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EN ISO 22854:2021

(Main)

Liquid petroleum products - Determination of hydrocarbon types and oxygenates in automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas chromatography method (ISO 22854:2021)

Liquid petroleum products - Determination of hydrocarbon types and oxygenates in automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas chromatography method (ISO 22854:2021)

This document specifies the gas chromatographic (GC) method for the determination of saturated, olefinic and aromatic hydrocarbons in automotive motor gasoline and ethanol (E85) automotive fuel. Additionally, the benzene and toluene content, oxygenated compounds and the total oxygen content can be determined.
NOTE 1   For the purposes of this document, the terms % (m/m) and % (V/V) are used to represent respectively the mass fraction, w, and the volume fraction, φ.
This document defines two procedures, A and B.
Procedure A is applicable to automotive motor gasoline with total aromatics of 19,32 % (V/V) up to 46,29 % (V/V); total olefins from 0,40 % (V/V) up to 26,85 % (V/V); oxygenates from 0,61 % (V/V) up to 9,85 % (V/V); oxygen content from 1,50 % (m/m) to 12,32 % (m/m); benzene content from 0,38 % (V/V) up to 1,98 % (V/V) and toluene content from 5,85 % (V/V) up to 31,65 % (V/V).
The method has also been tested for individual oxygenates. A precision has been determined for a total volume of methanol from 1,05 % (V/V) up to 16,96 % (V/V); a total volume of ethanol from 0,50 % (V/V) up to 17,86 % (V/V); a total volume of MTBE from 0,99 % (V/V) up to 15,70 % (V/V), a total volume of ETBE from 0,99 % (V/V) up to 15,49 % (V/V), a total volume of TAME from 0,99 % (V/V) up to 5,92 % (V/V), and a total volume of TAEE from 0,98 % (V/V) up to 15,59 % (V/V).
Although this test method can be used to determine higher-olefin contents of up to 50 % (V/V), the precision for olefins was tested only in the range from 0,40 % (V/V) to 26,85 % (V/V).
Although specifically developed for the analysis of automotive motor gasoline that contains oxygenates, this test method can also be applied to other hydrocarbon streams having similar boiling ranges, such as naphthas and reformates.
NOTE 2   For Procedure A, applicability of this document has also been verified for the determination of n-propanol, acetone, and di-isopropyl ether (DIPE). However, no precision data have been determined for these compounds.
Procedure B describes the analysis of oxygenated groups (ethanol, methanol, ethers, C3 – C5 alcohols) in ethanol (E85) automotive fuel containing ethanol between 50 % (V/V) and 85 % (V/V). The gasoline is diluted with an oxygenate-free component to lower the ethanol content to a value below 20 % (V/V) before the analysis by GC.
The sample can be fully analysed including hydrocarbons. Precision data for the diluted sample are only available for the oxygenated groups.
NOTE 3   For Procedure B, the precision can be used for an ethanol fraction from about 50 % up to 85 % (V/V). For the ether fraction, the precision as specified in Table 6 can be used for samples containing at least 11 % (V/V) of ethers. For the higher alcohol fraction, too few data were obtained to derive a full precision statement and the data presented in Table 6 are therefore only indicative.
NOTE 4   An overlap between C9 and C10 aromatics can occur. However, the total is accurate. Isopropyl benzene is resolved from the C8 aromatics and is included with the other C9 aromatics.

Flüssige Mineralölerzeugnisse - Bestimmung von Kohlenwasserstoffgruppen und sauerstoffhaltigen Verbindungen in Ottokraftstoffen und in Ethanolkraftstoff (E85) - Multidimensionales gaschromatographisches Verfahren (ISO 22854:2021)

Dieses Dokument legt ein Verfahren zur gaschromatographischen Bestimmung (GC) von gesättigten, olefinischen und aromatischen Kohlenwasserstoffen in Ottokraftstoffen und Ethanolkraftstoff (E85) fest. Zusätzlich können die Gehalte an Benzol und Toluol, sauerstoffhaltigen Verbindungen sowie der Gesamt-sauerstoffgehalt bestimmt werden.
ANMERKUNG 1 Für die Zwecke dieses Dokuments wird zur Angabe des Massenanteils, w, einer Substanz der Ausdruck „% (m/m)“ und für den Volumenanteil, φ, einer Substanz der Ausdruck „% (V/V)“ verwendet.
Dieses Dokument definiert zwei Verfahren, A und B.
Verfahren A ist anwendbar für Ottokraftstoffe mit einem Gesamtaromatenanteil von 19,32 % (V/V) bis zu 46,29 % (V/V), einem Gesamtolefinanteil von 0,40 % (V/V) bis zu 26,85 % (V/V), einem Anteil an sauerstoff-haltigen Verbindungen von 0,61 % (V/V) bis zu 9,85 % (V/V), einem Sauerstoffgehalt von 1,50 % (m/m) bis 12,32 % (m/m), einem Benzolgehalt von 0,38 % (V/V) bis zu 1,98 % (V/V) und einem Toluolgehalt von 5,85 % (V/V) bis zu 31,65 % (V/V).
Das Verfahren wurde auch für einzelne sauerstoffhaltige Verbindungen geprüft. Die Präzision wurde bestimmt für ein Gesamtvolumen an Methanol von 1,05 % (V/V) bis zu 16,96 % (V/V), ein Gesamtvolumen an Ethanol von 0,50 % (V/V) bis zu 17,86 % (V/V), ein Gesamtvolumen an MTBE von 0,99 % (V/V) bis zu 15,70 % (V/V), ein Gesamtvolumen an ETBE von 0,99 % (V/V) bis zu 15,49 % (V/V), ein Gesamtvolumen an TAME von 0,99 % (V/V) bis zu 5,92 % (V/V) und ein Gesamtvolumen an TAEE von 0,98 % (V/V) bis zu 15,59 % (V/V).
Obwohl dieses Prüfverfahren zur Bestimmung höherer Olefingehalte bis zu 50 % (V/V) angewendet werden kann, wurde die Präzision für Olefine nur im Bereich von 0,40 % (V/V) bis 26,85 % (V/V) ermittelt.
Obwohl dieses Verfahren speziell für die Analyse von Ottokraftstoffen mit sauerstoffhaltigen Verbindungen entwickelt wurde, kann es auch auf andere Kohlenwasserstoffe mit ähnlichen Siedebereichen, wie z. B. Naphthas und Reformate, angewendet werden.
ANMERKUNG 2 Für Verfahren A wurde die Anwendbarkeit dieses Dokuments auch für die Bestimmung von n-Propanol, Aceton und Diisopropylether (DIPE) überprüft. Es wurden jedoch für diese Verbindungen keine Präzisionsdaten bestimmt.
Verfahren B beschreibt die Analyse von sauerstoffhaltigen Verbindungen (Ethanol, Methanol, Ether, C3- bis C5-Alkohole) in Ethanolkraftstoffen (E85) mit einem Ethanolgehalt zwischen 50 % (V/V) und 85 % (V/V). Das Benzin wird mit einer sauerstofffreien Komponente verdünnt, um den Ethanolgehalt vor der GC-Analyse auf einen Wert unter 20 % (V/V) zu senken.
Die Probe kann einschließlich der Kohlenwasserstoffe vollständig analysiert werden. Präzisionsdaten für die verdünnte Probe sind nur für die Gruppe der Sauerstoffverbindungen vorhanden.
ANMERKUNG 3 Für Verfahren B kann die Präzision für einen Ethanolanteil von etwa 50 % (V/V) bis zu 85 % (V/V) verwendet werden. Für den Ethergehalt können die Präzisionsangaben in Tabelle 6 für Proben verwendet werden, deren Ethergehalt bei mindestens 11 % (V/V) liegt. Für höhere Alkoholgehalte wurden zu wenige Daten erhalten, um eine vollständige Präzisionsangabe abzuleiten; in diesem Fall sind die Werte in Tabelle 6 nur als informativ anzusehen.
ANMERKUNG 4 Es kann eine Überlappung zwischen C9- und C10-Aromaten auftreten. Das Gesamtergebnis ist jedoch korrekt. Isopropylbenzol wird von den C8-Aromaten abgetrennt und mit den anderen C9-Aromaten erfasst.

Produits pétroliers liquides - Détermination des groupes d'hydrocarbures et de la teneur en composés oxygénés de l'essence pour moteurs automobiles et du carburant éthanol pour automobiles E85 - Méthode par chromatographie multidimensionnelle en phase gazeuse (ISO 22854:2021)

Le présent document prescrit une méthode pour la détermination par chromatographie en phase gazeuse (CPG) des teneurs en hydrocarbures saturés, oléfiniques et aromatiques dans les essences pour moteurs automobiles et dans les carburants éthanol pour automobiles (E85). En outre, les teneurs en benzène, en composés oxygénés et en oxygène total peuvent être mesurées par cette méthode.
NOTE 1       Pour les besoins du présent document, les termes % (m/m) et % (V/V) sont utilisés pour représenter respectivement la fraction massique, w, et la fraction volumique, φ, d’un produit.
Le présent document définit deux modes opératoires, A et B.
Le mode opératoire A est applicable aux essences pour moteurs automobiles ayant une teneur en aromatiques totaux de 19,32 % (V/V) jusqu’à 46,29 % (V/V), une teneur en oléfines totales de 0,40 % (V/V) jusqu’à 26,85 % (V/V), une teneur en composés oxygénés de 0,61 % (V/V) jusqu’à 9,85 % (V/V), une teneur en oxygène total de 1,50 % (m/m) jusqu’à 12,32 % (m/m), une teneur en benzène de 0,38 % (V/V) jusqu’à 1,98 % (V/V) et une teneur en toluène de 5,85 % (V/V) jusqu’à 31,65 % (V/V).
La méthode a également été testée pour des composés oxygénés individuels. Des données de fidélité ont été déterminées pour un volume total de méthanol de 1,05 % (V/V) à 16,96 % (V/V); un volume total d'éthanol de 0,50 % (V/V) à 17,86 % (V/V); un volume total de MTBE de 0,99 % (V/V) à 15,70 % (V/V), un volume total d'ETBE de 0,99 % (V/V) à 15,49 % (V/V), un volume total de TAME de 0,99 % (V/V) à 5,92 % (V/V), et un volume total de TAEE de 0,98 % (V/V) à 15,59 %(V/V).
Bien que cette méthode d’essai puisse être utilisée pour déterminer des teneurs en oléfines plus élevées, jusqu’à 50 % (V/V), la fidélité pour les oléfines n’a été établie que pour des teneurs comprises entre 0,40 % (V/V) et 26,85 % (V/V).
Bien que cette méthode ait été développée pour l’analyse d’essences pour moteurs automobiles qui contiennent des oxygénés, celle-ci peut aussi être appliquée à d’autres bases hydrocarbonées dont l’intervalle d’ébullition est voisin, tels que les naphtas et les réformats.
NOTE 2       Pour le mode opératoire A du présent document, l’applicabilité a été vérifiée pour le dosage du n-propanol, de l’acétone et du di-isopropyl éther (DIPE). Cependant, la fidélité n’a pas été déterminée pour ces composés.
Le mode opératoire B décrit l’analyse des groupes oxygénés (éthanol, méthanol, éthers et alcools C3‑C5) dans des carburants éthanol pour automobiles (E85) contenant de l’éthanol entre 50 % (V/V) et 85 % (V/V). L’essence est diluée avec un composant non oxygéné pour abaisser la teneur en éthanol à une valeur inférieure à 20 % (V/V) avant l’analyse par chromatographie en phase gazeuse (CPG).
L’échantillon peut être totalement analysé y compris les familles d’hydrocarbures. Les valeurs de fidélité pour les échantillons dilués ne sont disponibles que pour les groupes oxygénés.
NOTE 3       Pour le mode opératoire B, les valeurs de fidélité peuvent être utilisées pour une fraction d’éthanol d’environ 50 % (V/V) jusqu’à 85 % (V/V). Pour la fraction éther, la fidélité telle que spécifiée dans le Tableau 6 peut être utilisée pour des échantillons contenant au moins 11 % (V/V) d’éthers. Pour la fraction des alcools supérieurs, trop peu de données ont été recueillies pour établir véritablement des valeurs de fidélité, ainsi les valeurs présentées dans le Tableau 6 ne sont-elles données qu’à titre indicatif.
NOTE 4       Il peut y avoir un chevauchement e

Tekoči naftni proizvodi - Določevanje vrste ogljikovodikov in oksigenatov v motornem bencinu in bencinu na osnovi etanola (E85) - Metoda multidimenzionalne plinske kromatografije (ISO 22854:2021)

General Information

Status
Published
Publication Date
03-Aug-2021
Withdrawal Date
27-Feb-2022
ICS
75.080 - Petroleum products in general
Technical Committee
CEN/TC 19 - Petroleum products, lubricants and related products
Drafting Committee
CEN/TC 19/WG 9 - Chromatographic test methods
Current Stage
6060 - Definitive text made available (DAV) - Publishing
Start Date
04-Aug-2021
Completion Date
04-Aug-2021
Ref Project
SIST EN ISO 22854:2021 - Liquid petroleum products - Determination of hydrocarbon types and oxygenates in automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas chromatography method (ISO 22854:2021)

Relations

Replaces
EN ISO 22854:2016 - Liquid petroleum products - Determination of hydrocarbon types and oxygenates in automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas chromatography method (ISO 22854:2016)
Effective Date
08-Jun-2022
Revised
prEN ISO 22854 - Liquid petroleum products - Determination of hydrocarbon types and oxygenates in automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas chromatography method (ISO/DIS 22854:2023)
Effective Date
28-Jan-2023

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SLOVENSKI STANDARD
SIST EN ISO 22854:2021
01-oktober-2021
Nadomešča:
SIST EN ISO 22854:2016
Tekoči naftni proizvodi - Določevanje vrste ogljikovodikov in oksigenatov v
motornem bencinu in bencinu na osnovi etanola (E85) - Metoda
multidimenzionalne plinske kromatografije (ISO 22854:2021)
Liquid petroleum products - Determination of hydrocarbon types and oxygenates in
automotive-motor gasoline and in ethanol (E85) automotive fuel - Multidimensional gas
chromatography method (ISO 22854:2021)
Flüssige Mineralölerzeugnisse - Bestimmung der Kohlenwasserstoffgruppen und der
sauerstoffhaltigen Verbindungen in Ottokraftstoffen und in Ethanolkraftstoff (E85) -
Multidimensionales gaschromatographisches Verfahren (ISO 22854:2021)
Produits pétroliers liquides - Détermination des groupes d'hydrocarbures et de la teneur
en composés oxygénés de l'essence pour moteurs automobiles et du carburant éthanol
pour automobiles E85 - Méthode par chromatographie multidimensionnelle en phase
gazeuse (ISO 22854:2021)
Ta slovenski standard je istoveten z: EN ISO 22854:2021
ICS:
71.040.50 Fizikalnokemijske analitske Physicochemical methods of
metode analysis
75.160.20 Tekoča goriva Liquid fuels
SIST EN ISO 22854:2021 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN ISO 22854:2021

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SIST EN ISO 22854:2021


EN ISO 22854
EUROPEAN STANDARD

NORME EUROPÉENNE

August 2021
EUROPÄISCHE NORM
ICS 75.080 Supersedes EN ISO 22854:2016
English Version

Liquid petroleum products - Determination of
hydrocarbon types and oxygenates in automotive-motor
gasoline and in ethanol (E85) automotive fuel -
Multidimensional gas chromatography method (ISO
22854:2021)
Produits pétroliers liquides - Détermination des Flüssige Mineralölerzeugnisse - Bestimmung der
groupes d'hydrocarbures et de la teneur en composés Kohlenwasserstoffgruppen und der sauerstoffhaltigen
oxygénés de l'essence pour moteurs automobiles et du Verbindungen in Ottokraftstoffen und in
carburant éthanol pour automobiles E85 - Méthode par Ethanolkraftstoff (E85) - Multidimensionales
chromatographie multidimensionnelle en phase gaschromatographisches Verfahren (ISO 22854:2021)
gazeuse (ISO 22854:2021)
This European Standard was approved by CEN on 18 July 2021.

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
© 2021 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN ISO 22854:2021 E
worldwide for CEN national Members.

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SIST EN ISO 22854:2021
EN ISO 22854:2021 (E)
Contents Page
European foreword . 3

2

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SIST EN ISO 22854:2021
EN ISO 22854:2021 (E)
European foreword
This document (EN ISO 22854:2021) has been prepared by Technical Committee ISO/TC 28 "Petroleum
and related products, fuels and lubricants from natural or synthetic sources" in collaboration with
Technical Committee CEN/TC 19 “Gaseous and liquid fuels, lubricants and related products of
petroleum, synthetic and biological origin.” the secretariat of which is held by NEN.
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 February 2022, and conflicting national standards
shall be withdrawn at the latest by February 2022.
Attention is drawn to the possibility that some of the elements of this document may be the su
...

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SIST EN 15522-2:2023

This document specifies a method to identify and compare the compositional characteristics of oil samples. Specifically, it describes the detailed analytical and data processing methods for identifying the characteristics of spill samples and establishing their correlation to suspected source oils. Even when samples or data from suspected sources are not available for comparison, establishing the specific nature (e.g. refined petroleum, crude oil, waste oil, etc.) of the spilled oil still helps to constrain the possible source(s).
This methodology is restricted to petroleum related products containing a significant proportion of hydrocarbon-components with a boiling point above 150 °C. Examples are: crude oils, higher boiling condensates, diesel oils, residual bunker or heavy fuel oils, lubricants, and mixtures of bilge and sludge samples, as well as distillate fuels and blends. While the specific analytical methods are perhaps not appropriate for lower boiling oils (e.g. kerosene, jet fuel, or gasoline), the general concepts described in this methodology, i.e. statistical comparison of weathering-resistant diagnostic ratios, are applicable in spills involving these kinds of oils.
Paraffin based products (e.g. waxes, etc.) are outside the scope of this method because too many compounds are removed during the production process [37]. However, the method can be used to identify the type of product involved.
Although not directly intended for identifying oil recovered from groundwater, vegetation, wildlife/tissues, soil, or sediment matrices, they are not precluded. However, caution is needed as extractable compounds can be present in these matrices that alter and/or contribute additional compounds compared to the source sample. If unrecognized, the contribution from the matrix can lead to false “non-matches”. It is therefore advisable to analyse background sample(s) of the matrix that appear unoiled.
When analysing “non-oil” matrices additional sample preparation (e.g. clean-up) is often required prior to analysis and the extent to which the matrix affects the correlation achieved is to be considered. Whether the method is applicable for a specific matrix depends upon the oil concentration compared to the “matrix concentration”. In matrices containing high concentrations of oil, a positive match can still be concluded. In matrices containing lower concentrations of oil, a false “non-match” or an “inconclusive match” can result from matrix effects. Evaluation of possible matrix effects is beyond the scope of this document.

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CEN
EN ISO 3679:2022(Main)
Determination of flash point - Method for flash no-flash and flash point by small scale closed cup tester (ISO 3679:2022, Corrected version 2023-05)
SIST EN ISO 3679:2023

This document describes three procedures (A, B and C) covering determinations of flash no-flash and flash point.
Rapid equilibrium procedures A and B are applicable to flash no-flash and flash point tests of paints, including water-borne paints, varnishes, binders for paints and varnishes, adhesives, solvents, petroleum products including aviation turbine, diesel and kerosene fuels, fatty acid methyl esters and related products over the temperature range –30 °C to 300 °C. The rapid equilibrium procedures are used to determine whether a product will or will not flash at a specified temperature (flash no-flash procedure A) or the flash point of a sample (procedure B). When used in conjunction with the flash detector (A.1.6), this document is also suitable to determine the flash point of fatty acid methyl esters (FAME). The validity of the precision is given in Table 2.
Non-equilibrium procedure C is applicable to petroleum products including aviation turbine, diesel and kerosine fuels, and related petroleum products, over the temperature range –20 °C to 300 °C. The non-equilibrium procedure is automated to determine the flash point. Precision has been determined over the range 40 °C to 135 °C.
For specifications and regulations, procedures A or B are routinely used (see 10.1.1).

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EN ISO 13736:2021/A1:2022(Amendment)
Determination of flash point - Abel closed-cup method - Amendment 1: Bias statement update (ISO 13736:2021/Amd 1:2022)
SIST EN ISO 13736:2021/A1:2022
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EN ISO 4259-4:2022(Main)
Petroleum and related products - Precision of measurement methods and results - Part 4: Use of statistical control charts to validate 'in-statistical-control' status for the execution of a standard test method in a single laboratory (ISO 4259-4:2021, Corrected version 2023-10)
SIST EN ISO 4259-4:2022

This document specifies the process and methodology for the construction, operation, and maintenance of statistical control charts to assess if a laboratory's execution of a standard test method is in-statistical-control and how to establish and validate the 'in-statistical-control' status.
It specifies control charts that are most appropriate for ISO/TC 28 test methods where the dominant common cause variation is associated with the long term, multiple operator conditions. The control charts specified for determination of in-statistical-control are: individual (I), moving range of 2 (MR2), and either the exponentially weighted moving average (EWMA) or zone-based run rules [similar to Western Electric (WE) run rules[3]] as sensitivity enhancement strategy to support the I-chart.
The procedures in this document have been primarily designed for numerical results obtained from testing of control samples prepared from a homogenous source of petroleum and related products in a manner that preserves the homogeneity of properties of interest between control samples. If the test method permits, a certified reference material (CRM) sample is used as a control sample provided the sample composition is representative of the material being tested and is not a pure compound; if this is done then the laboratory best establishes its own mean for the CRM sample.
This document is applicable to properties of interest that are (known to be) stable over time, and for data sets with sufficient resolution to support validation of the assumption that the data distribution can be approximately represented by the normal (Gaussian) model. Mitigating strategies are suggested for situations where the assumption cannot be validated.

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