Plastic damage mechanism and grain orientation evolution along the thickness direction in heavy-walled submarine pipelines during the progressive forming process

IF 6.1 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Ling-zhi Xu , Gui-ying Qiao , Ying-long Ma , Yu Gu , Kai Xu , Xiao-wei Chen , Fu-ren Xiao
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Abstract

The progressive forming process (JCOE process) results in the creation of a high-strength submarine pipeline with substantial wall thickness. However, the accumulated of strain during the transverse forming process leads to increased disparities in the microstructure of layers with varying thicknesses, thereby impacting the longitudinal mechanical properties of the pipes. This investigation explores the combination of three-dimensional (3D) simulation and experimental methods allowed for comparison of how the JCOE process impacts the mechanisms of plastic damage and the evolution of longitudinal grain orientation in layers with varying thicknesses in pipes. It was revealed in the findings that the increase in accumulated strain led to a rise in dislocation density within the grain. This exacerbated dislocation pile-up at ferrite boundaries and ferrite/bainite interfaces and raised the level of plastic damage. A reduction in grain size enhanced the strain gradient in the surface layer, resulting in hindered advancement of plastic damage. From the 1/2-thickness layer towards the surface layer, the crystal orientation tended predominantly towards the [110] direction with the accumulation of strain. At a lower level of the accumulated plastic strain, the predominant orientation of the texture in the 1/2-thickness layer was directed towards the α-fibers. As the accumulated deformation progressed into the 1/4-thickness layer, the α-fiber transformed to a {001}<110> type texture under the combined effect of conjugated slip and cross-slip. The transformation of the {001}<110> type texture into the {112}<110> type texture ensued as the accumulated deformation progressed to the surface layer and tended to shift to the {111}<110> type texture. The results of this work guide methods to control the microstructure and properties of heavy-wall dual-phase steel submarine pipelines.
渐进成型过程中厚壁海底管道的塑性损伤机制和沿厚度方向的晶粒取向演变
渐进成型工艺(JCOE 工艺)可制造出具有较大壁厚的高强度海底管道。然而,横向成型过程中累积的应变会导致不同厚度层的微观结构差异增大,从而影响管道的纵向机械性能。这项研究结合三维模拟和实验方法,比较了 JCOE 工艺如何影响塑性损伤机制以及管道中不同厚度层的纵向晶粒取向演变。研究结果表明,累积应变的增加导致晶粒内位错密度上升。这加剧了铁素体边界和铁素体/贝氏体界面的位错堆积,并提高了塑性破坏的程度。晶粒尺寸的减小增强了表层的应变梯度,从而阻碍了塑性破坏的发展。从 1/2厚度层向表层,随着应变的累积,晶体取向主要趋向于[110]方向。在较低的累积塑性应变水平上,1/2 厚层的纹理取向主要朝向 α 纤维。随着累积变形进入 1/4厚度层,在共轭滑移和交叉滑移的共同作用下,α纤维转变为{001}<110>型纹理。随着累积变形向表层发展,{001}<110>型纹理转变为{112}<110>型纹理,并有向{111}<110>型纹理转变的趋势。这项工作的结果为控制厚壁双相钢海底管道的微观结构和性能提供了指导方法。
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来源期刊
Materials Science and Engineering: A
Materials Science and Engineering: A 工程技术-材料科学:综合
CiteScore
11.50
自引率
15.60%
发文量
1811
审稿时长
31 days
期刊介绍: Materials Science and Engineering A provides an international medium for the publication of theoretical and experimental studies related to the load-bearing capacity of materials as influenced by their basic properties, processing history, microstructure and operating environment. Appropriate submissions to Materials Science and Engineering A should include scientific and/or engineering factors which affect the microstructure - strength relationships of materials and report the changes to mechanical behavior.
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