SIST EN ISO/ASTM 52925:2023

SLOVENSKI STANDARD
oSIST prEN ISO/ASTM 52925:2020
01-junij-2020
Procesi aditivne proizvodnje - Lasersko sintranje polimernih delov/laserska fuzija
plasti polimernih delov - Kvalifikacija materialov (ISO/ASTM/DIS 52925:2020)
Additive manufacturing processes - Laser sintering of polymer parts/laser-based powder
bed fusion of polymer parts - Qualification of materials (ISO/ASTM/DIS 52925:2020)
Additive Fertigung - Lasersintern von Polymerteilen/laserbasiertes pulverbettbasiertes
Schmelzen von Polymerteilen - Qualifizierung von Materialien (ISO/ASTM/DIS
52925:2020)
Procédés de fabrication additive - Frittage laser de pièces polymères / fusion laser sur lit
de poudre de pièces polymères - Qualification des matériaux (ISO/ASTM/DIS
52925:2020)
Ta slovenski standard je istoveten z: prEN ISO/ASTM 52925
ICS:
25.030 3D-tiskanje Additive manufacturing
oSIST prEN ISO/ASTM 52925:2020 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN ISO/ASTM 52925:2020

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oSIST prEN ISO/ASTM 52925:2020
DRAFT INTERNATIONAL STANDARD
ISO/ASTM DIS 52925
ISO/TC 261 Secretariat: DIN
Voting begins on: Voting terminates on:
2020-04-10 2020-07-03
Additive manufacturing processes — Laser sintering of
polymer parts/laser-based powder bed fusion of polymer
parts — Qualification of materials
ICS: 25.030
THIS DOCUMENT IS A DRAFT CIRCULATED
This document is circulated as received from the committee secretariat.
FOR COMMENT AND APPROVAL. IT IS
THEREFORE SUBJECT TO CHANGE AND MAY
NOT BE REFERRED TO AS AN INTERNATIONAL
STANDARD UNTIL PUBLISHED AS SUCH.
IN ADDITION TO THEIR EVALUATION AS
ISO/CEN PARALLEL PROCESSING
BEING ACCEPTABLE FOR INDUSTRIAL,
TECHNOLOGICAL, COMMERCIAL AND
USER PURPOSES, DRAFT INTERNATIONAL
STANDARDS MAY ON OCCASION HAVE TO
BE CONSIDERED IN THE LIGHT OF THEIR
POTENTIAL TO BECOME STANDARDS TO
WHICH REFERENCE MAY BE MADE IN
Reference number
NATIONAL REGULATIONS.
ISO/ASTM DIS 52925:2020(E)
RECIPIENTS OF THIS DRAFT ARE INVITED
TO SUBMIT, WITH THEIR COMMENTS,
NOTIFICATION OF ANY RELEVANT PATENT
RIGHTS OF WHICH THEY ARE AWARE AND TO
©
PROVIDE SUPPORTING DOCUMENTATION. ISO 2020

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oSIST prEN ISO/ASTM 52925:2020
ISO/ASTM DIS 52925:2020(E)

COPYRIGHT PROTECTED DOCUMENT
© ISO/ASTM International 2020
All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may be
reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting on
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ISO copyright office ASTM International
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Published in Switzerland
ii © ISO/ASTM International 2020 – All rights reserved

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Contents Page
Foreword .iv
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Symbols and abbreviations . 1
4.1 Symbols . 1
4.2 Abbreviations . 2
5 Sampling . 2
5.1 General . 2
5.2 Characterisation of new (virgin) powder and powder mixes . 2
5.3 Characterisation of used powder . 2
6 Factory test certificate . 3
6.1 General . 3
6.2 Particle size distribution . 3
6.3 Residual monomer content/extract content . 3
6.4 Supplementary data . 3
7 Factors influencing processability . 4
7.1 General . 4
7.2 Flowability of the powder . 4
7.3 Relative humidity of the powder (surface moisture) . 4
7.4 Particle size distribution . 5
8 Factors affecting part quality . 5
8.1 General . 5
8.2 Melting behaviour, melt flow and MVR . 6
8.2.1 General. 6
8.2.2 Laboratory methods . 6
8.2.3 Melt volume-flow rate (MVR) . 6
8.3 Melting temperature and recrystallisation temperature . 7
Annex A (informative) Hausner ratio (H ) . 9
R
Annex B (informative) Determination of the melt volume-flow rate (MVR) .12
Annex C (informative) Round robin MVR test .15
Bibliography .18
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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
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.
The committee responsible for this document is ISO/TC 261, Additive manufacturing, in cooperation
with ASTM Committee F42, Additive Manufacturing Technologies, on the basis of a partnership
agreement between ISO and ASTM International with the aim to create a common set of ISO/ASTM
standards on Additive Manufacturing.
This is the first edition of this document.
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oSIST prEN ISO/ASTM 52925:2020
DRAFT INTERNATIONAL STANDARD ISO/ASTM DIS 52925:2020(E)
Additive manufacturing processes — Laser sintering of
polymer parts/laser-based powder bed fusion of polymer
parts — Qualification of materials
1 Scope
This document establishes specific parameters and recommendations for the qualification of
polymeric materials intended for laser sintering. The parameters and recommendations presented
in this document relate mainly to the material polyamide 12 (PA12), but references are also made to
polyamide 11 (PA11). The parameters and recommendations set forth herein may not be applicable to
other polymeric materials.
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 ASTM 52900, Additive manufacturing — General principles — Terminology
ASTM D6779Standard Classification System for and Basis of Specification for Polyamide Molding and
Extrusion Materials (PA)
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO/ASTM 52900, apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at http:// www .electropedia .org/
— ISO Online browsing platform: available at http:// www .iso .org/ obp
4 Symbols and abbreviations
4.1 Symbols
The following symbols are used throughout this standard:
Symbols Designation Unit
D 10% quantile of particle size based on the sample volume µm
v10
D 50% quantile of particle size based on the sample volume µm
v50
D 90% quantile of particle size based on the sample volume µm
v90
H Hausner ratio —
R
s standard deviation of repeatability —
r
s standard deviation of reproducibility —
R
T processing temperature range °C
B
T initial crystallisation temperature °C
ic
T initial melting temperature °C
im
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Symbols Designation Unit
V bulk volume mL
∞
tapped volume mL
V
0
η relative viscosity –
rel
bulk density g/mL
ρ
∞
ρ tapped density g/mL
0
4.2 Abbreviations
The following abbreviations are used throughout this standard:
AM additive manufacturing
DSC dynamic scanning calorimetry
GPC gel permeation chromatography
MFI melt flow index
MFR melt mass flow rate
MVR melt volume flow rate
PA11 polyamide 11
PA12 polyamide 12
RoHS restriction of the use of certain hazardous substances
5 Sampling
5.1 General
When analysing a small powder sample to determine its quality and suitability for laser sintering, it
must be ensured, that this sample is representative of the powder as a whole.
5.2 Characterisation of new (virgin) powder and powder mixes
Each new batch of virgin powder shall be tested and also each powder mix comprising used and virgin
powder should be tested in accordance with the measurement methods listed in this standard. Test of
powder mix is recommended for series serial production to ensure consistent part quality. To minimise
the scope of testing and ensure a high level of powder homogeneity, batch size of mixed powder should
be as large as possible.
5.3 Characterisation of used powder
Since different temperature histories within the used powder of a part cake can lead to significant
differences in material quality, the total quantity of powder shall be homogenised to obtain a
representative powder sample.
In practice this can be achieved by thoroughly mixing the powder in a mixer, for example. Once mixed,
the sample can be taken from any part of the powder. If a sufficiently large mixer is not available, several
samples (up to five, each weighing 20 g) may be taken from different areas and mixed together. Samples
for analysis may then be taken from this mix.
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IMPORTANT — Ideally, the total volume of powder should be homogenised rather than individual
samples.
6 Factory test certificate
6.1 General
The factory test certificate should contain batch-specific measurements of powder parameters
(characteristic values) that can have a critical impact on the manufacturing process.
Each factory test certificate shall include the data according 6.2 to 6.4.
6.2 Particle size distribution
The particle size distribution has a significant influence on flowability and bulk density and thus
contributes to the processability and part characteristics. Typical data are the D , D and D
v10 v50 v90
values. These correspond to the particle size at which 10 %, 50 % or 90 % of the volume fraction of
the powder is smaller than this value. A volume- or mass-related analysis is preferable to a numerical
analysis since small particles account for only a small mass or volume fraction, even when they are
present in large numbers.
A large number of large particles impairs the surface quality and fine detailing (detail resolution) of the
part. The D value can be used to indicate the coarse fraction; i.e. 10 % of the volume fraction of the
v90
powder is larger than this particle size.
A high proportion of fine particles produces more fine particulate matter which can contaminate the AM
machine and its surroundings. The smaller the particles, the larger the surface-to-volume ratio and the
stronger the surface forces and electrostatic charge are. This impairs flowability and can cause powder
deposits to accumulate on the recoating system, for example. The D value serves as a measure of the
v10
fine fraction; i.e. 10 % of the volume fraction of the powder is smaller than this particle size.
The median particle size (D value) provides a good indication of the resulting surface roughness of
v50
parts since this is largely determined by particles adhering to the parts or partially fused particles.
IMPORTANT — D , D and D values shall be indicated as a minimum. It is advantageous to
v10 v50 v90
indicate the particle size distribution in full.
7.4 explains how to determine the particle size distribution.
6.3 Residual monomer content/extract content
The residual monomer content/extract content of a laser sinter powder should be kept to a minimum
level to minimise the release of gases from the powder. These monomeric gas releases can condense on
colder areas of the additive manufacturing machine and soil the system as a result. Optical elements
soiled in this way absorb laser radiation, leading to a reduction in the laser power delivered to the build
field. This can have a detrimental effect on the mechanical properties and the part density. Soiling of
mechanically stressed components can accelerate ageing or in extreme cases, cause them to fail.
IMPORTANT — The residual monomer content is indicated as percentage mass and should be
below 0,5 % for polyamide 11 and polyamide 12 powders.
6.4 Supplementary data
Normally, the powder formulation is confidential and is not disclosed. However, the purchaser can
generally assume that the material supplier keeps to his formulation and that the content of fillers and
additives remains constant from one batch to another and is monitored during production. No change
to the formulation or to the additives is acceptable without prior agreement from the customer It is
unusual to explicitly specify the formulation in the factory test certificate, as is also the case with
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plastic pellets for injection moulding applications. Powder shall be certified to specification call-out
such as ASTM D6779. Appropriate certificates (e.g. Safety Data Sheet, “Globally Harmonized System
of Classification and Labelling of Chemicals”, EU Directive 2011/65/EU) are issued to confirm that
the formulation contains no harmful substances. Important components and their effect on part
characteristics are listed below:
— stabilisers: these prevent thermal degradation within the polymer and also influence the mechanical
characteristics of the resulting part.
— fillers (e.g. glass beads): fillers in the polymer influence the mechanical characteristics of the part.
— flame retardants: these influence the flammability of the parts.
— additives: certain additives can be contractually excluded, depending on subsequent use.
IMPORTANT — The supplementary information shall be agreed between the contractual
partners, depending on the desired area of application.
7 Factors influencing processability
7.1 General
Many characteristics of the polymer powder ultimately determine whether or not a part produced by
laser sintering conforms to requirements. However, the tolerance limits of many of these characteristics
largely depend on the AM machine and/or the processing parameters used. For this reason, this section
deals only with those factors which make processing fundamentally unfeasible; in other words, the
measurements described below can be used to exclude unsuitable material.
7.2 Flowability of the powder
The flowability and flow characteristics of the powder determine the quality of the powder recoating.
If a powder is not free-flowing because the particle shape and/or distribution is unfavourable or its
electrostatic charge is too strong, neither the powder feed to the process chamber nor the application of
a thin powder layer in the AM machine can be guaranteed. Any powder with poor flow characteristics
shall be detected and excluded. . There are various possibilities to determine the flowability of powders
and their use for laser sintering powders is under investigation. One possibility that has shown good
results in a round robin test (Annex A) is the determination of the Hausner ratio H . This is based on
R
determination of flowability as per ISO 6186 and determination of bulk density as per ISO 60. Whilst
the last two methods are defined very precisely in the corresponding standards, determination of the
Hausner ratio has yet to be standardised. Annex A of this standard describes in detail the definition of
the Hausner ratio H , its determination by measurement and its significance.
R
7.3 Relative humidity of the powder (surface moisture)
When grains of powder are in motion, the surfaces of individual particles come into contact with one
another and then separate again, leading to charge separation which causes the powder to develop
electrostatic charge. Since a polymer is an insulator (non-conductive material), no charge equalisation
can occur within the individual particles. Discharge takes place across the surface moisture of the
particle, as well as via the ambient air. The electrical conductivity of the powder generated by the
surface moisture is therefore critical for breaking down electrostatic charges inside the powder volume.
Since it depends on the moisture at the particle surface, measurement of the moisture using moisture
scales is not informative. With this method, the moisture loss of a sample is measured by increasing
the temperature. However, in the case of polyamides, the polymer itself also absorbs water and this
moisture also escapes on heating. Thus it is not possible to distinguish whether the water played an
active role in discharge at the particle surface or was trapped inside the particles.
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A moisture meter with probe is therefore a suitable alternative. This measurement method determines
the relative humidity of the air. The probe can be inserted in the powder since the relative humidity of
the air is an indirect indication of the surface moisture of the powder. The higher the measured relative
humidity, the higher the surface moisture of the powder. To obtain reproducible measurements,
the probe should be inserted to the same depth in the powder bed each time. The depth should be a
minimum of 200 mm. For PA12 and PA11, relative humidities of 40 % to 60 % measured in this way
have proved ideal for processing the powder.
7.4 Particle size distribution
As already described in 6.2, particle size distribution has an influence on processability and/or part
quality and for this reason it should also be monitored in powder mixes comprising used and virgin
powder. Problems with processability can occur if the coarse fraction is too high. These large particles
can cause defects during recoating (e.g. stripes or scratches) or even displace small parts in extreme
cases. The coarse fraction also has an influence on the surface quality and detail resolution of the part.
The coarse fraction is characterised by the D value.
v90
The fine fraction also causes defects during coating due to interparticle interactions, electrostatic
charging and resulting poor flowability. The fine fraction is characterised by the D value.
v10
Various measurement methods are available to determine the coarse and fine fraction by means of
analysis.
The best-known is laser diffraction pursuant to ISO 13320. Here the powder, dispersed in compressed
air (dry measurement) or in a liquid dispersant (wet measurement) is placed in the path of a laser beam
and the particle size distribution is calculated using detectors which measure the light scattering
pattern.
Optical image analysis is another method. A distinction is made between static image analysis for
resting particles (ISO 13322-1) and dynamic image analysis for particles in motion, dispersed in air or
liquid (ISO 13322-2). Both versions are based on the analysis of 2D projected images of powder particles,
which provide information about particle size distribution and particle shape (including sphericity).
Sieving analysis (ASTM D1921 or ISO 3310) is a robust method of analysing powders. Here a powder
sample is poured into a tower containing several sieves. The top sieve has the largest mesh width and
each lower sieve has a smaller mesh width than the one above. By weighing the individual fractions
retained in each sieve it is possible to determine the particle size distribution of the powder by weight
of the single fractions.
For powder monitoring purposes, a simplified version comprising just one coarse sieve could be used
to determine purely the coarse fraction and establish an internal threshold for coarse material. The
mesh width of the coarse sieve should correlate with the layer thickness subsequently required (the
thinner the layers, the finer the sieve). Mesh widths from 120 µm to 200 µm shall be used. The coarse
fraction retained on the sieve should not exceed 5 %. No contaminants or extremely large particles/
agglomerates should be visible. This method is a very reliable means of detecting insufficiently sieved
powder or a sieve damage during powder processing.
8 Factors affecting part quality
8.1 General
A range of factors have an impact on part quality. Material characteristics which have an influence on
the finished part and can be measured using analytical methods are described in the following sections.
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8.2 Melting behaviour, melt flow and MVR
8.2.1 General
The flow characteristics of a polymer melt are largely determined by the molecular weight distribution
and the temperature, pressure and shear rate of the melt. The higher the melt temperature, the lower
the viscosity. This effect is even more pronounced with laser sintering than with conventional polymer
processing methods, since shear and pressure are not involved. In this case, temperature, molecular
shape and chain length determine whether the powder forms an adequate melt film, how many pores
remain in the part and how well the layer bonds to the previous layer. The flow characteristics of the
melt thus give an indication of the part mechanics and the layer-to-layer bonding.
The process parameters (e.g. laser power and scan speed) are normally selected to produce a homogenous
melt layer. Too low melt flow leads to the formation of pores in the component or poor layer bonding.
Both outcomes can have an adverse effect on part mechanics. Thus it is extremely important to control
the melt viscosity of both virgin powders and powder mixes in order to produce high-quality parts.
8.2.2 Laboratory methods
The viscosity is determined at molecular level via the molecular structure and molecular mass
distribution. GPC (gel permeation chromatography) can be used to obtain information about the
molecular chain length and the static distribution of chain lengths in the material. However, since the
method is extremely time-consuming and costly, it is recommended only for detailed analyses.
Determination of the solution viscosity also provides information about the average chain length and
molecular mass. This is done using polymers in varying concentrations dissolved in specific solvents.
Typical solvents include m-cresol, tetrachloroethane and concentrated sulphuric acid. Polyamides are
measured in a capillary viscometer in accordance with ISO 307. The relative viscosity (η ) is calculated
rel
fr
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