Cyclic deformation and fatigue of polycrystalline Cu under pure compressive cyclic loading condition

纯压缩循环加载条件下多晶Cu的循环变形与疲劳

• 批准号: RGPIN-2014-06545
• 负责人: Wang, Zhirui
• 金额: $ 2.11万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=638178
• 关键词: Cyclic; deformation; fatigue; polycrystalline; Cu

The objectives of the present project are to investigate and characterize the cyclic deformation response and fatigue crack initiation of engineering structure materials under pure compressive fatigue loading conditions. Fatigue fracture is the most frequently observed failure form of engineering components. The majority of fatigue failures observed in practice are through three stages, i.e. crack initiation, crack propagation and final fracture. Thus, prevention of crack initiation is considered one of the most important approaches to improve fatigue strength of engineering materials. Factors that affect fatigue crack initiation are often multiple including stress state, material property, and service condition. It has been shown that the overwhelming majority of fatigue crack initiation is due to tensile or mixed stress mode. Accordingly, most previous studies on cyclic deformation and fatigue fracture were carried out with either tension or multiple-direction load conditions. There has been no systematic study on cyclic deformation and fatigue fracture of engineering materials under pure compressive fatigue load, although such failure form does happen with critical engineering components, such as the fatigue fracture of aircraft landing gear frames. To fill the gap in the knowledge pool, the present project is therefore proposed. The outcome of the study will provide the understanding of the fundamental mechanisms on cyclic deformation and fatigue failure of materials under pure compressive loading condition, and offer better approach for industrial applications in fatigue life improvement.Previously, the cyclic deformation and fatigue response of selected steel under pure compressive cyclic loading was investigated in our group. It was found that, even if the applied fatigue load was fully compressive, fatigue crack may still form provided that there was even a very moderate stress concentration site. In fact, a critical condition in terms of von Mises stress was defined for crack initiation. For the samples without any stress concentration site, the observation was not comprehensive. This indicates further the significance of the present investigation. The proposed project is a more fundamental study aiming at the micro mechanisms of the cyclic deformation and fatigue crack formation under the compression fatigue condition. For the major part of this study, a model material, i.e. polycrystalline copper, will be used. In order to verify the findings from the fundamental study, tests will also be carried out with samples made of structure steels so that more industry-applicable results can be obtained.The experimental methodology for the proposed study is listed as follows. (1) Investigation of the cyclic stress-strain response: This part of the work will examine the cyclic hardening and/or softening response of the materials under the compressive cyclic stress conditions as well as cyclic creep behavior due the asymmetrical loading condition. (2) Motoring of the evolution of surface microstructure: This will include semi in situ observation of surface morphology changes, for which fatigue tests will be stopped at selected cycle numbers and the surface will be traced using not only optical and scanning electron microscopes but also atomic force microscope. (3) Examination of interior micro-structure change upon cycling: This will be done through transmission electron microscope to explore the evolution of dislocation structure corresponding to the stress-strain response. Finally, based on the results of the above tests, samples of structural steels will be tested with similar methodology but only for selected loading conditions. Thus, the fundamentals and their practical applicability may be further developed.

本项目的目标是研究和表征工程结构材料在纯压缩疲劳载荷条件下的循环变形响应和疲劳裂纹萌生。疲劳断裂是工程部件最常见的失效形式。实践中观察到的大多数疲劳失效都经历三个阶段，即裂纹萌生、裂纹扩展和最终断裂。因此，防止裂纹萌生被认为是提高工程材料疲劳强度的最重要方法之一。影响疲劳裂纹萌生的因素通常是多种的，包括应力状态、材料性能和使用条件。已经表明，绝大多数疲劳裂纹萌生是由于拉伸或混合应力模式造成的。因此，大多数先前关于循环变形和疲劳断裂的研究都是在拉伸或多向载荷条件下进行的。尽管关键工程部件确实会发生这种失效形式，例如飞机起落架框架的疲劳断裂，但目前尚未对纯压缩疲劳载荷下工程材料的循环变形和疲劳断裂进行系统研究。为了填补知识库的空白，因此提出了本项目。该研究成果将有助于理解材料在纯压缩循环加载条件下循环变形和疲劳失效的基本机制，为提高疲劳寿命的工业应用提供更好的途径。此前，我们课题组对所选钢材在纯压缩循环加载下的循环变形和疲劳响应进行了研究。研究发现，即使施加的疲劳载荷是完全压缩的，只要存在非常中等的应力集中部位，仍然可能形成疲劳裂纹。事实上，冯米塞斯应力的临界条件被定义为裂纹萌生。对于没有应力集中部位的样品，观察结果并不全面。这进一步表明了本次调查的意义。本项目是针对压缩疲劳条件下循环变形和疲劳裂纹形成的微观机制进行的更为基础的研究。对于本研究的主要部分，将使用模型材料，即多晶铜。为了验证基础研究的结果，还将对结构钢样品进行测试，以便获得更多工业适用的结果。本研究的实验方法如下。 (1)循环应力-应变响应的研究：这部分工作将检查材料在压缩循环应力条件下的循环硬化和/或软化响应以及由于不对称载荷条件导致的循环蠕变行为。 (2) 表面微观结构演变的驱动：这将包括表面形态变化的半原位观察，为此，疲劳试验将在选定的循环次数时停止，并且不仅使用光学和扫描电子显微镜，而且还使用原子力显微镜来追踪表面。 (3)循环时内部微观结构变化的检查：这将通过透射电子显微镜进行，以探索与应力应变响应相对应的位错结构的演变。最后，根据上述测试的结果，结构钢样品将采用类似的方法进行测试，但仅针对选定的负载条件。因此，基本原理及其实际适用性可以得到进一步发展。