Modular Multilevel Converters for Large-Scale Grid-Connected Photovoltaic Systems: A Review

Alotaibi, Saud; Darwish, Ahmed

doi:10.3390/en14196213

Cited by 24 publications

(14 citation statements)

References 131 publications

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“…Therefore, in EV fast and ultra-fast charging applications, multilevel converters (MLCs), including Cascaded H-Bridge (CHB) [46,47], Flying Capacitor (FC) [48,49], and Neutral Point Clamped (NPC) [50][51][52][53] converters have been preferable in some publications (see Figure 12). Their outstanding advantages include low THD, smaller dv/dt, minimized magnetic components, less voltage stress across the semiconductor devices in high-voltage applications (e.g., 100 V rated switches within the 400 V voltage battery range), low electromagnetic interference (EMI), and a low rated switch, in addition to reduced voltage transition between levels [132][133][134][135][136][137][138][139][140][141][142][143]. However, reliability, voltage balancing, high cost, and complex structure and control are some concerns related to MLCs.…”

Section: Ev-interfaced Converter Topologiesmentioning

confidence: 99%

Power Converter Topologies for Grid-Tied Solar Photovoltaic (PV) Powered Electric Vehicles (EVs)—A Comprehensive Review

2022

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The transport sector generates a considerable amount of greenhouse gas (GHG) emissions worldwide, especially road transport, which accounts for 95% of the total GHGs. It is commonly known that Electric vehicles (EVs) can significantly reduce GHG emissions. However, with a fossil-fuel-based power generation system, EVs can produce more GHGs and therefore cannot be regarded as purely environmentally friendly. As a result, renewable energy sources (RES) such as photovoltaic (PV) can be integrated into the EV charging infrastructure to improve the sustainability of the transportation system. This paper reviews the state-of-the-art literature on power electronics converter systems, which interface with the utility grid, PV systems, and EVs. Comparisons are made in terms of their topologies, isolation, power and voltage ranges, efficiency, and bi-directional power capability for V2G operation. Specific attention is devoted to bidirectional isolated and non-isolated EV-interfaced converters in non-integrated architectures. A brief description of EV charger types, their power levels, and standards is provided. It is anticipated that the studies and comparisons in this paper would be advantageous as an all-in-one source of information for researchers seeking information related to EV charging infrastructures.

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Section: Ev-interfaced Converter Topologiesmentioning

confidence: 99%

Power Converter Topologies for Grid-Tied Solar Photovoltaic (PV) Powered Electric Vehicles (EVs)—A Comprehensive Review

2022

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“…Several research papers considered the design and the control of modular and cascaded configurations instead of the conventional back-to-back converter in different RESs including PV and WTs [68][69][70][71][72][73][74][75][76][77][78][79][80]. Taking the large-scale PV (LSPV) systems, for example, modular converters emerged as a promising candidate where the power conversion stage is formed from several submodules (SMs) instead of one bulky centralized power converter.…”

Section: Modular and Cascaded Configurationsmentioning

confidence: 99%

A Review on Power Electronic Topologies and Control for Wave Energy Converters

Darwish

Aggidis

2022

Energies

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Ocean energy systems (OESs) convert the kinetic, potential, and thermal energy from oceans and seas to electricity. These systems are broadly classified into tidal, wave, thermal, and current marine systems. If fully utilized, the OESs can supply the planet with the required electricity demand as they are capable of generating approximately 2 TW of energy. The wave energy converter (WEC) systems capture the kinetic and potential energy in the waves using suitable mechanical energy capturers such as turbines and paddles. The energy density in the ocean waves is in the range of tens of kilowatts per square meter, which makes them a very attractive energy source due to the high predictability and low variability when compared with other renewable sources. Because the final objective of any renewable energy source (RES), including the WECs, is to produce electricity, the energy capturer of the WEC systems is coupled with an electrical generator, which is controlled then by power electronic converters to generate the electrical power and inject the output current into the utility AC grid. The power electronic converters used in other RESs such as photovoltaics and wind systems have been progressing significantly in the last decade, which improved the energy harvesting process, which can benefit the WECs. In this context, this paper reviews the main power converter architectures used in the present WEC systems to aid in the development of these systems and provide a useful background for researchers in this area.

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“…Due to its feature, this converter is suitable for medium-and high-voltage applications, e.g., high-power motor drives [7], high-voltage direct current transmission (HVDC) [8], unified power flow controller (UPFC) [9], and static synchronous compensators (STATCOM) [10,11]. Moreover, for gridconnected PV systems [12], modular multilevel inverters are the preferred solution to connect large-scale PV plants [13] to the medium-voltage (MV) grid because then the costly and bulky transformer can be removed.…”

Section: Introductionmentioning

confidence: 99%

An Improved Sliding Mode Control with Integral Surface for a Modular Multilevel Power Converter

et al. 2022

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This paper presents a novel method for current control for a modular multilevel converter (MMC). The proposed current control methodology is based on a modified sliding mode control (SMC) with proportional and integral (PI) sliding surface which allows fast transient responses and improves the robustness of the MMC control performance. As the proposed method is derived via Lyapunov direct method, the closed-loop stability is ensured and results in globally asymptotically stable. Furthermore, the reaching time is also guaranteed by the proposed method, leading to fast transient responses. The proposed method is validated by comparing with some existing methods, which are proportional integral controller and conventional SMC, via offline and hardware-in-loop (HIL) simulations where a 10 MW, medium-voltage MMC system is tested. According to these results, the proposed method is able to provide fast transient responses, zero overshoot, and robustness to the weak grid and short-circuit conditions.

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Modular Multilevel Converters for Large-Scale Grid-Connected Photovoltaic Systems: A Review

Cited by 24 publications

References 131 publications

Power Converter Topologies for Grid-Tied Solar Photovoltaic (PV) Powered Electric Vehicles (EVs)—A Comprehensive Review

Power Converter Topologies for Grid-Tied Solar Photovoltaic (PV) Powered Electric Vehicles (EVs)—A Comprehensive Review

A Review on Power Electronic Topologies and Control for Wave Energy Converters

An Improved Sliding Mode Control with Integral Surface for a Modular Multilevel Power Converter

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