Practical Framework for Frequency Stability Studies in Power Systems With Renewable Energy Sources

Ortiz-Villalba, D.; Rahmann, Claudia; Alvarez, R.; Cañizares, Claudio A.; Strünck, Christoph

doi:10.1109/access.2020.3036162

Cited by 29 publications

(23 citation statements)

References 34 publications

(44 reference statements)

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“…As is common in stability assessments of large-scale power systems, we adopt a worst-case approach, meaning that only a limited set of critical operating points and contingencies are investigated [69]. Since frequency stability problems are more likely to arise during periods of low system inertia [2], [17], the study is undertaken for the minimum net load operating point (i.e., when SGs generate the least amount of power), in which case only few SGs are available to support the system frequency response.…”

Section: ) System Operating Conditions and Contingenciesmentioning

confidence: 99%

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Determination of Control Requirements to Impose on CIG for Ensuring Frequency Stability of Low Inertia Power Systems

et al. 2022

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Section: ) System Operating Conditions and Contingenciesmentioning

confidence: 99%

“…Additionally, the red dots indicate the location of the critical contingencies studied. Note that, as usual in frequency stability assessments of realistic size power systems, critical contingencies considered for the simulations are sudden outages of large online generation units [69], [75].…”

Section: B System Operating Conditionmentioning

confidence: 99%

Determination of Control Requirements to Impose on CIG for Ensuring Frequency Stability of Low Inertia Power Systems

et al. 2022

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“…These are variable speed machines, which are electrically detached from the corresponding host network via power electronics interfaces. As a result, these WTGs are incapable of offering inertial support and governor response without additional control strategy [3]. Therefore, frequency response of a power system is likely to deteriorate under high wind penetration [4].…”

Section: Introductionmentioning

confidence: 99%

A Frequency and Voltage Stability-Based Load Shedding Technique for Low Inertia Power Systems

et al. 2021

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The aim of this research work is to develop a load shedding methodology to improve the frequency response of low inertia grids by attaining satisfactory voltage stability. In recent times, wind energy integration has considerably increased in many power grids. Consequently, conventional synchronous machines are being replaced from dispatch. Unlike traditional synchronous machines, variable speed wind turbine generators usually do not take part in frequency regulation without supplementary control mechanism. During substantial wind penetration, a power system may have a small number of online synchronous machines. As a result, synchronous inertia and governor responsive reserve significantly reduce. Under such situation, a system has to rely on load shedding as a last line of defense to rescue the system frequency following a large contingency. However, the conventional Under-Frequency Load Shedding (UFLS) strategy may lead to larger frequency deviation and higher amount of load cut in certain cases. A new load shedding methodology is presented in this paper to overcome this challenge. Unlike conventional UFLS technique, higher proportion of load shedding is applied to relatively weaker buses in terms of voltage stability in the proposed mechanism. Based on reactive power margin, which is an index to specify voltage stability, a general expression to quantify load shedding is derived. Also, the adaptability of the proposed strategy to various load levels is ensured. Later on, performances of the developed strategy are explored in a low inertia wind dominated test network. Simulations are executed considering various penetration levels of wind power and for two severe contingencies -loss of 550 MW interconnection and loss of 650 MW interconnection. Investigations reveal that the proposed load shedding methodology ensures satisfactory frequency response in all simulation cases. Also, the developed technique yields less frequency deviation and load cut compared to the conventional UFLS mechanism. Therefore, the reported load shedding scheme is found to be more competent to concurrently maintain frequency and voltage stabilities in renewable dominated power systems.

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“…Meanwhile, the output of REG has high fluctuation and intermittency, which requires more active power reserves to maintain the system frequency stability. Also, the frequency stability issue becomes worse (Ortiz-Villalba et al, 2020;He et al, 2020), when REG is absorbed across control areas via the transmission lines in the interconnected power grid. Therefore, with the increase of the renewable energy penetration (REP) level, the frequency instability caused by the insufficient system inertia and the active power reserve becomes a distinct threat of the interconnected power grid.…”

Section: Introductionmentioning

confidence: 99%

Power Configuration Scheme for Battery Energy Storage Systems Considering the Renewable Energy Penetration Level

Chen¹,

Xie²,

Chen

et al. 2021

Front. Energy Res.

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With the increase of the renewable energy penetration (REP) level in the interconnected power grid, the proportion of the grid-connected conventional synchronous generators reduces continuously, resulting in the decrease of the system inertia. The insufficient system inertia brings challenges to the system frequency stability. Battery energy storage systems (BESSs), regarded as the high-quality frequency regulation resource, play an important role in maintaining the frequency stability of the system with the high REP level. To configure the proper power of BESSs in system frequency regulation, a BESS power configuration scheme (PCS) considering the REP constraint is proposed in this paper. In particular, the process to obtain the REP boundary of the interconnected grid on the premise of system frequency stability is included in the PCS, and the optimal power configuration of the BESS is further determined on the analysis of the BESS impact on the REP boundary. Furthermore, a simulation model of the Australian five-area interconnected power grid is built in MATLAB/Simulink, and the proposed REP-constrained PCS is verified and analyzed. At last, the promising results show that the PCS can take full advantages of the BESS in frequency regulation and meet the system requirement of the frequency stability at a particular REP level.

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Practical Framework for Frequency Stability Studies in Power Systems With Renewable Energy Sources

Cited by 29 publications

References 34 publications

Determination of Control Requirements to Impose on CIG for Ensuring Frequency Stability of Low Inertia Power Systems

Determination of Control Requirements to Impose on CIG for Ensuring Frequency Stability of Low Inertia Power Systems

A Frequency and Voltage Stability-Based Load Shedding Technique for Low Inertia Power Systems

Power Configuration Scheme for Battery Energy Storage Systems Considering the Renewable Energy Penetration Level

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