Abstract:Fixed carbon content was not only an industrial index for graphite ore, but also an important factor to evaluate the grade reserves of graphite ore. Fixed carbon was the residual carbon after removing inorganic carbon and organic carbon. The inorganic carbon was removed by adding nitric acid(2+8) in the beaker followed by boiling at low temperature, and the organic carbon was removed by burning and ashing. The determination of fixed carbon in graphite ore was realized by high frequency combustion infrared absorption with metallic tungsten and pure iron as the flux. The effect of crucible treatment method, nitric acid concentration, ashing temperature, ashing time and the mass ratio of tungsten to pure iron on the determination were discussed. The results showed that the blank of crucible was less than 0.003% after burning in muffle furnace at 1 050 ℃ for 2 h, and its influence on the determination results could be ignored. The inorganic carbon in sample could be effectively removed after treatment with nitric acid(2+8). The organic carbon in sample could be effectively removed by burning at 450 ℃ for 3 h. After optimization, the mass ratio of metallic tungsten to pure iron in flux was 1.7∶0.3. Under the optimized conditions, the limit of detection was 0.000 80%, and the limit of quantification was 0.002 67%. The content of fixed carbon in graphite ore certified reference material for composition analysis was determined according to the experimental method. The results were basically consistent with the standard values. The relative standard deviations (RSDs, n=6) were between 1.2% and 3.5%. Six graphite ore samples with different content gradient were determined according to the experimental method, and the RSDs were between 2.1% and 9.2%. Meanwhile, the samples were also determined by non-aqueous titration method in standard method of GB/T 3521-2008. The relative errors of two methods were less than the allowable limits of relative errors specified in The specification of testing quality management for geological laboratories.
王斌, 李霈, 刘巍平. 高频燃烧红外吸收法测定石墨矿中固定碳[J]. 冶金分析, 2021, 41(3): 51-55.
WANG Bin, LI Pei, LIU Weiping. Determination of fixed carbon in graphite ore by high frequency combustion infrared absorption method. , 2021, 41(3): 51-55.
刘丹丹.石墨的应用及其发展前景[J].黑龙江冶金.2016,36(1):56-57.LIU Dandan.Application and development prospect of graphite[J].Heilongjiang Metallurgy, 2016, 36(1):56-57.
[2]
焦丽香,高树学,郭加朋,等.我国石墨资源开发利用现状分析[J].中国非金属矿业工业导刊,2019(增1):1-6.JIAO Lixiang,GAO Shuxue,GUO Jiapeng,et al.Analysis on the current situation of graphite resources development and utilization in China[J]. China Nonmetallic Minerals Industry, 2019(Supplement 1):1-6.
代建强,姚永生,张亚增.重铬酸钾氧化-非水滴定法测定石墨矿中固定碳[J].冶金分析,2015,35(12):23-27.DAI Jianqiang,YAO Yongsheng,ZHANG Yazeng.Determination of fixed carbon in graphite ore by potassium dichromate oxidation-nonaqueous titration[J].Metallurgical Analysis,2015,35(12):23-27.
[6]
陈建帮.含碳酸盐石墨矿中固定碳含量测定方法的改进[J].中国非金属矿工业导刊,2013(6):30-31.CHEN Jianbang.Improved method for the determination of carbon content in graphite ore containing carbonate[J].China Nonmetallic Minerals Industry,2013(6):30-31.
[7]
刘攀,唐伟,张斌彬,等.高频感应燃烧-红外吸收光谱法在分析金属材料中碳、硫的应用[J].理化检验(化学分册),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.
[8]
王慧,李万国.红外碳硫分析仪测定硅铁中碳硫[J].理化检验(化学分册),2003,39(8):485,487.WANG Hui,LI Wanguo.Determine the carbon and sulfur in ferrosilicon by the infrared carbon and sulfur analyzer[J].Physical Testing and Chemical Analysis (Part: B Chemical Analysis),2003,39(8):485,487.
[9]
郑伟,梁清华,魏宏楠,等.高频燃烧红外吸收光谱法测定铪合金中碳[J].中国无机分析化学,2019,9(3):45-47.ZHENG Wei,LIANG Qinghua,WEI Hongnan,et al.Determination of carbon in hafnium alloy by high-frequency combustion infrared absorption spectrometry[J]. Chinese Journal of Inorganic Analytical,2019,9(3):45-47.
[10]
范福男,王春福.大理岩型石墨矿中固定碳的测定方法[J].岩矿测试,1996,18(2):135-138.FAN Funan,WANG Chunfu.Method for determination of fixed carbon in marble graphite mines[J].Rock and Mineral Analysis,1996,18(2):135-138.
[11]
欧阳泉根,李晓燕,白静梅,等.盐酸预处理-高频燃烧红外吸收法测定含铀岩石中有机碳[J].冶金分析,2020,40(2):18-23.OUYANG Quangen,LI Xiaoyan,BAI Jingmei,et al.Determination of organic carbon in uranium-bearing rock by high frequency combustion infrared absorption with hydrochloric aced pretreatment[J].Metallurgical Analysis,2020,40(2):18-23.
[12]
宋志敏,赵俊宏,赵亚男,等.稀硝酸处理-高频红外碳硫仪法测定石墨矿中固定碳研究[J].河南科学,2018,36(8):1205-1209.SONG Zhimin,ZHAO Junhong,ZHAO Yannan,et al.Determination of fixed carbon on graphite ores with the treatment of dilute nitrate by using high frequency IR-absorption spectrometry[J]. Hennan Science,2018,36(8):1205-1209.
[13]
张宏丽,高小飞,王盘喜,等.高频燃烧-红外吸收光谱法测定槽探样品中固定碳的含量[J].理化检验(化学分册),2017,53(10):1188-1191.ZHANG Hongli,GAO Xiaofei,WANG Panxi,et al.Determination of fixed carbon in trenching samples by high frequency combustion-infrared absorption spectrometry[J]. Physical Testing and Chemical Analysis (Part B: Chemical Analysis),2017,53(10):1188-1191.
[14]
杨艳明,李美玉,赵毅华.高频燃烧-红外吸收法测定石墨中的固定碳含量[J].分析测试技术与仪器,2018,24(1):52-56.YANG Yanming,LI Meiyu,ZHAO Yihua.Determination of fixed carbon content in graphite by high frequency combustion-infrared absorption method[J].Analysis and Testing Technology and Instrument,2018,24(1):52-56.
[15]
巩海娟,赵淑洁,王岚,等.高频红外碳硫分析仪测定石墨样品中固定碳研究[J].世界地质,2012,31(3):603-607.GONG Haijuan,ZHAO Shujie,WANG Lan,et al.Research on determination of fixed carbon in graphite sample using high frequency IR-absorption spectrometry[J]. Global Geology,31(3):603-607.
[16]
邹芳.高频红外法测定碳酸盐型石墨矿中固定碳的研究[J].矿物岩石,2014,34(3):14-18.ZUO Fang.Determination of fixed carbon in carbonate type graphite mines[J].Journal of Mineralogy and Petrology,2014,34(3):14-18.
