Determination of iron in copper smelting dust by titanium trichloride reduction-potassium dichromate titration method
MIAO Xiaohuan1,2
1. BGRIMM MTC Technology Co.,Ltd.,Beijing 102628,China; 2. Beijing Key Laboratory for Evaluation and Testing of Metallic Mineral Resources,Beijing 102628,China
Abstract:The matrix of copper smelting dust is complex, which contains high content elements such as copper, arsenic, antimony, carbon, sulfur and silicon, which could interfere with the determination of iron in sample by potassium dichromate titration. The sample was dissolved with ammonium fluoride, hydrochloric acid, nitric acid, sulfuric acid and perchloric acid. The interferences of arsenic and antimony were eliminated by hydrobromic acid. The excessive ammonia was added to form ferric hydroxide precipitate, realizing the separation from other elements such as copper and nickel. The precipitate was dissolved with hydrochloric acid, and the solution was reduced with stannous chloride to pale yellow. Thus, the determination of iron in copper smelting dust was realized by potassium dichromate titration method. The influence of some factors on the determination was discussed, including the method of sample dissolution, the duration of sulfuric acid smoke, and the interferences of arsenic or antimony, the dosage of ammonium chloride, the boiling time after adding ammonia and the type of filter paper. The optimized conditions are as follows: the duration of sulfuric acid smoke was 15-30 min after the sample was dissolved with mixed acid;When the content of arsenic in sample was higher than 1 mg or the content of antimony content was higher than 2 mg, 5 mL of hydrobromic acid should be added to eliminate their interference. The dosage of ammonium chloride was 3-4 g. The boiling time after adding ammonia was 1-2 min for complete precipitation. The precipitates were filtered with medium speed filter paper. Two copper smelting dust samples were selected for recovery tests, and the recoveries were between 99.00% and 101.37%. Four copper smelting dust samples were determined according to the proposed method, and the results were basically consistent with those obtained by inductively coupled plasma atomic emission spectrometry (ICP-AES). The relative standard deviations (RSD, n=11) were between 0.32% and 0.56%. The proposed method was applicable for the determination of iron in dusts during all stages of copper smelting process, and it was not affected by the difference of sample matrix.
[1] 张荣良,丘克强,谢永金,等.铜冶炼闪速炉烟尘氧化浸出与中和脱砷[J].中南大学学报(自然科学版),2006,37(1):73-78. ZHANG Rongliang,QIU Keqiang,XIE Yongjin,et al. Treatment process of dust from flash smelting furnace at copper smelter by oxidative leaching and dearsenifying process from leaching solution[J].Journal of Central South University(Science and Technology),2006,37(1):73-78. [2] 王玉芳,李相良,周起帆,等.铜冶炼烟尘处理技术综述[J].有色金属工程,2019,9(11):53-59. WANG Yufang, LI Xiangliang, ZHOU Qifan,et al. Review copper smelting flue dust treatment technology[J].Nonferrous Metals Engineering,2019,9(11):53-59. [3] González A,Font O,Moreno N,et al. Copper flash smelting flue dust as a source of germanium[J]. Waste and Biomass Valorization,2017(8):2121-2129. [4] 冉银华,张志明,郭强,等.某铜冶炼炉渣回收铜的选矿工艺试验[J].矿业研究与开发,2019,39(3):63-66. RAN Yinhua,ZHANG Zhiming,GUO Qiang, et al. Beneficiation test of copper recovery from a copper smelting slag[J].Mining Reseach and Development,2019,39(3):63-66. [5] 李艳萍,刘敏,张浩,等.火焰原子吸收光谱法测定铜冶炼烟尘中铋[J].中国无机分析化学,2019,9(5):67-71. LI Yanping, LIU Min, ZHANG Hao,et al. Determination of bismuth in copper smelting dust by flame atomic absorption spectrometry[J].Chinese Journal of Inorganic Analytical Chemistry,2019,9(5):67-71. [6] 胡花苗,陈娅陶,郑洪毅,等.Na2EDTA 滴定法测定铜冶炼烟尘中铋含量[J].中国无机分析化学,2019,9(5):42-48. HU Huamiao,CHEN Yatao,ZHENG Hongyi,et al. Determination of bismuth in copper smelting dust by Na2EDTA titration[J].Chinese Journal of Inorganic Analytical Chemistry,2019,9(5):42-48. [7] MONTENEGRO V,SANO H,FUJISAWA T. Recirculation of high aesenic content copper smelting dust to smelting and converting processes[J].Minerals Engineering,2013,49:184-189. [8] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.GB /T 6730.65-2009 铁矿石 全铁含量的测定 三氯化钛还原重铬酸钾滴定法(常规方法)[S].北京:中国标准出版社,2009. [9] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会GB/T 8151.3-2012 锌精矿化学分析方法 第3部分:铁量的测定 Na2EDTA滴定法[S].北京:中国标准出版社,2012. [10] 北京矿冶研究总院测试研究所.有色冶金分析手册[M].北京:冶金工业出版社,2004:228-229. [11] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.GB/T 6730.73-2016 铁矿石 全铁含量的测定 EDTA光度滴定法[S]. 北京:中国标准出版社.2016. [12] 赵乐,李叶静,房宏伟.基于两种不同分光光度法测定石灰石中三氧化二铁含量的比较[J].广东化工,2020,47(5):183-184. ZHAO Le,LI Yejing,FANG Hongwei. Comparison of detecting for Fe2O3 in limestone based on two different spectrophotometry[J].Guangdong Chemical Industry,2020,47(5):183-184. [13] 张晨.电感耦合等离子体原子发射光谱(ICP-AES)法测定铜冶炼烟尘中锌[J].中国无机分析化学,2021,10(4):56-58. ZHANG Chen. Determination of znin copper smelting dust by ICP-AES[J].Chinese Journal of Inorganic Analtyical Chemistry,2021,10(4):56-58. [14] 王铭.重铬酸钾滴定法测定高硅铁矿石中的铁[J].云南冶金,2017,46(5):66-68. WANG Ming.Determination of iron in iron ore with high-silicon content by dichromate titration[J].YunNan Metallurgy,2017,46(5):66-68. [15] 张霞,马超,李美慧,等.重铬酸钾滴定法测定钼铁中铁[J].冶金分析,2022,42(9):82-89. ZHANG Xia,MA Chao,LI Meihui,et al.Determination of Iron in ferromolybdenum by potassium dichromate titration[J].Metallurgical Analysis,2022,42(9):82-89. [16] 刘映平.三氯化钛-次甲基蓝-硫酸铈容量法测定铅锑精矿中铁的含量[J].化工技术与开发,2016,45(6):49-51. LIU Yingping.Determination of iron in lead antimony concentrate by titanium trichloride-methylene blue-cerium sulate volumetric method[J].Technology & Development of Chemical Industry,2016,45(6):49-51.
