Solidification Crack Evolution in High-Strength Steel Welding Using the Extended Finite Element Method

Chen, Zhanglan; Liu, Jianmin; Qiu, Haijun

doi:10.3390/ma13020483

Cited by 5 publications

(4 citation statements)

References 37 publications

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“…Since the plastic strain was experimentally inaccessible, numerical simulation was utilized here as an alternative through thermo-mechanics in the ANSYS package by coupling the thermal results listed in Table 1 . The thermo-mechanical constitutive model of FH690 steel was referred to in [ 30 ]. The simulated plastic strain at point A in three EP sub-cases was extracted and is shown in Table 4 .…”

Section: Discussionmentioning

confidence: 99%

Toughening and Hardening Limited Zone of High-Strength Steel through Geometrically Necessary Dislocation When Exposed to Electropulsing

Xiong

Liu

2022

Materials

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The enhancement of both low-temperature impact toughness and the hardness of a high strength steel heat-affected zone (HAZ) is investigated by using high-density electropulsing (EP). The athermal and thermal effects of EP on HAZ microstructure and resultant mechanical properties were examined based on physical metallurgy by electron backscattered diffraction and on tests of hardness and impact toughness at −60 °C, respectively. EP parameters were carefully determined to avoid electro-contraction and excessive pollution of the base metal by using numerical simulation. The EP results show that the mean impact toughness and hardness of HAZ are 2.1 times and 1.4 times improved, respectively. In addition to the contribution of microstructure evolution, geometrically necessary dislocation (GND) is also a contributor with an increase of 1.5 times, against the slight decrease in dislocation line density and dislocation density. The mechanisms behind this selective evolution of dislocation components were correlated with the localized thermal cycle EP, i.e., the competition among thermo- and electro-plasticity, and work-hardening due to local thermal expansion. The selective evolution enables the local thermal cycle EP tailor the martensitic substructure that is most favorable for toughness and less for hardness. This selective span was limited within 4 mm for a 5 mm thick sample. The local thermal cycle EP is confirmed to be capable of enhancing in both toughness and hardness within a millimeter-scale region.

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Section: Discussionmentioning

confidence: 99%

Toughening and Hardening Limited Zone of High-Strength Steel through Geometrically Necessary Dislocation When Exposed to Electropulsing

Xiong

Liu

2022

Materials

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“…The (XFEM) emerged from the cohesive segments method [40,41]. When it is employed in unison with the phantom node technique [42][43][44], it is possible to replicate crack initiation and proliferation in an indiscriminate direction. This is because the crack propagation is not bound to mesh-based element peripheries.…”

Section: Dam Modeling By Xfemmentioning

confidence: 99%

Experimental and Nonlinear Analysis of Cracking in Concrete Arch Dams Due to Seismic Uplift Pressure Variations

Kadhim

Alfatlawi

Hussein

2021

IJE

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Cracked concrete arch dam's behavior due to moderate earthquake magnitude and water pressure variation was investigated. Plain concrete was used to cast the dam's models with 45 Mpa design strength. A shake table has been planned, manufactured, and built to create a dynamic testing facility. The experimental work was included testing of four scaled-down concrete arch dams' models, which is divided into two groups, each group contains two different degrees of curvature models. An artificial crack was made at the center of the dam's body. The extended finite element method (XFEM) is outlined in order to address the numerical predicate for the propagation of a crack. The results showed a good behavior of all arch dams under moderate earthquake intensity. The arch dam with a higher degree of curvature recorded 17.8% and 16.2% lower displacement at Z and X-direction, respectively. The stress evaluation and crack propagation in comparison with the arch dam owns the lowest degree of curvature. Hence, increasing the degree of curvature led to raising the stability of the dam, earthquake resistance, less displacement, and less growth of tensile cracks.

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“…The mechanical behavior of an MA constituent is different from that of the matrix, which creates a local inhomogeneous strain, promoting the nucleation of microvoids at the MA interfaces and degrading the HAZ’s fracture toughness. According to the classical Griffith theory [ 2 , 3 ], a brittle fracture occurs once the area of MA constituents reaches a critical value, such as 1 μm 2 [ 4 ]. This local brittle fracture remains ineffectively suppressed by narrowing the HAZ region with decreased heat input in in situ welds [ 1 ].…”

Section: Introductionmentioning

confidence: 99%

Eliminating the Brittleness Constituent to Enhance Toughness of the High-Strength Steel Weld Heat-Affected Zone Using Electropulsing

Chen

Xiong

et al. 2022

Materials

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The evolution of the martensite–austenite (MA) constituent in the heat-affected zone (HAZ) of high-strength steel FH690 welds when subjected to electropulsing (EP) treatment was investigated herein, with the aim of eliminating brittle MA to enhance toughness. The features induced by EPT were correlated with the microstructure and fractography through scanning electron microscopy and electron backscatter diffraction analyses, together constituting an impact property evaluation. The Charpy V-notch impact results showed EPT could improve toughness of the HAZ from 34.1 J to 51.8 J (the calibrated value was 46 J). Examinations of EP-treated microstructure showed a preferred Joule heating: at the site of the MA constituent, the cleavage fractography introduced by the MA constituent was substituted with ductile dimples with various sizes. Decreases in grain size of 40% and 47% for the matrix and the retained austenite, respectively, were achieved; while for regions without the MA constituent, microstructural modification was negligible. The temperature rise at sample surface was less than 60 °C. The mechanism behind this favorable Joule heating for the MA constituent was correlated with the electrical properties of the MA constituent in contrast with martensite matrix. The toughness enhancement of the HAZ was thus attributed to the elimination of the coarse MA constituent. The present investigation suggested that electropulsing, characterized as a narrow-duration current, is a promising method for preferred elimination of brittle factors and thus improving the toughness of HAZ of high-strength steel within a limited region with a width less than 2 mm.

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Solidification Crack Evolution in High-Strength Steel Welding Using the Extended Finite Element Method

Cited by 5 publications

References 37 publications

Toughening and Hardening Limited Zone of High-Strength Steel through Geometrically Necessary Dislocation When Exposed to Electropulsing

Toughening and Hardening Limited Zone of High-Strength Steel through Geometrically Necessary Dislocation When Exposed to Electropulsing

Experimental and Nonlinear Analysis of Cracking in Concrete Arch Dams Due to Seismic Uplift Pressure Variations

Eliminating the Brittleness Constituent to Enhance Toughness of the High-Strength Steel Weld Heat-Affected Zone Using Electropulsing

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