Inclusion of Pre-Existing Undervoltage Load Shedding Schemes in AC-QSS Cascading Failure Models

Gharebaghi, Sina; Vennelaganti, Sai Gopal; Chaudhuri, Nilanjan Ray; He, Ting; Porta, Thomas F. La

doi:10.1109/tpwrs.2021.3075210

Cited by 9 publications

(2 citation statements)

References 25 publications

(48 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In this section, we contrast the cascading failure simulation results in the ground truth (that uses a 4 th -order generator model solved using TM) with the AC-QSS model [29] and dynamic model with classical generator representation. Going forward, 'error' will imply difference w.r.t.…”

Section: Comparison With Ac-qss and Classical Modelsmentioning

confidence: 99%

An Approach for Fast Cascading Failure Simulation in Dynamic Models of Power Systems

Gharebaghi¹,

Chaudhuri²,

He³

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

The ground truth for cascading failure in power system can only be obtained through a detailed dynamic model involving nonlinear differential and algebraic equations whose solution process is computationally expensive. This has prohibited adoption of such models for cascading failure simulation. To solve this, we propose a fast cascading failure simulation approach based on implicit Backward Euler method (BEM) with stiff decay property. Unfortunately, BEM suffers from hyperstability issue in case of oscillatory instability and converges to the unstable equilibrium. We propose a predictor-corrector approach to fully address the hyperstability issue in BEM. The predictor identifies oscillatory instability based on eigendecomposition of the system matrix at the post-disturbance unstable equilibrium obtained as a byproduct of BEM. The corrector uses right eigenvectors to identify the group of machines participating in the unstable mode. This helps in applying appropriate protection schemes as in ground truth. We use Trapezoidal method (TM)-based simulation as the benchmark to validate the results of the proposed approach on the IEEE 118-bus network, 2, 383-bus Polish grid, and IEEE 68-bus system. The proposed approach is able to track the cascade path and replicate the end results of TM-based simulation with very high accuracy while reducing the average simulation time by ≈ 10 − 35 fold. The proposed approach was also compared with the partitioned method, which led to similar conclusions.

show abstract

Section: Comparison With Ac-qss and Classical Modelsmentioning

confidence: 99%

An Approach for Fast Cascading Failure Simulation in Dynamic Models of Power Systems

Gharebaghi¹,

Chaudhuri²,

He³

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Recently, researchers are working on load shedding and also on the priority of renewable energy integration in the smart grid. Domestic load shedding is performed in the literature to maintain the supply quality (Azasoo et al, 2020;Alrajhi, 2022), while various sensitivity parameters that combine the negative effects of frequency, voltage, and load shedding are studied through max-min optimization (Alshammari et al, 2018;Alsiraji and El-Shatshat, 2018;Cruz et al, 2020;Talaat et al, 2020;Gharebaghi et al, 2021;Hong and Hsiao, 2022). The authors (Alrajhi, 2018;Jiang et al, 2020) have linearized various components and the system dynamics for load shedding due to the nonlinearity of system voltage dynamics and frequency.…”

Section: Introductionmentioning

confidence: 99%

Load shedding for frequency and voltage control in the multimachine system using a heuristic knowledge discovery method

et al. 2022

View full text Add to dashboard Cite

The voltage profile of different buses and the rotor dynamics of generators are adversely affected by a generator outage. Generator outages can be minimized using a variety of strategies and algorithms. An AI-based knowledge discovery approach has been reported in this article. This article proposes a technique for identifying sensitive loads and the amount of active and reactive power curtailment for rotor speed regulation and voltage management at the terminals. The MATLAB®/Simulink environment verifies and tests the method’s practicality on an IEEE-10-machine-39-bus system. Active power shedding is considered for rotor angle stability, while reactive power is also shedded for maintaining the terminal voltage at the loads. A sequential outage is considered to simulate a scenario where the two generators with the highest active and reactive power are taken out of service. The generator’s rotor speed, terminal voltage, and load are measured with and without load restriction. In all situations, the rotor and center of inertia speed are 1 p.u. The average steady-state load terminal voltage is 0.967 V. The average terminal voltage of all load buses improves from 0.933 to 0.972 and 0.936 to 0.971, case-wise. The reported results confirm and validate the effectiveness and applicability of the proposed technique.

show abstract

An approach for fast cascading failure simulation in dynamic models of power systems

Gharebaghi

Chaudhuri

et al. 2023

Applied Energy

View full text Add to dashboard Cite

Inclusion of Pre-Existing Undervoltage Load Shedding Schemes in AC-QSS Cascading Failure Models

Cited by 9 publications

References 25 publications

An Approach for Fast Cascading Failure Simulation in Dynamic Models of Power Systems

An Approach for Fast Cascading Failure Simulation in Dynamic Models of Power Systems

Load shedding for frequency and voltage control in the multimachine system using a heuristic knowledge discovery method

An approach for fast cascading failure simulation in dynamic models of power systems

Contact Info

Product

Resources

About