A mesomechanical analysis of the stress–strain localisation in friction stir welds of polycrystalline aluminium alloys

Балохонов, Р. Р.; Романова, В. А.; Batukhtina, E. E.; Martynov, S. A.; Zinoviev, Aleksandr; Zinovieva, O.

doi:10.1007/s11012-015-0250-9

Cited by 10 publications

(8 citation statements)

References 34 publications

(44 reference statements)

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“…The strength of the material was found to depend on the degree of ordering of the microstructure. A similar numerical analysis for a microstructure containing fine and coarse grains in the nugget and base materials and elongated grains in the TMAZ was performed in [10]. Maximum plastic strain localization and fracture sites were found to depend on the specimen strain and strength of the material.…”

Section: Fig 1 Schematics Of Friction Stir Welding and Typical Micromentioning

confidence: 89%

“…Maximum plastic strain localization and fracture sites were found to depend on the specimen strain and strength of the material. Both sets of calculations [9,10], however, were performed for rather idealized 2D microstructures, with the isotropic elastic-plastic models being used to describe the deformation response of individual grains. It is, therefore, a challenge to perform a more realistic 3D analysis of microscale stress and strain fields formed in different FSW microvolumes under loading with accounting for an anisotropic elastic-plastic material response on the grain scale.…”

Section: Fig 1 Schematics Of Friction Stir Welding and Typical Micromentioning

confidence: 99%

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A Numerical Study of the Microscale Plastic Strain Localization in Friction Stir Weld Zones

et al. 2018

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A crystal plasticity approach was used to study the effects of grain shape and texture on the deformation behavior of friction stir weld (FSW) microregions. The explicit stress-strain analysis was performed for two representative grain structures with equiaxed and extended grains. Grain orientations were assigned to simulate no texture or a weak or strong cubic texture. Calculations have shown that the texture gave rise to earlier plastic strain localization on a larger scale. The highest stresses were found to develop in a non-textured specimen with equiaxed grains where the grain boundaries served as a barrier to dislocation motion. In both equiaxed and extended grain structures with a strong cubic texture no pronounced strain localization was seen on the grain scale but mesoscale shear bands appeared early in the deformation process. The calculations have shown that the microstructure-based simulation is a reasonable tool to study the deformation behavior of FSW materials, which is difficult to be predicted within macroscopic models alone.

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Section: Fig 1 Schematics Of Friction Stir Welding and Typical Micromentioning

confidence: 89%

Section: Fig 1 Schematics Of Friction Stir Welding and Typical Micromentioning

confidence: 99%

A Numerical Study of the Microscale Plastic Strain Localization in Friction Stir Weld Zones

et al. 2018

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“…A plane strain boundary-value problem is solved by the finite difference method with the use of the Wilkins scheme [1][2][3][4]. A ceramic coating and steel substrate are described as elastic-brittle and elastic-plastic solids, respectively.…”

Section: Statement Of the Problemmentioning

confidence: 99%

The influence of the mechanical properties of a steel substrate on the macroscopic strength of a coated material

Балохонов¹,

Zinoviev²,

Романова³

et al. 2016

AIP Conference Proceedings

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Abstract. The stress-strain localization and fracture in a steel substrate -porous ceramic coating microstructure subjected to compression -is investigated numerically. The effects of the substrate grain size and coating-substrate interface geometry on the mechanical behavior of the coated material are discussed. The elongation of the microstructure for which the first crack is initiated in the coating (crack initiation strain) is shown to increase exponentially with an increase in the substrate grain size. The location of the first crack in the coating is found to vary with the substrate grain size. The strength properties of the composite material are found to be unaffected by a serrated coating-substrate interface.

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“…FSW, invented in 1991 by W.M. Thomas at TWI [3], finds numerous applications [4,5,6,7] in a short time span compared to other welding processes. However, a coherent understanding of FSW process has not yet been achieved and there persists the quest for even better understanding of various aspects of the process, such as strain, strain rate, evolution of process forces, etc.…”

Section: Introductionmentioning

confidence: 99%

Investigation on Effect of Strain Rate and Heat Generation on Traverse Force in FSW of Dissimilar Aerospace Grade Aluminium Alloys

et al. 2019

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The emergence of the aerospace sector requires efficient joining of aerospace grade aluminium alloys. For large-scale industrial practices, achievement of optimum friction stir welding (FSW) parameters is chiefly aimed at obtaining maximum strain rate in deforming material with least application of traverse force on the tool pin. Exact computation of strain rate is not possible due to complex and unexposed material flow kinematics. Estimation using micro-structural evolution serves as one of the very few methods applicable to analyze the yet unmapped interdependence of strain rate and traverse force. Therefore, the present work assessed strain rate in the stir zone using Zener Holloman parameter. The maximum and minimum strain rates of 6.95 and 0.31 s−1 were obtained for highest and least traverse force, respectively.

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A mesomechanical analysis of the stress–strain localisation in friction stir welds of polycrystalline aluminium alloys

Cited by 10 publications

References 34 publications

A Numerical Study of the Microscale Plastic Strain Localization in Friction Stir Weld Zones

A Numerical Study of the Microscale Plastic Strain Localization in Friction Stir Weld Zones

The influence of the mechanical properties of a steel substrate on the macroscopic strength of a coated material

Investigation on Effect of Strain Rate and Heat Generation on Traverse Force in FSW of Dissimilar Aerospace Grade Aluminium Alloys

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