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WESEP REU June 3, 2013 Iowa State University. Electric Power Industry Overview. James D. McCalley Harpole Professor of Electrical & Computer Engineering. Outline. The electric power industry Control centers Electricity markets. 2. Organizations comprising the Electric Power Industry. - PowerPoint PPT Presentation
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WESEP REUJune 3, 2013
Iowa State University
Electric Power Industry Overview
James D. McCalleyHarpole Professor of
Electrical & Computer Engineering
Outline1. The electric power industry2. Control centers3. Electricity markets
2
Organizations comprising the Electric Power IndustryOrganizations comprising the Electric Power Industry• Investor-owned utilities: 239 (MEC, Alliant, Xcel, Exelon, …)• Federally-owned: 10 (TVA, BPA, WAPA, SEPA, APA, SWPA…)• Public-owned: 2009 (Ames, Cedar Falls, Muscatine, …)• Consumer-owned: 912 (Dairyland, CIPCO, Corn Belt, …)• Non-utility power producers: 1934 (Alcoa, DuPont,…)• Power marketers: 400 (e.g., Cinergy, Mirant, Illinova, Shell Energy, PECO-
Power Team, Williams Energy,…)• Coordination organizations: 9 (ISO-NE, NYISO, PJM, MISO, SPP, ERCOT,
CAISO, AESO, NBSO), 7 are in the US.• Oversight organizations:
• Regulatory: 52 state, 1 Fed (FERC)• Reliability: 1 National (NERC), 8 regional entities• Environment: 52 state (DNR), 1 Fed (EPA)
• Manufacturers: GE, ABB, Toshiba, Schweitzer, Westinghouse,…• Consultants: Black&Veatch, Burns&McDonnell, HD Electric,…• Vendors: Siemens, Areva, OSI,…• Govt agencies: DOE, National Labs,…• Professional organizations: IEEE PES …• Advocacy organizations: AEWA, IWEA, Wind on Wires…• Trade Associations: EEI, EPSA, NAESCO, NRECA, APPA, PMA,…• Law-making bodies: 52 state legislatures, US Congress
3
4
Apr 1990: UK Pool
opens
Jan. 1991: Norway launches Nordpool
Jan. 1996: Sweden in Nordpool
Oct 1996: New
Zealand NZEM
Jan 1998: PJM ISO created
Mar 1998: Cal ISO opens
Jan. 1998: Finland in Nordpool
Dec 1998: Australia
NEM opens
Nov 1999: NY ISO launches
May 1999: ISO-NE opens
Jan. 2000: Denmark in
Nordpool
Mar 2001: NETA
replaces UK Pool
July 2001: ERCOT becomes
one control
area May 2002:
Ontario IMO
launches
North America
1990 1992 2000 1998 1996 1994
Jan. 2001: Alberta Pool opens
Overseas
2002 2004 2006
Dec 2001 MISO becomes first RTO
Feb 1996 MISO formed.
April 2005 MISO Markets Launch
1996: ERCOT becomes ISO.
Jan 2002 ERCOT opens retail zonal mrket
2008 Feb 2007 SPP Markets Launch
Dec 2008 ERCOT Nodal Market
Launched
Big changes between 1992 and about 2002….Big changes between 1992 and about 2002….
1900-1996/2000
G G
G
G
G
G
G
G
TransmissionOperator
IndependentSystem
Operator
TransmissionOperator
TransmissionOperator
Today
G G G
G
G
G
G G
Transmission and System Operator
Vertically Integrated Utility
IndependentSystem
Operator
5
What are the North American Interconnections?What are the North American Interconnections?
“Synchronized”
6
What is NERC?What is NERC?• NERC: The North American Reliability Corporation, certified by federal government
(FERC) as the “electric reliability organization” for the United States.• Overriding responsibility is to maintain North American bulk transmission/generation
reliability. Specific functions include maintaining standards, monitoring compliance and enforcing penalties, performing reliability assessments, performing event analysis, facilitating real-time situational awareness, ensuring infrastructure security, trains/certifies system operators.
• There are eight NERC regional councils (see below map) who share NERC’s mission for their respective geographies within North America through formally delegated enforcement authority
• Western Electricity Coordinating Council (WECC)
• Midwest Reliability Organization (MRO)• Southwest Power Pool (SPP)• Texas Reliability Entity (TRE)• Reliability First Corporation (RFC)• Southeast Electric Reliability Council
(SERC)• Florida Reliability Coordinating Council
(FRCC)• Northeast Power Coordinating Council
(NPCC)
7
What is FERC?What is FERC?• An independent agency that regulates the interstate transmission of electricity,
natural gas, and oil. It does the following:• Regulates transmission & wholesale sales of electricity in interstate commerce;• Regulates all wholesale natural gas transmission;• Reviews mergers/acquisitions /corporate transactions by electricity companies; • Can review some siting applications for electric transmission projects;• Licenses and inspects private, municipal, and state hydroelectric projects;• Protects the reliability of the high voltage interstate transmission system through
mandatory reliability standards; • Monitors and investigates energy markets; • Enforces FERC regulatory requirements via civil penalties/other means;• Oversees environmental matters related to natural gas/hydroelectric projects; • Administers accounting/financial reporting regs+conduct of regulated companies
• FERC does not:• Regulate retail electricity and natural gas sales to consumers;• Regulate activities of municipals or federal power marketing agencies;• Regulate nuclear power plants (NRC does this);• Address reliability problems related to failures of local distribution facilities; • Consider tree trimmings near local distribution power lines in residential
neighborhoods
8
Regional Transmission Organizations/Independent System OperatorsRegional Transmission Organizations/Independent System Operators• The regional system operator: monitors and controls grid in real-time• The regional market operator: monitors and controls the electricity markets• The regional planner: coordinates 5 and 10 year planning efforts• They own no electric power equipment.• None of them existed before 1996.• They are central to electricity production and transmission today.
9
Energy Control CentersEnergy Control Center (ECC):
• SCADA, EMS, operational personnel• “Heart” (eyes & hands, brains) of the power system
Supervisory control & data acquisition (SCADA):• Supervisory control: remote control of field devices, including gen• Data acquisition: monitoring of field conditions• SCADA components:
» Master Station: System “Nerve Center” located in ECC» Remote terminal units: Gathers data at substations; sends to Master
Station» Communications: Links Master Station with Field Devices, telemetry is
done by either leased wire, PLC, microwave, or fiber optics.
Energy management system (EMS)• Topology processor & network configurator• State estimator and power flow model development• Automatic generation control (AGC), Optimal power flow (OPF)• Security assessment and alarm processing
10
Energy control centers
11
SubstationRemote terminal unit
SCADA Master Station
Com
mun
icati
on li
nk
Energy control center with EMS
EMS alarm displayEMS 1-line diagram 12
ECCs: EMS & SCADA
13
ECCs: SCADA, Telemetry, EMS, RT, DA Markets
SCADA
Breaker/Switch Status Indications
System Model Description
Telemetry & Communications equipment
State Estimator
Network Topology program
AGC
SCED1 Contingency
Analysis & Loss Analysis
ContingencyAlarms
Updated System Electrical Model
Analog Measurements
Display to Operator
Power flows, Voltages etc.,
Display to Operator
Bad Measurement Alarms
Generator Outputs, Frequency, Tie-line flows
Generation Raise/Lower Signals
State Estimator Output
(AC power flow)
Substation and power plant RTUs
Display to Operator
SCED2
Gen base points
SCUC Real-time operating plan
Intra-day reliability unit commitment (RAC)
SCUC Day-ahead operating plan
Day-ahead reliability unit commitment (RAC)
SCUC
SCED3
Nodal injections
Contingency constraints &
loss sensitivities
SFT
Pre-defined
constraint list
Day-ahead market solution
Day-ahead market
Locational marginal
prices
EMS
Real-time market
Intra-day & day-ahead reliability unit commitment (RAC)
Day-ahead market
Automatic Generation Control (AGC) is a feedback control system that regulates the power output of electric generators to maintain a specified system frequency and/or scheduled interchange.
14
Balancing authorities
Performs AGC within designated area.105 BAs in N. Am.: 67 in EI, 38 in WI, 1 in Texas.Every ISO is a BA. Not every BA is an ISO.
15
Basic market design used by all ISOs today.
Schedules entire “next-day” 24hr period.
Schedules interchange for entire “next-day” 24hr period, starting at current hour, optimizing one hour at a time (1 value per hr)
Computes dispatch every 5 minutes.
16
Balancing Systems
NETWORKAUTOMATIC GENERATION
CONTROL SYSTEM
REAL-TIME MARKET
1 sol/5min gives 1 oprtng cdtn
DAY-AHEAD MARKET
1 sol/day gives 24 oprting cdtns
ENERGY & RESERVE SELL OFFERS
ENERGY BUY BIDS
FREQUENCY DEVIATION FROM 60 HZ
ENERGY BUY BIDS
REQUIRED RESERVES
ENERGY & RESERVE SELL OFFERS REQUIRED
RESERVES
minΣΣ zit{Cost(GENit)+Cost(RSRVit)}sbjct to ntwrk+status cnstraints
minΣΣ {Cost(GENit)+Cost(RSRVit)}sbjct to ntwrk cnstraints
LARGE MIXED INTEGER PROGRAM
LARGE LINEAR PROGRAM
BOTH CO-OPTIMIZE: energy & reserves
17
Basics of electricity markets
1. Locational marginal prices (LMPs), $/MWhr, indicate the energy price at each bus.
2. Markets compute LMPs via an internet-based double auction that maximizes participant benefits. The LMPs are computed from SCED every hour in the DAM and every 5 minutes in the RTM.
3. The DAM and the RTM are 2 separate settlement processes.
18
Internet-based two-sided auction markets
Internet System
B1
B2
B3
S1
S2
Sellers submit offers to sell in terms of •Price ($/MWhr)•Quantity (MWhr)
Buyers submit bids to buy in terms of •Price ($/MWhr)•Quantity (MWhr)
Price at which seller is willing to sell increases with amount (cost of producing 1 more energy unit increases as a gen is loaded higher)
Price at which buyer is willing to buy decreases with amount (first unit is used to supply most critical needs and after those needs are satisfied, next units of energy are used to satisfy less critical needs)
Offers to sell 1 MWhr Bids to buy 1 MWhrS1 S2 B1 B2 B3
$10.00 $10.00 $70.00 $70.00 $25.00$50.00 $50.00 $70.00 $50.00 0$65.00 $70.00 $65.00 $25.00 0$70.00 $70.00 $65.00 0 0
∞ ∞ 0 0 0∞ ∞ 0 0 0∞ ∞ 0 0 0
This table orders offers and bids for each agent.
19
Internet-based two-sided auction markets
Offer/bid order
Offers to sell 1 MWhr Bids to buy 1 MWhr
Seller Price Buyer Price
1 S1 $10.00 B1 $70.002 S2 $10.00 B1 $70.003 S1 $50.00 B2 $70.004 S2 $50.00 B1 $65.005 S1 $65.00 B1 $65.006 S2 $70.00 B2 $50.007 S1 $70.00 B2 $25.008 S2 $70.00 B3 $25.00
This table orders offers and bids for each agent (same as previous slide)
This table orders offers and bids across all selling and buying agents, respectively.
Offers to sell 1 MWhr Bids to buy 1 MWhrS1 S2 B1 B2 B3
$10.00 $10.00 $70.00 $70.00 $25.00$50.00 $50.00 $70.00 $50.00 0$65.00 $70.00 $65.00 $25.00 0$70.00 $70.00 $65.00 0 0
∞ ∞ 0 0 0∞ ∞ 0 0 0∞ ∞ 0 0 0
20
Market clearing price
Computed as the price where the supply schedule intersects the demand schedule.
SUPPLY
DEMAND
Price ($/MWhr)
Quantity (MWhr)
L. Tesfatsion, “Auction Basics for Wholesale Power Markets: Objectives and Pricing Rules,” Proceedings of the 2009 IEEE Power and Energy Society General Meeting, July, 2009.
21
Market clearing price
Computed as the price where the supply schedule intersects the demand schedule.
Price ($/MWhr)
Quantity (MWhr)
SUPPLY
DEMAND
L. Tesfatsion, “Auction Basics for Wholesale Power Markets: Objectives and Pricing Rules,” Proceedings of the 2009 IEEE Power and Energy Society General Meeting, July, 2009.
Security-constrained economic dispatch (SCED)
22
Subject to
We allow offers and bids to be made on energy and reserves.This problem is solved for a single operating condition. The operating condition is representative for a certain time period (either 1 hour or 5 minutes).
Max demand Σ di+wi<DMAXi for all i (9)
Value ReserveCosts ReserveCosts Production
min i
iii
ii
eDemandValu
iii
iii WwRrUdCg
The above is a simplified version. The MISO Business Practice Manual BPM-002-r11, Chapter 6, provides a detailed description of the SCED. See https://www.midwestiso.org/Library/BusinessPracticesManuals/Pages/BusinessPracticesManuals.aspx.
1. SCED obj fnct also includes regulation term, separating reg-up from reg-down.
2. “Value” terms in obj fnct can be set by stepped curves established by ISO.
Security-constrained unit commitment (SCUC)
23
power balance i
itti
it dDg , t (2)
reserve ti
it SDr , t (3)
min generation iitit MINzg ,, ti (4) max generation iititit MAXzrg ,, ti (5) max spinning reserve iitit MAXSPzr ,, ti (6) ramp rate pos limit iitit MxIncgg 1 ,, ti (7) ramp rate neg limit iitit MxDecgg 1 ,, ti (8) start if off-then-on ititit yzz 1 ,, ti (9) shut if on-then-off ititit xzz 1 ,, ti (10) normal line flow limit
ikititki MxFlowdga )( ,, tk (11)
security line flow limits i
jkitit
jki MxFlowdga )()( )( ,,, tjk (12)
Value ReserveCosts ReserveCostsShutdown Costs StartupCosts ProductionCosts load)-(no Fixed
min t i
ititt i
ititt i
ititt i
itit
eDemandValu
t iitit
t iitit
t iitit WwRrHxSyUdCgFz
Subject to
We allow offers and bids to be made on energy & reserves. This problem is solved across multiple time periods, usually 24 hrs (1 hr at a time) but sometimes fewer (e.g, 4 or 6) and sometimes more.
Max demand Σ di+wi<DMAXi for all I,t (13)
The above is a simplified version. The MISO Business Practice Manual BPM-002-r11, Chapter 4, provides a detailed description of the SCUC. See https://www.midwestiso.org/Library/BusinessPracticesManuals/Pages/BusinessPracticesManuals.aspx.
1. SCUC obj fnct also includes regulation term, separating reg-up from reg-down.
2. “Value” terms in obj fnct can be set by stepped curves established by ISO.
Two markets - comments1. Two markets: “Energy & operating reserve” are 2 different markets, 1 for
buying/selling energy, 1 for buying/selling operating reserve.2. Co-optimization: The first “SC” in SC-SCED/SC-SCUC stands for
“simultaneous co-optimized” referring to the fact that both energy & operating reserve markets are cleared within 1 optimization formulation.
3. Reserves: Regulation reserve supplies minute-by-minute variation in net-demand via AGC. Spinning/supplemental reserve provide backup for contingencies (gen loss). Spinning is inter-connected, supplemental need not be; both must be available within 10 mins of a request.
4. Use of SC-SCED: In DAM, SC-SCUC solves once per hour and then for that hour, SC-SCED is also solved. RTM uses the RT commitment as input to SC-SCED in computing RT dispatch every 5 minutes.
5. LMPs: SC-SCUC gives hourly commitment & dispatch, but no nodal prices (LMPs). SC-SCED (given a commitment) gives dispatch & nodal prices.
6. Contingencies: Transmission security constraints for SC-SCUC are enforced via a predefined constraint list for the SCUC and a simultaneous feasibility testing (SFT) function iterating with SCED.
24
25
Electricity “two settlement” markets
Day-Ahead Market(every day)
Real-Time Market(every 5 minutes)
Energy & reserve offers from gens
Energy bids from loads
Internet system
Which gens get committed, at roughly what levels for next 24 hours, and settlement
Internet system
Energy offers from gens
Energy bids from loads
Generation levels for next 5 minutes and settlement for deviations from day-ahead market
Generates 100 mw; paid $100.
Generates 99 mw; pays $1.
26
Locational marginal prices
1. Units are $/MWhr2. One for each bus in the network.3. If the network is lossless, transmission capacity is infinite,
then all buses have the same LMP, λ. In this case, λ is the increase in system cost if total load increases by 1 unit (corresponds to simple market we will see).
4. With a lossy and congested network, LMPk is the increase in cost of bus k MW load increases by 1 unit.
dk
lossM
jjkjk P
PtLMP
1
27
MISO and PJM balancing areas
28
RT LMPs in the MISO and PJM balancing areas
7:20 am (CST) 9/8/2011Source: MISO - PJM Interconnection Joint and Common Market Web site, previously at www.miso-pjm.com/ but not maintained.
29
RT LMPs in the MISO and PJM balancing areas
7:40 am (CST) 9/8/2011Source: MISO - PJM Interconnection Joint and Common Market Web site, previously at www.miso-pjm.com/ but not maintained.
30
Average annual locational marginal prices
31
Locational marginal prices – effect of transmission.
326:00 am-noon (CST) 8/28/2012
RT LMPs in the MISO and PJM balancing areas- temporal variation for four different nodes
33March 4, 2013, 10:20 CST
RT LMPs in the MISO balancing area
https://www.midwestiso.org/MarketsOperations/RealTimeMarketData/Pages/RealTimeMarketData.aspx
34March 4, 2013, 10:20 CST
Ancillary services in the MISO balancing area
https://www.midwestiso.org/MarketsOperations/RealTimeMarketData/Pages/RealTimeMarketData.aspx
35
Market prices - Energy
Real-Time 8:25 am (CST) 6/4/2013
36
Market prices – Ancillary Services
Real-Time: 8:25 am (CST) 6/4/2013
Day-ahead: hour ending 9 am (CST) 6/4/2013
37
Day-ahead LMPs in ISO-NE balancing areas
For hour ending 11:00 am (EST) 9/8/2011New England ISO website, at http://www.iso-ne.com/portal/jsp/lmpmap/Index.jsp but no longer available.
38
RT LMPs in the ISO-NE balancing areas
10:25 am (EST) 9/8/2011New England ISO website, at http://www.iso-ne.com/portal/jsp/lmpmap/Index.jsp but no longer available.
39
RTAncillary service prices in ISO-NE bal areas
10:25 am (EST) 9/8/2011
Regulation clearing price is $5.11/MW.
Load Zones: Connecticut (CT), Southwest CT (SWCT), Northeast Massachusetts/Boston (NEMABSTN)
TMSR=10min spinning rsrvTMNSR=10min non-spinning rsrvTMOR=30min operating rsrv
New England ISO website, at http://www.iso-ne.com/portal/jsp/lmpmap/Index.jsp but no longer available.
Market time line
Ref: A. Botterud, J. Wang, C. Monteiro, and V. Miranda “Wind Power Forecasting and Electricity Market Operations,” available at www.usaee.org/usaee2009/submissions/OnlineProceedings/Botterud_etal_paper.pdf 40
Base point calculation via real-time market
41
Source: Y. Makarov, C. Loutan, J. Ma, and P. de Mello, “Operational impacts of wind generation on California power systems,” IEEE Trans on Power Systems, Vol. 24, No. 2, May 2009.
Focus on interval 2, { t+5, t+10}.
For interval 2, a short-term net load forecast is made 7.5 min before interval 2 begins, at t-2.5, and generation set points are computed accordingly via SCED.
At t+2.5, which is 2.5 minutes before interval 2 begins, the units start to move.
The units are ramped at a rate which provides that they reach the desired base point at t+7.5 min, which is 2.5 min after the interval begins.
ADS: automatic dispatch systemDOT: dispatch operating target
Key point: The base point is computed from a net load forecast. There is error in this forecast, which typically increases as wind penetration increases. This error contributes to power imbalance and therefore frequency deviation.
42
How did wind participate in markets?
Demand schedule without wind
Supply schedule without wind
Quantity (MWhr)
Price ($/MWhr)
Point X
“Old” approach•Participates in day-ahead energy market•Does not participate in day-ahead AS market•Does not participate in RTM•Wind generates what it can (self-scheduled/price-taker)•No deviation penalties•Paid based on computed LMP without wind, Point X below•Marginal unit backed off
Does not affect supply curve!
An excellent summary of wind and markets for all North American ISOs (as of Oct. 2011) can be found at http://www.uwig.org/windinmarketstableOct2011.pdf.
43
How does wind participate in markets?
“New” Midwest ISO approach: Dispatchable intermittent resource (DIR)
• Participates in day-ahead energy• Makes offer into RT market like any other
generator. But one unique DIR feature:• Instead of capacity max offered in by other generation
resources, the forecasted wind MW is used as the operation capacity maximum;
• Units are expected to follow the dispatch signal;• Units missing “schedule band” of 8% on either side of
dispatch instruction for four consecutive 5-min periods are penalized.
•What are implications?
44
How does wind participate in markets?
What are implications? Wind is dispatchable! Forecasting is key!•DIRs are expected to provide rolling forecast of 12 five-minute periods for the Forecast Maximum Limit.•If forecast not submitted in time, MISO forecast is used.•Each 5 minute dispatch optimization uses Forecast Maximum Limit based on the following order
1. Participant submitted Forecast for the interval•Must be less than or equal to the Feasibility Limit•Must have been submitted less than 30 minutes ago
2.MISO Forecast•Must be less than or equal to the Feasibility Limit•Must have been created less than 30 minutes ago
3.State Estimator
45
How does wind participate in markets?
46
Midwest ISO’s wind forecasting accuracy?
47
Why is DIR beneficial? (from MISO document)1. The entire market benefits when more resources are fully integrated into the Energy Market. Specifically, operational efficiency and market transparency will be improved, since fewer manual wind curtailments will be necessary, and LMPs will reflect each resource that impacts a constraint(s). For these reasons, registration as DIR is consistent with Good Utility Practice.
2. The automated dispatch for DIRs will be more efficient than the manual curtailment process currently in place for Intermittent Resources. This will lead to more optimal economic solutions that utilize wind more completely than a manual process.
3. The make -whole provisions of the tariff apply to DIRs, whereas they do not apply to Intermittent Resources. If a DIR is unprofitably dispatched above its Day-Ahead position, it is eligible for the RT Offer Revenue Sufficiency Guarantee (RSG) Payment provisions of the tariff. If a DIR is dispatched below its Day-Ahead position, and does not maintain its Day-Ahead margin, it is eligible for the Day Ahead Margin Assurance Payment provisions of the Tariff. This provides DIRs with assurance that dispatches, both upward and downward, will be economical.
See https://www.midwestiso.org/Library/Repository/Communication%20Material/Strategic%20Initiatives/DIR%20FAQ.pdf.
48
Why is DIR beneficial?Inclusion of the DIRs in the RT dispatch provides that DIR offers are optimized by SCED.•This provides more flexibility to manage constraints. Therefore, there will be fewer manual curtailments, which benefits wind for increased MWhrs produced, and benefits others because it can be predicted (improves transparency).•Benefits to system because wind offers low and therefore affects all time periods some (has very large effect during peak periods) – see next slide.
Why does wind offer low when its LCOE is high?
How then, can wind energy be profitable in the long-term, if it is offering prices that are lower than its LCOE?.
Because markets incentivize agents to offer their marginal cost (cost of producing the next MW) to be dispatched. This is the value for which they break-even in the short-term. Since wind requires no fuel, its marginal costs are mainly maintenance-related and subsequently low compared to marginal cost of fuel-based units.
It is because markets settle at the clearing price, i.e., (assuming infinite transmission & no losses), everyone gets paid the clearing price, not their offer price
49
Why is DIR beneficial?Difference in prices with (solid) and without (dashed) wind.Slanted lines are demand curves for night, day, and peak.Without wind, prices are slightly higher at night, significantly higher during the day, and much higher during the peak.
“Wind energy and Electricity Prices: Exploring the “merit order effect”,” a literature review by Poyry for the European Wind Energy Association, April , 2010., available at www.ewea.org/fileadmin/ewea_documents/documents/publications/reports/MeritOrder.pdf.
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