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Planning and Operational Challenges in Interconnected DER … · 2020. 9. 3. · –Need...
Transcript of Planning and Operational Challenges in Interconnected DER … · 2020. 9. 3. · –Need...
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Interconnected- Highly Utilized Grid WorkshopSeptember 29-30, 2016
Interconnected- Highly Utilized Grid WorkshopSeptember 29-30, 2016
Planning and Operational Challenges in Interconnected DER-based Grids
Planning and Operational Challenges in Interconnected DER-based Grids
Santiago GrijalvaGeorgia Institute of Technology
Santiago GrijalvaGeorgia Institute of Technology
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Interconnected GridInterconnected Grid
• Millions of spatially distributed, variable DERs are being connected to the grid.
• Operation needs much better coordination across all subsystems: ISO, utilities, microgrids, buildings, homes.
• Grid is cyber-controlled and more Integrated with other systems (gas, transportation, etc.)
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OverviewOverview
1. Transmission– Spatial Distribution– Utilization, Contingencies, Metrics– Scalable Decentralized Optimization
2. Distribution– Multi-layer Cyber-Physical System– Distribution System Operator (DSO) Simulator– Distribution PV Hosting Capacity
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Transmission UtilizationTransmission Utilization
• Line Capacity Utilization– Eastern Interconnection, Sumer Peak 2016, Normal Operation
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UtilizationUtilization
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Desired Higher Utilization
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Weak Elements/Severe ContingenciesWeak Elements/Severe Contingencies
• Eastern Interconnection, N-1 Contingencies (80k+)– Weak Elements are overloaded under many contingencies– Sever Contingencies overload many elements.
• Insecurity Metric: Aggregate MW Contingency Overload. • Has been increasing year after year.
61,000800600400200
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Transmission PlanningTransmission Planning
• Currently resource and transmission planning are not well integrated. Difficulty handling:– Full AC models, voltage constraints, and limits due to
voltage and transient stability.– Emerging technologies: routers, switching, DC.– Large number of scenarios.
• Challenges:– Integrated gen + demand + DER, + transmission planning. – Must handle order of magnitude increase in control variables.– Intertemporal behavior, integer variables, non-convexities.– New controls, devices, operational structures. – Interactions with other infrastructures.
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Scalable Decentralized OptimizationScalable Decentralized Optimization
• Example: Unit Commitment– Large-Scale ISO realistic data– Full UC model: reserve, CSU, CSD, ….17k+ constraints.
– Problem solved orders of magnitude faster.
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OverviewOverview
1. Transmission– Spatial Distribution– Utilization, Contingencies, Metrics– Scalable Decentralized Optimization
2. Distribution– Multi-layer Cyber-Physical System– Distribution System Operator (DSO) Simulator– Distribution PV Hosting Capacity
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Emerging Complexity in DistributionEmerging Complexity in Distribution
• DER integration: – PV, Wind, EV, Demand Response, CHP. – Microgrids, Virtual Power Plants
• Active customers/prosumers• Microgrids• Smart distribution devices/smart appliances• AMI creates a wealth of data that can be exploited• Evolving marketplaces• Utility business models
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Layered Energy Cyber-Physical SystemLayered Energy Cyber-Physical System
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DSO Simulation Studio (ARPA-E Open 2015)DSO Simulation Studio (ARPA-E Open 2015)
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• A Multi-Layer SimulatorDSO Simulation Studio
Devices Controllers: Intelligent ControllersPower Electronics, Protections, Sensors
Market
System
Time Series DER Quasi-Steady State Solver
Power Grid: Wires, Transformers, Capacitors, etc. DER: Flexible Load, Solar PV, Storage, CHP, Wind, EV
Locational-Temporal Pricing Module
Security Modeling
Forecasting Multi-Agent Prosumer Model
DSO Design and Policy Engine
DSO Rules
Regulators
Market Participants
UtilityEngineers
Developers
Decentralized Energy Scheduling
DER Services
DER Services Valuation
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DSO Simulator Expected FeaturesDSO Simulator Expected Features
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• Decentralized energy scheduling of DER-rich systems of arbitrary size.
• Explicit modeling of energy services transacted in the DSO.
• Locational and time-vector pricing of P/Q, ancillary, and security services.
• 3D Interactive Visualization• Analytics and valuation of DER
services, DSO rules, and business models.
• Simulation of multi-scale interactions of DSO with up-stream ISO, same level DSOs, and downstream (microgrid, building, and home) prosumer subsystems.
3D Visualization Concept
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PV Hosting CapacityPV Hosting Capacity
• How much PV can we put on a distribution circuit?• Constraints:
– Under and over-voltages– Thermal limits– Protections– Back-feeding
• Complexity– Variability (seasonal, daily, second to second). – Need quasi-static time series (QSTS) Simulation
• One-year, at 1 sec granularity (31M solutions). – Local and distributed PV– Effect of controllers and smart inverters
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PV Impact and Hosting CapacityPV Impact and Hosting Capacity
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QuantizationQuantization
• Various methods for computation improvement: circuit reduction, parallelization.
• Recent improvements: quantization– Accurate results, ~ 5% of solutions compared to brute-force.
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Towards DER Hosting CapacityTowards DER Hosting Capacity
• Challenges:– System impact and hosting capacity determination for solutions
with all types of DERs, (e.g. solar + storage). – Hosting capacity for circuits that already host complex DERs.