Abstract
Wireless sensor networks (WSN) provide a powerful solution to the task of monitoring the operational conditions of buried and non-buried pipes of different lengths and materials. Due to the limited energy stored in the sensor nodes, the use of low-power vibration sensors becomes the preferred choice. However, the monitoring of vibrations for leak detection in wall-mounted pipelines, and the associated complexities are not adequately dealt with in the literature. This article offers to fill this gap by presenting a feasibility study of leak detection in wall-mounted water pipelines through vibrations measurements using low-power accelerometers. The work is divided into two steps: Firstly, a careful analysis is performed to understand the effect of various fittings such as clamps, bends, and leaks of various sizes, on the vibrations produced. Then this knowledge is used to find the best locations for placement of nodes in order to efficiently detect leaks of various sizes. This analysis revealed two important facts: (a) difficulty in detecting medium-size leaks as their vibrations and those from the no-leak condition are very indistinguishable, (b) vibrations measured away from the leak are of a small benefit to the leak detection process. Consequently, 3 different learning models are applied, all fed with information from multiple nodes, in order to reliably detect leaks and classify their size. Comparing the performances of these models shows that the Support Vector Machine (SVM)-based model gives the best results, in that for the worst case of medium-size leaks and with the use of one sensor, the worst accuracies for leak detection and leak size classification have remarkably been improved from being respectively 51% and 36% with one sensor, to being 88% and 93%, respectively, with only a moderate increase in the number of sensors to four.
Highlights
Pipelines play a vital role in transporting various types of fluids in industries, as well as in carrying water and gas for usage in residential and commercial buildings
This analysis is needed in order to select the best locations at which to deploy the sensors for leak detection purposes
The sensors are deployed at the experimentally-selected best locations and the data collected under various leak conditions, is used as the training data set for the two developed learning models and for both tasks of leak detection and size classification
Summary
Pipelines play a vital role in transporting various types of fluids in industries, as well as in carrying water and gas for usage in residential and commercial buildings. The associate editor coordinating the review of this manuscript and approving it for publication was Agustin Leobardo Herrera-May. in the shortest possible time, various automated Pipeline Monitoring Systems (PMS) have been developed for use in industry. In the shortest possible time, various automated Pipeline Monitoring Systems (PMS) have been developed for use in industry These monitoring solutions differ from each other in various respects such as pipeline characteristics that include the material the pipeline is made of [2], the surroundings of the pipeline itself, the size and geometry of the monitoring network [3], the nature of the application being monitored and various types of leak detection instruments, including sensors, and monitoring methodologies used.
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