Coating failure analysis based on microfracture beneath point indentation

基于点压痕下微裂纹的涂层失效分析

• 批准号: 239211-2007
• 负责人: Liu, Rong
• 金额: $ 1.6万
• 依托单位: Carleton University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2011
• 资助国家: 加拿大
• 起止时间: 2011-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=479140
• 关键词: Coating; failure; analysis; based; microfracture

Hard coatings are increasingly used to improve the tribological performance and corrosion resistance of advanced engineering components, for example, gas turbine blades and combustion chambers. Generally, coating failures occur in two modes: (1) interfacial failure or delamination such that the coating layer spalls off the substrate; and (2) coating fracture. In either way, the coating loses its function of protection, thus the component life may be reduced significantly. While many studies have focused on coating/substrate interfacial delamination, the proposed research is to investigate coating fracture based on the mechanics of point-indentation microfracture. The point-indentation technique was originally developed to characterize a material's hardness or resistance to yield. Later, it was also found to be an effective means to characterize fracture toughness of brittle materials. Since most coating materials are brittle, it is expected that this approach can be applied for coating strength evaluation. In this research, indentation tests will be conducted on various coatings (varying thickness and materials) to investigate their cracking behaviors, combining with the Scanning Electron Microscope (SEM) observation. An analytical approach to the mechanics of point-indentation microfracture of coatings will be developed. The effects of coating thickness and the interface on the cracking pattern will be concerned. Two steps will be involved in the analytical solution: (1) determine the stress field beneath the loaded indenter in a coating in terms of the solution of an elastic half-space subjected to a normal point load, because among the three principal normal stresses, the tensile stress field will predetermine the ultimate history of brittle fracture in an elastically loaded coating, and (2) quantify the scale of the micro-cracking in terms of the applied load and thus derive an expression for the stress intensity factor in terms of the indenter load and characteristic crack dimension. The ultimate goal of this research will develop an indentation based method to evaluate the fracture toughness of coatings through crack length and geometry measurements.

硬涂层越来越多地用于改善先进工程部件的摩擦学性能和耐腐蚀性，例如燃气轮机叶片和燃烧室。通常，涂层失效发生在两种模式中：(1)界面失效或分层，使涂层从基材上脱落；(2)涂层断裂。在任何一种情况下，涂层都失去了其保护功能，从而可能大大降低组件的寿命。许多研究都集中在涂层/基体界面的分层上，而本文提出的研究是基于点压痕微断裂的机理来研究涂层断裂。点压痕技术最初是用来表征材料的硬度或抗屈服性能的。后来，它也被发现是表征脆性材料断裂韧性的有效手段。由于大多数涂层材料是脆性的，因此期望该方法可以应用于涂层强度评估。在本研究中，将对不同涂层（不同厚度和材料）进行压痕试验，并结合扫描电镜（SEM）观察，研究其开裂行为。提出了涂层点压痕微断裂的力学分析方法。研究了涂层厚度和界面对裂纹形态的影响。解析解将涉及两个步骤：(1)根据受法向点载荷的弹性半空间解，确定涂层中受压压头下方的应力场，因为在三个主法向应力中，拉应力场将预先确定弹性加载涂层的脆性断裂的最终历史；(2)用外加载荷量化微裂纹的尺度，从而推导出压头载荷和特征裂纹尺寸的应力强度因子表达式。本研究的最终目标是开发一种基于压痕的方法，通过裂纹长度和几何测量来评估涂层的断裂韧性。