Supraharmonics in Power Grid: Identification, Standards, and Measurement Techniques

Alfalahi, Saad T. Y.; Alkahtani, Ammar Ahmed; Al-Shetwi, Ali Q.; Al-Ogaili, Ali Saadon; Abbood, Afaneen A.; Mansor, Muhamad; Fazea, Yousef

doi:10.1109/access.2021.3099013

Cited by 45 publications

(35 citation statements)

References 48 publications

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“…Very high power DCFCs can lead to superharmonic disturbances on LV and MV grid distribution networks. The main sources of supraharmonics are power electronic converters within the frequency range of 2-150 kHz [149,158]. Supraharmonics have a detrimental impact on power quality in electrical distribution systems [158].…”

Section: Harmonic Distortionsmentioning

confidence: 99%

“…The main sources of supraharmonics are power electronic converters within the frequency range of 2-150 kHz [149,158]. Supraharmonics have a detrimental impact on power quality in electrical distribution systems [158]. This may lead to additional heating, reduced lifetime, malfunctioning of equipment, tripping of residual current devices, increased capacitive currents and associated safety risks, and protection device and security system failures [11,158].…”

Section: Harmonic Distortionsmentioning

confidence: 99%

“…Supraharmonics have a detrimental impact on power quality in electrical distribution systems [158]. This may lead to additional heating, reduced lifetime, malfunctioning of equipment, tripping of residual current devices, increased capacitive currents and associated safety risks, and protection device and security system failures [11,158]. Supraharmonics generated by inverters used in renewable energy generation and their negative impacts on distribution grids are discussed in [158].…”

Section: Harmonic Distortionsmentioning

confidence: 99%

“…This may lead to additional heating, reduced lifetime, malfunctioning of equipment, tripping of residual current devices, increased capacitive currents and associated safety risks, and protection device and security system failures [11,158]. Supraharmonics generated by inverters used in renewable energy generation and their negative impacts on distribution grids are discussed in [158]. Research on the sources and impacts of superharmonic emissions in microgrids, and how the integration of new technologies, such as renewable energy generation and DCFCs, can worsen the negative impacts of supraharmonics in microgrids, is discussed in [11,158].…”

Section: Harmonic Distortionsmentioning

confidence: 99%

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Review of Fast Charging for Electrified Transport: Demand, Technology, Systems, and Planning

2022

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As the number and range of electric vehicles in use increases, and the size of batteries in those vehicles increases, the demand for fast and ultra-fast charging infrastructure is also expected to increase. The growth in the fast charging infrastructure raises a number of challenges to be addressed; primarily, high peak loads and their impacts on the electricity network. This paper reviews fast and ultra-fast charging technology and systems from a number of perspectives, including the following: current and expected trends in fast charging demand; the particular temporal and spatial characteristics of electricity demand associated with fast charging; the devices and circuit technologies commonly used in fast chargers; the potential system impacts of fast charging on the electricity distribution network and methods for managing those impacts; methods for long-term planning of fast charging facilities; finally, expected future developments in fast charging technology and systems.

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Section: Harmonic Distortionsmentioning

confidence: 99%

Section: Harmonic Distortionsmentioning

confidence: 99%

Section: Harmonic Distortionsmentioning

confidence: 99%

Section: Harmonic Distortionsmentioning

confidence: 99%

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Review of Fast Charging for Electrified Transport: Demand, Technology, Systems, and Planning

2022

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“…However, oil-based fuel remains the most efficient source of energy on a WTT basis, based on current energy production technologies, with an average of 3.82 MJ/km, followed by hydrogen (7 MJ/km) and electricity (11.90 MJ/km). However, when it comes to natural resources and energy security, renewable energy-based power is perhaps the most efficient, and therefore desirable, form of energy [44][45][46]. Based on [8,41], TTW energy consumption is commonly measured in diesel equivalent miles per gallon (mpg) or megajoules per kilometer (MJ/km).…”

Section: Wtw Energy Efficiencymentioning

confidence: 99%

Review of the Estimation Methods of Energy Consumption for Battery Electric Buses

Al-Ogaili¹,

Al-Shetwi

Al‐Masri

et al. 2021

Energies

Self Cite

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In the transportation sector, electric battery bus (EBB) deployment is considered to be a potential solution to reduce global warming because no greenhouse gas (GHG) emissions are directly produced by EBBs. In addition to the required charging infrastructure, estimating the energy consumption of buses has become a crucial precondition for the deployment and planning of electric bus fleets. Policy and decision-makers may not have the specific tools needed to estimate the energy consumption of a particular bus network. Therefore, many state-of-the-art studies have proposed models to determine the energy demand of electric buses. However, these studies have not critically reviewed, classified and discussed the challenges of the approaches that are applied to estimate EBBs’ energy demands. Thus, this manuscript provides a detailed review of the forecasting models used to estimate the energy consumption of EBBs. Furthermore, this work fills the gap by classifying the models for estimating EBBs’ energy consumption into small-town depot and big-city depot networks. In brief, this review explains and discusses the models and formulations of networks associated with well-to-wheel (WTW) assessment, which can determine the total energy demand of a bus network. This work also reviews a survey of the most recent optimization methods that could be applied to achieve the optimal pattern parameters of EBB fleet systems, such as the bus battery capacity, charger rated power and the total number of installed chargers in the charging station. This paper highlights the issues and challenges, such as the impact of external factors, replicating real-world data, big data analytics, validity index, and bus routes’ topography, with recommendations on each issue. Also, the paper proposes a generic framework based on optimization algorithms, namely, artificial neural network (ANN) and particle swarm optimization (PSO), which will be significant for future development in implementing new energy consumption estimation approaches. Finally, the main findings of this manuscript further our understanding of the determinants that contribute to managing the energy demand of EBBs networks.

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A Comprehensive Review on Supraharmonics—The Next Big Power Quality Concern

Rajkumar,

Balasubramanian,

Kathirvelu

2024

Smart Grids and Energy

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Supraharmonics in Power Grid: Identification, Standards, and Measurement Techniques

Cited by 45 publications

References 48 publications

Review of Fast Charging for Electrified Transport: Demand, Technology, Systems, and Planning

Review of Fast Charging for Electrified Transport: Demand, Technology, Systems, and Planning

Review of the Estimation Methods of Energy Consumption for Battery Electric Buses

A Comprehensive Review on Supraharmonics—The Next Big Power Quality Concern

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