Transcript Slides
ECE 476 POWER SYSTEM ANALYSIS Lecture 1 Introduction Professor Tom Overbye Department of Electrical and Computer Engineering About Me Professional – – – – – Received BSEE, MSEE, and Ph.D. all from University of Wisconsin at Madison (83, 88, 91) Worked for eight years as engineer for an electric utility (Madison Gas & Electric) Have been at UI since 1991, doing teaching and doing research in the area of electric power systems Developed commercial power system analysis package, known now as PowerWorld Simulator. This package has been sold to about 400 different corporate entities worldwide DOE investigator for 8/14/2003 blackout About Me Nonprofessional – – Married to Jo Have three children – – – Tim age 13 Hannah age 11 Amanda age 9 Live in country by Homer Like to bike to work (at least part of the way) Teach 2nd/3rd Grade Sunday School class at First Baptist Church My Kids Simple Power System Every power system has three major components – generation: source of power, ideally with a specified voltage and frequency – load: consumes power; ideally with a constant resistive value – transmission system: transmits power; ideally as a perfect conductor Complications No ideal voltage sources exist Loads are seldom constant Transmission system has resistance, inductance, capacitance and flow limitations Simple system has no redundancy so power system will not work if any component fails Notation - Power Power: Instantaneous consumption of energy Power Units Watts = voltage x current for dc (W) kW – 1 x 103 Watt MW – 1 x 106 Watt GW – 1 x 109 Watt Installed U.S. generation capacity is about 900 GW ( about 3 kW per person) Maximum load of Champaign/Urbana about 300 MW Notation - Energy Energy: Integration of power over time; energy is what people really want from a power system Energy Units Joule = 1 Watt-second (J) kWh – Kilowatthour (3.6 x 106 J) Btu – 1055 J; 1 MBtu=0.292 MWh U.S. electric energy consumption is about 3600 billion kWh (about 13,333 kWh per person, which means on average we each use 1.5 kW of power continuously) Power System Examples Electric utility: can range from quite small, such as an island, to one covering half the continent – there are four major interconnected ac power systems in North American, each operating at 60 Hz ac; 50 Hz is used in some other countries. Airplanes and Spaceships: reduction in weight is primary consideration; frequency is 400 Hz. Ships and submarines Automobiles: dc with 12 volts standard Battery operated portable systems North America Interconnections Electric Systems in Energy Context Class focuses on electric power systems, but we first need to put the electric system in context of the total energy delivery system Electricity is used primarily as a means for energy transportation – Use other sources of energy to create it, and it is usually converted into another form of energy when used About 40% of US energy is transported in electric form Concerns about need to reduce CO2 emissions and fossil fuel depletion are becoming main drivers for change in world energy infrastructure Sources of Energy - US About 86% Fossil Fuels CO2 Emissions (millions of metric Biomass, 2.4 Other, 0.8 Hydro, 2.7 Nuclear, 8.1 tons, and per quad) Petroleum: 2598, 64.0 Natural Gas: 1198, 53.0 2115, 92.3 Petroleum,Coal: 40.6 Natural Gas, 22.6 1 Quad = 293 billion kWh (actual) Coal, 22.9 1 Quad = 98 billion kWh (used, taking into account efficiency) Source: EIA Energy Outlook 2007, Table 1, 2005 Data Electric Energy by Sources, US Nuclear Renewable 2.5% 19.4% Petroleum 2.0% Hydroeletric 7.1% Gas 20.0% Source: EIA State Electricity Profiles, 2006 Coal 49.0% Electric Energy by Sources, Calif. Renewable 11.3% Coal 1.0% Nuclear 14.7% Petroleum 1.0% Hydroeletric 22.2% Source: EIA State Electricity Profiles, 2006 Gas 49.8% Oregon is 71% Hydro, while Washington State is 76% Hydro Electric Energy by Sources, Illinois Renewable 0.4% Nuclear 48.9% Coal 47.6% Hydroeletric 0.1% Petroleum 0.1% Source: EIA State Electricity Profiles, 2006 Gas 2.9% Global Warming and the Power Grid 15 What is Known: CO2 in Air is Rising Value was about 280 ppm in 1800, 384 in 2007 Rate of increase is about 3ppm per year Source: http://cdiac.ornl.gov/trends/co2/sio-mlo.htm 16 As is Worldwide Temperature Baseline is 1961 to 1990 mean Source: http://www.cru.uea.ac.uk/cru/info/warming/ Change in U.S Annual Average Temperature 17 Source: http://www.sws.uiuc.edu/atmos/statecli/Climate_change/ustren-temp.gif 18 Not But Average Temperatures are Increasing Everywhere Equally Source : http://www.sws.uiuc.edu/atmos/statecli/Climate_change/iltren-temp.jpg World Population Trends Country Japan Germany Russia USA China India World 2005 127.5 82.4 142.8 295.7 1306 1094 6449 2015 124.7 81.9 136.0 322.6 1393 1274 7226 19 2025 117.8 80.6 128.1 349.7 1453 1449 7959 Source: www.census.gov/ipc/www/idb/summaries.html; values in millions; percent change from 2005 to 2025 % -7.6 -2.1 -10.3 18.2 11.2 32.4 23.4 20 Eventual Atmospheric CO2 Stabilization Level Depends Upon CO2 Emissions Regardless of what we do in the short-term the CO2 levels in the atmosphere will continue to increase. The eventual stabilization levels depend upon how quickly CO2 emissions are curtailed. Emissions from electricity production are currently about 40% of the total Energy Economics Electric generating technologies involve a tradeoff between fixed costs (costs to build them) and operating costs – – – Nuclear and solar high fixed costs, but low operating costs Natural gas/oil have low fixed costs but high operating costs (dependent upon fuel prices) Coal, wind, hydro are in between Also the units capacity factor is important to determining ultimate cost of electricity Potential carbon “tax” major uncertainty Ball park Energy Costs Nuclear: $15/MWh Coal: $22/MWh Wind: $50/MWh Hydro: varies but usually water constrained Solar: $150 to 200/MWh Natural Gas:8 to 10 times fuel cost in $/MBtu Note, to get price in cents/kWh take price in $/MWh and divide by 10. Natural Gas Prices 1990’s to 2008 Course Syllabus Introduction and review of phasors & three phase Transmission line modeling Per unit analysis and change of base Models for transformers, generators, and loads Power flow analysis and control Economic system operation/restructuring Short circuit analysis Transient stability System protection Brief History of Electric Power Early 1880’s – Edison introduced Pearl Street dc system in Manhattan supplying 59 customers 1884 – Sprague produces practical dc motor 1885 – invention of transformer Mid 1880’s – Westinghouse/Tesla introduce rival ac system Late 1880’s – Tesla invents ac induction motor 1893 – First 3 phase transmission line operating at 2.3 kV History, cont’d 1896 – ac lines deliver electricity from hydro generation at Niagara Falls to Buffalo, 20 miles away Early 1900’s – Private utilities supply all customers in area (city); recognized as a natural monopoly; states step in to begin regulation By 1920’s – Large interstate holding companies control most electricity systems History, cont’d 1935 – Congress passes Public Utility Holding Company Act to establish national regulation, breaking up large interstate utilities (repealed 2005) 1935/6 – Rural Electrification Act brought electricity to rural areas 1930’s – Electric utilities established as vertical monopolies Vertical Monopolies Within a particular geographic market, the electric utility had an exclusive franchise Distribution In return for this exclusive franchise, the utility had the obligation to serve all existing and future customers at rates determined jointly by utility and regulators Customer Service It was a “cost plus” business Generation Transmission Vertical Monopolies Within its service territory each utility was the only game in town Neighboring utilities functioned more as colleagues than competitors Utilities gradually interconnected their systems so by 1970 transmission lines crisscrossed North America, with voltages up to 765 kV Economies of scale keep resulted in decreasing rates, so most every one was happy Current Midwest Electric Grid History, cont’d -- 1970’s 1970’s brought inflation, increased fossil-fuel prices, calls for conservation and growing environmental concerns Increasing rates replaced decreasing ones As a result, U.S. Congress passed Public Utilities Regulator Policies Act (PURPA) in 1978, which mandated utilities must purchase power from independent generators located in their service territory (modified 2005) PURPA introduced some competition History, cont’d – 1990’s & 2000’s Major opening of industry to competition occurred as a result of National Energy Policy Act of 1992 This act mandated that utilities provide “nondiscriminatory” access to the high voltage transmission Goal was to set up true competition in generation Result over the last few years has been a dramatic restructuring of electric utility industry (for better or worse!) Energy Bill 2005 repealed PUHCA; modified PURPA Utility Restructuring Driven by significant regional variations in electric rates Goal of competition is to reduce rates through the introduction of competition Eventual goal is to allow consumers to choose their electricity supplier State Variation in Electric Rates The Goal: Customer Choice The Result for California in 2000/1 OFF OFF The California-Enron Effect WA MT VT ME ND MN OR ID SD WY NV WI CO CA PA IL KS AZ OK NM RI IA NE UT NY MI MO IN OH W VA VA KY CT NJ DE DC MD NC TN AR SC MS AL TX NH MA GA LA AK FL HI electricity restructuring delayed restructuring Source : http://www.eia.doe.gov/cneaf/electricity/chg_str/regmap.html no activity suspended restructuring August 14th, 2003 Blackout 2007 Illinois Electricity Crisis Two main electric utilities in Illinois are ComEd and Ameren Restructuring law had frozen electricity prices for ten years, with rate decreases for many. Prices rose on January 1, 2007 as price freeze ended; price increases were especially high for electric heating customers who had previously enjoyed rates as low as 2.5 cents/kWh Current average residential rate (in cents/kWh) is 10.4 in IL, 8.74 IN, 11.1 WI, 7.94 MO, 9.96 IA, 19.56 CT, 6.09 ID, 14.03 in CA, 10.76 US average