Modelling the formation and self-healing of creep damage in iron-based alloys

Versteylen C. D.; Sluiter M. H. F.; van Dijk N. H.

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Modelling the formation and self-healing of creep damage in iron-based alloys

机译：模拟铁基合金蠕变损伤的形成和自我愈合

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A self-consistent model is applied to predict the creep cavity growth and strain rates in metals from the perspective of self-healing. In this model, the creep cavity growth rate is intricately linked to the strain rate. The self-healing process causes precipitates to grow inside creep cavities. Due to the Kirkendall effect, a diffusional flux of vacancies is induced in the direction away from the creep cavity during this selective self-healing precipitation. This process impedes the creep cavity growth. The critical stress for self-healing can be derived, and an analysis is made of the efficiency of self-healing elements in binary Fe-Cu, Fe-Au, Fe-Mo, and Fe-W alloys. Fe-Au is found to be the most efficient self-healing alloy. Fe-Mo and Fe-W alloys provide good alternatives that have the potential to be employed at high temperatures.

机译：应用自我一致的模型以从自我愈合的角度预测金属中的蠕变腔生长和应变率。在该模型中，蠕变腔生长速率与应变速率有比复杂。自我愈合过程导致沉淀物在蠕变内部生长。由于KIRKENDALL效果，在这种选择性自愈合沉淀过程中，在远离蠕变腔的方向上诱导空位的扩散磁通量。该过程阻碍了蠕变腔生长。可以推导出自我愈合的临界应力，分析是二元Fe-Cu，Fe-Au，Fe-Mo和Fe-W合金中的自愈元素的效率。 Fe-Au被发现是最有效的自我愈合合金。 Fe-Mo和Fe-W合金提供了良好的替代方案，具有在高温下使用的潜力。

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《Journal of Materials Science》 |2018年第20期|共16页
作者
Versteylen C. D.; Sluiter M. H. F.; van Dijk N. H.;
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作者单位

Delft Univ Technol Fac Appl Sci Fundamental Aspects Mat &

Energy Mekelweg 15 NL-2629 JB Delft Netherlands;

Delft Univ Technol Dept Mat Sci &

Engn Virtual Mat &

Mech Mekelweg 2 NL-2628 CD Delft Netherlands;

Delft Univ Technol Fac Appl Sci Fundamental Aspects Mat &

Energy Mekelweg 15 NL-2629 JB Delft Netherlands;

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正文语种 eng
中图分类工程材料学;
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1. Modelling the formation and self-healing of creep damage in iron-based alloys [J] . Versteylen C. D., Sluiter M. H. F., van Dijk N. H. Journal of Materials Science . 2018,第20期

机译：模拟铁基合金蠕变损伤的形成和自我愈合
2. Assessment of creep damage models in the prediction of high-temperature creep behaviour of Alloy 617 [J] . Kan Kevin, Muransky Ondrej, Bendeich Philip J., International Journal of Pressure Vessels and Piping . 2019,第期

机译：对合金高温蠕变行为预测的蠕变损伤模型的评估617
3. Effect of Creep Deformation on Creep-Fatigue Damage in Lamellar TiAl Alloy [J] . Young Sam Park, Soo Woo Nam, Seung Jin Yang Materials transactions . 2001,第7期

机译：蠕变变形对层状TiAl合金蠕变疲劳损伤的影响
4. A review of creep deformation and rupture mechanisms of low Cr-Mo alloy for the development of creep damage constitutive equations under lower stress [C] . Q. H. Xu, Q. Xu, Z. Lu, International Conference on Scientific Computing . 2013

机译：低Cr-Mo合金蠕变变形及破裂机制述评下应力下蠕变损伤组成方程的发展
5. Creep-Fatigue Damage Investigation and Modeling of Alloy 617 at High Temperatures. [D] . Tahir, Fraaz. 2017

机译：高温下617合金的蠕变疲劳损伤研究与建模。
6. Modelling the formation and self-healing of creep damage in iron-based alloys [O] . C. D. Versteylen, M. H. F. Sluiter, N. H. van Dijk -1

机译：模拟铁基合金中蠕变损伤的形成和自我修复
7. Damage Localization of Conventional Creep Damage Models and Proposition of a New Model for Creep Damage Analysis. [O] . Yan LIU, Sumio MURAKAMI 1998

机译：传统蠕变损伤模型的损伤定位及蠕变损伤分析新模型的命题。
8. Micromechanical Modeling of Microstructural Damage in Creeping Alloys. Final Report [R] . Argon, A. S. 1984

机译：匍匐合金微观组织损伤的微观力学模型。总结报告

Modelling the formation and self-healing of creep damage in iron-based alloys

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