Your search keyword '"Villa-Acevedo, Walter"' showing total 4 results

1. External Multi-Gap Lightning Arrester Modeling Using the Integration Method.

Author

Rodríguez-Serna, Johnatan M., Villa-Acevedo, Walter M., and López-Lezama, Jesús M.

Subjects

*POWER distribution networks, *LIGHTNING, *ELECTRIC utilities, *GENETIC algorithms

Abstract

Electric power distribution networks are exposed to both internal and external disturbances. Lightning strikes are among the latter and are responsible for a significant percentage of damage in distribution transformers, especially in rural areas. Electric utilities must pay special attention to prevent damage and service interruption due to these unforeseeable events. In this context, Surge Protection Devices (SPDs) combined with a series of external air gaps are designed to safeguard electric equipment and systems from transient over-voltages. There are several well-known models of SPDs in the specialized literature; nonetheless, few studies have been carried out with external gaps and multi-gaps. The main contribution of this paper is a methodology to model the disruptive effect in an external air gap by determining the parameters of Kind's and Chowdhuri's models using the integration method. The adjustment of the model parameters is carried out by a genetic algorithm (GA). The proposed model was tested and validated using experimental measurements, and its capability to predict the time-to-breakdown under different impulse voltages was verified. [ABSTRACT FROM AUTHOR]

Published

2024

2. Microgrid Protection Coordination Considering Clustering and Metaheuristic Optimization.

Author

Santos-Ramos, Javier E., Saldarriaga-Zuluaga, Sergio D., López-Lezama, Jesús M., Muñoz-Galeano, Nicolás, and Villa-Acevedo, Walter M.

Subjects

METAHEURISTIC algorithms, MICROGRIDS, PARTICLE swarm optimization, GENETIC algorithms, HIERARCHICAL clustering (Cluster analysis), K-means clustering

Abstract

This paper addresses the protection coordination problem of microgrids combining unsupervised learning techniques, metaheuristic optimization and non-standard characteristics of directional over-current relays (DOCRs). Microgrids may operate under different topologies or operative scenarios. In this case, clustering techniques such as K-means, balanced iterative reducing and clustering using hierarchies (BIRCH), Gaussian mixture, and hierarchical clustering were implemented to classify the operational scenarios of the microgrid. Such scenarios were previously defined according to the type of generation in operation and the topology of the network. Then, four metaheuristic techniques, namely, Genetic Algorithm (GA), Particle Swarm Optimization (PSO), Invasive Weed Optimization (IWO), and Artificial Bee Colony (ABC) were used to solve the coordination problem of every cluster of operative scenarios. Furthermore, non-standard characteristics of DOCRs were also used. The number of clusters was limited to the maximum number of setting setting groups within commercial DOCRs. In the optimization model, each relay is evaluated based on three optimization variables, namely: time multiplier setting (TMS), the upper limit of the plug setting multiplier (PSM), and the standard characteristic curve (SCC). The effectiveness of the proposed approach is demonstrated through various tests conducted on a benchmark test microgrid. [ABSTRACT FROM AUTHOR]

Published

2024

3. Solving the Optimal Reactive Power Dispatch Problem through a Python-DIgSILENT Interface.

Author

Sánchez-Mora, Martin M., Bernal-Romero, David Lionel, Montoya, Oscar Danilo, Villa-Acevedo, Walter M., and López-Lezama, Jesús M.

Subjects

REACTIVE power, INTEGER programming, METAHEURISTIC algorithms, POWER resources, GENETIC algorithms, NONLINEAR programming, TEST systems

Abstract

The Optimal Reactive Power Dispatch (ORPD) problem consists of finding the optimal settings of reactive power resources within a network, usually with the aim of minimizing active power losses. The ORPD is a nonlinear and nonconvex optimization problem that involves both discrete and continuous variables; the former include transformer tap positions and settings of reactor banks, while the latter include voltage magnitude settings in generation buses. In this paper, the ORPD problem is modeled as a mixed integer nonlinear programming problem and solved through two different metaheuristic techniques, namely the Mean Variance Mapping Optimization and the genetic algorithm. As a novelty, the solution of the ORPD problem is implemented through a Python-DIgSILENT interface that combines the strengths of both software. Several tests were performed on the IEEE 6-, 14-, and 39-bus test systems evidencing the applicability of the proposed approach. The results were contrasted with those previously reported in the specialized literature, matching, and in some cases improving, the reported solutions with lower computational times. [ABSTRACT FROM AUTHOR]

Published

2022

4. A Novel Constraint Handling Approach for the Optimal Reactive Power Dispatch Problem.

Author

Villa-Acevedo, Walter M., López-Lezama, Jesús M., and Valencia-Velásquez, Jaime A.

Subjects

*REACTIVE power, *GENETIC algorithms, *FEASIBILITY studies, *METAHEURISTIC algorithms, *COMPUTER simulation

Abstract

This paper presents an alternative constraint handling approach within a specialized genetic algorithm (SGA) for the optimal reactive power dispatch (ORPD) problem. The ORPD is formulated as a nonlinear single-objective optimization problem aiming at minimizing power losses while keeping network constraints. The proposed constraint handling approach is based on a product of sub-functions that represents permissible limits on system variables and that includes a specific goal on power loss reduction. The main advantage of this approach is the fact that it allows a straightforward verification of both feasibility and optimality. The SGA is examined and tested with the recommended constraint handling approach and the traditional penalization of deviations from feasible solutions. Several tests are run in the IEEE 30, 57, 118 and 300 bus test power systems. The results obtained with the proposed approach are compared to those offered by other metaheuristic techniques reported in the specialized literature. Simulation results indicate that the proposed genetic algorithm with the alternative constraint handling approach yields superior solutions when compared to other recently reported techniques. [ABSTRACT FROM AUTHOR]

Published

2018