SR EN ISO 3452-1 (2021e PDF
SR EN ISO 3452-1 (2021e PDF
SR EN ISO 3452-1 (2021e PDF
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SR EN ISO 3452-1
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English Version
CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this
European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references
concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CEN
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member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by
translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management
Centre has the same status as the official versions.
CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,
Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway,
Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and
United Kingdom.
© 2021 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN ISO 3452-1:2021 E
worldwide for CEN national Members.
EN ISO 3452-1:2021 (E)
Contents Page
European foreword....................................................................................................................................................... 3
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2
EN ISO 3452-1:2021 (E)
European foreword
This document (EN ISO 3452-1:2021) has been prepared by Technical Committee ISO/TC 135 "Non-
destructive testing" in collaboration with Technical Committee CEN/TC 138 “Non-destructive testing”
the secretariat of which is held by AFNOR.
This European Standard shall be given the status of a national standard, either by publication of an
identical text or by endorsement, at the latest by December 2021, and conflicting national standards
shall be withdrawn at the latest by December 2021.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN shall not be held responsible for identifying any or all such patent rights.
According to the CEN-CENELEC Internal Regulations, the national standards organizations of the
following countries are bound to implement this European Standard: Austria, Belgium, Bulgaria,
Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland,
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Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Republic of
North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and the
United Kingdom.
Endorsement notice
The text of ISO 3452-1:2021 has been approved by CEN as EN ISO 3452-1:2021 without any
modification.
3
INTERNATIONAL ISO
STANDARD 3452-1
Third edition
2021-05
Reference number
ISO 3452-1:2021(E)
© ISO 2021
ISO 3452-1:2021(E)
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Contents Page
Foreword...........................................................................................................................................................................................................................................v
1 Scope.................................................................................................................................................................................................................................. 1
2 Normative references....................................................................................................................................................................................... 1
3 Terms and definitions...................................................................................................................................................................................... 1
4 Safety precautions............................................................................................................................................................................................... 2
5 General principles................................................................................................................................................................................................ 2
5.1 Personnel...................................................................................................................................................................................................... 2
5.2 Description of the method............................................................................................................................................................. 2
5.3 Process sequence................................................................................................................................................................................... 2
5.4 Equipment.................................................................................................................................................................................................... 3
5.5 Effectiveness.............................................................................................................................................................................................. 3
6 Products, sensitivity and designation............................................................................................................................................. 3
6.1 Product family.......................................................................................................................................................................................... 3
6.2 Testing products..................................................................................................................................................................................... 3
6.3 Sensitivity..................................................................................................................................................................................................... 3
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6.4 Designation................................................................................................................................................................................................. 4
7 Compatibility............................................................................................................................................................................................................. 4
7.1 General............................................................................................................................................................................................................ 4
7.2 Compatibility of penetrant testing products.................................................................................................................. 4
7.3 Compatibility of penetrant testing products and the material to be tested........................................ 4
8 Test procedure......................................................................................................................................................................................................... 5
8.1 Written test procedure...................................................................................................................................................................... 5
8.2 Precleaning.................................................................................................................................................................................................. 5
8.2.1 General...................................................................................................................................................................................... 5
8.2.2 Mechanical precleaning.............................................................................................................................................. 5
8.2.3 Chemical precleaning.................................................................................................................................................... 5
8.2.4 Drying......................................................................................................................................................................................... 5
8.3 Temperature............................................................................................................................................................................................... 5
8.4 Application of penetrant.................................................................................................................................................................. 6
8.4.1 Methods of application................................................................................................................................................ 6
8.4.2 Penetration time............................................................................................................................................................... 6
8.5 Excess penetrant removal.............................................................................................................................................................. 6
8.5.1 General...................................................................................................................................................................................... 6
8.5.2 Water........................................................................................................................................................................................... 6
8.5.3 Solvents..................................................................................................................................................................................... 6
8.5.4 Emulsifier................................................................................................................................................................................ 6
8.5.5 Water and solvent............................................................................................................................................................ 7
8.5.6 Excess penetrant removal check......................................................................................................................... 7
8.5.7 Drying after excess penetrant removal......................................................................................................... 7
8.6 Developing................................................................................................................................................................................................... 7
8.6.1 General...................................................................................................................................................................................... 7
8.6.2 Dry developer...................................................................................................................................................................... 8
8.6.3 Water-suspendable developer.............................................................................................................................. 8
8.6.4 Solvent-based developer............................................................................................................................................ 8
8.6.5 Water soluble developer............................................................................................................................................ 8
8.6.6 Water- or solvent-based for special application (e.g. peelable developer).................... 8
8.6.7 No developer (type I only)........................................................................................................................................ 8
8.7 Inspection..................................................................................................................................................................................................... 9
8.7.1 General...................................................................................................................................................................................... 9
8.7.2 Viewing conditions......................................................................................................................................................... 9
8.7.3 Wipe-off technique......................................................................................................................................................... 9
8.7.4 Recording............................................................................................................................................................................. 10
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.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
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. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
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constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to the
World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see www.iso.org/
iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 135, Non-destructive testing,
Subcommittee SC 2, Surface methods, in collaboration with the European Committee for Standardization
(CEN) Technical Committee CEN/TC 138, Non-destructive testing, in accordance with the Agreement on
technical cooperation between ISO and CEN (Vienna Agreement).
This third edition cancels and replaces the second edition (ISO 3452-1:2013) which has been technically
revised.
The main changes compared to the previous edition are as follows:
— clarification of understanding of product family;
— addition of the new procedure “no developer”;
— technical revision according to the state of the art.
A list of all parts in the ISO 3452 series can be found on the ISO website.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
1 Scope
This document specifies a method of penetrant testing used to detect discontinuities, e.g. cracks, laps,
folds, porosity and lack of fusion, which are open to the surface of the material to be tested using white
light or UV-A (365 nm) radiation. It is mainly applied to metallic materials, but can also be performed
on other materials, provided that they are inert to the test media and not excessively porous (castings,
forgings, welds, ceramics, etc.)
This document also includes requirements for process and control testing, but is not intended to be
used for acceptance criteria. It gives neither information relating to the suitability of individual test
systems for specific applications nor requirements for test equipment.
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NOTE 1 Methods for determining and monitoring the essential properties of penetrant testing products to be
used are specified in ISO 3452-2 and ISO 3452-3.
NOTE 2 The term "discontinuity" is used in this document in the sense that no evaluation concerning
acceptability or non-acceptability is included.
NOTE 3 CEN/TR 16638 addresses penetrant testing using actinic blue light.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements 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 3059, Non-destructive testing — Penetrant testing and magnetic particle testing — Viewing conditions
ISO 3452-2, Non-destructive testing — Penetrant testing — Part 2: Testing of penetrant materials
ISO 3452-3, Non-destructive testing — Penetrant testing — Part 3: Reference test blocks
ISO 3452-4, Non-destructive testing — Penetrant testing — Part 4: Equipment
ISO 3452-5, Non-destructive testing — Penetrant testing — Part 5: Penetrant testing at temperatures
higher than 50 degrees C
ISO 3452-6, Non-destructive testing — Penetrant testing — Part 6: Penetrant testing at temperatures
lower than 10 degrees C
ISO 12706, Non-destructive testing — Penetrant testing — Vocabulary
4 Safety precautions
As penetrant inspection techniques often require the use of harmful, flammable and/or volatile
materials, safety regulations (e.g. optical radiation legislation) shall be taken into account.
Prolonged or repeated contact of these materials with the skin or any mucous membrane should be
avoided. Working areas shall be adequately ventilated and sited away from sources of heat, sparks or
naked flames, taking into account all applicable safety regulations.
The penetrant testing products and equipment shall be used with care and always in compliance with
the instructions supplied by the manufacturer.
UV-A sources shall always be maintained in a good condition.
Care shall be taken to ensure the safe implementation of the method.
5 General principles
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5.1 Personnel
Testing shall be carried out by proficient, suitably trained and qualified personnel and, where applicable,
shall be supervised by competent personnel nominated by the employer or, by delegation of the
employer to the inspection company in charge of testing. To demonstrate appropriate qualification, it
is recommended that personnel be certified according to ISO 9712 or an equivalent formalized system.
Penetrant testing operations, unless otherwise agreed, shall be authorized by a competent supervisory
individual (Level 3 or equivalent) approved by the employer.
5.4 Equipment
The equipment used for carrying out penetrant testing depends on the number, size, weight and shape
of the parts to be tested. The equipment shall be as specified in ISO 3452-4.
5.5 Effectiveness
The effectiveness of the penetrant testing depends upon many factors, including
a) types of penetrant materials and testing equipment;
b) surface preparation and condition;
c) material under examination and expected discontinuities;
d) temperature of the test surface;
e) penetration and development time;
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f) viewing conditions.
Control checks shall be carried out to demonstrate that the correct testing parameters are used in
accordance with Annex B.
6.3 Sensitivity
Sensitivity levels shall be determined according to ISO 3452-2. By using specific product families,
different sensitivity levels may be achieved. ISO 3452-2 describes penetrant baseline sensitivity and
product family sensitivity.
6.4 Designation
The product family to be used for penetrant testing is given a designation comprising the type, the
method and the form for the testing products, and a figure which indicates the sensitivity level achieved
by testing according to ISO 3452-2.
EXAMPLE A product family comprising a fluorescent penetrant (I), water as the excess penetrant remover
(A), and a dry-powder developer (a), and having a system sensitivity of level 2 gives the following penetrant
testing system designation when using ISO 3452-1 and ISO 3452-2: product family ISO 3452-2, IAa Level 2.
7 Compatibility
7.1 General
The penetrant testing products shall be compatible with each other and the material to be tested. The
use for which the part or parts is designed shall also be considered.
7.3.1 In most cases the compatibility can be assessed prior to use by means of the corrosion tests
detailed in ISO 3452-2.
7.3.2 The wettability of the test surface using the selected penetrant testing product shall be
established before testing. When parts are not visible during penetrant application (e.g. automated
systems), the wettability of the penetrant on the test surface shall be visually checked before testing on a
representative sample.
7.3.3 The chemical or physical properties of some non-metallic materials can be adversely affected
by the penetrant testing products; their compatibility shall be established before inspecting parts
manufactured from, and assemblies that include, such materials.
7.3.4 In situations where contamination can occur, it is essential to ensure that the penetrant testing
products do not have a deleterious effect on fuels, lubricants, hydraulic fluids, etc.
7.3.5 For parts associated with peroxide rocket fuel, explosive stores (these include all items containing
explosive propellant, initiating or pyrotechnic materials), oxygen equipment or nuclear applications, the
compatibility of penetrant testing products shall be given special consideration.
8 Test procedure
8.2 Precleaning
8.2.1 General
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Contaminants such as scale, rust, oil, grease, paint and water shall be removed — if necessary using
mechanical or chemical methods, or a combination of these. Precleaning shall ensure that the test
surface is free from residues and that it allows the penetrant to enter any discontinuity. The cleaned
area shall be large enough to prevent interference from areas adjacent to the actual test surface.
Scale, slag, rust, etc. shall be removed using suitable methods such as brushing, rubbing, abrasion,
blasting or high-pressure blasting (water or ice pellets). These methods remove contaminants from the
surface and generally are incapable of removing contaminants from within surface discontinuities. In
all cases care shall be taken to ensure that the discontinuities are not masked by plastic deformation
or clogging from abrasive materials. If necessary to ensure that discontinuities are open to the surface,
subsequent etching treatment shall be carried out, followed by adequate rinsing and drying.
Chemical precleaning shall be carried out, using suitable chemical cleaning agents, to remove residues
such as grease, oil, paint or etching materials.
Residues from chemical precleaning processes can react with a penetrant and greatly reduce its
sensitivity. Therefore, chemical agents shall be removed from the surface under examination, after the
cleaning process, using suitable cleaning methods.
8.2.4 Drying
As the final stage of precleaning, the parts to be tested shall be thoroughly dried, so that neither water
nor solvent remains on the test surface and in the discontinuities.
8.3 Temperature
The testing materials, the test surface and the ambient temperature shall be within the range from
10 °C to 50 °C, except for the drying process (8.2.4). Rapid temperature changes can cause condensation,
which may interfere with the process and should be avoided.
For temperatures outside the range from 10 °C to 50 °C, inspection shall be carried out in accordance
with ISO 3452-5 or ISO 3452-6, as applicable.
Penetrant can be applied to the part to be tested by spraying, brushing, flooding, dipping or immersion.
Penetrant shall remain on the test surface throughout the entire penetration time.
The appropriate penetration time depends on the properties of the penetrant, the application
temperature, the material of the part to be tested and the discontinuities to be detected.
The penetration time shall be between 5 min and 60 min and shall not be less than the manufacturer's
recommended time for the required sensitivity. The penetration time shall be defined in the written
test procedure.
8.5.1 General
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The excess penetrant removal shall be such that penetrant remains in the discontinuities.
8.5.2 Water
When water is used for removal it shall be applied by wiping, immersion or spray. Care shall be
exercised to avoid overwashing for example by the use of high-pressure spray, excessive time or
excessive mechanical action. When wiping is used, excess penetrant shall be removed first by using
a suitable clean lint-free cloth or absorbent paper and subsequently by cleaning with a clean lint-free
cloth lightly moistened with water.
8.5.3 Solvents
Excess penetrant shall be removed first by using a suitable clean lint-free cloth or absorbent paper
and subsequently by using a clean lint-free cloth lightly moistened with solvent. Any other removal
technique shall be technically approved for adequacy and agreed by the contracting parties, particularly
when the solvent remover is sprayed directly onto the part to be tested.
8.5.4 Emulsifier
To allow the post-emulsifiable penetrant to be removed from the test surface, it shall be rendered water-
rinsable by application of an emulsifier. Before the application of the emulsifier, a water wash shall be
performed in order to remove the bulk of the excess penetrant from the test surface and facilitate a
uniform action of the hydrophilic emulsifier that will be applied subsequently.
The emulsifier shall be applied by immersion or by foam equipment. The concentration and the contact
time of the emulsifier shall be determined by the user through pre-tests. After emulsification, a final
wash shall be carried out in accordance with 8.5.2.
To allow the post-emulsifiable penetrant to be removed from the test surface, it shall be rendered water-
rinsable by application of an emulsifier. This can only be done by immersion. The emulsifier contact
time shall be evaluated by the user through pre-tests according to the manufacturer's instructions.
This time shall be sufficient to allow only the excess penetrant to be removed from the test surface
during the subsequent water wash. The emulsifying time given by the manufacturer shall not be
exceeded. Immediately after emulsification, a water wash shall be carried out in accordance with 8.5.2.
First, the excess water-washable penetrant shall be removed using water (see 8.5.2). Subsequently the
surface shall be wiped with a clean lint-free cloth, lightly moistened with solvent.
During excess penetrant removal, the test surface shall be checked for penetrant residues that may
affect interpretation.
Excess penetrant removal shall be carried out under the conditions specified in ISO 3059 to confirm
correct removal.
In order to facilitate rapid drying of excess water, any droplets and puddles of water shall be removed
from the part.
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Except when using water-based developer, the test surface shall be dried as quickly as possible after
excess penetrant removal, using one of the following methods:
a) wiping with a clean, dry, lint-free cloth;
b) evaporation at ambient temperature after hot water dip;
c) evaporation at elevated temperature;
d) forced air circulation;
e) a combination of methods a) to d).
If compressed air is used, particular care shall be taken to ensure that it is clean and does not affect any
penetrant bleed-back that may already have started. It is recommended that a maximum pressure of
200 kPa (2 bar) is used and a distance of around 300 mm or more is allowed between the nozzle and the
test surface.
If forced air circulation or a drier is used for drying, the air temperature shall not exceed 70 °C. The
drying time shall not lead to a surface temperature higher than 50 °C.
The method of drying the part to be tested shall be carried out such that the penetrant remaining in the
discontinuities does not dry.
8.6 Developing
8.6.1 General
The developer shall be maintained in a uniform condition during use and shall be evenly applied to the
test surface.
The application of the developer shall be carried out as soon as possible after the removal of excess
penetrant.
Care shall be exercised when using water-based developers with water-washable penetrants to avoid
removing further penetrant from the discontinuities.
The development time shall be defined in the written test procedure. The development times shall be
selected according to the application. The development time shall not be less than 10 min.
Dry developer may only be used with fluorescent penetrants. The developer shall be uniformly
applied to the test surface by one of the following techniques: dust storm, electrostatic spraying, flock
gun, fluidized bed or storm cabinet. The test surface shall be thinly covered by the developer; local
agglomerations are not permitted.
A thin, uniform application of the developer shall be carried out by immersion in agitated suspension
or by spraying with suitable equipment in accordance with the approved procedure. The immersion
time and temperature of the developer shall be determined by the user through pre-tests according to
the manufacturer's instructions. The immersion time shall be as short as possible to ensure optimum
results.
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The part shall be dried by evaporation and/or by the use of a forced-air circulation.
The developer shall be applied by spraying uniformly. The spray shall be such that the developer arrives
slightly wet on the surface, giving a thin, uniform layer.
A uniform application of the developer shall be carried out by immersion or by spraying with suitable
equipment in accordance with the approved procedure. The immersion time and temperature of
the developer shall be determined by the user through pre-tests according to the manufacturer's
instructions. The immersion time should be as short as possible to ensure an optimum result.
The part shall be dried by evaporation and/or by the use of a drying oven.
When an indication that needs to be recorded is shown with the penetrant inspection process the
following steps should be used:
— Wipe off the developer with a clean, dry, lint-free cloth.
— Apply the same penetrant by any convenient means, then follow exactly the same process as initially
used, up to application of the developer.
— After excess penetrant removal and drying of the part, apply the peelable developer as recommended
by the manufacturer.
— When the recommended development time has elapsed, carefully peel off the developer coating.
Indication(s) appear(s) on the face of the coating in direct contact with the part.
Penetrant testing without a developer shall only be performed with specific agreement between
contracting parties. The sensitivity shall also be agreed on by the contracting parties and may be based
on the baseline sensitivity of the penetrant used.
8.7 Inspection
8.7.1 General
Indications produced by the penetrant method may provide limited information on the shape, depth and
dimension of discontinuities. In some cases, it may be advantageous to carry out the first examination
just after the application of the developer or as soon as the developer is dry. This facilitates a better
evaluation of indications.
Care should be taken to differentiate between true indications and spurious or false indications, such
as scratches or changes of section. The operator shall carry out any necessary testing and observations
to identify and, if possible, to eliminate the reason for such false indications.
All indications which cannot be confidently discounted as false shall be classified as linear or non-linear
and shall be recorded as required by the product standard.
Inspection shall be carried out when the development time has elapsed.
The final evaluation and the indication sizing shall be performed at the end of the development time.
Inspection aids such as magnification instruments or mirrors can be used.
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Assessment by the wipe-off technique (see 8.7.3) may assist the inspection.
Viewing conditions shall conform to ISO 3059. Additionally, for fluorescent techniques, sufficient time
shall be allowed for the operator's eyes to become dark-adapted in the inspection area, at least 1 min
before inspection commences.
This technique is used to assist in the assessment of the nature of a discontinuity causing an indication
and consists of the removal of the initial indication followed by a further development process. It shall
not be used to remedy general inspection process irregularities such as inadequate removal. The exact
process may be the subject of a specific agreement between the contracting parties or included within
relevant acceptance criteria. Unless otherwise agreed, repeating the procedure is not permitted. Where
no indication redevelops, this shall not be the sole evidence for assessing an indication as spurious or
non-relevant but can be used to demonstrate that the initial interpretation is correct (e.g. water mark
or surface contamination) or to allow the inspector to obtain additional beneficial information by
witnessing the growth of the indication during the redevelopment time.
The process is as follows:
a) using a small, clean, lint-free swab lightly moistened with fast-drying solvent, wipe across the
surface where the indication is present to remove that indication in a manner that further bleed out
will occur if a discontinuity is present;
b) view the area under inspection conditions to ensure the penetrant materials have been completely
removed;
c) apply further developer — use a light coating of wet solvent-based (non-aqueous) developer, applied
from a distance where the material dries almost immediately on contact, unless otherwise agreed;
d) inspect the area immediately after the application of the developer;
e) inspect again at intervals and at the final development time of 10 min.
8.7.4 Recording
Recording may be done by any adequate method, e.g. written description, sketch, peel technique or
photograph.
After final inspection, post cleaning of the part is necessary only in those cases where the penetrant
testing products can interfere with subsequent processing, testing or service requirements.
8.9 Retesting
If retesting is necessary, e.g. because no unambiguous evaluation of indications is possible, the entire
test procedure, starting with the precleaning, shall be repeated.
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If necessary, more favourable test conditions shall be chosen for this procedure. The use of a different
type of penetrant or a penetrant of the same type from a different manufacturer is not allowed.
9 Test report
The test report shall contain the following information, in reference to this document:
a) information on the part tested:
1) designation;
2) dimensions;
3) material;
4) surface condition;
5) production stage;
b) purpose of testing;
c) designation of the penetrant system used, as specified in 6.4, giving the manufacturer's name and
product designation as well as the batch number;
Note Type III penetrants are recorded according to their use. That means a type III penetrant used as
colour contrast penetrant is recorded as type II. A type III penetrant used as a fluorescent penetrant (UV-A
is used) is recorded similar to type I.
d) test procedure;
e) deviations (if any) from the test procedure;
f) viewing conditions;
g) test temperatures;
h) test results (description of discontinuities detected);
i) test location, date of testing, name of the operator;
Annex A
(normative)
The sequence of operations to be followed is illustrated for the general case (except form f and g) by
Figure A.1.
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Annex B
(normative)
B.1 General
This annex describes process and control tests used to monitor the implementation of the method.
In order to maintain the integrity of a penetrant process, the process as a whole and the individual
components of the system shall be regularly checked to ensure that they meet the required standards.
This requirement is applicable to process lines where materials are reused. For products supplied in
aerosols or thixotropic penetrants, only used for a single inspection, reduced or no testing may be
required as determined by a suitably qualified person, e.g. ISO 9712, Level 3.
Table B.1 details the process and control tests to be carried out and their frequency. It is the
responsibility of a suitably qualified person, e.g. ISO 9712, Level 3, to decide which tests are applicable
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to a particular process line. The tests may be carried out at more frequent intervals or additional tests
carried out if necessary to ensure correct processing conditions.
The test shall be carried out and the results recorded in accordance with Table B.1 by a suitably
qualified person, e.g. ISO 9712, Level 2.
B.2 Records
A separate record of the process and control test results for each working place shall be maintained.
Any deviations found shall be reported to the responsible person and the appropriate corrective action
taken.
The following information shall be included in the records:
a) company and site;
b) process line identity;
c) date;
d) shift;
e) name and qualification;
f) signature.
General review
UV-A lamps B.3.9 X X
UV-A irradiance B.3.10 X X
Visible light intensity in inspection booth (fluorescent
B.3.11 X X
systems)
Penetrants
Visible light intensity (colour contrast systems) B.3.12 X X
Emulsifiers
Supplier's overcheck a B.3.15 X X
Developers
Concentration of hydrophilic remover a B.3.16 X X
15
Table B.1 (continued)
16
Frequency Recording
Control tests Subclause Start of each Numerical Visual as-
Weekly Monthly Yearly
work period value sessment
c) Temperature B.3.17.3.3 X X
ISO 3452-1:2021(E)
Calibration/Verification
c) Fluorescence of suspension B.3.17.4.3 X X
Reference test block B.3.21 X X X
a Not intended for aerosols.
B.3.2.1 General
This test shall be carried out using a type 2 reference test block in accordance with ISO 3452-3.
Alternative known defect standards may be used where authorized by a suitably qualified person, e.g.
ISO 9712, Level 3. It may be advantageous to also use a component with known natural discontinuities
typical of those normally expected.
A record in the form of a permanent replica, photograph or other suitable means, showing the
indications, including the background fluorescence, shall be prepared using new, unused materials
(penetrant) of the same family and processed using the same parameters normally in use and retained
for reference. This record shall be used as a comparison for the practical results obtained using the
Asociația de Standardizare din România, SNTGN TRANSGAZ SA MEDIAS, 10.02.2022
same test for the daily system performance check. Indications from peelable developers are not the
same as those obtained using standard developers. The indications on the type 2 reference test block or
on the component with known flaws shall show the same number of indications and pattern as those of
the record prepared using the same materials and process sequence. Similarly, the level of background
shall be the same as that shown on the record.
Permanent replica shall be scaled approximately 1:1, and the indications shall be easy to compare with
test results.
Separate reference pieces shall be allocated to each individual penetrant; for this purpose, an individual
penetrant shall be only one product as designated by the manufacturer.
The test panel or known defect standard used for the performance test shall be maintained in such
condition that it detects changes in process parameters. In particular, it is necessary to remove
penetrant materials remaining from previous tests. It may be beneficial between uses to store the panel
in a solvent or other remover.
No method used shall physically modify the discontinuities.
B.3.14.1 Use standard reference samples of the colour contrast penetrant at 1 %, 0,9 %, 0,8 % and 0,7 %
in high-flash kerosene or any other suitable non-volatile solvent.
To prepare the reference samples, it is recommended that dilutions of 10 %, 9 %, 8 % and 7 % are first
prepared and then further diluted at 1 to 10.
These reference samples shall be stored in light-proof sealed containers.
B.3.14.2 Prepare a 1 % solution of the penetrant under test in the same solvent as specified in B.3.14.1.
B.3.14.3 Using test tubes, under evenly distributed visible light, compare the colour intensity of the
penetrant under test against the reference samples.
B.3.17 Developers
Ensure that the powder is free flowing, fluffy and not caked.
Examine a sample of the powder under UV-A irradiance to ensure that it is free from fluorescence that
can affect the process.
As a guide it is not expected that more than 10 fluorescent specks per 10 000 mm2 (e.g. eight specks on
a 100 mm diameter disk) will be visible.
B.3.17.3.1 Concentration
This test uses a graph of concentration against density produced by the manufacturer to determine the
concentration of the developer.
a) Check the level of the tank and bring it back to its original level by the addition of water and mix
thoroughly.
b) Take a sample of the contents of the tank and adjust the temperature to 20 °C or to the temperature
at which the hydrometer has been calibrated.
c) Measure the density of the sample using a hydrometer.
The density will enable the concentration of the developer to be read from the graph.
Ensure that the whole surface of the reference test block type 2 used for the system performance check
has been evenly coated with the developer.
B.3.17.3.3 Temperature
Examine a sample of the solution under UV-A irradiation to ensure that it is free from fluorescence.
B.3.17.4.1 Concentration
This test uses a graph of concentration against density produced by the manufacturer to determine the
concentration of the developer.
a) Check the level of the tank and, if necessary, add water to bring it back to its original level and mix
Asociația de Standardizare din România, SNTGN TRANSGAZ SA MEDIAS, 10.02.2022
B.3.17.4.2 Temperature
Thoroughly mix the bath of developer to ensure that the powder is in suspension. Examine a sample of
the developer suspension under ultraviolet light to ensure that it is free from fluorescence.
Annex C
(informative)
Bibliography
[1] ISO 9712, Non-destructive testing — Qualification and certification of NDT personnel
[2] CEN/TR 16638, Non-destructive testing — Penetrant and magnetic particle testing using blue light
[3] Artificial Optical Radiation Directive (AORD) (2006/25/EC)
Asociația de Standardizare din România, SNTGN TRANSGAZ SA MEDIAS, 10.02.2022
ICS 19.100
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