Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability

Sunil Nangrani; Harshad Akre

Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability

Abstract

Increasing the integration of renewable energy sources into electrical power systems reduces overall inertia, leading to potential frequency instability. Effective control strategies are crucial to maintain frequency stability in hybrid industrial micro grids. This research proposes a fractional sliding mode control strategy for frequency stabilization in hybrid industrial micro grids. Explicit state-space model of a multisource hybrid industrial micro grid, includes load, energy storage systems, photovoltaic and wind farms, electric vehicles and batteries with state-of-charge control. This research investigates the effectiveness of the proposed controller based on fractional order to improve the frequency stability and micro grid performance. The proposed controller effectively damps frequency oscillations and maintains frequency stability under diverse scenarios. The controller demonstrates robustness, fast response, and reliability in managing frequency deviations.

Keywords

References

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Details

Primary Language

English

Subjects

Electrical Energy Transmission, Networks and Systems, Electrical Energy Generation (Incl. Renewables, Excl. Photovoltaics)

Journal Section

Conference Paper

Authors

Sunil Nangrani ^*
0000-0002-4433-8148
India

Harshad Akre
0009-0009-9678-4412
India

Publication Date

March 5, 2026

Submission Date

April 11, 2025

Acceptance Date

January 22, 2026

Published in Issue

Year 2026 Volume: 10 Number: Special

IZ

https://izlik.org/JA68ZL52FY

Cite

RIS / Bibtex

APA

Nangrani, S., & Akre, H. (2026). Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability. International Journal of Engineering Science and Application, 10(Special), 1-8. https://izlik.org/JA68ZL52FY

AMA

1.Nangrani S, Akre H. Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability. IJESA. 2026;10(Special):1-8. https://izlik.org/JA68ZL52FY

Chicago

Nangrani, Sunil, and Harshad Akre. 2026. “Hybrid Industrial Microgrid With Fractional Order Controller for Improved Frequency Stability”. International Journal of Engineering Science and Application 10 (Special): 1-8. https://izlik.org/JA68ZL52FY.

EndNote

Nangrani S, Akre H (March 1, 2026) Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability. International Journal of Engineering Science and Application 10 Special 1–8.

IEEE

[1]S. Nangrani and H. Akre, “Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability”, IJESA, vol. 10, no. Special, pp. 1–8, Mar. 2026, [Online]. Available: https://izlik.org/JA68ZL52FY

ISNAD

Nangrani, Sunil - Akre, Harshad. “Hybrid Industrial Microgrid With Fractional Order Controller for Improved Frequency Stability”. International Journal of Engineering Science and Application 10/Special (March 1, 2026): 1-8. https://izlik.org/JA68ZL52FY.

JAMA

1.Nangrani S, Akre H. Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability. IJESA. 2026;10:1–8.

MLA

Nangrani, Sunil, and Harshad Akre. “Hybrid Industrial Microgrid With Fractional Order Controller for Improved Frequency Stability”. International Journal of Engineering Science and Application, vol. 10, no. Special, Mar. 2026, pp. 1-8, https://izlik.org/JA68ZL52FY.

Vancouver

1.Sunil Nangrani, Harshad Akre. Hybrid Industrial Microgrid with Fractional Order Controller for Improved Frequency Stability. IJESA [Internet]. 2026 Mar. 1;10(Special):1-8. Available from: https://izlik.org/JA68ZL52FY