Your search keyword '"ELECTRIC power distribution grids"' showing total 30,400 results

1. Decomposition characteristics of C4F7N-based SF6-alternative gas mixtures.

Author

Gao, Wenqiang, Posada, Luisa, Shiravand, Vahid, Shubhashish, Shubhashish, Price, Capri, Zhang, Boya, Potyrailo, Radislav, Younsi, Karim, Shan, Shiyao, Ndiaye, Ibrahima, Cabrera, Charlotte, Zhou, Jierui, Perret, Maxime, Berteloot, Thomas, Kieffel, Yannick, Laso, Andres, Uzelac, Nenad, Suib, Steven L., and Cao, Yang

Subjects

*MOLECULAR sieves, *REAL gases, *ELECTRIC power distribution grids, *CATALYSIS, *ACCELERATED life testing, *GAS mixtures

Abstract

C4F7N [2,3,3,3-tetrafluoro-2-(trifluoromethyl)propanenitrile]/CO2 gas mixtures are being developed as an eco-friendly electrical insulator to replace SF6, the most potent greenhouse industrial gaseous dielectric. However, recent studies have reported complicated and often conflicting decomposition pathways for C4F7N/CO2 gas mixtures, which has raised concerns. In this work, the decomposition characteristics of C4F7N/CO2 gas mixtures were studied comprehensively by both designed computations and experiments. Computations were performed starting from fundamental propositions of C4F7N/CO2 decompositions, which were further experimentally verified by pyrolysis, long-term thermal aging with/without catalytic materials (industrial-grade molecular sieves 4A), and electrical decomposition by spark discharge. The results of both computations and experiments suggest that in an ideal thermal decomposition, C4F7N is likely to decompose into C2F6 and small fluoronitriles first at high temperatures. The generation of C3F6 and C2N2 from C4F7N thermal decomposition at lower temperatures appears because of the catalytic effect of incompatible materials, for example, the industrial-grade molecular sieves 4A that we tested. The electron impact dissociation of C4F7N plays an important role in C4F7N electrical decomposition, leading to additional formation of distinctive small molecules of CF4 and C2N2 of low concentrations. It was pointed out based on a real arcing test in a load disconnector that the decomposition of C4F7N gas mixtures in real applications will be at a much moderate and manageable rate than what was obtained from the highly accelerated laboratory tests presented in this work. The signatures of decomposition products extracted in this study provide invaluable guidance for developing decomposition-based diagnosis and fixation of decomposition byproducts toward SF6-free power grids. [ABSTRACT FROM AUTHOR]

Published

2024

2. THE NIGHT THE LIGHTS WENT OUT IN MOORE COUNTY.

Author

FLANDERS, LAURA

Subjects

*WHITE supremacy, *EMERGENCY management, *INFRASTRUCTURE (Economics), *ELECTRIC power distribution grids, *DRAG shows, *MASS shootings

Abstract

In December 2022, an intentional attack on the electrical grid in Moore County, North Carolina, caused a widespread blackout that lasted for five days. The attack, which involved high-powered firearms at two electrical substations, resulted in significant disruptions to daily life, including school closures and the death of an elderly woman who relied on an oxygen machine. Despite a state of emergency being declared and a reward offered for information leading to an arrest, no suspects have been named and there have been no arrests. The incident occurred in the context of a debate surrounding a drag show in the area, which faced opposition and threats from anti-LGBTQ groups. The attack on the grid is part of a larger trend of white supremacist groups advocating for attacks on critical infrastructure. [Extracted from the article]

Published

2023

3. Laying the groundwork for long-duration energy storage.

Author

Twitchell, Jeremy

Subjects

*ENERGY storage, *ELECTRIC power distribution grids, *CARBON dioxide mitigation, *CONSTRUCTION planning, *CLEAN energy

Abstract

The electric grid was designed to move large amounts of energy through space, but decarbonization goals will require it to also move energy through time--from days and seasons with a surplus of energy production to days and seasons with insufficient production. Long-duration energy storage technologies that can hold a large amount of electricity and distribute it over periods of many hours to days and even seasons will play a critical role in the clean energy transition. But creating an environment in which these nascent technologies can develop and thrive will require changes in how the grid is planned and built. [ABSTRACT FROM AUTHOR]

Published

2023

4. Modeling and Control of Dual Active Bridge‐Modular Multilevel Converter‐Based Solid State Transformer for Grid Integration of SPV and Battery Energy Storage.

Author

Sharma, Ankita, Chilipi, Rajasekharareddy, and Praveen Kumar, Kunisetti V.

Subjects

*ENERGY storage, *ELECTRIC power distribution grids, *ENERGY management, *CAPACITORS, *PREDICTION models

Abstract

ABSTRACT This article deals with the modeling and control of a solid‐state transformer (SST) based on a dual active bridge (DAB) and modular multilevel converter (MMC) for integrating solar photovoltaic (SPV) and battery energy storage (BES) systems into the grid. SST uses DABs for bidirectional DC‐DC conversion and an MMC for DC‐AC conversion. A hybrid control method is developed in this study, which combines proportional‐integral (PI) controllers and model predictive control (MPC) to achieve the multiple objectives of the SST. The DABs' control system uses PI controllers for power extraction from the SPV system and to regulate the charging and discharging of the BES according to power generation and demand fluctuations. MPC is applied to control the active power injection, regulate the DC‐link and sub‐module capacitor voltages of the MMC. Moreover, the developed hybrid control method ensures reliable SST performance even under adverse conditions like grid voltage distortion, unbalance, and frequency variations. An energy management strategy is developed based on total power generation, reference active power injection, and the state of charge of the BES. This strategy ensures accurate reference power injection to the grid despite dynamic changes in operating conditions. The article also presents a detailed mathematical model of the DAB and MMC components, and the stability of the control algorithm is analyzed theoretically. The effectiveness of the SST and the proposed hybrid control scheme is demonstrated through MATLAB/Simulink simulations and hardware‐in‐the‐loop experimental results under various operating conditions. [ABSTRACT FROM AUTHOR]

Published

2024

5. Power system frequency nadir prediction based on data-driven and power-frequency polynomial fitting.

Author

Li, Hongxin, Wang, Lisen, Qi, Sirui, Wang, Ziqiang, Wang, Yanting, Zhou, Shichen, and Zheng, Wenwei

Subjects

MOMENTS of inertia, BACK propagation, FREQUENCY stability, RENEWABLE energy sources, ELECTRIC power distribution grids

Abstract

As the proportion of renewable energy and power electronics equipment continues to rise, the level of rotational inertia decreases considerably, resulting in severe frequency stability challenges to the power grid. It is of great significance to accurately predict the frequency nadir following a large disturbance. This paper proposes a novel data-model fusion-driven approach for the prediction of frequency nadir. As the physics-driven part, a Simplified Prediction Model (SPM) based on power-frequency polynomial fitting is developed to quickly produce the frequency nadir. As the data-driven part, Back Propagation Neural Network (BPNN) is deployed to correct the errors of the SPM to achieve more accurate results. This serial integration scheme not only obtains the final prediction result with higher accuracy, but also meets the computational efficiency requirements of online prediction. Compared with existing integration-driven methods, SPM only focuses on the active power-frequency characteristics of the system, which retains the most critical effects and greatly reduces the dependence of BPNN on sample data quality. Case studies on a modified IEEE 39-bus system verify the effectiveness of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2024

6. Application of torque observer based on belief rule base to power redistribution process.

Author

Li, Cheng, Gao, Haibo, Sun, Wangfeng, and Xu, Xiaobin

Subjects

*ELECTRIC power distribution grids, *ELECTRIC generators, *ELECTRIC propulsion, *SHIP propulsion, *PROPULSION systems

Abstract

When navigating in ice zones, broken ice can be drawn into the propeller by the wake current, significantly altering the propeller load and causing severe fluctuations in the power grid of electrical propulsion ship. To address this issue, this paper presents two kinds of power redistribution control (PRC) strategies, which utilises the dynamic feedback from the ship's generator sets to the electric propulsion system to improve the frequency control. The PRC strategy #2, which receives feedback from generator's torque deviation, has better control effect than PRC strategy #1 with feedback from speed deviation. Since the accuracy of the estimated mechanical torque directly affects the control effect of strategy #2, this paper designs a torque observer based on the Belief Rule Base (BRB) by matching the PRC strategy to regulate the grid frequency in real-time. Given the power grid's fluctuations primarily caused by aft propellers, the power will be partly redistributed to the bow thruster to stabilise the ship's grid. Experiments show that this method can maintain the stability of the grid frequency by quickly correcting the power distribution during the process of sudden shedding propeller load. [ABSTRACT FROM AUTHOR]

Published

2024

7. Improving the efficiency and reliability of India's power grid through targeted EHV transmission line investments: a case of UPPCL.

Author

Shrivastava, Sarika, Srivastava, Vijai Kumar, Khalid, Saifullah, Khan, Irfan Ahmad, and D.K.Nishad

Subjects

*ELECTRIC lines, *ELECTRIC power distribution grids, *ROOT cause analysis, *HIGH voltages, *WEATHER

Abstract

This study analyzes the optimization of Extra High Voltage (EHV) transmission line design parameters by Uttar Pradesh Power Corporation Limited (UPPCL) in India to improve power grid efficiency and reliability. UPPCL reduced insulation specifications for 400 kV lines from 27 to 21 disc insulators and decreased live metal clearance from 2600 to 2400 mm, resulting in 7–9% cost savings per line and reduced right-of-way requirements. While initial test lines performed satisfactorily for over 5 years, longer lines experienced operational challenges related to insulator quality, bird activity, and design margins. Tripping issues emerged during adverse weather conditions, particularly in foggy winter periods. Root cause analysis revealed the need for stringent insulator quality control, regular cleaning to mitigate bird dropping contamination, and potential corona ring design improvements. This case study demonstrates how targeted EHV transmission line optimization can yield significant cost and environmental benefits, while highlighting the importance of balancing economic gains with reliability and safety considerations. The findings provide valuable insights for future EHV transmission line designs and upgrades across India's power grid. [ABSTRACT FROM AUTHOR]

Published

2024

8. Enhancing domain-specific text generation for power grid maintenance with P2FT.

Author

Yang, Yi, Li, Chenhao, Zhu, Binghang, Zheng, Wenjie, Zhang, Fengda, and Li, Zhuangzhuang

Subjects

*LANGUAGE models, *NATURAL language processing, *ELECTRIC power distribution grids, *PROCESS capability, *COMPUTER performance

Abstract

The digitization of operation and maintenance in the intelligent power grid equipment relies on a diverse array of information for smart decision-making. In the domain of intelligent decision generation, proficiency is contingent upon extensive learning from copious amounts of text. This necessitates not only robust processing capabilities but also a high level of specialization. In addressing situations where authorization is lacking, pre-trained language models (PLMs) have already provided ideas when confronted with specialized domains or tasks. In consideration of the complexity of textual content in the field of the power grid, which encompasses a multitude of specialized knowledge and involves an abundance of proprietary terminology, we have undertaken an exploration of pre-trained model specialization using the power grid domain as an example, specifically for the task of generating maintenance strategies. A two-stage fine-tuning approach (P2FT) is employed, utilizing a large-scale pre-training model specifically designed for natural language processing. The efficacy and practical value of this method were evaluated through multiple metrics, juxtaposed with other advanced approaches involving low-parameter or parameter-free fine-tuning methods. Through a meticulous analysis and validation of experimental outcomes, we have corroborated the feasibility and practical application value of employing this approach for pre-trained model specialization. Additionally, it has furnished valuable guidance for text generation within both the Chinese language domain and the power grid domain. [ABSTRACT FROM AUTHOR]

Published

2024

9. Research on assessment method of maximum distributed generation hosting capacity in distribution system with high shares of renewables and power electronics.

Author

Wan, Dai, Fan, Kailun, He, Jingyu, Zhang, Haochong, Yang, Gexing, and Duan, Xujin

Subjects

*POWER electronics, *ELECTRICAL load, *ELECTRIC power distribution grids, *RESEARCH methodology, *ALGORITHMS

Abstract

With the rapid development of distributed generation (DG) within the framework of modern power systems, accurately assessing the maximum DG hosting capacity in distribution networks is crucial for ensuring the safe and stable operation of the power grid. This paper first introduces an assessment model of maximum DG hosting capacity in distribution network based on optimal power flow (OPF). Then, a two-step method that combines the linearization method and the recursive method is proposed, which consists of two parts: firstly, using linearization method to quickly calculate the preliminary assessment value of maximum DG hosting capacity, and then using a recursive method to accurately correct the preliminary assessment value. Additionally, the proposed improved comprehensive sensitivity index and safety constraint verification method can enhance the computational efficiency and accuracy of the recursive algorithm. Finally, the proposed methods were simulated and validated on the IEEE 33-bus system. [ABSTRACT FROM AUTHOR]

Published

2024

10. Model predictive control of 3L‐NPC inverter to enhance fault ride through capability under unbalanced grid conditions.

Author

Smith, Cameron, Gargoom, Ameen, Arif, M. T., and Haque, Md. Enamul

Subjects

RENEWABLE energy sources, ELECTRIC vehicle charging stations, INDEPENDENT system operators, ELECTRIC power distribution grids, SWITCHING costs

Abstract

Unbalanced voltages are becoming increasingly common in distribution networks due to the growing integrations of distributed renewable energy resources as well as large loads such as electric vehicle chargers. Such unbalanced voltages introduce significant control challenges as they produce ripples in the controlling signals, impacting the operation of inverters during the unbalanced conditions. Therefore, this paper proposes a controlling algorithm for three‐level inverters aimed at suppressing these ripples on controlling signals; improving the overall performance of inverters, and consequently enhancing the fault ride‐through capability under unbalanced conditions and faults. The proposed controlling algorithm enables inverters to operate in either a balanced current output mode or a suppressed‐ripple active power output mode, depending on the specific event scenario and demands from the grid operators. Current harmonics are suppressed even under severe faults. For improving the voltage balance on the DC capacitors in three‐level inverters, an enhanced method of neutral point current prediction is presented. The proposed method ensures higher balancing accuracy through the use of weighted switching costs, avoiding the requirement of a balancing controller or current extrapolation. Simulation and experimental results demonstrate the effectiveness of the proposed controller for reliable grid operation. [ABSTRACT FROM AUTHOR]

Published

2024

11. A CC/VC‐based power tracking method for photovoltaic inverter operated in voltage control mode.

Author

Wang, ZhenXiong, Peng, Yingjie, Yi, Hao, Zhang, Wei, Wu, Jingting, Li, Qiru, and Zhuo, Fang

Subjects

POWER electronics, VOLTAGE control, ELECTRIC power distribution grids, ENERGY storage, VOLTAGE

Abstract

The active power control of photovoltaic (PV) inverters without energy storage can flatten the fluctuating power and support the voltage amplitude and frequency of the grid. When operated in grid‐forming voltage‐control mode, because the PV power can change rapidly and widely, the PV inverter needs to track the power commands quickly and precisely. Traditionally, this goal is achieved with the estimation of PV power curve or PI‐based multiple‐loop feedback control, where flexibility, availability and accuracy are not satisfactory. Therefore, a CC/VC‐based power tracking (CVPT) method is proposed, which only uses single‐loop in control. The proposed method does not need to tune multiple loops and can respond faster, which is important for grid‐forming voltage control. Furthermore, the different operating modes due to the limitation of PV maximum power are analysed, and a mode switch method is proposed. Simulation and experimental results demonstrate that the PV inverter can cope with power disturbances from both the power and grid sides and maintain the quality of grid voltage. [ABSTRACT FROM AUTHOR]

Published

2024

12. Enhancing distance protection in transmission grids with high penetration of renewable energy sources through cooperative protection.

Author

Koloushani, Sayed Mahdi and Taher, Seyed Abbas

Subjects

*RENEWABLE energy sources, *SOLAR energy, *ELECTRIC power distribution grids, *WIND power, *POWER transmission

Abstract

This article introduces innovative protection strategies, including cooperative protection, for power transmission grids amidst a significant shift towards renewable energy sources (RES) such as wind and solar power, as well as inverter‐based resources (IBRs). The method employs a global consensus algorithm to achieve cooperative protection efficiently. This scheme leverages consensus protocols to dynamically oversee distance relay decisions, ensuring efficient fault detection and localization. The decentralized nature of the proposed method enhances robustness and security, while its high‐speed operation is ensured through non‐iterative global consensus algorithms, which provide rapid fault detection and localization crucial for real‐time protection. By incorporating virtual leaders and leveraging existing communication infrastructure, the method achieves superior selectivity in identifying faulty lines, enhancing the reliability and stability of power transmission grids with high‐RES penetration. Notably, the method does not require learning and training processes, making it adaptable to varying power system topologies without the need for extensive retraining or adaptation periods. The proposed methodology enables simultaneous participation in multiple protection zones by establishing interaction rules between agents. Virtual leaders simplify the selection of protection areas, enhancing scalability and fault localization. Simulation results conducted on the IEEE 39‐bus test system validate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

13. Identification of dominant instability modes in power systems based on spatial‐temporal feature mining and TSOA optimization.

Author

Yu, Miao, Sun, Jianqun, Tian, Shuoshuo, Zhang, Shouzhi, Wei, Jingjing, and Wu, Yixiao

Subjects

*OPTIMIZATION algorithms, *CONVOLUTIONAL neural networks, *DYNAMIC stability, *EXECUTIVE power, *ELECTRIC power distribution grids

Abstract

The recognition of the transient dominant instability mode is of great significance for rapidly and accurately formulating transient emergency decisions in power systems. In response to the challenge of accurately distinguishing between angle instability and voltage instability, which are coupled in actual power grids, this paper explores the mapping relationship between simulation data and the stable state of the system, as well as the dominant instability mode. The method enables real‐time identification of the dominant instability mode, which bypasses complex physical mechanisms. Firstly, spatio‐temporal feature mining is conducted, where convolutional neural networks are employed to learn crucial local features of transient curves, and bidirectional gated recurrent unit s utilized to learn transient features over time sequences. Next, a multihead attention mechanism is introduced to enhance sensitivity to important time steps in the sequence data. Finally, the transit search optimization algorithm optimizes the global model parameters, further increasing the accuracy of the model. Using the IEEE 10‐machine and 39‐node system as an example for simulation, the results validate that the proposed method exhibits significant advantages in terms of accuracy and applicability compared with other machine learning methods. [ABSTRACT FROM AUTHOR]

Published

2024

14. Energy management of hybrid AC/DC microgrid considering incentive‐based demand response program.

Author

Duc, Tung Trieu, Tuan, Anh Nguyen, Duc, Tuyen Nguyen, and Takano, Hirotaka

Subjects

*ENERGY demand management, *LOAD management (Electric power), *RENEWABLE energy sources, *ELECTRIC power distribution grids, *ENERGY consumption, *MICROGRIDS

Abstract

Increasing the use of renewable energy in microgrids (MGs) offers environmental and economic benefits. However, the unpredictable and intermittent nature of available resources poses challenges for optimal MG scheduling. Hybrid AC–DC microgrids provide a solution, seamlessly integrating renewables while reducing energy losses and improving power grid reliability. Additionally, incentive‐based demand response programs promote flexible energy consumption, further mitigating the variability of renewable generation and enhancing grid stability. This paper investigates the challenges and potential of high renewable penetration in hybrid AC–DC MGs, analysing the role of demand response programs in system optimization. The microgrid's energy management is modelled using MILP, while a Stackelberg game represents the demand response program. These models are integrated to optimize energy management and demand response jointly. Simulations demonstrate the cost‐saving benefits of this integrated framework, achieved through coordinated flexible resource scheduling and incentive‐based demand response programming. [ABSTRACT FROM AUTHOR]

Published

2024

15. Enhancing Vanadium Redox Flow Battery Performance with ZIF-67-Derived Cobalt-Based Electrode Materials.

Author

Young, Christine, Liao, Zhen-Qi, Li, Dong-Rong, Li, Pei-Ling, Wang, Chen-Yang, Ho, Shu-Mei, and Chen, Chi-Chang

Subjects

*VANADIUM redox battery, *RENEWABLE energy sources, *TRANSMISSION electron microscopy, *ENERGY consumption, *ELECTRIC power distribution grids

Abstract

Vanadium redox flow batteries (VRFBs) have emerged as a promising energy storage solution for stabilizing power grids integrated with renewable energy sources. In this study, we synthesized and evaluated a series of zeolitic imidazolate framework-67 (ZIF-67) derivatives as electrode materials for VRFBs, aiming to enhance electrochemical performance. Four materials—Co/NC-700, Co/NC-800, Co3O4-350, and Co3O4-450—were prepared through thermal decomposition under different conditions and coated onto graphite felt (GF) electrodes. X-ray diffraction (XRD), scanning electron microscopy (SEM), and transmission electron microscopy (TEM) analyses confirmed the structural integrity and distribution of the active materials. Electrochemical evaluations revealed that electrodes with ZIF-67-derived coatings exhibited significantly lower charge transfer resistance (Rct) and higher energy efficiency (EE) compared to uncoated GF electrodes. Co/NC-800//GF delivered the highest energy efficiency and discharge capacity among the tested configurations, maintaining stable performance over 100 charge–discharge cycles. These results indicate that Co/NC-800 holds great potential for use in VRFBs due to its superior electrochemical activity, stability, and scalability. [ABSTRACT FROM AUTHOR]

Published

2024

16. Research on Gating Fusion Algorithm for Power Grid Survey Data Based on Enhanced Mamba Spatial Neighborhood Relationship.

Author

Zhang, Aiyuan, Lv, Jinguo, Geng, Yu, Wang, Xiaolei, and Li, Xianhu

Subjects

*ELECTRIC power distribution grids, *ELECTRIC lines, *PROCESS capability, *DEEP learning, *REMOTE-sensing images, *MULTISPECTRAL imaging

Abstract

In power grid surveying, it is often necessary to fuse panchromatic and multispectral imagery for the design of power lines. Despite the abundance of deep learning networks for fusing these images, the results often suffer from spectral information loss or structural blurring. This study introduces a fusion model specifically tailored for power grid surveying that significantly enhances the representation of spatial–spectral features in remote sensing images. The model comprises three main modules: a TransforRS-Mamba module that integrates the sequence processing capabilities of the Mamba model with the attention mechanism of the Transformer to effectively merge spatial and spectral features; an improved spatial proximity-aware attention mechanism (SPPAM) that utilizes a spatial constraint matrix to greatly enhance the recognition of complex object relationships; and an optimized spatial proximity-constrained gated fusion module (SPCGF) that integrates spatial proximity constraints with residual connections to boost the recognition accuracy of key object features. To validate the effectiveness of the proposed method, extensive comparative and ablation experiments were conducted on GF-2 satellite images and the QuickBird (QB) dataset. Both qualitative and quantitative analyses indicate that our method outperforms 11 existing methods in terms of fusion effectiveness, particularly in reducing spectral distortion and spatial detail loss. However, the model's generalization performance across different data sources and environmental conditions has yet to be evaluated. Future research will explore the integration of various satellite datasets and assess the model's performance in diverse environmental contexts. [ABSTRACT FROM AUTHOR]

Published

2024

17. Research on Network Security Protection Technology Based on P2AEDR in New Low-Voltage Control Scenarios for Power IoT and Other Blockchain-Based IoT Architectures.

Author

Miao, Weiwei, Zhao, Xinjian, Li, Nianzhe, Zhang, Song, Li, Qianmu, and Li, Xiaochao

Subjects

*COMPUTER network security, *ACCESS control, *ELECTRIC power distribution grids, *TRUST, *INTERNET of things, *DEEP learning

Abstract

In the construction of new power systems, the traditional network security protection mainly based on boundary protection belongs to static defense and still relies mainly on manual processing in vulnerability repair, threat response, etc. It is difficult to adapt to the security protection needs in large-scale distributed new energy, third-party aggregation platforms, and flexible interaction scenarios with power grid enterprise systems. It is necessary to conduct research on dynamic security protection models for IoT and other Blockchain-based IoT architectures. This article proposes a network security comprehensive protection model P2AEDR based on different interaction modes of cloud–edge interaction and cloud–cloud interaction. Through continuous trust evaluation, dynamic access control, and other technologies, it strengthens the internal defense capabilities of power grid business, shifting from static protection as the core mode to a real-time intelligent perception and automated response mode, and ultimately achieving the goal of dynamic defense, meeting the security protection needs of large-scale controlled terminal access and third-party aggregation platforms. Meanwhile, this article proposes a dynamic trust evaluation algorithm based on deep learning, which protects the secure access and use of various resources in a more refined learning approach based on the interaction information monitored in the system. Through experimental verification of the dynamic trust evaluation algorithm, it is shown that the proposed model has good trust evaluation performance. Therefore, this research is beneficial for trustworthy Power IoT and other Blockchain-based IoT architectures. [ABSTRACT FROM AUTHOR]

Published

2024

18. Impact of Impedances and Solar Inverter Grid Controls in Electric Distribution Line with Grid Voltage and Frequency Instability.

Author

Kaewnukultorn, Thunchanok and Hegedus, Steven

Subjects

*ELECTRIC impedance, *REACTIVE power control, *ELECTRIC power distribution grids, *ELECTRIC lines, *CLEAN energy

Abstract

The penetration of solar energy into centralized electric grids has increased significantly during the last decade. Although the electricity from photovoltaics (PVs) can deliver clean and cost-effective energy, the intermittent nature of the sunlight can lead to challenges with electric grid stability. Smart inverter-based resources (IBRs) can be used to mitigate the impact of such high penetration of renewable energy, as well as to support grid reliability by improving the voltage and frequency stability with embedded control functions such as Volt-VAR, Volt–Watt, and Frequency–Watt. In this work, the results of an extensive experimental study of possible interactions between the unstable grid and two residential-scale inverters from different brands under different active and reactive power controls are presented. Two impedance circuits were installed between Power Hardware-in-the-loop (P-HIL) equipment to represent the impedance in an electric distribution line. Grid voltage and frequency were varied between extreme values outside of the normal range to test the response of the two inverters operating under different controls. The key findings highlighted that different inverters that have met the same requirements of IEEE 1547-2018 responded to grid instabilities differently. Therefore, commissioning tests to ensure inverter performance are crucial. In addition to the grid control, the residential PV installed capacity and physical distances between PV homes and the substation, which impacted the distribution wiring impedance which we characterized by the ratio of the reactive to real impedance (X/R), should be considered when assigning the grid-supporting control setpoints to smart inverters. A higher X/R of 3.5 allowed for more effective control to alleviate both voltage and frequency stability. The elimination of deadband in an aggressive Volt-VAR control also enhanced the ability to control voltage during extreme fluctuation. The analysis of sudden spikes in the grid responses to a large frequency drop showed that a shallow slope of 1.5 kW/Hz in the droop control resulted in a >65% lower sudden reactive power overshoot amplitude than a steeper slope of 2.8 kW/Hz. [ABSTRACT FROM AUTHOR]

Published

2024

19. Assessment of Insulation Coordination and Overvoltage for Utility Girds Integrated with Solar Farms.

Author

Soomro, Mansoor, Abbasi, Riaz, Baloch, Mazhar, Chauhdary, Sohaib Tahir, and Siddiqui, Mokhi Maan

Subjects

*ELECTRIC power distribution grids, *SOLAR power plants, *OVERVOLTAGE, *SYSTEM safety, *LIGHTNING

Abstract

Due to the economic and environmental concerns associated with fossil fuels, many government and private organizations are progressively shifting towards the integration of solar farms with Utility Grids. However, these systems are facing insulation failure issues due to internal and external transient overvoltage's, in which their shape, magnitude, and duration are unpredictable, and consequently, the insulation stress also becomes unpredictable. To ensure the safety and integrity of the system against any transient overvoltage event, it is important to carry out an insulation coordination analysis. The primary goal of this research work is to achieve this optimization in an economically viable manner, ensuring both operational stability and cost-effectiveness in the design of electrical equipment like surge Arresters. The research work presented in the literature does not fully evaluate all International Electrotechnical Commission (IEC) overvoltage classes as specified in the insulation coordination standards for Utility Grids integrated with solar farms. Therefore, this research paper investigates the impact of various transient and switching overvoltage conditions, as defined in the IEC 60071.4 Insulation Coordination Standard at the Solar and Utility Grid Electrical power system using PSCAD 4.6/EMTP Software. Five distinct simulation scenarios were developed to assess the systems' resilience against insulation stress events. The proposed system was also examined with and without the application of a lightning surge arrester. [ABSTRACT FROM AUTHOR]

Published

2024

20. Boosting the Development and Management of Wind Energy: Self-Organizing Map Neural Networks for Clustering Wind Power Outputs.

Author

Li, Yanqian, Zhou, Yanlai, Luo, Yuxuan, Ning, Zhihao, and Xu, Chong-Yu

Subjects

*WIND power, *SELF-organizing maps, *POWER resources, *ELECTRIC power distribution grids, *CLUSTER analysis (Statistics)

Abstract

Aimed at the information loss problem of using discrete indicators in wind power output characteristics analysis, a self-organizing map neural network-based clustering method is proposed in this study. By identifying the appropriate representativeness and topological structure of the competition layer, cluster analysis of the wind power output process in four seasons is realized. The output characteristics are evaluated through multiple evaluation indicators. Taking the wind power output of the Hunan power grid as a case study, the results underscore that the 1 × 3-dimensional competition layer structure had the highest representativeness (72.9%), and the wind power output processes of each season were divided into three categories, with a robust and stable topology structure. Summer and winter were the most representative seasons. Summer had strong volatility and small wind power outputs, which required the utilization of other power sources to balance power supply and load demand. Winter featured low volatility and large wind power outputs, necessitating cooperation with peak-shaving power sources to enhance the power grid's absorbability to wind power. The seasonal clustering analysis of wind power outputs will be helpful to analyze the seasonality of wind power outputs and can provide scientific and technical support for guiding the power grid's operation and management. [ABSTRACT FROM AUTHOR]

Published

2024

21. Two-Stage Optimal Scheduling Strategy of Microgrid Distribution Network Considering Multi-Source Agricultural Load Aggregation.

Author

Ma, Guozhen, Pang, Ning, Wang, Yunjia, Hu, Shiyao, Xu, Xiaobin, Zhang, Zeya, Wang, Changhong, and Gao, Liai

Subjects

*PARTICLE swarm optimization, *RENEWABLE energy sources, *AGRICULTURAL economics, *REACTIVE power, *ELECTRIC power distribution grids, *MICROGRIDS

Abstract

With the proposed "double carbon" target for the power system, large-scale distributed energy access poses a major challenge to the way the distribution grid operates. The rural distribution network (DN) will transform into a new local power system primarily driven by distributed renewable energy sources and energy storage, while also being interconnected with the larger power grid. The development of the rural DN will heavily rely on the construction and efficient planning of the microgrid (MG) within the agricultural park. Based on this, this paper proposes a two-stage optimal scheduling model and solution strategy for the microgrid distribution network with multi-source agricultural load aggregation. First, in the first stage, considering the flexible agricultural load and the market time-of-use electricity price, the economic optimization is realized by optimizing the operation of the schedulable resources of the park. The linear model in this stage is solved by the Lingo algorithm with fast solution speed and high accuracy. In the second stage, the power interaction between the MG and the DN in the agricultural park is considered. By optimising the output of the reactive power compensation device, the operating state of the DN is optimised. At this stage, the non-linear and convex optimization problems are solved by the particle swarm optimization algorithm. Finally, the example analysis shows that the proposed method can effectively improve the feasible region of safe operation of the distribution network in rural areas and improve the operating income of a multi-source agricultural load aggregation agricultural park. [ABSTRACT FROM AUTHOR]

Published

2024

22. Reinforcement Learning-Enhanced Adaptive Scheduling of Battery Energy Storage Systems in Energy Markets.

Author

Liu, Yang, Lu, Qiuyu, Yu, Zhenfan, Chen, Yue, and Yang, Yinguo

Subjects

*BATTERY storage plants, *PRICE fluctuations, *ENERGY storage, *ELECTRIC power distribution grids, *ELECTRICITY pricing

Abstract

Battery Energy Storage Systems (BESSs) play a vital role in modern power grids by optimally dispatching energy according to the price signal. This paper proposes a reinforcement learning-based model that optimizes BESS scheduling with the proposed Q-learning algorithm combined with an epsilon-greedy strategy. The proposed epsilon-greedy strategy-based Q-learning algorithm can efficiently manage energy dispatching under uncertain price signals and multi-day operations without retraining. Simulations are conducted under different scenarios, considering electricity price fluctuations and battery aging conditions. Results show that the proposed algorithm demonstrates enhanced economic returns and adaptability compared to traditional methods, providing a practical solution for intelligent BESS scheduling that supports grid stability and the efficient use of renewable energy. [ABSTRACT FROM AUTHOR]

Published

2024

23. Multimodal Operation Data Mining for Grid Operation Violation Risk Prediction.

Author

Meng, Lingwen, Zhong, Jingliang, Luo, Shasha, Zhu, Xinshan, Wang, Yulin, and Zhang, Shumei

Subjects

*INDEPENDENT component analysis, *ELECTRIC power distribution grids, *DISEASE risk factors, *RANDOM forest algorithms, *INDEPENDENT system operators

Abstract

With the continuous expansion of the power grid, the issue of operational safety has attracted increasing attention. In power grid operation control, unauthorized operations are one of the primary causes of personal accidents. Therefore, preventing and monitoring unauthorized actions by power grid operators is of critical importance. First, multimodal violation data are integrated through information systems, such as the power grid management platform, to construct a historical case database. Next, word vectors for three types of operation-related factors are generated using natural language processing techniques, and key vectors are selected based on generalized correlation coefficients using mutual information, enabling effective dimensionality reduction. Independent component analysis is then employed for feature extraction and further dimensionality reduction, allowing for the effective characterization of operational scenarios. For each historical case, a risk score is derived from a violation risk prediction model constructed using the Random Forests (RF) algorithm. When a high-risk score is identified, the K-Nearest Neighbor (KNN) algorithm is applied to locate similar scenarios in the historical case database where violations may have occurred. Real-time violation risk assessment is performed for each operation, providing early warnings to operators, thereby reducing the likelihood of violations, and enhancing the safety of power grid operations. [ABSTRACT FROM AUTHOR]

Published

2024

24. EV Smart-Charging Strategy for Power Management in Distribution Grid with High Penetration of Distributed Generation.

Author

Maia Jr., Geraldo L., Santos, Caio C. L., Nunes, Paulo R. M., Castro, José F. C., Marques, Davidson C., Medeiros, Luiz H. A. De, Limongi, Leonardo R., Brito, Márcio E. C., Dantas, Nicolau K. L., Filho, Antônio V. M. L., Fernandes, Amanda L., Chai, Jiyong, and Zhang, Chenxin

Subjects

*ELECTRIC power distribution grids, *ELECTRIC vehicle charging stations, *DISTRIBUTED power generation, *CLEAN energy, *ENERGY consumption, *ELECTRIC automobiles, *ELECTRIC vehicles

Abstract

Accelerated environmental impacts are a growing concern in the modern world. Electric mobility and the transition to a cleaner energy matrix have become increasingly discussed topics. In this context, this work presents a framework for controlling an electric vehicle (EV)-charging station integrated into a microgrid application as a basis for creating the infrastructure integrated into a smart grid concept. Considering the electrification of the transportation sector future perspectives, a brief review is conducted on the impacts of EV fleet growth in different countries and how smart-charging technologies are identified as solutions for mitigating the negative effects of energy and power consumption associated with EV-charging stations. An analysis of the technical characteristics and the tools that enable the deployment of a fleet-charging operator are examined, specifically focusing on the communication protocol for EVs, such as the OCPP (Open Charge Point Protocol) parameterization/configuration. A new EV-charging station control method is proposed to manage the impacts of distributed solar photovoltaic generation and mitigate the effects of the duck curve. Finally, an integration architecture via IEC 61850 for these elements is proposed, in a practical implementation for variable power control, considering different strategies to deal with distributed generation impact using EV-fleet-charging power demand dynamic management. [ABSTRACT FROM AUTHOR]

Published

2024

25. Survey of Reliability Challenges and Assessment in Power Grids with High Penetration of Inverter-Based Resources.

Author

Haghighi, Rouzbeh, Bui, Van-Hai, Wang, Mengqi, and Su, Wencong

Subjects

*RENEWABLE energy sources, *POWER electronics, *ELECTRIC power distribution grids, *CONVERTERS (Electronics), *RELIABILITY in engineering

Abstract

Decarbonization is driving power systems toward more decentralized, self-governing models. While these technologies improve efficiency, planning, operations, and reduce the carbon footprint, they also introduce new challenges. In modern grids, particularly with the integration of power electronic devices and high penetration of Renewable Energy Sources (RES) and Inverter-Based Resources (IBRs), traditional reliability concepts may no longer ensure adequate performance due to systemic restructuring. This shift necessitates new or significantly modified reliability indices to capture the characteristics of the evolving power system. Ensuring converter reliability is essential for effective planning, which requires precise, component-to-system-level modeling, as different converters impact system performance indicators. However, the existing literature in this field faces a significant limitation, as most studies focus on a singular perspective. Some examine reliability at the device-level, others at the component-level, while broader reviews in power systems often emphasize system-level analysis. In this paper, we aim to bridge these gaps by comprehensively reviewing the interconnections between these levels and analyzing the mutual influence of power converter and system reliability. A key point to highlight is that, with the rapid evolution of modern power grids, decision-makers must adopt a multi-level approach that incorporates insights from all levels to enable more accurate and realistic planning and operational strategies. Our ultimate goal is to provide an in-depth investigation of studies addressing the unique challenges posed by modern power grids. Finally, we will highlight the gaps in the literature and suggest directions for future research. [ABSTRACT FROM AUTHOR]

Published

2024

26. Leveraging the Synergy of Digital Twins and Artificial Intelligence for Sustainable Power Grids: A Scoping Review.

Author

Ranawaka, Ama, Alahakoon, Damminda, Sun, Yuan, and Hewapathirana, Kushan

Subjects

*NATURAL language processing, *SWARM intelligence, *ELECTRIC power distribution grids, *DIGITAL twins, *ARTIFICIAL intelligence, *DEEP learning

Abstract

As outlined by the International Energy Agency, 44% of carbon emissions in 2021 were attributed to electricity and heat generation. Under this critical scenario, the power industry has adopted technologies promoting sustainability in the form of smart grids, microgrids, and renewable energy. To overcome the technical challenges associated with these emerging approaches and to preserve the stability and reliability of the power system, integrating advanced digital technologies such as Digital Twins (DTs) and Artificial Intelligence (AI) is crucial. While existing research has explored DTs and AI in power systems separately, an overarching review of their combined, synergetic application in sustainable power systems is lacking. Hence, in this work, a comprehensive scoping review is conducted under the Preferred Reporting Items for Systematic Reviews and Meta-Analyses extension for Scoping Reviews (PRISMA-ScR). The main results of this review analysed the breadth and relationships among power systems, DTs, and AI dynamics and presented an evolutionary timeline with three distinct periods of maturity. The prominent utilisation of deep learning, supervised learning, reinforcement learning, and swarm intelligence techniques was identified as mainly constrained to power system operations and maintenance functions, along with the potential for more sophisticated AI techniques in computer vision, natural language processing, and smart robotics. This review also discovered sustainability-related objectives addressed by AI-powered DTs in power systems, encompassing renewable energy integration and energy efficiency, while encouraging the investigation of more direct efforts on sustainable power systems. [ABSTRACT FROM AUTHOR]

Published

2024

27. Review of Low Voltage Ride-Through Capabilities in Wind Energy Conversion System.

Author

Ntuli, Welcome Khulekani, Kabeya, Musasa, and Moloi, Katleho

Subjects

*WIND energy conversion systems, *PERMANENT magnet generators, *INDUCTION generators, *TECHNOLOGICAL innovations, *ELECTRIC power distribution grids

Abstract

The significance of low voltage ride-through (LVRT) capability in wind energy conversion systems (WECSs) is paramount for ensuring grid stability and reliability during voltage dips. This systematic review delves into the advancements, challenges, and methodologies associated with LVRT capabilities in WECSs. By synthesizing recent research findings, this review highlights technological innovations, control strategies, and regulatory requirements that influence LVRT performance. Key insights include the efficacy of various LVRT techniques, the role of grid codes in shaping LVRT standards, and the integration of advanced control algorithms to improve system resilience. The study offers a comprehensive understanding of the current landscape of LVRT in WECSs and pinpoints future research directions to optimize their performance in increasingly complex grid environments. During the LVRT process, the stator of a double-fed induction generator (DFIG) is directly linked to the power grid. When the external power grid experiences a failure, the stator flux produces a significant transient component, resulting in substantial overvoltage and overcurrent on the rotor side of the DFIG. Failure to implement preventative measures may result in damage to the converter, therefore compromising the safety and stability of how the power system functions. [ABSTRACT FROM AUTHOR]

Published

2024

28. A Multi-Functional Integrated Onboard Charger for Dual-Motor Driving EVs.

Author

Tong, Minghao, Liu, Xiaoqiang, Chen, Yudong, Sun, Le, and Xu, Zhiyuan

Subjects

*MOTOR drives (Electric motors), *ELECTRIC power distribution grids, *VOLTAGE, *AC DC transformers, *TOPOLOGY

Abstract

In this paper, to achieve versatile, cost-effective charging for dual-motor EVs, a multi-functional integrated onboard charger is constructed using a dual-motor driving system. In the driving mode, a five-phase flux-switching permanent-magnet (FSPM) motor powers the front, while a three-phase FSPM motor drives the rear. While in the charging mode, different topologies are adopted for different application scenarios, such as the single-phase AC charging mode, the three-phase AC charging mode, and the DC charging mode. The five-phase FSPM motor and its inverters serve as a boost-based AC/DC converter in both single-phase and three-phase AC charging modes, transforming grid power to DC. In the DC charging mode, they are reconfigured to function as a buck converter. During the three-phase AC charging mode, the three-phase FSPM motor and its inverters take on the role of a rear-stage buck converter. They function to regulate the rectified DC voltage, ensuring it meets battery charging needs. The performance of the integrated charger is validated through simulation and experiment results. [ABSTRACT FROM AUTHOR]

Published

2024

29. Data-Driven Information Management Method of Power Supply Chains Using Mobile Cloud Computing.

Author

Ma, Jingze, Zhan, Guoye, Yang, Fan, and Chen, Xingpei

Subjects

*INFORMATION resources management, *ELECTRIC power distribution grids, *DATABASES, *K-means clustering, *DATA warehousing

Abstract

Based on the spring, spring MVC and MyBatis structures of the cloud platform SSM framework, an information management platform for power grid material supply chain is built. The data layer uses a variety of sensors to collect power grid material supply chain information, and the information is fed back to the data storage layer after being integrated by the logical reorganization function of the persistence layer. The data storage layer uses the multi-sensor supply chain information fusion method based on paste progress to fuse the information and store it in the database. The business logic layer calls the information in the database and uses the improved k-means clustering algorithm to detect the abnormal supply chain data information. After calculation and data control by the control layer, the data management results are displayed through the presentation layer. The experimental results show that the absolute error of data fusion is very low. It can effectively cluster data information and distinguish outlier anomaly information at the same time, and the effect of information management is good. [ABSTRACT FROM AUTHOR]

Published

2024

30. Ginkgo - A math library designed to accelerate Exascale Computing Project science applications.

Author

Cojean, Terry, Nayak, Pratik, Ribizel, Tobias, Beams, Natalie, Mike Tsai, Yu-Hsiang, Koch, Marcel, Göbel, Fritz, Grützmacher, Thomas, and Anzt, Hartwig

Subjects

*SOFTWARE libraries (Computer programming), *MATHEMATICAL forms, *LIBRARY design & construction, *SCIENCE projects, *ELECTRIC power distribution grids

Abstract

Large-scale simulations require efficient computation across the entire computing hierarchy. A challenge of the Exascale Computing Project (ECP) was to reconcile highly heterogeneous hardware with the myriad of applications that were required to run on these supercomputers. Mathematical software forms the backbone of almost all scientific applications, providing efficient abstractions and operations that are crucial to harness the performance of computing systems. G inkgo is one such mathematical software library, nurtured by ECP, providing high-performance, user-friendly, and performance portable interfaces for applications in ECP and beyond. In this paper, we elaborate on G inkgo 's philosophy of high-performance software that is sustainable, reproducible, and easy to use. We showcase the wide feature set of solvers and preconditioners available in G inkgo and the central concepts involved in their design. We elaborate on four different ECP software integrations: MFEM, PeleLM + SUNDIALS, XGC, and ExaSGD that use G inkgo to accelerate their science runs. Performance studies of different problems from these applications highlight the effectiveness of G inkgo and the benefits incurred by these ECP applications. [ABSTRACT FROM AUTHOR]

Published

2024

31. A Study on the Potential of Carbon Dioxide Utilization Through its Co‐Injection with Hydrogen into the Blast Furnace Tuyeres.

Author

Shatokha, Volodymyr

Subjects

*CARBON sequestration, *PRODUCT life cycle assessment, *ELECTRIC power distribution grids, *CARBON emissions, *ELECTRIC power production, *COKE (Coal product), *BLAST furnaces

Abstract

The potential of CO2 utilization through its injection into blast furnace (BF) tuyeres is studied using the 1D steady‐state zonal model. Scenarios with the injection of CO2, hydrogen, and their co‐injection at various H2/CO2 mass ratios are analyzed. The impacts on factors affecting vertical temperature patterns and the position of the cohesive zone in the BF are identified. A life cycle assessment for several scenarios with various carbon emissions intensities of hydrogen production, carbon capture, and grid electricity generation is performed. Injection of CO2 without the addition of hydrogen increases the coke rate, reduces productivity, and increases direct CO2 emissions; however, thanks to producing top gas with higher calorific value, injection of CO2 may reduce the global warming potential (GWP) if the electric grid carbon intensity is above 654 kg‐CO2 kWh−1, while carbon capture is powered by green electricity. Although the injection of hydrogen alone would result in a more substantial reduction of GWP from the baseline than the injection of H2/CO2 mix at any mass ratio, considering the identified impacts on heat exchange and the position of the cohesive zone in the BF, co‐injection might be an enabling solution for the adoption of hydrogen injection. [ABSTRACT FROM AUTHOR]

Published

2024

32. Fast bus voltage detection method for single-phase power converters with split capacitors based on reduced-order generalized integrals.

Author

Zhang, Chao, Guan, Yunhai, Zhu, Wenchao, Gao, Rongwei, Wang, Zhuo, and Fu, Haijun

Subjects

*GENERALIZED integrals, *DYNAMIC loads, *SIGNAL detection, *ELECTRIC power distribution grids, *VOLTAGE

Abstract

Under dynamic conditions, the response time of traditional voltage detection methods is relatively lengthy, leading to overshoots in the DC-link voltage of single-phase power converters, which significantly degrades system performance. This study proposes a rapid voltage transient detection method based on reduced-order generalized integrator (ROGI) aimed at improving the response speed of bus voltage peak detection. By reducing the order of the algorithm, this method shortens the generation time of orthogonal signals and accelerates the detection speed of voltage changes. This enables grid power to rapidly compensate for the load power under dynamic conditions while maintaining a high-precision complementarity of the split capacitor voltage. As a result, it effectively diminishes severe fluctuations in DC-link voltage, which increases the stability of the system under dynamic load changes. This paper meticulously derives the relationship between capacitor voltage changes and grid response delays, and constructs the ROGI algorithm and its control scheme, ensuring the robustness of the method in the presence of system parameter variations. Finally, to validate the effectiveness of the proposed method, a hardware experimental platform is established and tested. Results of load step response experiments indicate that the ROGI algorithm, in comparison to traditional detection methods, reduces the detection time by 40.9%. [ABSTRACT FROM AUTHOR]

Published

2024

33. Direct Grid Connection of a Prototype with Real-Time Control for Energy Recovery and Pressure Control in a Water Distribution Network through Hydraulic Regulation.

Author

Maio, Marco, Marini, Gustavo, Zotti, Fernando, and Fontana, Nicola

Subjects

*FREQUENCY changers, *PRESSURE control, *WATER leakage, *PUMP turbines, *ELECTRIC power distribution grids, *WATER distribution

Abstract

Although pressure regulation valves (PRVs) are commonly used for reducing leakage in water distribution networks (WDNs), in recent years, many studies have highlighted the opportunity of using pumps as turbines (PATs) so as to couple pressure reduction (and thus leakage reduction) with hydropower generation. Unlike in water transmission systems however, flow discharge in a WDN varies continuously, consequently requiring real-time control (RTC) of pressure. Nevertheless, RTC of a PAT in a WDN remains an open issue, due to the lack of information and knowledge about PAT operation in a real environment. Whereas previous experimental studies have described PAT installation with a frequency converter in which the power produced gets dissipated through electrical resistance, in the hydraulic regulation layout, impeller speed depends on the electrical grid. Consequently, this paper proposes a comprehensive algorithm to both control the pressure at the control node of a WDN and produce power through a PAT directly connected to the electrical grid. The operation of the prototype was considered under hydraulic regulation, demonstrated by several studies to represent the most effective trade-off between costs and benefits. Further testing by means of laboratory experiments designed to simulate the operation of a grid-connected PAT installed in a WDN effectively validated the robustness of the proposed method. The results proved the ability of the prototype and algorithm to couple hydropower generation with pressure control even when the flow varied suddenly. [ABSTRACT FROM AUTHOR]

Published

2024

34. Forecasting intrusion in critical power systems infrastructure using Advanced Autoregressive Moving Average (AARMA) based intrusion detection for efficacious alert system.

Author

Singh, Neeraj Kumar, Majeed, Mahshooq Abdul, and Mahajan, Vasundhara

Subjects

INFRASTRUCTURE (Economics), MOVING average process, DATA science, ELECTRIC power distribution grids, SECURITY systems, INTRUSION detection systems (Computer security)

Abstract

Copyright of Scientia Iranica. Transaction D, Computer Science & Engineering & Electrical Engineering is the property of Scientia Iranica and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

35. Cyber‐attack and defense method for load frequency control in smart grid systems with electric vehicles.

Author

Ranjan, Mrinal, Shankar, Ravi, Raj, Utkarsh, Kumar, Sarvesh, and Kumar, Jitendra

Subjects

ELECTRIC power distribution grids, OPTIMIZATION algorithms, RENEWABLE energy sources, GRIDS (Cartography), DEEP learning

Abstract

The latest advancements in Vehicle‐to‐Grid (V2G) technology enable Electric Vehicles (EVs) to contribute to Frequency Regulation (FR), mitigating the impact of uncertain power fluctuations in renewable resources. However, diverse cyber‐attacks pose threats to the Load Frequency Control (LFC) system and smart grid infrastructure, compromising their accuracy and reliability. This research paper focuses on the effects of cyber‐attacks on frequency regulation in a smart grid system that relies on a communication network. The study proposes a two‐area system and a modified IEEE‐39 bus three‐area system, incorporating intermittent solar photovoltaic and wind turbine sources, traditional conventional sources, and electric vehicles. To ensure frequency stabilization and tie‐line power, the researchers introduce a cascade FOPIDN‐(1+TD) controller. Its parameters are optimized using a novel Quasi Opposition Arithmetic Optimization Algorithm (QOAOA). The proposed approach's dynamic response is compared with other commonly used controllers, demonstrating its effectiveness in maintaining stability. The article focuses on the LFC system and presents a novel approach involving a cyber‐physical model. It introduces a method for detecting and defending against cyber‐attacks using deep learning, specifically utilizing the Long‐Short‐Term‐Memory (LSTM) network. The effectiveness of the proposed defense strategy is demonstrated through experiments conducted on both a two‐area interconnected power system and the IEEE‐39 bus system. The outcomes indicate that the suggested defense mechanism effectively maintains acceptable levels of power system frequency and tie‐line power during cyber‐attacks. Additionally, the validity of the controller's performance is verified through real‐time analysis using Hardware‐In‐The‐Loop (HIL) simulation with the OPAL‐RT platform. [ABSTRACT FROM AUTHOR]

Published

2024

36. Ship Power System Network Reconfiguration Based on Swarm Exchange Particle Swarm Optimization Algorithm.

Author

Meng, Ke, Zhang, Jundong, Xu, Zeming, Zhou, Aobo, Wu, Shuyun, Zhu, Qi, and Pang, Jiawei

Subjects

PARTICLE swarm optimization, GOLDEN ratio, NAVIGATION in shipping, GLOBAL optimization, ELECTRIC power distribution grids, GENETIC algorithms

Abstract

As one of the important components of a ship, the ship's integrated power system is an important safeguard for ships. In order to improve the service life of the ship's power grid, the power system should be able to realize rapid reconstruction to ensure continuous power supply of important loads when the ship is attacked or fails suddenly. Therefore, it is of vital importance to study the reconfiguration technology of the ship's integrated power system to ensure that it can quickly and stably cope with all kinds of emergencies in order to guarantee the safe and reliable navigation of the ship. This paper takes the ship's ring power system as the research object and sets up the maximum recovery load and the minimum number of switching operations. The load is divided uniformly and the generator efficiency is balanced for the reconstruction of comprehensive function. It also sets up the system capacity, topology, and branch current limitations of the constraints to establish a mathematical model. The load branch correlation matrix method is used for branch capacity calculation and generator efficiency equalization calculation, and the load backup power supply path matrix is added on the basis of the matrix to judge the connectivity of some loads before reconfiguration. In this paper, for the network reconfiguration of the ship circular power system, which is a discrete nonlinear problem with multiple objectives, multiple time periods, and multiple constraints, we choose to use the particle swarm algorithm, which is suitable for global optimization, with a simple structure and fewer parameters; improve the particle swarm algorithm using the swarm exchange strategy by setting up two main and auxiliary swarms for global and local search; and exchange some of the particles with the golden ratio in order to keep the diversity of the populations. The simulation results of the network reconfiguration of the ship power system show that the improved algorithm can solve the power system network reconfiguration problem more effectively and provide a feasible reconfiguration scheme in a shorter time compared with the chaotic genetic algorithm under the same fault case test, and it also proves that the use of the swarm exchange particle swarm algorithm greatly improves the performance of reconfiguring the power grid of the ship. [ABSTRACT FROM AUTHOR]

Published

2024

37. Power Signal Histograms—A Method of Power Grid Data Compression on the Edge for Real-Time Incipient Fault Forensics.

Author

Tyler, Joshua H., Reising, Donald R., Cooke, Thomas, and Murphy, Anthony

Subjects

DATA compression, DATA libraries, DATA warehousing, ELECTRIC power distribution grids, IMAGE registration

Abstract

Across the power grid infrastructure, deployed power transmission systems are susceptible to incipient faults that interrupt standard operations. These incipient faults can range from being benign in impact to causing massive hardware damage and even loss of life. The power grid is continuously monitored, and incipient faults are recorded by Digital Fault Recorders (DFRs) to mitigate such outcomes. DFR-recorded data allow for power quality forensics and event analysis, but this ability comes at the cost of high data storage and data transmission requirements. It is common for data older than two weeks to be overwritten due to storage limitations, without being analyzed. This inhibits the creation of long-term data libraries that would enable incipient fault forensics and the characterization of behavior that precedes them, which limits the development and implementation of preventive measures; thus, there is a critical need to reduce DFR-recorded data's storage requirements. This work addresses this critical need by leveraging the cyclic and residual histograms and introducing the frequency and Root Means Squared (RMS) histograms, which alleviate the current high data storage requirements and provide effective Incipient Fault Prediction (IFP). The residual, frequency, and RMS histograms are an extension of the cyclic histogram, reduce the data storage requirement by up to 99.58 %, can be generated on the DFR without interrupting its normal operations, and are capable of predicting voltage arcing six hours before it is strong enough to trigger a DFR-recorded event. [ABSTRACT FROM AUTHOR]

Published

2024

38. Condition Monitoring of Electrical Transformers Using the Internet of Things: A Systematic Literature Review.

Author

Msane, Mzamo R., Thango, Bonginkosi A., and Ogudo, Kingsley A.

Subjects

FAULT diagnosis, INTERNET of things, ELECTRIC power distribution grids, DATABASE searching, MICROCONTROLLERS, SYSTEM downtime

Abstract

Featured Application: IoT-based transformer monitoring enhances predictive maintenance, reduces downtime, and optimizes power grid reliability and efficiency in smart grids. The adoption of Internet of Things (IoT) technology for transformer condition monitoring is increasingly replacing traditional methods. This systematic review aims to evaluate the existing research on IoT frameworks used in transformer condition monitoring, providing insights into their effectiveness and research trends. This review seeks to identify the leading IoT frameworks employed in transformer condition monitoring; analyze the key research objectives, methods, and outcomes; and assess the global research distribution and technological tools used in this field. A systematic literature review was conducted by searching published databases using keywords related to "Internet of Things", "transformers", "condition monitoring", and "fault diagnosis". The search spanned publications released between 2014 and 2024, yielding 262 articles. Of these, 120 met the predefined review criteria and were included for further analysis. This review found that Arduino boards are the most used microcontrollers for monitoring and analyzing transformer operational parameters, with Arduino IDE 1.8 being the predominant software for programming. The primary research focus in the reviewed literature is the identification of transformer faults. The geographical distribution of research contributions shows that India leads with 65% of the studies, followed by China (11%) and Pakistan (5%). The findings indicate a strong global interest in developing IoT-based transformer condition monitoring systems, particularly in India. This review highlights the potential of IoT technologies to enhance transformer monitoring and diagnostics. The insights gained from this review can guide future research and the development of more advanced IoT frameworks for transformer condition monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

39. Reducing Peak Power in a Multiple Load System by Delaying the Activation of Electrical Loads Using a Filter Based on a PI Controller.

Author

Kasprzyk, Jerzy and Szulc, Michał

Subjects

ELECTRICAL load, TRACKING control systems, ELECTRIC power, ENERGY consumption, ELECTRIC power distribution grids

Abstract

In a power grid with multiple two-state loads, the total power can vary over a significant range. This results in the inability to supply this system from a low-power source. The solution is an algorithm that shapes energy demand depending on its availability. For this purpose, a new load distribution method is proposed based on introducing a buffer between the temperature controller output and the heater and filtering the load using a master Proportional–Integral (PI) controller. The aim of the work was to evaluate the quality of the developed algorithm for limiting power peaks in the power grid. The research was conducted on a model of the Creep Test Laboratory with 389 heaters simulated in MATLAB Simulink R2023b. The algorithm was tested with various settings of the master controller parameters. By experimentally adjusting these parameters, a ten-fold reduction in peak power was achieved. The standard deviation for the L1 phase was reduced from 7.6 kW to 0.6 kW. Similar results were obtained for phases L2 and L3. The tested control system tracked changes in the average power value by changing the number of loads switched on and by frequency-modulating the signal when the change was less than the power of a single load. It was demonstrated that the controlled delayed switching of electrical loads can modify the shape of the total electric power without affecting their operation. The proposed solution features a low computational complexity, which allows its implementation in various systems. [ABSTRACT FROM AUTHOR]

Published

2024

40. Comparison of Advanced Flexible Alternating Current Transmission System (FACTS) Devices with Conventional Technologies for Power System Stability Enhancement: An Updated Review †.

Author

Carbonara, Andrea, Dambone Sessa, Sebastian, L'Abbate, Angelo, Sanniti, Francesco, and Chiumeo, Riccardo

Subjects

FLEXIBLE AC transmission systems, SCIENTIFIC literature, RENEWABLE energy sources, SYNCHRONOUS capacitors, ELECTRIC power distribution grids

Abstract

The continuously growing penetration of renewable energy sources (RESs) in electrical networks provides increasing challenges and critical situations to be managed by worldwide system operators. Due to their features and variability, non-programmable RES power plants, whose increasing penetration reduces the inertia level of the power system, may determine the instability effects on the grids, especially from the frequency and voltage regulation standpoints. The present study focuses on the support that advanced FACTS (Flexible Alternating Current Transmission System) devices, such as STATCOMs (Static Synchronous Compensators), can provide to the power system operation in terms of system inertia improvement, frequency stability, and voltage stability. In particular, a review of the scientific literature and practice is performed, with the aim of benchmarking the ongoing evolution of these technologies, also comparing them with different options based on synchronous condensers, synchronous condensers integrated with flywheels, and STATCOMs with supercapacitors. The outcome of the analysis consists of an updated evaluation of the state-of-the-art technological development in the field and of a comparison between different FACTSs with the purpose of identifying the most suitable solutions for different practical situations, also taking account of synergies across various options. This study includes an updated overview regarding the status of STATCOM installation in the Italian power grid. [ABSTRACT FROM AUTHOR]

Published

2024

41. Short-Term Prediction Model of Wave Energy Converter Generation Power Based on CNN-BiLSTM-DELA Integration.

Author

Zhang, Yuxiang, Liu, Shihao, Shen, Qian, Zhang, Lei, Li, Yi, Hou, Zhiwei, and Chen, Renwen

Subjects

CONVOLUTIONAL neural networks, RENEWABLE energy sources, WAVE energy, OCEAN wave power, ELECTRIC power distribution grids

Abstract

Wave energy is a promising source of sustainable clean energy, yet its inherent intermittency and irregularity pose challenges for stable grid integration. Accurate forecasting of wave energy power is crucial for reliable grid management. This paper introduces a novel approach that utilizes a Bidirectional Gated Recurrent Unit (BiGRU) network to fit the power matrix, effectively modeling the relationship between wave characteristics and energy output. Leveraging this fitted power matrix, the wave energy converter (WEC) output power is predicted using a model that incorporates a Convolutional Neural Network (CNN), a Bidirectional Long Short-Term Memory (BiLSTM) network, and deformable efficient local attention (DELA), thereby improving the accuracy and robustness of wave energy power prediction. The proposed method employs BiGRU to transform wave parameters into power outputs for various devices, which are subsequently processed by the CNN-BiLSTM-DELA model to forecast future generation. The results indicate that the CNN-BiLSTM-DELA model outperforms BiLSTM, CNN, BP, LSTM, CNN-BiLSTM, and GRU models, achieving the lowest mean squared error (0.0396 W) and mean absolute percentage error (3.7361%), alongside the highest R 2 (98.69%), underscoring its exceptional forecasting accuracy. By enhancing power forecasting, the method facilitates effective power generation dispatch, thereby mitigating the adverse effects of randomness on the power grid. [ABSTRACT FROM AUTHOR]

Published

2024

42. Optimal Configuration Method for Multi-Type Reactive Power Compensation Devices in Regional Power Grid with High Proportion of Wind Power.

Author

Wang, Ying, Dang, Jie, Ding, Cangbi, Zheng, Chenyi, and Tang, Yi

Subjects

ELECTRIC power distribution grids, REACTIVE power, ELECTRIC potential, WIND power, CONSTRUCTION costs, WIND power plants, OFFSHORE wind power plants

Abstract

As the large-scale development of wind farms (WFs) progresses, the connection of WFs to the regional power grid is evolving from the conventional receiving power grid to the sending power grid with a high proportion of wind power (WP). Due to the randomness of WP output, higher requirements are put forward for the voltage stability of each node of the regional power grid, and various reactive power compensation devices (RPCDs) need to be rationally configured to meet the stable operation requirements of the system. This paper proposes an optimal configuration method for multi-type RPCDs in regional power grids with a high proportion of WP. The RPCDs are located according to the proposed static voltage stability index (VSI) and dynamic VSI based on dynamic voltage drop area, and the optimal configuration model of RPCDs is constructed with the lowest construction cost as the objective function to determine the installed capacity of various RPCDs. Finally, the corresponding regional power grid model for intensive access to WFs is constructed on the simulation platform to verify the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

43. A Two-Layer Optimal Scheduling Strategy for Rural Microgrids Accounting for Flexible Loads.

Author

Zhao, Guo, Zhang, Chi, and Ren, Qiyuan

Subjects

CLEAN energy, ELECTRIC power distribution grids, ENERGY consumption, RENEWABLE energy sources, GENETIC algorithms

Abstract

In the context of China's "double carbon" goals and rural revitalization strategy, the energy transition promotes the large-scale integration of distributed renewable energy into rural power grids. Considering the operational characteristics of rural microgrids and their impact on users, this paper establishes a two-layer scheduling model incorporating flexible loads. The upper-layer aims to minimize the comprehensive operating cost of the rural microgrid, while the lower-layer aims to minimize the total electricity cost for rural users. An Improved Adaptive Genetic Algorithm (IAGA) is proposed to solve the model. Results show that the two-layer scheduling model with flexible loads can effectively smooth load fluctuations, enhance microgrid stability, increase clean energy consumption, and balance microgrid operating costs with user benefits. [ABSTRACT FROM AUTHOR]

Published

2024

44. Intelligent optimal demand response implemented by blockchain and cooperative game in microgrids.

Author

Bai, Fenhua, Zhang, Chi, and Zhang, Xiaohui

Subjects

ENERGY consumption forecasting, BLOCKCHAINS, MICROGRIDS, POWER resources, ELECTRIC power distribution grids, ENERGY industries

Abstract

Distributed renewable energy supply (RES) is a new pattern for the transformation of power grids. As a characteristic case of RES, microgrids have an advantage in convenient operation. However, the energy management of microgrids remains as a major concern. With the emergence of the decentralized paradigm, blockchain potentially provides a reliable energy data metering and payment for the whole life cycle of energy management. In particular, the demand response (DR) in the microgrid can stimulate demanders to spontaneously manage their load consumption and maintain the balance of the energy trading market. To achieve optimal DR, a dynamic pricing strategy under the blockchain and game‐theoretic approach is proposed. First, the blockchain‐based architecture is applied to ensure the reliability of energy data and lay a foundation of binding agreements for games. Then, the pricing mechanism under the cooperative game is formulated to optimize DR. Moreover, to help resolve the optimal response quantity and reduce the supply punishment of the RES providers, the DR requires accurate forecasting of the energy generation and consumption profiles. Therefore, an ensemble method Long Short‐Term Gate Support (LSTGS) is designed to forecast the RES and load power for intelligent agent to make decision on effective energy scheduling and DR. Taking the classic distributed energy context as a case study, we demonstrate the effectiveness of our approach and show that it can achieve DR profits maximized and improve the stability of the energy‐trading market. [ABSTRACT FROM AUTHOR]

Published

2024

45. Improving quality of electricity generated by grid-tied inverters in solar power plants in low generated power mode using frequency adaptive PWM.

Author

Plakhtii, Oleksandr, Nerubatskyi, Volodymyr, Ivakhno, Volodymyr, and Zamaruiev, Volodymyr

Subjects

SOLAR power plants, ELECTRIC currents, ELECTRIC power distribution grids, SOLAR energy, ELECTRICITY, PULSE width modulation, PULSE width modulation transformers

Abstract

Copyright of Automatisierungstechnik is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

46. THE DEFECT IDENTIFICATION SYSTEM OF ELECTROMECHANICAL EQUIPMENT ON THE EDGE SIDE OF THE POWER GRID UNDER EDGE COMPUTING.

Author

HAIAN HAN and FAN HU

Subjects

SYSTEM identification, ELECTRIC power distribution grids, INDUSTRIALISM, EDGE computing, DEEP learning

Abstract

With the development of the industrial Internet of Things, modern industrial systems have developed towards intelligence. Electromechanical Equipment (EE) is essential, and its defect identification is fundamental. Firstly, this research introduces the basic content of Gated Recurrent Unit (GRU), Variational Auto-Encoder (VAE) in Deep Learning (DL), and Edge Computing (EC) to explore the construction of a defect identification system for EE on the edge side of the power grid. Secondly, combined with the advantages of GRU and VAE, a GRU-VAE defect recognition model is proposed. Then, the EC architecture is introduced, and the EE defect identification system based on the GRU-VAE algorithm is constructed. The EC intelligent EE defect identification service system is designed with this as the core. Finally, simulation experiments are carried out using different data sets to verify the performance of the GRU-VAE model. The results show that the GRU-VAE model has higher precision and recall than the separate GRU model and VAE model, and the corresponding F1 value is also higher. The F1 value can reach 0.997 on aperiodic data and 0.966 on periodic data. In addition, the optimal thresholds of different datasets are analyzed, and the relationship between the length of the time window and the model's performance is studied. When the time window length is 15, the model performance is optimal. This research on the defect identification system of EE on the edge side of the power grid based on EC and DL can provide a new path and inject new vitality into the defect detection of EE. [ABSTRACT FROM AUTHOR]

Published

2024

47. EDGE COMPUTING METHOD FOR FALSE DATA INJECTION ATTACK DETECTION IN ELECTROMECHANICAL TRANSIENT SIMULATION GRID.

Author

GANG YANG, YING ZHANG, LILI ZHAO, LIMIN ZHANG, and NA ZHANG

Subjects

CUMULATIVE distribution function, STANDARD deviations, EDGE computing, KALMAN filtering, ELECTRIC power distribution grids

Abstract

Because edge computing is close to the terminal, it has significant advantages of low latency and high-security realtime control and has huge application prospects in the current popular smart grid. Because its edge side is close to the terminal, it can also effectively avoid the risk of information leakage when control instructions or communication data are transmitted to remote cloud center servers over a long distance. However, edge devices have a greater probability of encountering false data injection attacks (FDIAs) from illegal terminals because of their proximity to terminals. The transient electromechanical situation of the smart grid due to FDIAs is analyzed under edge computing. Due to the characteristics that the status values of grid nodes have temporal correlation before and after and spatial correlation between nodes, the Long Short-Term Memory (LSTM) for training time series data is selected to predict the status values of grid nodes in advance. The FDIA detection method is also proposed based on the LSTM network. By calculating the predicted value at each historical moment and the root means square error (RMSE) of the system state estimation at that moment, the detection threshold of the scheme is calculated through the cumulative distribution function of RMSE. Simulation experiments are conducted on the Institute of Electrical and Electronics Engineers (IEEE)-14 node standard system. The detection rate is as high as 99.71%, which verifies the effectiveness of the proposed FDIA detection scheme. This paper studies the security threat of FDIA to the stable power system operation and provides theoretical analysis and practical reference for other power grid security protection strategies. [ABSTRACT FROM AUTHOR]

Published

2024

48. Profit maximization of a wind-integrated deregulated system using V2G techniques and TCSC placement.

Author

Dawn, Subhojit, Ramakrishna, A., Ramesh, M., Das, Shreya Shree, Rao, K. Dhananjay, Cali, Umit, and Ustun, Taha Selim

Subjects

PROFIT maximization, RENEWABLE natural resources, ELECTRIC power distribution grids, SUSTAINABLE development, ENERGY industries

Abstract

Profit maximization is crucial for both producers and customers in power grids, particularly in deregulated energy markets. By focusing on profit maximization measures, power grids can improve economic viability and sustainability for all stakeholders. The growing demand for electricity in modern civilization poses a significant challenge to the power grid's ability to meet it. To address these difficulties, the power industry is attempting to integrate renewable sources into existing power facilities. Because of its unpredictable character, the presence of renewable energy in the electricity system becomes increasingly important and adds complexity to the grid. Given the intermittent nature of renewable sources, an energy storage device is required in this scenario. During the low-power use phase, the grid has ample power. Meanwhile, energy storage devices can be utilized to store extra power in the low power demand phase while maintaining the safety and stability of the power network during peak demand periods. V2G (Vehicle-to-Grid) technology is commonly employed to address the uncertainty of renewable resources while maintaining system stability. By using automobiles as transportable storage devices, V2G can make the best use of excess electricity during low-energy hours. Wind energy's volatility causes imbalances, lowering system profitability. With wind energy integration, power system profitability can be improved by analyzing uncertainties and employing mitigation strategies. To overcome the issue, the research optimizes the use of V2G and TCSC (thyristor-controlled series compensator). V2G permits bidirectional power flow, lowering imbalance pricing (IP) while considering power demand. TCSC can increase the transient stability of transmission lines, hence reducing line faults. TCSC's involvement in the system increases profitability by lowering congestion expenses. Strategic TCSC placement increases overall profitability. The approach strives to offer efficient, environmentally friendly power at a reasonable price while addressing the needs of both power providers and customers. This study also looks into the effects of V2G mixing on voltage stability, LMP (locational marginal price), and the effectiveness of a TCSC in a deregulated electrical system. MiPower software is used to simulate operation and find the optimal placement of the storage unit within the IEEE 14-bus system. [ABSTRACT FROM AUTHOR]

Published

2024

49. BN‐based seismic risk analysis and mitigation strategy for UHV converter station.

Author

Wu, Siyuan, Liu, Xiao, Chen, Junhan, and Xie, Qiang

Subjects

EARTHQUAKE hazard analysis, DISTRIBUTION (Probability theory), BAYESIAN analysis, ELECTRIC power distribution grids, CONDITIONAL probability

Abstract

Ultra‐high voltage (UHV) converter stations are critical nodes in power grids. This paper proposes a probabilistic framework for assessing and mitigating the seismic risk of UHV converter station systems to enhance the seismic performance of the grid. First, a Bayesian network model for the system functionality of UHV converter stations was established based on the enumeration of equipment failure scenarios. Conditional probability tables (CPTs) were used to represent the causal relationship among subsystems and system functionality. Inference calculations were conducted using Bayes' theorem. Then, the definition of system seismic loss risk distribution was proposed to assess the seismic risk of the system over its entire lifespan. The feasibility of this framework was validated using a specific UHV converter station, yielding analytical solutions for the probability distribution of system functionality and seismic vulnerability curves. Additionally, the cost‐effectiveness of several risk mitigation strategies was assessed. A cost‐benefit analysis was performed from the perspectives of both the expected loss of a single earthquake and the life‐cycle cost. The framework comprehensively considered the constraints imposed by series, parallel, and bypass control devices on the system's functionality. It was revealed that the seismic loss risk for UHV converter stations exhibits a characteristic of low probability but high loss. [ABSTRACT FROM AUTHOR]

Published

2024

50. Self-Attention Spatio-Temporal Deep Collaborative Network for Robust FDIA Detection in Smart Grids.

Author

Zu, Tong and Li, Fengyong

Subjects

INDEPENDENT system operators, ELECTRIC power distribution grids, DEEP learning, TIME series analysis, NOISE

Abstract

False data injection attack (FDIA) can affect the state estimation of the power grid by tampering with the measured value of the power grid data, and then destroying the stable operation of the smart grid. Existing work usually trains a detection model by fusing the data-driven features from diverse power data streams. Data-driven features, however, cannot effectively capture the differences between noisy data and attack samples. As a result, slight noise disturbances in the power grid may cause a large number of false detections for FDIA attacks. To address this problem, this paper designs a deep collaborative self-attention network to achieve robust FDIA detection, in which the spatio-temporal features of cascaded FDIA attacks are fully integrated. Firstly, a high-order Chebyshev polynomials-based graph convolution module is designed to effectively aggregate the spatio information between grid nodes, and the spatial self-attention mechanism is involved to dynamically assign attention weights to each node, which guides the network to pay more attention to the node information that is conducive to FDIA detection. Furthermore, the bi-directional Long Short-Term Memory (LSTM) network is introduced to conduct time series modeling and long-term dependence analysis for power grid data and utilizes the temporal self-attention mechanism to describe the time correlation of data and assign different weights to different time steps. Our designed deep collaborative network can effectively mine subtle perturbations from spatiotemporal feature information, efficiently distinguish power grid noise from FDIA attacks, and adapt to diverse attack intensities. Extensive experiments demonstrate that our method can obtain an efficient detection performance over actual load data from New York Independent System Operator (NYISO) in IEEE 14, IEEE 39, and IEEE 118 bus systems, and outperforms state-of-the-art FDIA detection schemes in terms of detection accuracy and robustness. [ABSTRACT FROM AUTHOR]

Published

2024