GB/T 223.69-2008 (GB/T223.69-2008, GBT 223.69-2008, GBT223.69-2008)
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GB/T 223.69-2008 | English | 145 |
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Iron, steel and alloy -- Determination of carbon contents -- Gas-volumetric method after combustion in the pipe furnace
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GB/T 223.69-2008
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GB/T 223.69-1997 | English | RFQ |
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Methods for chemical analysis of iron, steel and alloy. The gas-volumetric method after combustion in the pipe furnace for the determination of carbon content
| Obsolete |
GB/T 223.69-1997
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GB/T 223.69-1989 | English | RFQ |
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Methods for chemical analysis of iron, steel and alloy--The combustion volumetric method for the determination of carbon content
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GB/T 223.69-1989
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Standard ID | GB/T 223.69-2008 (GB/T223.69-2008) | Description (Translated English) | Iron, steel and alloy - Determination of carbon contents - Gas-volumetric method after combustion in the pipe furnace | Sector / Industry | National Standard (Recommended) | Classification of Chinese Standard | H11 | Classification of International Standard | 77.080.01 | Word Count Estimation | 37,355 | Date of Issue | 2008-05-13 | Date of Implementation | 2008-11-01 | Older Standard (superseded by this standard) | GB/T 223.69-1997 | Quoted Standard | GB/T 6379.1; GB/T 6379.2; GB/T 20066 | Drafting Organization | China Steel Research Institute Group | Administrative Organization | National Steel Standardization Technical Committee | Regulation (derived from) | National Standard Approval Announcement 2008 No.8 (Total No.121) | Proposing organization | China Iron and Steel Association | Issuing agency(ies) | Administration of Quality Supervision, Inspection and Quarantine of People's Republic of China; Standardization Administration of China | Summary | This standard specifies the determination of the carbon content of the combustion tube with the gas volumetric method. This section applies to steel, iron, mass fraction of high-temperature alloys and precision alloy for the determination of 0. 10% to 2. 00% carbon content. |
GB/T 223.69-2008
GB
NATIONAL STANDARD OF THE
PEOPLE’S REPUBLIC OF CHINA
ICS 77.080.01
H 11
Replacing GB/T 223.69-1997
Iron, steel and alloy - Determination of carbon
contents - Gas-volumetric method after
combustion in the pipe furnace
ISSUED ON. MAY 13, 2008
IMPLEMENTED ON. NOVEMBER 01, 2008
Issued by. General Administration of Quality Supervision, Inspection and
Quarantine of the People’s Republic of China;
Standardization Administration of the People’s Republic of
China.
Table of Contents
Foreword ... 3
1 Scope ... 4
2 Normative references ... 4
3 Principle ... 5
4 Reagents and materials ... 5
5 Instruments and equipment ... 6
6 Sampling ... 8
7 Analysis procedure ... 9
8 Calculation of results ... 10
9 Precision ... 12
10 Test report ... 12
Annex A (informative) Correction factor of temperature and pressure ... 14
Annex B (informative) Additional information for precision joint test... 42
Foreword
This Part of GB/T 223 replaces GB/T 223.69-1997 “Methods for chemical analysis of
iron, steel and alloy - The gas-volumetric method after combustion in the pipe furnace
for the determination of carbon content”.
Compared with GB/T 223.69-1997, main modifications of this Part are as follows.
- MODIFY the name to “Iron, steel and alloy - Determination of carbon contents -
Gas-volumetric method after combustion in the pipe furnace”.
- MODIFY the equations for calculation of results and the units of the amount in the
equations;
- NORMALIZE the description of the precision function.
Annexes A and B of this Part are informative annexes.
This Part is proposed by China Iron and Steel Association.
This Part is under the jurisdiction of National Technical Committee on Iron & Steel of
Standardization Administration of China.
Drafting organization of this Part. China Iron & Steel Research Institute Group.
Main drafters of this Part. Cui Qiuhong, Wang Yuxing.
The historical editions of the standard replaced by this Part are as follows.
GB 223.69-1989, GB/T 223.69-1997.
Iron, steel and alloy - Determination of carbon
contents - Gas-volumetric method after
combustion in the pipe furnace
Warning. Personnel using this Part shall have practical experience in formal
laboratory work. This Part does not indicate all possible security issues. It is the
user's responsibility to take appropriate safety and health measures and to
ensure compliance with the requirements of the relevant state laws and
regulations.
1 Scope
This Part of GB/T 223 specifies a gas-volumetric method after combustion in the pipe
furnace for the determination of the carbon content.
This Part applies to the determination of the carbon content with the mass fraction of
0.10 % ~ 2.00 % in steel, iron, high temperature alloys and precision alloys.
2 Normative references
The following standards contain provisions which, through reference in this Part of
GB/T 223, constitute provisions of this Part. At the time of publication, the editions
indicated were valid. All standards are subject to revision, and parties to agreements
based on this Part are encouraged to investigate the possibility of applying the most
recent editions of the standards indicated below. For undated references, the latest
edition of the normative document referred to applies.
GB/T 6379.1 Accuracy (trueness and precision) of measurement methods and
results - Part 1. General principles and definitions
GB/T 6379.2 Accuracy (trueness and precision) of measurement methods and
results - Part 2. Basic method for the determination of repeatability and
reproducibility of a standard measurement method
GB/T 20066 Steel and iron - Sampling and preparation of samples for the
determination of chemical composition
3 Principle
The sample and flux are combusted in the high temperature (1 200 °C ~ 1 350 °C)
pipe furnace with oxygen introduced, and the carbon is completely oxidized to carbon
dioxide. After removing the sulfur dioxide, collect the gas mixture in the gas burette,
and measure the volume. Use potassium hydroxide solution to absorb carbon dioxide,
and then measure the volume of the remaining gas. The difference between the
volume of gas before and after absorption is the volume of carbon dioxide, which is
used to calculate the carbon content.
4 Reagents and materials
4.1 Oxygen, with the purity of not less than 99.5 % (volume fraction).
If oxygen is suspected of containing organic impurities, an oxidizing catalyst [copper
oxide (II) or platinum] pipe heated to the temperature of above 45 °C shall be added
before using the oxygen purification device.
4.2 Solvent, applicable to washing the oil or dirt on the surface of the sample, such as
acetone.
4.3 Active manganese dioxide (or silver vanadate), granular.
When there is not suitable chemically active grade manganese dioxide, it can be
prepared as follows.
To prepare about 50 g of active manganese dioxide, DISSOLVE 200 g of manganese
tetra-sulfate manganese sulfate (MnSO4 • 4H2O) in 2.5 L of water in a 4 L beaker,
ADJUST it to alkaline with ammonia (ρ is about 0.90 g/mL), ADD 1 L of freshly prepared
ammonium persulfate solution (225 g/L), HEAT the solution to boil and keep boiling for
another 10 min. During the heating and boiling, in order to keep the solution being
ammoniac, ammonia shall be continuously added to settle the precipitate. If the
supernatant does not clear or precipitate does not settle quickly, it may add 50 mL ~
100 mL of ammonium persulfate solution (225 g/L), boil for 10 min and keep the
solution always being ammoniac. ALLOW the solution to stand for some time so that
the manganese dioxide is completely precipitated. SIPHON the supernatant carefully
and WASH the precipitate with 3 L or 4 L of warm water at 500 mL to 600 mL each
using decantation method. After each wash and before decantation, fully stir the
manganese dioxide in water to make it settle. Finally, wash with dilute sulfuric acid
solution [add 2 drops of sulfuric acid per 1 000 mL of solution (ρ is 1.84 g/mL)] twice in
the same manner.
During this period, PREPARE a funnel with the diameter of 15 cm, TAKE a filter plate
with the diameter of 5 cm and PLACE it on the funnel, and COVER the filter plate with
a thin layer of purified asbestos pulp (it may also use a Brinell porcelain funnel instead
of a filter plate). After the last wash, TRANSFER the manganese dioxide to the filter,
RINSE it with warm water until it is free of sulfate ions, and PLACE it on a porcelain
plate and DRY in an oven at 105 °C. Finely GROUND the manganese dioxide in a
mortar so that it passes through a sieve with the diameter of 0.8 mm, and then
sufficiently DRY at 105 °C.
4.4 Potassium permanganate - potassium hydroxide solution, WEIGH 30 g of
potassium hydroxide and DISSOLVE in 70 mL of potassium permanganate saturated
solution.
4.5 Sulfuric acid blocking solution, ADD 1 mL of sulfuric acid (ρ is about 1.84 g/mL) to
1 000 mL of water, and ADD a few drops of methyl orange solution (1 g/L) until there
is a stable light red.
4.6 Sodium chloride blocking solution, WEIGH 26 g of sodium chloride and DISSOLVE
in 74 mL of water, ADD a few drops of methyl orange solution (1 g/L), ADD sulfuric acid
(1 + 2) dropwise until there is a stable light red.
4.7 Flux, granular tin, copper, copper oxide, vanadium pentoxide, iron powder. The
carbon content of each flux shall generally not exceed 0.005 0 % by mass. The blank
test shall be carried out before use, and the blank value shall be deducted from the
measured value of the sample.
4.8 Glass wool.
5 Instruments and equipment
In analysis, except for the following provisions, only ordinary laboratory instruments
and equipment are used.
Instruments and equipment installation are shown in Figure 1.
1 - oxygen bottle;
2 - partial pressure gauge (with flow meter and buffer valve);
3 - buffer bottle;
4 - gas washing bottle I;
5 - gas washing bottle II;
6 - drying tower;
7 - oxygen supply piston;
8 - glass ground stopper;
9 - pipe furnace;
10 - temperature controller (or pressure regulator).
11 - spherical drying pipe;
12 - desulfurizing pipe;
13 - capacity carbon detector (including serpentine pipe a, gas burette b, levelling
bottle c, absorber d, small piston e, three-way piston f).
14 - porcelain pipe;
15 - porcelain boat.
Figure 1 -- Diagram of instrument and equipment
5.1 Oxygen purification device
5.1.1 Buffer bottle (see Figure 1)
5.1.2 Gas washing bottle I (see Figure 1), containing potassium permanganate -
potassium hydroxide solution (4.4), and the amount of the solution loading is about a
third of the volume of the gas washing bottle I.
5.1.3 Gas washing bottle II (see Figure 1), containing sulfuric acid (ρ about 1.84 g/mL).
and the amount of sulfuric acid loading is about one third of the volume of the gas
washing bottle II.
5.1.4 Drying tower (see Figure 1), containing asbestos (or soda lime) on the upper
layer, and anhydrous calcium chloride on the lower layer, separated with glass wool
(4.8) in the middle; the bottom and the top are also covered with glass wool.
5.2 Pipe furnace (see Figure 1)
With thermocouple and temperature controller. High-temperature heating equipment
can also be high-frequency heating device.
5.3 Porcelain pipe (see Figure 1)
The porcelain pipe is of 600 mm length and 23 mm diameter (porcelain pipes of similar
specifications can also be used). The thick end of the porcelain pipe is connected to
the glass ground stopper, and the conical end is connected to the spherical drying pipe
by a rubber pipe. Check whether it leaks before use, and then burn. The rubber stopper
for the connection between the porcelain pipe and the oxygen purification device (5.1),
the drying pipe, and the desulfurizing ...
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