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Detecting gas pipeline leaks in sandy soil with fiber-optic distributed acoustic sensing

Zhuo Chen, Chengcheng Zhang, Bin Shi, Yan Zhang, Zheng Wang, Hao Wang, Tao Xie

2023Tunnelling and Underground Space Technology45 citationsDOIOpen Access PDF

Abstract

Detecting pinhole leaks in long-haul buried gas pipelines is challenging due to weak leak signals and large spans. Fiber-optic distributed acoustic sensing (DAS) technology offers highly sensitive long-distance monitoring. This study evaluates DAS for detecting pinhole gas leaks in pipelines buried in sandy soil. Controlled experiments examined the effects of pipe-to-fiber distance, fiber position, leak direction, gas pressure, and leak diameter. Pressurized gas erodes the overlying soil, forming cavities and fissures that change soil morphology. Gas preferentially diffuses upward; an optical fiber above the pipe has the highest sensitivity regardless of leak direction and should be deployed above pipelines. Two mechanisms produce DAS-recorded leak vibration signals: dynamic soil straining and gas–fiber friction. Vibration energy from dynamic soil motion concentrates at 60–120 Hz while gas–fiber friction exhibits a broader spectral response. Increasing gas pressure or leak diameter increases detected vibration power but decreases peak frequency and proportion generated by soil strain, indicating a shift toward gas–fiber friction as the dominant mechanism. These results inform improved pinhole leak monitoring in buried gas pipelines using DAS technology.

Topics & Concepts

LeakPipeline transportPinhole (optics)Soil gasOptical fiberFiberMaterials scienceFiber optic sensorOptical fiber cableGas leakAcousticsEnvironmental scienceOpticsComposite materialSoil scienceSoil waterChemistryEnvironmental engineeringPhysicsOrganic chemistryAdvanced Fiber Optic SensorsGeotechnical Engineering and Underground StructuresSeismic Waves and Analysis
Detecting gas pipeline leaks in sandy soil with fiber-optic distributed acoustic sensing | Litcius