Hot Corrosion and Mechanical Performance of Repaired Inconel 718 Components via Laser Additive Manufacturing

Zhang, Qunli; Zhang, Jie; Zhuang, Yifan; Lu, Jinzhong; Yao, Jianhua

doi:10.3390/ma13092128

Cited by 20 publications

(8 citation statements)

References 44 publications

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“…Figure 16 c,d shows the cross sections of grooves filled by DMD without and with prior laser remelting. Similar to the findings of Zhang et al [ 25 ], there is a high bonding quality for both conditions, without bonding defects. The specimen with prior laser remelting shows a more regular bonding depth, especially in the inclined wall area.…”

Section: Resultssupporting

confidence: 90%

Laser Remelting Process Simulation and Optimization for Additive Manufacturing of Nickel-Based Super Alloys

et al. 2021

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Nickel-based super alloys are popular for applications in the energy and aerospace industries due to their excellent corrosion and high-temperature resistance. Direct metal deposition (DMD) of nickel alloys has reached technology readiness for several applications, especially for the repair of turbomachinery components. However, issues related to part quality and defect formation during the DMD process still persist. Laser remelting can effectively prevent and repair defects during metal additive manufacturing (AM); however, very few studies have focused on numerical modeling and experimental process parameter optimization in this context. Therefore, the aim of this study is to investigate the effect of determining the remelting process parameters via numerical simulation and experimental analyses in order to optimize an industrial process chain for part repair by DMD. A heat conduction model analyzed 360 different process conditions, and the predicted melt geometry was compared with observations from a fluid flow model and experimental single tracks for selected reference conditions. Subsequently, the remelting process was applied to a demonstrator repair case. The results show that the models can well predict the melt pool shape and that the optimized remelting process increases the bonding quality between base and DMD materials. Therefore, DMD part fabrication and repair processes can benefit from the remelting step developed here.

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Section: Resultssupporting

confidence: 90%

Laser Remelting Process Simulation and Optimization for Additive Manufacturing of Nickel-Based Super Alloys

et al. 2021

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“…It was found, that the LENS could be successfully applied for the repair process and prevent effectively the phase transformations on the border of the cladding and substrate material resulting from the extremely high temperature. Zhang et al [ 27 ] performed the repair of the Inconel 718 components by means of laser additive manufacturing. In this study, the Inconel 718 was deposited on the substrate of the same material with a trapezoid grove by a fiber-coupled diode laser system (Laserline LDF400–2000, Mülheim-Kärlich, Germany) which was characterized by the wavelength of 980 nm and maximum laser power of 2 kW.…”

Section: Resultsmentioning

confidence: 99%

“…Additionally, the molybdenum addition transforms the Laves phase morphology and decreases the segregation zone around the Laves phase. Moreover, the research of Zhang et al [ 27 ] presents, that the laser repair technology applied for the Inconel 718 alloy components led to elemental precipitation and the occurrence of the Laves phase. It could be concluded, that the process parameters proposed by the authors in a recent study enable a slight reduction of a phase transformation that occurred due to the high temperature resulting from the relatively high laser power of 900 W.…”

Section: Resultsmentioning

confidence: 99%

Suitability of Laser Engineered Net Shaping Technology for Inconel 625 Based Parts Repair Process

et al. 2021

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In this paper, the Inconel 625 laser clads characterized by microstructural homogeneity due to the application of the Laser Engineered Net Shaping (LENS, Optomec, Albuquerque, NM, USA) technology were studied in detail. The optimized LENS process parameters (laser power of 550 W, powder flow rate of 19.9 g/min, and heating of the substrate to 300 °C) enabled to deposit defect-free laser cladding. Additionally, the laser clad was applied in at least three layers on the repairing place. The deposited laser clads were characterized by slightly higher mechanical properties in comparison to the Inconel 625 substrate material. Microscopic observations and X-ray Tomography (XRT, Nikon Corporation, Tokyo, Japan) confirmed, that the substrate and cladding interface zone exhibited a defect-free structure. Mechanical properties and flexural strength of the laser cladding were examined using microhardness and three-point bending tests. It was concluded, that the LENS technology could be successfully applied for the repair since a similar strain distribution was found after Digital Image Correlation measurements during three-point bending tests.

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“…As previously stated, this phase is detrimental to Inconel 718 mechanical properties as it reduces strengthening phases such as γ" from being formed (Witzel, Stannard, Gasser, & Kelbassa, 2011;Zhang Q. , Zhang, Zhuang, Lu, & Yao, 2020). As Laves formation is promoted by increased Nb and Mo segregation, this can be reduced by using a dwell time between depositing adjacent tracks and subsequent layers.…”

Section: Laves Phasementioning

confidence: 99%

“…To mitigate elemental segregation, and subsequent formation of Laves, it is suggested that process conditions such as heat input, cooling rate and thermal gradients should be controlled (Radhakrishna & Prasad Rao, 1997) The dominant microstructure obtained for DED-L Inconel 718 consists of columnar dendrites elongated in the direction towards the heat sourceessentially consisting of γ-dendrites and interdendritic Laves (Jelvani, Razavi, Barekat, Dehnavi, & Erfanmanesh, 2019;Smith, et al, 2016;Zhao, Chen, Lin, & Huang, 2008;Zhang Q. , Zhang, Zhuang, Lu, & Yao, 2020;Mantri, et al, 2021). Laves forms irregularly, with morphology differing between laser powers (Zhu, Xu, & Gu, 2018).…”

Section: Laves Phasementioning

confidence: 99%

Laser direct energy deposition – the effect of process parameters on inconel 718

Elkington¹

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Laser Direct Energy Deposition (DED-L) is an Additive Manufacturing process which uses a laser beam as an energy source to melt blown metal powder to fabricate components. Complex relationships exist between the process parameters, which means that understanding these relationships, and their effect, is critical in understanding DED-L. This research investigates DED-L process parameters using a Trumpf 505 DMD system, aiming to determine the effect of altering specific process parameters on the metallurgical and mechanical properties of Inconel 718. Laser power, scan speed, and powder feed rate were first investigated using a Taguchi Design of Experiments. Anisotropy, build direction and a heat-treatment were then examined. The results demonstrate that the interactions between laser power, scan speed, and powder feed rate must be considered when determining process parameter values. An empirical working envelope of process parameter combinations for fabricating Inconel 718 on the Trumpf 505 DMD system was identified. For thick wall DED-L parts, changing the process parameters did not have any significant effect on the material properties. Process parameter combinations were found to be non-transferable between geometries – identical process parameters result in different material properties moving between different geometries. Thus individually built small test samples should not be used as representative of a larger components material properties. Combining different build directions did not have a negative effect on material properties at the interface between the build directions. Heat-treating eliminated the columnar dendritic grain structure, reduced Laves phase volume, and increased Vickers Hardness by 55%. This research adds to previous knowledge of how Inconel 718 behaves following fabrication by DED-L, and aids in understanding material integrity in thick wall DED-L builds. This contributes to improving the viability of using DED-L within industry.

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Hot Corrosion and Mechanical Performance of Repaired Inconel 718 Components via Laser Additive Manufacturing

Cited by 20 publications

References 44 publications

Laser Remelting Process Simulation and Optimization for Additive Manufacturing of Nickel-Based Super Alloys

Laser Remelting Process Simulation and Optimization for Additive Manufacturing of Nickel-Based Super Alloys

Suitability of Laser Engineered Net Shaping Technology for Inconel 625 Based Parts Repair Process

Laser direct energy deposition – the effect of process parameters on inconel 718

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