贾伟涛
职称:教授(讲师特殊破格),研究生导师
邮箱:jwt860520@163.com
学术荣誉
“一级学术骨干”引进人才
学术兼职
SCI期刊Journal of Magnesium and Alloys青年编委、Shock and Vibration客座编辑、Crystals客座编辑
教育背景
2015.09-2019.01,东北大学材料加工工程专业,博士,导师:乐启炽
2012.09-2015.07,bz博中手机诚信网投机械设计及理论专业,硕士,导师:马立峰
2008.09-2012.07,bz博中手机诚信网投机械设计制造及其自动化专业,本科
工作履历
2019.01-2021.12,bz博中手机诚信网投 bz博中手机诚信网投,讲师
2022.01-至今,bz博中手机诚信网投 bz博中手机诚信网投,教授
任教课程
本科生课程:轧钢工艺学、机械工程基础、轧钢自动化
研究生课程:英语论文写作、人工智能及智能控制技术
科研工作
1)研究领域
特种金属材料成形控性一体化、金属塑性变形过程多尺度模拟与智能分析
2)承担项目
[1]国家自然科学基金(青年项目),辊差温强压剪控轧镁合金晶粒细化与基面织构改性并行控制及强韧机理,2022/01-2024/12,主持;
[2]山西省重点研发项目(半导体与新材料领域),轨道交通用高强镁合金型材及锻件制备与产业化,202102050201005,2022/01-2024/12,主持;
[3]国家自然科学基金重点项目,低成本高强塑镁合金板材的合金设计与异步轧制变形的基础研究,2017/01-2020/12,课题负责;
[4]山西省应用基础研究计划,镁合金铸轧薄板大应变轧制区热行为时变性及主动热控制研究,2019/09-2022/09,主持;
[5]山西省高等学校科技创新项目,宽幅镁板带大压下热轧变形区温度与形变协控机理研究,2019/07-2021/07,主持;
[6]山西省高校科协项目,高品质镁合金薄板低成本轧制关键技术,2020/08-2021/06,主持;
[7]山西省来晋工作优秀博士奖励资金,预变形调控改善镁合金板材轧制成形性的作用及机理,2020/05-2023/05,主持;
[8]一级学术骨干科研启动基金,宽幅镁合金板带轧制流程板温感控机理与工艺优化研究,2019/04-2020/03,主持;
[9]国家自然科学基金重点项目,镁铝复合板短流程轧制及其壳体构件一体化成形新方法新技术研究,2020/01-2023/12,课题负责;
[10]企业技术开发项目,镁合金板材大应变热轧变形区板温的在线感知,委托单位:山西八达镁业有限公司,2021/09-2023/11,主持;
[11]轻质合金饭金成形技术情报课题,委托单位:南京晨光集团有限责任公司,2021/8-2021/10,主持;
[12]企业技术开发项目,高端装备与金属材料精密成型研发与产业化,委托单位:江苏省海安高新技术产业开发区,2020/10-2023/10,课题负责;
[13]国家重点研发计划项目(十三五),大规格高性能镁合金变形加工材制造关键技术,2015/01-2020/12,骨干参与。
3)代表性成果
论文:
[1]W. Jia,L. Ma, Q. Le, C. Zhi, P. Liu, Deformation and fracture behaviors of AZ31B Mg alloy at elevated temperature under uniaxial compression, Journal of Alloys and Compounds. 783 (2019) 863–876.(SCI收录,ESI高被引)
[2]W. Jia,L.Wang, L. Ma, et al., Deformation failure behavior and fracture model of twin-roll casting AZ31 alloy under multiaxial stress state, Journal of Materials Research and Technology.17 (2022) 2047-2058.(SCI收录)
[3]W. Jia,L. Ma, M. Jiao, Q. Le, T. Han, C. Che, Fracture criterion for predicting edge-cracking in Hot rolling of twin-roll casted AZ31 Mg alloy, Journal of Materials Research and Technology. 9 (2020) 4773–4787.(SCI收录)
[4]W. Jia,Y. Tang, F. Ning, Q. Le, L. Bao, Optimum rolling speed and relevant temperature- and reduction-dependent interfacial friction behavior during the break-down rolling of AZ31B alloy, Journal of Materials Science & Technology. 34 (2018) 2051–2062.(SCI收录)
[5]W. Jia,Q. Le, Y. Tang, Y. Ding, F. Ning, J. Cui, Role of pre-vertical compression in deformation behavior of Mg alloy AZ31B during super-high reduction hot rolling process, Journal of Materials Science & Technology. 34 (2018) 2069–2083.(SCI收录)
[6]W. Jia,F. Ning, Y. Ding, Q. Le, Y. Tang, J. Cui, Role of pre-width reduction in deformation behavior of AZ31B alloy during break-down rolling and finish rolling, Materials Science and Engineering: A. 720 (2018) 11–23.(SCI收录)
[7]W. Jia,Q. Le, Heat-transfer analysis of AZ31B Mg alloys during single-pass flat rolling: Experimental verification and mathematical modeling, Materials & Design. 121 (2017) 288–309.(SCI收录)
[8]W. Jia,Y. Tang, Q. Le, J. Cui, Air-cooling analysis of AZ31B magnesium alloy plate: Experimental verification, numerical simulation and mathematical modeling, Journal of Alloys and Compounds. 695 (2017) 1838–1853.(SCI收录)
[9]W. Jia,S. Xu, Q. Le, L. Fu, L. Ma, Y. Tang, Modified Fields–Backofen model for constitutive behavior of as-cast AZ31B magnesium alloy during hot deformation, Materials & Design. 106 (2016) 120–132.(SCI收录)
[10]W. Jia,L. Ma, Y. Tang, Q. Le, L. Fu, Relationship between microstructure and properties during multi-pass, variable routes and different initial temperatures hot flat rolling of AZ31B magnesium alloy, Materials & Design. 103 (2016) 171–182.(SCI收录)
[11]W. Jia,Y. Tang, F. Ning, Q. Le, J. Cui, Microstructural and mechanical responses to various rolling speeds determined in multi-pass break-down rolling of AZ31B alloy, Mater. Res. Express. 5 (2018) 046516.(SCI收录)
[12]W. Jia,L. Ma, Y. Tang, Q. Le, et al., Prediction for Magnesium Alloy Rolling Force Based on Quantitative Study of Contact Friction, Rare Metal Materials and Engineering. 46 (2017) 2763–2769.(SCI收录)
[13]J. Zou, L. Ma,W. Jia(通讯作者),et al., Microstructural and mechanical response of ZK60 magnesium alloy subjected to radial forging, Journal of Materials Science & Technology.83 (2021) 228–238.(SCI收录)
[14]J. Lei, L. Ma,W. Jia(通讯作者),et al., Zonal differences in deformation characteristics of AZ31 Mg alloy constrained by heterogeneous metals, Journal of Materials Research and Technology.13 (2021) 2161-2179.(SCI收录)
[15]Q. Le,W. Jia(通讯作者), F. Ning, Heat transfer analysis of magnesium alloy plate during transport process, Journal of Magnesium and Alloys. 7 (2019) 291–296.(SCI收录)
[16]C. Zhi, L. Ma,W. Jia(通讯作者), X. Huo, Q. Fan, Z. Huang, Q. Le, J. Lin, Dependence of deformation behaviors on temperature for twin-roll casted AZ31 alloy by processing maps, Journal of Materials Research and Technology. 8 (2019) 5217–5232.(SCI收录)
[17]P. Liu, L. Ma,W. Jia(通讯作者), T. Wang, G. Zhao, Hot deformation behavior of a novel bimetal consisting of BTW1 and Q345R characterized by processing maps, Front. Mech. Eng. 14 (2019) 489–495.(SCI收录)
[18]J. Lei, L. Ma,W. Jia(通讯作者), Y. Zhu, Z. Huang, J. Lin, Microstructure and properties of Mg–Al–Mn magnesium alloy under shear deformation coupled tension rolling, Mater. Res. Express. 6 (2019) 106586.(SCI收录)
[19]R. Zhao,W. Jia(通讯作者), L. Ma, F. Ning, H. Xie, Y. Yuan, Transverse microstructural evolution and its cellular automata simulation during hot rolling of AZ31 alloy wide-width plate, Mater. Today Commun. 32 (2022) 104097.
[20]Y. Meng, L. Ma,W. Jia(通讯作者), Experimental and Simulation Analysis of Warm Shearing Process Parameters for Rolled AZ31B Magnesium Alloy Plate, Crystals. 12 (2022) 661.
[21]M. Jiao, L. Ma,W. Jia(通讯作者), Y. Zhu, J. Lin, Q. Le, A new phenomenological model describing the compressive thermal deformation flow stress of cast-rolled AZ31B Mg alloy, Mater. Res. Express. 6 (2019) 096597.(SCI收录)
[22]P. Liu, L. Ma,W. Jia(通讯作者), Z. Jiang, T. Wang, G. Zhao, Effect of cumulative reduction on the microstructure and properties of the NM400/Q345R composite plate, Mater. Res. Express. 6 (2019) 096534.(SCI收录)
[23]S. Xu,W. Jia(通讯作者), Z. Song, Effects of electromagnetic field on physical behaviors during low-frequency electromagnetic casting of Mg alloy AZ31, Materials Research Express. 6 (2019) 066569.(SCI收录)
[24]贾伟涛,马立峰,蒋亚平,刘鹏涛,徐海洁,铸态AZ31B镁合金中厚板热轧制温度场数学模型,稀有金属材料与工程. 45 (2016) 702–708.(SCI收录)
[25]贾伟涛,马立峰,刘鹏涛,徐海洁,蒋亚平, AZ31B镁合金中厚板轧制热力耦合场数学模型,稀有金属材料与工程. 45 (2016) 1175–1181.(SCI收录)
[26]贾伟涛,马立峰,马自勇,蒋亚平,徐海洁,刘鹏涛,铸态AZ31B镁合金变温轧制过程及流变应力,稀有金属材料与工程. 45 (2016) 152–158.(SCI收录)
[27]马立峰,贾伟涛(通讯作者),林金保,黄庆学,黄志权,铸态AZ31B镁合金变温轧制本构数学模型的建立,稀有金属材料与工程. 45 (2016) 339–345.(SCI收录)
[28]贾伟涛,马立峰,乐启炽,换热器板片波纹结构辊压成形工艺设计,东北大学学报(自然科学版). 38 (2017) 379–384.(EI收录)
[29]范沁红,马立峰,赵镇波,贾伟涛(通讯作者),乐启炽.镁合金轧制热流体式控温轧辊温度变化规律研究[J/OL].机械工程学报. 2022.(EI收录)
[30]贾伟涛,乐启炽,基于Fields-Backofen方程的镁合金热变形本构模型,精密成形工程. 9 (2017) 17–24.(会议优秀论文)
专利:
[1]贾伟涛,马立峰,等.一种液压缸驱动连杆机构的双向圆钢剪切机,国家发明专利, ZL201910930994.X.(授权)
[2]贾伟涛,赵瑞,等.一种镁合金板材大应变热轧变形区板温的在线感知方法,国家发明专利, ZL201910932139.2.(授权)
[3]贾伟涛,马立峰,等.一种半固态镁合金梯度挤压组合模具,国家发明专利, ZL201910993511.0.(授权)
[4]贾伟涛,马立峰,等.一种半固态镁合金剪切推送装置,国家发明专利, ZL201910993122.8.(授权)
[5]贾伟涛,马立峰,等.一种镁合金波纹管射流辅助局部差温强旋成形装置及方法,国家发明专利, ZL201911112637.9.(授权)
[6]贾伟涛,马立峰,等.一种半固态镁合金梯度冷却密封装置,国家发明专利, ZL201910993114.3.(授权)
[7]雷军义,贾伟涛,等.一种镁合金无缝管材连铸连挤直轧装置与方法,国家发明专利,ZL201910993110.5.(授权)
著作:
[1]《镁合金板带轧制工艺基础研究》,机械工业出版社,2019,参编.
[2]《金属剪切设备与技术》,机械工业出版社,2019,参编.
获奖:
[1]特种承载构件用高强难变形镁合金板材制备技术开发与应用,山西省技术发明一等奖,2020.
[2]大塑性变形制备高性能镁合金应用基础研究,山西省自然科学二等奖,2020.
[3]大塑性变形及合金化制备高性能镁合金应用基础研究,山西省高等学校优秀成果奖-自然科学二等奖,2019.
[4]Deformation and fracture behaviors of AZ31B Mg alloy at elevated temperature under uniaxial compression,太原市自然科学优秀学术论文一等奖,2019.
[5]Prediction for Magnesium Alloy Rolling Force Based on Quantitative Study of Contact Friction,太原市自然科学优秀学术论文二等奖,2019.
[6]bz博中手机诚信网投第十六届青年教师教学竞赛,三等奖,2021.
[7]宝钢教育奖,2018.
