Modeling of a variable Speed control system of the Industrial drive chain of Carrigres-Kinshasa by Pulse Width Modulation

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Modeling of a variable Speed control system of the Industrial drive chain of Carrigres-Kinshasa by Pulse Width Modulation

Author Affiliations

¹Laboratory of Electrical Engineering and Electronic, Polytechnic Superior National School, Marien Ngouabi University, Brazzaville, Congo
²Laboratory of Electrical Engineering, ISTA-Kinshasa, Democratic Republic of the Congo
³Laboratory of Electrical Engineering, ISTA-Kinshasa, Democratic Republic of the Congo
⁴Faculty of Sciences and Techniques, Marien Ngouabi University, Brazzaville, Congo

Res. J. Engineering Sci., Volume 15, Issue (2), Pages 16-20, May,26 (2026)

Abstract

In this article, we will study static converters, their operation, and the behavior of the voltages and currents that are necessary. Once the modeling of the asynchronous machine is completed, and the control of the asynchronous drive has been studied, namely pulse width modulation, the effectiveness of the adopted technique can only be confirmed after supplying the machine with the voltages delivered by the inverter, and this for two tests, no-load and load.

References

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[ref1] Al-Jumaili, A. M., Saad, A., & Kadhim, M. G. (2025)., A Resonant-PWM Hybrid DC-AC Converter with GaN Technology for Enhanced Efficiency and Low THD in Energy Storage Systems., Mathematical Modelling of Engineering Problems, 12(9).
Google Scholar

[ref2] Adesunloro, G. M., Oluyemi, F. O., & Olumodeji, I. A. (2025)., Design and Implementation of a Microcontroller-Based Solar Inverter for Efficient DC–AC Conversion., Tech-Sphere Journal for Pure and Applied Sciences, 2(1).
Google Scholar

[ref3] Y. Zhang, H. Li, and X. Chen (2024)., High-Efficiency Multilevel Inverter for Renewable Energy Systems with Optimized PWM Control., IEEE Trans. Power Electronics.

[ref4] R. Kumar and P. Singh (2023)., Performance Analysis of Sinusoidal PWM Inverters for Electric Vehicle Applications., J. Electrical Engineering & Technology.

[ref5] Oveissi, M. (1983)., Comparative study of voltage source and current source inverter fed induction motor drive., Doctoral dissertation, Concordia University.
Google Scholar

[ref6] D. Lee and S. Park (2025)., Next-GenerationInverter Topologies for Photovoltaic Systems., Solar Energy Journal.

[ref7] R. Oliveira and M. Costa (2024)., PWM Techniques for Harmonic Reduction in DC-AC Converters., J. Modern Power Systems and Clean Energy.

[ref8] N. Singh and V. Sharma (2023)., Resilient Inverter Designs for Microgrid Stability., Int. J. Renewable Energy Research.

[ref9] Suresh, K., Parimalasundar, E., Kumar, B. H., Singh, A. R., Bajaj, M., & Tuka, M. B. (2024)., Design and implementation of a universal converter for microgrid applications using approximate dynamic programming and artificial neural networks., Scientific Reports, 14(1), 20899.
Google Scholar

[ref10] M. Hernandez and J. Torres (2024)., Adaptive Control Strategies for PWM Inverters in Smart Grids,, Int. J. Power Electronics and Drive Systems.

[ref11] J. Wang and L. Zhao (2023)., GaN-Based DC-AC Converters: Advances in Switching Loss Reduction, Renewable Energy Journal., undefined

[ref12] Q. Chen and Y. Liu (2025)., Digital Control of Inverters Using AI-Based PWM Modulation., IEEE Access.