Omonigho Peter Emenuvwe, Umar Ali Umar, Samaila Umaru, Ayodeji Nathaniel Oyedeji
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引用次数: 0
Abstract
Abstract This study aimed to develop and implement a fuzzy logic controlled-intelligent air purifier/humidifier. The concepts of passive purification and evaporative humidification were used to build this device, and engineering ideas and theories were used to guide the development of electrical and mechanical systems. Additionally, a fuzzy logic controller was designed, built, and integrated into the air purifier/humidifier device to help with its operation. It does this by analyzing input signals from all the sensors (dust, VOC gas, humidity, and water level) and activating the actuators (suction and blow fan). On the Arduino IDE, a C/C++ programming code was developed and uploaded onto the Arduino Uno R3 board, which houses the ATmega328P microcontroller processor. In estimating the clean air delivery rate, noise level, and moisture delivery rate, the performance of the developed air purifier/humidifier was assessed. Additionally, the electrical systems’ power consumption and the fuzzy logic controller’s ease of use were each assessed. In light of the room capacity taken into consideration, the findings obtained demonstrated that the proposed air purifier/humidifier device satisfies the minimum standard requirement of a clean air delivery rate of 140m3/hr. The outcome also revealed that the designed device’s noise level is lower than the typical threshold for an air purifier, which is less than 40 decibels. Additionally, after 68 minutes, the device raised the humidity level in a controlled area from 21% to 40%.
摘要:本课题旨在开发并实现一种模糊逻辑控制的智能空气净化器/加湿器。采用被动净化和蒸发加湿的概念构建该装置,并采用工程思想和理论指导电气和机械系统的开发。此外,还设计、构建了一个模糊逻辑控制器,并将其集成到空气净化器/加湿器设备中,以帮助其运行。它通过分析来自所有传感器(灰尘、VOC气体、湿度和水位)的输入信号并激活执行器(吸力和吹风机)来实现这一点。在Arduino IDE上,开发了C/ c++编程代码并将其上传到Arduino Uno R3板上,该板装有ATmega328P微控制器处理器。在估计清洁空气输送率、噪音水平和水分输送率时,评估了所开发的空气净化器/加湿器的性能。此外,还对电气系统的功耗和模糊控制器的易用性进行了评估。考虑到房间容量,所获得的结果表明,拟议的空气净化器/加湿器装置满足140立方米/小时洁净空气输送率的最低标准要求。结果还显示,该设计设备的噪音水平低于空气净化器的典型阈值,即低于40分贝。此外,68分钟后,该设备将受控区域的湿度水平从21%提高到40%。
期刊介绍:
The International Journal of Low-Carbon Technologies is a quarterly publication concerned with the challenge of climate change and its effects on the built environment and sustainability. The Journal publishes original, quality research papers on issues of climate change, sustainable development and the built environment related to architecture, building services engineering, civil engineering, building engineering, urban design and other disciplines. It features in-depth articles, technical notes, review papers, book reviews and special issues devoted to international conferences. The journal encourages submissions related to interdisciplinary research in the built environment. The journal is available in paper and electronic formats. All articles are peer-reviewed by leading experts in the field.