Abstract
The scientific community is active in developing new models and methods to help reach the ambitious target set by UN SDGs7: universal access to electricity by 2030. Efficient planning of distribution networks is a complex and multivariate task, which is usually split into multiple subproblems to reduce the number of variables. The present work addresses the problem of optimal secondary substation siting, by means of different clustering techniques. In contrast with the majority of approaches found in the literature, which are devoted to the planning of MV grids in already electrified urban areas, this work focuses on greenfield planning in rural areas. K-means algorithm, hierarchical agglomerative clustering, and a method based on optimal weighted tree partitioning are adapted to the problem and run on two real case studies, with different population densities. The algorithms are compared in terms of different indicators useful to assess the feasibility of the solutions found. The algorithms have proven to be effective in addressing some of the crucial aspects of substations siting and to constitute relevant improvements to the classic K-means approach found in the literature. However, it is found that it is very challenging to conjugate an acceptable geographical span of the area served by a single substation with a substation power high enough to justify the installation when the load density is very low. In other words, well known standards adopted in industrialized countries do not fit with developing countries’ requirements.
Highlights
In 2019, 770 million people in the world lacked access to electricity
The cluster radius is computed as the maximum distance between each of the cluster points and the centroid. This is a proxy for the maximum length of low voltage feeders, that should be limited in order to avoid high voltage drops
The LUKESbased algorithm is the only one that provides a first design of the low voltage grid, making it possible to better estimate low voltage feeders’ length while the others only estimate the influence area of each transformer
Summary
In 2019, 770 million people in the world lacked access to electricity. Approximately 75% of them are found in Sub-Saharan Africa alone, where access to electricity rate in rural areas is only 30% [1,2]. In a global framework where the goal of the 7th SDG is to ensure access to affordable, reliable, sustainable and modern energy for all, rural electrification planning is needed. Distribution network planning is composed of several steps such as location of feeders, location of substations, allocation of loads, and transformer sizing [4,5,6]. This work focuses on the problem of distribution substations siting, and is inserted in a wider project, called Gisele (Geographic Information Systems for electrification) [7], for the development of a tool for optimal rural electrification planning. Distribution feeders and substations should respect geographical and technical constraints, i.e., voltage drops and loading of the conductors, while connecting costumers with adequate value of security and reliability
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