researcher

Researcher

2717-9494 2717-9494

Ankara Bilim Üniversitesi

Electrical Engineering (Other)

Elektrik Mühendisliği (Diğer)

Optimization of Controller Parameter Multilevel Converter-Based STATCOM for Reactive Power Compensation

Optimization of Controller Parameter Multilevel Converter Based STATCOM for Reactive Power Compensation

https://orcid.org/0000-0003-1629-7219

Hamad

Yousıf

University of Kirkuk

07 31 2024

04 01 29 40 12 18 2023 07 17 2024

2013

Researcher

Static Synchronous Compensator (STATCOM) is a self-tuning proportional-integral (PI) controller that has been developed to handle the voltage and reactive power of Cascaded H-Bridges (CHB-STATCOM) to improve the power system. The purpose of optimizing controller parameters for a Multilevel Converter-based STATCOM (Static Synchronous Compensator) in the context of reactive power compensation is to enhance the performance and efficiency of the STATCOM system in regulating the power factor and voltage of an electrical system. This controller was introduced in this article. This research presented that the STATCOM should have the capability to operate both in the inductive and capacitive mode of operation and absorb or inject the desired amount of reactive power into the grid. The reactionary power that is received or supplied contributes to the improvement of the power system. The benefits of the self-tuning PI controller have been optimized to their full potential through the use of Accelerated Particle Swarm Optimization (APSO) strategies. The STATCOM is implemented into the electrical system, and its reaction to varying reactive and voltage levels is analyzed as part of the process of determining whether or not the optimization techniques are successful. Two controllers are now in operation at the STATCOM. The first controller is in charge of managing the DC voltage (which is employ me to produce reference signal depended on differences in phase angle), and the second controller is in charge of controlling the reactive power. Both controllers are in use at the same time. (Which is what is utilized to produce the modulation index). The output of the controller is then transferred to the phase change carrier, which is followed by pulse width modulation in a sinusoidal pattern. Because of this, the power converter switch may now function properly.

Static Synchronous Compensator (STATCOM) is a self-tuning proportional-integral (PI) controller that has been developed to handle the voltage and reactive power of Cascaded H-Bridges (CHB-STATCOM) in order to improve the power system. The purpose of optimizing controller parameters for a Multilevel Converter-based STATCOM (Static Synchronous Compensator) in the context of reactive power compensation is to enhance the performance and efficiency of the STATCOM system in regulating the power factor and voltage of an electrical system. This controller was introduced in this article. This research presented that the STATCOM should have the capability to be operate both in inductive and capacitive mode of operation and absorb or injects the desired amount of reactive power into the grid. The reactionary power that is received or supplied contributes to the improvement of the power system. The benefits of the self-tuning PI controller have been optimized to their full potential through the use of Accelerated Particle Swarm Optimization (APSO) strategies. The STATCOM is implemented into the electrical system, and its reaction to varying reactive and voltage levels is analyzed as part of the process of determining whether or not the optimization techniques are successful. Two controllers are now in operation at the STATCOM. The first controller is in charge of managing the DC voltage (which is employ me to produce reference signal depended on differences in phase angle), and the second controller is in charge of controlling the reactive power. Both controllers are in use at the same time. (Which is what is utilized to produce the modulation index). The output of the controller is then transferred to the phase change carrier, which is followed by pulse width modulation in a sinusoidal pattern. Because of this, the power converter switch may now function properly.

APSO Reactive power compensation STATCOM PI control Phase shift pulse width modulation

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[6]. Zotin, A., Hamad, Y., Simonov, K., Kurako, M., & Kents, A. (2020, June). Processing of CT lung images as a part of radiomics. In International Conference on Intelligent Decision Technologies (pp. 243-252). Singapore: Springer Singapore.

[7]. Hamad, Y., Mohammed, O. K. J., & Simonov, K. (2019, March). Evaluating of tissue germination and growth rate of ROI on implants of electron scanning microscopy images. In Proceedings of the 9th international conference on information systems and technologies (pp. 1-7).

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[20]. Safonova, A., Hamad, Y., Dmitriev, E., Georgiev, G., Trenkin, V., Georgieva, M., ... & Iliev, M. (2021). Individual tree crown delineation for the species classification and assessment of vital status of forest stands from UAV images. Drones, 5(3), 77.

[21]. Kabaev, E., Hamad, Y., Simonov, K., & Zotin, A. (2020). Visualization and Analysis of the Shoulder Joint Biomechanics in Postoperative Rehabilitation. In SibDATA (pp. 34-41).

[22]. Seno, M. E., Abed, A. A., Hamad, Y. A., Bhatt, U. M., Babu, B. R., & Bansal, S. (2022, December). Cloud Based Smart Kitchen Automation and Monitoring. In 2022 5th International Conference on Contemporary Computing and Informatics (IC3I) (pp. 1544-1550). IEEE.

[23]. Seno, M. E., Abed, A. A., Hamad, Y. A., Pundir, S., Srivastava, A. P., & Ali, S. (2022, December). Forwarding Factor Routing Protocol for Opportunistic Internet of Things Networks. In 2022 5th International Conference on Contemporary Computing and Informatics (IC3I) (pp. 988-995). IEEE.

[24]. Safonova, A., Hamad, Y., Alekhina, A., & Kaplun, D. (2022). Detection of norway spruce trees (Picea Abies) infested by bark beetle in UAV images using YOLOs architectures. IEEE Access, 10, 10384-10392.

[25]. Mustafa, M. O., & Abbas, N. M. (2021). Harmonic Suppression Compensation of Photovoltaic Generation Using Cascaded Active Power Filter. Eastern-European Journal of Enterprise Technologies, 6(8), 114.

[26]. Zainel, Q. M., Darwish, S. M., & Khorsheed, M. B. (2022). Employing quantum fruit fly optimization algorithm for solving three-dimensional chaotic equations. Mathematics, 10(21), 4147.