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朴钟宇

姓名 朴钟宇
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学校 浙江工业大学
部门 机械工程学院
学位 博士
学历 机械工程学院
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个人简介         博士,机械工程学院副院长、教授、博士生导师、博士后合作导师,浙江省杰出青年科学基金获得者,入选浙江省“万人计划”青年拔尖人才、浙江省高校领军人才培养计划、浙江省高校中青年学科带头人、浙江省“新世纪151人才工程”。主要从事智能表面制造、服役状态感知、摩擦学与表面工程等方面研究。主持重点项目(区域联合)、面上项目、青年项目等国家基金4项;军委装备发展部装备预研重点项目、领域基金、重点项目/共性技术项目课题、军委科技委基础加强项目子课题等军工项目9项;浙江省杰出青年基金、浙江省万人计划项目等省部/厅局级项目11项第一/通讯作者发表SCI论文49篇,ESI热点论文1篇、ESI高被引论文3篇,参编专著3部、教材1部第一发明人授权国家发明专利29件,实施转化5件,单件专利最高转化金额30万获国家教学成果奖二等奖(R3)、浙江省教学成果奖一等奖(R2)、二等奖(R8)获浙江省自然科学奖三等奖(R1)、中国机械工程学会绿色制造科技奖二等奖(R1)、黑龙江省自然科学奖二等奖(R4)、国土资源科技奖二等奖(R7)担任《Surface Science and Technology 》编委、《中国表面工程》(EI检索)编委、《摩擦学学报》(EI检索)青年编委、《表面技术》(EI检索)青年编委、《材料保护》青年编委、《功能材料》青年编委担任机械工程学会高级会员、机械工程学会表面工程分会常务委员、机械工程学会环境保护与绿色制造技术分会委员、机械工程学会摩擦学分会摩擦设计专委会委员、机械工程学会材料分会青年工作委员会委员担任教育部学位中心评审专家、教育部高校科学研究发展中心评审专家、中国科协科普中国专家;国家、浙江省、北京市、重庆市、广东省、辽宁省、四川省科技计划项目/自然科学基金委通讯评议专家,河北省科技奖励评审专家担任Renewable & Sustainable Energy Reviews、Journal of Power Sources等70份国内外期刊的审稿专家【教育经历】2001年-2005年,燕山大学,机械设计及制造及其自动化,学士学位2005年-2011年,燕山大学,机械设计及理论,博士学位(再制造国家重点实验室,联合培养)【工作经历】2011年-2012年,水利部产品质量标准研究所,工程师2012年- 至今 ,浙江工业大学机械工程学院,讲师、副教授、教授、副院长2017年-2018年,美国卡内基梅隆大学工程学院,访问学者 科研项目 【主持项目-纵向】[1]国家自然科学基金区域创新联合基金重点项目,多场条件下的磁流变橡胶摩擦学行为智能调控研究[2]国家自然科学基金面上项目,声电耦合作用下塑性变形诱导热喷涂层强化机制及耐磨机理[3]国家自然科学基金面上项目,多场协同下铝合金表面复合多尺度结构构筑及腐蚀磨损行为[4]国家自然科学基金青年基金项目,裂纹尺度突变信息实时反馈的喷涂层疲劳磨损失效预警研究[5]浙江省自然科学基金杰出青年基金,复合能场表面制造技术及耐磨延寿机制[6]中央军委装备发展部装备预研共用技术领域基金项目快速支持项目(第二阶段),XXXXXXXXX[7]中央军委装备发展部装备预研领域基金项目,XXXXXXXXX[8]中央军委装备发展部装备预研项目(共性技术)课题,XXXXXXXXX[9]中央军委科技委基础加强项目子课题,XXXXXXXXX[10]中央军委科技委基础加强计划技术领域基金项目,XXXXXXXXX[11]中央军委装备发展部装备预研领域重点项目子课题,XXXXXXXXX[12]中央军委装备发展部装备预研领域基金项目分项,XXXXXXXXX[13]浙江省科技厅公益性项目,仪器化纳米压入金属样品低损伤抛光加工关键技术[14]浙江省高校基本业务费,重载齿轮表面跨尺度主动设计及多能场创成[15]流体动力与机电系统国家重点实验室开放基金,超精密加工表面晶态损伤表征及质量评价体系研究[16]特种装备制造与先进加工技术教育部/浙江省重点实验室开放研究基金,钢铁样品超精密加工表面测试分析体系研究[17]浙江省教育厅科研项目,纳米级表面对喷涂层疲劳磨损力-寿模型的影响研究【主持项目-横向】[1]企业委托项目,浙江工业大学-杭州圆方工程技术咨询有限公司联合研发中心 (500万)[2]企业委托项目,复杂柔性件智能精密加工系统[3]企业委托项目,腔镜下用止血粉末端创面喷射力测试方法及系统开发[4]企业委托项目,XXXXX轴承在役状态监测及力学性能演变检测 科研成果 【成果奖励】2022年,《机械工程学报》、《计算机集成制造系统》优秀审稿专家,1/12021年,黑龙江省自然科学奖二等奖,苛刻工况防护涂层的界面调控理论及演变机制,4/52021年,《机械工程学报》、《中国表面工程》优秀审稿专家,1/12020年,《机械工程学报》优秀审稿专家,1/12019年,国土资源科学技术奖二等奖,钻探机具关键部件表面工程技术及其工程化应用,7/102018年,中国机械工程学会绿色制造科学技术进步奖二等奖,节能环保型铝活塞设计、制造及产业示范,1/132013年,河北省优秀博士论文奖,1/12012年,燕山大学优秀博士学位论文,1/12010年,全国青年摩擦学学术会议优秀会议论文奖,1/12008年,Proceeding of 4th World Congress on Maintenance优秀会议论文,1/1【代表性学术论文】(*为通讯作者)【2024】[49]Piao Zhong-yu, Wei Chao-tang, Yuan Zhi-peng, Zhang Jian, Xu Min, Zhou Zhen-yu*. Research on online identification of surface burnishing tool machining conditions by spindle current signal analysis. Tribology International. 2024. 195: 109575.[48]Zhou Zhen-yu, Jiang Zhi-guo, Zheng Qiu-yang, Li Yu, Yuan Zhi-peng, Ding Cong, Piao Zhong-yu*. Research on the construction of gradient nanostructure and anti-tribocorrosion behavior of aluminum alloy surface. Tribology International. 2024. 194: 109448.[47]Ding Cong, Qiao Zhi-zhao, Feng Shi-qing, Zhou Zhen-yu, Piao Zhong-yu*. Friction and wear performances of 7075 aluminum alloy surface with V-shaped microtexture via numerical simulation and experimental characterizations. Industrial Lubrication and Tribology. 2024. Accepted【2023年】[46]Zheng Qiu-yang, Zhou Zhen-yu, Li Yu, Chen Jian-hao, Ye Sen-bin, Piao Zhong-yu*. Molecular dynamic simulation of the influence of vibration effects on scratching processes in Varied crystal orientations. Modelling and Simulation in Materials Science and Engineering. 2023. Accepted[45]Feng Shi-qing, Ding Cong*, Qiao Zhi-zhao, Yuan Zhi-peng, Zhou Zhen-yu, Hou Wen-tao, Piao Zhong-yu*. Correlation between vibration signal and surface quality based on recurrence analysis during surface burnishing process. Mechanical Systems and Signal Processing. 2023. 200:110654[44]Ding Cong, Feng Shi-qing, Qiao Zhi-zhao, Zhu Hua, Zhou Zhen-yu, Piao Zhong-yu*. Experimental prediction model for the running-in state of a friction system based on chaotic characteristics and BP neural network. Tribology International. 2023. 188:108846[43]Zhou Zhen-yu, Zheng Qiu-yang, Li Yu, Jiang Zhi-guo, Yuan Zhi-peng, Piao Zhong-yu*.Effect of ultrasonic vibration on the deformation through indentation test and molecular dynamics simulation. Mechanics of Materials. 2023. 184:104744[42]Zhou Zhen-yu, Zheng Qiu-yang, Li Yu, Jiang Zhi-guo, Yuan Zhi-peng, Yan Ju-yu, Piao Zhong-yu*. Influence of surface burnishing process with single strain path and reciprocating strain path on copper wear behavior. Wear. 2023. 530:205022[41]Zhou Zhen-yu, Zheng Qiu-yang, Li Yu, Ding Cong, Peng Guang-jian*, Piao Zhong-yu*. Research on the mechanism of the two-dimensional ultrasonic surface burnishing process to enhance the wear resistance for aluminum alloy. Friction. 2023. DOI: 10.1007/s40544-023-0777-z.[40]Ding Cong, Feng Shi-qing, Qiao Zhi-zhao, Zhou Zhen-yu, Piao Zhong-yu*. Running-in performance of 7075 aluminum alloy strengthened by burnishing technology. Journal of Mechanical Science and Technology. 2023. 37(5):2545-2553[39]Hou Wen-tao, Xu Wei-wei, Zhou Zhen-yu, Ding Cong, Piao Zhong-yu*. Study of the effect of ultrasonic vibration on nickel-based coating by electrical discharge machining. Journal of Materials Engineering and Performance. 2023. 32(20):9418-9427[38]Yuan Zhi-peng, Zhou Zhen-yu, Jiang Zhi-guo,Zhao Ze-yu, Ding Cong*, Piao Zhong-yu*. Evaluation on Surface Roughness of Aluminum Alloy in Burnishing Process Based on Chaos theory. Chinese Journal of Mechanical Engineering. 2023. 36(1):2【2022年】[37]Li Yu, Zheng Qiu-yang, Zhou Zhen-yu, Ding Cong, Ye Sen-bin, Piao Zhong-yu*. Molecular dynamics study on the effect of electric current on electrically-assisted scratching for crystal copper. Physica Scripta. 2022. 97(11):115401[36]Hou Wen-tao, Ding Yu-quan, Huang Guo-qiang, Nazmul Huda, Luqman Hakim Ahmad Shah, Piao Zhong-yu*, Shen Yi-fu*, Shen Zhi-kai, Adrian Gerlich. The role of pin eccentricity in friction stir welding of Al‑Mg‑Si alloy sheets: microstructural evolution and mechanical properties. International Journal of Advanced Manufacturing Technology. 2022. 121:7661-7675 ESI高被引论文[35]Peng Guang-jian, Hu Yahao, Dou Guijing, Sun Yiheng, Huan Yong, Kang Sung Hoon*, Piao Zhong-yu*. Enhanced mechanical properties of epoxy composites embedded with MF/TiO2 hybrid shell microcapsules containing n-octadecane. Journal of Industrial and Engineering Chemistry. 2022. 110:414-423[34]Zheng Qiu-yang, Zhou Zhen-yu, Ding cong, Li Yu, Lin En, Ye Sen-bin*, Piao Zhong-yu*. Mechanical response of single-crystal copper under vibration excitation based on molecular dynamics simulation. Journal of Manufacturing Processes. 2022. 75:605-616[33]Ding Cong, Zhou Zhen-yu, Piao Zhong-yu*, Mao Peng-zhan*. Influence of the ultrasonic vibration on system dynamic responses in the multi-ball surface burnishing process. Journal of Manufacturing Science and Engineering-Transactions of the ASME. 2022. 144: 051002【2021年】[32]Zhou Zhen-yu, Zheng Qiu-yang, Ding Cong, Yan Ju-yu, Piao Zhong-yu*. Effect of surface burnishing process with different strain paths on the copper microstructure. Journal of Manufacturing Processes. 2021, 71: 653-668[31]Zhou Zhen-yu, Zheng Qiu-yang, Ding Cong, Yan Ju-yu, Peng Guang-jian, Piao Zhong-yu*. Research on the promotion mechanism of surface burnishing process by two-dimensional ultrasonic vibration. Journal of Materials Research and Technology. 2021, 13:1068-1082[30]Zhou Zhen-yu, Zheng Qiu-yang, Ding Cong, Yan Ju-yu, Piao Zhong-yu*. A review of the development of surface burnishing process technique based on bibliometric analysis and visualization. International Journal of Advanced Manufacturing Technology. 2021, 116(5-6):1955-1999[29]Chen Jian-hao, Zheng Qiu-yang, Zhou Zhen-yu, Ding Cong, Piao Zhong-yu*. Molecular dynamics simulation of monocrystalline copper nano-scratch process under the excitation of ultrasonic vibration. Materials Research Express. 2021, 8(4): 046507 [28]Ding Cong, Zhou Zhen-yu, Piao Zhong-yu*. Investigation of the running-in quality at different rotating-speeds by chaos theory. International Journal of Bifurcation and chaos. 2021, 31(7):2150108[27]Zhou Zhen-yu, Zheng Qiu-yang, Ding Cong, Yu Guang-lei, Peng Guang-jian, Piao Zhong-yu*. Investigation of Two-Dimensional Ultrasonic Surface Burnishing Process on 7075-T6 Aluminum. Chinese Journal of Mechanical Engineering. 2021, 34:19[26]Ding Cong, Sun Guo-dong, Zhou Zhen-yu, Piao Zhong-yu*. Investigation of the optimum surface roughness of AISI 5120 steel by using a running-in attractor. Journal of Tribology-Transactions of the ASME.2021, 143(9): 094501.【2020年】[25]Zhou Zhen-yu, Yu Guang-lei, Zheng Qiu-yang, Ma Guo-zheng, Ye Sen-bin, Ding Cong, Piao Zhong-yu*. Wear behavior of 7075-aluminum after ultrasonic-assisted surface burnishing. Journal of Manufacturing Processes. 2020. 51:1-9 ESI高被引论文[24]Tang Wei-chen, Piao Zhong-yu*, Zhang Jiang*, Liu Shi-ying, Deng Li-jun. Effect of trace elements on the pinhole fatigue-resistance of gasoline Al-Si piston alloy. Engineering Failure Analysis. 2020. 108:104430[23]Piao Zhong-yu, Wang Hai-dou, Xu Bin-shi, Yu Xiao-xiao. Rolling Contact Fatigue Behavior of Thermal-Sprayed Coating: A Review. Critical Reviews in Solid State and Materials Sciences. 2020. 45(6):429-456[22]Ding Cong, Zhou Zhen-yu, Yuan Zhi-peng, Zhu Hua, Piao Zhong-yu*. Study on the correlation between the running-in attractor and the wear particle group. Industrial Lubrication and Tribology. 2020.72(5):681-686【2019年及之前】[21]Piao Zhong-yu*, Zhou Zhen-yu, Xu Jia, Wang Hai-dou. Use of X-ray computed tomography to investigate rolling contact cracks in plasma sprayed Fe–Cr–B–Si coating. Tribology Letters. 2019. 67 (1) 11 ESI热点论文、ESI高被引论文[20]Piao Zhong-yu, Wen Dong-hui*, Yin Lin-zhi, Zhao Meng-meng. Ultra-smooth Cu surface fabricated by hydrodynamic suspension polishing technique. Precision Engineering. 2019. 57:189-194  [19]Zhang Jian, Piao Zhong-yu*, Liu Shi-ying, Su Sheng-wei, Deng Li-jun. Investigation of wear behavior of graphite coating on aluminum piston skirt of automobile engine. Engineering Failure Analysis. 2019. 97:408-415 [18]Wen Dong-hui, Yin Lin-zhi, Piao Zhong-yu*, Lu Cong-da, Li Gang, Leng Qiao-hui. Performance investigation of proton exchange membrane fuel cell with intersectant flow field. International Journal of Heat and Mass Transfer. 2018.121:775-787[17]Zhang Jian, Piao Zhong-yu*, Deng Li-jun, Zhang Sen, Liu Jing. Influence of pin assembly on the wear behavior of piston skirt. Engineering Failure Analysis. 2018. 89:28-36[16]Zhang Jian, Piao Zhong-yu*, Liu Shi-ying. Influence of skirt profile structure of gasoline engine piston on the friction and wear characteristics under standard conditions.Journal of Tribology-Transactions of the ASME. 2018. 140: 021703-11.[15]Wen Dong-hui, Yin Lin-zhi, Piao Zhong-yu*, Lu Cong-da, Li Gang, Leng Qiao-hui. A novel intersectant flow field of metal bipolar plate for proton exchange membrane fuel cell. International Journal of Energy Research. 2017. 41:2184-2193 [14]Piao Zhong-yu*, Xu Jia, Yin Lin-zhi, Wen Dong-hui, Xu Bin-shi, Wang Hai-dou. Surface integrity design of plasma sprayed coating for resisting contact fatigue. Materials Chemistry and Physics. 2016. 179:174-181[13]Wen Dong-hui, Piao Zhong-yu*, Zhang Tai-hua. A hydrodynamic suspension polishing method for ultrasmooth and low-damage surface. Precision Engineering. 2016. 46:278-287[12]Xu Jia, Zhou Zhen-yu, Piao Zhong-yu*. Accumulated damage process of thermal sprayed coating under rolling contact by acoustic emission technique. Frontiers of Mechanical Engineering. 2016, 11(3): 227–232[11]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Wen Dong-hui. Investigation of RCF failure prewarning of Fe-based coating by online monitoring. Tribology International. 2014.72:156-160 [10]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Wen Dong-hui. Influence of surface nitriding treatment on rolling contact behavior of Fe-based plasma sprayed coating. Applied Surface Science. 2013. 266:420-425[9]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Wen Dong-hui. Investigation of acoustic emission source of Fe-based sprayed coating under rolling contact.International Journal of Fatigue. 2013.47:184-188[8]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Wen Dong-hui. Influence of surface roughness on rolling contact fatigue behavior of Fe-Cr alloy coatings. Journal of Materials Engineering and Performance. 2013. 22:767-773[7]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Wen Dong-hui. Characterization of Fe-based alloy coating deposited by supersonic plasma spraying. Fusion Engineering and Design. 2013. 88(11):2933-2938[6]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou. Investigation of spalling mechanism of the thermal sprayed coating under rolling contact by FIB-SEM. Engineering Failure Analysis. 2012. 25: 106-111[5]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Pu Chun-huan. Investigation of fatigue failure prediction of Fe-Cr alloy coatings under rolling contact based on acoustic emission technique. Applied Surface Science. 2011. 257(7): 2581-2586[4]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Pu Chun-huan. A separation of experimental study on coatings failure signal responses under rolling contact. Tribology International. 2011. 44:1304-1308[3]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Pu Chun-huan. Investigation of rolling contact fatigue lives of Fe-Cr alloy coatings under different loading conditions. Surface & Coatings Technology. 2010. 204(9-10):1405-1411[2]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Pu Chun-huan. Influence of undercoating on rolling contact fatigue performance of Fe-based coating. Tribology International. 2010. 43(1-2):252-258[1]Piao Zhong-yu*, Xu Bin-shi, Wang Hai-dou, Pu Chun-huan. Effects of thickness and elastic modulus on stress condition fatigue-resistant coating under rolling contact. Journal of Central South University of Technology. 2010. 17(5): 899-905【授权发明专利】[29]朴钟宇, 余光磊, 郑秋阳, 周仁泽, 周振宇. 柔性电极电火花沉积复合滚压加工刀具. 2023.9.12, 中国, 国家发明专利, 专利号:ZL2017 1 1416261.1[28]朴钟宇, 周振宇, 余光磊, 郑秋阳,周仁泽. 爪式柔性超声弧面滚压刀具. 2023.7.21, 中国, 国家发明专利, 专利号: ZL 2019 1 0101730.3[27]朴钟宇, 周振宇, 郑秋阳, 余光磊, 周仁泽. 双重弹性元件弧面滚压刀具. 2023.7.21, 中国, 国家发明专利, 专利号: ZL 2019 1 0101724.8[26]朴钟宇, 郑秋阳, 周振宇, 严飓煜, 陈健豪, 余光磊, 丁丛, 张丽慧, 叶森斌. 制备高通量薄膜的磁控溅射装置及其制备高通量薄膜的制备方法. 2023.6.27, 中国, 国家发明专利, 专利号: ZL 2019 1 1313706.2[25]朴钟宇, 周振宇, 郑秋阳, 余光磊, 周仁泽. 电致塑性效应辅助滚压刀具. 2023.6.27, 中国, 国家发明专利, 专利号: ZL 2019 1 0101752.X[24]朴钟宇, 严飓煜, 陈健豪, 周振宇, 郑秋阳, 余光磊, 丁丛, 张丽慧, 叶森斌. 回转件内壁电火花沉积设备. 2023.6.27, 中国, 国家发明专利, 专利号: ZL 2019 1 1313802.7[23]朴钟宇, 周振宇, 郑秋阳, 余光磊, 周仁泽. 柔性传动超声齿面滚压刀具. 2023.6.27, 中国, 国家发明专利, 专利号: ZL 2019 1 0101757.2[22]朴钟宇, 周振宇, 余光磊, 郑秋阳, 周仁泽. 液压驱动稳压齿轮齿面滚压刀具. 2023.6.27, 中国, 国家发明专利, 专利号: ZL 2019 1 0101756.8[21]朴钟宇, 赵泽宇, 彭光健, 丁丛, 侯文涛, 叶森斌, 周振宇. 一种电脉冲辅助滚压加工平台. 2023.5.30, 中国, 国家发明专利, 专利号: ZL 2022 1 0261884.0[20]朴钟宇,赵泽宇, 姜治国, 彭光健, 丁丛, 侯文涛, 叶森斌. 一种旋转换刀柔性滚压刀具. 2023.4.25, 中国, 国家发明专利, 专利号:ZL 2022 1 0205990.7[19]朴钟宇, 周振宇, 郑秋阳, 周仁泽, 余光磊. 一种表面梯度薄膜的制备方法. 2020.8.18, 中国, 国家发明专利, 专利号: ZL201711416464.0[18]朴钟宇,周振宇,徐佳. 一种电极位置可调的电火花沉积滚压刀具. 2018.11. 中国, 国家发明专利. 专利号: ZL201611166961.5[17]朴钟宇,周振宇,徐佳. 一种滚压力可测的柔性电火花沉积滚压刀具. 2018.09, 中国,国家发明专利. 专利号: ZL201611166978.0[16]朴钟宇,周振宇,徐佳,文东辉. 滚压加工力热测试平台. 2018.09, 中国, 国家发明专利. 专利号: ZL201610665555.7[15]朴钟宇,徐佳,周振宇.一种压力可测的柔性平面滚压刀具. 2018.09, 中国, 国家发明专利. 专利号:ZL201611167002.5[14]朴钟宇,徐佳,周振宇,郑波,赵朦朦.一种滚压力及刀具转速可变的平面滚压刀具. 2018.07, 中国, 国家发明专利. 专利号:ZL201510682658.X[13]朴钟宇,周振宇,郑波,赵朦朦,徐佳.一种给予恒定滚压力的平面滚压刀具. 2018.07, 中国, 国家发明专利. 专利号:ZL201510693107.3[12]朴钟宇,周振宇,徐佳.一种滚压力可调节的刚性平面滚压刀具. 2018.7, 中国, 国家发明专利. 专利号:ZL201611167001.0[11]朴钟宇, 赵朦朦, 周振宇, 徐佳, 郑波. 一种铣滚一体刀具. 2018.06, 中国, 国家发明专利, 专利号:ZL201510693100.1[10]朴钟宇,周振宇,郑波,赵朦朦,徐佳.一种给予电磁加热的平面滚压刀具. 2018.06 中国, 国家发明专利. 专利号:ZL201510692925.1[9]朴钟宇,徐佳,周振宇,郑波,赵朦朦.一种利用真空抽气进行润滑的平面滚压刀具. 2018.06, 中国, 国家发明专利. 专利号:ZL201510693111.X[8]朴钟宇,徐佳,周振宇.一种具有电火花沉积功能的柔性平面滚压刀具. 2018.6, 中国, 国家发明专利. 专利号:ZL201611168448.X[7]朴钟宇,赵朦朦,周振宇,徐佳,郑波.一种通过气缸进行恒力加压的平面滚压刀具. 2018.02, 中国, 国家发明专利. 专利号:ZL201510693131.7[6]朴钟宇, 徐佳, 周振宇, 文东辉. 超声滚压表面纳米化加工装置. 2018.2, 中国, 国家发明专利, 专利号:ZL201610666709.4[5]朴钟宇,周振宇,郑波,赵朦朦,徐佳.一种给予恒距离滚压的平面滚压刀具. 2018.01, 中国, 国家发明专利. 专利号:ZL201510692924.7[4]朴钟宇, 徐佳, 周振宇, 郑波, 赵朦朦. 一种带有锥形无刷电机的平面滚压刀具. 2017.11, 中国, 国家发明专利, 专利号:ZL201510692963.7[3]朴钟宇, 赵朦朦, 尹林志, 徐佳, 文东辉. 一种改进的平面滚压方法及装置. 2017.10, 中国, 国家发明专利, 专利号:ZL201510507073.4[2]朴钟宇, 徐钉, 文东辉. 一种动压浮离抛光方法. 2015.09, 中国, 国家发明专利. 专利号: ZL201310244152.1[1]朴钟宇, 徐钉, 文东辉. 一种动压浮离抛光装置. 2015.08, 中国, 国家发明专利. 专利号: ZL201310244168.2 学术兼职 [1] 机械工程学会表面工程分会青年学组副主任委员[2] 《中国表面工程》编委[3] 机械工程学会摩擦学分会摩擦设计专委会委员[4] 机械工程学会表面工程分会第一、二届青年工作委员会委员[5] 机械工程学会材料分会青年工作委员会委员[6] 机械工程学会高级会员[7] 教育部学位中心评审专家[8] 国家、浙江、北京、重庆、广东、辽宁自然科学基金/科技计划项目通讯评议专家[9] 河北省科技奖励评审专家库成员[10]担任Renewable & Sustainable Energy Reviews、Journal of Power Sources等46份国内外期刊审稿专家 教学与课程 【本科生生课程】《工程图学》(国家一流本科课程)《创新设计》(浙江省一流本科课程)《工程与人文》【研究生课程】《论文写作指导》 育人成果 【育人成果】2021年,面向区域先进制造产业集群的机械类硕士协同创新培养探索与实践—十五年总结,浙江省教学成果奖一等奖,2/102021年,“四融合四转变”机械类创新人才培养模式探索与实践,浙江省教学成果奖二等奖,8/102021年,基于区域产业协同创新的机械类硕士研究生培养探索与实践,浙江工业大学教学成果奖特等奖,2/102021年,“四融合四转变”机械类创新人才培养模式探索与实践,浙江工业大学教学成果奖特等奖,8/102020年,第六届中国国际“互联网+”大学生创新创业大赛金奖,指导教师,4/102014年,第六届全国大学生机械创新设计大赛一等奖,指导教师,2/2

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