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学者姓名:黄晔
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Abstract :
This study investigated the fabrication of a strengthened Ti-TiO2 material with adding 0.5 wt.% TiO2 nanoparticles via selective laser melting process in comparison with CP-Ti. Through the process parameters optimized by response surface methodology, the Ti-TiO2 material fabricated by SLM showed remarkable tensile strength of 800.6 MPa and elongation of 14%, as compared to the fabricated CP-Ti with tensile strength of 594.0 MPa and elongation of 21%. The x-ray diffraction patterns of fabricated specimens showed the expansion of the hcp-Ti lattice along the c-axis due to dissolved oxygen atoms from the decomposition of TiO2 nanoparticles. The microstructure analysis observed remains of incompletely decomposed TiO2 and TiO phases in SLMed Ti-TiO2 material, which was distinguished from former studies. Consequently, the decomposition behavior of added TiO2 nanoparticles associated with the dissolved oxygen in the Ti-matrix during the SLM process was discussed. Based on the evaluation of both the solution effect of oxygen atoms and the reinforcing effect of undecomposed nanoparticles, the dissolved oxygen from decomposed TiO2 was considered the primary factor in the intensified strength of SLMed Ti-TiO2 material. These results could offer novel insights into the additive manufacturing of high-strength and biocompatible titanium alloy via the SLM process.
Keyword :
additive manufacturing additive manufacturing biomaterials biomaterials composites composites metallic matrix metallic matrix strengthening mechanism strengthening mechanism titanium titanium
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| GB/T 7714 | Xiang, Hongliang , Chen, Xiaoyu , Huang, Ye et al. Decomposition Behavior and Strengthening Mechanism of Ti-TiO2 Material in Selective Laser Melting Process [J]. | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE , 2025 . |
| MLA | Xiang, Hongliang et al. "Decomposition Behavior and Strengthening Mechanism of Ti-TiO2 Material in Selective Laser Melting Process" . | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE (2025) . |
| APA | Xiang, Hongliang , Chen, Xiaoyu , Huang, Ye , Wu, Chaochao , Mou, Gang , Zheng, Kaikui . Decomposition Behavior and Strengthening Mechanism of Ti-TiO2 Material in Selective Laser Melting Process . | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE , 2025 . |
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The supportfree printing of overhanging structure arouses enormous interest for its advantages to eliminate the need for support removal and to improve the efficiency in laser powder bed fusion (L-PBF) additive manufacturing. However, the improvement of down -facing surface quality remains a significant challenge, where an in-depth understanding of the formation of overhanging tracks is essential. This paper developed a multiphysics model of overhanging tracks in L-PBF to systematically investigate the formation mechanisms of key features such as discontinuity and dross, as well as their correlation with surface roughness. It reveals that there are two main causes of discontinuity of overhanging tracks: the coalescence and balling of the melt under low energy density, and the irregular sinking of melt pool at the overhanging edge. The high energy density could mitigate the occurrence of discontinuous tracks, but it might also lead to undesirable dross upon the complete penetration of the overhanging structure. The relationship between processing parameters, morphological defects and surface roughness were systematically discussed, which revealed the necessity to tailor processing parameters for different overhang angles to improve the down -facing surface quality. Furthermore, the significant correlation between the single-track morphology and the down -facing surface roughness has been demonstrated quantitatively, which proposed a practical way to predict the trend of the down -facing surface quality by single-track simulation. This could help improve the supportfree printing process in metal additive manufacturing.
Keyword :
Laser powder bed fusion Laser powder bed fusion Multi-physics modeling Multi-physics modeling Overhanging structure Overhanging structure Supportfree printing Supportfree printing Surface roughness Surface roughness
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| GB/T 7714 | Xiang, Hongliang , Zhou, Yulong , Zhang, Xiangkai et al. Supportfree printing in laser powder bed fusion: Formation mechanisms of discontinuity, dross and surface roughness [J]. | OPTICS AND LASER TECHNOLOGY , 2024 , 177 . |
| MLA | Xiang, Hongliang et al. "Supportfree printing in laser powder bed fusion: Formation mechanisms of discontinuity, dross and surface roughness" . | OPTICS AND LASER TECHNOLOGY 177 (2024) . |
| APA | Xiang, Hongliang , Zhou, Yulong , Zhang, Xiangkai , Li, Jie , Huang, Ye , Mou, Gang et al. Supportfree printing in laser powder bed fusion: Formation mechanisms of discontinuity, dross and surface roughness . | OPTICS AND LASER TECHNOLOGY , 2024 , 177 . |
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Reliability of joints in solar arrays significantly influences the service life of satellites. Interface between solar cell and interconnector experiences serious temperature cycling during space service which would further lead to failure. To further improve the interface joining thermal reliability, elucidation of the interface formation and corresponding microstructure evolution during thermal fatigue is necessary. In this study, parallel gap resistance welded (PGRW) multi-layered joint between GaAs solar cell and Ag foil are subjected to different temperature cycling tests (-160-120 C-degrees, -165-160 (degrees)olution interdiffusion between Ag foil and Au surface of solar cell electrode. Also, conducted temperature cycling essentially lead to thermal fatigue process at Ag/Au interface, therefore more serious interface strength degradation is generated by larger temperature cycling range. Joint failure is initiated by thermal fatigue induced dislocation and residual strain concentrations around dissimilar interface. And the large mismatch in coefficients of thermal expansion (CTE) of the multilayer structure amplifies the thermal fatigue effect.(c) 2023 The Author(s). Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
Keyword :
Ag foil Ag foil Dissimilar interface Dissimilar interface GaAs solar cell GaAs solar cell Parallel gap resistance welding Parallel gap resistance welding Thermal fatigue Thermal fatigue
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| GB/T 7714 | Ding, Yuhan , Li, Xiaoran , Shen, Chen et al. Failure mechanism of parallel gap resistance welding joint between Ag foil and GaAs solar cell by temperature cycling [J]. | JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T , 2023 , 26 : 3272-3284 . |
| MLA | Ding, Yuhan et al. "Failure mechanism of parallel gap resistance welding joint between Ag foil and GaAs solar cell by temperature cycling" . | JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T 26 (2023) : 3272-3284 . |
| APA | Ding, Yuhan , Li, Xiaoran , Shen, Chen , Huang, Ye , Wei, Yi , Chen, Nannan et al. Failure mechanism of parallel gap resistance welding joint between Ag foil and GaAs solar cell by temperature cycling . | JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T , 2023 , 26 , 3272-3284 . |
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Rapid development of new energy vehicle desires more advanced lightweight design; such need makes the use of more Al continuously attractive to automotive industry. Since welding is the most commonly used method to build a car, the quality of Al/steel dissimilar joint becomes a key factor influencing the vehicle reliability. There is a common sense that Al/steel dissimilar joint would fracture either along Al/steel interface or Al heat-affected zone (HAZ), but the mechanism of such fracture mode variation is lack of experimental support. And as the joint interface is inevitably composed of Fe2Al5 and Fe4Al13 intermetallic layers, the detailed fracture procedure is usually too fast to be captured in situ and therefore rarely reported. In the present work, the fracture mode of Al/steel dissimilar overlap joints made using variable polarity cold metal transfer-based arc brazing is investigated using high-speed camera under special instrument setup. And by combining the high-speed camera results with interface material characterization results, the mechanism of fracture mode variation in Al/steel dissimilar overlap joint under axial tensile force is clarified. It is found that along with the increase in arc welding heat input, the fracture propagation path would experience a variation in "Al/steel interface -> Al HAZ." And such variation is practically induced by the synergistic effect of both overlap joint stress concentration and Al/steel interface strength, which is subsequently confirmed by numerical model analysis and a specially designed interface shear strength test.
Keyword :
dissimilar joint dissimilar joint fracture fracture interface interface numerical simulation numerical simulation welding welding
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| GB/T 7714 | Xu, Peizhi , Hua, Xueming , Shen, Chen et al. Fracture Mode Variation Mechanism of Al/Steel Dissimilar Overlap Joint Made Using Variable Polarity Cold Metal Transfer-Based Arc Brazing [J]. | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE , 2022 , 32 (2) : 512-523 . |
| MLA | Xu, Peizhi et al. "Fracture Mode Variation Mechanism of Al/Steel Dissimilar Overlap Joint Made Using Variable Polarity Cold Metal Transfer-Based Arc Brazing" . | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE 32 . 2 (2022) : 512-523 . |
| APA | Xu, Peizhi , Hua, Xueming , Shen, Chen , Mou, Gang , Huang, Ye , Wu, Kanglong et al. Fracture Mode Variation Mechanism of Al/Steel Dissimilar Overlap Joint Made Using Variable Polarity Cold Metal Transfer-Based Arc Brazing . | JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE , 2022 , 32 (2) , 512-523 . |
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