SIST EN 17289-1:2021

SLOVENSKI STANDARD
SIST EN 17289-1:2021
01-februar-2021
Karakterizacija razsutih materialov - Določanje velikostno utežene fine frakcije in
deleža kristaliničnega kremena - 1. del: Splošne informacije in izbira preskusnih
metod
Characterization of bulk materials - Determination of a size-weighted fine fraction and
crystalline silica content - Part 1: General information and choice of test methods
Charakterisierung von Schüttgütern - Bestimmung einer größengewichteten Feinfraktion
und des Anteils an kristallinem Quarz - Teil 1: Allgemeine Information und Auswahl der
Prüfverfahren
Caractérisation des matériaux en vrac - Détermination de la fraction fine pondérée par
taille et de la teneur en silice cristalline - Partie 1 : Informations générales et choix des
méthodes d’essai
Ta slovenski standard je istoveten z: EN 17289-1:2020
ICS:
13.040.30 Kakovost zraka na delovnem Workplace atmospheres
mestu
SIST EN 17289-1:2021 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 17289-1:2021

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SIST EN 17289-1:2021


EN 17289-1
EUROPEAN STANDARD

NORME EUROPÉENNE

December 2020
EUROPÄISCHE NORM
ICS 13.040.30
English Version

Characterization of bulk materials - Determination of a
size-weighted fine fraction and crystalline silica content -
Part 1: General information and choice of test methods
Caractérisation des matériaux en vrac - Détermination Charakterisierung von Schüttgütern - Bestimmung
de la fraction fine pondérée par taille et de la teneur en einer größengewichteten Feinfraktion und des Anteils
silice cristalline - Partie 1 : Informations générales et an kristallinem Quarz - Teil 1: Allgemeine Information
choix des méthodes d'essai und Auswahl der Prüfverfahren
This European Standard was approved by CEN on 4 October 2020.

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
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.





EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2020 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 17289-1:2020 E
worldwide for CEN national Members.

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EN 17289-1:2020 (E)
Contents Page
European foreword . 3
Introduction . 4
1 Scope . 6
2 Normative references . 6
3 Terms and definitions . 6
4 Symbols and abbreviations . 9
5 Test methods . 9
6 Guidelines for the determination of crystalline silica . 11
6.1 Preparation of sample to be analysed . 11
6.2 Sample preparation for further analysis by XRD and FT-IR . 11
7 Test report . 11
Annex A (informative) Bias and uncertainties . 13
A.1 General . 13
A.2 Bias between EN 481 and sedimentation SWFF probability function and influence of
density and mineral phase mass fraction . 13
A.3 Uncertainty . 16
Annex B (informative) Round robin test to establish a SWFF reference sample . 18
B.1 General . 18
B.2 Test material . 18
B.3 Evaluation and appraisal method . 19
B.4 Results . 20
Annex C (informative) Determination of crystalline silica in bulk samples using X-Ray
diffraction (XRD) or FT-IR spectroscopy . 23
C.1 General . 23
C.2 Preparation of bulk samples for determination of CS using XRD . 23
C.3 Preparation of bulk samples for determination of CS using FT-IR . 26
Annex D (informative)  Calculating SWFF and SWFFCS from a given particle size distribution
using a spreadsheet . 29
D.1 Spreadsheet setup . 29
D.2 Example . 30
Bibliography . 33
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European foreword
This document (EN 17289-1:2020) has been prepared by Technical Committee CEN/TC 137
“Assessment of workplace exposure to chemical and biological agents”, the secretariat of which is held
by DIN.
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 June 2021, and conflicting national standards shall be
withdrawn at the latest by June 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 organisations 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,
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.

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SIST EN 17289-1:2021
EN 17289-1:2020 (E)
Introduction
A method was developed in the industrial minerals industry for the purpose of determining the “size-
weighted relevant fine fraction” within the bulk material. This document sets out the methods
which can be used to measure and calculate the fine fraction of the bulk material and the fine fraction
of the crystalline silica, in several types of bulk materials. This information provides additional
information to users for their risk assessment and to compare bulk materials. It has been used
in the industry and by institutes previously under the acronym SWeRF. EN 17289 (all parts) is based
on that industrial method and specifies the analytical methods to determine the difference between
materials with coarse quartz and fine quartz, for example, sands versus flour.
As further activities with the material (intentional or otherwise) can change the particle size
distribution, the size-weighted fine fraction can also change. Therefore, the method reports (in terms of
the mass fraction in the bulk material in percent) both, the total crystalline silica (CS) and the estimated
size-weighted fine fraction of CS.
Conventions as specified in EN 481 [1] can be used as input for this document. However, the output
of this document is not related to the respirable fraction and cannot be used to replace workplace
exposure measurements.
EN 17289 (all parts) specifies two procedures that can be used to estimate the size-weighted fine
fraction (SWFF) in bulk materials. It also specifies how the SWFF, once separated, can be further
analysed to measure the content of crystalline silica (SWFFCS). The method can be used for comparing
the fine fraction in different bulk samples. EN 17289 (all parts) uses the term fine fraction to indicate
that it does not analyse airborne particles, but it evaluates the proportion of particles in a bulk material
that, based on their particle size, have a potential to be respirable if they were to become airborne.
EN 17289 (all parts) also allows for the size-weighted fine fraction of crystalline silica (SWFFCS)
particles in bulk materials to be evaluated in terms of mass fraction in percent, if the fraction separated
is subsequently analysed by a suitable method.
In a comparison of similar bulk materials, in which the particle size distribution is the only variable,
the SWFF can provide useful information to guide material selection. For example, leaving all other
factors aside, a bulk material with a lower SWFF value can pose less of a risk in terms of potential
occupational exposure. For the actual exposure at the workplace, the handling etc. of the material,
will play a major role.
Concentrations of respirable dust, or respirable crystalline silica (RCS), in the workplace air, resulting
from processing and handling of bulk materials, will depend on a wide variety of factors and these
concentrations cannot be estimated using SWFF or SWFFCS values. SWFF and SWFFCS values are not
intended for workplace exposure assessments as they have no direct relationship with occupational
exposure.
The evaluation of bulk materials using SWFF is complementary to determining the dustiness according
to EN 15051-1 [2].
The difference between EN 17289 (all parts) and EN 15051-1 is that SWFF quantifies the fine fraction in
a bulk material while dustiness quantifies the respirable, thoracic and inhalable dust made airborne
from the bulk material after a specific activity (dustiness characterizes the material with relation to the
workplace atmosphere when working with the bulk material).
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EN 17289 Characterization of bulk materials — Determination of a size-weighted fine fraction
and crystalline silica content consists of the following parts:
— Part 1: General information and choice of test methods;
— Part 2: Calculation method;
— Part 3: Sedimentation method.
NOTE This document is intended for use by laboratory experts who are familiar with FT-IR, XRD methods,
PSD measurements and other analytical procedures. It is not the intention of this document to provide instruction
in the fundamental analytical techniques.

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1 Scope
This document specifies the requirements and choice of test method for the determination of the size-
weighted fine fraction (SWFF) and the size-weighted fine fraction of crystalline silica (SWFFCS) in bulk
materials.
This document gives also guidance on the preparation of the sample and the determination of
crystalline silica by X-ray Powder Diffractometry (XRD) and Fourier Transform Infrared Spectroscopy
(FT-IR).
NOTE EN 17289-2 specifies a method to calculate the size-weighted fine fraction from a measured particle
size distribution and assumes that the particle size distribution of the crystalline silica particles is the same as the
other particles present in the bulk material. EN 17289-3 specifies a method using a liquid sedimentation
technique to determine the size-weighted fine fraction of crystalline silica. Both methods are based upon a
number of limitations and assumptions, which are listed in EN 17289-2 and EN 17289-3, respectively. The method
in EN 17289-3 can also be used for other constituents than CS, if investigated and validated.
This document is applicable for crystalline silica containing bulk materials which have been fully
investigated and validated for the evaluation of the size-weighted fine fraction and crystalline silica.
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.
EN 1540, Workplace exposure — Terminology
EN 17289-2, Characterization of bulk materials — Determination of a size-weighted fine fraction and
crystalline silica content — Part 2: Calculation method
EN 17289-3:2020, Characterization of bulk materials — Determination of a size-weighted fine fraction
and crystalline silica content — Part 3: Sedimentation method
ISO 16258-2:2015, Workplace air — Analysis of respirable crystalline silica by X-ray diffraction — Part 2:
Method by indirect analysis
3 Terms and definitions
For the purposes of this document, the terms and definitions given in EN 1540 and the following 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
3.1
10th–percentile particle diameter
d
10
particle diameter corresponding to 10 % of the cumulative undersize distribution (by volume or by
mass)
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3.2
90th–percentile particle diameter
d
90
particle diameter corresponding to 90 % of the cumulative undersize distribution (by volume or by
mass)
3.3
between-samples standard deviation
S

s
standard deviation between the random samples used for homogeneity check
3.4
bulk sample
portion that is representative of the bulk material
3.5
coefficient of variation of the reproducibility
CV
R
ratio of standard deviation to the mean of test results produced under reproducibility conditions,
i.e. conditions where test results are obtained with the same method on identical test items in different
laboratories with different operators using different equipment
3.6
complex refractive index
n
p
refractive index of a particle, consisting of a real and an imaginary (absorption) part
Note 1 to entry: The complex refractive index of a particle can be expressed mathematically as
nn−×i k
pp p
where
i
is the square root of −1;
is the positive imaginary (absorption) part of the refractive index of a particle;
k
p
is the positive real part of the refractive index of a particle
n
p
[SOURCE: ISO 13320:2020, 3.1.5, [3] modified – Note 2 to entry deleted]
3.7
crystalline silica
SiO
2
silicon dioxide with Si and O orientated in a fixed pattern as opposed to a nonperiodic, random
molecular arrangement defined as amorphous
Note 1 to entry: The three most common crystalline forms of silica are quartz, tridymite, and cristobalite.
7
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3.8
equivalent Stokes diameter
equivalent spherical diameter
diameter of a sphere having the same rate of sedimentation and density as the particle for laminar flow
in a liquid
3.9
mass fraction of crystalline silica
w
CS
mass fraction of crystalline silica in the bulk sample, in percent (%)
3.10
median particle diameter
d
50
particle diameter, where 50 % of the particles, by volume or by mass, are smaller than this diameter
and 50 % are larger
3.11
mineral phase
homogeneous substance with a well-defined set of physical and chemical properties; it defines a
uniquely identifiable mineral
3.12
particle density
ratio of the mass of particles to the volume of the particles, in which closed pores are included
in the volume while open pores and volume between particles are excluded
3
Note 1 to entry: Particle density is typically determined using a pycnometer and has the dimension kg/m .
3.13
size-weighted fine fraction
SWFF
w

SWFF
fraction of the mass of a bulk material as determined by the size and density of the particles and a well-
defined probability function, in percent (%)
3.14
size-weighted fine fraction of crystalline silica
SWFFCS
w
SWFFCS
fraction of the mass of crystalline silica particles in the SWFF, in percent (%)
3.15
skeletal density
mass of a unit volume of the diatomaceous earth (DE) skeleton, inaccessible to Helium
3.16
standard deviation for proficiency assessment
σ

measure of dispersion used in the assessment of proficiency, based on the available information
[SOURCE: ISO 13528:2015, 3.4 [4]]
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3.17
supernatant
column of liquid that is separated from the total sedimentation liquid column which contains the solid
particles of interest
Note 1 to entry: See EN 17289-3:2020, Figure A.2.
3.18
z-score
z

standardized measure of laboratory bias, calculated using the assigned value and the standard
deviation for proficiency assessment
[SOURCE: ISO 13528:2015, 3.7]
4 Symbols and abbreviations
CS crystalline silica
DE diatomaceous earth
LD laser diffraction
PSD particle size distribution
FT-IR Fourier transform infrared spectroscopy
MMAD mass median aerodynamic diameter
RCS respirable crystalline silica
RI refractive index
SWFF size-weighted fine fraction
SWFFCS size-weighted fine fraction of crystalline silica
XRD X-ray powder diffractometry
5 Test methods
There are two ways to determine the SWFF and SWFFCS:
a) by calculation, as specified in EN 17289-2;
b) by sedimentation in a liquid, as specified in EN 17289-3.
The calculation method requires that the aerodynamic particle size distribution of the bulk material
is known. When SWFFCS needs to be determined this is often not possible since the PSD of the CS
in the sample cannot be determined separately from the rest of the sample. The CS can be finer
or coarser than the bulk of the sample. Instead, in this case the sedimentation method shall be used
to determine the SWFFCS.
The calculation method is easier and faster to perform. This can be a reason to choose the calculation
method over the sedimentation method; the assumption is then made that the size distributions
are the same so that SWFFCS can be calculated from the PSD of the whole sample. However, this can
only be done after experiments have shown that the results are accurate and consistently equal
or higher than the results from sedimentation for that particular bulk material.
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The sedimentation method is a good approximation for the determination of SWFF and SWFFCS.
However, when samples have a narrow size distribution and a median diameter ( d ) in the range
50
from 6 µm to 12 µm (aerodynamic) the method shall not be used since results will be too low.
Instead the calculation method shall be applied. This is possible because of the narrow size distribution.
In this case the difference in PSD between CS and bulk of the sample is small.
The analytical approach specified in these methods fulfils the expanded uncertainty requirements
of EN 482 [5]. Guidance on bias and uncertainties is given in Annex A.
Figure 1 gives a flowchart to assist the user in selecting the appropriate test method for the
determination of SWFF and SWFFCS. Both calculation and sedimentation methods are based
upon a number of assumptions, which are listed in EN 17289-2 and EN 17289-3, respectively.

Figure 1 — Selection of test method for SWFF and SWFFCS
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NOTE Experiments were performed on a series of minerals in order to make recommendations on the use
of the different methods (see Annex B).
6 Guidelines for the determination of crystalline silica
6.1 Preparation of sample to be analysed
Samples shall be extracted from the bulk material using a method, which will result in a representative
sample (for example, ISO 14488 [7], BS 3406-1 [6]), respecting the limitations of the analytical methods.
6.2 Sample preparation for further analysis by XRD and FT-IR
Sample preparation is specified in Annex C using XRD and FT-IR.
The content of crystalline silica of the sample shall be determined using techniques such as X-ray
Powder Diffractometry (XRD) as specified, for example, in EN 13925-1, EN 13925-2 and EN 13925-3
[8], [9], [10] and ISO 16258-2 or Fourier Transform Infrared Spectroscopy (FT-IR) as specified in
ISO 19087 [11].
NOTE 1 The sample preparation step in EN 13925-2 is applicable for both analytical methods.
NOTE 2 All paragraphs related to sampling in ISO 16258-2 and ISO 19087 are not applicable to this document.
NOTE 3 Omotoso et al. [12] and Chipera and Bish [13] specify quantitative mineral analysis.
7 Test report
The test report shall contain at least the following information:
a) reference to this document (“EN 17289-1”);
b) date of testing;
c) identification of test facility;
d) identification of contractor or subcontractor, if applicable;
e) identification of the test method used – calculation or sedimentation method;
f) identification of the method of sampling and sample preparation used;
g) identification of samples of test materials;
3
h) particle density of the sample, in kilograms per cubic metre (kg/m );
i) density of the substance of interest (for example, quartz, cristobalite), in kilograms per cubic metre
3
(kg/m );
j) the mass fraction of the substance of interest (for example, quartz, cristobalite) in the bulk sample,
in percent (%);
k) the mass fraction of SWFF and/or SWFFCS in the bulk sample, in percent (%).
The test report shall also include specific minimum requirements for the calculation and/or
sedimentation methods as follows:
1) For the calculation method:
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a) method of determination of PSD (for example, by laser diffraction (LD) analysis (specify wet or
dry and Mie or Fraunhofer), gravitational sedimentation method, particle time-of-flight
(TOF) method)
b) an example of a calculation sheet for determining SWFF by calculation can be found in Annex D
and on the Safe Silica website (https://safesilica.eu/safety-and-measurement/).
2) For the sedimentation method:
a) total sample mass that was dispersed, in grams [g];
b) type and volume of sedimentation liquid, in millilitres (ml);
c) temperature, density and viscosity of the liquid;
d) type of dispersants (if used);
e) method of dispersion;
f) sedimentation time, in seconds (s);
g) depth of the separated liquid column, in metres (m);
h) supernatant residue, in grams (g);
i) method of determination of substance of interest e.g. Quartz XRD or FT-IR;
j) fine fraction of CS in the supernatant, in percent (%).
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Annex A
(informative)

Bias and uncertainties
A.1 General
As with any method of analysis there are biases and uncertainties. These are investigated in this Annex.
A.2 looks at the biases arising from the size distribution measurement and in particular: the biases
arising from the different probability functions and the issues associated with the density of
multicomponent particles. The biases arising from three scenarios of increasing complexity are
compared with the ideal powder of a single mineral phase of crystalline silica. A.3 lists the uncertainties
associated with the calculation method (EN 17289-2) and sedimentation method (EN 17289-3).
With any method of analysis representative sampling is extremely important. A recognized method or
standard should be followed. The use of the methods specified in the sampling standards referenced in
ISO 14488 and BS 3406-1, will allow the sampling uncertainty to be calculated.
A.2 Bias between EN 481 and sedimentation SWFF probability function
and influence of density and mineral phase mass fraction
A.2.1 Bias between EN 481 and sedimentation SWFF probability curve
A.2.1.1 General
This subclause specifies the theoretical comparison between the respirable sampling convention
and the SWFF probability function.
A.2.1.2 Ideal powder, one mineral phase of known density and ideal SWFF measurement
The SWFF and respirable sampling conventions have been compared theoretically for an ideal
dispersed powder and ideal SWFF measurement (without bias or uncertainties) for which the particles
have the following characteristics:
— all particles are spherical;
— all particles have an identical and known density;
— all particles (independent of size) are completely dispersed in air and test liquid, respectively;
— no particle is attached to (agglomerated with) any other particle, neither when dispersed in air
nor when dispersed in the test liquid.
The comparison was carried out by calculating a bias map of the SWFF probability function / fraction
relative to the respirable fraction for the aerodynamic mass-weighted particle size distributions
specified in EN 13205-2 [14]. For such an ideal powder and an ideal measurement, it does not matter
whether the SWFF was determined using EN 17289-2 or EN 17289-3.
For this ideal situation, the bias between the two sampling conventions is small, generally within ± 5 %
except for particles greater than 6 μm where the bias is in the range from −5 % to −20 %. This is due
to the sedimentation method not sampling particles of more than 6 μm aerodynamic diameter ( d ).
ae
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A.2.2 Internal SWFF sedimentation bias
A.2.2.1 General
This subclause specifies the bias between SWFF 1 sedimentation (spherical non-agglomerated particles,
one mineral phase, density of quartz mixture) and SWFF 2 sedimentation (spherical non-agglomerated
particles, two mineral phases one of them being quartz, identical mass fraction of quartz to total mass
of the particle for all particles independently of particle size).
A.2.2.2 Ideal powder, two mineral phases of known density and ideal SWFF sedimentation
measurement
The SWFF 1 and SWFF 2 have been compared theoretically for ideal dispersed powders and ideal SWFF
measurement (without bias or uncertainties) for which the particles have the following characteristics:
SWFF 1:
— all particles are spherical;
— all particles have one mineral phase;
— all particles have an identical and known density (quartz density);
— all particles (independent of size) are completely dispersed in air and test liquid, respectively;
— no particle is attached to (agglomerated with) any other particle
...