Overcurrent module to simulate the behavior of relays 50 and 51 in the steady state of an electrical fault

  • Alex Danilo Panchi Guamangallo Universidad Técnica de Cotopaxi
  • Xavier Alfonso Proaño Maldonado Universidad Técnica de Cotopaxi
Keywords: Inverse and Definite Time Overcurrent, Electric protections, Continuity of Electrical Service

Abstract

In Electrical Power Systems (SEP), it is very important to guarantee the continuity of the electrical service in the presence of electrical failures, as well as safeguard the integrity of the equipment that makes up a SEP. To achieve this objective, different equipment is used such as: inverse and definite time overcurrent relay. The present project focused on the construction of a prototype of a defined inverse time overcurrent relay, using mathematical models defined in the IEC 2554 and BS142 Standard, the module contains a human machine interface (HMI), which facilitates the reading of current such as operation times and the entry of variables such as Dial, TAP and curve type selection, essential parameters for calibration. The current signal is measured by a hall effect sensor, which is connected to an analog input of the Arduino card, the signal is processed so that an effective value (RMS) is obtained, representing the value measured in the secondary of a current transformer TC, consequently the prototype calculates the operation time at different Dial and Tap configurations, where the module allows a minimum response time of 9 milliseconds when it reaches the defined time configuration. Keywords: Inverse and definite time overcurrent, electrical protections, continuity of electrical service.

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References

R. Samuel, Protección de Sistemas Eléctricos, Manizales: Universidad Nacional de Colombia Manizales, 2012.

U. d. l. R. d. Uruguay, «Calculo de las corrientes de cortocircuitos,» [En línea]. Available: https://iie.fing.edu.uy/ense/asign/iiee/Documentos/Teorico/Calculo_de_las_corrientes_de_cortocircuito.pdf. [Último acceso: 25 02 2018].

D. Fermandez, Instalaciones elécticas industriales I, Cochabamba-Bolivia: Universidad Mayor de San Simon, 202.

Schneider-electric, «Cuaderno Tecnico Nº158, Cálculo de corrientes de cortocircuito,» vol. 1, nº 14, p. 38, 2000.

C. d. O. E. d. S. I. Nacional, Criterios de ajustes y coordinación de los sistemas de protección del SEIN, Quito, 2014.

A. Salvador, «Ingeniería de diseño para la utilización de los relés multifuncion de la central mazar en las central molino perteneciente a celec ep.,» vol. 1, nº 34, p. 261, 2015.

A. MicroSystems, Fully Integrated, Hall Effect-Based Linear Current Sensor IC, Massachusetts, 2017.

PanamaHitex, «PanamaHitex,» [En línea]. Available: http://panamahitek.com/el-setup-y-el-loop-en-arduino/. [Último acceso: 18 07 18].

P. C. S. V. León Miguel, Diseño y construcción de un banco de protecciones de sobrecorriente, para alimentadores de media tensión, Guayaquil: Universidad Politécnica Salesiana, 2015.

V. M. C. G. Conde Enriquez, Diseño teórico y simulación de un relevador de sobrecorriente con capacidades dinámicas de ajuste, México: SciELO, 2010.

G. Francisco, Sistemas Electricos de Potencia, giaELEC.org, 2007.

EcuaRED, «Proteccion de sobrecorriente,» Conocimieno con todos y para todos, vol. I, nº 1, p. 3, 2018.

R. Raul, «Programa digital de coordinacion de protecciones de sobrecorriente,» Escuela Politecnica Nacional, vol. 1, nº 15, p. 125, 1981.

A. Martha, «Coordinacion de reles de sobrecorriente en sistemas de distibucion con penetracion de generacion distribuida,» vol. 1, nº 27, p. 57, 2015.

M. G. Zapata Carlos, «Coordinacion de reles de sobrecorriente en sistemas radiales utilizando programacion lineal,» Universidad Tecnologica de Pereira, vol. I, nº 1, p. 6, 2003.

Published
2021-09-13
How to Cite
Panchi GuamangalloA. D., & Proaño MaldonadoX. A. (2021). Overcurrent module to simulate the behavior of relays 50 and 51 in the steady state of an electrical fault. Ciencias De La Ingeniería Y Aplicadas, 4(2), 30-39. Retrieved from http://190.15.139.149/index.php/ciya/article/view/356
Issue
Vol. 4 No. 2 (2020)
Section
Artículo de investigación

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