Application of high frequency combustion infrared absorption method for analysis standard of carbon and sulfur in inorganic solid material
ZENG Lei1, CHEN Qianqian1, LIU Pan*1, 2, LI Bin1, ZHANG Yi1, ZHANG Xinyao1, 3
1. Luoyang Ship Material Research Institute, Luoyang 471023, China; 2. Xiamen Sunrui Material Research Institute Co., Ltd., Xiamen 361100, China; 3. Henan Key Laboratory of Technology and Application of Structural Materials for Ship and Marine Equipment, Luoyang 471023, China
Abstract:Carbon and sulfur are the routine detection items in inorganic solid materials. High frequency combustion infrared absorption method has been recommended as the standard method for analysis of carbon and sulfur in various inorganic solid materials due to its advantages such as fast and accurate. The application status of high frequency combustion infrared absorption method for analysis of carbon and sulfur in inorganic solid materials such as iron and steel, nickel alloys, ferroalloys, metallurgical additives, nonferrous metal alloys, geological rock, metal ores, rare earth metals, nuclear materials, and inorganic non-metallic materials was reviewed, based on about 150 national standards, industrial standards, local standards or group standards. The main parameters of the above standards, such as the applicable objects, determination scope, adding amount and order of sample and fluxes, were listed. The adoption and development route of standards were introduced. Then some suggestions on simplification and integration were put forward. The application prospect and development direction of high frequency combustion infrared absorption method in the standardization for analysis of carbon and sulfur in new materials were prospected. It was expected to further strengthen the integration, revision and updating of standard methods and the research and development of standard samples, so as to improve the standard method system for carbon and sulfur analysis in inorganic solid materials.
曾磊, 陈倩倩, 刘攀, 李斌, 张毅, 张欣耀. 高频燃烧红外吸收法在无机固体材料碳/硫分析标准中的应用[J]. 冶金分析, 2023, 43(5): 32-45.
ZENG Lei, CHEN Qianqian, LIU Pan, LI Bin, ZHANG Yi, ZHANG Xinyao. Application of high frequency combustion infrared absorption method for analysis standard of carbon and sulfur in inorganic solid material. , 2023, 43(5): 32-45.
[1] 张光.金属材料中碳硫分析技术的现状与进展[J].材料开发与应用,1994,9(2):46-49. ZHANG Guang.Status and development of carbon and sulfur analysis technology in metallic materials[J].Development and Application of Materials,1994,9(2):46-49. [2] 刘攀,唐伟,张斌彬,等.高频感应燃烧-红外吸收法在分析金属材料中碳、硫的应用[J].理化检验(化学分册),2016,52(1):109-118. LIU Pan,TANG Wei,ZHANG Binbin,et al.Application of high frequency induction combustion-infrared absorption spectroscopy for analysis of carbon or sulfur in metal materials[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2016,52(1):109-118. [3] 刘攀,唐伟,张斌彬,等.高频感应燃烧-红外吸收光谱法在分析无机非金属样品中碳、硫的应用[J].理化检验(化学分册),2016,52(4):487-496. LIU Pan,TANG Wei,ZHANG Binbin,et al.Application of high frequency induction combustion-infrared absorption spectrometry to the determination of carbon or sulfur in inorganic non-metal samples[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2016,52(4):487-496. [4] 刘攀,杜米芳,唐伟,等.无机固体样品中硫的测定方法的研究进展[J].理化检验(化学分册),2017,53(8):984-992. LIU Pan,DU Mifang,TANG Wei,et al.Recent advances of researches on determination methods for sulfur in inorganic solid samples[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2017,53(8):984-992. [5] 刘攀,杜米芳,唐伟,等.无机固体样品中碳的分析方法综述[J].分析仪器,2018(4):8-15. LIU Pan,DU Mifang,TANG Wei,et al.Review of methods for analysis of carbon in inorganic solid samples[J].Analytical Instrumentation,2018(4):8-15. [6] 刘瑞,李会影.红外吸收法在钒中碳分析中的应用研究[J].材料开发与应用,2017,32(4):50-54. LIU Rui,LI Huiying.Study on the application of infrared absorption method in carbon analysis of vanadium[J].Development and Application of Materials,2017,32(4):50-54. [7] 刘攀,唐伟.高频感应燃烧红外吸收法测定焊接药剂中硫含量[J].冶金分析,2017,37(11):64-68. LIU Pan,TANG Wei.Determination of sulfur in welding flux by high frequency induction combustion infrared absorption method[J].Metallurgical Analysis,2017,37(11):64-68. [8] 常国梁,刘攀,张毅.高频感应燃烧-红外吸收光谱法测定蒙乃尔镍铜合金中碳[J].冶金分析,2020,40(7):16-21. CHANG Guoliang,LIU Pan,ZHANG Yi.Determination of carbon in Monel Ni-Cu alloy by high frequency combustion infrared absorption spectroscopy method[J].Metallurgical Analysis,2020,40(7):16-21. [9] 刘攀,张毅,常国梁,等.高频感应燃烧红外吸收法测定铁硅硼非晶合金薄带中碳[J].冶金分析,2020,40(9):24-30. LIU Pan,ZHANG Yi,CHANG Guoliang,et al.Determination of carbon in iron-silicon-boron amorphous alloy strip by high frequency combustion infrared absorption method[J].Metallurgical Analysis,2020,40(9):24-30. [10] 李擎.燃烧-气体容量法测定WC-Ni-Al粉末中总碳含量的研究[J].硬质合金,2017,34(4):281-285. LI Qing.Determination of total carbon content in WC-Ni-Al powder by combustion gas volumetric method[J].Cemented Carbide,2017,34(4):281-285. [11] 王丽,段心翠,苏佳新.燃烧中和滴定法测定铁矿石中高含量硫[J].冶金分析,2002,22(6):68-69. WANG Li,DUAN Xincui,SU Jiaxin.Determination of high content of sulfur in iron ores by combustion-neutralizing titrimetry[J].Metallurgical Analysis,2002,22(6):68-69. [12] 董秀珍.提高库仑滴定法测定全硫准确度的方法[J].选煤技术,2014(2):56-60,64. DONG Xiuzhen.The way of increasing the measuring accuracy of total sulfur of coulometric method[J].Goal Preparation Technology,2014(2):56-60,64. [13] 马一嘉,罗冰虹,谭凯馨.高温燃烧碘量法测定土壤中总硫含量的方法优化[J].中国无机分析化学,2018,8(6):25-28. MA Yijia,LUO Binghong,TAN Kaixin.Optimization of method for determination of total sulfur in soil by high temperature combustion iodine method[J].Chinese Journal of Inorganic Analytical Chemistry,2018,8(6):25-28. [14] 王敏娟,赵婷,陶冶,等.管式炉燃烧-硫酸钡比浊法测定硼铁中低硫[J].冶金分析,2002,22(1):9-10,23. WANG Minjuan,ZHAO Ting,TAO Ye,et al.Determination of low sulfur in ferro-boron by tube-furnace combustion-barium sulfate turbidimetry[J].Metallurgical Analysis,2002,22(1):9-10,23. [15] 张红,任旭东,郝茜.硫化钐中硫和钐的分离与测定[J].冶金分析,2016,36(1):57-61. ZHANG Hong,REN Xudong,HAO Qian.Separation and determination of sulfur and samarium in samarium sulfide[J].Metallurgical Analysis,2016,36(1):57-61. [16] 兰宇卫,陆建平,章张法,等.微波消解-吸附柱分离-离子色谱法测定钢样中微量硫[J].冶金分析,2008,28(1):24-26. LAN Yuwei,LU Jianping,ZHANG Zhangfa,et al.Ion chromatographic determination of trace sulfur in steel with microwave digestion and adsorption column separation[J].Metallurgical Analysis,2008,28(1):24-26. [17] 唐华应,方艳,刘惠丽.电感耦合等离子体原子发射光谱法测定钒铁中硫含量[J].冶金分析,2013,33(9):70-72. TANG Huaying,FANG Yan,LIU Huili.Determination of sulfur in ferrovanadium by inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2013,33(9):70-72. [18] 汪雨,任敏,陈舜琮.高分辨连续光源原子吸收光谱法测定煤中硫[J].冶金分析,2011,31(8):12-16. WANG Yu,REN Min,CHEN Shunzong.Determination of sulphur in coal by high resolution atomic absorption spectrometry with continuum light source[J].Metallurgical Analysis,2011,31(8):12-16. [19] 张征宇,芦飞,赵卫星.火花放电原子发射光谱法测定奥氏体易切削不锈钢中高含量硫[J].冶金分析,2022,42(1):43-49. ZHANG Zhengyu,LU Fei,ZHAO Weixing.Determination of high content sulfur in austenitic free-cutting stainless steel by spark discharge atomic emission spectrometry[J].Metallurgical Analysis,2022,42(1):43-49. [20] 刘洁,葛晶晶,孙中华.辉光放电光谱法测定因瓦合金中14种元素[J].冶金分析,2016,36(12):8-12. LIU Jie,GE Jingjing,SUN Zhonghua.Determination of fourteen elements in invar alloy by glow discharge optical emission spectrometry[J].Metallurgical Analysis,2016,36(12):8-12. [21] 刘佳,沈学静,张关震,等.激光诱导击穿光谱技术对火车车轮钢中成分的原位统计分布分析表征[J].光谱学与光谱分析,2021,41(7):2269-2274. LIU Jia,SHEN Xuejing,ZHANG Guanzhen,et al.Characterization of original position statistical distribution of composition in train wheel steel by laser-induced breakdown spectrum[J].Spectroscopy and Spectral Analysis,2021,41(7):2269-2274. [22] 沈非,杨培全,李家骥,等.X射线荧光光谱法测定钢铁材料中硫、磷含量[J].理化检验(化学分册),2014,50(1):126-127. SHEN Fei,YANG Peiquan,LI Jiaji,et al.Determination of sulfur and phosphorus in steel materials by X-ray fluorescence spectrometry[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2014,50(1):126-127. [23] 刘芬,赵志娟,赵良仲.大气颗粒沉积物的X射线光电子能谱分析[J].环境科学与工程(英文版),2008,2(4):1-4. LIU Fen,ZHAO Zhijuan,ZHAO Liangzhong.X-ray photoelectron spectroscopy analysis of deposited air particles[J].Journal of Environmental Science and Engineering,2008,2(4):1-4.
