M. Olivares-Luna, I. Mejía-Caballero, U. Figueroa-López, I. A. Carmona-Cervantes, L. E. Castillo-Vela, I. Campos-Silva
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引用次数: 0
摘要
评价了经调质后处理的渗硼和硼渗AISI 8620钢的层/基体系统的实际附着力的新结果。硬度(H)和杨氏模量(E)由仪器维氏微压痕测定。据此估算了残余应力(σr)和破坏弹性应变(H/E)。通过扫描电子显微镜(SEM)对整个实验装置进行了微观结构表征。最后,通过划痕测试评估实验集的实际附着力,使用从1到150 N的渐进载荷,以10 mm min-1,划痕长度为7 mm。结果表明:调质处理增加了层/基体系统的实际附着力,这是由于外层的FeB相在硼化物层上的溶解。此外,由于沿硼化物层和渗碳区的压残余应力深度增大,硼碳渗碳材料在实际粘接测试中表现出临界载荷的2倍左右的增加。与渗硼和渗硼+调质材料相比,渗硼+调质处理为AISI 8620钢提供了机械支撑,降低了层的脆性。
The Study of Practical Adhesion of a Layer/Substrate System on an AISI 8620 Steel Exposed to Boriding and Borocarburizing
Novel results about the practical adhesion of the layer/substrate system on borided and borocarburized AISI 8620 steels exposed to a quenching-tempering post-treatment were evaluated. The hardness (H) and Young modulus (E) were obtained by instrumented Vickers microindentation. Consequently, the residual stresses (σr) and elastic strain to failure (H/E) were estimated. The microstructural characterization of the entire experimental set was carried out by scanning electron microscopy (SEM). Finally, the practical adhesion of the experimental set was evaluated with a scratch test, using a progressive load from 1 to 150 N at 10 mm min–1, with a scratch length of 7 mm. The results indicated that the quenching-tempering treatment increased the practical adhesion of the layer/substrate system, due to the dissolution of the outer FeB phase on the boride layer. Furthermore, the borocarburized material showed an increase around 2 times of the critical load during the practical adhesion test, attributed to a greater depth of the compressive residual stresses along the boride layer and the carburized zone. The borocarburizing + quenching-tempering treatment provided a mechanical support to the AISI 8620 steel, reducing the brittleness of the layer, in comparison with the borided and borided plus quenching-tempering material.
期刊介绍:
Protection of Metals and Physical Chemistry of Surfaces is an international peer reviewed journal that publishes articles covering all aspects of the physical chemistry of materials and interfaces in various environments. The journal covers all related problems of modern physical chemistry and materials science, including: physicochemical processes at interfaces; adsorption phenomena; complexing from molecular and supramolecular structures at the interfaces to new substances, materials and coatings; nanoscale and nanostructured materials and coatings, composed and dispersed materials; physicochemical problems of corrosion, degradation and protection; investigation methods for surface and interface systems, processes, structures, materials and coatings. No principe restrictions exist related systems, types of processes, methods of control and study. The journal welcomes conceptual, theoretical, experimental, methodological, instrumental, environmental, and all other possible studies.
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