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SIST ISO 13163:2013

Water quality - Lead-210 - Test method using liquid scintillation counting

Water quality - Lead-210 - Test method using liquid scintillation counting

ISO 13163 specifies the determination of lead-210 (210Pb) activity concentration in samples of all types of water using liquid scintillation counting (LSC). For raw and drinking water, the sample should be degassed in order to minimize the ingrowth of 210Pb from radon-222 (222Rn).
Using currently available liquid scintillation counters, this test method can measure the 210Pb activity concentrations in the range of less than 20 mBq⋅l-1 to 50 mBq⋅l-1. These values can be achieved with a counting time between 180 min and 720 min for a sample volume from 0,5 l to 1,5 l.
Higher 210Pb activity concentrations can be measured by either diluting the sample or using smaller sample aliquots or both.
It is the laboratory's responsibility to ensure the suitability of this test method for the water samples tested.

Qualité de l'eau - Plomb 210 - Méthode d'essai par comptage des scintillations en milieu liquide

L'ISO 13163:2013 spécifie la détermination de l'activité volumique du plomb 210 dans des échantillons de tout type d'eau par comptage en scintillation liquide (CSL). Pour les eaux brutes et les eaux potables, il convient que l'échantillon soit dégazé afin de limiter la re-croissance du plomb 210 à partir du radon 222 .
À l'aide d'un compteur à scintillation liquide standard, cette méthode d'essai peut mesurer les valeurs d'activité volumique du plomb 210 sur un domaine allant de moins de 20 mBq/l à 50 mBq/l. Ces valeurs peuvent être atteintes avec un temps de comptage compris entre 180 min et 720 min pour une prise d'essai de 0,5 l à 1,5 l.
Des valeurs plus élevées d'activité volumique du plomb 210 peuvent être mesurées en effectuant une dilution de l'échantillon et/ou en utilisant des aliquotes plus petites.

Kakovost vode - Svinec Pb-210 - Preskusna metoda s štetjem s tekočinskim scintilatorjem

ISO 13163 določa metodo za določevanje koncentracije aktivnosti svinca 210 (210Pb) v vzorcih vseh vrst vode s štetjem s tekočinskim scintilatorjem (LSC). Pri neobdelani in pitni vodi mora biti vzorec razplinjen za zmanjševanje vraščanja svinca 210 iz radona 222 (222Rn). S števci s tekočinskim scintilatorjem lahko s to preskusno metodo izmerite koncentracijo aktivnosti svinca 210 v razponu od manj kot 20 mBq•l-1 do 50 mBq•l-1. Te vrednosti se lahko dosežejo v času štetja med 180 in 720 min za količino vzorca od 0,5 do 1,5 l. Višje koncentracije aktivnosti svinca 210 se lahko izmerijo z redčenjem vzorca ali raztopinami manjših vzorcev ali obojim. Laboratorij mora zagotoviti primernost te preskusne metode za vzorce vode, ki se testirajo.

General Information

Status
Withdrawn
Public Enquiry End Date
30-Sep-2013
Publication Date
11-Nov-2013
Withdrawal Date
15-Aug-2022
ICS
13.060.60 - Examination of physical properties of water
17.240 - Radiation measurements
Technical Committee
KAV - Water quality
Current Stage
9900 - Withdrawal (Adopted Project)
Start Date
01-Aug-2022
Due Date
24-Aug-2022
Completion Date
16-Aug-2022
Ref Project
ISO 13163:2013 - Water quality — Lead-210 — Test method using liquid scintillation counting

Relations

Replaced By
SIST EN ISO 13163:2022 - Water quality - Lead-210 - Test method using liquid scintillation counting (ISO 13163:2021)
Effective Date
01-Sep-2022

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Standards Content (Sample)


SLOVENSKI STANDARD
01-december-2013
.DNRYRVWYRGH6YLQHF3E3UHVNXVQDPHWRGDVãWHWMHPVWHNRþLQVNLP
VFLQWLODWRUMHP
Water quality - Lead-210 - Test method using liquid scintillation counting
Qualité de l'eau - Plomb 210 - Méthode d'essai par comptage des scintillations en milieu
liquide
Ta slovenski standard je istoveten z: ISO 13163:2013
ICS:
13.060.60 Preiskava fizikalnih lastnosti Examination of physical
vode properties of water
17.240 Merjenje sevanja Radiation measurements
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

INTERNATIONAL ISO
STANDARD 13163
First edition
2013-10-15
Water quality — Lead-210 — Test
method using liquid scintillation
counting
Qualité de l’eau — Plomb 210 — Méthode d’essai par comptage des
scintillations en milieu liquide
Reference number
©
ISO 2013
© ISO 2013
All rights reserved. Unless otherwise specified, 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 the internet or an intranet, without prior
written permission. Permission can be requested from either ISO at the address below or ISO’s member body in the country of
the requester.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Published in Switzerland
ii © ISO 2013 – All rights reserved

Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Symbols . 2
4 Principle . 3
5 Reagents and equipment . 4
6 Sampling and storage . 5
6.1 Sampling . 5
6.2 Sample storage . 5
7 Procedure. 5
7.1 Sample preparation . 6
7.2 Preconcentration . 6
7.3 Separation of Pb . 7
7.4 Measurement . 8
8 Quality assurance and quality control programme . 9
8.1 General . 9
8.2 Influencing variables . 9
8.3 Instrument verification.10
8.4 Contamination .10
8.5 Method verification .10
8.6 Demonstration of analyst capability .10
9 Expression of results .10
9.1 General .10
9.2 Yield determination .11
9.3 Calculation of activity concentration .12
9.4 Decision threshold .13
9.5 Detection limit .13
9.6 Confidence interval limits.13
10 Test report .14
Annex A (informative) Spectra examples .15
Bibliography .17
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. 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. 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.
The committee responsible for this document is ISO/TC 147, Water quality, Subcommittee SC 3,
Radioactivity measurements.
iv © ISO 2013 – All rights reserved

Introduction
Radioactivity from several naturally occurring and anthropogenic sources is present throughout the
environment. Thus, water bodies (e.g. surface water, groundwater, seawater) can contain the following
radionuclides of natural or human-made origins:
— natural radionuclides, including potassium-40, and those originating from the thorium and uranium
decay series, particularly radium-226, radium-228, uranium-234, uranium-238, and lead-210, can
be found in water for natural reasons (e.g. desorption from the soil and wash-off by rain water) or
can be released from technological processes involving naturally occurring radioactive materials
(e.g. the mining and processing of mineral sands or the production and use of phosphate fertilizer);
— human-made radionuclides, such as transuranium elements (americium, plutonium, neptunium,
curium), tritium, carbon-14, strontium-90, and gamma-emitting radionuclides, can also be found in
natural waters as a result of authorized routine releases into the environment in small quantities of
the effluent discharged from nuclear fuel cycle facilities. They are also released into the environment
following their use in unsealed form for medical and industrial applications. They are also found in
the water as a result of past fallout contamination resulting from the explosion in the atmosphere of
nuclear devices and accidents such as those that occurred in Chernobyl and Fukushima.
Drinking water may thus contain radionuclides at activity concentrations which could present a risk
to human health. In order to assess the quality of drinking water (including mineral waters and spring
waters) with respect to its radionuclide content and to provide guidance on reducing health risks by
taking measures to decrease radionuclide activity concentrations, water resources (groundwater, river,
lake, sea, etc.) and drinking water are monitored for their radioactivity content as recommended by the
World Health Organization [WHO] and required by some national authorities.
An International Standard on a test method for lead-210 activity concentrations in water samples is
justified for test laboratories carrying out these measurements, required sometimes by national
authorities, as laboratories may have to obtain a specific accreditation for radionuclide measurement in
drinking water samples.
Lead-210 activity concentration can vary according to local geological and climatic characteristics and
-1 -1
usually ranges from 2 mBq⋅l to 300 mBq⋅l (References [12][13]). The guidance level for lead-210 in
-1
drinking water, as recommended by WHO, is 100 mBq⋅l (Reference [14]).
-1
NOTE The guidance level is the activity concentration with an intake of 2 l⋅day of drinking water for 1 year
-1
that results in an effective dose of 0,1 mSv⋅year for members of the public, an effective dose that represents a
very low level of risk that is not expected to give rise to any detectable adverse health effect.
INTERNATIONAL STANDARD ISO 13163:2013(E)
Water quality — Lead-210 — Test method using liquid
scintillation counting
WARNING — Persons using ISO 13163 should be familiar with normal laboratory practice.
ISO 13163 does not purport to address all of the safety problems, if any, associated with its use.
It is the responsibility of the user to establish appropriate safety and health practices and to
ensure compliance with any national regulatory conditions.
IMPORTANT — It is absolutely essential that tests conducted according to ISO 13163 be carried
out by suitably trained staff.
1 Scope
ISO 13163 specifies the determination of lead-210 ( Pb) activity concentration in samples of all types
of water using liquid scintillation counting (LSC). For raw and drinking water, the sample should be
210 222
degassed in order to minimize the ingrowth of Pb from radon-222 ( Rn).
Using currently available liquid scintillation counters, this test method can measure the Pb activity
-1 -1
concentrations in the range of less than 20 mBq⋅l to 50 mBq⋅l . These values can be achieved with a
counting time between 180 min and 720 min for a sample volume from 0,5 l to 1,5 l.
Higher Pb activity concentrations can be measured by either diluting the sample or using smaller
sample aliquots or both.
...


INTERNATIONAL ISO
STANDARD 13163
First edition
2013-10-15
Water quality — Lead-210 — Test
method using liquid scintillation
counting
Qualité de l’eau — Plomb 210 — Méthode d’essai par comptage des
scintillations en milieu liquide
Reference number
©
ISO 2013
© ISO 2013
All rights reserved. Unless otherwise specified, 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 the internet or an intranet, without prior
written permission. Permission can be requested from either ISO at the address below or ISO’s member body in the country of
the requester.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Published in Switzerland
ii © ISO 2013 – All rights reserved

Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Symbols . 2
4 Principle . 3
5 Reagents and equipment . 4
6 Sampling and storage . 5
6.1 Sampling . 5
6.2 Sample storage . 5
7 Procedure. 5
7.1 Sample preparation . 6
7.2 Preconcentration . 6
7.3 Separation of Pb . 7
7.4 Measurement . 8
8 Quality assurance and quality control programme . 9
8.1 General . 9
8.2 Influencing variables . 9
8.3 Instrument verification.10
8.4 Contamination .10
8.5 Method verification .10
8.6 Demonstration of analyst capability .10
9 Expression of results .10
9.1 General .10
9.2 Yield determination .11
9.3 Calculation of activity concentration .12
9.4 Decision threshold .13
9.5 Detection limit .13
9.6 Confidence interval limits.13
10 Test report .14
Annex A (informative) Spectra examples .15
Bibliography .17
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. 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. 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.
The committee responsible for this document is ISO/TC 147, Water quality, Subcommittee SC 3,
Radioactivity measurements.
iv © ISO 2013 – All rights reserved

Introduction
Radioactivity from several naturally occurring and anthropogenic sources is present throughout the
environment. Thus, water bodies (e.g. surface water, groundwater, seawater) can contain the following
radionuclides of natural or human-made origins:
— natural radionuclides, including potassium-40, and those originating from the thorium and uranium
decay series, particularly radium-226, radium-228, uranium-234, uranium-238, and lead-210, can
be found in water for natural reasons (e.g. desorption from the soil and wash-off by rain water) or
can be released from technological processes involving naturally occurring radioactive materials
(e.g. the mining and processing of mineral sands or the production and use of phosphate fertilizer);
— human-made radionuclides, such as transuranium elements (americium, plutonium, neptunium,
curium), tritium, carbon-14, strontium-90, and gamma-emitting radionuclides, can also be found in
natural waters as a result of authorized routine releases into the environment in small quantities of
the effluent discharged from nuclear fuel cycle facilities. They are also released into the environment
following their use in unsealed form for medical and industrial applications. They are also found in
the water as a result of past fallout contamination resulting from the explosion in the atmosphere of
nuclear devices and accidents such as those that occurred in Chernobyl and Fukushima.
Drinking water may thus contain radionuclides at activity concentrations which could present a risk
to human health. In order to assess the quality of drinking water (including mineral waters and spring
waters) with respect to its radionuclide content and to provide guidance on reducing health risks by
taking measures to decrease radionuclide activity concentrations, water resources (groundwater, river,
lake, sea, etc.) and drinking water are monitored for their radioactivity content as recommended by the
World Health Organization [WHO] and required by some national authorities.
An International Standard on a test method for lead-210 activity concentrations in water samples is
justified for test laboratories carrying out these measurements, required sometimes by national
authorities, as laboratories may have to obtain a specific accreditation for radionuclide measurement in
drinking water samples.
Lead-210 activity concentration can vary according to local geological and climatic characteristics and
-1 -1
usually ranges from 2 mBq⋅l to 300 mBq⋅l (References [12][13]). The guidance level for lead-210 in
-1
drinking water, as recommended by WHO, is 100 mBq⋅l (Reference [14]).
-1
NOTE The guidance level is the activity concentration with an intake of 2 l⋅day of drinking water for 1 year
-1
that results in an effective dose of 0,1 mSv⋅year for members of the public, an effective dose that represents a
very low level of risk that is not expected to give rise to any detectable adverse health effect.
INTERNATIONAL STANDARD ISO 13163:2013(E)
Water quality — Lead-210 — Test method using liquid
scintillation counting
WARNING — Persons using ISO 13163 should be familiar with normal laboratory practice.
ISO 13163 does not purport to address all of the safety problems, if any, associated with its use.
It is the responsibility of the user to establish appropriate safety and health practices and to
ensure compliance with any national regulatory conditions.
IMPORTANT — It is absolutely essential that tests conducted according to ISO 13163 be carried
out by suitably trained staff.
1 Scope
ISO 13163 specifies the determination of lead-210 ( Pb) activity concentration in samples of all types
of water using liquid scintillation counting (LSC). For raw and drinking water, the sample should be
210 222
degassed in order to minimize the ingrowth of Pb from radon-222 ( Rn).
Using currently available liquid scintillation counters, this test method can measure the Pb activity
-1 -1
concentrations in the range of less than 20 mBq⋅l to 50 mBq⋅l . These values can be achieved with a
counting time between 180 min and 720 min for a sample volume from 0,5 l to 1,5 l.
Higher Pb activity concentrations can be measured by either diluting the sample or using smaller
sample aliquots or both.
It is the laboratory’s responsibility to ensure the suitability of this test method for the water samples tested.
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.
ISO/IEC Guide 98-3, Uncertainty of measurement — Part 3: Guide to the expression of uncertainty in
measurement (GUM:1995)
ISO/IEC Guide 99, International vocabulary of metrology — Basic and general concepts and associated
terms (VIM)
ISO/IEC 17025, General requirements for the competence of testing and calibration laboratories
ISO 5667-3, Water quality — Sampling — Part 3: Preservation and handling of water samples
ISO 11929, Determination of the characteristic limits (decision threshold, detection limit and limits of the
confidence interval) for measureme
...


NORME ISO
INTERNATIONALE 13163
Première édition
2013-10-15
Qualité de l’eau — Plomb 210 —
Méthode d’essai par comptage des
scintillations en milieu liquide
Water quality — Lead-210 — Test method using liquid
scintillation counting
Numéro de référence
©
ISO 2013
DOCUMENT PROTÉGÉ PAR COPYRIGHT
© ISO 2013
Droits de reproduction réservés. Sauf indication contraire, aucune partie de cette publication ne peut être reproduite ni utilisée
sous quelque forme que ce soit et par aucun procédé, électronique ou mécanique, y compris la photocopie, l’affichage sur
l’internet ou sur un Intranet, sans autorisation écrite préalable. Les demandes d’autorisation peuvent être adressées à l’ISO à
l’adresse ci-après ou au comité membre de l’ISO dans le pays du demandeur.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Publié en Suisse
ii © ISO 2013 – Tous droits réservés

Sommaire Page
Avant-propos .iv
Introduction .v
1 Domaine d’application . 1
2 Références normatives . 1
3 Symboles . 2
4 Principe . 3
5 Réactifs et matériel . 4
6 Échantillonnage et conservation . 5
6.1 Prélèvement de l’échantillon . 5
6.2 Conservation des échantillons . . 5
7 Mode opératoire. 5
7.1 Préparation de l’échantillon . 6
7.2 Pré-concentration . 6
7.3 Séparation du Pb . 7
7.4 Mesurage . 9
8 Programme d’assurance qualité et de contrôle de la qualité .10
8.1 Généralités .10
8.2 Variables d’influence .10
8.3 Vérification des instruments .11
8.4 Contamination .11
8.5 Vérification de la méthode .11
8.6 Démonstration de l’aptitude de l’analyste .11
9 Expression des résultats.11
9.1 Généralités .11
9.2 Détermination des rendements.12
9.3 Calcul de l’activité volumique.12
9.4 Seuil de décision .13
9.5 Limite de détection .14
9.6 Limites de l’intervalle de confiance .14
10 Rapport d’essai .14
Annexe A (informative) Exemples de spectres .16
Bibliographie .18
Avant-propos
L’ISO (Organisation internationale de normalisation) est une fédération mondiale d’organismes
nationaux de normalisation (comités membres de l’ISO). L’élaboration des Normes internationales est
en général confiée aux comités techniques de l’ISO. Chaque comité membre intéressé par une étude
a le droit de faire partie du comité technique créé à cet effet. Les organisations internationales,
gouvernementales et non gouvernementales, en liaison avec l’ISO participent également aux travaux.
L’ISO collabore étroitement avec la Commission électrotechnique internationale (CEI) en ce qui concerne
la normalisation électrotechnique.
Les procédures utilisées pour élaborer le présent document et celles destinées à sa mise à jour sont
décrites dans les Directives ISO/CEI, Partie 1. Il convient, en particulier, de prendre note des différents
critères d’approbation requis pour les différents types de documents ISO. Le présent document a été
rédigé conformément aux règles de rédaction données dans les Directives ISO/CEI, Partie 2, www.iso.
org/directives.
L’attention est appelée sur le fait que certains des éléments du présent document peuvent faire l’objet de
droits de propriété intellectuelle ou de droits analogues. L’ISO ne saurait être tenue pour responsable
de ne pas avoir identifié de tels droits de propriété et averti de leur existence. Les détails concernant les
références aux droits de propriété intellectuelle ou autres droits analogues identifiés lors de l’élaboration
du document sont indiqués dans l’Introduction et/ou sur la liste ISO des déclarations de brevets reçues,
www.iso.org/brevets.
Les éventuelles appellations commerciales utilisées dans le présent document sont données pour
information à l’intention des utilisateurs et ne constituent pas une approbation ou une recommandation.
Le comité chargé de l’élaboration du présent document est l’ISO/TC 147, Qualité de l’eau, sous-comité
SC 3, Mesurages de la radioactivité.
iv © ISO 2013 – Tous droits réservés

Introduction
La radioactivité, d’origine naturelle et anthropique est présente partout dans l’environnement. Par
conséquent, les eaux (par exemple les eaux de surface, les eaux souterraines, l’eau de mer) peuvent
contenir les radionucléides suivants d’origine naturelle ou artificielle:
— les radionucléides naturels, y compris le potassium 40, et ceux issus des chaînes de désintégration
du thorium et de l’uranium, notamment le radium 226, le radium 228, l’uranium 234, l’uranium 238
et le plomb 210, peuvent se trouver naturellement dans l’eau (par exemple par désorption du sol
ou lessivage par les eaux pluviales) ou peuvent être libérés par des processus technologiques
impliquant des matières radioactives naturelles (par exemple extraction minière et traitement de
sables minéraux ou production et utilisation d’engrais phosphatés);
— les radionucléides artificiels, tels que les éléments transuraniens (américium, plutonium, neptunium,
curium), le tritium, le carbone 14, le strontium 90 et les radionucléides émetteurs gamma peuvent
aussi se trouver dans les eaux naturelles car la réglementation autorise leur libération périodique
dans l’environnement en faibles quantités dans les effluents rejetés par les installations de
retraitement du combustible nucléaire. Ils sont également libérés dans l’environnement suite à
leur utilisation sous forme non scellée en médecine nucléaire et dans des applications industrielles.
Ils sont aussi présents dans l’eau suite aux retombées des essais nucléaires en atmosphère et aux
accidents nucléaires tels que ceux qui se sont produits à Tchernobyl et Fukushima.
L’eau potable peut donc contenir des radionucléides à des valeurs d’activité volumique susceptibles de
présenter un risque pour la santé humaine. Afin d’évaluer la qualité de l’eau potable (y compris les eaux
minérales et les eaux de source) en fonction de sa teneur en radionucléides et de fournir des lignes
directrices pour réduire les risques pour la santé en prenant des dispositions visant à réduire les valeurs
d’activité volumique des radionucléides, la radioactivité des ressources en eau (eaux souterraines,
rivières, lacs, mers, etc.) et des eaux potables est surveillée conformément aux recommandations de
l’Organisation mondiale de la santé (OMS) et aux exigences de certaines autorités nationales.
Une Norme internationale spécifiant une méthode d’essai concernant les valeurs d’activité volumique du
plomb 210 dans les échantillons d’eau est justifiée pour les laboratoires d’essais réalisant ces mesures et
qui sont parfois tenus d’obtenir une accréditation spécifique des autorités nationales pour la réalisation
de mesures de radionucléides dans les échantillons d’eau potable.
L’activité volumique du plomb 210 peut varier selon les caractéristiques géologiques et climatiques
−1 −1
locales et se situe généralement entre 2 mBq·l et 300 mBq·l (Références [12][13]) Le niveau de
-1
plomb 210 dans l’eau potable recommandé par l’OMS est de 100 mBq·l (Référence [14]).
NOTE Le niveau recommandé est l’activité volumique correspondant à l’absorption de 2 l/jour d’eau potable
pendant 1 an, qui donne une dose efficace de 0,1 mSv/an pour le public, c’est-à-dire une dose efficace présentant
un très faible niveau de risque et censée ne donner lieu à aucun effet nocif notable pour la santé.
NORME INTERNATIONALE ISO 13163:2013(F)
Qualité de l’eau — Plomb 210 — Méthode d’essai par
comptage des scintillations en milieu liquide
AVERTISSEMENT — Il convient que l’utilisateur de la présente Norme internationale connaisse
bien les pratiques courantes de laboratoire. La présente Norme internationale n’a pas pour but
de traiter tous les problèmes de sécurité qui sont, le cas échéant, liés à son utilisation. Il incombe
à l’utilisateur d’établir des pratiques appropriées en matière d’hygiène et de sécurité, et de
s’assurer de la conformité à la réglementation nationale en vigueur.
IMPORTANT — Il est absolument essentiel que les essais réalisés conformément à la présente
Norme internationale soient exécutés par un personnel ayant reçu une formation adéquate.
1 Domaine d’application
La présente Norme internationale spécifie la détermination de l’activité volumique du plomb 210 ( Pb)
dans des échantillons de tout type d’eau par comptage en scintillation liquide (CSL). Pour les eaux brutes
et les eaux potables, il convient que l’échantillon soit dégazé afin de limiter la re-croissance du Pb à
partir du radon 222 ( Rn).
À l’aide d’un compteur à scintillation liquide standard, cette méthode d’essai peut mesurer les valeurs
−1 −1
d’activité volumique du plomb 210 sur un domaine allant de moins de 20 mBq·l à 50 mBq·l . Ces
valeurs peuvent être atteintes avec un temps de comptage compris entre 180 min et 720 min pour une
prise d’essai de 0,5 l à 1,5 l.
Des valeurs plus élevées d’activité volumique du plomb 210 peuvent être mesurées en effectuant une
dilution de l’échantillon et/ou en utilisant des aliquotes plus petites.
Il incombe au laboratoire de s’assurer de la pertinence de la présente méthode d’essai pour les échantillons
d’
...


МЕЖДУНАРОДНЫЙ ISO
СТАНДАРТ 13163
Первое издание
2013-10-15
Качество воды. Свинец-210. Метод
испытания с использованием
жидкостного сцинтилляционного
счетчика
Water quality —Lead-210 — Test method using liquid scintillation counting
.
Ответственность за подготовку русской версии несёт GOST R
(Российская Федерация) в соответствии со статьёй 18.1 Устава ISO
Ссылочный номер
©
ISO 2013
ДОКУМЕНТ ЗАЩИЩЕН АВТОРСКИМ ПРАВОМ

©  ISO 2013
Все права сохраняются. Если не задано иначе, никакую часть настоящей публикации нельзя копировать или использовать в
какой-либо форме или каким-либо электронным или механическим способом, включая фотокопии и микрофильмы, без
предварительного письменного согласия офиса ISO по адресу, указанному ниже, или членов ISO в стране регистрации
пребывания.
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Опубликовано в Швейцарии
ii © ISO 2013 – Все права сохраняются

Содержание Страница
Предисловие .iv
1 Область применения .1
2 Нормативные ссылки .1
3 Условные обозначения .2
4 Сущность метода.3
5 Реактивы и оборудование.4
6 Отбор и хранение проб.5
6.1 Отбор проб .5
6.2 Хранение проб.5
7 Процедура.5
7.1 Приготовление образцов.6
7.2 Концентрирование .6
7.3 Отделение Pb .7
7.4 Измерение .9
8 Программа обеспечения качества и управления качеством.10
8.1 Общие вопросы.10
8.2 Влияющие переменные.10
8.3 Верификация прибора.10
8.4 Загрязнение.11
8.5 Верификация метода.11
8.6 Демонстрация способности аналитика.11
9 Выражение результатов .11
9.1 Общие вопросы.11
9.2 Определение выхода.12
9.3 Вычисление удельной объемной активности.12
9.4 Порог принятия решения.14
9.5 Предел обнаружения.14
9.6 Пределы доверительного интервала.15
10 Протокол испытания.15
Приложение А (информативное) Примеры спектров.17
Библиография.19

© ISO и IDF 2013 – Все права сохраняются iii

Предисловие
Международная организация по стандартизации (ISO) является Всемирной федерацией национальных
организаций по стандартизации (комитетов-членов ISO). Разработка международных стандартов
обычно осуществляется техническими комитетами ISO. Каждый комитет-член, заинтересованный в
деятельности, для которой был создан технический комитет, имеет право быть представленным в этом
комитете. Международные правительственные и неправительственные организации, имеющие связи с
ISO, также принимают участие в работах. Что касается стандартизации в области электротехники, ISO
работает в тесном сотрудничестве с Международной электротехнической комиссией (IEC).
Процедуры, используемые для разработки настоящего документа, и процедуры, предназначенные для
его последующего ведения, описаны в Директивах ISO/IEC, Часть 1. В частности, должны быть
указаны разные критерии подхода к различным типам документов ISO. Проект настоящего документа
был разработан по редакционным правилам, указанным в Директивах ISO/IEC, Часть 2.
www.iso.org/directives
Обращается внимание на возможность того, что некоторые элементы данного международного
стандарта могут быть объектом патентных прав. ISO не несет ответственности за идентификацию
какого-либо или всех таких патентных прав. Детали любых патентных прав, идентифицированных при
разработке настоящего документа, будут указаны во введении или в списке ISO полученных патентных
деклараций. www.iso.org/patents
Любое фирменное название, используемое в этом документе, указывается только как информация для
удобства пользователей и не является рекомендацией.
Комитетом, ответственным за этот документ, является ISO/TC 147, Качество воды, Подкомитет SC 5,
Измерения радиоактивности.
iv © ISO и IDF 2013 – Все права сохраняются

Введение
Радиоактивность в окружающей среде обусловлена повсеместным присутствием различных
естественных и антропогенных источников ионизирующего излучения. Следовательно, водные
объекты (например, поверхностные, грунтовые и сточные воды) могут содержать нижеприведенные
радионуклиды естественного и искусственного происхождения:
— естественные радионуклиды, включающие калий-40 и радионуклиды, образующиеся из рядов
радиоактивного распада тория и урана, в частности радий-226, радий-228, уран-234, уран-238 и
свинец-210, могут попадать в воду естественным путем (например, десорбция из почвы и
вымывание дождевой водой) или в результате выбросов технологических процессов, в которых
используются естественные радиоактивные материалы (например, добыча полезных ископаемых
и обработка минеральных песков или производство и использование фосфатных удобрений);
— искусственные радионуклиды, такие как трансурановые элементы (америций, плутоний, нептуний,
кюрий), тритий, углерод-14, стронций-90 и гамма-излучающие радионуклиды, могут попадать в
природные воды в результате санкционированных плановых выбросов в окружающую среду
небольших количеств промышленных отходов из предприятий ядерного топливного цикла. Их
также сбрасывают в окружающую среду после использования в негерметизированном виде для
медицинских и промышленных целей. Кроме того они встречаются в воде в виде загрязнения от
прошлых радиоактивных осадков, которые происходят в результате взрыва ядерных устройств в
атмосфере и аварий, таких как в Чернобыле и Фукусиме.
Питьевая вода может, таким образом, содержать радионуклиды с удельной активностью,
представляющей риск для здоровья человека. Чтобы оценить качество питьевой воды (включая
минеральную и родниковую воду) относительно содержания радионуклидов и дать руководящие
указания по уменьшению риска для здоровья путем принятия мер для уменьшения удельной
активности радионуклидов, проводят мониторинг радиоактивного загрязнения водных ресурсов
(грунтовых вод, рек, озер, морей и т.д.) и питьевой воды согласно рекомендациям Всемирной
организации здравоохранения [WHO] и требованиям некоторых федеральных властей.
Международный эталон для метода испытания удельной активности свинца-210 в водных пробах
подтвержден для испытательных лабораторий, выполняющих эти измерения, которые иногда
требуются федеральными органами власти, так как для измерения радионуклидов в пробах питьевой
воды лабораториям надо получить специальную аккредитацию.
Удельная активность свинца-210 может меняться в зависимости от местных геологических и
-1 -1
климатических характеристик и обычно колеблется в пределах от 2 мБк·л до 300 мБк·л (Ссылки
[12][13]). Требуемый уровень для свинца-210 в питьевой воде согласно рекомендациям WHO
-1
составляет 100 мБк·л (Ссылка [14]).
ПРИМЕЧАНИЕ Требуемым уровнем является удельная объемная активность при потреблении питьевой воды
-1 -1
2 л·день в течение 1 года, приводящая к эффективной дозе 0,1 мЗв·год для потребителей, которая
представляет очень низкую степень риска, не предполагающую какого-либо обнаруживаемого вредного влияния
на здоровье.
© ISO и IDF 2013 – Все права сохраняются v

МЕЖДУНАРОДНЫЙ СТАНДАРТ ISO 13163:2013(R)

Качество воды. Свинец-210. Метод испытания с
использованием жидкостного сцинтилляционного счетчика
ПРЕДУПРЕЖДЕНИЕ — Лица, использующие этот международный стандарт, должны быть
знакомы с нормальной лабораторной практикой. В настоящем международном стандарте не
предусматривается рассмотрение всех проблем безопасности, если таковые имеются,
связанных с его использованием. Пользователь сам должен установить надлежащие
нормативы по технике безопасности и защите здоровья и обеспечить их соответствие
условиям национального регулирования.
ВАЖНО — Абсолютно необходимо, чтобы испытания согласно этому международному
стандарту проводились соответственно обученным персоналом.
1 Область применения
ISO 13163 устанавливает метод определения удельной объемной активности свинца-210 ( Pb) в
пробах воды всех типов с использованием жидкостного сцинтилляционного счетчика (LSC). Пробы
сырой и питьевой воды следует дегазировать, для того чтобы свести к минимуму врастание Pb из
радона-222 ( Rn).
Используя имеющиеся в настоящее время жидкостные сцинтилляционные счетчики, этим методом
210 -1 -1
можно измерять удельную объемную активность Pb в диапазоне от менее 20 мБк·л до 50 мБк·л .
Эти значения могут быть получены за время счета от 180 мин до 720 мин для объема пробы от 0,5 л
до 1,5 л.
Более высокие значения удельной активности Pb могут быть измерены путем разбавления пробы
или путем использования меньших аликвот или тем и другим способом.
В обязанность лаборатории входит обеспечение пригодности этого метода испытания для
анализируемых проб воды
2 Нормативные ссылки
Следующие ссылочные нормативные документы целиком или частично являются обязательными при
применении данного документа. Для жестких ссылок применяется только цитированное издание
документа. Для плавающих ссылок необходимо использовать самое последнее издание нормативного
ссылочного документа (включая любые изменения).
ISO/IEC Guide 98-3, Неопределенность измерений. Часть 3. Руководство по выражению
неопределенности измерений (GUM:1995)
ISO/IEC Guide 99, Международный словарь по метрологии. Основные и общие понятия и
соответствующие термины (VIM)
ISO/IEC 17025, Общие требования к компетентности испытательных и калибровочных
лабораторий
ISO 5667-3, Качество воды. Отбор проб. Часть 1. Руководство по хранению и обращению с пробами
воды
ISO 11929, Определение предельных характеристик (порога принятия решения, предела
обнаружения и пределов доверительного интервала) для измерений ионизирующего излучения.
Основы и применение
ISO 80000-10, Величины и единицы. Часть 10. Атомная и ядерная физика
3 Условные обозначения
Применительно к настоящему документу используются условные обозначения, определения, единицы
и сокращения, определенные в ISO 80000-10, ISO 11929, ISO/IEC Guide 99, и нижеследующие.
C коэффициент врастания Bi до наступления равновесия в пробе за период между концом
coeff
элюирования висмута и началом времени счета
c удельная объемная активность в пробе, в беккерелях на литр
A
c удельная объемная активность эталона, в беккерелях на литр
A0
*
порог принятия решения, в беккерелях на литр
c
A
#
предел обнаружения, в беккерелях на литр
c
A
<>
нижний и верхний пределы доверительного интервала, в беккерелях на литр
cc,
AA
R химический выход
c
r скорость счета импульсов от холостого реактива, в обратных секундах
b
r скорость счета импульсов от образца, в обратных секундах
g
r калибровочная скорость счета, в обратных секундах
s
r фоновая скорость счета, в обратных секундах
S1 элюированный раствор, содержащий свинец
t время счета импульсов от образца, в секундах
g
t время калибровочного счета, в секундах
s
t время фонового счета, в секундах
U расширенная неопределенность, вычисленная по U = ku(c ) при k = 1, 2…, в беккерелях на литр
A
u(c ) стандартная неопределенность, связанная с результатом измерения, в беккерелях на литр
A
V объем элюированной фазы, в литрах
V общий объем испытательного образца вместе с носителем, в литрах
e
V объем эталонного испытательного образца, в литрах
s
V об
...

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This document specifies conditions for the determination of 90Sr and 89Sr activity concentration in samples of environmental water using liquid scintillation counting (LSC) or proportional counting (PC).
The method is applicable to test samples of drinking water, rainwater, surface and ground water, marine water, as well as cooling water, industrial water, domestic, and industrial wastewater after proper sampling and handling, and test sample preparation. Filtration of the test sample and a chemical separation are required to separate and purify strontium from a test portion of the sample.
The detection limit depends on the sample volume, the instrument used, the sample count time, the background count rate, the detection efficiency and the chemical yield. The method described in this document, using currently available LSC counters, has a detection limit of approximately 10 mBq l−1 and 2 mBq l−1 for 89Sr and 90Sr, respectively, which is lower than the WHO criteria for safe consumption of drinking water (100 Bq·l−1 for 89Sr and 10 Bq·l−1 for 90Sr)[3]. These values can be achieved with a counting time of 1 000 min for a sample volume of 2 l.
The methods described in this document are applicable in the event of an emergency situation. When fallout occurs following a nuclear accident, the contribution of 89Sr to the total amount of radioactive strontium is not negligible. This document provides test methods to determine the activity concentration of 90Sr in presence of 89Sr.
The analysis of 90Sr and 89Sr adsorbed to suspended matter is not covered by this method.
It is the user’s responsibility to ensure the validity of this test method selected for the water samples tested.

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SIST EN ISO 10703:2021(Main)
Water quality - Gamma-ray emitting radionuclides - Test method using high resolution gamma-ray spectrometry (ISO 10703:2021)
EN ISO 10703:2021

This document specifies a method for the physical pre-treatment and conditioning of water samples and the determination of the activity concentration of various radionuclides emitting gamma-rays with energies between 40 keV and 2 MeV, by gamma‑ray spectrometry according to the generic test method described in ISO 20042.
The method is applicable to test samples of drinking water, rainwater, surface and ground water as well as cooling water, industrial water, domestic and industrial wastewater after proper sampling, sample handling, and test sample preparation (filtration when necessary and taking into account the amount of dissolved material in the water). This method is only applicable to homogeneous samples or samples which are homogeneous via timely filtration.
The lowest limit that can be measured without concentration of the sample or by using only passive shield of the detection system is about 5·10-2 Bq/l for e.g. 137Cs.1 The upper limit of the activity corresponds to a dead time of 10 %. Higher dead times may be used but evidence of the accuracy of the dead-time correction is required.
Depending on different factors, such as the energy of the gamma-rays, the emission probability per nuclear disintegration, the size and geometry of the sample and the detector, the shielding, the counting time and other experimental parameters, the sample may require to be concentrated by evaporation if activities below 5·10-2 Bq/l need to be measured. However, volatile radionuclides (e.g. radon and radioiodine) can be lost during the source preparation.
This method is suitable for application in emergency situations.
1The sample geometry: 3l Marinelli beaker; detector: GE HP N relative efficiency 55 % ; counting time: 18h.

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SIST EN ISO 13162:2021(Main)
Water quality - Carbon 14 - Test method using liquid scintillation counting (ISO 13162:2021)
EN ISO 13162:2021

This document specifies a method for the measurement of 14C activity concentration in all types of water samples by liquid scintillation counting (LSC) either directly on the test sample or following a chemical separation.
The method is applicable to test samples of supply/drinking water, rainwater, surface and ground water, marine water, as well as cooling water, industrial water, domestic, and industrial wastewater.
The detection limit depends on the sample volume, the instrument used, the sample counting time, the background count rate, the detection efficiency and the chemical recovery. The method described in this document, using currently available liquid scintillation counters and suitable technical conditions, has a detection limit as low as 1 Bq∙l−1, which is lower than the WHO criteria for safe consumption of drinking water (100 Bq·l-1). 14C activity concentrations can be measured up to 106 Bq∙l-1 without any sample dilution.
It is the user’s responsibility to ensure the validity of this test method for the water samples tested.

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SIST EN ISO 22515:2021(Main)
Water quality - Iron-55 - Test method using liquid scintillation counting (ISO 22515:2021)
EN ISO 22515:2021

This document specifies a test method for the determination of iron-55 (55Fe) activity concentration in samples of all types of water using liquid scintillation counting (LSC). Using currently available liquid scintillation counters, this test method can measure the 55Fe activity concentrations in the range from the limit of detection up to 120 mBq l-1. These values can be achieved with a counting time between 7 200 s and 10 800 s for a sample volume from 0,5 l to 1,5 l. Higher activity concentrations can be measured by either diluting the sample or using smaller sample aliquots or both.
NOTE      These performance indicators are wholly dependent on the measurement regimes in individual laboratories; in particular, the detection limits are influenced by amount of stable iron present.
The range of application depends on the amount of dissolved material in the water and on the performance characteristics of the measurement equipment (background count rate and counting efficiency).
It is the laboratory’s responsibility to ensure the suitability of this test method for the water samples tested.

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SIST EN ISO 22017:2021(Main)
Water quality - Guidance for rapid radioactivity measurements in nuclear or radiological emergency situation (ISO 22017:2020)
EN ISO 22017:2020

This document provides guidelines for testing laboratories wanting to use rapid test methods on water samples that may be contaminated following a nuclear or radiological emergency incident. In an emergency situation, consideration should be given to:
—     taking into account the specific context for the tests to be performed, e.g. a potentially high level of contamination;
—     using or adjusting, when possible, radioactivity test methods implemented during routine situations to obtain a result rapidly or, for tests not performed routinely, applying specific rapid test methods previously validated by the laboratory, e.g. for 89Sr determination;
—     preparing the test laboratory to measure a large number of potentially contaminated samples.
The aim of this document is to ensure decision makers have reliable results needed to take actions quickly and minimize the radiation dose to the public.
Measurements are performed in order to minimize the risk to the public by checking the quality of water supplies. For emergency situations, test results are often compared to operational intervention levels.
NOTE    Operational intervention levels (OILs) are derived from IAEA Safety Standards[8] or national authorities[9].
A key element of rapid analysis can be the use of routine methods but with a reduced turnaround time. The goal of these rapid measurements is often to check for unusual radioactivity levels in the test sample, to identify the radionuclides present and their activity concentration levels and to establish compliance of the water with intervention levels[10][11][12]. It should be noted that in such circumstances, validation parameters evaluated for routine use (e.g. reproducibility, precision, etc.) may not be applicable to the modified rapid method. However, due to the circumstances arising after an emergency, the modified method may still be fit-for-purpose although uncertainties associated with the test results need to be evaluated and may increase from routine analyses.
The first steps of the analytical approach are usually screening methods based on gross alpha and gross beta test methods (adaptation of ISO 10704 and ISO 11704) and gamma spectrometry (adaptation of ISO 20042, ISO 10703 and ISO 19581). Then, if required[13], test method standards for specific radionuclides (see Clause 2) are adapted and applied (for example, 90Sr measurement according to ISO 13160) as proposed in Annex A.
This document refers to published ISO documents. When appropriate, this document also refers to national standards or other publicly available documents.
Screening techniques that can be carried out directly in the field are not part of this document.

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