Deformation Behavior and J-Integral of Macroscopic Hydride Platelet Clusters in Hydrided Zr-2.5Nb Pressure Tube Materials Under Plane Strain Conditions

Volume 6A: Materials and Fabrication Pub Date : 2019-11-15 DOI:10.1115/pvp2019-93763

Shengji Wu, Jwo Pan, D. Scarth, S. Lawrence

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Abstract

The mechanical behavior and J-integral of macroscopic hydride platelet clusters in hydrided Zr-2.5Nb pressure tube materials are investigated by two-dimensional finite element analyses with cohesive zone model under plane strain conditions. The hydride platelets are assumed to be separated at the early stage of the loading and are treated as cracks. The cohesive zone model with a trapezoidal traction-separation law is adopted. The macroscopic mechanical behavior is quantified by the macroscopic stress-strain relations and the fracture parameter of the bulk radial hydride is specified by the J integral-stress relations. The hydride platelet spacing has major effects while the cohesive energy and cohesive strength have minor effects on the mechanical behavior and fracture properties of the bulk hydrides. The computational results suggest that the hydride platelet cluster can be viewed as a soft region with a reduced load carrying capacity at large stress under plane strain loading conditions. A hydride platelet cluster may be treated as a cracked bulk hydride but with a reduced crack tip driving force for fracture.

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平面应变条件下Zr-2.5Nb压力管材料中宏观氢化物血小板团簇的变形行为及j积分

采用二维内聚区模型，研究了平面应变条件下Zr-2.5Nb压力管材料中宏观氢化物血小板团簇的力学行为和j积分。假定氢化物薄片在加载初期就已分离，并作为裂纹处理。采用具有梯形牵引-分离规律的粘聚带模型。宏观力学行为用宏观应力-应变关系来量化，断裂参数用J积分-应力关系来表示。氢化物血小板间距对整体氢化物的力学行为和断裂性能影响较大，而结合能和结合能对整体氢化物的力学行为和断裂性能影响较小。计算结果表明，在平面应变加载条件下，氢化物血小板簇可视为大应力下承载能力降低的软区。一个氢化物血小板簇可以作为一个破裂的块状氢化物处理，但是裂纹尖端的断裂驱动力降低了。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 6A: Materials and Fabrication

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