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Frequency Challenges of the Future Power System
3rd International Workshop DynPOWER Dynamic Stability Challenges of the Future Power Grids
Hector Chavez, Ph.D.EE Department
U. of Santiago, Chile
LInESLaboratorio de Integración de
Energías Sustentables
Agenda
1. About Chile, U. of Santiago and the Chilean Power Sys
2. Situational awareness and model representativeness
3. Economic operation and frequency control 4. Lower inertia and frequency control
Chile
https://brilliantmaps.com/chile-long/https://www.beautifulworld.com/south-america/chile/
https://brilliantmaps.com/chile-long/https://www.beautifulworld.com/south-america/chile/
U. Of Santiago
U. de Santiago (1981)
Escuela de Artes y Oficios (1849) Universidad Técnica del Estado (1947)
QS 13 in LA 2019
The sustainable Energy Integration Laboratory
- Kick off in March 2014.- 1 Associated Prof. / 2 Staff- 5 research projects and various
equipment initiatives (~ US$ 1MM, 2014 -August 2019).
- Current Students: 2Ph.D, 6 Master, 7 Undergrads.
- A complete teaching lab for solar and wind applications; a PDC unit connected to a South American low voltage network
LInESLaboratorio de Integración de
Energías Sustentables
Medfasee
http://www.medfasee.ufsc.br/conosur/http://www.medfasee.ufsc.br/temporeal/
http://www.medfasee.ufsc.br/conosur/http://www.medfasee.ufsc.br/temporeal/
The Chilean Power System
“ISO” type of power system operation. Poor regional interconnections
The Chilean Power System
35297 km of transmission lines
The Chilean Power System
Capacity 2018 Energy 2018
20% by 2025 as a Renewable target
2. Situational awareness and model representativeness
Situation awareness
https://www.naspi.org/sites/default/files/reference_documents/NASPInet%202%20v1.13%20102518.pdfNASPInet 2.0 Architecture Guidance
It is happening and we can see it now with PMU!
Example from Brazil (UFSC)
0.52 Hz oscillation
https://www.naspi.org/sites/default/files/reference_documents/NASPInet%202%20v1.13%20102518.pdf
Look-ahead awareness
https://www.naspi.org/sites/default/files/reference_documents/NASPInet%202%20v1.13%20102518.pdf
NASPInet 2.0 Architecture Guidance
What if we can see it beforehand?
https://www.naspi.org/sites/default/files/reference_documents/NASPInet%202%20v1.13%20102518.pdf
Actual system at time t
Simulator
Model (simple)
Scenario 1
Scenario “n”
Scenario 2
….
Simulated system at time t + k
Actual system at time t + ε
….
Simulation time k >> ε
Real time ε
SIC Falla 257
65( )kP MW∆ =
Chavez, H.; Hesamzadeh, M.; Carlsson, F., A Simplied Model for Predicting Primary Control Inadequacy in the Presence of Wind Power," Sustainable Energy, IEEE Transactions on, vol.7, no.11, pp.271,278, Jan. 2016.
Freq. Response is identified for different load conditions with a linear 3-order model
Model parameters can be identified for several demand conditions; data of generator contingencies is needed
Model representativeness
Faster than real time simulationsPMU 1
PMU 2
PMU n
PDC
Perform Data Identification
Obtain frequency measurements
A contingency has occurred ?
NO
YES
Obtain contingency frequency data
Obtain contingency size from SCADA or estimate
Store load level, renewable production and identified parameters
Update parameter identification data base
“Faster” than real time simulator
based on reduced-order model
Real time System conditions
Look-ahead frequency dynamic
simulationUnder construction
Data Analytic Tool for Clustering Identification based on Dimensionality Reduction of Frequency Measurements, IEEE SGSMA019, College Station, TX. May 2019
Frequency of synchronous machines in DE, IT, ES and TR following the outage of one generation unit in France.
Coherency issues
3. Economic operation and Frequency Control
Time (minutes)
0 1 2 3 4 5 6
Freq
uenc
y (H
Z)
59.7
59.75
59.8
59.85
59.9
59.95
60
60.05ERCOT 21:17:09.814322 Sat 18 Feb 2012 (049)
Governors (primary) get system back to balance
One run of the RTM to restore deployed primary reserves (tertiary) after 1 min the contingency happened
Overlapping operation
Economic operation and AGC will be jointly performing secondary control (US NERC has different performance standards for this and frequency min-to-min regulation)
Economic op. + dynamics
Economic operation:- Reserve
Assignment
AGC Model
Frequency Response model from identification
Flexibility is accounted for by reserve determination, but it really has a meaning while performing frequency control
Optimization Differential Equations
ResultsDecember 13 of 2017 to January 3, 2018 (Chilean Sys) 4-by-4 frequency actual data
Simulation
σ = 0,027281
σ = 0,0257
These analysis are needed for frequency control performance standard simulation (ENTSO-E, NERC)
Example for Chilean CEN
A month of simulated economic and AGC operation
4. Lower inertia
Inertia remembered
• Inertia is a battery of kinetic energy
It is the one thing that makes conservation of energy possible and communicates the state of the balance through the frequency.
On the Inertia of Future More-Electronics Power Systems, IEEE Journalof Emerging and Selected Topics in Power Electronics
Synthetic inertia
H. R. Chamorro, M. Ghandhari and R. Eriksson, "Wind power impact on power system frequency response," 2013 North American Power Symposium (NAPS), Manhattan, KS, 2013, pp. 1-6.
Synthetic inertia
• Most approaches work; which one is the best?– The test power system is not the same
amongst the approaches.– Most approaches do not consider the
dynamics of the system.
• Difficult to compare
Optimal synthetic inertia
• Optimal control can be used to, for example, minimize the ROCOF of the power system:– Generalized dynamic system to
represent any power system under any normal operating condition
Optimal synthetic inertia
• Optimal control can be used to, for example, minimize the ROCOF of the power system:– Minimization of the ROCOF as an
objective function.– Optimal control to ensure stability (H2,
LQR, LMI).– Distributed control possible.
Optimal synthetic inertiaSCADA
Imbalance
Under construction
Final remarks
• Situational awareness is important, but we need to prevent bad thing from happening. Data analytics.
• Markets are getting closer to power system operation. Dynamics+Market.
• Synthetic inertia has still limited application with no standardization. Fast frequency response definition.
Frequency Challenges of the Future Power System
3rd International Workshop DynPOWER Dynamic Stability Challenges of the Future Power Grids
Hector Chavez, Ph.D.EE Department
U. of Santiago, Chile
LInESLaboratorio de Integración de
Energías Sustentables
Foliennummer 1Foliennummer 2ChileU. Of SantiagoFoliennummer 5MedfaseeThe Chilean Power SystemThe Chilean Power SystemThe Chilean Power System2. Situational awareness and model representativeness�Situation awarenessLook-ahead awarenessFaster than real timeFoliennummer 14Faster than real time simulationsFoliennummer 163. Economic operation and Frequency Control�Foliennummer 18Economic op. + dynamics ResultsExample for Chilean CEN4. Lower inertia �Inertia rememberedSynthetic inertiaSynthetic inertiaOptimal synthetic inertiaOptimal synthetic inertiaOptimal synthetic inertiaFinal remarksFoliennummer 30