Your search keyword '"Xu, Songzhe"' showing total 4 results

1. Multi-scale Modeling and Experimental Study on Microstructure of Ni-Based Superalloys in Additive Manufacturing.

Author

Xu, Songzhe, Lu, Heyu, Wang, Jiang, Shi, Ling, Chen, Chaoyue, Hu, Tao, and Ren, Zhongming

Subjects

MULTISCALE modeling, NICKEL alloys, INCONEL, LAVES phases (Metallurgy), LATTICE Boltzmann methods, HEAT resistant alloys, MICROSTRUCTURE

Abstract

In this work, a novel multi-scale method is proposed to investigate the microstructure and Laves phase morphology of Inconel 718 alloy in directed energy deposition (DED). The proposed multi-scale model considers the significant effect of micro-scale melt flow during solidification in DED by coupling a phase field method with the lattice Boltzmann method (PF-LBM) in dendrite growth computation, and it reveals that the melt flow homogenizes the distribution of solute concentration and reduces the primary dendrite arm spacing (PDAS). Experiments are also carried out to validate the multi-scale model and illustrate the difference in Laves phase morphology under two manufacturing conditions. The results show that cooling rate is the dominant factor that overshadows the effect of temperature gradient to solidification rate ratio ( G / V p ) in determining the morphology of Laves phase in interdendritic region, and a lower cooling rate tends to produce discrete Laves phase morphology, while a higher cooling rate tends to produce long-chain morphology, which is detrimental to mechanical property. Using this multi-scale model, a parametric study is numerically performed to predict and summarize the Laves phase morphology pattern under varied practical manufacturing parameters (i.e., laser power and scanning speed). The proposed multi-scale model is demonstrated capable to suggest optimal manufacturing parameters for a preferred mechanical property in DED based on accurate Laves phase computation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Effects of Static Magnetic Field on the Microstructure of Selective Laser Melted Inconel 625 Superalloy: Numerical and Experiment Investigations.

Author

Zhu, Wanli, Yu, Sheng, Chen, Chaoyue, Shi, Ling, Xu, Songzhe, Shuai, Sansan, Hu, Tao, Liao, Hanlin, Wang, Jiang, and Ren, Zhongming

Subjects

SELECTIVE laser melting, MAGNETIC field effects, INCONEL, SOLID-liquid interfaces, NICKEL alloys, HEAT resistant alloys, LORENTZ force

Abstract

A number of researchers have reported that a static magnetic field (SMF) will affect the process of selective laser melting (SLM), which is achieved mainly through affecting molten pool evolution and microstructure growth. However, its underlying mechanism has not been fully understood. In this work, we conducted a comprehensive investigation of the influence of SMF on the SLM Inconel 625 superalloy through experiments and multi-scale numerical simulation. The multi-scale numerical models of the SLM process include the molten pool and the dendrite in the mushy zone. For the molten pool simulation, the simulation results are in good agreement with the experimental results regarding the pool size. Under the influence of the Lorentz force, the dimension of the molten pool, the flow field, and the temperature field do not have an obvious change. For the dendrite simulation, the dendrite size obtained in the experiment is employed for setting up the dendrite geometry in the dendrite numerical simulation, and our findings show that the applied magnetic field mainly influences the dendrite growth owing to thermoelectric magnetic force (TEMF) on the solid–liquid interface rather than the Lorentz force inside the molten pool. Since the TEMF on the solid–liquid interface is affected by the interaction between the SMF and thermal gradient at different locations, we changed the SLM parameters and SMF to investigate the effect on the TEMF. The simulation shows that the thermoelectric current is highest at the solid–liquid interface, resulting in a maximum TEMF at the solid–liquid interface and, as a result, affecting the dendrite morphology and promoting the columnar to equiaxed transition (CET), which is also shown in the experiment results under 0.1 T. Furthermore, it is known that the thermoelectric magnetic convection (TEMC) around the dendrite can homogenize the laves phase distribution. This agrees well with the experimental results, which show reduced Nb precipitation from 8.65% to 4.34% under the SMF of 0.1 T. The present work can provide potential guidance for microstructure control in the SLM process using an external SMF. [ABSTRACT FROM AUTHOR]

Published

2021

3. Effect of static magnetic field on the molten pool dynamics during laser powder bed fusion of Inconel 718 superalloy.

Author

Yu, Sheng, Chen, Chaoyue, Xu, Songzhe, Hu, Tao, Shuai, Sansan, Wang, Jiang, Zhao, Jiwei, and Ren, Zhongming

Subjects

*MAGNETIC field effects, *MAGNETIC flux density, *MAGNETISM, *HEAT resistant alloys, *MARANGONI effect, *COMPUTATIONAL fluid dynamics

Abstract

Recent researches show that a static magnetic field (SMF) has an impact on the molten pool dynamics and microstructure of laser powder bed fusion (L-PBF). This work is intended to the multiple effect of SMF on the molten pool dynamics during L-PBF of Inconel 718 superalloy. A three-dimensional (3D) multiphase computational fluid dynamics (CFD) model at the powder-bed scale was established by coupling the electromagnetic braking and Seebeck effect in a static vertically-distributed magnetic field. Results show that the magnetic damping force (MDF) of the order of 104 N/m3∼105 N/m3 within the whole molten pool suppresses the Marangoni convection. The thermoelectric magnetic force (TEMF) of the order of 106 N/m3∼107 N/m3 rotates in the mushy zone and further enhances the melt flow of the whole molten pool. The SMF will not transform the flow pattern and temperature distribution in the molten pool. SMFs of 0.1 T and 0.3 T will suppress the melt flow, while that of 0.5 T will enhance the melt flow. The width of molten pool first decreases and then increases when the magnetic flux density (MFD) increases from 0 T to 0.5 T. In addition, applying a SMF of 0.3 T can effectively inhibit pore defect and spatters. This work can provide insight into the control of molten pool by introducing a SMF during L-PBF. • Multiphase computational fluid dynamics model is implemented by considering the electromagnetic braking and Seebeck effect. • The effect of Lorentz force on the molten pool dynamics with different magnetic flux densities is discussed. • The magnetic damping force suppresses the melt flow while the thermoelectric magnetic force promotes the melt flow. • The pore defect and spatters are effectively suppressed under a magnetic field of 0.3 T. [ABSTRACT FROM AUTHOR]

Published

2024

4. On the control of epitaxial growth and stray grains during laser-directed energy deposited Ni-based single crystal superalloy.

Author

Guan, Wei, Chen, Chaoyue, Pan, Xinwei, Zhao, Ruixin, Lu, Xufei, Hu, Tao, Xu, Songzhe, Xuan, Weidong, Panwisawas, Chinnapat, Lei, Liming, Wang, Jiang, and Ren, Zhongming

Subjects

*EPITAXY, *SINGLE crystals, *HEAT resistant alloys, *HEAT treatment, *THERMOCYCLING, *LASER weapons, *LASER deposition, *THERMAL barrier coatings

Abstract

Laser-directed energy deposition (L-DED) is considered as an effective repair method for damaged single-crystal (SX) superalloy turbine blades. However, controlling stray grains (SGs) and epitaxial growth is still the major problem. This study investigated the influences of pre-solution treatment and intrinsic heat treatment (IHT) on the formation of SGs and epitaxial growth of L-DED René N5 SX superalloy. The γ/γ' eutectics and coarse γ' precipitates at the inter-dendrite region can be eliminated after pre-solution treatment procedures before the L-DED experiment. A lower temperature in pre-solution treatment resulted in the retention of residual γ/γ' eutectics and coarse γ' precipitates. Thus, the aggravated element segregation within the local melt pool and interface collapse during the L-DED process can result in stray grains (SGs) formation. Improved pre-solution treatment procedures can also help reduce SGs caused by the carbides in the substrate. Besides, the SG formation in the deposited layers can be attributed to the recrystallization as a result of high thermal stress during the IHT in thermal cycles. The optimized pre-solution treatment procedure reduced the elemental segregation of the substrates , resulting in a larger primary dendrite arm spacing (PDAS) from the bottom of the deposited layers. Due to IHT during thermal cycles in the deposited layers, the equivalent heat treatment process promoted the re-precipitation and growth of γ' phase. Meanwhile, the optimized pre-solution treatment procedure decreased the size of the heat-affected zone (HAZ) caused by thermal cycles. In summary, by optimizing the substrates' pre-solution treatment procedures to eliminate the γ/γ' eutectics ,coarse precipitaes and decrease the carbides in the subsrtates, the formation of SGs resulting from substrate segregation and heterogeneous microstructure can be controlled. This work provides the potential guidance of substrate pre-treatment for L-DED repair of SX superalloys. [Display omitted] • Pre-solution heat treatment procedure is benefit to the control of stray grains (SGs) in the bottom of the molten pool. • SGs found in the deposited zone were strongly associated with recrystallization. • Improper pre-solution treatment procedure increased the length of heat-affect zone (HAZ). • Intrinsic heat-treatment (IHT) caused by thermal cycles led to different microstructure evolution of γ' precipitates in the sample. [ABSTRACT FROM AUTHOR]

Published

2024