Online State Estimation of the Integrated Electricity and Gas System Based on the Gaseous Circuit Method

In this paper, an online state estimation (SE) scheme of the integrated electricity and gas system (IEGS) is developed. The online SE scheme handles different time resolutions of the electrical power system (EPS) and natural gas system (NGS) by determining the SE model to be applied. When the combin...

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Bibliographic Details
Published inIEEE transactions on smart grid Vol. 14; no. 5; pp. 3465 - 3481
Main Authors Yin, Guanxiong, Cetenovic, Dragan, Levi, Victor, Sun, Hongbin, Terzija, Vladimir
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.09.2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Circuits
Constrained WLS state estimation
Constraint modelling
Electric power systems
Electricity
Frequency analysis
Frequency measurement
Gas dynamics
Gas pipelines
Gas sampling
gaseous circuit method
Indexes
integrated electricity and gas system
Mathematical models
Natural gas
Parameter sensitivity
Partial differential equations
Pipelines
Power flow
State estimation
Time measurement
Voltage measurement
Yard waste
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Summary:In this paper, an online state estimation (SE) scheme of the integrated electricity and gas system (IEGS) is developed. The online SE scheme handles different time resolutions of the electrical power system (EPS) and natural gas system (NGS) by determining the SE model to be applied. When the combined state estimation of the two systems is executed, the proposed Unified State Estimation (USE) model is applied. The USE model is based on the weighted least squares (WLS) estimation within the pre-specified electricity and gas sampling windows. The EPS is modeled via AC power flow because (fast) electromechanical transients die out between two SCADA sampling points. Gas dynamics in pipelines of a natural gas system (NGS) are much slower and can be encapsulated by successive measurements in time. It is proposed to convert the governing model in the form of partial differential equations (PDEs) into algebraic equations in the frequency domain giving the gaseous circuit method (GCM). Time-space coupling constraints are incorporated into the model by considering temporal EPS quantities and NGS frequency components in the time domain. The proposed USE model can adapt to both the NGS's steady and dynamic operating conditions by considering different frequency components. To analyze the sensitivity to USE parameters and demonstrate the effectiveness and scalability of the proposed model, case studies are developed using one small IEGS and one larger IEGS obtained by integrating the IEEE 39-bus EPS and 20-node Belgium NGS.
ISSN:1949-3053
1949-3061
DOI:10.1109/TSG.2022.3231407