Batteryless Sensor Devices for Underground Infrastructure—A Long-Term Experiment on Urban Water Pipes

IF 1.6 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Low Power Electronics and Applications Pub Date : 2023-04-29 DOI:10.3390/jlpea13020031

Manuel Boebel, Fabian Frei, F. Blumensaat, C. Ebi, M. Meli, Andreas Rüst

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引用次数: 2

Abstract

Drinking water is becoming increasingly scarce as the world’s population grows and climate change continues. However, there is great potential to improve drinking water pipelines, as 30% of fresh water is lost between the supplier and consumer. While systematic process monitoring could play a crucial role in the early detection and repair of leaks, current practice requires manual inspection, which is both time-consuming and costly. This project envisages maintenance-free measurements at numerous locations within the underground infrastructure, a goal that is to be achieved through the use of a harvesting device mounted on the water pipe. This device extracts energy from the temperature difference between the water pipe and the soil using a TEG (thermoelectric generator), takes sensor measurements, processes the data and transmits it wirelessly via LoRaWAN. We built 16 harvesting devices, installed them in four locations and continuously evaluated their performance throughout the project. In this paper, we focus on two devices of a particular type. The data for a full year show that enough energy was available on 94% of the days, on average, to take measurements and transmit data. This study demonstrates that it is possible to power highly constrained sensing devices with energy harvesting in underground environments.

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用于地下基础设施的无电池传感器装置——城市水管的长期试验

随着世界人口的增长和气候变化的持续，饮用水变得越来越稀缺。然而，由于30%的淡水在供应商和消费者之间流失，改善饮用水管道的潜力很大。虽然系统的过程监测可以在早期检测和修复泄漏方面发挥关键作用，但目前的做法需要手动检查，这既耗时又昂贵。该项目设想在地下基础设施内的许多位置进行免维护测量，这一目标将通过使用安装在水管上的收集装置来实现。该设备使用TEG（热电发电机）从水管和土壤之间的温差中提取能量，进行传感器测量，处理数据，并通过LoRaWAN无线传输。我们建造了16个收割装置，将其安装在四个位置，并在整个项目中不断评估其性能。在这篇论文中，我们关注两种特定类型的设备。全年的数据显示，平均94%的天数有足够的能量进行测量和传输数据。这项研究表明，在地下环境中通过能量采集为高度受限的传感设备供电是可能的。

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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