Pipeline leak detection using in-situ soil temperature and strain measurements
This project investigated whether by measuring temperature and strain changes in the ground around a pipeline a leak can be detected using fibre optic instrumentation. The concept entails installation of an optic fibre along the length of the pipeline in the pipe trench when a new pipe is install...
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Language: | en |
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University of Pretoria
2018
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Online Access: | http://hdl.handle.net/2263/66579 Jahnke, SI 2018, Pipeline leak detection using in-situ soil temperature and strain measurements, MEng Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/66579> |
Summary: | This project investigated whether by measuring temperature and strain changes in the ground
around a pipeline a leak can be detected using fibre optic instrumentation. The concept entails
installation of an optic fibre along the length of the pipeline in the pipe trench when a new pipe
is installed. Alternatively, the possibility also exists to retrofit such a leakage detection system
by burying it near (above) existing pipes, although this has not been investigated in this project.
The success of such a leakage detection system is based on the hypothesis that the
temperature differential between the water in a pipeline and the ground around the pipe will
result in a detectable temperature change in the ground when a leak occurs. Softening of the
pipe support due to leaking water should result in strain changes in the soil immediately around
the pipe and in the pipe itself, both of which should be detectable. All three of these quantities,
i.e. ground temperature, ground strain and pipe strain can be measured using fibre optic
technology. This study is based on detecting temperature and strain changes using fibre
Bragg grating sensors (FBGS) at discrete locations along the length of a pipe.
The success of a system based on temperature measurement implies that temperature
changes caused by a leak should be distinguishable from naturally occurring temperature
cycles. Installations were therefore conducted to measure ground temperature changes to a
depth of 3m over the course of a year and comparing those to temperature changes measured
in active water mains over the same period in Pretoria. A temperature differential that always
exceeded 2°C was recorded, indicating that the system has potential to provide a means of
leak detection. A laboratory study was carried out to observe temperature changes associated with an
advancing wetting plume caused by a simulated leak using thermistors buried in fine sand.
Depending on the magnitude of the soil-water temperature differential, a rapid drop in
temperature was observed at monitoring locations during the progression of the wetting plume
(the water temperature is typically lower than the soil temperature). However, an initial shortduration
increase (spike) in temperature was consistently observed at measurement locations
upon first passage of the wetting front. It is hypothesised that this spike is caused by the
release of free surface energy upon wetting of the soil. As expected, immediately following
this spike after the passage of the wetting front, a significant and rapid change in temperature
was noted during the tests. The temperature reduction is dependent on the temperature
differential between the water and the surrounding soil and illustrated the potential of the
proposed method of leak detection (i.e. detecting leaks by observing a reduction in ground
temperature).
After the laboratory phase, a field study was conducted during which a 110 mm diameter 12
m long uPVC pipe was installed with sensor arrays consisting of both temperature and total
strain FBGS. Thermistors were used as temperature sensors as in the case of the laboratory
investigation. Strain sensors used were discrete optical strain gauges or fibre Bragg grating
sensors (FBGS). Fifty percent of the FBGS were epoxied to the pipe to measure pipe strains,
while the remaining 50% were free-floating, situated in a thin oil-filled plastic tube buried in the
corner of the pipe trench. The purpose of the epoxied FBGS was to measure pipe strain
changes, while the purpose of the free-floating FGBS was to detect temperature-induce strain
changes. During a leak, strain changes were recorded in the free-floating FBGS several times
exceeding the values expected based on the temperature changes measured by the
thermistors. In addition, very significant pipe strain changes were observed. These
observations indicate that significant ground and pipe strains occur due to wetting and
subsequent softening of the soil caused by the leak. The change in total strain and
temperature observed during a leakage event provided strong evidence that both parameters
can be used to effectively indicate the presence of a leakage event.
A complication identified in the study is that network pressure fluctuations result in significant
pipe strains which would complicate leak identification. It is therefore recommended that the
leakage detection system should comprise of an optic fibre separated from, but in close
proximity to the pipe. This study should be followed up to investigate the performance of a
leakage detection system based on distributed strain measurement and the potential of
retrofitting the proposed detection system to existing pipelines. === Dissertation (MEng)--University of Pretoria, 2018. === Civil Engineering === MEng === Unrestricted |
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