Phenomenological Model of Cavitation Erosion of Nitrogen ION Implanted Hiped Stellite 6

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY Advances in Materials Science Pub Date : 2023-03-01 DOI:10.2478/adms-2023-0007
M. Szala
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引用次数: 1

Abstract

Abstract Stellites are a group of Co-Cr-C-W/Mo-containing alloys showing outstanding behavior under cavitation erosion (CE) operational conditions. The process of ion implantation can improve the CE resistance of metal alloys. This work presents the elaborated original phenomenological model of CE of nitrogen ion implanted HIP-consolidated (Hot Isostatically Pressed) cobalt alloy grade Stellite 6. The ultrasonic vibratory test rig was used for CE testing. The nitrogen ion implantation with 120 keV and fluence of 5 × 1016 N+/cm−2 improves HIPed Stellite 6 cavitation erosion resistance two times. Ion-implanted HIPed Stellite 6 has more than ten times higher CE resistance than the reference AISI 304 stainless steel sample. Comparative analysis of AFM, SEM and XRD results done at different test intervals reveals the kinetic of CE process. The model includes the surface roughness development and clarifies the meaning of cobalt-based matrix phase transformations under the nitrogen ion implantation and cavitation loads. Ion implantation modifies the cavitation erosion mechanisms of HIPed Stellite 6. The CE of unimplanted alloy starts on material loss initiated at the carbides/matrix interfaces. Deterioration starts with cobalt matrix plastic deformation, weakening the carbides restraint in the metallic matrix. Then, the cobalt-based matrix and further hard carbides are removed. Finally, a deformed cobalt matrix undergoes cracking, accelerating material removal and formation of pits and craters’ growth. The nitrogen ion implantation facilitates ɛ (hcp—hexagonal close-packed)) → γ (fcc—face-centered cubic) phase transformation, which further is reversed due to cavitation loads, i.e., CE induces the γ → ɛ martensitic phase transformation of the cobalt-based matrix. This phenomenon successfully limits carbide removal by consuming the cavitation loads for martensitic transformation at the initial stages of erosion. The CE incubation stage for ion implanted HIPed Stellite 6 lasts longer than for unimplanted due to the higher initial content of γ phase. Moreover, this phase slows the erosion rate by restraining carbides in cobalt-based matrix, facilitating strain-induced martensitic transformation and preventing the surface from severe material loss.
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氮离子注入髋部钨铬钴合金空化侵蚀的现象学模型
摘要:钨铬钴合金是一类含Co-Cr-C-W/ mo的合金,在空化蚀蚀(CE)操作条件下表现优异。离子注入工艺可以提高金属合金的CE电阻。本文提出了氮离子注入hip -固结(热等静压)钴合金级Stellite 6的CE的原始现象学模型。采用超声振动试验台进行CE检测。以120 keV注入5 × 1016 N+/cm−2的氮离子,使HIPed Stellite 6的抗空化侵蚀能力提高了2倍。离子注入的HIPed Stellite 6具有比参考AISI 304不锈钢样品高十倍以上的CE电阻。对不同测试间隔的AFM、SEM和XRD结果进行对比分析,揭示了CE过程的动力学。该模型包含了表面粗糙度的发展,阐明了氮离子注入和空化载荷下钴基基体相变的意义。离子注入改变了HIPed Stellite 6的空化侵蚀机制。未注入合金的CE从碳化物/基体界面处的材料损失开始。劣化始于钴基体的塑性变形,削弱了金属基体中的碳化物约束。然后,除去钴基基体和进一步的硬质碳化物。最后,变形的钴基体发生开裂,加速材料的去除和形成坑和陨石坑的生长。氮离子注入促进了钴基基体的γ→γ (hcp -六方密堆积)→γ (fcc -面心立方)相变,而空化载荷进一步逆转了这一过程,即CE诱导钴基基体的γ→γ马氏体相变。这种现象通过消耗腐蚀初期马氏体转变的空化载荷,成功地限制了碳化物的去除。离子注入的HIPed Stellite 6的CE孵育期比未注入的更长,这是由于初始γ相含量较高。此外,该相通过抑制钴基基体中的碳化物,促进应变诱导马氏体转变和防止表面严重的材料损失来减缓侵蚀速率。
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Advances in Materials Science
Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
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