Abstract:The analytical method of gaseous elements in metal has already existed for more than 6 years. The detection methods are different from those for other chemical elements. Five typical cases (hydrogen in aluminum, argon in metal, helium in metal, hydrogen in rare earth steel, and oxygen in aluminum or magnesium) were listed for technical exchange and discussion. Among the analysis of gases in metals, the analysis of hydrogen in aluminum is the most difficult. Some researchers tried to simplify the analysis method of hydrogen in aluminum. It was expected to obtain the results rapidly and accurately like that in steel. For example, the commonly used impulse fusion method was tested a hundred times, but it was not successful. Then high frequency (or tubular furnace) heating extraction was adopted, which made the testing of hydrogen in aluminum simple like that of hydrogen in steel. With the aid of legal argon co-detector by impulse mass spectrometry, the reliable analysis method of argon in metal was established. The proposed method has been used for more than ten years. For the determination of helium in metal, the fast interface attachment were usually self-developed and the testing was conducted in the existing hydrogen determinator. The phenomenon of "zero peak value" occurred in the analysis of hydrogen in rare earth steel. The peak of hydrogen was not observed in three instruments from three domestic senior departments. Theoretically, it was due to the influence of rare earths. The fusion method and extraction method were compared to provide the evidence that the analysis of hydrogen in steel was interfered by rare earths. The sample was not melted in thermal extraction method, thus reducing the interference of rare earth pollution to the minimum level, and the peak of hydrogen in rare earth steel could be obtained. The chemical activity of magnesium was strong. During the determination of oxygen in magnesium by impulse fusion method, the interference of volatile pollution was very serious. Some researchers tried to use such instrument for the analysis of oxygen content in magnesium, and the domestic export data were finally consistent with the foreign entry data. Then the difficulty for oxygen detection in magnesium was solved by employing exclusive instrument with special technical scheme.
朱跃进, 朱瑛才. 金属中气体元素分析典型案例[J]. 冶金分析, 2022, 42(1): 1-9.
ZHU Yuejin, ZHU Yingcai. Typical case study on analysis of gaseous element in metal. , 2022, 42(1): 1-9.
[1] 杨维琛,李捷报,张素荣,等.无汞真空套管色谱法测定固态铝及铝合金中的氢[J].轻金属(Light Metals),1984(11):40-45. [2] 陈文绣,陈文,李素娟.氮载气熔融法测定铝锂合金中氢[J].冶金分析,1994,14(2):6-8. CHEN Wenxiu,CHEN Wen,LI Sujuan.Determination of hydrogen in Al-Li alloy by nitrogen carrier gas fusion method[J].Metallurgical Analysis,1994,14(2):6-8. [3] 国家市场监督管理总局,中国国家标准化管理委员会.GB/T 20957.30—2018铝及铝合金化学分析方法 第30部分 氢含量的测定 加热提取热导法[S].北京:中国标准出版社,2018. [4] 朱跃进,李素娟,高鹏.脉冲热导法测定铝中氢的探讨[J].冶金分析,2016,36(12):18-25. ZHU Yuejin,LI Sujuan,GAO Peng.Discussion on determination of hydrogen in aluminium by impulse heating thermal conductivity[J].Metallurgical Analysis,2016,36(12):18-25. [5] 谢君,朱瑛才,仉凤江,等.坩埚对高温合金中氧氮及氢分析结果的影响[J].冶金分析,2018,38(10):7-15. XIE Jun,ZHU Yingcai,ZHANG Fengjiang,et al.Influence of crucible on analysis results of oxygen, nitrogen and hydrogen in superalloy[J].Metallurgical Analysis,2018,38(10):7-15. [6] 谢君,张琳,朱瑛才,等.金属中超低氢的分析研究[J].冶金分析,2021,45(1):1-8. XIE Jun,ZHANG Lin,ZHU Yingcai.Research on analysis of ultralow content hydrogen in metals[J].Metallurgical Analysis,2021,45(1):1-8. [7] 朱跃进,王强,耿小颖.脉冲热导法测定金属中氩[C]//2008年国际冶金及材料分析测试学术报告会论文集.北京:出版者不详,2008:1041-1043. [8] 朱跃进,胡少成.脉冲熔融-飞行时间质谱法测定钛中氦和氩[J].冶金分析,2013,33(10):16-20. ZHU Yuejin,HU Shaocheng.Determination of helium and argon in titanium by pulse heating-time of flight mass spectrometry[J].Metallurgical Analysis,2013,33(10):16-20. [9] 朱跃进,徐磊,吴杰,等.钛基合金中氩的分析探讨及应用[J].冶金分析,2015,35(3):13-18. ZHU Yuejin,XU Lei,WU Jie,et al.Discussion on the determination and application of argon in titanium-based alloy[J].Metallurgical Analysis,2015,35(3):13-18. [10] 朱跃进.脉冲热导法测定金属中氦[C]//2008年国际冶金及材料分析测试学术报告会论文集.北京:出版者不详,2004:348-350. [11] 国家市场监督管理总局,中国国家标准化管理委员会.GB/T 223.82—2018钢铁 氢含量的测定 惰性气体熔融-热导或红外法[S].北京:中国标准出版社,2019. [12] 朱跃进,李素娟,邓羽,等.应用脉冲熔融法和感应热抽取法探讨钢中超低氢分析“零峰值”问题[J].冶金分析,2017,37(6):1-8. ZHU Yuejin,LI Sujuan,DENG Yu,et al.Discussion on “zero peak” problem of ultralow hydrogen analysis in steel by impulse-heating fusion and induction-heating hot extraction[J].Metallurgical Analysis,2017,37(6):1-8. [13] 朱跃进,李素娟,陈文绣.铝中氧的测定[J].冶金分析,1995,15(5):55-56. ZHU Yuejin,LI Sujuan,CHEN Wenxiu.Determination of oxygen in aluminium[J].Metallurgical Analysis,1995,15(5):55-56. [14] 朱跃进,李素娟.脉冲红外法测定镁中氧[J].分析试验室,2000,19(增刊):30-31. ZHU Yuejin,LI Sujuan.Determination of oxygen in magnesium by impulse heating-infrared absorption[J].Chinese Journal of Analysis Laboratory,2000,19(Sup.):30-31. [15] 朱跃进,李素娟.惰气熔融法测定镁中氧、氢、氮[J].冶金分析,2011,31(12):58-61. ZHU Yuejin,LI Sujuan.Determination of oxygen,hydrogen and nitrogen in magnesium by inert gas fusion method[J].Metallurgical Analysis,2011,31(12):58-61.
