Resumen

Este trabajo estudia el gradiente de temperatura en espacios cúbicos de dimensiones pequeñas utilizando dispositivos de enfriamiento peltier. Se demuestra que el material, el volumen, potencia y temperatura exterior afecta la eficiencia de un elemento termoeléctrico.  Los materiales seleccionados en la construcción de los espacios cúbicos cuentan con baja conductividad térmica, a fin de evitar que la temperatura exterior afecte a la medición. Se tomaron periódicamente valores de temperatura en espacios cúbicos. El banco de prueba consiste en microcontrolador, disipadores de calor en lado frio y caliente y módulos peltier. Se realizó la comparación de los valores que obtienen en cada volumen. Se determina el uso de mayor cantidad de celdas peltier, optimizando el tiempo de enfriamiento y la potencia necesaria que se requiera. Según las ecuaciones que se obtienen el comportamiento del enfriamiento en espacios cúbicos es semejante, la eficiencia que se presenta en enfriamiento a espacios es reflejada en material, volumen, potencia de enfriamiento y temperatura externa.

 Palabras Claves: Peltier, Modelado, temperatura, Gradiente, Optoelectrónica.

Abstract

This paper studies the temperature gradient in cubic spaces of small dimensions using peltier cooling devices. The dependency of the material, volume, power and external temperature was studied, which it affects the efficiency of a thermoelectric element. The materials selected for the cubic spaces elaboration were chosen with low thermal conductivity, since this avoid the room temperature affecting the measurement. The internal temperature of the cubic spaces was taken at periodic    intervals to observe its behavior. The characterization was carried out using a microcontroller, heat sinks on cold and hot sides, and peltier modules. The temperature was compared between each volume used to obtain an optimization as a function of peltiers cells, in a minimal time of set point of cooling temperature and the power required. The equiation obtain in According to the equations that are obtained the behavior of movement in cubic spaces is similar, the efficiency that is presented in space limitations is reflected in material, volume, cooling power and external temperature.

Keywords: Peltier, Modeling, Temperature, Gradient, Optoelectronics.

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