Pipeline break detection using pressure transient monitoring

Misiunas, Dalius; Vitkovsky, J; Olsson, Gustaf; Simpson, A; Lambert, M

Pipeline break detection using pressure transient monitoring

Mark

Misiunas, Dalius ^LU ; Vitkovsky, J ; Olsson, Gustaf ^LU ; Simpson, A and Lambert, M (2005) In Journal of Water Resources Planning and Management 131(4). p.316-325

Abstract: Sudden pipe breaks occur in water transmission pipelines and distribution mains. The consequences of these breaks can be very expensive because of the service interruption, the cost of repair, and damage to surrounding property and infrastructure. The costs associated with the pipeline breaks can be reduced by minimizing the break detection and location time. This paper presents a new continuous monitoring approach for detecting and locating breaks in pipelines. A sudden pipe break creates a negative pressure wave that travels in both directions away from the break point and is reflected at the pipeline boundaries. Using the pressure data measured at one location along the pipeline, the timing of the initial and reflected transient waves... (More); Sudden pipe breaks occur in water transmission pipelines and distribution mains. The consequences of these breaks can be very expensive because of the service interruption, the cost of repair, and damage to surrounding property and infrastructure. The costs associated with the pipeline breaks can be reduced by minimizing the break detection and location time. This paper presents a new continuous monitoring approach for detecting and locating breaks in pipelines. A sudden pipe break creates a negative pressure wave that travels in both directions away from the break point and is reflected at the pipeline boundaries. Using the pressure data measured at one location along the pipeline, the timing of the initial and reflected transient waves induced by the break determines the location of the break. The magnitude of the transient wave provides an estimate of the break size. The continuous monitoring technique uses a modified two-sided cumulative sum (CUSUM) algorithm to detect abrupt break-induced changes in the pressure data. The adaptive tuning of CUSUM parameters is implemented to detect breaks of differing sizes and opening times. The continuous monitoring technique is verified by using results from both laboratory and field experiments and shows potential for detecting and locating sudden breaks in real pipelines. (Less)

Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/233782

author

Misiunas, Dalius ^LU ; Vitkovsky, J ; Olsson, Gustaf ^LU ; Simpson, A and Lambert, M

organization

Industrial Electrical Engineering and Automation

publishing date

2005

type

Contribution to journal

publication status

published

subject

Other Electrical Engineering, Electronic Engineering, Information Engineering

in

Journal of Water Resources Planning and Management

volume

131

issue

4

pages

316 - 325

publisher

American Society of Civil Engineers (ASCE)

external identifiers

wos:000230123700008
scopus:22944431507

ISSN

0733-9496

DOI

10.1061/(ASCE)0733-9496(2005)131:4(316)

language

English

LU publication?

yes

id

a7493a78-38e3-4299-a414-c275f7f1371f (old id 233782)

date added to LUP

2016-04-01 16:41:54

date last changed

2022-02-20 07:48:46

@article{a7493a78-38e3-4299-a414-c275f7f1371f,
  abstract     = {{Sudden pipe breaks occur in water transmission pipelines and distribution mains. The consequences of these breaks can be very expensive because of the service interruption, the cost of repair, and damage to surrounding property and infrastructure. The costs associated with the pipeline breaks can be reduced by minimizing the break detection and location time. This paper presents a new continuous monitoring approach for detecting and locating breaks in pipelines. A sudden pipe break creates a negative pressure wave that travels in both directions away from the break point and is reflected at the pipeline boundaries. Using the pressure data measured at one location along the pipeline, the timing of the initial and reflected transient waves induced by the break determines the location of the break. The magnitude of the transient wave provides an estimate of the break size. The continuous monitoring technique uses a modified two-sided cumulative sum (CUSUM) algorithm to detect abrupt break-induced changes in the pressure data. The adaptive tuning of CUSUM parameters is implemented to detect breaks of differing sizes and opening times. The continuous monitoring technique is verified by using results from both laboratory and field experiments and shows potential for detecting and locating sudden breaks in real pipelines.}},
  author       = {{Misiunas, Dalius and Vitkovsky, J and Olsson, Gustaf and Simpson, A and Lambert, M}},
  issn         = {{0733-9496}},
  language     = {{eng}},
  number       = {{4}},
  pages        = {{316--325}},
  publisher    = {{American Society of Civil Engineers (ASCE)}},
  series       = {{Journal of Water Resources Planning and Management}},
  title        = {{Pipeline break detection using pressure transient monitoring}},
  url          = {{http://dx.doi.org/10.1061/(ASCE)0733-9496(2005)131:4(316)}},
  doi          = {{10.1061/(ASCE)0733-9496(2005)131:4(316)}},
  volume       = {{131}},
  year         = {{2005}},
}

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Pipeline break detection using pressure transient monitoring