Resumen
Los generadores de Ozono son dispositivos que operan por descarga Corona, ionizan el aire hasta disociar el Oxígeno neutro (O2), formando radicales de Oxígeno (O-) recombinándose con O2 formando Ozono (O3). Los generadores de Ozono comerciales presentan dos problemas principalmente: a) funcionan en periodos cortos de tiempo por consumir elevadas corrientes y b) no controlan la producción del O3. Este trabajo se enfoca en controlar la corriente consumida por un generador comercial empleado un Arduino. Se simuló, diseñó y realizó un circuito Buck optoaislado capaz de transmitir una señal de retroalimentación PWM (Pulse-Width Modulation). El control utilizado es ON/OFF (encendido-apagado), se programamó y ejecutó desde MATLAB. Se implementó un filtro EMA (Exponential Moving Average) debido a la no linealidad de la corriente del generador, ya que las señales del sensor presentaron ruido en el sensor. El control ON/OFF fue capaz de mantener a momentos la corriente alrededor del límite deseado.
Palabras Claves: Arduino, Circuito reductor Buck, Control ON/OFF, Generador de Ozono, MATLAB

Abstract
Ozone generators are devices that operate by Corona discharge effect, that is, they ionize the air until causing the dissociation of neutral Oxygen (O2), forming Oxygen radicals (O-) that recombine with another neutral molecule to form the Ozone (O3). Commercial ozone generators have two main problems: a) they work for short periods of time due to high current discharge and b) they do not allow O3 production to be controlled. This work focuses essentially on the control of current consumed by a commercial generator, for which an Arduino microcontroller has been used. An opto-coupled Buck circuit capable of transmitting a PWM (Pulse-Width Modulation) feedback signal was simulated, designed and realized. The control presented is of the ON/OFF type (on-off) and its programming was carried out and executed from the MATLAB software. An EMA (Exponential Moving Average) filter was implemented due to the non-linearity of the current in the generator, since it presented signals with noise in the sensor. The ON/OFF control was able to keep the current around the desired limit at times.
Keywords: Arduino, Buck Converter, MATLAB, ON/OFF Control, Ozone Generator.

Bertol Charise D; Vieira Karoline Pissolatto; Rossato Luciana Grazziotin; D’Avila, J. V. (2012). Microbiological environmental monitoring after the use of air purifier ozone generator. Ozone Science Engineering Vol. 34

Kogelchatz U and Elliason (1995), Ozone Generation and Applications, Handbook of Electrostatic Processes Edited by J-S Chang et al. CRC Press Cap 26, p 581.

Chalmers I D; Baird R C; Kelly, T. (1998). Control of an ozone generator - theory and practice. Measurement Science and Technology.

Cortés, J. d. J. G., Mendoza, J. M. O., Orendain, G. C., Cuevas, J. J., y Pérez, S. S. (2020). Sistema inalámbrico con arduino para medicion y registro de temperatura en un invernadero (wireless system with arduino for measuring and recording temperature in a greenhouse). Pistas Educativas, 42 (137).

Dyas A; Boughton B J; Das, B. C. (1983). Ozone killing action against bacterial and fungal species; microbiological testing of a domestic ozone generator. Journal of Clinical Pathology.

Eau des Paris. Produire l’eau. Consultado mayo 2022, de http://www.eaudeparis.fr/nc/les-metiers/produire/.

García, H. A. C., Montañez, F. G., González, J. J., Carmona, G. R. T., Hernandez Ávila, J. L. H., y Littlewood, E. C. (2018). Control en lazo abierto de un sistema de levitación magnética mediante un inversor y una tarjeta arduino. Pistas Educativas, 38 (120).

Hart, D. W. (2001). Electrónica de potencia. Pearson Educación. Cap 6, p 211-212.

Hothongkham P.; Kinnares, V. (2009). Analysis and modelling of an ozone generator using a phase-shift PWM full bridge inverter.

Kinnares V; Hothongkham, P. (2010). Circuit analysis and modeling of a phase-shifted pulsewidth modulation full-bridge-inverter-fed ozone generator with constant applied electrode voltage. IEEE Transactions on Power Electronics.

Mendoza, R. A. A., Ramos, D. C. R., y Guerrero, M. L. (2022). Diseño y pruebas por simulación de un convertidor reductor para apoyar la experimentación en electrónica. Pistas Educativas, 43 (141).

Takaki K.; Yagi I.; Fujiwara T.; Go, T. (2011). Influence of circuit parameter on ozone synthesis using inductive energy storage system pulsed power generator. IEEE Transactions on Dielectrics and Electrical Insulation.

Vergura, S. (2020). Bollinger bands based on exponential moving average for statistical monitoring of multi-array photovoltaic systems. Energies.

Xu Huan; Ding Feng; Yang, E. (2020). Three-stage multi-innovation parameter estimation for an exponential autoregressive time-series model with moving average noise by using the data filtering technique. International Journal of Robust and Nonlinear Control.