熔融制样-X射线荧光光谱法测定高碳铬铁中铬铁硅锰

doi:10.13228/j.boyuan.issn1000-7571.012273

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摘要为解决高温熔融时铬铁试样中还原性物质对铂-金坩埚的侵蚀问题,实验确定在600～850 ℃条件下,以经碳烧失校正的试样、铬系合金专用氧化剂、无水偏硼酸锂混匀后,在石墨粉垫底陶瓷坩埚内程序升温氧化高碳铬铁试样,氧化后用六偏磷酸钠和无水偏硼酸锂作为熔剂,滴加1～3 mL 300 g/L溴化铵溶液作为脱模剂,在1 050 ℃电热熔样炉中熔融20 min,制得玻璃样片,采用X射线荧光光谱法对玻璃样片进行测定。最终,建立了高碳铬铁中铬、铁、硅、锰含量的测定方法。硅和锰检测下限分别为44.51 μg/g和22.62 μg/g。精密度试验表明,高碳铬铁试样中铬、铁、硅、锰测定结果的相对标准偏差(RSD,n=12)分别为0.44%、0.51%、2.1%、4.8%;正确度试验表明,高碳铬铁合金标准样品中铬、铁、硅、锰的测定值与标准值间的误差,分别控制在GB/T 4699.2—2008、GB/T 5687.13—2021、GB/T 5687.2—2007和GB/T 5687.10—2006规定的允许差范围内。按照实验技术方案测定高碳铬铁中铬、铁、硅、锰含量,能够满足高碳铬铁试样的常规检测需求。

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	滕广清
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关键词 ：熔融制样, X射线荧光光谱法(XRF), 高碳铬铁, 铬, 铁, 硅, 锰, 陶瓷坩埚, 预氧化, 石墨粉

Abstract：In order to solve the corrosion problem of platinum crucible by the reducing substances in ferrochrome sample during high temperature fusion, the following experiment conditions were adopted: under the temperature of 600-850 ℃, the sample with carbon loss correction, the special oxidizing agent for chromium alloy and anhydrous lithium metaborate were mixed, and the high-carbon ferrochrome sample was oxidized in the ceramic crucible with graphite powder as the base by temperature programming; after oxidation, sodium hexametaphosphate and anhydrous lithium metaborate were used as the flux, and 1-3 mL of 300 g/L ammonium bromide solution were added as the release agent; the mixture was melted in electric melting furnace at 1 050 ℃ for 20 min to prepare the glass pellet, which was then determined by X-ray fluorescence spectrometry. Consequently, a determination method of chromium, iron, silicon and manganese in high-carbon ferrochrome was established. The lower limits of determination for silicon and manganese were 44.51 μg/g and 22.62 μg/g, respectively. The precision tests showed that the relative standard deviations (RSD, n=12) of determination results for chromium, iron, silicon and manganese were 0.44%, 0.51%, 2.1% and 4.8%, respectively. The trueness tests showed that the errors between the measured values of chromium, iron, silicon and manganese in certified reference materials of high carbon ferrochrome and the standard values could be controlled within the allowable deviation ranges specified in GB/T 4699.2-2008, GB/T 5687.13-2021, GB/T 5687.2-2007 and GB/T 5687.10-2006, respectively. According to the proposed technical scheme, the determination results of chromium, iron, silicon, and manganese in high carbon ferrochrome could meet the routine detection requirements of high-carbon ferrochrome samples.

Key words： fusion sample preparation X-ray fluorescence spectrometry(XRF) high-carbon ferrochrome chromium iron silicon manganese ceramic crucible pre-oxidation graphite powder

收稿日期: 2023-07-17

ZTFLH:	O657.34
	TF03+1

通讯作者: 鲍希波(1974—),男,正高级工程师,大学本科,研究方向为X射线荧光光谱分析和实验室管理;E-mail:baoxibo@hbisco.com

作者简介: 滕广清(1975—),男,高级工程师,大学本科,研究方向为钢铁冶金实验室光谱分析和实验室管理;E-mail:tengguangqing@hbisco.com

引用本文:

滕广清, 侯钢铁, 张改梅, 鲍希波. 熔融制样-X射线荧光光谱法测定高碳铬铁中铬铁硅锰[J]. 冶金分析, 2024, 44(3): 23-29. TENG Guangqing, HOU Gangtie, ZHANG Gaimei, BAO Xibo. Determination of chromium,iron,silicon and manganese in high-carbon ferrochrome by X-ray fluorescence spectrometry with fusion sample preparation. , 2024, 44(3): 23-29.

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http://yjfx.chinamet.cn/CN/10.13228/j.boyuan.issn1000-7571.012273 或 http://yjfx.chinamet.cn/CN/Y2024/V44/I3/23

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