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The dynamic fracture phase-field model predicted similar crack propagation to what was found in the literature for quasi-static and dynamic validation cases. By varying the critical load level for the L-shaped soda-lime glass specimens using the new crack driving force, the model predicted a positive correlation between the initial crack propagation speed and the critical load level, similar to what was seen in the experiments. However, the predicted crack propagation speed decreased quicker than the experimental crack propagation speed. The tension-compression splits had an impact on the predicted crack propagation paths. Overall, the proposed crack driving force used in the dynamic fracture phase-field model seems to capture the relation between critical load and initial crack propagation speed and thus enables crack predictions for specimens of varying strength.</p></div>","PeriodicalId":590,"journal":{"name":"International Journal of Fracture","volume":"245 1-2","pages":"57 - 73"},"PeriodicalIF":2.2000,"publicationDate":"2024-01-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://link.springer.com/content/pdf/10.1007/s10704-023-00754-3.pdf","citationCount":"0","resultStr":"{\"title\":\"Modeling brittle crack propagation for varying critical load levels: a dynamic phase-field approach\",\"authors\":\"Jonas Rudshaug, Tore Børvik, Odd Sture Hopperstad\",\"doi\":\"10.1007/s10704-023-00754-3\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Brittle materials are known for their violent and unpredictable cracking behavior. 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引用次数: 0
摘要
脆性材料以其剧烈和不可预测的开裂行为而闻名。这种行为是由微观材料缺陷以及系统势能和材料表面能之间的竞争共同决定的。在本研究中,我们介绍了如何在商用有限元(FE)求解器中实施带有新裂纹驱动力的动态断裂相场模型,并使用三种不同的拉伸-压缩分裂来检验其行为。在验证了该模型的实施后,我们使用该模型研究了其对具有不同临界载荷水平的准静载 L 型钠钙玻璃试样的预测能力。在准静态和动态验证情况下,动态断裂相场模型预测的裂纹扩展与文献中的结果相似。通过使用新的裂纹驱动力改变 L 形钠长石玻璃试样的临界载荷水平,该模型预测了初始裂纹扩展速度与临界载荷水平之间的正相关关系,这与实验中的结果类似。然而,预测的裂纹扩展速度比实验的裂纹扩展速度下降得更快。拉伸-压缩分裂对预测的裂纹扩展路径有影响。总之,动态断裂相场模型中使用的裂纹驱动力似乎捕捉到了临界载荷与初始裂纹扩展速度之间的关系,因此可以对不同强度的试样进行裂纹预测。
Modeling brittle crack propagation for varying critical load levels: a dynamic phase-field approach
Brittle materials are known for their violent and unpredictable cracking behavior. A behavior which is dictated by a combination of microscopical material defects and the competition between the potential energy of the system and the surface energy of the material. In this study, we present the implementation of a dynamic fracture phase-field model with a new crack driving force into a commercial finite element (FE) solver and examine its behavior using three different tension-compression splits. After validating the implementation, we use the model to investigate its predictive capacity on quasi-statically loaded L-shaped soda-lime glass specimens with varying critical load levels. The dynamic fracture phase-field model predicted similar crack propagation to what was found in the literature for quasi-static and dynamic validation cases. By varying the critical load level for the L-shaped soda-lime glass specimens using the new crack driving force, the model predicted a positive correlation between the initial crack propagation speed and the critical load level, similar to what was seen in the experiments. However, the predicted crack propagation speed decreased quicker than the experimental crack propagation speed. The tension-compression splits had an impact on the predicted crack propagation paths. Overall, the proposed crack driving force used in the dynamic fracture phase-field model seems to capture the relation between critical load and initial crack propagation speed and thus enables crack predictions for specimens of varying strength.
期刊介绍:
The International Journal of Fracture is an outlet for original analytical, numerical and experimental contributions which provide improved understanding of the mechanisms of micro and macro fracture in all materials, and their engineering implications.
The Journal is pleased to receive papers from engineers and scientists working in various aspects of fracture. Contributions emphasizing empirical correlations, unanalyzed experimental results or routine numerical computations, while representing important necessary aspects of certain fatigue, strength, and fracture analyses, will normally be discouraged; occasional review papers in these as well as other areas are welcomed. Innovative and in-depth engineering applications of fracture theory are also encouraged.
In addition, the Journal welcomes, for rapid publication, Brief Notes in Fracture and Micromechanics which serve the Journal''s Objective. Brief Notes include: Brief presentation of a new idea, concept or method; new experimental observations or methods of significance; short notes of quality that do not amount to full length papers; discussion of previously published work in the Journal, and Brief Notes Errata.