Heating Device Based on Modified Microwave Oven: Improved to Measure Liquid Temperature by Using FBG Sensors

Jesus Garavito; Carlos Galvis; Ana Milena López; Arlet Patricia Franco; Francisco Barreiro; Rosa Liliana Tarazona; Claudia Milena Serpa-Imbett

doi:10.3390/photonics8040104

Photonics (Apr 2021)

Heating Device Based on Modified Microwave Oven: Improved to Measure Liquid Temperature by Using FBG Sensors

Jesus Garavito,
Carlos Galvis,
Ana Milena López,
Arlet Patricia Franco,
Francisco Barreiro,
Rosa Liliana Tarazona,
Claudia Milena Serpa-Imbett

Affiliations

Jesus Garavito: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Carlos Galvis: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Ana Milena López: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Arlet Patricia Franco: DANM/Desarrollo y Aplicación de Nuevos Materiales, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Francisco Barreiro: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Rosa Liliana Tarazona: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia
Claudia Milena Serpa-Imbett: Grupo de Investigación en Tecnologías Emergentes, Escuela de Ingenierías y Arquitectura, Universidad Pontificia Bolivariana Seccional Montería, Cra 6 no. 97 A 99, Montería 230001, Colombia

DOI: https://doi.org/10.3390/photonics8040104
Journal volume & issue: Vol. 8, no. 4
p. 104

Abstract

Read online

A prototype device based on a modified domestic microwave oven for liquid food products pasteurization is presented. This novel design has a coiling glass pipe adapted inside a microwave cavity to allow liquid continuous flow, in which several temperature optical sensors based on Fiber Bragg Grating were installed to measure, by means of contact, the circulating liquid temperature in the pipe, while the oven is on, to obtain the profile temperature as a function of time at different pipe points. The temperatures at liquid input and output were also measured with thermocouples. This device was tested to establish how well it may perform using different standardized liquids with well-known physicochemical and dielectric properties, such as water, water with dissolved sugars, water with dissolved salts, and water with dissolved sugars and salts. It could be observed that the maximum temperature reached was 90 °C for distilled water, 80 °C for water with dissolved salts, 60 °C for water with dissolved sugars and 80 °C for water with dissolved sugars and salts, showing that these data were in agreement with previous results in the literature. This type of device would be potentially useful to establish the device’s efficiency in terms of retention time, energy consumption, and volume of processed liquid, thus, broadening the use of this microwave heating technology with several types of liquid substances.

Published in Photonics

ISSN: 2304-6732 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Technology: Engineering (General). Civil engineering (General): Applied optics. Photonics
Website: http://www.mdpi.com/journal/photonics

About the journal

Abstract

Keywords