Enhancement of power quality issues for a hybrid AC/DC microgrid based on optimization methods

Khosravi, Nima; Echalih, Salwa; Baghbanzadeh, Rasoul; Hekss, Zineb; Hassani, Rahman; Messaoudi, Mustapha

doi:10.1049/rpg2.12476

Cited by 21 publications

(10 citation statements)

References 38 publications

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“…The secondary control level comprises of both the voltage regulation loop and the current regulation loop [7]. The voltage regulation loop compensates for the voltage deviation caused by the droop control.…”

Section: Design Of Island Mode DC Microgridmentioning

confidence: 99%

“…The current regulation loop adjusts the power distribution based on the fluctuating power generation of RES and the battery charge status. The correction voltage values obtained from both regulation loops are added together and transmitted to the primary control [7].

\begin{equation}\delta {v}_i = \delta {v}_{V,i} + \delta {v}_{I,i},\end{equation}

where 𝛿𝑣 𝑉 ,i is the voltage regulation term and 𝛿𝑣 I,i is the current regulation term at node i .…”

Section: Design Of Island Mode DC Microgridmentioning

confidence: 99%

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Event‐triggered distributed secondary control for enhancing efficiency, reliability and communication in island mode DC microgrids

Irmak,

Kabalcı,

Calpbinici

2023

IET Renewable Power Gen

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Although distributed secondary control helps control microgrids, it can provide insufficient performance in some cases where the system includes both renewable energy sources (RESs) and energy storage systems (ESSs). Therefore, an improved distributed secondary control structure is proposed in this study to improve efficiency and reliability in island mode DC microgrids that include RESs and ESSs. In order to regulate the power flow in accordance with the real time generation of the sources, maximum power calculation algorithms have been created within the secondary control levels of the PV and wind controllers. Furthermore, a fuzzy logic‐based energy management system has been designed in the secondary control of the battery controller to manage the power flow of the whole system considering the battery charge states and the total power generated by RESs. The distributed secondary control operates in event‐triggered mode to reduce the communication burdens. To avoid zeno behavior, event‐triggered control is designed based on sampled data. The proposed control scheme has been tested in Simulink environment and its stability is verified using Lyapunov's stability criteria. Results show that the power demand is successfully provided proportionally among the RESs and the communication burden is reduced considerably.

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Section: Design Of Island Mode DC Microgridmentioning

confidence: 99%

\begin{equation}\delta {v}_i = \delta {v}_{V,i} + \delta {v}_{I,i},\end{equation}

where 𝛿𝑣 𝑉 ,i is the voltage regulation term and 𝛿𝑣 I,i is the current regulation term at node i .…”

Section: Design Of Island Mode DC Microgridmentioning

confidence: 99%

Event‐triggered distributed secondary control for enhancing efficiency, reliability and communication in island mode DC microgrids

Irmak,

Kabalcı,

Calpbinici

2023

IET Renewable Power Gen

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“…Some nonlinear control algorithms have been applied to the qZSI system, including neural network control, fuzzy control, and sliding mode control of the BHO and PSO methods to adjust PI-MR controller parameters. Compared to conventional linear control algorithms to reduce the system's harmonic perturbations [20][21][22][23][24]. In actual control, each controller is independent of each other, and the number of states and constraints need to be dynamically calculated as the working conditions change.…”

Section: Introductionmentioning

confidence: 99%

Variable weight coefficient MPC control strategy for qZSI‐VSG wind power grid‐connected system

Zhang

Liu

Luo³

et al. 2023

IET Renewable Power Gen

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Quasi‐Z source inverters (qZSI) can overcome the disadvantages of conventional wind power systems, because of achieving the balanced DC‐link voltage by using its boost ability. The majority of currently used control methods for conventional inverters are susceptible to parameter changes, and the qZSI are controlled by finite switching sequence model predictive control (FSS‐MPC). In this paper, a Variable weight coefficient Model Predictive Control (V‐MPC) strategy is proposed. First, based on the optimal scheduling algorithm, according to the priority of the controlled object. The proportioning weights of the global feasible solution and the local optimal solution in the algorithm are coordinated. Then, using the equality‐constraints quadratic programming method, according to the relationship between the system frequency and the reference value, increase the weight of the qZSI algorithm or increase the proportion of VSG control to improve the ability to suppress frequency fluctuations. It can give full play to the short‐term power support role of the virtual synchronous wind turbine. The modeling and testing findings validate the suggested control strategy. When compared to the conventional finite control set model predictive control (FCS‐MPC), the V‐MPC can minimize the big store inductance current ripple and have lower THD in the load currents waveform.

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“…Using the proposed design, UPQC gained active and reactive power injection capabilities in addition to its well-known benefit. Experiments were carried out in various circumstances to validate the efficacy of the suggested strategy in increasing power quality metrics [19], [20]. In series circuit is controlled by DVR, and the voltage varies in response to load variations, which are assessed using the suggested rational energy transformative optimization algorithm [21].…”

Section: Introductionmentioning

confidence: 99%

Unified power quality control based microgrid for power quality enhancement using various controlling techniques

Madhavan¹,

Nalini

2022

IJEECS

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This research analyses the introduction of unified power quality control (UPQC) to mitigate the power quality problems, which is caused by using power electronics devices. In this article, the challenges in power quality, the suggested UPQC control approaches that are made by the distributed generation of dynamic voltage restorer (DVR) and static synchronous compensator (STATCOM) with the DC-link. The DVR is a series active power filter (APF) compensator and the STATCOM is a shunt APF compensator. In the meanwhile, DVR compensates voltage related issuesas well as STATCOM provides the needed reactive power supply by load and reducing the current issues associated with the unity power factor. The main objectives of the UPQC to mitigate voltage imbalance, harmonics, negative-sequence current and reactive power. To overcome the PQ issues the multifunction power conditioner is implemented. In addition, several proposed control approaches were employed and compared with series and shunt APFs. In MATLAB/Simulink software is used to illuminate the performance of the control strategies. Finally, the simulation will be evaluated and PQ problems in UPQC will be reduced by various techniques such as unit vector template generation technique (UVTGT), power balancing theory (BPT), proportional integral (PI) control technique and hysteresis control technique.

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Enhancement of power quality issues for a hybrid AC/DC microgrid based on optimization methods

Cited by 21 publications

References 38 publications

Event‐triggered distributed secondary control for enhancing efficiency, reliability and communication in island mode DC microgrids

Event‐triggered distributed secondary control for enhancing efficiency, reliability and communication in island mode DC microgrids

Variable weight coefficient MPC control strategy for qZSI‐VSG wind power grid‐connected system

Unified power quality control based microgrid for power quality enhancement using various controlling techniques

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