Karafan Journal

Karafan Journal

Improvement of the Energy Hub System Performance by Considering the Consumer Welfare Index under Adverse Weather Conditions

Document Type : Original Article

Authors
Ali Khodadadi 1
Taher Abedinzadeh 2
Hasan Alipour 2
Jaber Pouladi 2
1 PhD Student, Department of Electrical Engineering, Shabestar Branch, Islamic Azad University, Shabestar, Iran.
2 Assistant Professor, Department of Electrical Engineering, Shabestar Branch, Islamic Azad University, Shabestar, Iran.
10.48301/kssa.2023.368503.2331
Abstract
Economical and resilient operation of energy systems has always been one of the important and main priorities of the energy systems operators. However, with the progress made in various fields of energy systems, especially power systems, the discussion of resilience and reduction of energy not supplied has become more important. In other words, in addition to the supply of energy consumers, the issue of energy welfare is raised which is a function of the energy not supplied index. And according to that, the consumer expects the energy receives with maximum possible power quality and minimum outage. Therefore, in this paper a bi-objective optimization model is proposed to improve the economic performance of the energy hub system and to improve the resilience of electric consumers under adverse weather conditions, in which the operational cost of the hub energy is minimized and on the other hand, the consumer welfare index, which is a function of the energy not supplied index of the system, has been maximized. It is assumed that outage rate of electrical lines can be affected by weather conditions. To solve the optimization problem, the epsilon constraint method has been used and in the following, the fuzzy Max-Min method is used to select the optimal solution from among the set of solutions.
Keywords
Energy Hub System
Multi-objective Optimization
Pareto Solutions
Resiliency
Adverse Weather Conditions
Subjects
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Karafan Journal
Volume 20, Issue 1 - Serial Number 61
Technical & Engineering
Spring 2023
Pages 477-510

  • Receive Date 24 November 2022
  • Revise Date 01 March 2023
  • Accept Date 10 April 2023