M. ZORIG Abdelmalik

MCA

Directory of teachers

Department

Departement of ELECTRONICS

Research Interests

ELectronique de puissance et ses applications

Contact Info

University of M'Sila, Algeria

Email : abdelmalik.zorig@univ-msila.dz

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Recent Publications

2024-05-24

Circulating currents control method for paralleled three-level NPC inverters

Parallel multilevel inverter becoming a very attractive structure for medium- and high-power/voltage applications. This is mainly due to the fact that it can achieve high-power level and overcome voltage /current limitations of switching devices. However due to the differences in hardware parameters, the circulating current appears in this structure and degrades its performance. This paper presents a circulating current control method for paralleled three-level neutral point clamped (NPC) inverter. The analytical model that describes the circulating current generation and behaviors is demonstrated, and then using this model, a control method to eliminate the circulating current is proposed. The proposed strategy is realized by introducing a control variable adjusting the application times of the redundant vectors of the three-level space vector modulation (SVPWM). In addition, a PI-controller based on closed loop control is synthetized to determine automatically the appropriate adjustable duration, during which the redundant vectors will be applied to eliminate the circulating current among the paralleled inverter. Finally, the effectiveness of the proposed circulating current control method under different operating conditions is confirmed through experimental validation.
Citation

M. ZORIG Abdelmalik, Abdelhamid Rabhi, Mohammed Belkheiri, , (2024-05-24), "Circulating currents control method for paralleled three-level NPC inverters", [national] Electrical Engineering , Springer Nature

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2022-06-28

Neutral Point Voltage Balancing Control Based on Adjusting Application Times of Redundant Vectors for Three-level NPC inverter

Three-level neutral-point-clamped (NPC) inverter is used in many industrial applications due to its attractive advantages in terms of harmonics content, achieved power level, and electromagnetic interference reduction. However, the main concern in this topology is the imbalance of the neutral point (NP) voltage in the dc side of the inverter. Indeed, the NP voltage distorts the output voltage of the inverter and increases voltage stress on its switching devices. In this article, a new NP voltage balancing control based on modified three-level space vector pulse width modulation (SVPWM) is proposed. The core idea of this method consists in adjusting the application times of redundant vectors in such a way that the NP voltage is kept balanced. In this method, the appropriate adjustment direction is determined by measuring only the capacitor voltages and the output currents of the inverter. The performances of the proposed method are validated and compared through various experimental tests, and the obtained results show an excellent NP voltage balancing regardless of the modulation index values
Citation

M. ZORIG Abdelmalik, (2022-06-28), "Neutral Point Voltage Balancing Control Based on Adjusting Application Times of Redundant Vectors for Three-level NPC inverter", [national] IEEE Journal of Emerging and Selected Topics in Power Electronics , IEEE

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2022

Programmation orientée objet en c++

Ce cours est ..
Citation

M. ZORIG Abdelmalik, (2022), "Programmation orientée objet en c++", [national] Université de M'sila

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Modified 3LSVPWM for Circulating Currents Control in Paralleled 3Level T-type Inverters

This paper suggested a circulating current control
strategy dedicated for paralleled multilevel t-type inverters. The
suggested circulating current control strategy consist in
integrating into the three-level space-vector pulse width
modulation a control variable allowing the adjustment of small
vectors duty cycles. The method is easy to implement for modular
design, and can effectively eliminate the circulating current even
though, the inverters have an asymmetry in hardware or control
parameters. The effectiveness of the proposed circulating current
control is validated under different operating conditions through
Processes-in-the Loop simulation (PIL) using TMS320F28335
DSP board.
Citation

M. ZORIG Abdelmalik, (2022), "Modified 3LSVPWM for Circulating Currents Control in Paralleled 3Level T-type Inverters", [international] 19th IEEE International Multi-Conference on Systems, Signals & Devices (SSD 2022 , Sétif, Algérie

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2020

Circulating Current Control for Parallel Three-Level TType Inverters

Parallel inverter is one of the most interesting topology to achieve high power level, overcame current limitation on the switching devices and also to enhance the output current waveforms. However, the circulating current results from the common connection of both AC and DC sides directly can increase the current stresses and conduction losses of the switching devices and reduces inverters efficiency. This paper provides an investment on the threelevel Space vector modulation and proposes a new strategy to eliminating the circulating current for paralleled three-level t-type inverters. Results obtained confirmed the performance and the effectiveness of the proposed circulating current control strategy.
Citation

M. ZORIG Abdelmalik, (2020), "Circulating Current Control for Parallel Three-Level TType Inverters", [international] 2nd International Conference on Electronic Engineering and Renewable Energy ( ICEERE'20) , Saidia, Moroco

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2019

Neutral Point Voltage Balancing Control and Quality power Improvement of PV System Based on Dual Three-level Stage Conversion

This paper presents an overall control approach for a grid connected photovoltaic (PV) system based on three-level DC-DC boost converter (3LBC) on the front of a three-level t-type inverter (3LT 2 I) acting as active power filter. The neutral-point (NP) voltage balancing is ensured by a new control strategy applied for 3LBC; this avoids the need to change the conventional three-level space vector modulation (SVPWM) algorithm or to add additional components. The capability of the proposed system to control the current injected into the grid, compensate the harmonics and the reactive power demand, and also guarantee the DC-link capacitors voltages balancing is demonstrated through variety of simulations.
Citation

M. ZORIG Abdelmalik, (2019), "Neutral Point Voltage Balancing Control and Quality power Improvement of PV System Based on Dual Three-level Stage Conversion", [international] 6th International Conference on Control Engineering & Information Technology (CEIT) , Istanbul, Turkey

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2018

Sliding Mode Control and Modified SVM for Suppressing Circulating Currents in Parallel-Connected Inverters

Parallel operation of multi-inverters is an effective way to increase the power capacity and the reliability of power electronic systems. However, in parallel inverter operation, one of the most crucial problems is the zero-sequence circulating current (ZSCC). The ZSCC flows between parallel inverters, which results in current distortion, harmonic loss, unbalanced load sharing, and a decline in the overall system performance. In this paper, a sliding mode ZSCC controller for paralleled three-phase inverters is proposed. The suggested controller takes advantage of zero-vector redundancies to adjust their dwell time and cancel any voltage difference that can generate ZSCC between the paralleled inverters. The appropriate adjustment quantity is determined using a sliding mode controller, and as a result, a better ZSCC cancelation can be achieved at different operation conditions. Experimental results of two parallel inverters show the feasibility of the proposed ZSCC elimination method.
Citation

M. ZORIG Abdelmalik, Mohammed Belkheiri, Abdelhamid Rabhi, Frede Blaabjerg, , (2018), "Sliding Mode Control and Modified SVM for Suppressing Circulating Currents in Parallel-Connected Inverters", [international] Electric Power Components and Systems , Taylor and Francis Online

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2017

Novel Differential Current Control Strategy Based on a Modified Three-Level SVPWM for Two Parallel-Connected Inverters

Recently, parallel inverters have been investigated to provide multilevel characteristics besides their advantage to increase the power system capacity, reliability, and efficiency. However, the issue of differential currents imbalance remains a challenge in parallel inverter operation. The distribution of switching vectors of the resulting multilevel topology has a certain degree of self-differential current balancing properties. Nevertheless, the method alone is not sufficient to maintain balanced differential current in practical applications. This paper proposes a closed-loop differential current control method by introducing a control variable adjusting the dwell time of the selected switching vectors and thus maintaining the differential currents balanced without affecting the overall system performance. The control strategy, including distribution of switching sequence, selection of adjusted switching vectors, and calculation of adjusting times are described and analyzed in detail in this paper. Finally, experimental results confirm the performance and effectiveness of the proposed method.
Citation

M. ZORIG Abdelmalik, (2017), "Novel Differential Current Control Strategy Based on a Modified Three-Level SVPWM for Two Parallel-Connected Inverters", [international] IEEE Journal of Emerging and Selected Topics in Power Electronics , IEEE

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2016

Control of grid connected photovoltaic system using three-level t-type Inverter

Three-level T-Type inverter (3LT2I) topology has
numerous advantageous compared to three-level neutral-pointclamped (NPC) inverter. The main benefits of 3LT2I inverter are
the efficiency, inverter cost, switching losses, and the quality of
output voltage waveforms. In this paper, a photovoltaic
distributed generation system based on dual-stage topology of
DC-DC boost converter and 3LT2I is introduced. To that end, a
decoupling control strategy of 3LT2I is proposed to control the
current injected into the grid, reactive power compensation, and
DC-link voltage. The resulting system is able to extract the
maximum power from photovoltaic generator, to achieve
sinusoidal grid currents, and to ensure reactive power
compensation. The voltage-balancing control of two split DC
capacitors of the 3LT2I is achieved using three-level space vector
modulation with balancing strategy based on the effective use of
the redundant switching states of the inverter voltage vectors.
The proposed system performance is investigated at different
operating conditions.
Citation

M. ZORIG Abdelmalik, Mohammed Belkheiri, Abdelhamid Rabhi, , (2016), "Control of grid connected photovoltaic system using three-level t-type Inverter", [international] 4th International conference on renewable energy: generation and applications , Belfort, France

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Control of three-level T-type inverter based grid connected PV system

Multilevel inverters topology is an effective way to improve the capacity of full power converter in distributed generation system. However, the major concern for multilevel inverters is the fluctuation in the neutral-point (NP) voltage. This paper focuses on overall control including NP voltage balancing of a photovoltaic (PV) distributed generation system based on dual-stage conversion of three level DC-DC boost converter (3LBC) and three-level T-type inverter (3LT2I). The voltage-balancing control of two split DC capacitors of the 3LT2I has been transferred to the 3LBC, and thereby there is no need to change the conventional three-level space vector modulation (SVPWM) algorithm or to add additional components. Furthermore, it is simple and easy to implement and only one proportional-integral (PI) is needed to achieve good NP voltage balancing. Last, the capability of the overall system to control the current injected into the grid, reactive power compensation and keep DC-link NP voltage balance is investigated at different operating conditions.
Citation

M. ZORIG Abdelmalik, (2016), "Control of three-level T-type inverter based grid connected PV system", [international] 13th International Multi-Conference on Systems, Signals & Devices (SSD) , Leipzig, Germany

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Control of Grid Connected Photovoltaic System Using Three-Level T-Type Inverter

Three-level T-Type inverter (3LT2I) topology has numerous advantageous compared to three-level neutral-point-clamped (NPC) inverter. The main benefits of 3LT2I inverter are the efficiency, inverter cost, switching losses, and the quality of output voltage waveforms. In this paper, a photovoltaic distributed generation system based on dual-stage topology of DC-DC boost converter and 3LT2I is introduced. To that end, a decoupling control strategy of 3LT2I is proposed to control the current injected into the grid, reactive power compensation, and DC-link voltage. The resulting system is able to extract the maximum power from photovoltaic generator, to achieve sinusoidal grid currents, and to ensure reactive power compensation. The voltage-balancing control of two split DC capacitors of the 3LT2I is achieved using three-level space vector modulation with balancing strategy based on the effective use of the redundant switching states of the inverter voltage vectors. The proposed system performance is investigated at different operating conditions.
Citation

M. ZORIG Abdelmalik, Mohammed Belkeiri, Abdelhamid Rabhi, , (2016), "Control of Grid Connected Photovoltaic System Using Three-Level T-Type Inverter", [international] International Journal of Emerging Electric Power Systems , De Gruyter

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2015

Control of three-level NPC inverter based grid connected PV system

This paper presents the control of a photovoltaic distributed generation system based on dual-stage topology of DC-DC boost converter and three-level neutral-point-clamped (NPC) voltage source inverter (VSI). Decoupling control strategy of three-level VSI is proposed to control the current injected into the grid, reactive power compensation, and DC-link voltage. The resulting system is able to extract the maximum power from photovoltaic generator, to achieve sinusoidal grid currents, and to ensure reactive power compensation. The voltage-balancing control of two split DC capacitors of the three-level VSI is achieved using three-level space vector modulation with balancing strategy based on the effective use of the redundant switching states of the inverter voltage vectors. The proposed system performance is investigated at different operating conditions.
Citation

M. ZORIG Abdelmalik, Mohammed Belkheiri, , (2015), "Control of three-level NPC inverter based grid connected PV system", [international] 3rd International Conference on Control, Engineering & Information Technology (CEIT) , Tlemcen, Algeria

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Modeling and control of parallel inverters-based dualstage grid-connected PV system

Parallel operation of multi-inverters is an effective
way to increase the power capacity and the reliability of
distributed power systems. In this paper, a photovoltaic system
based on dual-stage topology of boost converter and parallel
three-phase inverters connected in distribution systems is
presented. Also, a decoupling control strategy of parallel
inverters system is proposed to control the current injected into
the grid, active and reactive power demand, and DC-link voltage.
The resulting system is able to extract the maximum power from
photovoltaic unit, to achieve sinusoidal grid currents, and to
ensure reactive power compensation. The proposed system
performance is investigated at different operating conditions.
Citation

M. ZORIG Abdelmalik, Mohammed Belkheiri, , (2015), "Modeling and control of parallel inverters-based dualstage grid-connected PV system", [international] International Electrical and Computer Engineering Conference , Setif, Algeria

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Control of grid connected photovoltaic system using dual three-level stage conversion

This paper presents the control of a photovoltaic distributed generation system based on dual-stage topology of three level DC-DC boost converter (3LBC) and three-level neutral-point-clamped (NPC) voltage source inverter (VSI). Decoupling control strategy of three-level VSI is proposed to control the current injected into the grid, reactive power compensation, and DC-link voltage. The resulting system is able to extract the maximum power from photovoltaic generator, to achieve sinusoidal grid currents, and to ensure reactive power compensation. The design and the selection of 3LBC are based not only on boosting up the photovoltaic generator (PVG) voltage but also to ensure equal balancing of the DC-link voltage capacitors. Moreover, they do not change the conventional three-level space vector modulation witch required heavy computational capability to implement the neutral point balance control algorithm. The proposed system performance is investigated at different operating conditions.
Citation

M. ZORIG Abdelmalik, (2015), "Control of grid connected photovoltaic system using dual three-level stage conversion", [international] 4th International Conference on Electrical Engineering (ICEE) , Boumerdes, Algeria

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2013

Sliding Mode Control of Interleaved DC-DC Boost Converter Integrated in PV system

Interleaving techniques are widely used to reduce input/output ripples, to increase the efficiency and to
increase the power capacity of the boost converters. This paper deals with the problem of
controlling energy generation systems including photovoltaic generator (PVG) and three phases
interleaved boost converter (IBC). The objective is to design controllers that are able to achieve (i)
input voltage tracking and robustness with respect to uncertainties that arise due to climate changes (ii)
and balanced current sharing between the used converters.
First a linear controller based on PI controller is proposed, and the behavior of IBC is compared with
conventional boost converter (CBC). Next a sliding mode controller (SMC) for three phases
interleaved boost converter is studied and compared to the conventional PI in terms of transient
response, current and voltage overshoot percentage, and input current ripple. Furthermore, the
robustness of the controllers is verified against variation for solar irradiation.
Citation

M. ZORIG Abdelmalik, Mohammed Belkheiri, , (2013), "Sliding Mode Control of Interleaved DC-DC Boost Converter Integrated in PV system", [international] 1st First International Conference on Power Electronics and their Applications, pp. 1–10, Djelfa, Algeria, Nov. 06–07, 2013 , Djelfa, Algeria

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