Experiments and Modeling of Fatigue of an Extruded Mg AZ61 Alloy

Jordon, J.B.; Gibson, J.B.; Horstemeyer, M.F.

doi:10.1002/9781118062029.ch13

Cited by 4 publications

(2 citation statements)

References 25 publications

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“…The faceted crack initiation appearance has been seen in previous work on WE43-T5 fatigue, as well as similar magnesium alloys being oriented toward the plane of maximum shear and was larger than the average grain size showing signs that slip is occurring across multiple similarly oriented grains and causing fracture [44,52]. This mechanism has been shown to most commonly occur at twin boundaries that can form from both the manufacturing process as well as during fatigue to accommodate the plastic strain necessary, as has been studied to explain the loading anisotropy seen in strain-controlled fatigue of magnesium alloys [53,54]. Twin boundaries function as stress concentrations, and they commonly form crack initiation sites in Mg alloys.…”

Section: Fractography For Bulk We43 Deposition Specimensmentioning

confidence: 99%

Elucidating the Effect of Additive Friction Stir Deposition on the Resulting Microstructure and Mechanical Properties of Magnesium Alloy WE43

Williams

Robinson

Williamson

et al. 2021

Metals

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In this work, the effect of processing parameters on the resulting microstructure and mechanical properties of magnesium alloy WE43 processed via Additive Friction Stir Deposition (AFSD), a nascent solid-state additive manufacturing (AM) process, is investigated. In particular, a parameterization study was carried out, using multiple four-layer deposits, to identify a suitable process window for a structural 68-layers bulk WE43 deposition. The parametric study identified an acceptable set of parameters with minimal surface defects and excellent consolidation for the fabrication of a bulk WE43 deposition. Microstructural, tensile, and fatigue life characterization was conducted on the bulk WE43 deposition and compared to commercially available wrought material to elucidate the process-structure-property-performance (PSPP) relationship of the AFSD process. This study shows that the bulk WE43 deposit exhibited a refined homogenous microstructure and a texture shift relative to the wrought material. However, a reduction in hardness and tensile behavior was observed in the as-deposited WE43 compared to the wrought control. Additionally, fatigue specimens extracted from the bulk deposition exhibited a decrease in life in the low-cycle regime but performed comparably to the wrought plate in the high-cycle regime. The outcomes of this study illustrate the potential of the AFSD process in additively manufactured structural load-bearing components made with magnesium alloy WE43 in the as-built condition.

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Section: Fractography For Bulk We43 Deposition Specimensmentioning

confidence: 99%

Elucidating the Effect of Additive Friction Stir Deposition on the Resulting Microstructure and Mechanical Properties of Magnesium Alloy WE43

Williams

Robinson

Williamson

et al. 2021

Metals

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show abstract

“…The microstructure-sensitive fatigue (MSF) model implemented in this study was first proposed by McDowell [39,40] for aluminum alloy A356-T6 [41]. The model was further expanded to additional aluminum alloys [42][43][44][45], other materials [46][47][48][49][50][51][52], and AM processes [30,53,54]. To elucidate the microstructural effect of AFS-D on fatigue resistance, the MSF was calibrated for the AFS-D using initial calibration parameters determined by Avery et al [30].…”

Section: Methodsmentioning

confidence: 99%

Evaluation of Microstructure and Mechanical Properties of Al-Zn-Mg-Cu Alloy Repaired via Additive Friction Stir Deposition

Avery

Cleek

Phillips

et al. 2022

Journal of Engineering Materials and Technology

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A novel solid-state additive manufacturing (AM) process, additive friction stir deposition (AFS-D), provides a new pathway for additively repairing damaged nonweldable aerospace materials that are susceptible to induced thermal gradients within the microstructure. In this work, we quantify the microstructural evolution and mechanical performance of an additively repaired AA7075-T651 (Al-Zn-Mg-Cu) via the AFS-D process. To evaluate the AFS-D process for repairing high strength aluminum alloys, the AFS-D technique was used to additively fill a linear groove that was machined into an AA7075-T651 plate. After repairing the plate with the AFS-D process, the repaired plate was subjected to standard T6 heat treatment. The results of this study show that the heat-treated AFS-D repair did not exhibit any significant grain growth and demonstrated an increase in the average Vickers hardness in the repair compared with the wrought 7075-T651 control. Tensile and fatigue behavior was investigated for heat-treated repair and compared with the wrought AA7075-T651 control. The heat-treated repair exhibited wrought-like tensile properties for yield stress (YS) and ultimate stress; however, the heat-treated repair had significant scatter in the elongation to failure. Additionally, the mean fatigue behavior of the heat-treated repairs displayed a reduction in cycles to failure compared with the wrought control. Lastly, a microstructure-sensitive fatigue life model was used to elucidate process-structure-property fatigue mechanism relations of the heat-treated repair and wrought AA7075.

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