Powered by Google-Search & Google-Books www.ChineseStandard.net Database: 169759 (Aug 1, 2021)
HOME   Quotation   Tax   Examples Standard-List   Contact-Us   Cart
  

GB/T 33817-2017 (GBT 33817-2017)

GB/T 33817-2017_English: PDF (GBT33817-2017)
Standard IDContents [version]USDSTEP2[PDF] delivered inStandard Title (Description)Related StandardStatusGoogle Book
GB/T 33817-2017English145 Add to Cart 0--10 minutes. Auto-delivered. Method for determination of the carbon content on the inner surface of copper and copper-alloy tube GB/T 33817-2017 Valid GB/T 33817-2017
 

BASIC DATA
Standard ID GB/T 33817-2017 (GB/T33817-2017)
Description (Translated English) Method for determination of the carbon content on the inner surface of copper and copper-alloy tube
Sector / Industry National Standard (Recommended)
Classification of Chinese Standard H13
Classification of International Standard 77.120.99
Word Count Estimation 9,950
Date of Issue 2017-05-31
Date of Implementation 2017-12-01
Drafting Organization Zhejiang Metallurgical Products Quality Inspection Station Co., Ltd., Zhejiang HaiLiang Co., Ltd., Zhejiang Tianning Alloy Material Co., Ltd.
Administrative Organization National Standard Committee on Nonferrous Metals (SAC/TC 243)
Proposing organization China Nonferrous Metals Industry Association
Issuing agency(ies) General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China, China National Standardization Administration Committee
Summary This standard specifies the determination of carbon content in the inner surface of copper and copper alloy pipes or fittings. This standard is applicable to the quantitative detection of carbon content in the inner surface of copper and copper alloy pipe or pipe fittings. The measurement range is 5 mg/m ^ 2 ~ 500 mg/m ^ 2

GB/T 33817-2017
GB
NATIONAL STANDARD OF THE
PEOPLE’S REPUBLIC OF CHINA
ICS 77.120.99
H 13
Method for Determination of
the Carbon Content on the Inner
Surface of Copper and Copper-Alloy Tube
ISSUED ON. MAY 31, 2017
IMPLEMENTED ON. DECEMBER 1, 2017
Issued by. General Administration of Quality Supervision, Inspection and
Quarantine;
Standardization Administration of PRC.
3. No action is required - Full-copy of this standard will be automatically &
immediately delivered to your EMAIL address in 0~60 minutes.
Table of Contents
Foreword ... 3
1 Scope ... 4
2 Terms and Definitions ... 4
3 Method Summary ... 4
4 Reagents ... 5
5 Apparatus ... 5
6 Specimen ... 6
7 Test Procedures ... 9
8 Calculation of Analysis Results ... 10
9 Precision ... 11
10 Test Report ... 12
Appendix A (Informative) Recommended Analysis Condition ... 13
Foreword
This Standard was drafted as per the rules specified in GB/T 1.1-2009.
This Standard was proposed by China Nonferrous Metals Industry Association.
This Standard shall be under the jurisdiction of National Technical Committee for
Standardization of Nonferrous Metals (SAC/TC 243).
Drafting organizations of this Standard. Zhejiang Province Metallurgic Products Quality
Test Station Co., Ltd., Zhejiang Hailiang Co., Ltd., and Zhejiang Tianning Alloy Material
Co., Ltd.
Chief drafting staffs of this Standard. Kong Shuilong, Yu Genghua, He Youqi, Wei
Lianyun, Ma Yong, Wang Yungang, Zhao Xuelong, Qian Xiaodong, and Chen Xuguang.
Method for Determination of
the Carbon Content on the Inner
Surface of Copper and Copper-Alloy Tube
1 Scope
This Standard specifies the method for determination of carbon content in copper and
copper-alloy tube or on the inner surface of tube.
This Standard is applicable to the quantitative test of carbon content in n copper and
copper-alloy tube or on the inner surface of tube; the measuring range is 5mg/m2 ~
500mg/m2.
2 Terms and Definitions
The following terms and definitions are applicable to this document.
2.1 Residual carbon (CR)
The carbon existing in the single substance form.
2.2 Potential carbon (CP)
The carbon existing in the organic compounds (e.g.. organic compounds of oil, grease,
etc.).
2.3 Total carbon (CT)
The total sum of residual carbon and potential carbon.
3 Method Summary
Heat the copper and copper-alloy tube or tube sample in the oxygen stream to certain
temperature, and burn the carbon existing on the inner surface. Use the infrared
absorption spectroscopy to determine the generated carbon dioxide; then measure the
content of residual carbon and potential carbon, respectively.
The content of potential carbon shall be calculated by substracting the residual carbon
from total carbon.
4 Reagents
4.1 Oxygen (minimum mass purity of 99.99%). the oxygen that can be purified to
99.99% by the purifier.
4.2 Deionized water (containing no carbon dioxide). boil the deionized water for
30min; inject the oxygen (4.1) for 15min during the process of cooling off the deionized
water to the room temperature; prepare before use.
4.3 Tetrachloroethylene (analytically pure).
4.4 Trichloroethylene (analytically pure).
4.5 Trichloroethane (analytically pure).
4.6 Nitric acid (1+1).
4.7 Mannitol Standard Solution A. weigh 1.2640g of mannitol (C6H14O6, pre-dry at
100°C~105°C, and place into the desiccator to cool off to the room temperature); place
into 100mL beaker; add deionized water (4.2) to dissolve. Transfer into 100mL
volumetric flask; dilute with deionized water (4.2) to the scale; mix evenly. 1µL of such
solution contains 5µg of carbon.
4.8 Mannitol Standard Solution B. transfer 10.00mL of mannitol standard solution
(4.7) into 100mL volumetric flask; dilute with deionized water (4.2) to the scale; mix
evenly. 1µL of such solution contains 5µg of carbon.
4.9 Carbon dioxide gas (minimum mass purity of 99.99%).
4.10 Soda asbestos.
4.11 Anhydrous magnesium perchlorate.
5 Apparatus
5.1 Tube furnace heating-infrared carbon and sulfur analyzer
The connection schematic diagram of the device can refer to Figure 1. The burning
process is implemented in the quartz pipe.
6.3.3 Use the cleaning square saws or bow saws with dense teeth to cut off the
required length; avoid the overheating of the specimen.
6.3.4 If the specimen length is greater than the length of combustion zone specified
by the combustion device in the sample chamber; cut the pipe fitting into two parts; so
that the two parts can enter into the combustion zone at the same time. If using the
electric saws, ensure the all saw surfaces contacting with the pipe fitting surface have
been degreased. When cutting and filing the pipe fitting, ensure the pipe sample is
fixed firmly (for instance, placing into the pliers) without excessive distortion.
6.3.5 When the diameter of copper and copper-alloy tube or pipe fitting exceeds the
furnace diameter, flatten the copper and copper-alloy tube and pipe fitting, so that
obtain the specimen with the inner surface meeting the requirements of test.
7 Test Procedures
7.1 Specimen
Take the prepared specimen (see 6.3).
7.2 The number of measurement
Perform two separate measurements, then take their average value.
7.3 Preparation before analysis
Inject the oxygen, check whether the pipe and piston of the whole device leaks gas.
Adjust and maintain the instrument into the normal working state. Turn on the power
and raise temperature to 600°C±10°C. The recommended analysis condition can refer
to Appendix A.
7.4 Blank test
7.4.1 Perform two blank tests before measurement.
7.4.2 Take the blank test specimen (see 6.2.4, 6.3); measure as per 7.6; the blank
value shall be calculated by the total surface area (inner and outer surface areas) of
the blank specimen. The blank value shall be the arithmetic mean of two specimens
measured; the blank value shall be no greater than 1.5mg/m2.
7.4.3 If the blank value is too large, the specimen preparation shall be re-evaluated
and re-set the blank value.
7.5 Calibration test
7.5.1 According to the carbon content in the specimen, select the corresponding