joe Hughes Large Central Units Substation Batteries Storage at Grid Edge 14 7

Community Energy Storage (CES) CES is a fleet of small distributed energy storage units connected to the secondary of transformers serving a few houses controlled together to provide feeder level benefits. Key Parameters Power Energy Voltage - Secondary Battery - PHEV Round Trip AC Energy Efficiency Value 25 kw 75 kwh 240 / 120V Li-Ion > 85% 25 KVA Functional Specifications for CES are OPEN SOURCE In 2009 EPRI hosted open webcasts to solicit industry wide input. www.aeptechcenter.com/ces 15 CES A Virtual Substation Battery CES is Operated as a Fleet offering a Multi-MW, Multi-hour Storage Local Benefits: 1) Backup power 2) Voltage correction 3) Renewable Integration CES Substation Power Lines Communication and Control Links 16 8

CES A Virtual Substation Battery CES is Operated as a Fleet offering a Multi-MW, Multi-hour Storage Local Benefits: 1) Backup power 2) Voltage correction 3) Renewable Integration Grid Benefits: 4) Load Leveling at substation 5) Power Factor Correction 6) Ancillary services Integration Platform CES Control Hub Utility Dispatch Center /SCADA Communication & Control Layout for CES Substation CES CES CES CES Power Lines Communication and Control Links 17 CES Layout 18 9

Benefits of CES While CES is, Functionally, a Multi-MW, Multi-hour Substation Battery, It has Inherent Advantages over Larger Batteries located in Substations: 1. More reliable Backup Power to customers (closer) 2. More scalable, flexible implementation (many small units) 3. More efficient in buffering customer renewable sources 4. More synergy with Electric Vehicle batteries (competition) 5. Easier installation and maintenance (240 V) 6. Unit outage is less critical to the grid (smaller) 19 AEP-EPRI SMART GRID DEMO Performance of a fully integrated and robust smart grid from the RTO through to end-use customers. 20 10

AEP Approach to SG Technology Simulations 21 AEP Simulation South Bend 22 11

Challenge: Need for Peak Shaving. Ideal and simple if stored energy is sufficient. However, there is no assurance that stored energy would be adequate and, therefore, peak shaving could be completely ineffective. Inadequate energy on high peak days makes peak shaving ineffective Set Trigger Level 23 Time Triggered Discharge Parameters Set Points: Start Time (same for all days) Minimum Demand below which no energy should be discharged Minimum Demand at for discharge No Discharge on Low demands 2:00 pm Day1 2:00 pm Day2 2:00 pm Day3 24 12

Time Triggered Load Following Simulation Results Time-triggerred Load Following Load (kw) 9000 8000 7000 6000 5000 4000 3000 2000 1000 0 AUGUST 10th - 20th, 2009 Load without Battery Load with Battery 25 Scheduled Discharge (or Charge) Simple but discharges a fixed amount of energy, even on the low peak days 26 13

Scheduled Discharge Parameters Set Points: Start Time Ramp Up duration (min) - T up Flat Duration (hours) - t FLAT Ramp Down Duration (min) t DN Dynamic Inputs: Unit Available Energy Status (Manual, etc.) Unit output (kw, kvar) Voltage Power T up t FLAT t DN Start Time 27 CES Unit Power & Energy Power Case 1 Reported Available energy is sufficient Case 2 Available energy is not sufficient 1.Planner Option (Keep Duration, reduce Power) 2.Dispatcher Option (Keep Power, reduce duration) Power Power 28 14

Scheduled Discharge Simulation Result Scheduled Discharge Load (kw) 8000 7000 6000 5000 4000 3000 2000 Load without Battery 1000 Load with Battery 0 Aug 3rd Aug 4th Aug 5th Aug 6th Aug 7th 29 Lessons Learned & Going Forward. Adequate storage capacity (energy) is needed to meet peak shaving (power) requirements with variable load behavior. Adaptive storage dispatch will permit optimal utilization of storage. Performance for pf correction will be analyzed. Cross-technology: CES will provide flexible integration into other DER schemes like VVC. 30 15

Conclusions AEP plans to deploy Community Energy Storage (CES) as part of its gridsmart SM initiatives. Virtual Power Plant Simulator enables the utility to analyze the performance of a fully integrated and robust smart grid from the RTO through to end-use customer appliances. Tom Walker tjwalker@aep.com Emeka Okafor cokafor@aep.com 31 16