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

Nigel J. Cassidy*, Paul O’Regan, Sha Luo, David N. Chapman, Ian Jefferson, Xinqun Zhu (Editor), Hongfang Lu (Editor), Zhao-Dong Xu (Editor), Ying-Qing Guo (Editor)

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

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Abstract

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.
Original languageEnglish
Article number1298
Number of pages20
JournalSensors
Volume24
Issue number4
Early online date17 Feb 2024
DOIs
Publication statusE-pub ahead of print - 17 Feb 2024

Bibliographical note

Funding
This research was funded by Innovate UK’s Sustainable Innovation Fund under grant number 77097 titled “Smart pipes for sustainable infrastructure innovation”. The National Buried Infrastructure Facility (NBIF) at the University of Birmingham was funded by the UK’s Engineering and Physical Sciences Research Council, grant award EP/P013635/1.

Keywords

  • pipeline
  • distributed fibre optic sensing
  • optical frequency domain reflectometry
  • buried infrastructure
  • strain measurement
  • drainage
  • stormwater

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