The solid particle erosion performance of tungsten inert gas yttria-stabilized zirconia - Inconel 625 composite cladding

N. Kamboj, Lalit Thakur Thakur, Manpreet K. Arora
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Abstract

The yttria-stabilized zirconia (YSZ) - Inconel 625 (IN625) composite cladding was deposited on a stainless steel substrate using a tungsten inert gas welding manipulator to protect it from solid particle erosion. Erosion wear tests were carried out at room temperature according to the ASTM G76-18 procedure. The surface of the tested material was exposed to a jet of alumina erodent particles at impact angles of 30 and 90°, respectively. Scanning electron microscopy images were utilized to examine the morphologies of the eroded surface and the microstructure of cladding. The erosive performance of YSZ - IN625 composite cladding was 3.5 and 2.4 times compared to the substrate at different impact angles. Improved microhardness and fracture toughness resulting from the favourable interaction between the hard ceramic YSZ particles and the IN625 matrix led to the enhanced erosion performance of composite cladding. Micro-cutting and ploughing were the predominant wear mechanisms in the substrate during the solid particle erosion test at a 30° impact angle, whereas the indentation-induced plastic deformation was domi­nant at a 90° impact angle. The results also revealed that the micro-cutting, detached splats and fissures were responsible for the wear in composite cladding at 30 and 90° impact angles.
钨惰性气体钇稳定氧化锆 - Inconel 625 复合包层的固体颗粒侵蚀性能
钇稳定氧化锆(YSZ)-铬镍铁合金 625(IN625)复合堆焊层使用钨极惰性气体焊接机械手沉积在不锈钢基体上,以防止固体颗粒的侵蚀。根据 ASTM G76-18 程序,在室温下进行了侵蚀磨损测试。测试材料的表面分别以 30° 和 90° 的冲击角暴露在氧化铝侵蚀颗粒的射流中。扫描电子显微镜图像用于检查侵蚀表面的形态和包层的微观结构。在不同的冲击角度下,YSZ - IN625 复合材料覆层的侵蚀性能分别是基体的 3.5 倍和 2.4 倍。硬质陶瓷 YSZ 颗粒与 IN625 基体之间的良好相互作用提高了微硬度和断裂韧性,从而增强了复合材料覆层的侵蚀性能。在 30° 冲击角的固体颗粒侵蚀试验中,基体的主要磨损机制是微切削和犁耕,而在 90° 冲击角的试验中,压痕引起的塑性变形占主导地位。结果还显示,在 30° 和 90° 冲击角下,复合材料覆层的磨损主要是由微切削、脱落的花斑和裂缝造成的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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