Implementación de un sistema de transmisión inalámbrica de energía eléctrica a través de acoplamiento resonante magnético de campo cercano para dispositivos de bajo consumo de potencia

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Jaime Rodrigo Vinueza Coba
Monica Alexandra Mayorga Arias
Monica Andrea Zabala Haro
Fabricio Javier Santacruz Sulca
Jefferson Alexander Ribadeneira Ramirez

Resumen

La presente investigación, expone un método alternativo de alimentación eléctrica a través del uso de resonancia magnética. Se utilizaron métodos matemáticos probados en anteriores aportes investigativos para el diseño de las antenas encargadas de la transmisión inalámbrica de energía con tecnología microstrip, sobre una placa FR4, además, se hace uso de circuitos integrados con tecnología MMIC para la generación y amplificación de ondas de radio – frecuencia en el rango de los 16 MHz a 23 MHz como fuente de energía. En la fase de recepción se utiliza un circuito doblador de voltaje de 3 etapas con el propósito de rectificar y amplificar la señal recibida. Los resultados obtenidos en la implementación del sistema, demuestran una recepción de la energía recibida entre el 20% y 30% del total transmitido, para distancias comprendidas entre 10 y 90 milímetros. entre las antenas sin obstáculos. Ésta investigación indica que es factible utilizar energía inalámbrica para cargar dispositivos de bajo consumo de potencia, comprobando que, con obstáculos, decae ínfimamente la eficiencia del sistema al atravesar materiales como aglomerado, plástico, vidrio, poli estireno expandido, tela y madera, perdiendo totalmente el rendimiento con metal.

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Implementación de un sistema de transmisión inalámbrica de energía eléctrica a través de acoplamiento resonante magnético de campo cercano para dispositivos de bajo consumo de potencia. (2018). MASKAY, 8(1), 35-45. https://doi.org/10.24133/maskay.v8i1.598
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Cómo citar

Implementación de un sistema de transmisión inalámbrica de energía eléctrica a través de acoplamiento resonante magnético de campo cercano para dispositivos de bajo consumo de potencia. (2018). MASKAY, 8(1), 35-45. https://doi.org/10.24133/maskay.v8i1.598

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