An optimal power flow solution for a power system integrated with renewable generation-Reference-Cited by-同舟云学术

An optimal power flow solution for a power system integrated with renewable generation

Published:2024 Issue:3 Volume:9 Page:6603-6627
ISSN:2473-6988
Container-title:AIMS Mathematics
language:
Short-container-title:MATH

Author:

Alghamdi Hisham¹,Hua Lyu-Guang²,Riaz Muhammad³,Hafeez Ghulam⁴,Ullah Safeer⁵,Zaidi Monji Mohamed⁶,Jalalah Mohammed¹

Affiliation:

1. Electrical Engineering Department, College of Engineering, Najran University, Najran 11001, Saudi Arabia; Email: hg@nu.edu.sa, jalalah@gmail.com

2. Power China Hua Dong Engineering Corporation Limited, Hangzhou 311122, China Hangzhou 311122, China; Email: lv_gh@hdec.com

3. Khyber Pakhtunkhwa Technical Education & Vocational Training Authority, Peshawar, Pakistan; Email: mriaz385@gmail.com

4. Department of Electrical Engineering, University of Engineering and Technology, Mardan 23200, Pakistan; Email: ghulamhafeez393@gmail.com

5. Department of Electrical Engineering, Quaid-e-Azam College of Engineering & Technology, Sahiwal, 57000, Pakistan; Email: safeer_iiui@yahoo.com

6. Department of Electrical Engineering-College of Engineering-King Khalid University-Abha-Saudi Arabia; Email: amzaydi@kku.edu.sa

Abstract

<abstract> <p>Integrating Green Renewable Energy Sources (GRES) as substitutes for fossil fuel-based energy sources is essential for reducing harmful emissions. The GRES are intermittent and their integration into the conventional IEEE 30 bus configuration increases the complexity and nonlinearity of the system. The Grey Wolf optimizer (GWO) has excellent exploration capability but needs exploitation capability to enhance its convergence speed. Adding particle swarm optimization (PSO) with excellent convergence capability to GWO leads to the development of a novel algorithm, namely a Grey Wolf particle swarm optimization (GWPSO) algorithm with excellent exploration and exploitation capabilities. This study utilizes the advantages of the GWPSO algorithm to solve the optimal power flow (OPF) problem for adaptive IEEE 30 bus systems, including thermal, solar photovoltaic (SP), wind turbine (WT), and small hydropower (SHP) sources. Weibull, Lognormal, and Gumbel probability density functions (PDFs) are employed to forecast the output power of WT, SP, and SHP power sources after evaluating 8000 Monte Carlo possibilities, respectively. The multi-objective green economic optimal solution consisted of 11 control variables to reduce the cost, power losses, and harmful emissions. The proposed method to address the OPF problem is validated using an adaptive IEEE bus system. The proposed GWPSO algorithm is evaluated by comparing it with PSO and GWO optimization algorithms in terms of achieving an optimal green economic solution for the adaptive IEEE 30 bus system. This evaluation is conducted within the confines of the same test system using identical system constraints and control variables. The integration of a small SHP with WT and SP sources, along with the proposed GWPSO algorithm, led to a yearly cost reduction ranging from <bold>$\$$19,368</bold> to <bold>$\$$30,081</bold>. Simulation findings endorsed that the proposed GWPSO algorithm executes fruitfully compared to alternative algorithms regarding a consistent convergence curve and robustness, proving its potential as a viable choice for achieving cost-effective solutions in power systems incorporating GRES.</p> </abstract>

Publisher

American Institute of Mathematical Sciences (AIMS)

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