DG Modeling Challenges & Results. Jens Schoene

Similar documents
Distribution Operations with High-penetration of Beyond the Meter Intermittent Renewables. Bob Yinger Southern California Edison April 15, 2014

Distributed Generation: Feeder Hosting Capacity. Dean E. Philips, P.E. FirstEnergy Service Corp Manager, Distribution Planning & Protection

Size template. Grid Connection Masterclass Energex John Lansley Senior Network Solutions Engineer

MODELING DISTRIBUTION SYSTEM IMPACTS OF SOLAR VARIABILIY AND INTERCONNECTION LOCATION

Session 10: General Overview of Interconnection Standards & Grid Codes for High Penetration PV October 21, 2015 Santiago, Chile

Electric Distribution System Simulation and Analysis Tools

Integration of Distributed Generation in the Power System. IEEE Press Series on Power Engineering

Solar Variability and Forecasting

SCE Experience with PV Integration

Modeling of PV Based Distributed Generator Systems with Diverse Load Patterns

Solar Power Plant Design and Interconnection

Step Voltage Regulators

APPLICATION NOTE. Increasing PV Hosting Capacity on LV Secondary Circuits with the Gridco System empower TM Solution

Guidelines for Large Photovoltaic System Integration

Modeling and Testing of Unbalanced Loading and Voltage Regulation

PSEG-LONG ISLAND SMART GRID SMALL GENERATOR INTERCONNECTION SCREENING CRITERIA FOR OPERATING IN PARALLEL WITH LIPA S DISTRIBUTION SYSTEM

Overcurrent Protection for the IEEE 34 Node Radial Test Feeder

Green Power Connection Net Energy Metering Engineering Review Process in Delaware and Speeding Up the Application Fee Process

Distributed Generation and the Impact on a Distribution System. Brian Lassiter Technical Sales Engineer

Distributed Generation Interconnection Collaborative (DGIC)

Simulated PV Power Plant Variability: Impact of Utility-imposed Ramp Limitations in Puerto Rico

Siemens Hybrid Power Solutions. Cost and emission reduction by integrating renewables into diesel plants

Distribution System Analysis Tools for Studying High Penetration of PV with Grid Support Features

Engineering innovation

Integration Capacity Analysis Workshop 11/10/15 California IOU s Approach

Experimental Verification of Advanced Voltage Control for Penetration of PV in Distribution System with IT Sectionalizing Switches

Energy Storage for Renewable Integration

VOLTAGE CONTROL IN DISTRIBUTION SYSTEMS AS A LIMITATION OF THE HOSTING CAPACITY FOR DISTRIBUTED ENERGY RESOURCES

Advanced Inverter Overview

Advanced Protection of Distribution Networks with Distributed Generators

RENEWABLE ENERGY INFEED R Herman, M Malengret and CT Gaunt University of Cape Town, South Africa

TECHNICAL INTERCONNECTION REQUIREMENTS FOR DISTRIBUTED GENERATION. Micro Generation & Small Generation, 3-phase, less than 30 kw

Rule Fast Track Analysis for National Life Insurance Co.

Power Quality & Custom Power

SOLAR FORECASTING AND GRID INTEGRATION

De Jaeger, Emmanuel ; Du Bois, Arnaud ; Martin, Benoît. Document type : Communication à un colloque (Conference Paper)

Electric Power Systems An Overview. Y. Baghzouz Professor of Electrical Engineering University of Nevada, Las Vegas

Overview of BNL s Solar Energy Research Plans. March 2011

About Southern California Edison

U.S. Department of Energy

Preparing for Distributed Energy Resources

What are the basic electrical safety issues and remedies in solar photovoltaic installations?

N.J.A.C. 14:8-4 NET METERING FOR CLASS I RENEWABLE ENERGY SYSTEMS

MICROGRIDS FOR DATA CENTERS

Impact of electric vehicles on the IEEE 34 node distribution infrastructure

SPECIFICATION COG-2007

Balancing and Reserve Power by PV Plants. Ken Christensen MSEE, BSEE Global Product Manager, SMA Utility-Scale and Hybrid Solutions

Satellite-Based Software Tools for Optimizing Utility Planning, Simulation and Forecasting

Distributed Generation and Power Quality Case Study

What Matters for Successful Integration of Distributed Generation

General Validation Test Program for Wind Power Plants Connected to the Hydro-Québec Transmission System

Research and Development: Advancing Solar Energy in California

Transmissão em Corrente Contínua

High Penetration of Distributed Solar PV Generation

Medium-voltage Transformers

Power System review W I L L I A M V. T O R R E A P R I L 1 0,

Assessment of power swing blocking functions of line protective relays for a near scenario of the Uruguayan system

Enterprise Approach to OSIsoft PI System

Substation Automation and Smart Grid

Totally Integrated Power SIESTORAGE. The modular energy storage system for a reliable power supply.

Operating the power system while enabling more renewables : which solutions?

Smart Grid and Renewable Energy Grid Integration. Jian Sun, Professor and Director Department of ECSE & Center for Future Energy Systems

Duke Energy Photovoltaic Integration Study: Carolinas Service Areas

Fleet Management and Grid Integration of PV Generating Stations

Cahier technique no. 196

Key Concepts Of Distributed Generation

Grid Modernization Distribution System Concept of Operations. Version 1.0

The Different Types of UPS Systems

Analysis of requirements in selected Grid Codes. Willi Christiansen & David T. Johnsen

Fundamentals of Power

ADMS(Advanced Distribution Management System ) in Smart Grid

Developing a Utility/Customer Partnership To Improve Power Quality and Performance

Energy Cost Reduction through Load Balancing & Load Shedding

COMMENTS OF THE SOLAR ALLIANCE NEW JERSEY INTERCONNECTION RULES APRIL 29 TH, 2011

Public Service Co. of New Mexico (PNM) - PV Plus Storage for Simultaneous Voltage Smoothing and Peak Shifting

GENERATOR DIFFERENTIAL PROTECTION RELAY STABILITY VIS-A -VIS SELECTION OF CTS MR. H. C. MEHTA & MR. JAY MEHTA Power Linker Group Co.

Grid integration of renewable energy

ETAP 11 The Future of Power Systems Engineering & Operation - Today

DC TRANSMISSION BASED ON VOLTAGE SOURCE CONVERTERS

FUNCTIONS AND CAPABILITIES OF PV INVERTERS TO BE PART OF A SMART GRID

CO-ORDINATION OF PARALLEL AC-DC SYSTEMS FOR OPTIMUM PERFORMANCE

SDG&E Electric Distribution System Interconnection Handbook. <Revised as of 10/21/2015>

Power Quality Standards for Electric Service

The Different Types of UPS Systems

Executive summary 2. 1 Introduction 4

Energy Storage Market Overview MADRI 3/3/2015 John Fernandes Policy & Market Development Manager

The Different Types of UPS Systems

Study to Determine the Limit of Integrating Intermittent Renewable (wind and solar) Resources onto Pakistan's National Grid

Distributed Generation: Benefits & Issues

Simulating Solar Power Plant Variability for Grid Studies: A Wavelet-based Variability Model

Voltage regulation in distribution systems - Tap changer and Wind Power

Transcription:

DG Modeling Challenges & Results Jens Schoene December 13, 2013

2 Outline PV Caused Issues on Distribution Systems Modeling Challenges Case Study

3 PV Caused Issues on Distribution Systems

4 Potential PV-caused issues Category Reverse Power Flow Voltage Fluctuation Feeder Section Loading Issue Overcurrent protection gets confused -> false trips, no trips Line regulators get confused -> high/low voltage on DG side Capacitor switching, Load Tap Changer (LTC) operation, and line Voltage Regulator (VR) operation caused by cloud shading. Flicker caused by step voltage change during switching. Capacitor switching transients (synchronous closing, preinsertion impedance, point-on-wave) Low/medium PV penetration -> PV offsets load thereby decreasing section loading High PV penetration -> PV may exceed base load, capacity sufficient to distribute surplus power? Power Losses PV changes loading (see row above). Impact on losses

5 More potential PV-caused issues Category Fault Current Unintentional Islanding Ground Fault Overvoltage Harmonics Dynamics Feeder Imbalance Issue PV increases fault current. Impact on relay protection. Utility system reclosing into live island may damage switchgear and loads. Single-phase fault -> TOVs on unfaulted phase. Harmonics caused by PV inverter Effect of fast transients caused by cloud shading and system disturbances. Dynamic interaction of transients with other conventional and non-conventional control devices. Imbalance caused by uneven distribution of PV causing Neutral-to- Earth voltages, Overloaded Neutrals

Modeling Challenges 6

7 Picking the right tool for the job Load Flow, balanced Load Flow, unbalanced Short Circuit Relay Coordination Arc Flash Harmonics Transient Analysis Dynamic Analysis Quasi Steady- State Analysis ATP, EMTP-RV, Simulink, PSCAD Aspen, Cape DesignBase, PowerFactory, Gridiant NexHarm PSLF, PSS/E OpenDSS GridLAB-D Best choice Can be done, but not preferred choice Cannot be done

Large Systems 8

9 Lots of variability Monthly variation (season) Net-PV profile of a residential unit Variation over hours and minutes (time of day, clouds)

10 Dealing with variability: Easy Way Make simplifying assumptions: All PVs follow the same generation curve. Accurate for a clear day, not accurate for cloudy day. Conservative when looking at overvoltages. Not conservative for voltage regulations. All loads follow the same load curve. Never accurate. Ignores changing nature of loads.

Case Studies 11

45 PV generators (actual) PV ID Power, kw PV ID Power, kw 1 3 24 5 2 1.9 25 2.5 3 3.7 26 2.5 4 5.4 27 7.5 5 6 28 6.835 6 2.4 29 6.8 7 65 30 9.2 8 1.1 31 4.68 9 4.3 32 7.8 10 3.6 33 3.152 11 1.5 34 5 12 2.9 35 7 13 3.5 36 5.4 14 5 37 4.3 15 6.472 38 999 16 2.4 39 998.9 17 8.28 40 8.8 18 2.5 41 7.1 19 5.4 42 4.8 20 6.7 43 4.8 21 10.4 44 2.4 22 2.2 45 33.2 23 5.1 12

432 PV generators (future scenario) Two large 1 MW PVs Simulations run with and without large PVs Effect of centralized PV vs distributed PV 13

14 Cloud Tracking Impact of High PV Penetration on Distribution Feeders in the USA

Accounting for Cloud Movement 15

16 Different PV production at different locations during same time

Disaggretating Loads Disaggregating 10 loads (shown for illustrative purpose) Disaggregating all residential loads used in our simulation 17

Simulation Scenarios 1. Low (actual) penetration of small PV w/ 2 MW PV 2. Low (actual) penetration of small PV w/o 2 MW PV 3. High penetration of small PV w/ 2 MW PV 4. High penetration of small PV w/o 2 MW PV 18

19 Simulation Cases: Residential Feeder Case # Load PV Resolution Sky Condition Aggregated Aggregated 0 Yes Yes 1 h Cloudy to Overcast 1 Yes Yes 30 sec Cloudy to Overcast 2 No Yes 30 sec Cloudy to Overcast 3 Yes No 30 sec Cloudy to Overcast 4 No No 30 sec Cloudy to Overcast 5 No No 1 h Cloudy to Overcast 6 No Yes 30 sec Clear

Residential PV: Tapchange Operation 20 PV significantly increases tap changing operations. Case 2 (PV aggregated) vs. Case 4 (no PV aggregation). Cases 0 and 5, 1 hour simulation step size (vs. 30 seconds for other cases). Case 6, clear day.

21 Residential PV: Voltage Profile 5% voltage limit PV raises voltage over permissible limit (at some locations, at some times).

Conclusions 22

Selected Conclusions Effect of aggregating PV generation Exaggerates the actual tap changing operations for high-pv penetration scenarios Model predicted tap changes = Actual tap changes Increasing PV on a Feeder Tap changes predicted from models that use aggregated PV generation Actual tap changes 23

24 Some Observations Reactive Power Use Tap Changes Real Power Use Increasing PV on a Feeder Line Losses Comprehensive CSI report publicly available here (do not confuse with Final Report of the same name): http://calsolarresearch.ca.gov/funded-projects/65-improvingeconomics-of-solar-power-through-resource-analysisforecasting-and-dynamic-system-modeling Improving Economics of Solar Power through Analysis, Forecasting, and Dynamic System Modeling. October 2013. Schoene, J. (Director of Research Studies, EnerNex) and J. Kleissl (Assoc. Prof., UC San Diego). University of California, San Diego

Discussion 25

Backup 26

Issues depend on PV penetration 27 level & feeder characteristics

28 What type of tools are out there? Operational Tools Online operation Facilitate real-time operational decision regarding voltage regulation, transformer loading, PQ, etc. Gridiant s GRIDview, PowerAnalytic s Paladin Live, Paladin SmartGrid Planning/Analysis Tools Offline simulations Facilitate planning/design decisions Look at what if scenarios

We have lots of tools 29

30 Automatic System Conversion CYME SynerGEE Electric EMTP-RV Centralized Data Format In MATLAB Based on OpenDSS OpenDSS OpenDSS File

31 Use of Solar Irradiance Data Historical irradiance data facilitate realistic simulations to determine overvoltages, equipment wear, protection issues, etc. Forecasting data useful for dispatch (ramp rates). Total generation fleet must have sufficient operational flexibility to reliably integrate variable renewable generation. Forecasting data potentially useful for voltage regulation.

32 Conclusions: Residential PV PV caused overvoltage => additional voltage regulators required PV increased tap changing operation of voltage regulators increased => loss-of-life and increased maintenance

OpenDSS 33

OpenDSS 34

OpenDSS 35

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information