Distributed Low-Power Electronic Units for Sensing and Communication in Water Pipeline Monitoring

IEEE Transactions on AgriFood Electronics Pub Date : 2024-06-14 DOI:10.1109/TAFE.2024.3409396

Daniele M. Crafa;Christian Riboldi;Marco Carminati

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引用次数: 0

Abstract

Sets of metal electrodes applied along pipelines can serve both for detecting leaks of water, as well as to bring power and transmit data among remote monitoring units. We present a modular electronic system developed to demonstrate this versatile hybrid wired and wireless sensing network concept applied to monitoring water distribution for agricultural applications. The system provides km-scale granularity, submeter spatial resolution and a selectable temporal resolution from seconds to hours. The central unit communicates with the gateway via a LoRa radio and contains the readout of water sensors (pressure, temperature, and flow rate by means of ultrasounds), while the remote unit detects water leakage by a novel sensing concept based on multiplexed differential impedance measurements. The latter is achieved with a 2 MHz analog lock-in circuit sequentially connected to the four electrodes. A small-scale hydraulic loop was built to experimentally validate the system. All parameters are tracked with 1% resolution. The total power consumption was minimized to only 10 mWh/day, easily provided by a compact solar panel for energetic autonomy.

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用于输水管道监测传感和通信的分布式低功耗电子装置

沿管道安装的一组金属电极既可用于检测水的泄漏，也可为远程监控装置供电和传输数据。我们介绍了一种模块化电子系统，以展示这种应用于农业输水监测的多功能有线和无线混合传感网络概念。该系统提供公里级粒度、亚米级空间分辨率和从秒到小时的可选时间分辨率。中央单元通过 LoRa 无线电与网关通信，包含水传感器读数（压力、温度和超声波流量），而远程单元则通过基于多路差分阻抗测量的新型传感概念来检测漏水情况。后者是通过与四个电极顺序连接的 2 MHz 模拟锁定电路实现的。为了对系统进行实验验证，我们建造了一个小型液压回路。所有参数的跟踪分辨率均为 1%。系统的总耗电量降至每天 10 毫瓦时，可由一个紧凑型太阳能电池板轻松提供，实现能量自主。

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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IEEE Transactions on AgriFood Electronics

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