WECC REMTF Workshop Spencer Tacke WECC Renewable Energy System Models Workshop March 9, 2016.

Slides:

Advertisements

Similar presentations

1 TSS Report PCC Meeting Salt Lake City, UT October 26-27, 2006.

Advertisements

Questions about AVR & PSS

Model Specification Requirements MSRATF Meeting – Mar 11, 2013 Stephanie Lu, MVWG Chair Seattle City Light.

Photos placed in horizontal position with even amount of white space between photos and header Sandia National Laboratories is a multi-program laboratory.

New Energy Horizons Opportunities and Challenges Fault Current Contributions from Wind Plants Dean Miller PacifiCorp July 25,

Siemens Power Technologies International

Wind Turbine Session 4.

Updated 1/28/2011. Technical Requirements & Regulatory Issues In Interconnection Agreements March 9, 2011 Jay Caspary ·

Renewable Energy in Islamic Republic Of Iran

System Strength Discussion

Transition Plan for Removing Wind Phase 1 Generic Models

Power Systems Consulting and Software 4 March 2004 BWEA Conference: UK Offshore Wind 2004 Integration of Offshore Wind Farms into the Local Distribution.

User Experience with New Solar PV Models California ISO

Wind energy in NZ 20% wind by 2030 Eric Pyle, Chief Executive, NZ Wind Energy Association.

North American Strategic Infrastructure Leadership Forum October 12, 2011.

1 The Effects of Integrating Wind Power on Transmission System Planning, Reliability, and Operations Phase 1 Preliminary Overall Reliability Assessment.

WECC Renewable Energy Modeling Workshop Conducted by the WECC Renewable Energy Modeling Task Force (REMTF) and Modeling and Validation Work Group (MVWG)

THE TRES AMIGAS SUPERSTATION Southwest Renewable Energy Conference Santa Fe, NMSeptember 16 th 2010 UNITING THE NATION’S ELECTRIC POWER GRID.

EPRI CIM for Dynamic Models Project Report Terry Saxton Xtensible Solutions May 13, 2009.

Integrating Renewables Gloria Godson Energy Bar Association December 3,

THE TRES AMIGAS SUPERSTATION IIEA - Dublin October 8, 2010 UNITING THE NATION’S ELECTRIC POWER GRID.

Distributed Generation

1 The Tres Amigas SuperStation VLPGO November 2011.

Grid, Smart grid, CURENT. Basic components of the Electric Grid Power Plant- Electricity generation Transmission- Transmit electricity to different areas.

1 Renewable Technology Working Group (RTWG) July 14, 2009 Henry Durrwachter.

ECE 576 – Power System Dynamics and Stability Prof. Tom Overbye University of Illinois at Urbana-Champaign 1 Lecture 23: Renewable.

20th Century Electric Transmission Grid

THE TRES AMIGAS SUPERSTATION ABB Western Utility Executive Conference September 28, 2010 UNITING THE NATION’S ELECTRIC POWER GRID.

B O N N E V I L L E P O W E R A D M I N I S T R A T I O N Page 1 Pacific Northwest Smart Grid Demonstration Project  Largest Smart Grid Demonstration.

Integrating Wind Energy Capabilities of Wind Power Plants Mark Ahlstrom Wind Energy: A Good Citizen of the Electric Grid Four Corners Wind Resource Center.

What’s happening in Spain? Access to the grid request of STE projects by Oct MW.

Overview OF MULTI Mega Watt WIND TURBINES and wind parks

Planning the Networked Grid Transmission Planning J.E.(Jeff) Billinton Manager, Regional Transmission - North Building the Networked Electricity Grid –

RECENT TRENDS IN POWER SYSTEMS

NERC LMTF: Current Activities Ryan Quint, PhD, PE Staff Coordinator, NERC Load Modeling Task Force WECC MVWG Meeting June 2016.

INDUCTION GENERATOR FOR WIND POWER GENERATION

Eric Peirano, Ph.D., TECHNOFI, COO

Modeling DER in Transmission Planning CAISO Experience

Minnesota Renewable Energy Integration and Transmission

Power Electronics and Control in Wind Energy Conversion Systems

IG BASED WINDFARMS USING STATCOM

Western Electricity Coordinating Council Renewable Energy Modeling Task Force REMTF Report to MVWG Abraham Ellis, Sandia March 18, 2015 Salt Lake.

APEC 21st Century Renewable Energy Development Initiative

Sustainable Energy Planning for Autonomous Power System of Crete

Intelligent Power Module

Design of Electric Power Systems and Utilities

Transition Plan for Removing Wind Phase 1 Generic Models

Reliability Assessment Committee Reliability Workshop Priorities

WECC REMTF Workshop Spencer Tacke

CMPLDWG Composite Model with Distributed Generation Approval

NERC-WECC Coordination

Jonathan young ColumbiaGrid

Transforming Scenario Narratives into Study Cases

NERC-WECC Coordination

Byron Woertz, Manager—System Adequacy Planning

MODELING DG IN BASE CASES

Siemens Power Technologies International

Reliability Assessment Committee Reliability Workshop Priorities

Modeling Subcommittee (MS) Updates

Western Electricity Coordinating Council Renewable Energy Modeling Task Force REMTF Report to MVWG Abraham Ellis, Sandia March 18, 2015 Salt Lake.

MODELING DG IN BASE CASES

CMPLDWG Composite Model with Distributed Generation Approval

Byron Woertz, Manager—System Adequacy Planning

Donald Davies Chief Senior Engineer

User Experience with New Solar PV Models California ISO

Transition Plan for Removing Wind Phase 1 Generic Models

Model Validation for Large Scale PV Plants

WECC REMTF Workshop Spencer Tacke

WECC REMTF Workshop Spencer Tacke

Chapter HEAT AND ELECTRICITY GENERATION AND SYSTEM INTEGRATION

Presentation transcript:

WECC REMTF Workshop Spencer Tacke WECC Renewable Energy System Models Workshop March 9, 2016

REMTF Workshop  Accurate, validated models are required for reliable and economic power system operations  NERC Reliability Standards require that power flow and dynamics models be provided 2

REMTF Workshop  Under WECC modeling guidelines (i.e., Generating Unit Model Validation Policy), all wind and PV power plants with aggregated capacity 20 MVA or larger must be modeled explicitly in WECC power flow and dynamics base cases, using models in the WCC Approved Dynamic Model Library  Manufacturer-specific dynamic models commonly provided for interconnection studies are not adequate for regional planning. WECC requires the use of approved models. 3

Recent Data Gathered by PPMVDTF  WECC base cases have close to 29 GW of total wind generation  74 plants with 5 GW of generating capacity are connected at 24 to 35-V level, and therefore have no collector system representation  94 plants with 5.2 GW of generating capacity have no dynamic models  54 plants with 2.8 GW of generating capacity are modeled with inappropriate dynamic models 4

REMTF Workshop  There is a significant opportunity for model improvement  The REMTF (under the MVWG) has led a multi- year effort developing dynamic models for wind and PV generators  The effort has been a broad industry effort  The collaborative community has worked under the auspices of the WECC and the REMTF, and the developed models have been WECC approved and are in major commercial software platforms 5

Wind Generation Dynamic Models  Development was done in phases  Initial implementation of type 3 and 4 types represented a limited set of manufacturers  Recently developed second generation models have the capabilities to capture a wider group of wind generation turbine makes and models 6

Grid-Connected PV Systems  Most are residential and commercial scale connected to distribution networks  But many are large generation facilities connected to the transmission system 7

Second Generation Models They were developed deliberately in a modular format to facilitate the ability to add new features and functions to the library of models without significant effort  1 st generation models were developed without the flexibility to represent various vendor equipment  2 nd generation models were developed with more flexibility and were validated against several vendor data 8

Goals of Second Generation Generic Models  Allow for easy implementation of new modules to build on existing components and allow for the ever-growing and changing technology, and  Allow for emulation of a wider range of control philosophies and thus the ability to be parameterized for representing a wide range of equipment 9

Wind Turbine Diagrams 10

The 2 nd Generation Renewable Energy System (RES) Models ModelFunction1 st or 2 nd Generation regc_aRES Generator/Converter Model2 nd reec_aRES Electrical Controls Model A2 nd reec_bRES Electrical Controls Model B2 nd reec_cRES Electrical Controls Model C2 nd repc_aRES Plant Controls Model A2 nd repc_bRES Plant Controls Model B2 nd (not yet finalized) wtgt_aWTG Turbine Shaft Model A2 nd wtgar_aWTC Aero-dynamic Model A2 nd wtgpt_aWTG Pitch Controller Model A2 nd wtgtrq_aWTG Torque Controller Model A2 nd wt1p_bPitch Controller for type 1 WTG Model B2 nd wt1gType 1 WTG generator model1 st wt1tType 1 WTG turbine shaft model1 st wt2gType 2 WTG generator model1 st wt2eType 2 WTG variable external rotor resistance controller1 st wt2tType 2 WTG turbine shaft model1 st lhvrtlow/high voltage ride-through relay model1 st lhfrtlow/high frequency ride-through relay model1 st 11

The 2 nd Generation RES Models RESModel Combination Type 1 WTGwt1g, wt1t, wt1p_b Type 2 WTGwt2g, wt2e, wt2t, wt1p_b Type 3 WTGregc_a, reec_a, repc_a, wtgt_a, wtgar_a, wtgpt_a, wtgtrq_a Type 4 WTGregc_a, reec_a, repc_a (optional: wtgt_a) PV plantregc_a, reec_b (or reec_a), repc_a BESSregc_a, reec_c (optional: repc_a) 12

The 2 nd Generation RES Models 13

The 2 nd Generation RES Model: WTG Type 1 and Type 2 14

The 2 nd Generation RES Model: WTG Type 3 15

The 2 nd Generation RES Model: WTG Type 4 16

The 2 nd Generation RES Model: PV 17

References WECC 2 nd Generation WTG Model Specifications: Wind-Turbine-Models pdf Wind-Turbine-Models pdf WECC PV Model Specifications: Model-Specification-September-2012.pdf Model-Specification-September-2012.pdf WECC PV Modeling Guide: amic%20Modeling%20Guidelines.pdf amic%20Modeling%20Guidelines.pdf WECC WTG Modeling Guide: amic%20Modeling%20Guidelines.pdf amic%20Modeling%20Guidelines.pdf Model User Guide for Generic Renewable Energy System Models: ductId= ductId=