iTeh StandardsiTeh Standards
EURUSD
Your shopping cart is empty.
SIST

SIST EN ISO 6326-5:2000

(Main)

Natural gas - Determination of sulfur compounds - Part 5: Lingener combustion method (ISO 6326-5:1989)

Natural gas - Determination of sulfur compounds - Part 5: Lingener combustion method (ISO 6326-5:1989)

Specifies a method for the determination of total sulphur in natural gas. It is applicable to gases with sulphur contents between 0,5 mg/m3 and 1 000 mg/m3. With a total sulphur content of more than 0,1 mg sulphur in the absorption solution, visual titration with an indicator can be chosen, whereas for lower contents turbidimetric titration is preferable.

Erdgas - Bestimmung von Schwefelverbindungen - Teil 5: Verbrennung nach dem Lingener-Verfahren (ISO 6326-5:1989)

Dieser Teil von ISO 6326 legt ein Verfahren für die Bestimmung des Gesamtschwefelgehaltes in Erdgas fest. Das Verfahren ist anwendbar auf Gase mit Schwefelgehalten zwischen 0,5 mg/m3 und 1000 mg/m3. Bei einem Gesamtschwefelgehalt von mehr als 0,1 mg in der Absorptionslösung kann die visuelle Titration mit einem Indikator gewählt werden, während bei niedrigeren Gehalten die Trübungstitration vorzuziehen ist.

Gaz naturel - Détermination des composés soufrés - Partie 5: Méthode de combustion Lingener (ISO 6326-5:1989)

La présente partie de l'ISO 6326 prescrit une méthode pour la détermination de la teneur totale en soufre du gaz naturel. Cette méthode est applicable aux gaz dont la teneur totale en soufre est comprise entre 0,5 mg/m3 et 1 000 mg/m3. Le titrage visuel avec indicateur peut être choisi lorsque la teneur totale en soufre est supérieure à 0,1 mg dans la solution absorbante, le titrage turbidimétrique étant préférable pour les teneurs inférieures. --
NOTE Dans toutes les parties de l'ISO 6326, 1 m3 de gaz est exprimé pour les conditions normales (0 °C; 101,325 kPa).

Zemeljski plin - Določevanje žveplovih spojin - 5. del: Metoda sežiga po Lingenerju (ISO 6326-5:1989)

General Information

Status
Withdrawn
Publication Date
30-Nov-2000
Withdrawal Date
19-Apr-2020
ICS
75.060 - Natural gas
Technical Committee
NAD - Petroleum products, lubricants and related products
Current Stage
9900 - Withdrawal (Adopted Project)
Start Date
17-Apr-2020
Due Date
10-May-2020
Completion Date
20-Apr-2020
Ref Project
EN ISO 6326-5:1997 - Natural gas - Determination of sulfur compounds - Part 5: Lingener combustion method (ISO 6326-5:1989)

Buy Standard

EN ISO 6326-5:2000EN ISO 6326-5:2000
PreviousNext
Standard
EN ISO 6326-5:2000
English language
11 pages
sale 10% off
Preview
sale 10% off
Preview
e-Library read for
1 day

Standards Content (Sample)

SLOVENSKI STANDARD
SIST EN ISO 6326-5:2000
01-december-2000
=HPHOMVNLSOLQ'RORþHYDQMHåYHSORYLKVSRMLQGHO0HWRGDVHåLJDSR/LQJHQHUMX
,62
Natural gas - Determination of sulfur compounds - Part 5: Lingener combustion method
(ISO 6326-5:1989)
Erdgas - Bestimmung von Schwefelverbindungen - Teil 5: Verbrennung nach dem
Lingener-Verfahren (ISO 6326-5:1989)
Gaz naturel - Détermination des composés soufrés - Partie 5: Méthode de combustion
Lingener (ISO 6326-5:1989)
Ta slovenski standard je istoveten z: EN ISO 6326-5:1997
ICS:
75.060 Zemeljski plin Natural gas
SIST EN ISO 6326-5:2000 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

---------------------- Page: 1 ----------------------

SIST EN ISO 6326-5:2000

---------------------- Page: 2 ----------------------

SIST EN ISO 6326-5:2000

---------------------- Page: 3 ----------------------

SIST EN ISO 6326-5:2000

---------------------- Page: 4 ----------------------

SIST EN ISO 6326-5:2000
ISO
INTERNATIONAL
6326-5
STANDARD
First edition
1989-07-01
Determination of Sulfur
Natura1 gas -
compounds -
Part 5 :
Lingener combustion method
Determination des composh soufr& -
Gaz naturel -
Partie 5 : MMode de combustion Lingener
Reference number
ISO 6326-5 : 1989 (El

---------------------- Page: 5 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (El
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. Esch 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, govern-
mental and non-governmental, in liaison with ISO, also take part in the work. ISO
collaborates closely with the International Electrotechnical Commission (1 EC) on all
matters of electrotechnical standardization.
Draft International Standards adopted by the technical committees are circulated to
the member bodies for approval before their acceptance as International Standards by
the ISO Council. They are approved in accordance with ISO procedures requiring at
least 75 % approval by the member bodies voting.
International Standard ISO 6326-5 was prepared by Technical Committee ISO/TC 158,
Analysis of gases.
Na tural gas -
ISO 6326 consists of the following Parts, under the general title
Determination of Sulfur compounds :
-
Part 7 : General in troduction
- Part 2: Gas chromatographic method using electrochemical detector for the
an
determina tion o f odoriferous Sulfur compounds
-
Part 3: Determination of hydrogen sulfide, mercaptan Sulfur and carbonyl
sulfide Sulfur by po ten tiometry
-
Part 4: Determination of individual Sulfur compounds chroma tograph y
bY WS
with a flame pho tometric detector
Part 5: Lingener combustion method
Annex A of this part of ISO 6326 is for information only.
0 ISO 1989
All rights reserved. No part of this publication may be reproduced or utilized in any form or by any
means, electronie or mechanical, including photocopying and microfilm, without Permission in
writing from the publisher.
International Organization for Standardization
Case postale 56 l CH-121 1 Geneve 20 l Switzerland
Printed in Switzerland
ii

---------------------- Page: 6 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (El
Introduction
The standardization of several methods for the determination of Sulfur compounds in
natura1 gas is necessary in view of the diversity of these compounds [hydrogen sulfide,
carbonyl sulfide, thiols (mercaptans), tetrahydrothiophene (THT), etc.] and the pur-
poses of the determinations (required accuracy, measurement at the drilling head or in
the transmission pipes, etc. ).
In Order to enable the user to choose the method most appropriate to his needs and to
perform the measurements under the best conditions, ISO 6326 has been prepared in
several Parts.
ISO 6326-1 gives a rapid comparison of standardized
methods and therefore provides
information for the choice of the method.
The other Parts of ISO 6326, including this Part, describe in detail the various stan-
dardized methods.
The determination of total Sulfur is specified in ISO 4260 : 1987, Petroleum products
and hydrocarbons - Determination of Sulfur content - Wickbold combustion
me thod.
. . .
Ill

---------------------- Page: 7 ----------------------

SIST EN ISO 6326-5:2000
This page intentionally lef? blank

---------------------- Page: 8 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5: 1989 (E)
INTERNATIONAL STANDARD
Determination of Sulfur compounds -
Natura1 gas -
Part 5 :
Lingener combustion method
1 Scope 3 Principle
This part of ISO 6326 specifies a method for the determination A measured volume sf gas is burnt with air at atmospheric
of total Sulfur in natura1 gas. The method is applicable to gases
pressure in a glass combustion apparatus. The resulting Sulfur
with Sulfur contents between 0,5 mg/m3 and ‘l 000 mg/m3. oxides are converted into sulfuric acid by absorption in
With a total Sulfur content of more than 0,l mg Sulfur in the
hydrogen peroxide solution. Depending on the Sulfur content
absorption Solution, visual titration with an indicator tan be of the test gas, the sulfate ions in the absorption Solution are
Chosen, whereas for lower contents turbidimetric titration is
determined using either visual titration with an indicator or tur-
preferable. bidimetric titration.
NOTE - In all Parts of ISO 6326, 1 m3 of gas is expressed at normal
conditions (0 OC; 101,325 kPa).
4 Reagents and materials
2 Normative rederences
During the analysis, use only reagents of recognized analytical
grade and only distilled water or water sf equivalent purity.
The following Standards contain provisions which, through
reference in this text, constitute provisions of this part of
4% Hydrogen Peroxide, IO % (rnlrn) aqueous Solution,
ISO 6326. At the time of publication, the editions indicated
Sulfur-free, as absorbing liquid for the Sulfur oxides.
were valid. All Standards are subject to revision, and Parties to
agreements based on this part of ISO 6326 are encouraged to
investigate the possibility of applying the most recent editions
4.2 Activated carbsn, for adsorption of Sulfur impurities
of the Standards listed below. Members of IEC and ISO main-
from the combustion air.
tain registers of currently valid International Standards.
4.3 Absorbing liquid :
ISO 385-1 : 1984, Laborstory glassware - 5urettes - Part 7 : 30 % Onl~n) aqueous Solution of
General requiremen ts. potassium hydroxide, for the purification of the combustion air.
ISO 648 : 1977, Laborstory glassware - he-mark pipettes.
One-mark 5 Apparatus
ISO 1042 : 1983, Laboratory glassware -
volume tric flasks.
The schematic layout of the apparatus is shown in figure 1.
ISO 3585 : 1976, Glass plant, Pipeline and fittings - Properties
Ordinary laboratory apparatus and
of borosilicate glass 3.3.

---------------------- Page: 9 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (El
Air
Combustion device
Pressure-equalizing vessel
Capillary flow meter
U-tube manometer
Dry gas meter with thermometer
Condensate separator
Vacuum pump
-
Figure 1 Schematic layout of the apparatus
5.3 Capillary flow meter (C), measuring range 10 I/min to
5.1 Combustion device (AI
30 I/min.
The combustion device is manufactured of borosilicate glass
complying with ISO 3535. lt consists of the Parts shown in
5.4 U-tube manometer (D), arm length 500 mm.
figure 2,
5.5 Dry gas meter (E)
5.1.1 Receiver with cooling jacket (see figure 3).
The range of the meter shall be appropriate for the quantity of
5.1.2 Flame tube (see figure 4)
Sample to be burned and the meter shall have been recently
calibrated. The gas meter shall be equipped with a thermometer
The outer diameter of the flame tube is determined by the in-
for the measurement of the gas temperature. The thermometer
side diameter of the receiver with cooling jacket and the annular
shall have a measuring range of 0 OC to at least 30 OC. The
gap shown in figure 2.
scale intervals shall be not less than 0,5 OC.
5.1.3 Burner (see figure 5)
NOTE - The gas meter should be flushed with the gas to be analysed
before the combustion, in particular when analysing gases with dif-
ferent Sulfur contents, to avoid disturbance by adsorption and desorp-
For the combustion of natura1 gases a universal burner with a
tion phenomena.
needle valve is often preferable.
5.1.4 Intermediate piece (see figure 6) 5.6 Condensate separator (FL
The thermometer shall have a measuring range of 0 OC to at
5.7 Vacuum pump (GI
least 100 OC. The scale interval shall be not less than 1 OC.
The suction capacity of the vacuum pump shall be at least
51.5 Reitmeyer attachment (see figure 7).
25 I/min. lt is recommended that a drying tower with a drying
agent be included between the condensate separator (F) and
the vacuum pump (G) to protect the oil in the vacuum pump.
5.2 Pressure-equaliming vessel (BL
2

---------------------- Page: 10 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (E)
Dimensions in millimetres
Tube8x l-
Tube 10 x l-
I
II
I
1
II
I
I
11
I
I
Il
I
I
I
II
I
I
II
I
I
11
Il
ll
l
Ir
1’
3,2’o,z
I’
I
I
I
I
Annular gap
h /--- Centred flame-tube
l
ek
I
11
l
I
I
/
I
11
11 I 11
Ii
1 JI *
Figure 2 - Combustion vessel

---------------------- Page: 11 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (E)
Dimensions in millimetres
Dimensions in millimetres
Spherical joint-cup 29/ 15-,
Conical joint-socket 60/46~
\
Conical joint-
socket socket 45/40 45/40
Hose connectionY
L Conical Conical joint- joint-
cone cone 60146 60146
Tube Tube 40 40 x x 1,6 1,6
iTube54x 1,8
/
/
C
0
2
s
Tube 75 x 2,2
r,
/
\Tube44x 1,6
f’
1
r Eight holes @ 2+ir5
/
- uniformly distributed
over the periphery
LOne-way cock
Figure 4 - Flame tube
Figure 3 - Receiver with cooling jacket

---------------------- Page: 12 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (El
Dimensions in millimetres
Three apertures
50
Spherical joint-cup-\ k-4
f-----q 9,5 k 0,5
13112
Gas jet apertu
@ 0,l + 0,05
Dimensions in millimetres
. Tube4Oxl ,6-\
79n-Y
Thermometer
iV--
Extension
displaced
rearward
joint-socket 14/23
by 90° --
1
Spherical joint-cup-
1919
Spherical joint-cup
/
Conical joint-cone
29115
45/40
Spherical joint-ball-’
29115
/
l-
Tube 1Ox
Figure 6 - Intermediate piece
Figure 5 - Burner
Dimensions in millimetres
Bent rearward through 90°
i-
Conical joint-
socket 14/23
A
-0
+
00
-8
Spherical joint-ball 29/15i
Figure 7 - Reitmeyer attachment
5

---------------------- Page: 13 ----------------------

SIST EN ISO 6326-5:2000
ISO 6326-5 : 1989 (El
7 Analytical determination
6 Procedure
With a total Sulfur content of more than 0,l mg Sulfur in the ab-
61 . Preparation for combustion
sorption Solution, visual titration with an indicator tan be
Chosen, whereas for lower contents turbidimetric titration is
Draw air, which if necessary should be cleaned of Sulfur im-
preferable.
purities with activated carbon (4.2) and/or absorbing liquid
(4.31, through the combustion apparatus with the
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

This May Also Interest You

SIST
SIST EN ISO 6978-2:2005/AC:2016(Corrigendum)
Natural gas - Determination of mercury - Part 2: Sampling of mercury by amalgamation on gold/platinum alloy - Technical Corrigendum 2 (ISO 6978-2:2003/Cor 2:2006)
EN ISO 6978-2:2005/AC:2016

ISO corr

  • Corrigendum
    4 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 16960:2014(Main)
Natural gas - Determination of sulfur compounds - Determination of total sulfur by oxidative microcoulometry method (ISO 16960:2014)
EN ISO 16960:2014

This International Standard specifies a method for the determination of total sulfur in the range from
1 mg/m3 to 200 mg/m3 in pipeline natural gas by oxidative microcoulometry. Natural gas with sulfur
contents above 200 mg/m3 can be analysed after dilution with a suitable sulfur-free solvent.

  • Standard
    15 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 6974-5:2014(Main)
Natural gas - Determination of composition and associated uncertainty by gas chromatography - Part 5: Isothermal method for nitrogen, carbon dioxide, C1 to C5 hydrocarbons and C6+ hydrocarbons (ISO 6974-5:2014)
EN ISO 6974-5:2014

EN ISO 6974-5 describes a gas chromatographic method for the quantitative determination of the content of nitrogen, carbon dioxide and C1 to C5 hydrocarbons individually and a composite C6+ measurement, which represents all hydrocarbons of carbon number 6 and above in natural gas samples. It is applicable to the analysis of gases containing constituents within the working ranges given in Table 1.

  • Standard
    32 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 15970:2014(Main)
Natural gas - Measurement of properties - Volumetric properties: density, pressure, temperature and compression factor (ISO 15970:2008)
EN ISO 15970:2014

EN-ISO 15970 gives requirements and procedures for the measurement of the properties of natural gas that are used mainly for volume calculation and volume conversion: density at reference and at operating conditions, pressure, temperature and compression factor. Only those methods and instruments are considered that are suitable for field operation under the conditions of natural gas transmission and distribution, installed either in-line or on-line, and that do not involve the determination of the gas composition. This International Standard gives examples for currently used instruments that are available commercially and of interest to the natural gas industry. NOTE Attention is drawn to requirements for approval of national authorization agencies and to national legal regulations for the use of these devices for commercial or official trade purposes. The density at reference conditions (sometimes referred to as normal, standard or even base density) is required for conversion of volume data and can be used for other physical properties. Density at operating conditions is measured for mass-flow measurement and volume conversion using the observed line density and can be used for other physical properties. This International Standard covers density transducers based on vibrating elements, normally suitable for measuring ranges of 5 kg/m3 to 250 kg/m3. Pressure measurement deals with differential, gauge and absolute pressure transmitters. It considers both analogue and smart transmitters (i.e. microprocessor based instruments) and, if not specified otherwise, the corresponding paragraphs refer to differential, absolute and gauge pressure transmitters without distinction. Temperature measurements in natural gas are performed within the range of conditions under which transmission and distribution are normally carried out (253 K < T < 338 K). In this field of application, resistance thermometer detectors (RTD) are generally used. The compression factor (also known as the compressibility factor or the real gas factor and given the symbol Z) appears, in particular, in equations governing volumetric metering. Moreover, the conversion of volume at metering conditions to volume at defined reference conditions can properly proceed with an accurate knowledge of Z at both relevant pressure and relevant temperature conditions.

  • Standard
    56 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 15971:2014(Main)
Natural gas - Measurement of properties - Calorific value and Wobbe index (ISO 15971:2008)
EN ISO 15971:2014

EN-ISO 15971 concerns the measurement of calorific value of natural gas and natural gas substitutes by non-separative methods, i.e. methods that do not involve the determination of the gas composition nor calculation from it. It describes the principles of operation of a variety of instruments in use for this purpose, and provides guidelines for the selection, evaluation, performance assessment, installation and operation of these. Calorific values can be expressed on a mass basis, a molar basis or, more commonly, a volume basis. The working range for superior calorific value of natural gas, on the volume basis, is usually between 30 MJ/m3 and 45 MJ/m3 at standard reference conditions (see ISO 13443). The corresponding range for the Wobbe index is usually between 40 MJ/m3 and 60 MJ/m3. This International Standard neither endorses nor disputes the claims of any commercial manufacturer for the performance of an instrument. Its central thesis is that fitness-for-purpose in any particular application (defined in terms of a set of specific operational requirements) can be assessed only by means of a well-designed programme of experimental tests. Guidelines are provided for the proper content of these tests.

  • Standard
    58 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 13734:2014(Main)
Natural gas - Organic components used as odorants - Requirements and test methods (ISO 13734:2013)
EN ISO 13734:2013

This International Standard specifies requirements and test methods for organic compounds suitable for odorization of natural gas and natural gas substitutes for public gas supply, hereafter referred to as odorants.

  • Standard
    18 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 13686:2013(Main)
Natural gas - Quality designation (ISO 13686:2013)
EN ISO 13686:2013

This International Standard specifies the parameters required to describe finally processed and, where required, blended natural gas. Such gas is referred to subsequently in this text simply as "natural gas". The main text of this standard contains a list of these parameters, their units and references to measurement standards. Informative annexes give examples of typical values for these parameters, with the main emphasis on health and safety. In defining the parameters governing composition, physical properties and trace constituents, consideration has also been given to existing natural gases to ensure their continuing viability. The question of interchangeability is dealt with in annex A clause A.2.

  • Standard
    56 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 10723:2013(Main)
Natural gas - Performance evaluation for analytical systems (ISO 10723:2012)
EN ISO 10723:2012

This International Standard specifies a method of determining whether an analytical system for natural gas analysis is fit for purpose. It can be used either a) to determine a range of gas compositions to which the method can be applied, using a specified calibration gas, while satisfying previously defined criteria for the maximum errors and uncertainties on the composition or property or both, or b) to evaluate the range of errors and uncertainties on the composition or property (calculable from composition) or both when analysing gases within a defined range of composition, using a specifiedIt is assumed that a) for evaluations of the first type above, the analytical requirement has been clearly and unambiguously defined, in terms of the range of acceptable uncertainty on the composition, and, where appropriate, the uncertainty in physical properties calculated from these measurements, b) for applications of the second type above, the analytical requirement has been clearly and unambiguously defined, in terms of the range of composition to be measured and, where appropriate, the range of properties which may be calculated from these measurements, c) the analytical and calibration procedures have been fully described, and d) the analytical system is intended to be applied to gases having compositions which vary over rangesIf the performance evaluation shows the system to be unsatisfactory in terms of the uncertainty on the component amount fraction or property, or shows limitations in the ranges of composition or property values measurable within the required uncertainty, then it is intended that the operating parameters, including a) the analytical requirement, b) the analytical procedure, c) the choice of equipment, d) the choice of calibration gas mixture, and e) the calculation procedure, be reviewed to assess where improvements can be obtained. Of these parameters, the choice of the calibration gas composition is likely to have the most significant influence. This International Standard is applicable to analytical systems which measure individual component amount fractions. For an application such as calorific value determination, the method will be typically gas chromatography, set up, as a minimum, for the measurement of nitrogen, carbon dioxide, individual hydrocarbons from C1 to C5 and a composite measurement representing all higher hydrocarbons of carbon number 6 and above. This allows for the calculation of calorific value and similar properties with acceptable accuracy. In addition, components such as H2S can be measured individually by specific measurement methods to which this evaluation approach can also be applied. normally found in gas transmission and distribution systems. Performance evaluation of an analytical system is intended to be performed following initial installation to ensure that errors associated with assumed response functions are fit for purpose. Thereafter, periodic performance evaluation is recommended, or whenever any critical component of the analytical system is adjusted or replaced. The appropriate interval between periodic performance evaluations will depend upon both how instrument responses vary with time and also how large an error may be tolerated. This first consideration is dependent upon instrument/operation; the second is dependent on the application. It is not appropriate, therefore, for this International Standard to offer specific recommendations on intervals between performance evaluations.

  • Standard
    40 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 6974-1:2012/AC:2013(Main)
Natural gas - Determination of composition and associated uncertainty by gas chromatography - Part 1: General guidelines and calculation of composition - Technical Corrigendum 1 (ISO 6974-1:2012/Cor 1:2012)
EN ISO 6974-1:2012/AC:2012

This part of ISO 6974 gives methods for calculating component mole fractions of natural gas and specifies the data processing requirements for determining component mole fractions. This part of ISO 6974 provides for both single and multiple operation methods and either multi-point calibration or a performance evaluation of
the analyser followed by single-point calibration. This part of ISO 6974 gives procedures for the calculation of the raw and processed (e.g. normalized) mole fractions, and their associated uncertainties, for all components. The procedures given in this part of ISO 6974 are applicable to the handling of data obtained from replicate or
single analyses of a natural gas sample.

  • Corrigendum
    5 pages
    English language
    sale 10% off
    e-Library read for
    1 day
SIST
SIST EN ISO 6974-1:2012(Main)
Natural gas - Determination of composition and associated uncertainty by gas chromatography - Part 1: General guidelines and calculation of composition (ISO 6974-1:2012)
EN ISO 6974-1:2012

This part of ISO 6974 gives methods for calculating component mole fractions of natural gas and specifies the data processing requirements for determining component mole fractions. This part of ISO 6974 provides for both single and multiple operation methods and either multi-point calibration or a performance evaluation of
the analyser followed by single-point calibration. This part of ISO 6974 gives procedures for the calculation of the raw and processed (e.g. normalized) mole fractions, and their associated uncertainties, for all components. The procedures given in this part of ISO 6974 are applicable to the handling of data obtained from replicate or
single analyses of a natural gas sample.

  • Standard
    49 pages
    English language
    sale 10% off
    e-Library read for
    1 day