PI and Fuzzy Logic Controller Based Analysis of Load Frequency Control for Thermal-nuclear Hybrid Energy Systems

[{“box”:0,”content”:”[if 992 equals=”Open Access”]

n

Open Access

n

[/if 992]n

n

Year : March 15, 2024 | Volume : 14 | [if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] : 01 | Page : 1-9

n

n

n

n

n

n

By

n

    n t

    [foreach 286]n

    n

    Yatinkumar Rajendrabhai Daraji, Kalpana Meena

  1. [/foreach]

    n

n

n[if 2099 not_equal=”Yes”]n

    [foreach 286] [if 1175 not_equal=””]n t

  1. Student, Assistant Professor, Department of Electrical Engineering, Rajasthan Institute of Engineering and Technology, Jaipur,, Department of Electrical Engineering, Rajasthan Institute of Engineering and Technology, Jaipur,, Rajasthan, Rajasthan, India, India

    2. n[/if 1175][/foreach]

[/if 2099][if 2099 equals=”Yes”][/if 2099]nn

n

Abstract

nIn this paper a two-area system: area-1, which has a thermal power plant, and area-2, which contains a nuclear power plant. By combining these domains, two area thermal-nuclear systems are developed in the MATLAB Simulink framework. To ensure the quality of power generated and to feed the load, generation should be raised in tandem with the growth in load demand, or the network should be connected. Using various controllers, LFC is utilized to stabilize the power system’s factors. We are comparing the undershoot and settling time values for each scenario utilizing PI and fuzzy logic control approaches separately for 1% disturbance in either area in order to examine the performance of a two-area system. The simulation’s outcome demonstrates that the fuzzy logic controller solves the LFC problem effectively.

n

n

n

Keywords: Fuzzy Logic Controller, PI-Controller, Load Frequency Control (LFC), Thermal-Nuclear Hybrid Energy System

n[if 424 equals=”Regular Issue”][This article belongs to Trends in Electrical Engineering(tee)]

n

[/if 424][if 424 equals=”Special Issue”][This article belongs to Special Issue under section in Trends in Electrical Engineering(tee)][/if 424][if 424 equals=”Conference”]This article belongs to Conference [/if 424]

n

n

n

How to cite this article: Yatinkumar Rajendrabhai Daraji, Kalpana Meena PI and Fuzzy Logic Controller Based Analysis of Load Frequency Control for Thermal-nuclear Hybrid Energy Systems tee March 15, 2024; 14:1-9

n

How to cite this URL: Yatinkumar Rajendrabhai Daraji, Kalpana Meena PI and Fuzzy Logic Controller Based Analysis of Load Frequency Control for Thermal-nuclear Hybrid Energy Systems tee March 15, 2024 {cited March 15, 2024};14:1-9. Available from: https://journals.stmjournals.com/tee/article=March 15, 2024/view=0

nn

nn[if 992 equals=”Open Access”] Full Text PDF Download[else] nvar fieldValue = “[user_role]”;nif (fieldValue == ‘indexingbodies’) {n document.write(‘Full Text PDF‘);n }nelse if (fieldValue == ‘administrator’) { document.write(‘Full Text PDF‘); }nelse if (fieldValue == ‘tee’) { document.write(‘Full Text PDF‘); }n else { document.write(‘ ‘); }n [/if 992] [if 379 not_equal=””]n

Browse Figures

n

n

[foreach 379]n

n[/foreach]n

nn

n

n[/if 379]n

n

References

n[if 1104 equals=””]n

  1. Sharma, Deepesh, and Rajni Bala. “Load Frequency Control of Interconnected Hybrid Power System.” International Conference on Communication and Intelligent Systems. Singapore: Springer Nature Singapore, 2022.
  2. Basavarajappa, S. R., and M. S. Nagaraj. “Load frequency control of three area interconnected power system using conventional PID, fuzzy logic and ANFIS controllers.” 2021 2nd International Conference for Emerging Technology (INCET). IEEE, 2021.
  3. Latif, Abdul, et al. “State-of-the-art of controllers and soft computing techniques for regulated load frequency management of single/multi-area traditional and renewable energy based power systems.” Applied Energy 266 (2020): 114858.
  4. Haroun, AH Gomaa, and Yin-ya Li. “A novel optimized hybrid fuzzy logic intelligent PID controller for an interconnected multi-area power system with physical constraints and boiler dynamics.” ISA transactions 71 (2017): 364-379.
  5. Mishra, Mugdha, and Nitin Kumar Saxena. “Artificial Neural Network-Based Automatic Generation Control for Two-Area Nuclear-Thermal System.” Control and Measurement Applications for Smart Grid: Select Proceedings of SGESC 2021. Singapore: Springer Nature Singapore, 2022. 25-40.
  6. Chakraborty, Susmit, et al. “Design of FUZZY-3DOF-PID controller for an Ocean Thermal hybrid Automatic Generation Control system.” Scientia Iranica (2023).
  7. Bhaskar, Mukesh Kumar, Nidhi Singh Pal, and Vinod Kumar Yadav. “A comparative performance analysis of automatic generation control of multi-area power system using PID, fuzzy and ANFIS controllers.” 2018 2nd IEEE International Conference on Power Electronics, Intelligent Control and Energy Systems (ICPEICES). IEEE, 2018.
  8. Dwivedi, Anurag, and A. N. Tiwari. “Analysis of three-phase PWM rectifiers using hysteresis current control techniques: a survey.” International Journal of Power Electronics 8.4 (2017): 349-377.
  9. Gbadega, Peter Anuoluwapo, and Akshay Kumar Saha. “Dynamic Tuning of the Controller Parameters in a Two-Area Multi-Source Power System for Optimal Load Frequency Control Performance.” International Journal of Engineering Research in Africa 51 (2020): 111-129.
  10. Dong, Zhe, et al. “Review on the Recent Progress in Nuclear Plant Dynamical Modeling and Control.” Energies 16.3 (2023): 1443.
  11. Patel, Nimai Charan, et al. “SHO Algorithm Based PID Controller for Automatic Generation Control of Multiarea Multiunit Power System With Renewable Energy Source.” 2022 International Conference on Intelligent Controller and Computing for Smart Power (ICICCSP). IEEE, 2022.
  12. Dwivedi, Anurag, and A. N. Tiwari. “Three phase PWM converter using PI and fuzzy with hysteresis current controller.” International Journal of Power Electronics 10.1-2 (2019): 65-81.
  13. Cetiner, Sacit, and Pradeep Ramuhalli. Transformational challenge reactor autonomous control system framework and key enabling technologies. No. ORNL/SPR-2019/1178. Oak Ridge National Lab.(ORNL), Oak Ridge, TN (United States), 2019.

nn[/if 1104][if 1104 not_equal=””]n

    [foreach 1102]n t

  1. [if 1106 equals=””], [/if 1106][if 1106 not_equal=””],[/if 1106]

    2. n[/foreach]

n[/if 1104]

nn

nn[if 1114 equals=”Yes”]n

n[/if 1114]

n

n

Regular Issue Subscription Original Research

n

n

n

n

n

Trends in Electrical Engineering

n

[if 344 not_equal=””]ISSN: 2249-4774[/if 344]

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

n

Volume 14
[if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] 01
Received February 21, 2024
Accepted March 6, 2024
Published March 15, 2024

n

n

Views: 34

n

n

n

nn function myFunction2() {n var x = document.getElementById(“browsefigure”);n if (x.style.display === “block”) {n x.style.display = “none”;n }n else { x.style.display = “Block”; }n }n document.querySelector(“.prevBtn”).addEventListener(“click”, () => {n changeSlides(-1);n });n document.querySelector(“.nextBtn”).addEventListener(“click”, () => {n changeSlides(1);n });n var slideIndex = 1;n showSlides(slideIndex);n function changeSlides(n) {n showSlides((slideIndex += n));n }n function currentSlide(n) {n showSlides((slideIndex = n));n }n function showSlides(n) {n var i;n var slides = document.getElementsByClassName(“Slide”);n var dots = document.getElementsByClassName(“Navdot”);n if (n > slides.length) { slideIndex = 1; }n if (n (item.style.display = “none”));n Array.from(dots).forEach(n item => (item.className = item.className.replace(” selected”, “”))n );n slides[slideIndex – 1].style.display = “block”;n dots[slideIndex – 1].className += ” selected”;n }n”}]