GOST R ISO 13898-2-2006
GOST R ISO 13898−2-2006 Steel and cast iron. Spectrometer of atomic emission with inductively coupled plasma method for the determination of Nickel, copper and cobalt. Part 2. The determination of Nickel
GOST R ISO 13898−2-2006
Group B39
NATIONAL STANDARD OF THE RUSSIAN FEDERATION
Steel and cast iron.
SPECTROMETRIC ATOMIC EMISSION
INDUCTIVELY COUPLED PLASMA METHOD FOR THE DETERMINATION
NICKEL, COPPER AND COBALT.
Part 2.
The determination of Nickel
Stell and iron. Inductively coupled plasma atomic emission
spectrometric method for determination of nicel.
Part 2. Determination of content nicel
OKS 77.080.01
AXTU 0709
Date of introduction 2008−01−01
Preface
The objectives and principles of standardization in the Russian Federation established by the Federal law of 27 December 2002 N 184-FZ «On technical regulation», and rules for the application of national standards of the Russian Federation — GOST R 1.0−2004 «Standardization in the Russian Federation. The main provisions"
Data on standard
1 PREPARED AND SUBMITTED by the Technical Committee for standardization TC 145 «monitoring Methods of steel products"
2 APPROVED AND put INTO EFFECT by the Federal Agency for technical regulation and Metrology of December 21, 2006 No. 327-St
3 this standard is identical with ISO 13898−2:1997 «Steel and cast iron. Determination of Nickel, copper and cobalt. Spectrometric method of atomic emission with inductively coupled plasma. Part 2. Determination of Nickel content» (ISO 13898−2:1997 «Steel and iron — Determination of nickel, copper and cobalt contents — Inductively coupled plasma atomic emission spectrometric method. Part 2: Determination of nickel content»).
The name of this standard changed with respect to names specified international standard for compliance with GOST R 1.5−2004 (subsection 3.5).
In applying this standard it is recommended to use instead of the referenced international standards corresponding national standards of the Russian Federation, details of which are given in the Appendix With
4 INTRODUCED FOR THE FIRST TIME
AMENDED, published in the IUS N 9, 2007
An amendment made by the manufacturer of the database
Information about the changes to this standard is published in the annually issued reference index «National standards», and the text changes and amendments — in monthly indexes published information «National standards». In case of revision (replacement) or cancellation of this standard a notification will be published in a monthly information index «National standards». Relevant information, notification and lyrics are also posted in the information system of General use — on the official website of the Federal Agency for technical regulation and Metrology on the Internet
1 Scope
This standard specifies the spectrometer of atomic emission with inductively coupled plasma method for the determination of Nickel in non-alloy steels and cast iron.
The method is applicable for determining the mass fraction of Nickel in the range of 0.001% and 0.30%.
2 Normative references
This standard uses the regulatory references to the following international standards:
ISO 5725−1:1994 Accuracy (trueness and precision) of methods and measurement results. Part 1. General provisions and definitions
ISO 5725−2:1994 Accuracy (trueness and precision) of methods and measurement results. Part 2. The basic method for the determination of repeatability and reproducibility of a standard measurement method
ISO 5725−3:1994 Accuracy (trueness and precision) of methods and measurement results. Part 3. Intermediate indicators the precision of a standard measurement method
ISO 13898−1:1997 Steel and iron. Determination of Nickel, copper and cobalt. Spectrometric method of atomic emission with inductively coupled plasma. Part 1. General requirements and sampling
ISO 14284:1996 Steel and iron. Selection and preparation of samples for chemical analysis
3 General requirements
General requirements — ISO 13898−1.
4 Reagents and solutions
Unless otherwise specified, use reagents of the established analytical purity, distilled water, further purified by distillation or other means.
Additional requirements for the reagents — ISO 13898−1.
4.1 Standard solutions of Nickel
4.1.1 the Basic solution with 1.0 g/lof Nickel.
Preparation of standard solution: weighed metallic Nickel with a mass of 1,000 grams, taken with an accuracy of 0.1 mg and a purity of more than 99.99% was placed in a beaker with a capacity of 200 cm. Add 50 cm
of nitric acid (ISO 13898−1, 4.3), cover watch glass, heat gradually and boil until dissolved. Cooled to room temperature, transferred to a measuring flask with volume capacity of 1000 cm
, then bring to the mark with water and mix.
1 cmstandard solution contains 1.0 mg of Nickel.
4.1.2 Standard solution A, corresponding to 0,100 g/lof Nickel.
20.0 cmstandard solution of Nickel (4.1.1) is transferred to a volumetric flask with a capacity of 200 cm
, adjusted to the mark with water and mix.
Standard solution And prepared immediately before use.
1 cmstandard solution contains 0.10 mg of Nickel.
4.1.3 Standard solution corresponding to 0,020 g/lof Nickel.
10.0 cmcore solution of Nickel (4.1.1) is transferred to a volumetric flask with a capacity of 500 cm
, was adjusted to the mark with water and mix.
A standard solution is prepared immediately before use.
1 cmstandard solution contains 0,020 mg of Nickel.
If the calibration curve obtained is nonlinear, can be used an additional series of calibration solutions.
5 Instrument
Equipment must meet ISO 13898−1.
6 Sampling
Sampling — ISO 14284.
7 Preparation and analysis
7.1 the Hitch weight 1,000 g weighed with an accuracy of 1 mg.
7.2 the Control and experience that corresponds to the sample with zero content of Nickel, is carried out according to ISO 13898−1, 7.2.
7.3 Preparation of the sample solution is carried out according to ISO 13898−1,
7.3.1 Preparation of the calibration solutions
Make six chemical glasses with a capacity of 200 cmeach (1,00±0,001) g of pure iron (ISO 13898−1, 4.1), added to each 10 cm
of nitric acid (ISO 13898−1, 4.3), cover the watch glass and slowly heated until the cessation of the stormy vapors escaping. Add 10 cm
of hydrochloric acid (ISO 13898−1, 4.2) and continue heating until dissolved. Cooled to room temperature and quantitatively transfer the solution into six volumetric flasks with a capacity of 200 cm
each, rinsing them with a minimal amount of water. Using a pipette or burette, add to the volumetric flask standard solution of Nickel And (4.1.2), the volume of which is indicated in table 1.
Table 1 — Mass fraction of Nickel from 0.001% to 0.30%
The volume of a standard solution of Nickel And cm |
The concentration of Nickel |
Mass fraction of Nickel in the sample, % |
| 0* |
0 |
0 |
| 5,0 |
2,50 |
0,050 |
| 10,0 |
5,00 |
0,100 |
| 15,0 |
7,50 |
0,150 |
| 20,0 |
10,0 |
0,200 |
| 30,0 |
15,0 |
0,300 |
| * A solution with zero concentration of the element. | ||
If the calibration curve will be linear, can be used for additional calibration series of solutions (for example from tables 2 and 3). If you apply the methodology of the internal standard, then add 2cmof a solution of internal standard scandium (ISO 13898−1, 4.4) or 10 cm
of a solution of internal standard yttrium (ISO 13898−1, 4.5). Bring to mark with water and mix.
Table 2 — Mass fraction of Nickel less than 0.010%
The volume of a standard solution of Nickel, cm |
The concentration of Nickel |
Mass fraction of Nickel in the sample, % |
| 0* |
0 |
0 |
| 0,5 |
0,050 |
0,0010 |
| 1,0 |
0,100 |
0,0020 |
| 2,0 |
0,200 |
0,0040 |
| 3,0 |
0,300 |
0,0060 |
| 5,0 |
0,500 |
0,0100 |
| * A solution with zero concentration of the element. | ||
Table 3 — Mass fraction of Nickel from 0.010% to 0,060%
The volume of a standard solution of Nickel, cm |
The concentration of Nickel |
Mass fraction of Nickel in the sample, % |
| 0* |
0 |
0 |
| 5,0 |
0,50 |
0,010 |
| 10,0 |
Of 1.00 |
0,020 |
| 20,0 |
Of 2.00 |
0,040 |
| 30,0 |
Of 3.00 |
0,060 |
| 50,0 |
5,00 |
0,100 |
| * A solution with zero concentration of the element. | ||
7.4 Spectrometer measurements
7.4.1 Optimization of the device
Perform operations according to ISO 13898−1,
7.4.2 Measurement of radiation intensity
Perform operations according to ISO 13898−1,
7.4.3 Preparation of calibration curve
Perform operations according to ISO 13898−1,
8 Determination of results
8.1 Processing of results
Perform operations according to ISO 13898−1, 8.1.
The result of the analysis taking the arithmetic mean of two parallel definitions, if the differences between them do not exceed the values of permissible differences given in table 4 or calculated according to the schedule given in Appendix V.
Table 4
Percentage
| Mass fraction of Nickel |
The limit of repeatability (convergence) |
The limit of reproducibility |
The limit of intermediate precision |
| 0,001 |
0,00039 |
0,00076 |
0,00055 |
| 0,002 |
0,00046 |
0,00095 |
0,00067 |
| 0,005 |
0,00056 |
0,0013 |
0,00087 |
| 0,010 |
0,00066 |
0.0016 inch |
0,0010 |
| 0,020 |
0,00077 |
0,0020 |
0,0013 |
| 0,050 |
0,00095 |
0,0028 |
0.0016 inch |
| 0,050 |
0,0013 |
0,0037 |
0,0020 |
| 0,100 |
0,0026 |
0,0074 |
0,0037 |
| 0,200 |
0,0051 |
0,015 |
0,0070 |
| 0,300 |
0,0075 |
0,023 |
0,010 |
8.2 Precision
Routine testing of the present method was carried out in 26 laboratories in 12 countries. Analyzed 11 samples with a Nickel content within the specified range. Each laboratory performed three to determine each sample (see notes 1 and 2 of this subsection). Used samples are given in table A. 1 (Appendix A).
The results were processed statistically in accordance with ISO 5725−1, ISO 5725−2, ISO 5725−3 using data analysis of these samples containing 11 levels of Nickel concentrations in the working range.
The data obtained showed the presence of a logarithmic relationship between the mass fraction of Nickel and a margin of error of convergence of analysis results as well as indicators of the limit of reproducibility
and the limit of intermediate precision
(see note 3 of this subsection) that is presented in table 4. More information on international tests given in Appendix A.
Graphical representation of the data is given in Appendix V.
Notes
1 Two of the three definitions was carried out under conditions of repeatability, specified in ISO 5725−1, i.e. a single operator on the same equipment at identical operating conditions, one calibration and for the minimum period of time.
2 the Third definition was made at a different time (another day) by the same operator who performed the determination, described in note 1, using the same instrument with a new calibration.
3 the results obtained on the first day, was calculated according to ISO 5725−2, the limit of repeatability (convergence) and reproducibility limit
. According to the first result obtained on the first day, and the result obtained on the second day, was calculated according to ISO 5725−3 intralaboratory limit of intermediate precision
.
9 test report
Test report — ISO 13898−1, section 9.
Annex a (informative). More information on international testing
Appendix A
(reference)
Data for the repeatability (convergence) and reproducibility given in table 4, were obtained based on the results of international analytical tests carried out on nine samples of steel and two samples of cast iron with the participation of 26 laboratories.
The analyzed samples are presented in table A1.
Table A. 1
Percentage
| Sample |
Mass fraction of Nickel |
Data precision | ||||
| Certifi- carovano |
Received |
Limit povtorju- |
The limit of rehabilitation |
The limit of intermediate precision | ||
| JSS 003 Non-alloy steel |
0,0008 |
0,00076 |
0,00076 |
0,00049 |
0,00075 |
0,00053 |
| NR 1 C Non-alloy steel |
0,0090 |
0,0090 |
0,0089 |
0,00043 |
0,0014 |
0,0010 |
| NR 21 Non-alloy steel |
0,035 |
0,0346 |
0,0345 |
0,0011 |
0,0036 |
0,0013 |
| NBS 15 h Non-alloy steel |
0,017 |
0,0178 |
0,0178 |
0,00069 |
0,0023 |
0,0011 |
| F 16 NBS Non-alloy steel |
0,008 |
0,0083 |
0,0082 |
0,00054 |
0,0017 |
0,0011 |
| BAS 087−1 Non-alloy steel |
0,118 |
0,119 |
0,119 |
0,0029 |
0,0108 |
0,0043 |
| BCS 452 Non-alloy steel |
0,19 |
0,191 |
0,191 |
0,0040 |
0,0146 |
0,0056 |
| IRSID 081−1 Non-alloy steel |
0,042 |
0,0422 |
0,0422 |
0,00090 |
0,0024 |
0,0021 |
| IRSID 010−1 Non-alloy steel |
0,259 |
0,264 |
0,264 |
0,0089 |
0,0175 |
0,0107 |
| EURO 488−1 Pig iron |
0,0651 |
0,0655 |
0,0654 |
0,0012 |
0,0043 |
0,0023 |
| EURO 487−1 Pig iron |
0,040 |
0,0405 |
0,0404 |
0,0014 |
0,0027 |
0,0015 |
* The average value of the results obtained in the course of one day.
| ||||||
Annex b (informative). Graphical representation of the data for precision
The App
(reference)
| Mass fraction of Nickel less than 0.03%: |
Mass fraction of Nickel from 0.03% to 0.3%: |
|
|
|
|
|
|
;
;
;
;
,
,
where — the average value of the mass fraction of Nickel, obtained in the course of one day, %;
the average value of the mass fraction of Nickel based on the data of different days, %.
Figure B. 1 — Logarithmic plot between the mass fraction of Nickel and a limit
the repeatability or reproducibility limit
and the limit of intermediate
precision .
Application (reference). Data on compliance with national standards of the Russian Federation the reference to international standards
Application
(reference)
Table C. 1
| Marking the reference international standard |
Name and abbreviation relevant national standards |
| ISO 5725−1:1994 |
GOST R ISO 5725−1-2002 Accuracy (trueness and precision) of methods and measurement results. Part 1. General provisions and definitions |
| ISO 5725−2:1994 |
GOST R ISO 5725−2-2002 Accuracy (trueness and precision) of methods and measurement results. Part 2. The basic method for the determination of repeatability and reproducibility of a standard measurement method |
| ISO 5725−3:1994 |
GOST R ISO 5725−3-2002 Accuracy (trueness and precision) of methods and measurement results. Part 3. Intermediate indicators the precision of a standard measurement method |
| ISO 13898−1:1997 |
GOST R ISO 13898−1-2006 Steel and cast iron. Spectrometer of atomic emission with inductively coupled plasma method for the determination of Nickel, copper and cobalt. General requirements |
| ISO 14284:1996 |
* |
| * The corresponding national standard is missing. Prior to its adoption, it is recommended to use the translation into Russian language of this international standard. The translation of this international standard is the Federal information Fund of technical regulations and standards. | |
