Use of Fibre-Optic Sensors for Pipe Condition and Hydraulics Measurements: A Review

Prisutova, Jevgenija; Krynkin, Anton; Tait, Simon; Horoshenkov, Kirill V.

doi:10.3390/civileng3010006

Cited by 11 publications

(3 citation statements)

References 75 publications

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“…The proposed controller has overcome critical challenges caused by the design trade-offs and sacrifices required to keep the robot small (discussed in section 2.3 ) and controlled the robot stably, autonomously fulfilling Task 1 ( Section 2.2 ): to control the robot movement autonomously in sewer pipes, exhaustively explore a real pipe network in laboratory settings, and avoid obstacles. In this way, the proposed control architecture separates mobility, stability and navigational tasks (all of which can be implemented with only low-cost components and low power consumption) from localization, mapping and pipe inspection tasks (that may require additional, possibly more power-hungry sensors ( Worley et al, 2020 ; Aitken et al, 2021 ; Yu et al, 2021a ; Yu et al, 2021b ; Prisutova et al, 2022 ; Zhang et al, 2022 )). An example of a hybrid experiment is presented by Li et al ( Li et al, 2022 ) in this issue.…”

Section: Discussionmentioning

confidence: 99%

Autonomous control for miniaturized mobile robots in unknown pipe networks

Nguyen

Blight²,

Pickering³

et al. 2022

Front. Robot. AI

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Despite recent advances in robotic technology, sewer pipe inspection is still limited to conventional approaches that use cable-tethered robots. Such commercially available tethered robots lack autonomy, and their operation must be manually controlled via their tethered cables. Consequently, they can only travel to a certain distance in pipe, cannot access small-diameter pipes, and their deployment incurs high costs for highly skilled operators. In this paper, we introduce a miniaturised mobile robot for pipe inspection. We present an autonomous control strategy for this robot that is effective, stable, and requires only low-computational resources. The robots used here can access pipes as small as 75 mm in diameter. Due to their small size, low carrying capacity, and limited battery supply, our robots can only carry simple sensors, a small processor, and miniature wheel-legs for locomotion. Yet, our control method is able to compensate for these limitations. We demonstrate fully autonomous robot mobility in a sewer pipe network, without any visual aid or power-hungry image processing. The control algorithm allows the robot to correctly recognise each local network configuration, and to make appropriate decisions accordingly. The control strategy was tested using the physical micro robot in a laboratory pipe network. In both simulation and experiment, the robot autonomously and exhaustively explored an unknown pipe network without missing any pipe section while avoiding obstacles. This is a significant advance towards fully autonomous inspection robot systems for sewer pipe networks.

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Section: Discussionmentioning

confidence: 99%

Autonomous control for miniaturized mobile robots in unknown pipe networks

Nguyen

Blight²,

Pickering³

et al. 2022

Front. Robot. AI

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“…Over the past decade, distributed optical fibre sensing (DOFS)-based strain measurement systems have become popular for the monitoring and evaluation of infrastructure condition, health, performance and maintenance applications. In the civil engineering sector, modern advances in computational modelling, autonomous data processing techniques and remote monitoring have expanded DOFS use to bridges [ 1 , 2 ], foundations and piles [ 3 , 4 ], pipelines [ 5 , 6 ] and tunnels [ 7 , 8 ]. An extensive review of fibre optic sensing and its application to civil engineering and geotechnical problems can be found in [ 9 ] and [ 10 ] but it is important to summarise the key practical requirements of any FO-based monitoring technology, particularly with regard to buried infrastructure and, specifically, large-scale drainage and stormwater pipelines.…”

Section: Introductionmentioning

confidence: 99%

The Application of High-Resolution, Embedded Fibre Optic (FO) Sensing for Large-Diameter Composite Steel/Plastic Pipeline Performance under Dynamic Transport Loads

Cassidy,

O’Regan,

Luo

et al. 2024

Sensors

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Distributed optical fibre sensing (DOFS)-based strain measurement systems are now routinely deployed across infrastructure health monitoring applications. However, there are still practical performance and measurement issues associated with the fibre’s attachment method, particularly with thermoplastic pipeline materials (e.g., high-density polyethylene, HDPE) and adhesive affixment methods. In this paper, we introduce a new optical fibre installation method that utilises a hot-weld encapsulation approach that fully embeds the fibre onto the pipeline’s plastic surface. We describe the development, application and benefits of the new embedment approach (as compared to adhesive methods) and illustrate its practical performance via a full-scale, real-world, dynamic loading trial undertaken on a 1.8 m diameter, 6.4 m long stormwater pipeline structure constructed from composite spiral-wound, steel-reinforced, HDPE pipe. The optical frequency domain reflectometry (OFDR)-based strain results show how the new method improves strain transference and dynamic measurement performance and how the data can be easily interpreted, in a practical context, without the need for complex strain transfer functions. Through the different performance tests, based on UK rail-road network transport loading conditions, we also show how centimetre- to metre-scale strain variations can be clearly resolved at the frequencies and levels consistent with transport- and construction-based, buried infrastructure loading scenarios.

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“…However, the size of photonics devices fabricated on bulk materials is often large, and it is difficult to improve device integration. Therefore, single crystal LN thin with SOI like structure are urgently needed [7][8][9][10] .…”

Section: Introductionmentioning

confidence: 99%