李博




李 博


副教授 / 博导

智能制造工程系主任

增材制造与智能装备研究所所长

libo@ecust.edu.cn

上海市徐汇区梅陇路130号


  




工作经历教育背景:


1986年12月生,工学博士,中共党员。2014年6月博士毕业于南京航空航天大学、材料加工工程专业

2014年6月~2018年6月,上海市特种设备监督检验技术研究院、市特种设备事故调查中心,高级工程师。

2015年6月~2017年8月,金沙9001cc 以诚为本、动力工程及工程热物理专业,在职博士后

2018年6月至今,金沙9001cc 以诚为本金沙9001cc 以诚为本,副教授,智能制造工程系主任、上海高端装备可靠性技术协同创新中心副主任、上海市机械工程学会工业智能制造技术专委会副主任委员。

入选上海市东方英才、江苏省双创人才、上海市青年科技启明星计划,等。

 

研究方向

 

主要研究方向(招生方向):

(1)增材制造(3D打印)

(2)智能制造与智能装备

(3)结构完整性智能评价

  

欢迎机械、材料、智能制造专业背景学子加盟增材制造与智能装备团队攻读学位!

  

承担科研项目

国家自然科学基金面上项目“3D打印高熵合金多级构型强韧化设计与超低温抗侵彻机理”,2022-2025,主持

国家自然科学基金青年项目“搅拌摩擦修复/改性对铝合金深冷设备焊接结构完整性的影响机理”,2016-2018,主持

上海市“探索者”计划项目汽轮机叶片激光选区熔化增材制造的缺陷预测算法研究”,2024-2026,主持

上海市青年科技启明星人才计划项目“搅拌摩擦修复双金属复合板界面区缺陷愈合机理及结构完整性研究”,2016-2019,主持
上海市政府间国际科技合作项目“增材制造新一代核电装备部件蠕变-疲劳失效机理及结构完整性技术”,2019-2022,主持

上海市自然科学基金面上项目“激光增材制造构型复合化高熵合金形性调控机理”,2020-2023,主持
中国博士后科学基金特别资助项目“搅拌摩擦增材制造层状金属复材的界面行为及结构完整性”,2016-2017,主持
中国博士后科学基金面上一等资助项目“TC4钛合金搅拌摩擦加工表面合金化机理及性能”,2016-2017,主持
上海市质量技术监督局科技计划项目“应变强化不锈钢深冷容器相变量无损检测与力学性能评价方法”,2015-2017,主持 
航天科工集团“激光增材制造精密成型装备开发”,2018-2019,主持

中国联合重燃集团“先进重型燃机燃烧室复杂结构件构型技术研究”,2023-2024,课题负责

中国航发集团“航空发动机XXX增材制造技术”,2024-2026,课题负责

国防科工局民用航天项目“XXX异种材料XXX整体化增材制造技术”,2022-2024,子课题负责

国防项目“人工智能融合高性能激光增材制造XXX关键技术”,2021-2024,子课题负责

国家重点研发计划“超强韧中熵合金构件增材/强化/减材复合制造”—高性能中熵合金激光增材制造控形控性,2023-2025,子课题负责

国家重点研发计划“大尺寸氮化镓单晶制备用高温超高压反应釜设计制造技术”高性能特种镍基高温合金研制,2023-2025,子课题负责

国防项目“XXX激光增材制造控形控性”,2019-2024,子任务负责

国防项目“XXX电弧增材制造声学监测关键技术”,2019-2020,子任务负责

上海市科技支撑碳达峰碳中和专项“高效大功率碱性电解水制氢关键技术与装备研发”2021-2024,子课题负责

企业横向合作项目若干(包括:磁屏蔽等功能型部件、轻量化航空航天部件、多功能过程装备部件的3D打印,氢能源领域装置智能监测系统,高温功能涂层技术,特种设备失效分析,疲劳寿命预测,等)

教学育人

本科教学:
先后主讲材料力学》《金属先进成型技术》《增材制造原理》《增材制造(3D打印)技术赏析》《机械原理》《机械原理课程设计》《智能制造导论》《智能感知与信息处理》

研究生培养:
先后指导硕士研究生36人,博士研究生6人,多人次获国家研究生奖学金、上海市/校级优秀毕业生、优秀毕业论文。

代表性著作

学术论文(一作/通讯*):



高性能金属基结构增材制造/3D打印方向:

研究增材制造高性能合金及金属基复合材料的多尺度结构-强度-韧性-延性调控机制,探明严苛服役条件(高温、深冷、疲劳、冲击、腐蚀等)增材制造金属构件及材料的观动态演变机理,开发多材料一体化协同构筑、高精度微热源精密构筑、高合金化原位冶金构筑等增材制造新装备新方法,发展增材制造集成计算材料学,发掘适打印新型金属结构材料及应用。


Guoqing Huang, Tao Shen, Bo Li*. Microstructural evolution modeling and low-stress fatigue performance of bimodal-structured Al-Mg-Sc-Zr alloy produced by laser powder bed fusion additive manufacturing. Virtual and Physical Prototyping, 2024, 19: 2346287. (工程技术大类1区, IF: 10.2)

Yinan Chen, Bo Li*, Bo Chen*, Fuzhen Xuan. High-cycle fatigue induced twinning in CoCrFeNi high-entropy alloy processed by laser powder bed fusion additive manufacturing. Additive Manufacturing, 2023, 61: 103319. (工程技术大类1区, IF: 10.3)

Guoqing Huang, Bo Li*, Yinan Chen, Fuzhen Xuan. Nanotwining induced by tensile fatigue and dynamic impact of laser powder bed fusion additively manufactured CoCrFeNi high-entropy alloy. Journal of Materials Science and Technology, 2024, 183: 241-257. (材料科学大类1区, IF: 11.2)

Bo Li*, Wei Zhang, Wangqi Fu, Fuzhen Xuan*. Laser powder bed fusion (L-PBF) 3D printing thin overhang walls of permalloy for a modified honeycomb magnetic-shield structure. Thin-Walled Structures, 2023, 182:110185. (工程技术大类1区, IF: 5.7) 

Bo Li, Bo Qian, Yi Xu, Zhiyuan Liu, Jianrui Zhang, Fuzhen Xuan*. Additive manufacturing of ultrafine-grained austenitic stainless steel matrix composite via vanadium carbide reinforcement addition and selective laser melting: Formation mechanism and strengthening effect. Materials Science & Engineering A, 2019, 745: 495-508. (材料科学大类2区, IF: 6.1) 

Bo Li*, Lei Zhang, Yi Xu*, Zhiyuan Liu, Bo Qian, Fuzhen Xuan*. Selective laser melting of CoCrFeNiMn high entropy alloy powder modified with nano-TiN particles for additive manufacturing and strength enhancement: Process, particle behavior and effects. Powder Technology, 2020, 360: 509-521. (工程技术大类2区, IF: 4.5)

Bo Li*, Wei Zhang, Jianchao Shen, Fuzhen Xuan*. Micro-laminated CoCrFeMnNi−TiNp/CoCrFeMnNi high-entropy alloy matrix composite with bimodal grain structure via multi-material selective laser melting (MM-SLM) additive manufacturing. Composites Communications, 2022, 36: 101366. (材料科学大类2区, IF: 6.5) 

Bo Li*, Lei Zhang, Bin Yang. Grain refinement and localized amorphization of additively manufactured high-entropy alloy matrix composites reinforced by nano ceramic particles via selective-laser-melting/remelting. Composites Communications, 2020, 19: 56-60. (材料科学大类2区, IF: 6.5) 

Yajing Li, Hailong Dai*, Shuyao Zhang, Bo Li*, Yunran Ma, Chengyu Bao, Xu Chen, Fuzhen Xuan*.  The enhanced high-temperature oxidation resistance of additively manufactured GH4169 by adding small amounts of 304L. Journal of Materials Research and Technology, 2024, 30, 164-173. (材料科学大类2区, IF: 6.2)

Tao Shen, Bo Li*. An integrated computation framework for predicting mechanical performance of single-phase alloys manufactured using laser powder bed fusion: A case study of CoCrFeMnNi high-entropy alloy. Materials Today Communications, 2024, 39: 109180.

Bo Li*, Lei Zhang, Wangqi Fu, Haisheng Xu. General Investigations on Manufacturing Quality of Permalloy via Selective Laser Melting for 3D Printing of Customized Magnetic Shields. JOM, 2020, 72: 2834-2844.

Liming Yan, Bo Li*. A bimodal and heterogeneous laminate structure with alternately distributed copper-base and nickel-base alloys via multi-material laser powder bed fusion (MM-LPBF) additive manufacturing. Materials Letters, 2024, 137494.

Bo Li, Bo Qian*, Yi Xu, Zhiyuan Liu, Fuzhen Xuan*. Fine-structured CoCrFeNiMn high-entropy alloy matrix composite with 12 wt% TiN particle reinforcements via selective laser melting assisted additive manufacturing. Materials Letters, 2019, 252: 88-91.

Jianrui Zhang, Yabin Yan*, Bo Li*. Selective Laser Melting (SLM) Additively Manufactured CoCrFeNiMn High-Entropy Alloy: Process Optimization, Microscale Mechanical Mechanism, and High-Cycle Fatigue Behavior. Materials, 2022, 15: 8560. 

Jianrui Zhang, Bo Li*. The Influence of Laser Powder Bed Fusion (L-PBF) Process Parameters on 3D-Printed Quality and Stress–Strain Behavior of High-Entropy Alloy (HEA) Rod-Lattices. Metals, 2022, 12: 2109.



人工智能技术融合增材制造/3D打印方向:

推动大数据机器学习目标预测、图像识别与机器视觉、多模态信息融合等人工智能技术在增材制造3D/4D打印领域的深度融合,发展增材制造过程监测多模态信息融合及高价值隐性目标决策方法、增材制造材料及结构力学性能与服役寿命的机器学习预测、复杂3D几何构型智能设计、适打印新材料智能筛选、增材制造过程与材料的多尺度动态数字孪生体等技术及应用。


Tao Shen, Bo Li*, Jianrui Zhang, Fuzhen Xuan. Multi-source information fusion for enhanced in-process quality monitoring of laser powder bed fusion additive manufacturing. Additive Manufacturing, 2024, 104575. (工程技术大类1区, IF: 10.3)

Haijie Wang, Bo Li*, Liming Lei, Fuzhen Xuan*. Multi-physics information-integrated neural network for fatigue life prediction of additively manufactured Hastelloy X superalloy. Virtual and Physical Prototyping, 2024, 19: 2368652. (工程技术大类1区, IF: 10.2)

Haijie Wang, Bo Li*, Liming Lei*, Fuzhen Xuan. Uncertainty-aware fatigue-life prediction of additively manufactured Hastelloy X superalloy using a physics-informed probabilistic neural network. Reliability Engineering & System Safety, 2023, 109852. (工程技术大类1区, IF: 9.4)

Haijie Wang, Bo Li*, Saifan Zhang, Fuzhen Xuan. Traditional machine learning and deep learning for predicting melt-pool cross-sectional morphology of laser powder bed fusion additive manufacturing with thermographic monitoring. Journal of Intelligent Manufacturing, 2024. (工程技术大类2区, IF: 5.9)

Haijie Wang, Bo Li*, Fuzhen Xuan*. A dimensionally augmented and physics-informed machine learning for quality prediction of additively manufactured high-entropy alloy. Journal of Materials Processing Technology, 2022, 307: 117637. (材料科学大类2区, IF: 6.7) 

Haijie Wang, Bo Li*, Fuzhen Xuan*. Fatigue-life prediction of additively manufactured metals by continuous damage mechanics (CDM)-informed machine learning with sensitive features. International Journal of Fatigue, 2022, 164: 107147. (材料科学大类2区, IF: 5.7)

Liming Lei, Bo Li*, Haijie Wang, Guoqing Huang, Fuzhen Xuan. High-temperature high-cycle fatigue performance and machine learning-based fatigue life prediction of additively manufactured Hastelloy X. International Journal of Fatigue, 2023, 108012. (材料科学大类2区, IF: 5.7)

Haijie Wang, Bo Li*, Wei Zhang, Fuzhen Xuan. Microstructural feature-driven machine learning for predicting mechanical tensile strength of laser powder bed fusion (L-PBF) additively manufactured Ti6Al4V alloy. Engineering Fracture Mechanics, 2024, 295: 109788. (工程技术大类2区, IF: 4.7)

Haijie Wang, Bo Li*, Jianguo Gong, Fuzhen Xuan*. Machine learning-based fatigue life prediction of metal materials: Perspectives of physics-informed and data-driven hybrid methods. Engineering Fracture Mechanics, 2023, 284: 109242. (工程技术大类2区, IF: 4.7) 

Tao Shen, Wei Zhang, Bo Li*. Machine learning-enabled predictions of as-built relative density and high-cycle fatigue life of Ti6Al4V alloy additively manufactured by laser powder bed fusion. Materials Today Communications, 2023, 107286.

Haijie Wang, Saifan Zhang, Bo Li*. Machine learning-assisted acoustic emission monitoring for track formability prediction of laser powder bed fusion. Materials Today Communications, 2024, 38: 108522.

Tao Shen, Bo Li*. Digital twins in additive manufacturing: A state-of-the-art review. International Journal of Advanced Manufacturing Technology, 2024, 131: 63-92. 

Bo Li*, Wei Zhang, Fuzhen Xuan. Machine-learning prediction of selective-laser-melting additively manufactured part density by feature-dimension ascended Bayesian Network model for process optimization. International Journal of Advanced Manufacturing Technology, 2022, 121: 4023-4038. 

Haijie Wang, Bo Li*, Fuzhen Xuan*. Acoustic emission for in-situ process monitoring of selective laser melting additive manufacturing based on machine learning and improved variational modal decomposition. International Journal of Advanced Manufacturing Technology, 2022, 122: 2277-2292.

Qimin Wu, Haijie Wang, Bo Li*. Predicting the fatigue life of additively manufactured AlSi10Mg alloy using a physics-informed neural network incorporating continuous damage mechanics. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2024.

Haijie Wang, Jianrui Zhang*Bo Li*, Fuzhen Xuan. Machine learning-based fatigue life prediction of laser powder bed fusion additively manufactured Hastelloy X via nondestructively detected defects. International Journal of Structural Integrity2024.

张赛凡, 李博*, 轩福贞. 激光选区熔化过程声发射信号的降噪与分类预测方法. 机械工程学报, 2024, 60, 163-176.



功能与结构一体化增材制造/3D打印方向:

创制3D/4D打印构筑的力学超材料以及具有热/磁/传感/催化/能源等理化功能结构或器件,发展多类型3D/4D打印新装置新方法、混合增材制造(Hybrid 3D Printing)与多材料协同增材制造新理念、3D构筑过程原位复合化功能化新工艺,在混合柔性电子、新能源、换热器、微反应器、轻量化与结构功能一体化等方面应用。


Bo Li*, Shenghua Zhang, Lei Zhang, Yang Gao, Fuzhen Xuan*. Strain sensing behavior of FDM 3D printed carbon black filled TPU with periodic configurations and flexible substrates. Journal of Manufacturing Processes, 2022, 74: 283-295. (工程技术大类1区, IF: 6.1) 

Chuandong Li, Shuaishuai Yuan, Xinqi Yao, Xinhai Yu*, Bo Li*, Shan-Tung Tu. Structured nanoporous copper catalysts prepared by laser powder bed fusion and dealloying for on-board methanol steam reforming. Fuel, 2023, 347: 128367. (工程技术大类1区, IF: 6.7) 

Zhiyang Guo, Zhengyu Lian, Bo Li*, Fuzhen Xuan*. Scalable and adaptable tactile sensor array with island-bridge-form sensing units for multi-directional stimuli recognition. Measurement, 2024, 238: 115382. (工程技术大类2区, IF: 5.2)

Bo Li*, Wangqi Fu, Haisheng Xu, Bo Qian, Fuzhen Xuan*. Additively manufactured Ni-15Fe-5Mo Permalloy via selective laser melting and subsequent annealing for magnetic-shielding structures: Process, micro-structural and soft-magnetic characteristics. Journal of Magnetism and Magnetic Materials, 2020, 494: 165754. 

Bo Li*, Jianrui Zhang*, Tianxiang Deng, Facai Ren. Convertible Thermal Meta-Structures via Hybrid Manufacturing of Stereolithography Apparatus 3D Printing and Surface Metallization for Thermal Flow Manipulation. Polymers, 2023, 15: 174.

Bo Li*, Ciming Shen*. Solid stress-distribution-oriented design and topology optimization of 3D-printed heterogeneous lattice structures with light weight and high specific rigidity. Polymers, 2022, 14: 2807.

Bo Li*, Jiawei Shen, Hongyu Han, Jianrui Zhang*, Yang Gao*, Fuzhen Xuan. Design and 3D printing-assisted fabrication of microwave resonator-based passive wireless sensors for simultaneous measuring high temperatures and pressures. IEEE Sensors Journal, 2024. 

Bo Li*, Wen Liang, Lei Zhang, Facai Ren, Fuzhen Xuan*. TPU/CNTs flexible strain sensor with auxetic structure via a novel hybrid manufacturing process of fused deposition modeling 3D printing and ultrasonic cavitation-enabled treatment. Sensors and Actuators A: Physical, 2022, 340: 113526. 

Bo Li*, Wen Liang, Facai Ren. Electrohydrodynamic (EHD) inkjet printing flexible pressure sensors with a multilayer structure and periodically patterned Ag nanoparticles. Journal of Materials Science: Materials in Electronics, 2022, 33: 18734-18750. 

Bo Li*, Wen Liang, Facai Ren, Fuzhen Xuan. Structurally hierarchical flex-sensor of MWCNTs/TPU composite via mesh mould-based selective laser sintering (SLS) and ultrasonic cavitation-enabled treatment (UCT). Materials Letters, 2022, 324: 132764.

Cheng Qian, Ting Xiao, Yang Chen, Ning Wang*, Bo Li*, Yang Gao*. 3D Printed Reduced Graphene Oxide/Elastomer Resin Composite with Structural Modulated Sensitivity for Flexible Strain Sensor. Advanced Engineering Materials, 2021, 24: 117637.

Zhengji Zhong, Ciming Shen, Bo Li*. A non-uniform lattice design method for lightweight structuresin 3D printing. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2024.

Tianxiang Deng, Bo Li*, Fuzhen Xuan*. Additive manufactured thermal metamaterial devices for manipulating heat flow: Geometric configuration design and SLM-assisted fabrication. Engineering Research Express, 2021, 3: 025038.



搅拌摩擦增材制造方向:

基于搅拌摩擦焊原理,发展搅拌摩擦增材制造构筑与搅拌摩擦表面改性工艺及装置,开发异种金属多材料一体化搅拌摩擦增材制造工艺,研究搅拌摩擦温度场和粘塑性流场耦合作用下反复动态再结晶及原位合金化机制,设计优化多功能和高性能的搅拌摩擦加工区域空间堆叠,探明并调控新结构新材料的构-性关系,推动搅拌摩擦增材制造及搅拌摩擦再制造修复等工程应用。


李博, 沈以赴*. TC4钛合金表面搅拌摩擦加工制备Ti-Cu阻燃改性层. 中国有色金属学报, 2018(03): 7-17.

Bo Li*, Yifu Shen*, Lei Luo, Weiye Hu. Effects of processing variables and heat treatments on Al/Ti-6Al-4V interface microstructure of bimetal clad-plate fabricated via a novel route employing friction stir lap welding. Journal of Alloys & Compounds, 2016, 658: 904-913.

Bo Li, Yifu Shen*, Lei Luo, Weiye Hu. Fabrication and evaluation of Ti3Alp/Ti-6Al-4V surface layer via additive friction-stir processing. Materials & Manufacturing Processes, 2014, 29: 412-417.

Bo Li, Zhenhua Zhang, Yifu Shen*, Weiye Hu, Lei Luo. Dissimilar friction stir welding of Ti-6Al-4V alloy and aluminum alloy employing a modified butt joint configuration: Influences of process variables on the weld interfaces and tensile properties. Materials & Design, 2014, 53: 838-848. 

Bo Li, Yifu Shen*, Lei Luo, Weiye Hu. Fabrication of TiCp/Ti-6Al-4V surface composite via friction stir processing (FSP): Process optimization, particle dispersion-refinement behavior and hardening mechanism. Materials Science & Engineering A, 2013, 574: 75-85. 

Bo Li, Yifu Shen*, Weiye Hu, Lei Luo. Surface modification of Ti-6Al-4V alloy via friction-stir processing: Microstructure evolution and dry sliding wear performance. Surface & Coatings Technology, 2014, 239: 160-170.

Bo Li, Yifu Shen*, Weiye Hu. Surface nitriding on Ti-6Al-4V alloy via friction stir processing method under nitrogen atmosphere. Applied Surface Science, 2013, 274: 356-364.

Bo Li, Yifu Shen*, Lei Luo, Weiye Hu, Zhenhua Zhang. Surface aluminizing on Ti-6Al-4V alloy via a novel multi-pass friction-stir lap welding method: Preparation process, oxidation behavior and interlayer evolution. Materials & Design, 2013, 49: 647-656. 

Bo Li, Rundong Ding, Yifu Shen*, Yongzhi Hu, Yan Guo. Preparation of Ti-Cr and Ti-Cu flame-retardant coatings on Ti-6Al-4V using a high-energy mechanical alloying method: A preliminary research. Materials & Design, 2012, 35: 25-36.

Bo Li, Yifu Shen*. The investigation of abnormal particle-coarsening phenomena in friction stir repair weld of 2219-T6 aluminum alloy. Materials & Design, 2011, 32:3796-3802.

Bo Li, Yifu Shen*, Weiye Hu. The study on defects in aluminum 2219-T6 thick butt friction stir welds with the application of multiple non-destructive testing methods. Materials & Design, 2011, 32: 2073-2084.




专利/软件:

李博,宋智威,轩福贞,钱波. 一种用于SLM设备的粉末管理系统. CN202010076631.7

李博,黄国庆,轩福贞. 一种多材料SLM打印机粉末管理机械装置. CN202122160853.X

刘涑凡,李博,轩福贞,钱波. 一种用于大型SLM设备的工作台转移运输系统. CN202010076623.2

闫黎明,李博,轩福贞. 用于3D打印粗晶群微区-超细晶群微区排布的异质异构合金的方法与装置. CN202211042122.8

闫黎明,李博,轩福贞一种声发射信号监测成形悬垂结构零部件的方法与系统CN202410363726.5 

李博,韩宏宇,任发才,轩福贞. 用于无线温度监测的镀镍温度传感器贴片及其制备方法. CN202211574448.5

李博,梁雯,任发才,轩福贞. 一种纤维缠绕压力容器的在线损伤检测方法. CN202211575071.5

李博,宋智威,高阳,曲逸凡,马慧佳一种多喷头3D打印机CN202120599198.5

任发才,李博,轩福贞用于监测树脂基复合材料老化程度的无线柔性微波传感器CN202211621342.6

黄国庆,李博,任发才,轩福贞. 一种压力容器泄露感知报警系统. CN202223306095.9

宋智威,李博,轩福贞,钱波. 一种用于SLM设备的双成型缸装置及其铺粉系统. CN202010074410.6

黄国庆,李博,任发才,轩福贞. 一种新型材料抗冲击性能试验机. CN202223083086.8

沈以赴,张盛海,周小卫,李博. 激光熔深焊接的能量耦合自洽模型建立方法. CN102608918A
张盛海,沈以赴,周小卫,李博. 体压缩法控制等离子体的固定激光深熔焊接喷嘴及其控制方法. CN102601526A
沈以赴,高吉成,李博. 一种热塑性塑料搅拌摩擦焊接装置及焊接方法. CN103660282A
李博,汤晓英. 奥氏体不锈钢形变诱发马氏体检测设备. CN206177877U
李博. 一种分体式铣削针型搅拌装置. CN206335243U
李博. 一种用于板材的搅拌摩擦氮化试验装置. CN206143303U
李博. 一种用于搅拌摩擦加工表面改性搅拌区表面温度监测装置. CN206440384U
李博. 一种用于搅拌摩擦加工表面改性的气氛保护装置. CN206356728U
李博. 一种手持硬度仪. CN206339456U
李博,汤晓英,左延田. 一种手持探伤仪. CN206339534U
李博. 便携式手持化学成分检测仪. CN206339535U
王少军,孟乾,李博. 角接接头多功能试快. CN304975612S
王少军,李博. 便捷式磁粉探伤仪磁轭探头. CN304757091S
王少军,李博. 管道隧道沉降监测仪. CN304757090S
浦哲,李博. 一种加强型压力容器. CN208074156U
浦哲,李博. 一种压力管道组合支架. CN208074288U
王少军,孟乾,李博. 一种K型角接接头试快. CN207824255U
王少军,李博,孟乾. 一种穿越河流埋地金属管道防腐层检测装置. CN207689335U
王少军,李博,孟乾. 一种河川下埋地管道防腐层检测设备. CN207687690U
汤晓英,舒文华,罗晓明,左延田,李博,司俊,黄奕昶. 一种用于模拟受火试验的力学试验装置. CN207366351U
汤晓英,舒文华,左延田,李博,司俊,黄奕昶. 一种用于检测涂层或电镀层结合力的手持划痕仪. CN206440560U
司俊,舒文华,汤晓英,罗晓明,左延田,李博,黄奕昶. 一种用于模拟受火试验的火烧装置. CN206441448U
左延田,舒文华,汤晓英,罗晓明,李博,司俊,黄奕昶. 一种用于模拟受火试验的冲击试验装置. CN206440537U
舒文华,汤晓英,左延田,李博,司俊,黄奕昶. 一种用于模拟火候感度的测试装置. CN206096056U
舒文华,汤晓英,罗晓明,左延田,李博,司俊,黄奕昶. 一种用于模拟受火试验的腐蚀试验装置. CN206057155U

轩福贞,高阳,凌小峰,汪楠,鞠宽,李博,肖飚,舒文华,林泽昊,张颢出,梅志宇. 基于特征提取和神经网络的车辆随机载荷模式识别系统. CN113138005A

李博. 层状金属复材增材制造工艺数据库专家系统2019R0523673  

李博. 搅拌摩擦增材制造(3D打印)铣削加工复合工艺制造专家控制系统2019R0476922

李博. 搅拌摩擦修复工艺控制系统2019R0477143

李博, 王海杰, 沈涛. 激光增材制造疲劳性能集成计算软件. 2023SR1353421

李博, 王海杰, 沈涛. 激光增材制造疲劳寿命预测软件. 2024SR0178558

李博, 王海杰, 沈涛. 激光增材制造结构材料疲劳寿命智能预测软件2023SR1468499

李博闫黎明沈涛增材制造监测数据传输管控平台2024SR0841663

  

  

其他出版物/科技成果获奖情况:
编译《合于使用》(API579/ASME FFS中文版)上册、下册、工程案例集,中国质检出版社,2017年6月出版(负责译析第九章《ASSESSMENT OF CRACK-LIKE FLAWS裂纹型缺陷的评价》,审核第三、十二章和附录A、H)

撰写出版2015年度、2016年度、2017年度《警示录——上海市特种设备事故技术案例分析》

博士论文《基于搅拌摩擦焊技术的TC4钛合金表面改性研究》获江苏省百篇优秀博士学位论文奖(2015)

“同质异构与异质异构激光选区熔化增材制造及寿命预测关键技术”获2023年度中国发明协会“发明创新奖”排名1/6


 




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