目的 探究Mo元素对高铬铸铁药芯焊丝堆焊层组织及性能的影响。方法 采用CMT电弧堆焊工艺分别制备了含Mo元素与不含Mo元素的Cr27高铬铸铁堆焊试样。通过渗透检测、SEM、EBSD和销盘磨损实验等方法,研究了Mo元素的添加对堆焊层宏观形貌、显微组织和耐磨性能的影响规律。结果 Mo元素的添加导致堆焊过程中飞溅显著增加,并诱发横向裂纹形成。2种堆焊层均主要由(Fe, Cr)7C3共晶碳化物与奥氏体基体组成,但Mo元素的添加显著细化了堆焊层奥氏体晶粒,并提高了M7C3碳化物的体积分数。与不含Mo元素堆焊层相比,添加Mo元素堆焊层奥氏体晶粒细化约38.6%,堆焊层平均硬度从690HV提高至740HV,提升约7%,堆焊层平均摩擦系数由0.645降至0.395,磨损量降低约50%,耐磨损性能显著提升。结论 Mo元素在凝固过程中先析出了高熔点的Mo2C,作为异质形核核心提高了奥氏体的形核率,并且在凝固后期Mo2C还可以钉扎晶界,阻止奥氏体长大,从而细化奥氏体晶粒。此外,Mo元素的添加还会降低C元素在奥氏体中的固溶度,使更多C元素参与共晶反应,从而提高M7C3碳化物含量。碳化物含量的增加和晶粒细化使堆焊层硬度提高。2种堆焊层的磨损形式均以黏着磨损与磨粒磨损为主,但Mo元素的添加显著降低了摩擦系数与磨损失重,提高了耐磨性。
Abstract
To investigate the effect of Mo element on the microstructure and properties of the high chromium cast iron flux-cored wire hardfacing layer, the work aims to conduct a series of experimental researches and analyses. In the experimental method, Cr27 high chromium cast iron hardfacing specimens with and without Mo element were prepared respectively under the cold metal transfer (CMT) arc hardfacing process. To systematically explore the effect of Mo addition on the hardfacing layer, multiple characterization and testing methods were employed. Penetrant testing (PT) was used to detect the macroscopic defects of the hardfacing layer, scanning electron microscopy (SEM) was applied to observe the macro morphology and microstructure of the hardfacing layer, electron backscatter diffraction (EBSD) was adopted to analyze the grain size and distribution of the microstructure and the pin-on-disk wear test was carried out to evaluate the wear resistance of the hardfacing layer. Through the combination of these methods, the effect law of Mo element on the macro morphology, microstructure and wear resistance of the hardfacing layer was comprehensively studied. The experimental results showed that the addition of Mo element had obvious effects on the hardfacing process and the performance of the hardfacing layer. During the hardfacing process, the addition of Mo significantly increased the spatter and induced the formation of transverse cracks in the hardfacing layer. Microstructurally, both the Mo-containing and Mo-free hardfacing layers were mainly composed of (Fe, Cr)7C3 eutectic carbides and an austenite matrix. However, the addition of Mo brought significant microstructural changes: it notably refined the austenite grains of the hardfacing layer and increased the volume fraction of M7C3 carbides. Specifically, compared with the Mo-free hardfacing layer, the austenite grain size of the Mo-added hardfacing layer was refined by approximately 38.6%. In terms of mechanical properties, the average hardness of the Mo-added hardfacing layer increased from 690HV (of the Mo-free one) to 740HV, with an improvement of about 7%. In the wear resistance test, the average friction coefficient of the Mo-added hardfacing layer decreased from 0.645 (of the Mo-free one) to 0.395, and the wear mass loss was reduced by approximately 50%, indicating a significant improvement in wear resistance. The conclusion of this work is as follows: during the solidification process of the hardfacing layer, Mo element first precipitates Mo2C with a high melting point. This Mo2C acts as a heterogeneous nucleation core, which effectively increases the nucleation rate of austenite. In the later stage of solidification, Mo2C can also pin the grain boundaries, inhibiting the growth of austenite grains, thereby achieving the refinement of austenite grains. In addition, the addition of Mo element can reduce the solid solubility of C element in austenite, which promotes more C element to participate in the eutectic reaction, ultimately increasing the content of M7C3 carbides. The increase in carbide content and the refinement of grains together contribute to the improvement of the hardfacing layer's hardness. Regarding the wear mechanism, both the Mo-containing and Mo-free hardfacing layers are mainly dominated by adhesive wear and abrasive wear. However, the addition of Mo element significantly reduces the friction coefficient and wear mass loss of the hardfacing layer, thereby effectively enhancing its wear resistance.
关键词
Mo元素 /
高铬铸铁 /
晶粒细化 /
M7C3碳化物 /
磨损 /
CMT堆焊
Key words
Mo element /
high chromium cast iron /
grain refinement /
M7C3 carbide /
wear /
CMT hardfacing
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基金
广东省市场监督管理局科技项目(2025CT12)
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