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综合介绍 General Introduction 鹿旭飞，工学博士，从事高能束金属增材制造（3D打印）形性协同调控及热-力-组织模拟研究。已发表学术论文30余篇，被引1300余次，授权发明专利4项。 个人相册

教育教学

个人经历 personal experience 工作经历 教育经历 2024-03 至 今, 西北工业大学, 材料学院, 准聘教授2022-10 至 2024-03, 国际工程数值方法中心（CIMNE，西班牙） 2019-09 至 2022-09, 加泰罗尼亚理工大学（西班牙）, 结构分析, 博士2016-09 至 2019-04, 西北工业大学, 材料加工工程, 硕士2012-09 至 2016-06, 西北工业大学, 材料成型及控制工程, 学士

荣誉获奖

教育教学 Education and teaching 招生信息 欢迎材料、力学、机械及其相关专业的优秀学生保送、报考硕士和博士研究生，开展高能束金属增材制造研究。        1. 具备材料加工学科背景，对科研具有浓厚兴趣，踏实努力；        2. 熟悉有限元分析、多目标优化、结构拓扑优化优先；        3. 熟悉机械设计、力学分析、凝固组织分析优先。

科学研究

科研成果 Scientific research results 论文成果 专利成果 [1] Powder sheet additive manufacturing of multi-material structures: Experimental and computational characterizations.Composites Part B: Engineering,272 [2] Smart-substrate: a novel structural design to avert residual stress accretion in directed energy deposition additive manufacturing.Virtual and Physical Prototyping,18 [3] An enhanced finite element modelling based on self-regulation effect in directed energy deposition of Ti–6Al–4V.Journal of Materials Research and Technology,17 [4] Achieving fully-equiaxed fine β-grains in titanium alloy produced by additive manufacturing.Materials Research Letters,11 [5] A laser additive manufactured metastable Ti-10V-2Fe-3Al β-titanium alloy: Microstructure, mechanical properties, and deformation mechanisms.Materials Science and Engineering: A,890 [6] Recoater-induced distortions and build failures in selective laser melting of thin-walled Ti6Al4V parts.Journal of Manufacturing and Materials Processing,7 [7] 扫描路径对激光立体成形 TC4 构件热-力场的影响.材料工程,47 [8] Thermo-mechanical simulation of annealing heat treatment of Ni-based GH4099 superalloy made by laser powder bed fusion.Additive Manufacturing,73 [9] Globularization mechanism and near isotropic properties in subcritical heat-treated Ti6Al4V fabricated by directed energy deposition.Acta Metallurgica Sinica (English Letters),36 [10] Evolution of microstructure and mechanical property of Ti-47Al-2Cr-2Nb intermetallic alloy by laser direct energy deposition: From a single-track, thin-wall to bulk.Materials Characterization,190 [11] Modeling of the effect of the building strategy on the thermomechanical response of Ti-6Al-4V rectangular parts manufactured by laser directed energy deposition.Metals,10 [12] Crack-free laser powder bed fusion by substrate design.Additive Manufacturing,59 [13] Microstructure characteristics of a René N5 Ni-based single-crystal superalloy prepared by laser-directed energy deposition.Additive Manufacturing,61 [14] Mitigation of residual stresses and microstructure homogenization in directed energy deposition processes.Engineering with Computers,38 [15] Simulation-assisted investigation on the formation of layer bands and the microstructural evolution in directed energy deposition of Ti6Al4V blocks.Virtual and Physical Prototyping,16 [16] Residual stresses control in additive manufacturing.Journal of Manufacturing and Materials Processing,5 [17] Element vaporization of Ti-6Al-4V alloy during selective laser melting.Metals,10 [18] Passive behavior of nickel-based superalloys prepared by high-deposition-rate laser solid forming additive manufacturing.Corrosion Science,177 [19] In-situ grain structure control in directed energy deposition of Ti6Al4V.Additive Manufacturing,55 [20] Substrate design to minimize residual stresses in Directed Energy Deposition AM processes.Materials & Design,202 [21] Triboelectric nanogenerator based smart electronics via machine learning.Advanced Materials Technologies,5 [22] Evolution of solidification microstructure and dynamic recrystallisation of Inconel 625 during laser solid forming process.Journal of Materials Science,53 [23] 3D printing well organized porous iron-nickel/polyaniline nanocages multiscale supercapacitor.Journal of Alloys and Compounds,760 [24] Effect of heat treatment on the microstructural evolution and mechanical properties of GH4099 additive-manufactured by directed energy deposition.Journal of Alloys and Compounds,800 [25] Heat-affected coarsening of β grain in titanium alloy during laser directed energy deposition.Scripta Materialia,205 [26] Warpage analysis and control of thin-walled structures manufactured by laser powder bed fusion.Metals,11 [27] Finite element analysis and experimental validation of the thermomechanical behavior in laser solid forming of Ti-6Al-4V.Additive Manufacturing,21 [28] In situ measurements and thermo-mechanical simulation of Ti–6Al–4V laser solid forming processes.International Journal of Mechanical Sciences,153-154 [29] The microstructure evolution and tensile properties of Inconel 718 fabricated by high-deposition-rate laser directed energy deposition.Additive Manufacturing,31 [30] Formation mechanism of the α variant and its influence on the tensile properties of laser solid formed Ti-6Al-4V titanium alloy.Materials Science and Engineering: A,691 [31] Effect of solution heat treatment on the microstructure and mechanical properties of Inconel 625 superalloy fabricated by laser solid forming.Journal of Alloys and Compounds,767 [32] Residual stress and distortion of rectangular and S-shaped Ti-6Al-4V parts by Directed Energy Deposition: Modelling and experimental calibration.Additive Manufacturing,26 [1] 林鑫,鹿旭飞,马良,杨海欧,谭华,胡云龙.高能束增材制造有限元热力耦合模型的校验方法及其数据测量装置(CN201711124385.2), [2] 马良,鹿旭飞,林鑫.一种创建高精度增材制造有限元模型的方法(CN201810799158.8), [3] 马良,鹿旭飞,林鑫.基于激光立体成形自愈合效应的宏观热应力场有限元建模方法(CN201810482098.7), [4] 林鑫,鹿旭飞,马良.一种通过优化基板减小增材制造残余应力和非稳态的方法(CN201910054188.0),

学术成果

获奖信息 The winning information 获批2024年欧盟玛丽居里学者获批2023年西工大翱翔海外学者Metals期刊2022年最佳博士论文奖2022加泰罗尼亚理工大学优秀博士论文

综合介绍

团队信息 Team Information 隶属于“增材制造与创新设计”（林鑫、黄卫东教授）团队，团队建设有“国家级航宇材料结构一体化设计与增材制造装备技术国际联合研究中心”、“金属高性能增材制造与创新设计工业和信息化部重点实验室”，并与欧洲Airbus公司联合成立了“NPU-Airbus增材制造联合实验室”。团队长期专注于增材制造与创新设计、精确凝固理论与技术、以及材料加工过程的热-力-组织宏微观模型及模拟仿真方向的研究，已经发表增材制造相关学术论文500余篇，授权发明专利50余项，服务航空、航天、动力及能源等多个领域100余家单位，30余项国家重大重点型号任务，成果已在C919大飞机、“天问一号”火星探测器等“弹、箭、机、星”30余项重点重大型号获得应用，并转化孵化的3D打印企业“铂力特”首批登录科创板，市值位居全球同类企业首位。