Arduino based temperature and humidity control for condensation on wettability engineered surfaces

Rohit Gupta, Chayan Das, Ankit Roy, R. Ganguly, A. Datta
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引用次数: 14

Abstract

Condensation is a ubiquitous phenomenon which depends on several factors, ranging from the degree of subcooling to the relative humidity of the condensing environment. Characterizing condensation in experimental setups, therefore, requires a proper control strategy of operating parameters. Although industrial vapor chambers are available for carrying out condensation experiments under precisely controlled environments, these setups are prohibitively expensive. Here we have developed a low-cost, prototype vapor chamber that is equipped with advanced control systems. Environmental control aspects of a Styrofoam- made condensation chamber are developed in-house for testing condensation on wettability engineered surfaces. Peltier-heat sink arrangement is used to cool the condenser surface under study and the desired relative humidity is maintained within the chamber by means of spraying deionized water with a nebuliser. In order to automate the process, an Arduino Duemilanove board is amalgamated with the setup. Temperature is controlled by an ON/OFF trigger-driven mechanical relay connected to the Arduino environment, which in turn generates an opportunely amplified signal to control the supply voltage of the Peltier element. A K-type thermocouple is interfaced to the Arduino board with the help of MAX31855K thermocouple amplifier for measuring the plate temperature. For humidity and chamber-temperature monitoring, an SHT35D sensor is used. The relative humidity of the chamber is maintained by a mechanical relay-driven spray arrangement. The time-domain plots of humidity and plate temperature response indicates that the temperature fluctuations are within 0.25°C and RH fluctuations are within 0.5% about the set-point. Transient response of the temperature and RH data are monitored by the Serial Monitor of Arduino software, which indicates that the set values of temperature and RH are obtained approximately within 0 to 1000 seconds.
基于Arduino的温度和湿度控制,用于润湿性工程表面的冷凝
冷凝是一种普遍存在的现象,它取决于几个因素,从过冷程度到冷凝环境的相对湿度。因此,表征实验装置中的冷凝需要一个适当的操作参数控制策略。虽然工业蒸汽室可用于在精确控制的环境下进行冷凝实验,但这些装置过于昂贵。在这里,我们开发了一个低成本的原型蒸汽室,配备了先进的控制系统。环境控制方面的泡沫聚苯乙烯制成的冷凝室是开发内部测试凝结在润湿性工程表面。采用珀尔梯-热沉装置冷却所研究的冷凝器表面,并通过喷雾器喷洒去离子水来保持室内所需的相对湿度。为了使该过程自动化,Arduino Duemilanove板与设置合并。温度由连接到Arduino环境的ON/OFF触发器驱动的机械继电器控制,该继电器反过来产生适当放大的信号来控制Peltier元件的供电电压。利用MAX31855K型热电偶放大器将k型热电偶连接到Arduino板上,测量板温。湿度和室内温度监测采用SHT35D传感器。腔室的相对湿度由机械继电器驱动的喷雾装置保持。湿度和板温响应的时域图表明,在设定值附近,温度波动在0.25℃以内,RH波动在0.5%以内。通过Arduino软件的Serial Monitor监测温度和RH数据的瞬态响应,表明温度和RH的设定值大约在0到1000秒内得到。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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