IMPLEMENTATION OF AN ECONOMICAL IoT-BASED LIQUID TANK CONTROL SYSTEM TO SUPPORT ONLINE PROCESS CONTROL PRACTICUM

Q3 Engineering
R. P. Anugraha, J. Juwari, Renanto Renanto, Sahara Putri Fachrudya, Yuliana Erika Daoed
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Abstract

Due to the pandemic era, many courses in higher education were conducted online to minimize the risk of disease transmission. For several engineering courses that contain practical material, an appropriate method is required to deliver practicum learning materials online to maintain the quality of these courses. Therefore, in this paper, the implementation of an economical IoT-based (Internet of Things) liquid tank control system was introduced to support the online practicum class. The tank system design has a height of 120 cm and a diameter of 50 cm. The tank features a valve, flowmeter, and an 18 LPM water pump. The control systems, consisting of Arduino Uno, an ultrasonic sensor, and a stepper motor, was run on the MATLAB Simulink application. IoT systems can be deployed using the TeamViewer app. After running the simulation, it was found that the lower setpoint change did not make significant changes in the process and produced the same curve shape as the steady state. The curves at steady state and during processing are not much different for the disturbance change. The error can be calculated using IAE and ITAE. The performances of the control system with IAE and ITAE values are 1.460 and 915.122 for setpoint change, respectively. For disturbance change, the IAE and ITAE values are 0.877 and 490.446, respectively. This system can help students better understand the industry 4.0 concept and allow them do practical work effectively from home at a low cost.
基于物联网的经济型液罐控制系统的实施,以支持在线过程控制实践
由于大流行病时代的到来,高等教育中的许多课程都在网上进行,以尽量减少疾病传播的风险。对于一些包含实践材料的工科课程,需要一种适当的方法来在线提供实践学习材料,以保持这些课程的质量。因此,本文介绍了一种基于物联网(IoT)的经济型液体罐控制系统的实施,以支持在线实践课。液罐系统设计高度为 120 厘米,直径为 50 厘米。水箱配有一个阀门、流量计和一个 18 LPM 的水泵。控制系统由 Arduino Uno、超声波传感器和步进电机组成,在 MATLAB Simulink 应用程序上运行。物联网系统可使用 TeamViewer 应用程序进行部署。运行仿真后发现,较低的设定点变化并没有使流程发生显著变化,而且产生的曲线形状与稳态相同。对于扰动变化,稳态和处理过程中的曲线没有太大区别。误差可用 IAE 和 ITAE 计算。对于设定点变化,控制系统的 IAE 和 ITAE 值分别为 1.460 和 915.122。对于扰动变化,IAE 和 ITAE 值分别为 0.877 和 490.446。该系统可以帮助学生更好地理解工业 4.0 概念,并让他们以较低的成本在家有效地完成实践工作。
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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来源期刊
Journal of Chemical Technology and Metallurgy
Journal of Chemical Technology and Metallurgy Engineering-Industrial and Manufacturing Engineering
CiteScore
1.40
自引率
0.00%
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