郝兆朋

个人信息Personal Information

教授

博士生导师

硕士生导师

教师拼音名称:haozhaopeng

电子邮箱:

入职时间:2013-12-30

所在单位:长春工业大学

职务:院长

学历:博士研究生毕业

性别:男

联系方式:0431-85716615

学位:工学博士学位

在职信息:在职

毕业院校:哈尔滨工业大学

学科:机械制造及其自动化

个人简介Personal Profile

郝兆朋,工学博士,教授,博士生导师,机电工程学院 院长。

吉林省杰出青年基金获得者、吉林省优秀创新创业人才、吉林省青年科技奖获得者、吉林省突出贡献专业技术人才、吉林省拔尖创新人才、长春工业大学优秀青年学者,科研团队负责人、IAAM fellow

担任《材料导报》青年编委,中国机械工业金属切削刀具技术协会切削先进技术研究分会全国理事、切削与先进技术研究会(东北区)理事;J. Manufacturing ProcessesJ. Advanced Manufacturing and Technology, J. Alloy and Compounds, 航空制造技术等10余个国内外知名期刊审稿专家。

一、课题组研究方向及简介

Ø  研究方向

难加工材料高效、精密、洁净切削理论与技术;高效刀具开发;特种加工等方面

研究工作能紧密联系生产实际,探索符合吉林省航空装备制造、维修特色产业体系的研究目标和方向,发挥团队优势,注重学科的融合与攻关解决实际问题,并把基础研究和推广应用紧密结合,科研成绩显著,在难加工材料切削机理、刀具磨损机制与控制、绿色切削技术和工艺优化理论和方法等方面,取得了阶段性研究成果,关键技术有所突破。相关科研成果已在中国一汽车桥分公司、哈尔滨汽轮机厂、吉林省东元精密机械有限公司应用。发表学术论文80余篇,其中发表IJMTMIJMSJMPTASME汇刊PE等领域国际权威期刊SCI论文60余篇,EI论文5篇,授权专利10余件。

形成的相关切削理论与技术,获国际学术奖2021年度“IAAM medal”奖杰出青年科学家奖章1项,吉林省自然科学奖二等奖1项(第一完成人),吉林省自然科学学术成果二等奖1项(通讯作者),并参与获得省部级奖励2项。获中国力学学会与中国航空学会颁发的数字仿真科技奖“青年科技奖”称号,吉林省拔尖创新人才(第三层次)等。目前,任中国机械工业金属切削技术协会第十届全国理事(2019),国际先进材料学会高级会员(MIAAM2022)。

Ø 团队成员:郝兆朋教授、范依航教授、孔令昊博士

课题组目前共32人,包括在读博士6人,在读硕士23人。已毕业博士1人、已毕业硕士40人。

Ø 招生信息:

课题组每年招收2-3名博士,10-12名硕士(机械工程、智能制造及相近专业的学硕与专硕)

二、 科研项目

1. 吉林省杰出青年基金:声电耦合辅助切削镍基高温合金切削机理研究,2024,项目负责人

    2. 国家自然科学基金(面上):脉冲电流协同超声振动辅助切削镍基高温合金切削机理与工艺基础研究,2023,项目负责人

3. 国家自然科学基金(青年):基于镍基高温合金 微观结构变形特征的薄壁件低应力切削机理,2015,项目负责人

4. 吉林省重点科技攻关:镍基高温合金高效 、高质量车削加工 装置及关键技术研究,2015,项目负责人

5. 吉林省重点科技攻关:高速切削镍基合金加工表面形成机理与工艺技术,2021,项目负责人

6. 吉林省自然科学基金:切削镍基高温合金GH4169 微观结构变形机理与精密加工技术,2016,项目负责人

7.吉林省自然科学基金:高速切削镍基高温合金接触界面状态演化与刀具磨损机理,2020,项目负责人

8. 长春市重点研发计划:基于高温合金切削机理的高效、高质切削工艺开发与应用,2021,项目负责人

   9. 吉林省教育厅重点项目:镍基高温合金切削变形机理的研究,2017,项目负责人

10.国家自然科学基金:切削镍基高温合金的刀-屑界面形膜机制及刀具抗磨损机理研究,2016,主要参与人

   11.国家自然科学基金(面上):镍基高温合金振动辅助切削接触状态下加工表面形、性演变机理,2024,主要参与人

10. 国家自然科学基金-联合基金项目:热弹激励-超声冲 击耦合切削颗粒增强金属基复合材料新原理与新方法,2020,主要参与人

  代表性学术论文

[1]   作者. Study of cutting deformation in machining nickel-based alloy Inconel718. International Journal of Machine Tools & Manufacture, 2011, 51: 520-527. (Q1)

[2]   第一作者. New observations on tool wear mechanism in dry machining Inconel718. International Journal of Machine Tools & Manufacture, 2011, 51: 973-979,2011  (Q1)

[3] 作者. New observations on tool wear mechanism in machining Inconel 718 under water vapor cooling lubrication cutting conditions. Journal of Cleaner Production, 2015, 90: 381-387. (Q1)

[4]   第一作者. Diffusion mechanism of tools and simulation in nanoscale cutting the Ni-Fe-Cr series of Nickel-based superalloy. International Journal of Mechanical Sciences. 2019,150:625-636. (Q1)

[5]  通迅作者. Cutting deformation mechanism of SiCp/Al composites based on strain gradient theory. Journal of Materials Processing technology. 2022,299:117345. (Q1)

[6]第一作者.Dynamic Plastic Evolution Mechianism in Cutting Zone of Nickel-based Superalloy GH4169. Journal of Materials Processing technology,2023,313:117858.(Q1)

[7]Mechanical response of nanoindentation and material strengthening mechanism of nt-cBN based on molecular dynamics. International Journal of Refractory Metals and Hard Materials, 2022, 106: 105844.(Q1)

[8]第一作者:Theoretical calculation and analysis of new rare earth cemented carbide based on first-principles. International Journal of Refractory Metals and Hard Materials,2021, 101: 105688 .(Q1)

[9]第一作者. Research on tool stick-slip erosion wear mechanism in cutting nickel-based alloy GH4169. Tribology International 188 (2023) 108803.(Q1)

[10]第一作者. Cutting performance of the nanotwinned cBN tool in nano-cutting of Ni-Cr-Fe alloy. Journal of Manufacturing Processes 95 (2023) 521–534. (Q2)

[11]第一作者. Research on the dynamic plasticity mechanism of additive manufactured nickel–chromium–molybdenum corrosion-resistant alloy steel under impact load. Engineering Failure Analysis 152 (2023) 107503.(Q1)

[12]通讯作者. Effect of pulsed current on plastic deformation of Inconel 718 under high strain rate and high temperature conditions ,Journal of Alloys and Compounds,2023,943:169150.(Q1)

[13] 第一作者. Cutting parameters optimization based on optimal cutting temperature in machining Inconel718. Materials and Manufacturing Processes, 2012, 27: 1084-1089. (Q2)

[14] 第一作者. Flow characteristics and constitutive equations of flow stress in high speed cutting Alloy 718. Journal of Alloys and Compounds. 2017, 728: 854-862. (Q1)

[15]  第一作者.  New observations on wear mechanism of self-reinforced SiAlON ceramic tool in milling of Inconel 718. Archives of Civil and Mechanical Engineering, 2017,17(3): 467-474. (Q1)

[16]   作者. Materials response in tool-chip interface and its effects on tool wear in turning Inconel718. Materials and Manufacturing Processes, 2014, 29: 1446-1452.  (Q2)

[17] 第一作者.Study on constitutive model and deformation mechanism in high speed cutting Inconel718. Archives of Civil and Mechanical Engineering, 2019, 19439-452. (Q1)

[18] 作者. Surface residual stress in high speed cutting of superalloy Inconel718 based on multiscale simulation. Journal of Manufacturing Processes, 2018, 31: 480-493(Q2)

[19] 作者. Research on tool wear based on multi-scale simulation in high speed cutting Inconel718. Archives of Civil and Mechanical Engineering, 2018, 18(3): 928-940. (Q1)

[20] 第一作者. Failure feature and characterization of material of shear band in cutting Inconel718, Journal of Manufacturing Processes, 2019, 45:154-165.(Q2)

[21] 作者. Work hardening mechanism based on molecular dynamics simulation in cutting Ni-Fe-Cr series of Ni-based alloy. Journal of Alloys and Compounds,2020,819:1-8. (Q1)

[22] 第一作者.First-principles calculations of a new half-metallic Heusler alloy FeCrAs. Journal of Alloys and Compounds,2020,820:153118. (Q1)

[23] 第一作者.Influence of anisotropy of nickel-based single crystal superalloy in atomic and close-to-atomic scale cutting. Precision Engineering,2020,66:347-362 (Q2)

[24] 第一作者. Study on staged work hardening mechanism of nickel-based single crystal alloy during atomic and close-to-atomic scale cutting. Precision Engineering,2021,68:35-56 . (Q2)

[25] 第一作者.Study on the evolution mechanism of subsurface defects in Nickel-based single crystal alloy during atomic and close-to-atomic scale cutting. Journal of Manufacturing Processes202168:14-33. (Q2)

[26] 第一作者. Theoretical calculation and analysis of new rare earth cemented carbide based on First-principles. International Journal of Refractory Metals and Hard Materials,2021, 101 : 105688.(Q1)

[27] 第一作者. Research on Deformation Mechanism of Cutting Nickel-Based Superalloy Inconel718 Based on Strain Gradient Theory. Journal of Manufacturing Science and Engineering -Transactions of The ASME. 2021,143(10): 101007 .(Q2)

[28] 第一作者.  Wear characteristics and wear control method of carbide tool in turning Inconel 718. International Journal of Advanced Manufacturing Technology, 2015, 78: 1329-1336.  (Q2)

[29] 第一作者. Formation mechanism and characterization of shear band in high-speed cutting Inconel718.International Journal of Advanced Manufacturing Technology, 2018, 98: 2791-2799. (Q2)

[30] 作者. Research of plastic behavior in cutting Inconel718based on multi-scale simulation. International Journal of Advanced Manufacturing Technology, 2018,9 4:3731-3739. (Q2)

[31] 第一作者. A new method based on center theory to reveal the ferromagnetic exchange mechanism of Heusler alloy. Journal of Magnetism and Magnetic Materials.2021,523: 167627.(Q2)

[32] 作者. Study of surface quality in machining nickel-based alloy Inconel 718. International Journal of Advanced Manufacturing Technology, 2013, 69: 2659-2667. (Q2)

[33] 第一作者. Cutting mechanism of enhanced phase Ý in Inconel 718 based on strain gradient theory. The International Journal of Advanced Manufacturing Technology. 2021,113: ‏ 2523-2537. (Q2)   

[34] 作者. Wear characteristics of cemented carbide tool in dry machining Ti-6Al-4V. Machining Science and Technology, 2016, 20 (2): 249-261. (Q2)

[35] 作者. Tribological characteristics and wear mechanism of cemented carbide tool in dry machining Ti-6Al-4V. Int. J. Materials and Product Technology, 2017, 54(4): 275-290. (Q4)

[36] 第一作者.Machining characteristics of cutting Inconel718 with carbide tool .Int. J. Materials and Product Technology, 2019, 58(4): 275-287  (Q4)

[37] 第一作者.A physically-based constitutive model for viscoplastic deformation of Inconel718 at high strain rates and temperatures. Journal of Aerospace Engineering,2020 ,33(5): 04020051 (Q2)

[38] 第一作者.Study on phase transformation in cutting Ni-base superalloy based on Molecular dynamics method. Proceedings of the IMechE, Part C: Journal of Mechanical Engineering Science. 2021,235(11): 2065-2086.Q3

[39] 作者.Effect of workpiece atom diffusion into CBN tool on its crystal properties in cutting Ni-Fe-Cr alloy based on Molecular Dynamics SimulationInternational Journal of Precision Engineering and Manufacturing, 2021,22(4):635-647.Q3

[40] 作者.Atom diffusion mechanism in cutting Ni-based alloy containing γ’ phase (Ni3Al) with CBN tool based on MD simulation. Proceedings of the IMechE, part B: Journal of Engineering Manufacture. 2021, 235(11): 1763–1778.Q3

[41] 第一作者.Microscopic study on the mechanism of tool bond wear in cutting Ni-Fe-Cr-Co- Cu series Nickel-base superalloy. International Journal of Precision Engineering and Manufacturing, 2021,22(4):621-634.Q3

[42] 作者.Study on dynamic mechanical properties and constitutive model description of Inconel718. . Proceedings of the IMechE, Part C: Journal of Mechanical Engineering Science. 2021, (Q3)

[43] 第一作者. Diffusion mechanism of cutting Ni-based alloy with carbide tool based on Molecular Dynamics simulation. International Journal of Surface Science and Engineering.2022(已录用)

[44] 第一作者. Wear mechanism of Nanotwinned cBN tools in nano-cutting Ni-Cr-Fe alloy by molecular dynamics simulation .Journal of Manufacturing Processes.2022,81:490-504. (Q2)

[45] 第一作者. Material dynamic behavior in cutting zone of Inconel 718 and its influence on cutting process. Archives of Civil and Mechanical Engineering 22, 146 (2022).

[46] 作者. The effect of anisotropy of nickel-based single crystal alloys on the surface quality of sub-nanometer and near atomic scale cutting. Intermetallics 145 (2022) 107536.

[47] 第一作者. Influence of cutting parameters on cutting specific energy of Inconel718 based on strain gradient. Proceedings of the IMechE, part B: Journal of Engineering Manufacture. 2023.

[48] 第一作者. A GND simulation model for micro-deformation mechanism analyses in high-speed cutting Inconel718. The International Journal of Advanced Manufacturing Technology.2023, 128:2931–2952

[49] 第一作者.Theoretical Calculation and Performance Analysis of Four-element Metal Nitride Tool Coatings Based on First PrinciplesJournal of Materials Engineering and Performance. 2022

[50] 通迅作. Dynamic behavior description and three-dimensional cutting simulation of SiCp/Al composites with high volume fraction Journal of Manufacturing Processes2022

[51]第一作者.Research on Strengthening Mechanism of Rare Earth Cemented Carbide Tool Material. Journal of Engineering Materials and Technology-Transactions of The ASME., 2023,145(2), 021006.

[52]通迅作者:Theoretical Calculation and Analysis of Physical and Mechanical Properties of WC-Co Cemented Carbide with Lanthanum,Jornual of Materials Engineering and Performance. 2023. 

[53] 第一作者.Interface Bonding Mechanism of Ti3Al0.125Cr0.875 N/WC Carbide: A First PrinciplesStudy.Journal of Materials Engineering and Performance,2022,1-12. 2023. 

[54]  第一作者.Research on surface roughness prediction in turning Inconel 718 based on Gaussian process regression . Physica Scripta,2022,98(1):015216.

[55] 第一作者. 碳化硅增韧氧化铝基陶瓷刀具切削Inconel718 合金的刀具界面行为研究,中国机械工程,2021.091009-1016.EI源期刊)

[56] 通迅作者. SiCp/2024Al复合材料高应变率热变形行为的新本构模型.中国机械工程,2021.111346-1353.EI源期刊)

[57] 第二作者.基于机器视觉的单晶硅超声振动辅助切削亚表面裂纹损伤检测算法. 吉林大学学报(工学版)2021. DOI10.13229/j.cnki.jdxbgxb20210166。(EI源期刊)

[58] 第一作者. 高速切削Inconel718切屑形成过程中塑性变形研究,制造技术与机床,2017.08:84-87.

[59 第一作者. 速切削Inconel718绝热剪切带微观特征研究,组合机床与自动化加工技术,2018.06:15-22.

[60] 第二作者. 切削Ni 基高温合金适用的可转位硬质合金刀具的试验研究,航空制造技术,2012.10:62-64.

[61] 通讯作者. 纳米切削镍基单晶合金亚表面缺陷演化机理研究.机械科学与技术,2021DOI10.13433/j.cnki.1003-8728.20200445

[62] 第二作者.高效切削钛合金Ti-6Al-4V 硬质合金刀具扩散磨损研究,制造技术与机床,2016.03:20-28.

Ø  奖励

[1] 郝兆朋(1/1):国际学术奖,2021年度“IAAM medal”奖,“Material Processing & Manufacturing”领域杰出青年科学家奖章,国际先进材料学会,瑞典

[2] 郝兆朋(1/6)高性能金属难加工材料切削机理与工艺应用研究,吉林省自然科学奖,二等奖,吉林省人民政府,2021

[3] 郝兆朋(10/16):高性能复杂零件高速加工与快速三维测量,中国机械工业科学技术奖,一等奖,中国机械工业联合会 ,中国机械工程学会,2013 

[4] 郝兆朋(1/1):数字仿真奖青年科技奖,中国力学学会,中国航空学会,数字仿真奖评奖委员会,2021

[5] 郝兆朋(通迅作者):切削镍基高温合金水蒸汽+空气冷却润滑效应及刀具磨损机理,吉林省自然科学学术成果奖,二等奖,吉林省科技协会,2018

[6] 郝兆朋(7/10):高温合金叶片叶轮类零件加工工艺技术及工程应用,黑龙江省科技进步奖,二等奖,黑龙江省人民政府,2016

[7] 郝兆朋(12/13):复杂光学曲面主动调制加工新技术及应用,吉林省科技进步奖,一等奖,吉林省人民政府,2015

 

四、发明专利

[1] 郝兆朋(1/4):一种基于刀具磨损状态的切削参数优化方法,专利号:2020112067648

[2] 郝兆朋(1/5):一种振动切削刀具振幅检测的方法及装置,专利号:2020110996438

[3] 郝兆朋(1/5):一种适用于大直径热变形复合材料零件的外圆车削装置, 专利号:2020112008599

[4] 郝兆朋(1/4): 一种基于机理分析的切削用水蒸汽混合空气绿色冷却润滑剂,专利号:2020112068265

 

五、  毕业生去向

指导的硕士毕业生多人荣获省级、校级优秀硕士毕业论文、校优秀毕业生,获国家奖学金。多名毕业生在哈尔滨工业大学、大连理工大学、中科院深造,攻读博士学位;以及在广汽集团、 中国航发长春控制科技有限公司、恒普真空科技有限公司等企业工作。




  • 教育经历Education Background
  • 工作经历Work Experience
    2013.12 至今
    • 长春工业大学
    • 机电工程学院
  • 研究方向Research Focus
  • 社会兼职Social Affiliations
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团队成员Research Group

团队名称:难加工材料高效精密切削加工

团队介绍:团队长期从事难加工材料高效精密切削加工技术与理论研究,研究工作能紧密联系生产实际,探索符合吉林省航空装备制造、维修特色产业体系的研究目标和方向,发挥团队优势,注重学科的融合与攻关解决实际问题,并把基础研究和推广应用紧密结合,科研成绩显著。