ECE 5314: Power System Operation & Control Lecture 1 ...
Transcript of ECE 5314: Power System Operation & Control Lecture 1 ...
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ECE 5314: Power System Operation & Control
Lecture 1: Overview and Generation Units
Vassilis Kekatos
R1 Wood, Wollenberg, and Sheble, Power Generation, Operation, and Control, Chapter 1.
R2 Gomez-Exposito, Conejo, and Canizares, Eds., Electric Energy Systems, Analysis and
Operation, Chapter 1.
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Some history
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Power grid architecture
Figure: Final report on the August 14 2003 blackout in the US and Canada, Federal
Energy Regulatory Commission (FERC), Apr. 2004.
“Most significant engineering achievement of 20th century,” National Academy
of Engineering report 2010.
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Course overview: Thermal Units
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Course overview: Economic Dispatch
• How to allocate MW outputs to generators to minimize operation cost?
• Economic dispatch is a resource allocation problem.
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Course overview: Unit Commitment
0 20 40 60 80 100 120 140 160 18050
60
70
80
90
100
110
Hours
Total demand [GWh]
February 8−14, 2015
September 9−15, 2015
Figure: Electricity demand in Mid-continent Independent System Operator (MISO).
• Electricity load exhibits large variations across time.
• Which generators should be on/off-line at each time?
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Course overview: Transmission System Effects
Network-Constrained ED:
avoids transmission line overheating
Optimal Power Flow:
• enforces voltage magnitude constraints
• manages reactive power
• incorporates transmission losses
Contingency analysis:
Security-Constrained OPF (SC-OPF)
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Power system operations
Figure: Source [R1].
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Timescale of power system operations
Figure: Source [R2].
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Generation units
• Three-phase AC voltage system with controlled frequency and magnitude
• Broadly divided into:
• thermal plants (coal, nuclear, natural gas, oil)
• hydroelectric plants
• renewables (wind farms, solar panels)
• Different technologies vary in capital, maintenance and fuel costs
e.g., nuclear and hydro have high capital costs but low operating costs
• To see the current US electricity mix, check
https://www.washingtonpost.com/graphics/national/power-plants/
• Due to load cycles and for reliability issues, there are more generators than
needed. How do you pick the most economically efficient generation mix?
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Thermal plants
1. Burned fuel in boiler produces steam
2. Steam converted to mechanical energy in turbine
3. Generator converts mechanical to electric energy
Location: away from urban centers and close to water resources.
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Natural gas turbine plants
TGas
turbine
GasBurner
Gas turbine plant
Combustion
gases
AirCompressor
G Generator
Network
a.c.
T
G
Gas
turbine
Generator
Network
GasBurner
Combined Cycle Gas Turbine plant
Combustion
gases
AirCompressor
Steam
T
G
Steam
turbine
Generator
Heatinterchanger
Water
a.c.
Increased efficiency 60%; low emissions; reasonable investment costs
Peakers: fast-responding units in periods of high demand
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Nuclear power plants
Baseload units: together with large coal plants operate almost always at max.
Concerns related to catastrophic events and radioactive waste.
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Hydroelectric plants
• Turbine converts hydraulic to mechanical energy.
• Generator converts mechanical to electric energy.
• Types:
(a) Impoundment;
(b) diversion (run-of-the-river); and
(c) pumped storage.
First option in developing countries: avoid floods and control river navigation.
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Impoundment hydroelectric plant operation
Figure: Hydroelectric plant [R1].
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Pumped storage
Figure: Ludington bumped storage plant.
Consume power at low-price hours (overnight) to pump water upwards.
Regular operation (downward water flow) at high-price hours.
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Boiler-turbine-generator units
• valve between boiler and turbine controlling steam flow
• gross vs. net power produced (2-10% for auxiliary power system)
• To optimize generation mix, need relationship between net power and cost.
• Water in hydro is free; assign cost for controlling reservoir levels.
• Hydros are typically optimized over long periods of time.
• Renewable resources can be treated like load.
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Thermal unit cost curves
Input-output curve H(P ): fuel rate [MBtu/h] vs. net power output [MW]
Fuel-cost curve C(P ): multiply H(P ) by fuel cost [$/MBtu] to get [$/h]
• derived from calculations or test data
• approximated by piece-wise linear or quadratic curves
• maintenance and investment costs usually included
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Incremental cost curve
Incremental fuel-cost curve IC(P ): the derivative of C(P ) [$/MWh]
• (incremental) fuel-cost curves routinely used in economic dispatch
• generation limits (Pmin, Pmax)
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Heat-rate curve
Heat-rate curve: the ratio H(P )/P [Btu/kWh]
• curve’s minimum is the most efficient operation point
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