NZ718610B2 - Pipeline condition detecting apparatus and method - Google Patents
Pipeline condition detecting apparatus and method Download PDFInfo
- Publication number
- NZ718610B2 NZ718610B2 NZ718610A NZ71861014A NZ718610B2 NZ 718610 B2 NZ718610 B2 NZ 718610B2 NZ 718610 A NZ718610 A NZ 718610A NZ 71861014 A NZ71861014 A NZ 71861014A NZ 718610 B2 NZ718610 B2 NZ 718610B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- pipeline
- wall
- magnetic flux
- sensor
- condition
- Prior art date
Links
- 230000004907 flux Effects 0.000 claims description 54
- 238000001514 detection method Methods 0.000 claims description 18
- 238000007689 inspection Methods 0.000 claims description 12
- 230000001939 inductive effect Effects 0.000 claims description 7
- 238000005259 measurement Methods 0.000 claims description 6
- 230000005355 Hall effect Effects 0.000 claims description 5
- 230000000694 effects Effects 0.000 claims description 4
- 150000002500 ions Chemical class 0.000 description 14
- 238000004513 sizing Methods 0.000 description 10
- 238000005260 corrosion Methods 0.000 description 9
- 239000000463 material Substances 0.000 description 6
- 229910001018 Cast iron Inorganic materials 0.000 description 5
- 238000000034 method Methods 0.000 description 5
- 239000007789 gas Substances 0.000 description 4
- 241000282898 Sus scrofa Species 0.000 description 2
- 239000001257 hydrogen Substances 0.000 description 2
- UFHFLCQGNIYNRP-UHFFFAOYSA-N hydrogen Chemical compound [H][H] UFHFLCQGNIYNRP-UHFFFAOYSA-N 0.000 description 2
- 229910052739 hydrogen Inorganic materials 0.000 description 2
- 239000007788 liquid Substances 0.000 description 2
- 239000002893 slag Substances 0.000 description 2
- 230000000007 visual effect Effects 0.000 description 2
- 239000011800 void material Substances 0.000 description 2
- 206010016275 Fear Diseases 0.000 description 1
- 229910001060 Gray iron Inorganic materials 0.000 description 1
- 241001182492 Nes Species 0.000 description 1
- 241000282887 Suidae Species 0.000 description 1
- 230000002411 adverse Effects 0.000 description 1
- OKTJSMMVPCPJKN-UHFFFAOYSA-N carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 description 1
- 238000002485 combustion reaction Methods 0.000 description 1
- 238000011109 contamination Methods 0.000 description 1
- 230000001276 controlling effect Effects 0.000 description 1
- 230000001809 detectable Effects 0.000 description 1
- CWYNVVGOOAEACU-UHFFFAOYSA-N fe2+ Chemical compound [Fe+2] CWYNVVGOOAEACU-UHFFFAOYSA-N 0.000 description 1
- 229910002804 graphite Inorganic materials 0.000 description 1
- 239000010439 graphite Substances 0.000 description 1
- 238000011065 in-situ storage Methods 0.000 description 1
- 238000005272 metallurgy Methods 0.000 description 1
- 230000003746 surface roughness Effects 0.000 description 1
Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/72—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables
- G01N27/82—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws
Abstract
apparatus and a method for detecting the condition of a pipeline wall and analysis and estimate of the life of the pipeline by using apparatus which is mounted externally of the pipeline and is provided to be moved about and/or along at least a portion of the same. The apparatus includes at least one sensor array which includes a plurality of sensors, preferably three wherein said sensors are offset by 90 degrees with respect to each other, and which are axially offset so as to provide data for analysis and identification of pipeline defects. one sensor array which includes a plurality of sensors, preferably three wherein said sensors are offset by 90 degrees with respect to each other, and which are axially offset so as to provide data for analysis and identification of pipeline defects.
Description
ne condition detecting apparatus and method
The invention to which this application relates is the provision of apparatus
and a method for ing the condition of a pipeline wall and is and
estimate of the life of the pipeline.
It is known to provide apparatus which can be used to assess the quality,
damage, and/or risk of failure of pipelines which have been in service for a
period of time and, from the information provided by the tus and
method, to then assess r the pipeline is in a potentially ous
condition or needs specific maintenance to be undertaken and/or can allow
scheduled maintenance to be planned and performed on the basis of the
detected information. This therefore avoids the need for the pipeline to be
unnecessarily completely replaced and/or ensures that if the pipeline is in a
dangerous state of decay, this can be identified with the pipeline in situ and
without the need to first extensively excavate the pipe and repair or replace
the same.
A known detection apparatus is typically known as a "pig", which is passed
along the interior of the pipeline with the apparatus being carried by the
flow of the gas or liquid as it flows along the pipeline or. As the pig
passes along the interior of the pipe, results from detection means mounted
on the apparatus allows a survey to be formed of the pipeline condition.
However, a problem is that this type of apparatus is not always suitable or
ible with particular s or gases which pass along the pipeline
interior due to fears of contamination and/or safety risk. Thus, the use of
internally located and moving pigs is generally regarded as being impractical
or potentially dangerous, may affect the quality of some liquids passing
along the pipeline and also the results obtained from the same can be
inferior or not sufficiently accurate to allow a reliable survey of the pipeline
to be created.
2014/053080
It is also known to provide apparatus which can travel along the exterior
surface of a pipeline. This form of apparatus can be provided with means to
allow the same to be moved along the exterior of the pipeline.
In one embodiment a magnetic flux is generated which passes into the
pipeline. As the apparatus moves along the pipeline, the level of the
magnetic flux is monitored to ensure that any changes in flux are detected.
This change can be caused by "leakage" and is indicative of reduced pipe
wall thicknesses. As a result, the possible ion or damage to the pipe
wall is indicated and mapped with t to the position of the tus
on the pipeline.
With many types of pipeline, this form of apparatus can be satisfactory in
that the magnetic flux indicates the position of a defect and a subsequent
inspection of the external surface of the pipeline indicates to the user
whether the defect is on the external surface of the pipeline. If the defect is
visible then magnetic flux can be used to determine the depth of the fault
but, if the defect is not visible, the fault is then assumed to be on the or
wall of the ne and the magnetic flux change can again be used to
ine the size and depth of the fault. This apparatus is therefore
available for use where a visual check of the external pipeline can be used to
determine the position of the defect indicated by a magnetic flux change.
However, with certain materials, such as for example cast iron, there may be
defects on or near the exterior of the pipe which are not visible and
therefore the conventional tus cannot be used, as a visual check of
the external surface is not guaranteed to identify whether or not an external
or internal defect is present. In order to overcome this problem it is known
to provide apparatus which includes both Hall effect sensors and proximity
sensors to allow both the magnetic flux and change in condition of the
pipeline wall to be detected. The applicant’s copending application
EP1262771 bes one form of such apparatus.
In practice it has been found that it is desirable to be able to identify and
optimize the sizing of pipe wall defects, by collecting more data from, and
relating to, the pipeline wall which, in turn, allows more advanced
algorithms and software to be used to subsequently generate the defect
identification and sizing in the pipelines.
Conventional apparatus is found to have limitations in terms of the sensing
of defects particularly, gh not exclusively, when used on thick wall
grey iron pipeline walls. It is also found that the existing apparatus has
problems in being able to identify the width of defects which are detected. It
is also known that in certain instances the edges of large defects can be
confused and regarded, ectly, as small pipe wall defects.
A further problem is that the magnetic saturation of the pipeline wall which
is preferred to be ed in order to allow accurate measurement, cannot
always be achieved, ally when the pipeline being checked is relatively
large in diameter. If full magnetic tion is not achieved this can
adversely affect the cy of the defect sizing which is performed.
A further problem which can be experienced is the manner in which the
data which has been obtained is used in order to be able to predict the
estimated lifetime of the pipeline which has been checked, in a reliable
manner.
An aim of the present invention is to e an apparatus and method
which allows for the improved detection of the condition of the pipeline
wall in terms of accuracy of detection and the provision of a more accurate
survey of the pipeline wall condition. A further aim is to provide the y
to generate predictions with respect to the estimated lifetime of the pipeline
using the data which is obtained.
In a first aspect of the invention there is provided apparatus for the analysis
of the condition of at least part of a pipeline wall, said apparatus ble
on the external surface of the ne and including a body, means for
2014/053080
inducing a magnetic flux into, and at least partially through, the wall of the
pipeline adjacent the location of the apparatus and processing means for
ing data relating to the said pipeline wall condition and characterized
in that said processing mean includes at least one sensor array including a
plurality of sensors configured to detect ion in magnetic flux along
different respective axes with regard to the wall of the pipeline in order to
provide data representative of the condition of the wall of the pipeline.
Typically the at least one sensor array is provided with three s in a
uration so as to provide data ng to the magnetic flux in at least
three axes with regard to the pipeline wall.
In one embodiment the sensor array is provided as a tri—aXial sensor array.
In one embodiment the sensors are offset by 90 degrees with respect to
each other on the body such that the sensors in each array are d so as
to provide measurements with respect to the longitudinal aXis,
circumferentially and radially respectively relative to the pipe.
In one embodiment the sensors used in the arrays are Hall effect sensors
which are transducers that vary their output voltage in response to the
detected magnetic field or flux.
In one embodiment a plurality of said sensor arrays are provided at spaced
locations on the body of the tus and, in one ment, each of the
sensor arrays are formed by triaXially configured sensors.
Typically, when a change in magnetic fluX is detected by at least one of the
sensors, analysis of the readings from the sensors in the sensor array
provides information showing the length, width and height components of
the feature, typically a defect, in the pipeline wall which has caused the
change in magnetic fluX which has been detected.
In one embodiment the apparatus includes a sensor to provide an tion
of the level of magnetic saturation of the pipeline wall. Typically, this sensor
WO 55995
is located in front of the sensor arrays with respect to the direction of
movement of the body along the pipeline or track on which the body is
mounted. The purpose of this sensor is to determine r or not the
pipeline wall is magnetically saturated and/or indicate when it is not
magnetically saturated.
In one embodiment this sensor is a Gaussmeter magnetic field sensor.
In a further embodiment the apparatus includes means to measure and/or
monitor the ce between the underside of the body of the apparatus
and the surface of the pipeline wall along the length of the pipeline wall that
the body is moved.
The provision of the distance measurement means allows the effects of pipe
wall surface roughness and/or corrosion to be taken into t as these
can introduce variations in the distance and hence the air gap between the
underside of the body and the pipeline wall e which, in turn, can
introduce signal noise in the inspection tool outputs, and errors in the sizing
of the detected s.
In one embodiment the distance measurement means es a wheel
which contacts the pipeline wall, a gearbox connected to the wheel and a
potentiometer.
In one embodiment, the apparatus is provided to be moved around and/or
along, a length of pipeline with changes in the magnetic flux and the g
means being monitored as the apparatus moves along the pipeline.
In one embodiment, the sensing means includes a proximity sensor which is
used to detect and determine a change in condition of the pipeline at, or
near to, the external surface of the pipeline.
In one embodiment, the apparatus is mounted, and may be provided
ally, on a track, with the track, in turn, being mounted along a section
of the pipeline which is to be monitored, said apparatus movable along the
track and the track and apparatus can be selectively positioned on the
pipeline. The track may be provided with one or more wheels to allow the
track to be transportable along with the apparatus mounted thereon.
In one embodiment the track can be oned at selected locations around
the circumference of the length of pipeline so as to allow the survey of the
pipeline to be completed for a previously identified portion of the pipeline.
In one embodiment the apparatus body is provided at a spaced distance
from the pipeline wall on which the same is provided to be moved along
and the body is provided with a plurality of members which extend from the
underside of the body to the al surface of the pipeline. Typically the
said members are provided in the form of bristles which are e along
their longitudinal axis.
Typically the bristles are provided to be sufficiently flexible to allow the
same to bend down onto the pipeline wall in at least one direction so as to
allow the body to be moved along the pipeline in at least one direction and
the bristles can then be maintained in contact with the pipeline.
lly the elongate members are provided to effectively “close” the air
gap between the underside of the body and the external surface of the
pipeline and thereby increase the y for the magnetic flux levels achieved
by the apparatus to be increased and hence increase the possibility of
achieving magnetic saturation of even thicker and/or larger pipeline walls.
This, in turn, allows the accuracy of the data which is obtained to be
increased.
In a yet further aspect of the invention there is provided apparatus for the
analysis of the condition of at least part of a pipeline wall, said tus
mountable on the al e of the pipeline and including a body,
means for inducing a magnetic flux into and at least partially through the
wall of the pipeline adjacent the location of the apparatus and a means for
providing data relating to the said pipeline wall condition and characterized
in that the apparatus includes a sensor to measure the extent to which the
ne wall is saturated by the magnetic flux which is generated.
In one embodiment sensors are provided in at least one triaxially mounted
sensor array to measure changes in the level of magnetic flux tion as
the apparatus is moved along the pipeline wall.
In a further aspect of the invention there is provided a method for the
analysis and detection of changes in condition of at least a portion of a
pipeline wall, said method comprising the steps of moving apparatus
containing a magnetic flux inductor and sensing means along and/or around
a portion of pipeline, inducing a magnetic flux into the pipeline wall,
monitoring the readings from the magnetic flux g means, identifying
changes in the magnetic flux from data received from the sensing means to
fy a change in ion of the pipeline wall and wherein the sensing
means includes at least one sensor array including a plurality of sensors for
ing the magnetic flux.
In one embodiment the sensor array comprises there sensors each mounted
to be angularly offset from the other sensors in the array.
In one embodiment the sensor array comprises three sensors configured to
provide data relating to the magnetic flux along three axes. Typically the
three axes are such as to e data relating the length, width and height
of the defect which is detected in the ne wall.
In one embodiment the method es retrieving data from detection
means which also es at least one proximity sensor which is used to
monitor the change in condition of the external pipeline so changes in the
material structure on or near the external surface can be differentiated from
changes in condition on the internal surface of the pipeline and hence an
accurate indication of the location of the change in condition of the pipeline
al is provided. Furthermore, the extent of change in the proximity
WO 55995
sensor and also extent of change of magnetic flux can be used to determine
the size and depth of the change in condition.
In one embodiment, the pipeline is made from cast iron and the proximity
sensor indicates the existence of areas of graphite rather than cast iron
material on or near the external surface of the pipeline which would not
otherwise be detectable.
Over time, the method includes the step of building a history of faults and
defects which are ented by particular detected magnetic flux changes
and/or proximity sensor changes and, in the subsequent analysis of new
s of pipeline, reference is made to the historic data to reach a
conclusion as to the type and effect of the change in condition represented
by detected readings.
In one embodiment ultrasonic readings are performed at a number of
locations on the pipeline wall to allow wall thickness outliers to be removed,
and local wall thickness patterns to be used in the defect sizing thms
d to the magnetic tool outputs.
TYPically the data generated from the sensor arrays is Processed by
processing means using algorithms to ine the teristics of the
pipeline which are represented by the data ed by the sensors.
The use of the sensor arrays, such as the tri—axial sensor array, improves the
accuracy of the pipeline inspection which is achieved and, in particular
improves the inspection capability in relation to relatively thick walled
pipeline and yet further when investigating corrosion on the inner wall face
of the pipeline.
In one embodiment faults which have been ed as being internally
located faults and which are regarded as lying outside the expected statistical
n, are identified and an ultrasonic scanner is provided to the location
of these faults. From the scan generated from the data from the ultrasonic
scanner it can then be identified whether the fault lies on the surface of the
al wall of the pipeline or does in fact lie within the pipeline wall and
which is therefore indicative of a fault in the form of a void or slag ion
and the same can then be accurately assessed.
Specific embodiments of the invention with reference to the accompanying
Figures; wherein
Figures 1a and b illustrate the apparatus of the ion in on on a
pipeline in order to survey the same;
Figure 2 illustrates the tus of Figures 1a and b in greater detail and in
section;
Figures 3 and 4 illustrate the information which is received from a sensor
array in accordance with one embodiment of the invention;
Figure 5 illustrates the sensor array which provides the information
illustrated in Figures 3 and 4;
Figure 6 illustrates a scan plot which can be achieved using the sensor arrays
in accordance with one embodiment of the invention; and
Figure 7 indicates the pipeline life estimation calculated in accordance with
one embodiment of the invention.
The invention is related to the provision of tus and a method to allow
the detection of changes in condition of the wall of a pipeline to be
determined accurately and allow data to be provided which allows the
ongoing accurate analysis of the ion of the pipeline wall to be
achieved. This can be difficult to e especially with cast iron pipelines
and yet further with regard to pipelines which have relatively thick walls.
Cast iron material has a number of non—metallic inclusions which can mask
r defect signals and therefore make it difficult to accurately and
reliably detect defects and the metallurgy of these pipes can vary between
pipes and across the pipe n thickness. The internal non—metallic
inclusions and voids can potentially be identified as internal defects and so it
will be appreciated that the accurate detection of defects has conventionally
been a significant problem. Furthermore, thick wall pipes are more difficult
to fully magnetically saturate and this can result in a reduced repeatability in
defect sizing and the wall thickness itself can vary significantly in thick wall
castings due to large surface larities and eccentrically cast pipe. Also,
differences in e condition, including relatively large areas of shallow
ion, can influence inspection tool outputs and sizing algorithms and
ion on the outer face of the pipe can increase the air gap between the
inspection heads and the pipe wall in the magnetic circuit.
It is known to be able to utilise mathematical techniques process data from
detection apparatus in order to try and allow as accurate a survey of the
pipeline wall ion to be provided as possible. However, in each case,
the same is reliant upon the accuracy of the initial detection data and
therefore the apparatus and method as now described has an aim of trying
to identify the means to provide the more accurate data which can
subsequently be processed.
Figure 1b illustrates in a schematic manner a length of pipeline 4 with the
ion of apparatus 2 in accordance with the invention. The end
elevation of Figure la shows the apparatus 2 provided in location with
regard to part of the pipeline 4 and the tus is provided to allow a
survey of the ion of at least a portion of the pipeline wall to be
achieved. The apparatus is provided with a body 6 which is located on a
track or frame 8 which is located with the pipeline in a fixed manner. The
body 6 is then provided to be le along the track or frame, in this case
towards the viewer of the Figure la, and typically along the longitudinal axis
of the track 8 as indicated by the arrow 10 in Figures 1b and 2 in order to
allow the survey to be performed.
Figure 2 illustrates the body 6 of the apparatus in more detail in accordance
with the ion. The body is ed with slides 12 which includes a
plurality of rollers 14 which engage with the said track or frame 8 (not
shown in Figure 2) and which allow the body to be moved along the same
in the direction 10.
There is provided an air gap 18 between the underside of the body 6 and the
external face 22 of the pipeline 4. It is found that this air gap can mean that
magnetic saturation is not achieved through the depth of the pipeline wall
and this can introduce errors when defect sizing algorithms are utilised using
the data form the apparatus. Where saturation is not achieved then ng
out calibration scans on pipes of the same pipe wall thickness with
ed defects, can improve sizing accuracy and, since the inspection
data is held after reporting, this can be carried out retrospectively. However
in order to further improve the survey as it occurs, the body 6, as shown in
Figure 2, is provided with a sensing means 21 mounted in advance of the
same with regard to the direction of nt 10. This sensing means,
lly a Gaussmeter, detects whether or not the pipeline wall is saturated
and monitors the same as the body is moved along the pipeline wall.
The provision of the additional sensor 21 to measure the pipeline wall
magnetic fluX saturation allows a feedback loop to be ed to optimise
the ed electro—magnetic coil current, based on controlling the level of
the air—coupled flux running parallel to the pipe wall. The sensor 21 is
mounted in a non ferrous cover directly in front of the inspection head 23
and at the appropriate orientation to measure the air d flux running
parallel to the pipeline wall.
In on, or alternatively, and not shown, a series of elongate members in
the form of bristles can be provided to depend outwardly from the tool
body and towards the external face of the pipeline wall 22 to contact the
same. The inclusion of the bristles eliminates the air gaps between the
magnetic poles of the flux inducing means in the body and hence allow
higher saturation of the pipeline wall to be achieved and hence improve
saturation through the portion of the pipeline wall which is being surveyed.
The apparatus shown in Figure 2 provides two shoes 24,26 for inducing the
magnetic field from one of the shoes 24 into the pipeline wall and then back
through the shoe 26. Typically the shoes are connected to electromagnets
provided in the apparatus which allow the ic field to be induced and
typically the dimension of the shoes are such as to be substantially the same
width as the omagnets so as to reduce the air flux ce.
It is also necessary to allow the shoes to be changed so as to allow the
apparatus to be d to be used with pipelines of differing diameters
and/or to allow s to be d and replaced as required. In order to
accommodate this and allow the change to be made relatively quickly, the
apparatus, in one embodiment, is provided in connection with the frame 8
along which the same travels and the frame can simply be turned over and
access gained to replace the shoes and/or sensors as required. This avoids
the conventional need of having to substantially dismantle the apparatus to
achieve the s and/or to perform general maintenance.
There is illustrated in Figure 5 two sensor arrays 30, 30’ which are provided
within the body 6 and at the inspection head 23. The sensors provided in
each array are typically Hall effect sensors, which allow the detection of the
magnetic flux in the pipeline wall which ies the inspection head 23
and detects changes in the same in order to allow the data ore to be
used to indicate the presence of defects in the pipeline wall. In accordance
with the invention, each sensor array 30 includes three Hall sensors,
32,34,36 as shown in Figure 5. It will be seen that the respective longitudinal
axes 38, 40,42 of each of the sensors is arranged at a 90 degrees offset with
respect to the other sensors in the array and this allows a three dimensional
array of data signals to be received from the combination of sensors in each
sensor array.
The three dimensional data s which are received from the s in
each array are illustrated in Figure 3. Figure 3a indicates the plot obtained
from data from a sensor in the array for along the pipeline in the direction
of arrow 39, Figure 3b indicates the circumferential plot obtained from the
data from the sensor array in the direction of arrow 41 and Figure 3c
indicates the transverse plot obtained from data from the sensor array in the
direction of arrow 43, all with respect to the pipeline which is being analysed
and the length of which extends parallel with the arrow 39.
In Figure 4 there is rated on the right hand side the graphical plots
received from the sensor array 30 in accordance with the invention and on
the left hand side, a single graphical plot which would received from a
conventional, single Hall effect sensor containing apparatus and so it is seen
by providing the triaXial sensor array of the current invention so a
significantly greater level of detail can be provided and therefore a finer
granularity of is and detection of the s in the pipeline. Each
sensor array 30, in this embodiment, provides three signal outputs which,
when a defect is detected as eXisting in the pipeline wall due to changes in
the detected magnetic flux, also then allow the length, width and height of
the defect to be identified from the three different aXial data readings
obtained from the sensors in the array. As the sensors in each array are
closely located each sensor in the array will pass in the same plane through
the magnetic flux “bulge” which is created when a defect in the pipeline wall
is present and so the sensors provide data which relate to the length, width
and height of the “bulge” respectively. Analysis re can then be used to
take into account the slight longitudinal offset of the three sensors positions
in the array and any effect that this has on the reading from the respective
sensors.
The ion of the sensor arrays in accordance with the invention greatly
improves defect identification and the subsequent accuracy of the defect
sizing processes. The provision in each array of the sensors being installed at
different angles to the ic flux and, in particular to the flux conditions
when a defect is present in the ne wall, provides a greater level of
information on magnetic flux leakage patterns. An example of this is
illustrated in the plot illustrated in Figure 6 which relates to and is identified
as a vely long, narrow, defect in the ne wall in accordance with the
invention.
Thus, the provision of the sensor arrays provides improvement in the
signals obtained as a result of the displaced flux ing from pipe wall
defects by allowing the measurement of depth, width and length and this, in
conjunction with the proximity sensors, which allow the fication of
whether the identified defect is on internal or external e of the
pipeline wall provides a significant improvement in the accuracy of the data
which is obtained. The proximity sensor 44 is shown in Figure 5 and this
allows the determination of whether the defect detected by the sensors array
is located on the exterior or interior of the pipeline wall as if the
proximity sensor changes then the defect is deemed to be at the external
surface of the pipeline wall and if the defect is identified by the sensor array
as being present but the proximity sensor condition does not change then
the defect is determined to be internal or at the internal face of the pipeline
wall. In either case the data from the sensors in the sensor array can be used
to determined, the length, width and depth of the defect.
In one embodiment there is the possibility that a fault in the pipeline wall
which is ed may be indicated as being located on the interior surface
of the wall whereas in fact the fault is actually within the wall. This is most
likely to occur when the tus is used for the ion of faults in
relatively thick walled pipes. In this case, once the analysis using the
apparatus as herein described has been performed, faults which have been
detected and which are regarded as lying outside the ed statistical
pattern, are identified and an ultrasonic scanner is provided to the on
of these faults. From the scan generated from the data from the ultrasonic
scanner it can then be identified whether the fault lies on the surface of the
internal wall of the pipeline or does in fact lie within the pipeline wall and
which is therefore indicative of a fault in the form of a void or slag inclusion
and the same can then be tely assessed.
WO 55995
In one embodiment, when the apparatus is to be used in relatively
hazardous pipeline analysis such as nes used to carry gas, the electrical
safety is paramount. In this case the apparatus is provided such that there
are no electrical connectors directly d on the body of the tool and
instead a socket may be provided at the end of the track of the apparatus
with which a connector ted to the power supply can be connected
and locked in position. This allows the cable to be supplied to the body as
required but with no electrical connections provided on the body.
Furthermore the body itself can be provided with a cavity in which the
electronic processing and control apparatus is d and said cavity is
purged with a gas such as hydrogen and maintained with hydrogen therein
so as to prevent the risk of sparks or other combustion occurring and
thereby allowing the apparatus to be used in hazardous nments.
With respect to the analysis of the data which has been obtained using the
apparatus, the same can be used to determine an estimate of the likely
lifetime of the pipeline which has been monitored. The failure can be
considered to occur when the corrosion has proceeded to an extent that the
average remaining wall thickness in a pipeline n has reduced to the
critical thickness depth tc. The corrosion process for the pipeline can then
be modelled as an extreme value distribution, based on observed pits or
faults over a 1 meter length. The user can then select to model Pit depth
growth rates as a power law say proportional to the timeAO.5 and the pit
width growth rates may also be modelled, and a linear rate directly
proportional to time can be applied. When a distribution model has been
fitted to the data, it may be applied to calculate the total number of pits of
each depth within an area of st, say a 1 metre length.
Using the equation: I/k
The width and volume of all these pits may be estimated, and the total
volume of material lost to corrosion derived. This volume, applied over the
area of the 1 metre length gives an estimate of net wall thickness loss. This
calculation can be applied at times into the future to estimate the likely
increase in pit size and total corroded volume. Eventually so much material
is lost that the average wall thickness of the 1 meter length is predicted to
reach the critical wall thickness everywhere.
The table below shows a model generated using data ed from the
monitoring of a pipeline length and the model orates a depth
ion rate timeAO.5 and width corrosion rate which is linear with time.
age of pipe at pit depths estimated pit Approximate Estimated radius of estimated volume total volume of pits
which total pit to be count at each number of pits, based on linear each pit assumed of that depth
corrosion to be counted depth pits of this corrosion rate with conical (1/3 pi r42
assessed depth time h)mm/‘3
1 400.0 88.5 6 42 3707
1.5 311.5 68.9 9 141 9745
2 242.6 53.7 13 335 17991
2.5 188.9 41.8 16 654 27368
3 147.1 32.6 19 1131 36831
3.5 114.5 25.4 22 1796 45546
4 89.2 19.7 25 2681 52942
4.5 69.4 15.4 28 3817 58696
54.0 12.0 32 5236 62690
.5 42.1 9.3 35 6969 64963
6 32.7 7.3 38 9048 65659
6.5 25.5 5.6 11503 64986
7 19.8 4.4 14368 63180
7.5 15.4 3.4 17671 60486
8 12.0 2.7 21447 57134
40 8.5 9.3 2.1 25724 53334
9 7.3 1.6 30536 49269
9.5 5.7 1.3 35914 45091
4.4 1.0 41888 40923
.5 3.4 0.8 48490 36860
11 2.7 0.6 55753 32973
11.5 2.1 0.5 63706 29311
12 1.6 0.4 723 82 25907
12.5 1.3 0.3 81812 22778
13 1.0 1.0 92028 89611
13.5 0.8 0.8 103060 78035
14 0.6 0.6 114940 67671
14.5 0.5 0.5 127701 58456
0.4 0.4 141372 50312
.5 0.3 0.3 155985 43156
16 0.2 0.2 171573 36900
16.5 188166
The calculations may be repeated at times into the future, giving the results
indicated in Figure 7. 1n the results shown in Figure 7 and the table above
the pipe wall is about 16 mm and tc about 10mm, so an e wall loss of
6mm would indicate failure, in 2035. So in summary, failure may be
predicted based on the integration of all ted pit corrosion over the 1
meter length. Extrapolation over longer lengths will give much the same
result, because we are looking at a process more related to the ge’
condition of the asset, estimating the arrival at a state where the entire pipe
area is substantially degraded. It should also be noted that while the average
value does not change as more samples are analysed the estimate of the
e improves, whereas the likelihood of a single deep value ing,
does increase as more surface is considered.
There is therefore provided in accordance wit the invention apparatus which
can be used to provide accurate detection of s in pipeline walls
Without the need to place the apparatus internally of the pipeline.
Claims (17)
1. Apparatus for detection of the condition of at least part of a pipeline wall, said apparatus comprising: a track on the external surface of the pipeline and on which a body is mountable and moveable therealong, said body, including a first shoe for inducing a magnetic flux into an air gap between the underside of the body and the external face of the pipeline, and at least partially through, the wall of the pipeline adjacent the location of the apparatus and then back through a second shoe of the body, spaced from the first shoe, and processing means for providing data relating to the magnetic flux in the wall of said pipeline at different locations of the pipeline wall as the apparatus is moved with respect thereto and a proximity sensor to detect and determine a change in condition of the ne at, or near to, the al surface of the pipeline and said processing means including a plurality of sensor arrays within the body and at an inspection head located such that the magnetic flux induced into the pipeline wall underlies the inspection head, each of said sensor arrays including three sensors ured in a tri-axial sensor array to detect ion in magnetic flux in at least three axes with regard to the wall of the pipeline at the said different locations in order to provide data representative of the condition of the wall of the pipeline.
2. Apparatus according to claim 1 wherein the said sensors are offset by 90 degrees with respect to each other on the body such that the s in each array are located so as to provide measurements with respect to the longitudinal axis, circumferentially and radially respectively relative to the pipe.
3. tus according to any one of the preceding claims wherein the sensors used in the plurality of sensor arrays are Hall effect sensors.
4. tus according to claim 1 wherein the plurality of sensor arrays are ed at spaced locations on the body of the apparatus.
5. Apparatus according to claim 1 wherein the data from the sensors is passed to the processing means for is and changes in the data is used to provide information showing the length, width and height components of a defect detected in the pipeline wall which has caused the change in magnetic flux data.
6. Apparatus according to any one of the preceding claims n the apparatus includes a sensor to provide an indication of the level of magnetic flux saturation of the pipeline wall.
7. Apparatus according to claim 6 wherein the said sensor is located n an end of the body and the tri-axial sensor array.
8. Apparatus according to claim 6 wherein the said sensor is a Gaussmeter magnetic field sensor.
9. Apparatus ing to claim 1 wherein the apparatus includes means to measure and/or monitor the distance between the underside of the body of the apparatus and an external surface of the pipeline wall and detect variations in the distance and air gap between the underside of the body and the pipeline wall.
10. Apparatus according to claim 9 wherein the ce ement means includes a wheel which contacts the ne wall, a gearbox connected to the wheel and a potentiometer.
11. Apparatus according to claim 1 wherein the track is provided with one or more wheels to allow the track to be transportable along with the apparatus mounted thereon.
12. A method for detection of s in condition of at least a portion of a pipeline wall, said method comprising the steps of: moving apparatus containing a ic flux inductor and sensing means along and/or around a track mounted on the portion of pipeline; inducing a magnetic flux into an air gap between the underside of the body and the external face of the pipeline, and at least partially through the wall of the pipeline nt the location of the apparatus and then back through a second shoe of the body, spaced from the first shoe, the pipeline wall; ring the readings from the magnetic flux sensing means; and identifying changes in the magnetic flux from data received from the sensing means to fy a change in condition of the pipeline wall and wherein the sensing means includes a ity sensor and at least first and second sensor arrays, each including at least three sensors mounted in a tri-axial array for detecting magnetic flux and n said method includes the further step of using the sensing means to perform a calibration scan on another pipe of the same pipe wall thickness at the said portion of the pipeline wall.
13. A method according to claim 12 n each sensor array provides data relating to the magnetic flux along three axes to provide data relating to the length, width and height of a defect which is detected in the pipeline wall.
14. A method according to claim 12 wherein the method includes retrieving data from detection means which also includes at least one proximity sensor which is used to monitor the change in condition of the external ne so changes in the changes in condition on the internal surface of the pipeline and hence an accurate indication of the location of the change in condition of the pipeline al is provided.
15. A method according to claim 14 wherein the extent of change in the proximity sensor and also extent of change of magnetic flux can be used to determine the size and depth of the change in condition.
16. A method according to any of claims 12-15 wherein a history of faults and defects which are represented by particular detected magnetic flux changes and/or proximity sensor changes is built and, with respect to new samples of pipeline, nce is made to the historic data to reach a conclusion as to the type and effect of the change in condition represented by detected readings.
17. A method according to claim 12 wherein the apparatus is moved around and/or along, a length of pipeline with s in the magnetic flux and the sensing means being monitored as the apparatus moves around and/or along the pipeline.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GBGB1318096.3A GB201318096D0 (en) | 2013-10-14 | 2013-10-14 | Pipeline condition detecting apparatus and method |
GB1318096.3 | 2013-10-14 | ||
PCT/GB2014/053080 WO2015055995A2 (en) | 2013-10-14 | 2014-10-14 | Pipeline condition detecting apparatus and method |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ718610A NZ718610A (en) | 2021-06-25 |
NZ718610B2 true NZ718610B2 (en) | 2021-09-28 |
Family
ID=
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CA2926159C (en) | Pipeline condition detecting apparatus and method | |
US6967478B2 (en) | Pipe condition detecting apparatus | |
US8542127B1 (en) | Apparatus for the non-contact metallic constructions assessment | |
US9581567B2 (en) | System and method for inspecting subsea vertical pipeline | |
EP2808677B1 (en) | Method for non-contact metallic constructions assessment | |
US8447532B1 (en) | Metallic constructions integrity assessment and maintenance planning method | |
US10330641B2 (en) | Metallic constructions monitoring and assessment in unstable zones of the earth's crust | |
US20100300184A1 (en) | Pipeline Condition Detecting Method and Apparatus | |
KR101843890B1 (en) | Apparatus for Diagnosis Defect of Steel Structures and Weld | |
CA2991960C (en) | System and method for the prediction of leakage in a pipeline | |
CN102954997A (en) | Non-contact magnetic stress detection method for pipe defects | |
RU2719177C2 (en) | Inspection of pipe section and flaw detector | |
US20190178844A1 (en) | Differential magnetic evaluation for pipeline inspection | |
JP4742600B2 (en) | Internal defect measurement method and apparatus | |
Sukhorukov | Magnetic flux leakage testing method: Strong or weak magnetization? | |
KR101226465B1 (en) | Non destructive inspection apparatus and its method for measurement of accumulated oxide scale | |
NZ718610B2 (en) | Pipeline condition detecting apparatus and method | |
RU2536778C1 (en) | Method of detection of local defects of metal of buried pipeline | |
JP5013363B2 (en) | Nondestructive inspection equipment | |
KR20190123893A (en) | Residual Stress Measurement Apparatus for Tubular Type Electric Power Transmission Tower | |
JP2004294341A (en) | Flaw detection method and flaw detection apparatus by pulsed remote field eddy current | |
JP2004085347A (en) | Method for evaluating life of heat-resistant steel | |
WO2015194428A1 (en) | Non-destructive inspection device and non-destructive inspection method | |
Rempel | Anomaly detection using magnetic flux leakage technology | |
Maxfield et al. | Tool Tolerances in MFL In-Line Inspection and Why They’re Needed |