weld interface meaning in Chinese
焊缝界面
焊接界面
Examples
- Therefore , in order to understand the long - time performance of the weld , it is necessary to study the welding interface of niobium alloy and stainless steel , and know the microstructure evaluation . explosive welding and vacuum electron beam self - material brazing were used to prepare the specimen
因此,研究铌合金与不锈钢的焊接结合层,分析形成的互扩散层的组织、成分和性能变化,对了解不锈钢和nb合金的互扩散反应行为,焊接件的焊接工艺改进和长期使用性能的评估是很有意义的。 - The explosive welding specimen were also annealed in vacuum at various elevated temperature from 1000 to 1300 . optic microscope , sem , tem and eds ( electron diffraction scattering ) techniques are applied to observe the microstructure and the element profiles of the welding interface and the interdiffused layer , reveal the interdiffused performance of alloy elements at elevated temperature , and analyze the structure and composition of the precipitated phases . moreover , the tensile strength of welding line with the two different techniques and various welding parameters were carried out
采用金相、扫描电镜、透射电镜、能谱等多种实验手段对焊接结合层的微观组织结构、高温下nb - 1zr与不锈钢合金元素的互扩散行为,形成的互扩散层的成分、金相组织和扩散层中的析出相的相组成和相结构等,都进行了较为详细的分析,并且对在不同工艺、不同焊接参数下焊接的nb - 1zr合金和不锈钢的焊缝做了强度实验研究。 - Some factors influencing the grain growth were studied in detail using mc technique . the mc simulation of grain growth can provide not only grain growth kinetics but also detailed information on temporal grain morphology evolution . furthermore , mc technique can easily simulate the " thermal pin " phenomenal caused by steep temperature gradient near the weld interface
采用mc模拟技术,不仅能够模拟焊接haz奥氏体晶粒长大的动力学过程,而且能够逼真地模拟奥氏体晶粒微观形貌的变化,更重要的是它可以很好地模拟焊接haz存在的陡峭的温度梯度对奥氏体晶粒长大的影响。