钢中特征区域在不同设备间的重现观察

doi:10.13228/j.boyuan.issn1000-7571.011022

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摘要利用多台检测设备对钢中同一特征区域进行表征时,不同设备间的样品台兼容性问题会对特征区域的重现观察及测试造成影响。实验通过设备间的坐标转换和程序界面化显示,以钢中夹杂物作为特征区域,展示了在光学显微镜(OM)和扫描电镜(SEM)、扫描电镜和纳米压痕仪等设备间的重现观察及测试技术。结果显示,钢水样中3类夹杂物的纳米硬度分别为:Al₂O₃类夹杂物0.14GPa,Si-Ca-O类夹杂物8.83GPa,Si-O类夹杂物8.01GPa。同时,根据不同放大倍数下的最大允许偏移量和特征点坐标偏差的算术平均值,评价了这种重现观察技术的定位误差限:坐标偏差x方向小于33μm,y方向小于55μm。在设备转换时,特征区域定位速度快,位置精度高,且与样品台的移动能力相匹配,说明方法具有较好的实用性和设备通用性。

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	张珂
	金传伟
	吴园园

关键词 ：特征区域, 重现观察, 纳米硬度, 坐标转换, 坐标偏差

Abstract：During the characterization of same characteristic region in steel using different devices, the problem of sample stage compatibility between different equipment will have influence on the recurring observation and testing. Through the coordinate transformation between devices and program interface display, the inclusions in steel were taken as the characteristic region, and the recurring observation and testing among different devices, including optical microscope (OM) and scanning electron microscope (SEM), SEM and nanoindenter, were demonstrated. The results indicated that the nano-indentation hardness of three types of inclusions in molten steel sample was as below: 0.14GPa, 8.83GPa and 8.01GPa for Al₂O₃ type, Si-Ca-O type and Si-O type, respectively. Meanwhile, based on the maximum allowable offsets at different magnifications and the arithmetic mean of coordinate deviation of characteristic point, the positioning error limit of this recurring observation technique was evaluated: the coordinate deviation was less than 33μm in the x direction and less than 55μm in the y direction. The positioning speed of characteristic region was fast and the position accuracy was high during equipment replacement. Moreover, it well matched with the moving ability of sample stage in equipment, which showed that the proposed method had good practicability and equipment versatility.

Key words： characteristic region recurring observation nano-indentation hardness coordinate transformation coordinate deviation

收稿日期: 2020-02-13

ZTFLH:	TG115.21
	TG115.5+1

作者简介: 张珂(1982—),男,高级工程师,博士,从事钢铁冶金分析工作;E-mail:zhangke823@163.com

引用本文:

张珂, 金传伟, 吴园园. 钢中特征区域在不同设备间的重现观察[J]. 冶金分析, 2020, 40(9): 18-23. ZHANG Ke, JIN Chuan-wei, WU Yuan-yuan. Recurring observation of characteristic region in steel among different devices. , 2020, 40(9): 18-23.

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http://yjfx.chinamet.cn/CN/10.13228/j.boyuan.issn1000-7571.011022 或 http://yjfx.chinamet.cn/CN/Y2020/V40/I9/18

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