Adaptive Model Predictive Controller to Reduce Switching Losses for a Capacitor-Less D-STATCOM

Rohouma, Wesam; Metry, Morcos; Balog, Robert S.; Peerzada, Aaqib Ahmad; Begović, Miroslav

doi:10.1109/ojpel.2020.3015352

Cited by 25 publications

(7 citation statements)

References 43 publications

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“…In moderate DSTATCOM usage, this study provides a three-phase transformer-less architecture of modular multilevel converters (MMC) based on tumbled pulse width-modulated chopper cells [72]. To lower switching rate and switching losses in a capacitor less DSTATCOM, this paper developed an updated model predictive control (MPC) controller that penalizes high-resolution efficiency within permitted THD guidelines [73]. The modular multilevel cascade converter based on single-star bridge cells (MMCC-SSBC) is used in this study to show and explore a phasing shifted-pulse width modulation (PWM) distribution static synchronous compensator (DSTATCOM) [74].…”

Section: D-facts Planningmentioning

confidence: 99%

Challenges and opportunities of FACTS devices interacting with electric vehicles in distribution networks: A technological review

Mousaei,

Gheisarnejad,

Khooban

2023

Journal of Energy Storage

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Section: D-facts Planningmentioning

confidence: 99%

Challenges and opportunities of FACTS devices interacting with electric vehicles in distribution networks: A technological review

Mousaei,

Gheisarnejad,

Khooban

2023

Journal of Energy Storage

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“…In the light of these observations, a capacitor-less D-STATCOM based on a matrix converter (MC) has been proposed recently to address the dual challenges of fast reactive support and increased reliability [4]. The newly proposed capacitor-less D-STATCOM uses inductive storage and is controlled using a finite control set model predictive control (MPC).…”

Section: Introductionmentioning

confidence: 99%

Playing the (Streaming) Fame Game: (Re)presentations of success, challenges, and demand in streaming simulation games

Boudreau,

Bowman,

Consalvo

et al. 2024

Proceedings of the Annual Hawaii International Conference on System Sciences

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The increasing adoption of distributed energy resources (DERs), particularly solar generation and the use of unconventional loads such as plug-in electric vehicles (PHEVs), has a profound impact on the planning and operation of electric distribution systems. In particular, PHEV charging introduces stochastic peaks in energy consumption, while solar generation is fraught with variability during intermittent clouds. The stochastic nature of such DERs renders the operation of mechanical assets such as on-load tap changers and switched capacitor banks ineffective. A possible solution to mitigate the undesirable effects of DERs is using solid-state-based devices such as a distribution static synchronous compensator (D-STATCOM). This paper examines the capacity usage of a capacitor-less D-STATCOM in distribution systems while considering the uncertainties associated with using the aforementioned DERs. We propose a Monte Carlo simulation to study the capacity usage problem with DER inputs sampled from the proposed underlying distributions.

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“…The only difference between the proposed capacitorless D-STATCOM and the incumbent D-STATCOM is inductors instead of capacitors for energy storage. Previous literature on the capacitorless D-STATCOM has focused on power electronics and controls [47]. The impact of the capacitorless D-STATCOM on the overall power system has not been as well studied.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Capacitor-Less D-STATCOM for Voltage Profile Improvement in Distribution Network With High PV Penetration

Rohouma

Metry

Balog

et al. 2022

IEEE Open J. Power Electron.

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Distributed Energy Resources (DERs) have disrupted the traditional electrical system. Grid-connected photovoltaic (PV) systems deliver electric energy closer to the consumer, shifting the paradigm from centralized to distributed generation. The impact of the stochastic PV output power gives rise to potentially rapid voltage fluctuations. Reactive power compensation is needed to regulate the voltage profile to meet the relevant standards. Traditional approaches like switched capacitors cannot provide reactive power that is continuously adjustable at short time scales. This paper examines an alternative distribution static synchronous compensator (D-STATCOM) based on a matrix converter (MC) for the low voltage distribution networks with high PV penetration. This technology can extend service life by using inductors for energy storage. The converter being studied provides ancillary services, including reactive power support; the impact on reliability, operational constraints, and electrical behavior is demonstrated. The contribution of this paper is a detailed analysis and impact study of the capacitor-less D-STATCOM in high PV penetration distribution networks. The significance of this paper is that it studies the behavior of the power electronics converter and its interaction with the power systems without assuming or neglecting details of either. Compensation effects and reliability comparisons between the proposed capacitorless D-STATCOM and the incumbent D-STATCOM technology are also studied in

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Adaptive Model Predictive Controller to Reduce Switching Losses for a Capacitor-Less D-STATCOM

Cited by 25 publications

References 43 publications

Challenges and opportunities of FACTS devices interacting with electric vehicles in distribution networks: A technological review

Challenges and opportunities of FACTS devices interacting with electric vehicles in distribution networks: A technological review

Playing the (Streaming) Fame Game: (Re)presentations of success, challenges, and demand in streaming simulation games

Analysis of the Capacitor-Less D-STATCOM for Voltage Profile Improvement in Distribution Network With High PV Penetration

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