The development of new hardmetal coating applications such as fatigue-loaded parts, structural components and tools for metal forming is connected with improvement of their performance and reliability. For modelling purposes the knowledge of thermophysical, mechanical and other material data is required. However, this information is still missing today. In the present work the thermophysical data of a WC-17Co coating sprayed with a liquid-fuelled HVOF-process from a commercial agglomerated and sintered feedstock powder from room temperature up to 700℃ was determined as an example. The dependence of the heat conductivity on temperature was obtained through measurement of the coefficient of thermal expansion, the specific heat capacity and the thermal diffusivity. Heat conductivities ranging from 29.2 W/(mK) at 50℃ to 35.4 W/(mK) at 700℃ were determined. All measurements were performed twice (as-sprayed and after the first thermal cycle) in order to take into account the structural and compositional changes. Extensive XRD and FESEM studies were performed in order to characterize the phase compositions and microstructures in the as-sprayed and heat-treated states. Bulk samples obtained by spark plasma sintering from the feedstock powder were studied for comparison.
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机译:新的硬质合金涂层应用的开发,例如疲劳载荷零件,结构部件和用于金属成型的工具,与它们的性能和可靠性的提高息息相关。为了进行建模,需要了解热物理,机械和其他材料数据。但是,今天仍然缺少此信息。在本工作中,以从室温到700℃的市售烧结和烧结原料粉末为例,确定了用液体燃料HVOF工艺喷涂的WC-17Co涂层的热物理数据。通过测量热膨胀系数,比热容和热扩散率来获得热导率对温度的依赖性。测定的热导率在50℃下为29.2 W /(mK)至700℃下为35.4 W /(mK)。为了测量结构和成分的变化,所有的测量都进行了两次(喷涂后和第一次热循环后)。进行了广泛的XRD和FESEM研究,以表征喷涂和热处理状态下的相组成和微观结构。为了进行比较,研究了通过火花等离子体烧结从原料粉末获得的大块样品。
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