SIST EN 12341:2014

SLOVENSKI STANDARD
oSIST prEN 12341:2012
01-november-2012
=XQDQML]UDN6WDQGDUGQDJUDYLPHWULMVNDPHWRGD]DGRORþHYDQMHPDVQHIUDNFLMH
30DOL30OHEGHþLKGHOFHY
Ambient air - Standard gravimetric measurement method for the determination of the
PM10 or PM2,5 mass concentration of suspended particulate matter
Außenluft - Gravimetrisches Standardmessverfahren für die Bestimmung der PM10-
oder PM2,5-Massenkonzentration des Schwebstaubes
Air ambiant - Méthode normalisée de mesurage gravimétrique pour la détermination de
la concentration massique MP10 ou MP2,5 de matière particulaire en suspension
Ta slovenski standard je istoveten z: prEN 12341
ICS:
13.040.20 Kakovost okoljskega zraka Ambient atmospheres
oSIST prEN 12341:2012 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 12341:2012

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oSIST prEN 12341:2012


EUROPEAN STANDARD
DRAFT
prEN 12341
NORME EUROPÉENNE

EUROPÄISCHE NORM

July 2012
ICS 13.040.20 Will supersede EN 12341:1998, EN 14907:2005
English Version
Ambient air - Standard gravimetric measurement method for the
determination of the PM10 or PM2,5 mass concentration of
suspended particulate matter
Air ambiant - Méthode normalisée de mesurage Außenluft - Gravimetrisches Standardmessverfahren für die
gravimétrique pour la détermination de la concentration Bestimmung der PM10- oder PM2,5-Massenkonzentration
massique MP10 ou MP2,5 de matière particulaire en des Schwebstaubes
suspension
This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee CEN/TC 264.

If this draft becomes a European Standard, 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.

This draft European Standard was established by CEN 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, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United
Kingdom.

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.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice and
shall not be referred to as a European Standard.


EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2012 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 12341:2012: E
worldwide for CEN national Members.

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Contents Page
Foreword .3
Introduction .4
1 Scope .6
2 Normative references .6
3 Terms, definitions, symbols and abbreviations .7
4 Principle . 11
5 Equipment and facilities . 12
6 Filter conditioning, sampling and weighing procedures . 19
7 Ongoing quality control . 22
8 Expression of results . 25
9 Performance characteristics of the method . 25
Annex A (normative) Design drawings of standard inlets for the sampling of PM and PM . 34
10 2,5
Annex B (normative) Other samplers. 35
Annex C (informative) Suitability tests for filters . 43
Annex D (normative) Initial suitability testing of weighing facilities . 45
Annex E (informative) Results of experimental work . 46
Annex F (informative) Relationship with EU Directives . 48
Bibliography . 49

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Foreword
This document (prEN 12341:2012) has been prepared by Technical Committee CEN/TC 264 “Air quality”, the
secretariat of which is held by DIN.
This document is currently submitted to the CEN Enquiry.
This document will supersede EN 12341:1998 and EN 14907:2005.
prEN 12341:2012 includes the following significant technical changes with respect to EN 12341:1998 and
EN 14907:2005:
 this document is adapted from EN 14907:2005 due to consideration of best available technology;
 the three different standard reference methods for PM10 described in EN 12341:1998 and the two
different standard reference methods for PM2,5 described in EN 14907:2005 are replaced in this
document by only one possible standard reference method for PM10 and PM2,5.

3

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Introduction
For air quality across the European Union to be assessed on a consistent basis, Member States need to
employ standard measurement techniques and procedures. The aim of this European Standard is to present a
harmonised methodology for monitoring the 10 µm and 2,5 µm mass concentrations of suspended particulate
matter (PM , respectively PM ) in ambient air, following Directive 2008/50/EC on ambient air quality and
10 2,5
cleaner air for Europe [6], which sets the parameters specific to the assessment of ambient concentration
levels of particulate matter.
NOTE In principle, the methodology described in this European Standard may also be used for measurement of
mass concentrations of other PM fractions such as PM . However, this European Standard does not describe
1
standardized sampling inlets for such fractions.
This European Standard merges the earlier European Standards EN 12341:1998 [2] and EN 14907:2005 [4]
with the aim of harmonizing the very similar procedures that are used to measure mass concentrations of both
fractions of particulate matter in ambient air.
The European Standard method described in this European Standard is focused primarily on harmonization
and improvement of the data quality of measurement methods used in monitoring networks, with regard to
avoiding unnecessary discontinuities with historical data. It is a method that is suited for practical use in
routine monitoring, but not necessarily the method with the highest metrological quality.
There are no traceable reference standards for PM or PM measurements. Therefore, the standard method
10 2,5
defines the measured quantity by convention, specifically by the sample inlet design and associated
operational parameters covering the whole measurement process. This European Standard contains
— a description of a manual gravimetric standard measurement method for PM or PM using sequential
10 2,.5
samplers or single-filter samplers;
— a summary of performance requirements of the method;
— requirements for suitability testing of facilities and equipment on initial application of the method;
— requirements for ongoing quality assurance / quality control when applying the method in the field;
— the assessment of measurement uncertainty of the results of this European Standard method;
— (tentative) criteria and test methods for the evaluation of the suitability of filters for application using this
method.
The performance characteristics and requirements described in this European Standard were partly
determined in different comparative and validation trials. The trials were sponsored by the European
Commission and the European Free Trade Association.
However, for lack of appropriate criteria and protocols to test filters for fitness for purpose, considerable
differences may exist between results obtained when using different filter types, and even filters of the same
type. For example, differences of up to 15 % have been found when applying different brands of quartz-fibre
[7]
filters in parallel measurements of PM for concentrations around 50 % of the daily limit value . This may
10
have implications for results produced by automated measurement systems as these are calibrated by
comparison of results with those obtained using reference samplers.
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In principle, the filters collected for the purpose of determining the mass concentrations of PM or PM can
10 2,5
be used for further speciation, e.g. for the determination of concentrations of
• heavy metals and polycyclic aromatic hydrocarbons in conformity with Directive 2004/107/EC [8],
• constituents of PM to be used for source apportionment as required by Directive 2008/50/EC [6].
2,5
Additional requirements may have to be considered for those purposes (e.g. blank values of chemical
constituents).
However, the requirements of this European Standard are targeted firstly towards obtaining optimum results
for the measurement of mass concentrations of PM or PM .
10 2,5
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1 Scope
This European Standard describes a standard method for determining the PM or PM mass concentrations
10 2,5
of suspended particulate matter in ambient air by sampling the particulate matter on filters and weighing them
by means of a balance.
Measurements are performed with samplers with inlet designs as specified in Annex A, operating at a nominal
flow rate of 2,3 m³/h, over a nominal sampling period of 24 h. Measurement results are expressed in µg/m³,
where the volume of air is the volume at ambient conditions near the inlet at the time of sampling.

The range of application of this European Standard is from approximately 1 µg/m³ (i.e. the limit of detection of
the standard measurement method expressed as its uncertainty) up to 150 µg/m³ for PM and 120 µg/m³ for
10
PM .
2,5
NOTE 1 Although the European Standard is not validated for higher concentrations, its range of application could well

be extended to ambient air concentrations up to circa 200 µg/m³ when using suitable filter materials (see 5.1.4).
This European Standard describes procedures and gives requirements for the use of so-called sequential
samplers, equipped with a filter changer, suitable for extended stand-alone operation. Sequential samplers
are commonly used throughout the European Union for the measurement of concentrations in ambient air of
PM or PM . However, this European Standard does not exclude the use of single-filter samplers.
10 2,5
This European Standard does not give procedures for the demonstration of equivalence of other sampler
types, e.g. equipped with a different aerosol classifier and/or operating at different flow rates. Such procedures
and requirements are given in detail in the "Guide to the Demonstration of Equivalence of Ambient Air
Monitoring Methods" [9].
The present European Standard represents an evolution of earlier European Standards (EN 12341:1998 and
EN 14907:2005) through the development of the 2,3 m³/h sampler to include sheath air cooling, the ability to
cool filters after sampling, and the ability to monitor temperatures at critical points in the sampling system. It is
recommended that when equipment is procured, that it complies fully with the present European Standard.
However, older versions of these 2,3 m³/h samplers that do not employ sheath air cooling, the ability to cool
filters after sampling, or the ability to monitor temperatures at critical points in the sampling system have a
special status in terms of their use as reference samplers. Historical results obtained using these samplers will
remain valid. These samplers can still be used for monitoring purposes and for equivalence trials, provided
that a well justified additional allowance is made to their uncertainties.
In addition, three specific sampling systems – the “long nozzle” 2,3 m³/h sampler and the 68 m³/h sampler for
PM in EN 12341:1998, and the 30 m³/h PM inlet in EN 14907 – also have a special status in terms of their
10 2,5
use as reference samplers. Historical results obtained using these samplers will remain valid. These samplers
can still be used for monitoring purposes and for equivalence trials, provided that a well-justified additional
allowance is made to their uncertainties (see Annex B).
Other sampling systems, as described in Annex B of this European Standard, can be used provided that a
well justified additional allowance is made to their uncertainties as derived from equivalence tests.
NOTE 2 By evaluating existing data it has been shown that these samplers give results for PM and PM that are
10 2,5
equivalent to those obtained by application of this European Standard. Results are shown in Annex B.
This European Standard also provides guidance for the selection and testing of filters with the aim of reducing
the measurement uncertainty of the results obtained when applying this European Standard.
2 Normative references
The following documents, in whole or in part, are normatively referenced in this document and are
indispensable for its application. For dated references, only the edition cited applies. For undated references,
the latest edition of the referenced document (including any amendments) applies.
JCGM 100, Evaluation of measurement data — Guide to the expression of uncertainty in measurement
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3 Terms, definitions, symbols and abbreviations
3.1 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
3.1.1
ambient air
outdoor air in the troposphere, excluding workplaces as defined by Directive 89/654/EEC where provisions
concerning health and safety at work apply and to which members of the public do not have regular access
[SOURCE: Directive 2008/50/EC] [6]
3.1.2
calibration
operation that, under specified conditions, in a first step, establishes a relation between the quantity values
with measurement uncertainties provided by measurement standards and corresponding indications with
associated measurement uncertainties and, in a second step, uses this information to establish a relation for
obtaining a measurement result from an indication
[SOURCE: JCGM 200]
3.1.3
combined standard uncertainty
standard uncertainty of the result of a measurement when that result is obtained from the values of a number
of other quantities, equal to the positive square root of a sum of terms, the terms being the variances or
covariances of these other quantities weighted according to how the measurement result varies with changes
in these quantities
[SOURCE: JCGM 100]
3.1.4
coverage factor
numerical factor used as a multiplier of the combined standard uncertainty in order to obtain an expanded
uncertainty
[SOURCE: JCGM 100]
3.1.5
expanded uncertainty
quantity defining an interval about the result of a measurement that may be expected to encompass a large
fraction of the distribution of values that could reasonably be attributed to the measurand
Note 1 to entry: The fraction may be viewed as the coverage probability or level of confidence of the interval.
Note 2 to entry: To associate a specific level of confidence with the interval defined by the expanded uncertainty
requires explicit or implicit assumptions regarding the probability distribution characterized by the measurement result and
its combined standard uncertainty. The level of confidence that may be attributed to this interval can be known only to the
extent to which such assumptions may be justified.
[SOURCE: JCGM 100]
3.1.6
field blank
filter that undergoes the same procedures of conditioning and weighing as a sample filter, including transport
to and from, and storage in the field, but is not used for sampling air
Note to entry: A field blank is sometimes also called a procedure blank.
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3.1.7
weighing room blank
filter that undergoes the same procedures of conditioning and weighing as a sample filter, but is stored in the
weighing room
3.1.8
limit value
level fixed on the basis of scientific knowledge, with the aim of avoiding, preventing or reducing harmful effects
on human health and/or the environment as a whole, to be attained within a given period and not to be
exceeded once attained
[SOURCE: 2008/50/EC] [6]
3.1.9
monitoring station
enclosure located in the field in which a sampler has been installed to measure particulate matter in such a
way that its performance and operation comply with the prescribed requirements
3.1.10
parallel measurement
measurements from measuring systems, sampling from the same air over the same time period
3.1.11
performance characteristic
one of the parameters assigned to a sampler in order to define its performance
3.1.12
performance criterion
limiting quantitative numerical value assigned to a performance characteristic, to which conformance is tested
3.1.13
period of unattended operation
time period over which the sampler can be operated without requiring operator intervention
3.1.14
PM
x
particulate matter suspended in air which passes through a size-selective inlet with a 50 % efficiency cut-off at
x µm aerodynamic diameter
Note 1 to entry: By convention, the size-selective standard inlet designs prescribed in this European Standard – used
at the prescribed flow rates – possess the required characteristics to sample the relevant PM fraction suspended in
ambient air.
Note 2 to entry: The efficiency of the size selectiveness of other inlets used may have a significant effect on the
fraction of PM surrounding the cut-off, and, consequently on the mass concentration of PMx determined.
3.1.15
reference method
RM
measurement method(ology) which, by convention, gives the accepted reference value of the measurand
3.1.16
sampled air
ambient air that has been sampled through the sampling inlet and sampling system
3.1.17
sampling inlet
entrance to the sampling system where ambient air is collected from the atmosphere
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3.1.18
standard uncertainty
uncertainty of the result of a measurement expressed as a standard deviation
[SOURCE: JCGM 100]
3.1.19
suspended particulate matter
SPM
notion of all particles surrounded by air in a given, undisturbed volume of air
3.1.20
time coverage
percentage of the reference period of the relevant limit value for which valid data for aggregation have been
collected
3.1.21
uncertainty (of measurement)
parameter associated with the result of a measurement that characterises the dispersion of the values that
could reasonably be attributed to the measurand
[SOURCE: JCGM 100]
3.2 Symbols and abbreviations
For the purposes of this document, the following symbols and abbreviated terms apply.
Flow rate related to standard conditions
ϕ
Flow rate related to ambient conditions (T , P )
a a
ϕ
a
∆P Pressure difference determined for the time interval ∆t (leak test)
∆t Time interval needed for the pressure rise (leak test)
3
C Concentration of PM (µg/m ) at ambient conditions
k Coverage factor
m Filter mass
m Mass of blank conditioned filter
c
m Mass of sampled filter
l
m Mass of sampled and conditioned filter
s
m Mass of unsampled filter
u
P Pressure at t=0 (leak test)
0
P Ambient pressure
a
t Sampling time
T Ambient temperature
a
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u Standard uncertainty
u Between-sampler uncertainty
bs
u Uncertainty of flow
f
U Uncertainty due to the effect of humidity on a blank filter
mfb
u Uncertainty due to hysteresis effects on mass of PM
mh
Uncertainty of the mass of PM (ml – mu)
um
u Uncertainty due to buoyancy
mb
Uncertainty due to balance calibration
u
mba
u Uncertainty due to contamination
mc
u Uncertainty due to lack of filter efficiency
mfe
u Uncertainty due to the interaction with gases
mg
Uncertainty due to the effect of humidity on particulate matter
umhp
u Uncertainty due to inlet performance
mip
Uncertainty of the mass of a sampled filter
u
ml
u Uncertainty due to static charging of the filter
ms
u Uncertainty due to losses of PM on transport and storage
mtl
u Uncertainty of the mass of an unsampled filter
mu
Uncertainty due to balance zero drift
umzd
Leak flow rate (leak test)
ϕ
L
V Estimated total volume of the system (dead volume)
sys
w Relative uncertainty
W Expanded relative uncertainty
x Individual measurement result from a sampler
i
u Uncertainty due to flow calibration
fc
u Uncertainty due to flow drift
fd
u Uncertainty of sample time
t
EU European Union
GDE Guide to the Demonstration of Equivalence of Ambient Air Monitoring Methods
GUM Guide to the Expression of Uncertainty in Measurement
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JCGM Joint Committee for Guides in Metrology
PM Particulate Matter
POM Polyoxymethylene
PTFE Polytetrafluoroethylene
QA/QC Quality Assurance / Quality Control
RH Relative Humidity
RM Reference Method(ology)
SPM Suspended Particulate Matter
4 Principle
4.1 Description of the standard measuring principle
Ambient air is passed through a size-selective inlet at a known, constant flow rate. The relevant PM fraction is
collected on a filter for a known period of nominally 24 h. The mass of the PM material is determined by
weighing the filter at pre-specified, constant conditions before and after collection of the particulate matter.
Key factors which can affect the result of the measurement, and which are addressed by the procedures
prescribed within this European Standard, include
 (variations in) the design and construction of the size-selective inlet;
 the sampling flow rate;
 deposition losses of PM within the pipework between the inlet and the filter;
 uncontrolled losses within the pipework between the inlet and the filter, and on the filter due to
volatilisation of water and semi-volatile PM at any time between collection and weighing;
 changes in weight of the filters or PM due to, e.g. adsorption of water and semi-volatile compounds,
spurious addition or loss of material, buoyancy, or static electricity.
In order to minimize the effects of these factors, this European Standard gives requirements for a series of
parameters that determine the magnitudes of these effects.
4.2 Initial use and procedures for ongoing QA/QC
QA/QC procedures are described for sample collection, filter transport and handling, and filter weighing.
The quality assurance/quality control (QA/QC) procedures within this European Standard are separated into
those activities typically carried out with each measurement, and those carried out less frequently.
QA/QC procedures which are used for each measurement, including filter handling and conditioning, weighing
room conditions, proper functioning of the weighing instrument, and the use of blank filters, are described in
Clause 6.
It is of particular importance that the facilities used for the weighing of the filters before and after sampling fulfil
the requirements of this European Standard. Consequently, a series of tests is described through which the
user may ensure the proper operation of the facilities.
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Additional QA/QC procedures which are used on a less frequent basis, including flow calibration, calibration of
the weighing instrument, and maintenance (inlet cleaning) and leak testing of the sampling system, are
described in Clause 7.
5 Equipment and facilities
5.1 Sampling system components
5.1.1 General
This European Standard describes the designs for the sampling systems to be used within the standard
method.
Sequential sampling systems for the standard measurement methods for PM and PM typically consist of
10 2,5
the following elements, illustrated schematically in Figure 1:
 size-selective inlets, whose designs are prescribed in 5.1.2;
 connecting pipe-work between the inlet and the filter holder, described in 5.1.3;
 filter holder and filter, described in 5.1.4;
 flow control system, given by performance specifications in 5.1.5;
1)
 sample changer ;
)
1
 storage facility for filters in the sampler .
NOTE 1 There are two different filter storage facilities commercially available: in Alternative 1 the unsampled filter is
taken from the left blank filter magazine and – after the 24 h loading period – the sampled filter is moved to the sampled
filter magazine in the right (see Figure 1, Alternative 1). In Alternative 2 there is only one combined blank and sampled
filter magazine from which the unsampled filter is taken and where - after the 24 h loading period - the sampled filter is
moved back to (see Figure 1, Alternative 2).
NOTE 2 The sheath air cooling system in Figure 1 is optional (see 5.1.3 and B.1).

1) For single-filter samplers the sample changer and storage facilities are not required.
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Key
sheath air inlet and container/tube system (optional)
sampled filter magazine and systematic path of blank/sampled filter (Alternative 1)
systematic path of blank/sampled filter (Alternative 2)
1 air sample (T , P )
a a
2 impactor inlet
3 connecting pipework
4 sheath air inlet (optional)
5 filter holder
6 flow measuring device
7 pump
8 flow control system
9 measurement of temperature T and pressure P
a a
10 measurement of temperature T and pressure P

11 sample changer and filter storage
12 measurement of storage temperature
T ambient temperature
a
P ambient pressure
a
ϕ flow rate related to ambient conditions (T , P )
a a a
Figure 1 — Scheme of PM standard sampler

ϕ and ϕ are related as in Formula (1):
a
T P
a
ϕ =ϕ × × (1)
a
T P
a
where
T is the temperature in the flow measuring device, in Kelvin (K);
T is the ambient temperature, in Kelvin (K);
a
P is the pressure in the flow measuring device, in kilopascal (kPa);
P is the ambient pressure, in kilopascal (kPa).
a
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Requirements for the correct operation of the sampling system are specified in Table 1.
Table 1 — Requirements for sampling equipment
Design/performance a Clause

Requirement
characteristic
1 Inlet design As prescribed 5.1.2
2 Temperature of filter during Within 5 °C of ambient temperature for ambient 5.1.4
sampling temperatures ≥ 20 °C
3
3 Nominal flow rate 2,3 m /h at ambient conditions 5.1.5
4 Constancy of sample volumetric 5.1.5
≤ 2,0 % sampling time (averaged flow)
flow
≤ 5,0 % rated flow (instantaneous flow)
5 Leak tightness of the sampling 5.1.7
ϕ ≤ 1,0 % of sample flow rate
L
system
6 Single-filter sampling period 5.1.6
24 h ± 1 h
7 Uncertainty (95 % confidence) of 5.1.6
≤ 5 min
sampling time measurement
8 Uncertainty (95 % confidence) of 5.1.5
≤ 3 K
sensor for ambient temperature
measurement
9 Uncertainty (95 % confidence) of 5.1.5
≤ 1 kPa
sensor for ambient pressure
measurement
10 Uncertainty (95 % confidence) of 5.1.5
≤ 3 K
sensors for internal temperatures

(filter during sampling; filter
during storage)
11 Temperature
...