Pipeline Monitoring Using Vibroacoustic Sensing – A Review

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056
Volume: 03 Issue: 01 | Jan-2016 www.irjet.net p-ISSN: 2395-0072
© 2016, IRJET | Impact Factor value: 4.45 | ISO 9001:2008 Certified Journal | Page 1095
Pipeline Monitoring Using Vibroacoustic Sensing – A Review
S.Ravi1 , S.KarthikRaj2 , D.Sabareesan3 ,R.Kishore4
1Assistant professor, Department of Mechanical Engineering, Sri Ramakrishna Engineering College,
Coimbatore , Tamilnadu , India
2,3,4U.G Students, Department of Mechanical Engineering, Sri Ramakrishna Engineering College,
Coimbatore , Tamilnadu , India
Abstract : Vibroacuostic Sensing is an emerging technique for detection of leaks and foreign particles in fluid
transportation pipelines. This sensing is based on the remote identification of fluid transients and pipe shell vibrations
produced by interaction with pipe or flow. The system performance is a function of the thermodynamic properties of the fluids,
which can be separated into liquid, gases and multiphase mixtures. While liquid are considered incompressible, Gases and
mixtures sustain strong volume variations, thus producing variable flow conditions along the pipelines. This paper analyses
pressure transient propagation in gas filled pipelines. Field test should be conducted at different pressures, with or without
flow, and also in operational conditions, generating controlled interactions with infrastructure to collect vibroacoustic signals
by a network of monitoring stations located along the pipeline.
Key Words: Keywords – pipeline, vibroacoustic sensing , third party interference (TPI)
--------------------------------------------------------------------***----------------------------------------------------------------------
1. INTRODUCTION
Pipeline networks are economical means of transporting
oil and gas. Most pipelines have been designed with a
typical life span of 25 to 30 years. Existing pipelines are
aging and quite susceptible to failure, due to poor
construction of joints, fatigue and material cracks [1].
Prevention of failure of failures of pipelines is critical for
public safety and the environment. In order to maintain
healthy state of pipelines, continuous and accurate
monitoring of pipelines is crucial, especially for leakage.
Failure of pipeline leads to series accidents that cause
losses in terms of lives and money [2]. According to
recent survey [3] 30% of pipeline failure is due to
vibrations and fatigue failures. If the levels of noise and
vibrations increases above the optimum value it may
damage gas distribution station building elements,
pipelines, construction equipment’s and other
auxillaryelements. Excess vibrations in pipeline manifold
cause series accidents. Leakages in pipeline leads to
series economic losses and sometime leads to heavy
accidents due to reaction of gases with the atmosphere.
Leakages in pipelines may be caused due to third party
interference with the pipeline. To avoid failures in a
pipeline it need to monitor by use of vibroacoustic
sensing method [4] .It senses both vibrations and noise
produced during transportation. Another negative factor
in pipeline is ageing of pipeline.
The system consists of a discrete network of pressure
and vibration sensors installed on a pipe line at relative
distances. The acoustic and elastic waves produced by
third party interference and flow variations propagate
along the pipeline and are recorded at monitoring
stations [5]. Recording and processing of vibroacoustic
data is an emerging technique in real time monitoring of
fluid pipelines [6]. The methodology is based on
identification of pressure transients generated by pipe
and flow variations. Performance of the system is a
function of thermodynamic properties of transported
fluid [7,8]. The system uses multipoint acoustic
recording system to analyses pressure transients in gas
transportation at various conditions at different
pressure [9]. The main objective are the characterization
of the source wavelet with respect to interference action
(eg: leak, interference, impact).Third party interference
(TPI) activities with respect to generated pressure sound
wavelet and detection distance is measured at different
stations situated along the pipeline [10]. In advanced
applications, remote tracking of the position and velocity
of an inspection pig is carried out [11].
FIG1: Multipoint vibroacoustic sensing system

2. TESTING PROCEDURE:
2.1 IMPACT TEST:
A list of actions are carried at the pipe like impacting,
drilling, grinding in impact test to find third party
interference (TPI). The system consists of array of
vibrational sensor at the testing point. Impact tests are
carried out using an oscillating pendulum mass up to
80kg and a 5kg hammer. Different impact energies, E,
were obtained by increasing the departing distance of
the pendulum (E<750). Dynamic measurements of pipe
displacement were carried out at the hit position of
pendulum by three component accelerometer. It shows
that the energy entering the pipe was approximately two
third of the total one. The fig shows the impact test
parameters and acceleration signal at hammer.
FIG 2: Impact test parameters and acceleration signal at
hammer
2.2 PIG TRACKING:
Pig devices are frequently used for in-line service
inspection of gas pipelines. They are designed to collect a
wide range of, pig requires tracking because they may
strike inside pipe and their speed must be measured.
Some of the pigs use electromagnetic emitters and
moves inside the pipeline. Pigs can be taken out at the
monitoring station. When the sealing cups of the pig
encounter a weld, vibrational and acoustic signals are
generated. They carry information on the source and on
the transmission channel. The range of detection
dependents on the pipeline diameter and type of pig. Pig
tracking is used to measure environmental pressure
noise produced by the flow of fluid and by compressors.
Pig tracking involves two techniques welding hit count
and cross correlation method.
2.3 WELDING HIT COUNT:
This procedure is used to identify the count of weld and
sound peak produced by the pig at the welding joints or
dents. This case requires one station to detect the sound
peak. From this method we can find the position of
welded joints and its behavior at various load. Any defect
in welded joint is identified by change in sound peak
measured by the pig.
2.4 CROSS CORRELATION METHOD:
The sound peak produced by the pig at the welding dents
propagates in both directions and it is recorded at both
sides by the monitoring stations [12]. The cross
correlation peak happens at differential propagation
time between the source position and recording stations.
2.5 SPILL TEST:
Leak test were performed by operating different valves
along the pipeline [13]. Short (1s) and long (7to10s)
spilling sequences are produced. An echo detection
procedure [14] is applied by filtering the recording
signal with time varying matched filter with time varying
filter. The starting matched filter is the source wavelet.
3. LITERATURE REVIEW:
1) F. Musaakhunovaa , Aleksandr A. Igolkin , “An
extensive research on vibration and acoustic
characteristic in a pipeline is conducted ”.The levels of
vibration and acoustic noise level in various parts of
pipelines are measured to obtain experimental data to
vibration loading in pipeline.
2)Giancario Bernasconi ,Giuseppe Giunta , “design a
pipeline monitoring system, reducing negative pressure
waves ”.A discrete network of pressure and vibration
sensor are placed along the pipeline at a certain distance
and results from the sensor are recorded at various
stations along the pipeline .Thus collecting results for
gas transportation pipe lines
3) F.Diongi, A.Bassan, M.Veneziani, “Third party
interference and leakages must be avoided”. Remote real
time monitoring is setup using fibre optics and discrete
acoustic sensing to perform tests to simulate intrusions,
impacts and leak eve
4) Riccardo schiavon, Giancarlo bernasconi, “Real time
monitoring of pipeline is key factor for environmental

sustainability of oil and gas industry”. Campaigns in
controlled conditions were carried out and pressure
wave propagation is studied. Background noise removal
algorithms have been developed to increase sensitivity
of system.
5) Alberto Martini, Marco Troncossi and Alessandro
Rivola, “The objective is the development of system for
automatic early detection of burst leaks in service pipes”.
Detection of leaks in pipeline is conducted using
vibration monitoring techniques. The experimental data
obtained from the system are used develop algorithm for
leak detection purpose.
6) Rejane B.Santos, Wellick S .de Almeida, “Increasing
operational reliability of the systems is crucial to
minimize risk of leaks”. The system consists of
microphone installed inside the pipeline and coupled to
a data acquisition card and computer. Leak test are
carried out under event with leak and event without leak
by spectrum analysis.
7) Ritaban Dutta, Anthony Cohn, “Experimental multi
sensor images were obtained for monitoring pipelines”.
The system consists of vibro-acoustic sensor based
location methods and ground penetrating radar imaging
system. Three types of sensory images were processed
computationally to extract depth and location
information of the pipeline with high accuracy.
8) David Hanson, Bob Randall, “possible to locate
presence of leaks in pipes by measuring at remote
locations”. Leaks are detected by measuring time delay
of the leak noise reaching the different sensors. Location
of leak may be pinpointed by measuring wave speed in
the pipe.
9) Wei-Yu Lu, Wei-Hui Wang, “pipe flow noises are
calculated by numerical simulation of sound pressure
field along the pipe”. The frequency factors along the
material are determined by experimental modal analysis.
Flow noise can be eliminated by using shearing materials
like wool,
Lead sheet and aluminium.
10) Zheng Liu,Yehuda Kleiner, “Art of inspection using
condition assessment in pipelines”. The system includes
conventional non-destructive testing and advanced
sensors for monitoring. Structural deterioration of
pipeline can be controlled by using techniques like smart
pipe, augmented reality.
11)Jaiwan Cho ,Youngchil Seo, “ Defect detection in a
pipeline using ultrasound thermography”. Ul0trasonic
vibration energy is passed in the exterior side of the
pipeline. A hot spot is produced around the defect is
identified by measuring temperature along the pipe.
Temperature at hotspot is higher when compared to
other areas.
4. EXISTING METHDOLOGY:
1) Eddy current method: The eddy current technique
is based on electromagnetism. When an alternating
current is applied to a conductor, magnetic field is
created in and around the conductor. If another
conductor is brought closely eddy current induced
in second conductor.
2) Pressure wave Detector: The negative pressure
wave technique is an effective method for fluid
leakage detection and location. It is difficult to
distinguish the source that has led to fluid pressure
drop.
3) Fiber optic sensor: The ability to measure
temperatures and strains at thousands of points
along a single fiber is particularly relevant for
monitoring pipelines. Sensing system is based on
Raman scattering are used to detect pipeline
leakages.
4) Soil monitoring: In soil monitoring methods, the
pipeline is first injected with small amount of a
tracer chemical, which seeps out of the pipe in the
event of a leak. This is detected by dragging an
instrument along the pipeline
5) Infrared Thermography: Some leaks can be
detected through the identification of temperature
changes in the immediate surroundings. It is used to
detect hot fluid leaks. This methods equipment can
be used from moving vehicles ,aircraft and portable
system in ground cover
5. PROPOSED METHODOLGY:
The monitoring of pipeline health is done by using
acoustic waves [15]. This technique can be used to
measure pipeline walls, detect gas contamination,
measure flow, and detect gas leaks and structural
defects in the pipe.
An acoustic sensor uses mechanical waves as
sensing mechanism. As the waves propagates
through or on the surface of material, any changes
to characteristics of the propagation path affect the

velocity and amplitude of the wave. Changes in
velocity can be monitored by measuring the
frequency or phase characteristics of the sensor and
can be correlated to the corresponding physical
quantity that is being measured.
Due to limitations in detection range, it is usually
necessary to install many sensors along a pipeline.
The sensor detect acoustic signal in the pipeline and
discriminate leak sounds from other sounds
generated by normal operational changes. When a
leak occurs, noise is generated as the fluid escapes
from the pipeline. The wave of the noise propagates
with a speed determined by the physical properties
of fluid in the pipeline. Acoustic detectors detect
these waves and find the leaks.
6. CONCLUSION:
Impacts, intrusions, threats, leaks are the principle
causes of pipeline fluid transportation failure and
maintenance stops. On the other hand these events
produce vibrations and acoustic emissions in the
source point, that can be used to detect, locate and
classify the defect. Vibro acoustic sensing is
emerging technique for real time monitoring of
pipelines. The system has been used for both single
phase and multiphase transportation lines. The
main results are as follows
 Environmental noise is on order of 1 to 10 kpa is
produced by flow generation and regulation
equipment, as well as by turbulence. Sound
attenuation increases with frequency and
decreases with gas pressure and pipe radius.
Adaptive noise reduction requires very accurate
design of sensor positioning and knowledge of
pipe system layout.
 Pressure noise level produced by third party
interference and leak events is detected in the
50 to 300 Hz bandwidth at a distance of 10 km.
spills and leaks are low pass signals.
 Travelling pigs generate vibroacoustic
transients when they cross pipeline internal
welding dents. This signal can be effectively
processed to track the position of pig and its
velocity.
 Pipeline terminals are sources of environmental
pressure transients that propagates in both
direction along the flow. It is then possible by
cross correlation method to obtain an equivalent
acoustic channel of pipeline. Long term
monitoring pipeline can aid the detection of pipe
deformations and causes for failures of flow
regulation.
7. REFERENCES:
[1]. Giunta, G., Dionigi, F., Bernasconi, G., Del
Giudice, S., Rovetta, D., 2011a, “Vibroacoustic
Monitoring of Pigging Operations in Subsea Gas
Transportation Pipelines,” ASNT Fall
Conference, Palms Spring, USA.
[2]. Giunta, G., Dionigi, F., Bassan, A., Veneziani,
M., Bernasconi, G., Del Giudice, S., Rovetta, D.,
Schiavon, R., Zanon, F., 2011b, “Third Party
Interference and Leak Detection on Buried
Pipelines for Reliable Transportation of Fluids,”
10th Offshore Mediterranean Conference,
Ravenna, Italy.
[3]. Giunta G., Bernasconi G., Del Giudice S.,
2013, “Vibroacoustic Monitoring of Gas-Filled
Pipelines”, ASNT Fall Conference and quality
testing show, Las Vegas, Nevada, USA.
[4]. Alberto Martini, Marco Troncossi and
Alessandro Rivola, “vibration monitoring as a
tool for leak detection in water distribution
network”.
[5]. Rejane B.santos, Wellick S. de almeida,
Flavio V .da silva, “spectral analysis for detection
of leaks in pipe carrying compressed air”.
[6]. David Hanson, Bob Randall and Graham
Brown, “Locating leaks in underground water
pipes using complex spectrum”.
[7]. Wei- Yu Lu and Wei-Hui Wang,
“vibroacoustic attenuation effect of sandwich
damping mateil on pipe flow noise”.
[8]. Jaiwan Cho, Youngchil Seo and Seungho
Jung, “Defect detection within apipe using
ultrasonic sound excited thermograph”.
[9]. Giunta, G., Bernasconi, G., “Method and
system for continuous remote monitoring of the
integrity of pressurized pipelines and properties
of the fluids transported”.
[10]. Bernasconi, G., Del Giudice, S., Giunta, G.,
2012, “Pipeline Acoustic Monitoring,” Pipeline
Technology Conference, Hannover, Germany.
ionigi, F., Schiavon, R., Zanon, F., 2013a,
advanced Pipeline Monitoring Using Multipoint
Acoustic Data,” 11th Offshore Mediterranean
Conference and Exhibition, Ravenna, Italy.
Dionigi, F., 2013b, “Advanced pipeline
vibroacosutic monitoring”,

[13]. Giunta, G., Bernasconi, G., “Method and
system for the remote detection of the position
of a pig device inside a pressurized pipeline”.
[14]. Bickerstaff, R., Vaughn, M., Stoker, G.,
Hassard, M., Garrett, M., “Review of Sensor
Technologies for In-line Inspection of Natural
Gas Pipelines
[15]. Blackstock, D. T., 2000, “Fundamentals of
physical acoustics,” John Wiley&Sons, Inc.

Pipeline Monitoring Using Vibroacoustic Sensing – A Review

More Related Content

What's hot (20)

Similar to Pipeline Monitoring Using Vibroacoustic Sensing – A Review (20)

More from IRJET Journal (20)

Recently uploaded (20)

Pipeline Monitoring Using Vibroacoustic Sensing – A Review