Optimum Sizing and Placement of Wind Turbines in Distribution Networks Considering Correlation of Load Demand and Wind Power

• Main Authors: T. Agheb, I. Ahmadi, A. Zakariazadeh
• Format: Article
• Language: English
• Published: Iran University of Science and Technology 2021-09-01
• Series: Iranian Journal of Electrical and Electronic Engineering
• Subjects: correlation modeling; distribution system; load demand; wind turbine allocation and sizing.
• Online Access: http://ijeee.iust.ac.ir/article-1-1916-en.html

Optimal placement and sizing of distributed renewable energy resources (DER) in distribution networks can remarkably influence voltage profile improvement, amending of congestions, increasing the reliability and emission reduction.  However, there is a challenge with renewable resources due to the intermittent nature of their output power. This paper presents a new viewpoint at the uncertainties associated with output powers of wind turbines and load demands by considering the correlation between them. In the proposed method, considering the simultaneous occurrence of real load demands and wind generation data, they are clustered by use of the k-means method. At first, the wind generation data are clustered in some levels, and then the associated load data of each generation level are clustered in several levels. The number of load levels in each generation level may differ from each other. By doing so the unrealistic generation-load scenarios are omitted from the process of wind turbine sizing and placement. Then, the optimum sizing and placement of distributed generation units aiming at loss reduction are carried out using the obtained generation-load scenarios. Integer-based Particle Swarm Optimization (IPSO) is used to solve the problem. The simulation result, which is carried out using MATLAB 2016 software, shows that the proposed approach causes to reduce annual energy losses more than the one in other methods. Moreover, the computational burden of the problem is decreased due to ignore some unrealistic scenarios of wind and load combinations.