ISO 18211:2016

DRAFT INTERNATIONAL STANDARD ISO/DIS 18211.2
Secretariat: IIW
Voting begins on Voting terminates on

2015-06-29 2015-08-29
INTERNATIONAL ORGANIZATION FOR STANDARDIZATION    МЕЖДУНАРОДНАЯ ОРГАНИЗАЦИЯ ПО СТАНДАРТИЗАЦИИ    ORGANISATION INTERNATIONALE DE NORMALISATION


Non-destructive testing — Long range inspection of above
ground pipelines and plant piping using guided wave testing
with axial propagation

Titre manque
Partie #: Titre de la partie
ICS 19.100











Member bodies are requested to consult relevant national interests in ISO/TC 44/SC ## before
returning their ballot to the ISO Central Secretariat.

This draft International Standard is submitted to all ISO member bodies for voting, as a
standard prepared by an international standardizing body in accordance with Council
Resolution 42/1999. The proposer, the International Institute of Welding (IIW), has been
recognized by the ISO Council as an international standardizing body for the purpose of
Council Resolution 42/1999.

To expedite distribution, this document is circulated as received from the committee
secretariat. ISO Central Secretariat work of editing and text composition will be undertaken at
publication stage.

THIS DOCUMENT IS A DRAFT CIRCULATED FOR COMMENT AND APPROVAL. IT IS THEREFORE SUBJECT TO CHANGE AND MAY NOT BE
REFERRED TO AS AN INTERNATIONAL STANDARD UNTIL PUBLISHED AS SUCH.
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DRAFT INTERNATIONAL STANDARDS MAY ON OCCASION HAVE TO BE CONSIDERED IN THE LIGHT OF THEIR POTENTIAL TO BECOME
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©  International Organization for Standardization, 2015

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ISO/DIS 18211.2

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©  ISO 2015
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ISO/DIS 18211.2
Contents Page
Foreword . iv
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Test personnel . 3
5 General . 3
6 Factors influencing GWT performance . 4
6.1 External diameter . 4
6.2 Pipeline geometry . 4
6.3 Test range . 4
6.4 Road crossing . 5
7 Test equipment . 5
7.1 General . 5
7.2 Probe ring . 5
7.3 Signal processing and analysis system . 6
7.4 Periodic verification of equipment performance . 6
7.5 Settings . 6
8 Test procedure . 6
9 Requirements for test data quality . 7
10 Testing . 7
10.1 Preparation of the test object . 7
10.1.1 Surface temperature . 7
10.1.2 Removal of insulation . 7
10.1.3 Wall thickness assessment . 8
10.1.4 Surface preparation . 8
10.2 Probe ring test position . 8
10.3 Data Collection . 8
10.4 Reporting sensitivity . 8
10.5 Data interpretation . 9
10.6 Detection sensitivity . 9
10.7 Visual confirmation . 9
11 Complementary NDT to support the GWT . 9
12 Test report . 10
Annex A (informative) Selection of guided wave modes . 11
Bibliography . 15

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ISO/DIS 18211.2
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the
International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2.
The main task of technical committees is to prepare International Standards. Draft International Standards
adopted by the technical committees are circulated to the member bodies for voting. Publication as an
International Standard requires approval by at least 75 % of the member bodies casting a vote.
Attention is drawn to the possibility that some of the elements of this document may be the subject of patent
rights. ISO shall not be held responsible for identifying any or all such patent rights.
ISO 18211 was prepared by IIW, the International Institute of Welding.

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DRAFT INTERNATIONAL STANDARD ISO/DIS 18211.2

Non-destructive testing — Long range Inspection of above
ground pipelines and plant piping using guided wave testing
with axial propagation
1 Scope
This International Standard specifies a method for long range testing of carbon and low alloy steel above
ground pipelines and plant piping using guided ultrasonic waves with axial propagation applied on the entire
circumferential pipe section, in order to detect corrosion or erosion damage.
The Guided Wave Testing (GWT) technique allows for fast inspection of above ground pipelines, plant piping
and cased road crossings, giving a qualitative screening and localization of probable corroded and eroded
areas. GWT is typically performed on operating piping systems.
This International Standard can be applied to the following types of pipes:
a) above ground painted pipelines;
b) above ground insulated pipelines;
c) pipe sections within road crossings with external casing (without bitumen or plastic coating);
d) painted plant piping;
e) insulated plant piping.
Other types of pipes not included in the above list need dedicated approaches due to increased complexity.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced
document (including any amendments) applies.
ISO 9712, Non-destructive testing – Qualification and certification of personnel
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
3.1
axial direction
the direction along the main axis of the pipe
3.2
circumferential direction
the direction around the circumference of the pipe
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ISO/DIS 18211.2
3.3
total pipe wall cross-section (TCS)
the area between the inner and outer diameters of the pipe in a plane perpendicular to the pipe axis
3.4
cross-section change
the equivalent cross-section change calculated assuming that an indication is purely caused by a change in
the cross-section of the pipe wall
3.5
datum point
reference point for reporting a test position and for correlating test results with the corresponding position on
the test object
3.6
dead zone
length of pipe on either side of the test position where reflectors of interest cannot be detected because they
are covered by the transmitted pulse
3.7
flexural mode
a non-symmetric bending type mode of guided wave propagation in pipes, with particle displacements in axial,
circumferential and radial directions
3.8
focus
concentration of guided waves at a single axial and circumferential position, achieved either by hardware
settings or by post-processing of a recorded set of signals (synthetic focus)
3.9
geometric feature
pipeline feature (i.e. weld, support, flange, bend, etc.) causing the reflection of guided waves because of a
cross section change or other acoustic impedance variation
3.10
guided wave mode
distinct type of guided wave with a specific vibration pattern
3.11
longitudinal mode
a symmetric compression type mode of guided wave propagation in pipes, with particle displacements
predominantly in the axial direction
3.12
primary mode
guided wave mode which is chosen for the incident wave
3.13
probe ring
circumferential component, containing transducer elements with direct contact to the pipe
3.14
secondary mode
guided wave mode which is different from the primary mode and is generated by mode conversion at pipe
features or discontinuities
3.15
test frequency
centre frequency of the pulses transmitted by the probe ring
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ISO/DIS 18211.2
3.16
test position
axial position on the pipe where the probe ring is place
3.17
test range
the distance between the test position and the furthest position for which the minimum acceptable sensitivity
of the reference signal is achieved, in each direction (positive or negative)
3.18
torsional mode
a symmetric twisting type mode of guided wave propagation in pipes, with particle displacements in the
circumferential direction

4 Test personnel
The personnel performing ultrasonic guided wave testing shall be qualified in accordance with ISO 9712 or
with any another equivalent standard of the relevant industrial sector.
Training in the use of the specific equipment is required because there are significant differences between the
available systems and diagnostic approaches.
5 General
Ultrasonic Guided Wave Testing (GWT) uses elastic waves which are guided along the pipe wall and can
travel long distances, thus providing rapid near complete coverage of the volume of the pipe wall.
The typical test setup is comparable to conventional ultrasonic pulse-echo testing: an ultrasonic instrument
forces transducers in the probe ring to generate ultrasonic waves in the pipe wall which are reflected by
discontinuities and received by the same probe ring. The time-of-flight of the received signal indicates the
distance between the discontinuities and the probe ring. A single test with guided waves can cover a length of
pipe of tens of meters.
Within this standard, GWT is performed as a screening method. The reflections returning from discontinuities
and received by the ultrasonic instrument indicate the position of the discontinuity. However, they do not give
detailed quantitative information about its morphology. Therefore, GWT is used to indicate any locations which
need to be followed up with complementary detailed inspection. More information on the nature of guided
waves is given in Annex A.
Within this standard, GWT typically uses a frequency range between 20 kHz and 500 kHz. If the performance
of the test has been shown to have equal or better sensitivity to that obtained with the frequency range
specified above, a frequency lower than 20 kHz can be used for GWT.
The successful application of guided ultrasonic waves requires:
a) selective pure mode transmission and reception;
b) wave modes which are non dispersive in the frequency range used;
c) coverage of the full cross section of the pipe wall;
d) signals coming from each direction shall be distinguished.
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ISO/DIS 18211.2
The amplitude of a reflected ultrasonic guided wave signal from a discontinuity varies in a complex manner
that depends on many factors such as test frequency, guided wave mode and the specific morphology of the
discontinuity. It is often possible to correlate the size of the reflected signal with the overall cross section
change in the pipe wall resulting from wall loss, meaning that GWT can qualitatively group discontinuities into
different severity groups such as indications of low, medium and high concern. However, usually the
parameter of interest when testing piping systems with wall loss is the remaining wall thickness in areas with
discontinuities, which GWT cannot accurately provide (see Annex A for more information).
It is recommended to perform ultrasonic guided wave testing using a range of frequencies to improve the
accuracy of the test. Also, GWT ultrasonic instruments often employ advanced approaches like focusing or
synthetic focusing to improve the sensitivity and discontinuity sizing ability of GWT. The use of these is not
specified in this standard, but background information is provided in Annex A.
6 Factors influencing GWT performance
6.1 External diameter
The sensitivity of GWT depends on the cross section change. The absolute cross section change in a pipe
due to corrosion or erosion loss is measured in the units of area, and depends on both the depth and the
circumferential extent of the discontinuity. GWT is sensitive to a minimum percent of cross sectional loss,
which is a function of both the absolute cross section change and the pipe geometry. As an example, a
discontinuity in a small diameter pipe may represent a large percent change in cross section that is easily
detectable using GWT, but the same discontinuity in a large diameter pipe may represent a small cross
section change that cannot be detected using GWT. Because of this effective decrease in sensitivity as pipe
diameter increases, testing of pipes larger than DN 600 (24 inches diameter) can miss significant isolated
corrosion pits, so it is recommended that complementary NDT methods are used. When testing pipes where
the known damage mechanisms result in larger cross section changes rather than isolated pitting, GWT is still
recommended for rapid testing of pipes with diameters larger than DN600 (24 inches diameter).
6.2 Pipeline geometry
The complexity of the pipe geometry can limit guided wave propagation. Below are summarized the effects of
some common pipe features which can be present in the pipes listed in clause 1:
a) it is not possible to test beyond flanged joints or any breaks of the pipe because the guided waves
cannot propagate across them;
b) it is not permitted to test beyond an elbow fitting; instead the tool shall be moved to a test position on
the other side of the bend. Testing beyond ‘pulled’ bends, where a straight length of pipe is formed
into a curve of radius equal to 5 or more times the pipe diameter is permitted;
c) it is permitted to test beyond a branch or a tee only if the diameter of the branch is no greater than ½
the diameter of the pipe being tested. This restriction is to avoid problems with distortion of the
forward travelling guided wave by interactions with the branch;
d) it is not permitted to test beyond a support if the amplitude of reflection from it is higher than 6 dB
below the weld DAC curve. This restriction is to avoid problems of the distortion of the forward
travelling guided wave by interactions with the support.
6.3 Test range
The test range depends on many factors which are summarized below. In general, the test range is limited by
the signal/noise ratio (SNR) of the test data (see clause 9, item e).
a) geometrical features on the pipe attenuate and/or distort guided wave modes reducing test range;
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ISO/DIS 18211.2
b) the type of coating on the pipe can have a large effect on test range. Typically, insulation materials
like calcium silicate do not affect test range appreciably, but coatings like bitumen drastically reduce
test range by attenuating guided wave signals;
c) this standard only applies to above ground pipe, but buried pipe where there is soil in contact with the
pipe surface or pipe coating is a more difficult GWT application due to high attenuation and low signal
to noise;
d) the substance contained in the pipe effects test range, and it is a complex function depending on the
specific substance, ID corrosion products and the specific guided wave mode being used;
e) the presence of welds in the pipe cause reflections thereby attenuating the guided wave signal.
6.4 Road crossing
If performing GWT on a pipe passing through a road crossing with an external casing, achievement of the test
for the length of the crossing shall be proven by the test range including a reflection from a geometrical feature
(normally a weld) beyond the crossing, or a reflection from a geometrical feature (normally a weld) inside the
crossing that is identifiable from both sides of the crossing.
7 Test equipment
7.1 General
The test equipment consists of:
a) an ultrasonic instrument to generate and receive pulses in the frequency range from 20 kHz to 500
kHz;
b) a probe ring carrying transducers for the generation of guided wave modes;
c) a probe ring carrying transducers for the reception of reflected guided waves. It can be the same
probe ring used for generating guided wave modes;
d) an electronic system for recording, processing and analysing the reflected signals.
7.2 Probe ring
The transmitting probe ring shall be capable of generating the primary guided wave mode in isolation from
other possible modes of the pipe. If more than one wave mode is used, they should be used separately to
improve the reliability of the inspection.
The receiving probe ring shall be capable of separating the individual guided wave modes which are of
interest for the analysis and to suppress the undesired modes (see Annex A for more information).
There are three different types of transducers currently available to generate and receive guided ultrasonic
waves in pipes:
⎯ piezoelectric transducers;
⎯ electromagnetic acoustic transducers (EMAT);
⎯ magnetostrictive transducers.
These types of transducers are deployed on a probe ring which is placed around the pipe.
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ISO/DIS 18211.2
7.3 Signal processing and analysis system
The signal processing and analysis system shall produce its results in a form which can be recorded reliably
on a computer storage medium.
The results which are recorded shall be in a form such that the features in the results can be correlated to
physical locations on the piping system.
7.4 Periodic verification of equipment performance
The equipment shall be verified periodically, at intervals of no more than 12 months, to check its proper
functioning and performance, and any faults found shall be corrected.
This verification shall be performed in accordance with a dedicated written procedure following the
manufacturer's instructions.
7.5 Settings
If no relevant standards for equipment settings are available, the following minimum requirements shall be
met:
a) Frequency and signal settings
The settings which control the frequency and bandwidth of the signal shall be chosen to be appropriate for
specific relevant guided wave modes which have been selected according to the inspection procedure to be
used for the pipe under test.
b) Pulse repetition frequency
The pulse repetition frequency shall be set sufficiently low as to allow all signals to attenuate completely
between subsequent pulses.
8 Test procedure
GWT shall be performed according to a written test procedure, which shall include at least the following:
a) a reference to this standard;
b) background information (including standards, restrictions, safety requirements, etc.);
c) personnel qualification;
d) a description of the pipe to be tested;
e) range of the test;
f) access and environmental conditions;
g) surface preparation;
h) equipment used;
i) equipment parameters and functional testing;
j) parameters for data collection;
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k) parameters for evaluation of results;
l) complementary non-destructive testing;
m) reporting requirements;
n) recording of deviations from procedure.
9 Requirements for test data quality
The minimum requirements to assure the quality of the test data are:
a) Before testing, the whole combined test system shall be checked according to the specifications provided
by the manufacturer. If the GWT instrument performs self-checks, then the results of these shall be stored
with the recorded data. Any equipment deviations from allowed specification shall be rectified before
starting the test.
b) The tolerance of range setting shall be agreed between the parties (due to the long wavelength used for
GWT the tolerance on distance measurement is not likely to be better than ± 100 mm);
c) The probe ring coupling to the pipe surface shall be checked according to the procedures and thresholds
provided by the manufacturer. If the coupling is found not to meet the required specification, then the
surface preparation shall be improved, the probe ring re-applied and the data re-sampled.
d) If the equipment permits an absolute amplitude calibration, then it shall be used. Otherwise, calibration of
sensitivity, using knowledge of a well-characterised reflector, such as a girth weld, shall be used. The
calibration shall also include Distance Amplitude Correction (DAC) or Time Corrected Gain (TCG), in
order to compensate the calibration for axial position within the range of the test. DAC and TCG are to be
understood conceptually in the same manner as is established for conventional UT testing, as in
ISO 16811; a DAC provides a constant level of sensitivity as a function of range, allowing reflections at
varying ranges to be compared in a consistent manner to a known reference level. The calibration shall
be set according to the instructions provided by the manufacturer of the GWT equipment.
e) The signal-to-noise ratio shall be estimated according to the procedure provided by the manufacturer. For
adequate interpretation of the test data the signal-to-noise ratio shall be greater than 6 dB; small
amplitude signals below this value cannot be interpreted reliably and will lead to noise signals being
reported as discontinuities. The signal-to-noise ratio is used to determine the range of the test (see clause
6.3 for more information on test range).
10 Testing
10.1 Preparation of the test object
10.1.1 Surface temperature
The surface temperature of the pipe shall be within the operating range of the test equipment used.
10.1.2 Removal of insulation
Testing on insulated pipes requires the removal of circular bands of insulation at all the points where the probe
ring shall be positioned, and for a length sufficient to allow the fixing of the probe ring directly to the pipe
surface.
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10.1.3 Wall thickness assessment
Metal loss at the probe ring location affects the test performance of GWT. Visual testing and ultrasonic testing
shall be performed to assess the presence of external or internal metal loss. If metal loss is detected it is
recommended that the probe ring is attached to an alternative location. The wall thickness values shall be
recorded.
GWT does not provide inspection coverage in the dead zone. One way of providing 100% pipe inspection
coverage is to perform more than one guided wave test on a piping system where there is sufficient overlap
between tests to provide inspection coverage in all dead zones. If the dead zone is not inspected with GWT
using another test location, and if the dead zone must be tested, ultrasonic testing (or an alternative method)
shall be used.
10.1.4 Surface preparation
Testing on well adhered painted surfaces is normally satisfactory. Loose or flaking paint, superficial corrosion
products and other coatings shall be removed at the test location prior to attaching the probe ring if required to
achieve the data quality set out in clause 9, item e.
10.2 Probe ring test position
In a typical piping system, it is normal to require many different probe ring test positions to provide full
inspection coverage of the entire piping system. The choice of these locations for the probe ring is critical in
order to provide adequate inspection of the entire piping system (see clause 6.2 for more information). The
position(s) of the probe ring on the piping system shall be recorded with reference to a known physical datum
or on a piping drawing to allow repeatability.
10.3 Data Collection
Data shall be collected according to the instructions provided by the equipment manufacturer and to a
dedicated procedure. This procedure shall include instruction on the following:
a) ensuring proper probe ring coupling to the pipe surface;
b) ensuring proper electrical connection between system components;
c) setting test equipment parameters;
d) setting test equipment range;
e) setting test equipment sensitivity;
f) verifying data quality.
10.4 Reporting sensitivity
Prior to GWT data interpretation, DAC or TCG curves shall be applied to establish sensitivity using the
requirements in clause 9, item d. In practice, it is typically not possible to perform an absolute amplitude
cal
...