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GB/T 3653.4-2025: Ferroboron - Determination of aluminum content - EDTA titrimetric method, chrome azurol S spectrophotometric method and inductively coupled plasma atomic emission spectrometric method
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Std ID	Version	USD	Buy	Deliver [PDF] in	Title (Description)
GB/T 3653.4-2025	English	359	Add to Cart	4 days [Need to translate]	Ferroboron - Determination of aluminum content - EDTA titrimetric method, chrome azurol S spectrophotometric method and inductively coupled plasma atomic emission spectrometric method
GB/T 3653.4-2008	English	169	Add to Cart	3 days [Need to translate]	Ferroboron -- Determination of aluminium content -- EDTA titrimetric method
GB/T 3653.4-1988	English	199	Add to Cart	2 days [Need to translate]	Methods for chemical analysis of ferroboron--The EDTA volumetric method for the determination of aluminium content
GB 3653.4-1983	English	RFQ	ASK	3 days [Need to translate]	(Methods for chemical analysis of iron boron. EDTA volumetric method for determination of aluminum content)

GB/T 3653.4-2025: Ferroboron - Determination of aluminum content - EDTA titrimetric method, chrome azurol S spectrophotometric method and inductively coupled plasma atomic emission spectrometric method

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ICS 77.100 CCSH11 National Standards of the People's Republic of China Replaces GB/T 3653.4-2008 Determination of boron, iron, and aluminum content EDTA titration, chromium azure S spectrophotometry and Inductively Coupled Plasma Emission Spectroscopy Published on 2025-08-29 Implemented on 2026-03-01 State Administration for Market Regulation The State Administration for Standardization issued a statement.

Foreword

This document complies with the provisions of GB/T 1.1-2020 "Standardization Work Guidelines Part 1.Structure and Drafting Rules of Standardization Documents". Drafting. This document is Part 4 of GB/T 3653.GB/T 3653 has already published the following parts. ---Determination of Boron, Iron, and Boron Content by Alkali Titration (GB/T 3653.1); ---Determination of Carbon Content in Ferroboron by Gas Volumetric Method (GB/T 3653.2) ---Determination of Boron-Iron-Silicon Content by Perchloric Acid Dehydration Gravimetric Method (GB/T 3653.3); ---Determination of Boron-Iron-Aluminum Content. EDTA titration, Chromium Azure S spectrophotometry, and Inductively Coupled Plasma Atomic Emission Spectrometry (GB/T 3653.4); ---Chemical Analysis Methods for Ferroboron. Determination of Sulfur Content by Chromatographic Separation and Barium Sulfate Gravimetric Method (GB/T 3653.5); ---Chemical Analysis Methods for Boron-Iron. Determination of Phosphorus Content by Antimony-Phosphorus-Molybdenum Blue Spectrophotometry (GB/T 3653.6); ---Determination of Boron, Iron, and Sulfur Content by Infrared Absorption Method (GB/T 3653.7). This document supersedes GB/T 3653.4-2008 "Determination of Boron, Iron, and Aluminum Content by EDTA Titration". In comparison, aside from structural adjustments and editorial changes, the main technical changes are as follows. a) The scope has been changed (see Chapter 1, Chapter 1 of the.2008 edition); b) The instruments and equipment were changed (see 4.3, Chapter 5 of the.2008 edition); c) Added "Number of measurements" (see 4.5.2); d) Added "Representation of Analysis Results" (see 4.6.2); e) Added "Method 2.Chromium Azure S Spectrophotometry" (see Chapter 5); f) Added "Method 3.Inductively Coupled Plasma Emission Spectroscopy" (see Chapter 6); g) A "Flowchart for Accepting Sample Analysis Results" has been added (see Appendix A); h) "Performance test of inductively coupled plasma emission spectrometer" has been added (see Appendix B). Please note that some content in this document may involve patents. The issuing organization of this document assumes no responsibility for identifying patents. This document was proposed by the China Iron and Steel Association. This document is under the jurisdiction of the National Technical Committee on Standardization of Pig Iron and Ferroalloys (SAC/TC318). This document was drafted by. Shandong Metallurgical Research Institute Co., Ltd., Wuxi Zhuolang Materials Technology Co., Ltd., and Fangtongzhou Holdings. Limited Liability Company, Jiangsu Binxin Steel Group Co., Ltd., China Certification & Inspection Group Hebei Co., Ltd., Liaoyang International Boron Alloy Co., Ltd. Inner Mongolia Xintaiyuan New Materials Co., Ltd., Hebei Jinxi Steel Group Co., Ltd., Jilin Iron & Steel Ferroalloy Co., Ltd., Metallurgical Industry Information Standards Research Institute. The main drafters of this document are. Zhang Li, Wu Lijuan, Gao Hongji, Li Jing, Sun Yongfen, Cui Xiaocui, Ding Xiaotong, Liu Junli, Wu Zhifeng, and Zhao Lixin. Lin Tao, Chen Wanfeng, Zhou Ruidong, Wang Yingying, Tao Zhi, Wang Chao, Cao Fawei, Li Jinglin, Wang Lixia, Xu Zhibin, Meng Lili, Jiang Hongjiao, Sun Fengxiao Chu Yanshun, Ye Junying, Du Qianqian, Liu Fei, Zheng Haidong, Zheng Hongning, Wang Hao, Lu Chunsheng, Cheng Zhaoyang. This document was first published in 1983, revised for the first time in 1988, revised for the second time in.2008, and this is the third revision.

introduction

Because the detection of ferroborone involves many elements, and the applicable scope and methods for each element differ, it is crucial to ensure the accuracy of boron detection. To ensure the convenience and accuracy of iron testing standards, we have established a national standard system to support the analysis of different elements in ferroboron. The GB/T 3653 series of analytical methods for ferroboron is the basic standard for the detection of ferroboron in my country, and it is proposed to consist of the following seven parts. ---Determination of Boron Content in Ferroboron by Alkali Titration (GB/T 3653.1). The purpose is to determine the boron content in ferroboron using alkali titration. Titration method. ---Chemical Analysis Method for Ferroboron. Determination of Carbon Content by Gas Volumetric Method (GB/T 3653.2). The purpose is to measure the carbon content in ferroboron. The volume was determined using the gas volumetric method. ---Determination of Silicon Content in Ferroboron - Perchloric Acid Dehydration Gravimetric Method (GB/T 3653.3). The purpose is to determine the silicon content in ferroboron. The amount was determined by the perchloric acid dehydration gravimetric method. ---Determination of Boron-Iron-Aluminum Content. EDTA titration, Chromium Azure S spectrophotometry, and Inductively Coupled Plasma Atomic Emission Spectrometry (GB/T 3653.4). The purpose is to measure the aluminum content in ferroboron using EDTA titration and chromium azurite S spectrophotometry. And inductively coupled plasma emission spectroscopy. ---Chemical Analysis Method for Boron-Ferrous Iron. Determination of Sulfur Content by Chromatographic Separation and Barium Sulfate Gravimetric Method (GB/T 3653.5). The purpose is to measure the sulfur content in ferrous boron. The sulfur content was determined by the barium sulfate gravimetric method using chromatographic separation. ---Chemical Analysis Method for Boron-Iron. Determination of Phosphorus Content by Antimony-Phosphorus-Molybdenum Blue Spectrophotometry (GB/T 3653.6). The purpose is to measure the phosphorus content in ferroboron. The measurement was performed using the antimony-phosphorus-molybdenum blue spectrophotometric method. ---Determination of Sulfur Content in Ferroboron by Infrared Absorption Spectroscopy (GB/T 3653.7). The purpose is to measure the sulfur content in ferroboron using infrared absorption spectroscopy. Infrared absorption method. Determination of boron, iron, and aluminum content EDTA titration, chromium azure S spectrophotometry and Inductively Coupled Plasma Emission Spectroscopy Warning---Personnel using this document should have formal laboratory work experience. This document does not address all possible safety issues. Users are responsible for taking appropriate safety and health measures and ensuring compliance with relevant national regulations. 1.Scope This document describes the determination of boron-iron compounds using EDTA titration, chromium azurite S spectrophotometry, and inductively coupled plasma atomic emission spectrometry. Aluminum content. This document applies to the determination of aluminum content in ferroboron, with a determination range (mass fraction) of 0.02% to 8.00%. Method 1.EDTA titration Method 1.Determination range (mass fraction). 1.00%~8.00%; Method 2.Chromium Azure S spectrophotometric method determination range (mass fraction). 0.02%~ 1.00%; Method 3.Inductively Coupled Plasma Atomic Emission Spectrometry (ICP-AES) determination range (mass fraction). 0.02%~1.00%.

2 Normative references

The contents of the following documents, through normative references within the text, constitute essential provisions of this document. Dated citations are not included. For references to documents, only the version corresponding to that date applies to this document; for undated references, the latest version (including all amendments) applies. This document. GB/T 4010 Sample collection and preparation for chemical analysis of ferroalloys GB/T 6379.1 Accuracy (Correctness and Precision) of Measurement Methods and Results - Part 1.General Principles and Definitions GB/T 6379.2 Accuracy (correctness and precision) of measurement methods and results - Part 2.Determining the repeatability of standard measurement methods Basic methods of sex and representation GB/T 6682 Specifications and test methods for water used in analytical laboratories GB/T 7729 General Rules for Chemical Analysis of Metallurgical Products - Spectrophotometric Method GB/T 8170 Rules for rounding off numerical values and the representation and determination of limiting values GB/T 12805 Burettes for Laboratory Glassware GB/T 12806 Laboratory Glassware - Single-mark volumetric flasks GB/T 12807 Graduated Pipettes for Laboratory Glassware GB/T 12808 Laboratory Glassware - Single-mark Pipettes JJG768 Verification Procedure for Emission Spectrometer 3.Terms and Definitions This document does not contain any terms or definitions that need to be defined. 4.Method 1.EDTA Titration 4.1 Principle The sample was dissolved in nitric acid and hydrofluoric acid. After filtering out the residue, the filtrate was dissolved in hydrochloric acid medium, and iron ions were removed using methyl isobutyl ketone. The residue was then... Sodium pyrosulfate is melted, leached, and combined with the main liquid. Then, sodium hydroxide is used to separate impurities such as aluminum, manganese, and residual iron. An excess of sodium hydroxide is added. EDTA was titrated with copper sulfate standard solution at pH 5.5 using PAN as an indicator, followed by the addition of sodium fluoride. Release the EDTA complexed with aluminum, then back titrate with a standard copper sulfate solution, and calculate the mass fraction of aluminum based on the amount of standard solution consumed. 4.2 Reagents and Materials Unless otherwise specified, only approved analytical grade reagents and water of grade II or higher conforming to GB/T 6682 were used in the analysis. 4.2.1 Sodium pyrosulfate, solid. 4.2.2 Sodium hydroxide, solid. 4.2.3 Nitric acid, ρ≈1.42g/mL. 4.2.4 Perchloric acid, ρ≈1.67g/mL. 4.2.5 Hydrofluoric acid, ρ≈1.15g/mL. 4.2.6 Hydrochloric acid, ρ≈1.19g/mL. 4.2.7 Methyl isobutyl ketone. 4.2.8 Hydrogen peroxide, ρ≈1.10g/mL. 4.2.9 Hydrochloric acid, 1 1. 4.2.10 Hydrochloric acid, 7 5. 4.2.11 Hydrochloric acid, 5 95. 4.2.12 Sodium fluoride solution, 50 g/L. 4.2.13 Sodium hydroxide solution, 100 g/L. 4.2.14 Sodium hydroxide solution, 5 g/L. 4.2.15 Acetic acid-sodium acetate buffer solution (pH 5.5). Weigh.200g of sodium acetate (CH3COONa·3H2O) and dissolve it in 500mL of water. Add 9mL of glacial acetic acid (ρ≈1.05g/mL). Dilute with water to 1000 mL and mix well. 4.2.16 Aluminum standard solution,.200 μg/mL. Weigh 0.2000g of metallic aluminum (purity not less than 99.98%) into a 250mL beaker, add 5mL of water, and then add 15mL of water in several portions. Sodium hydroxide (4.2.13), after being heated to dissolve, is neutralized with hydrochloric acid (4.2.9) in excess (10 mL), boiled until dissolved, cooled to room temperature, and then transferred to... Dilute to the mark with water in a 1000mL volumetric flask and mix well. 1mL of this solution contains.200μg of aluminum. Commercially available certified standard solutions can also be used. 4.2.17 Copper sulfate standard titration solution, 0.01 mol/L. Preparation. Weigh 2.50g of copper sulfate (CuSO4·5H2O), place it in a 300mL beaker, add an appropriate amount of water to dissolve it, and then transfer it to... Add 1 to 2 drops of sulfuric acid (ρ≈1.84g/mL) to a 1000mL volumetric flask, dilute to the mark with water, and mix well. Standardization. Transfer 20.00 mL of EDTA standard solution (4.2.18) to a 300 mL Erlenmeyer flask, add 50 mL of water and 2 drops of phenolphthalein. The indicator solution (4.2.19) is added dropwise with sodium hydroxide solution (4.2.13) until it turns red, then neutralized with hydrochloric acid (4.2.9) until it is just colorless and in excess. Add 1-2 drops to 15 mL of acetate-sodium acetate buffer solution (4.2.15), heat to boiling, remove from heat, and add 8-10 drops of PAN indicator while hot. The reagent solution (4.2.20) was titrated with copper sulfate standard titration solution (4.2.17) until a clear purple-red color was obtained. Calculate the volume ratio factor for converting copper sulfate standard titration solution to EDTA standard titration solution according to formula (1). K= V1 V2 (1) ...