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- 基本教学信息
- 本科教学信息
- [1]金属体积成形工艺及模具,专业限选课,32学时
- 教学项目及获奖
- [1]2024年研究生国际化课程培育项目,执行年限:2024.07-2026.06,项目负责人;
[2]2024年燕山大学教学研究与改革项目,执行年限:2025.01-2025.12,项目负责人;
[3]
[4]2025年燕山大学教学研究与改革项目,执行年限:2026.01-2026.12,项目负责人; - 研究生教学信息
- 学科及研究方向
- 1.[硕士]材料加工工程(080503),研究方向: 航空航天复杂金属构件增材制造;铸造智能化;月球极区月壤水冰探测(与哈工大联合培养,2名/年)
2.[硕士]材料与化工(机械)(085600),研究方向:高效智能化焊接及增材制造;铸造构件材料-结构-性能一体化设计;月球极区月壤水冰探测(与哈工大联合培养,2名/年) - 研究生招生信息
- 本年度硕士招生指标4名! 欢迎具备金属材料基础的同学加入【重型装备与特种成形智能制造团队】团队!
优秀硕士可前往哈尔滨工业大学联合培养,培养方向:月球极区月壤水冰探测(与哈工大联合培养,2名/年)。
团队研究经费充足,导师团队梯次配置合理,可为学生提供科研指导和奖励,硕士阶段成果优秀同学可推荐至哈工大等其他高校攻读博士学位!
期待有理想、有热情、有抱负的学生,一起共事! Work hard, play hard!
招生计划:每年招收硕士研究生4-6名(包含学硕和专硕),有意向者可发送个人简历至bijiang@ysu.edu.cn。
招生学科:材料加工工程学硕和材料工程专硕(材料加工工程方向)相关学科;
研究方向:高效智能化焊接及增材制造;铸造构件材料-结构-性能一体化设计;月球极区月壤水冰探测
奖励补贴:论文发表奖励、劳务补贴。 - 硕士教学信息
- 《增材制造技术》 16学时 硕士研究生
2020级:刘 雷 一等奖学金(与董国疆教授联合培养,俄罗斯联合培养3个月)
2021级:王海翔 一等奖学金(俄罗斯联合培养3个月),硕博连读
吴刘坤 国家奖学金 一等奖学金(俄罗斯联合培养3个月)主持河北省研究生创新资助项目1项
刘泽奇 国家奖学金 一等奖学金
2022级:迟金泽 (与曹秒艳教授联合培养)国家奖学金 一等奖学金 主持河北省研究生创新资助项目1项
王克奇 (与董国疆教授联合培养)国家奖学金 一等奖学金 主持河北省研究生创新资助项目1项
2023级:周依文
谢鹏飞
邵宏飞
邹金良
2024级:白镐楠
任新科
宋浩玮
赵晨阳
王依洋 - 博士教学信息
- 科研信息
- 在研项目信息
- [1]燕山大学-优秀人才科研启动经费,执行年限:2021.01-2025.12,项目负责人;
[2]河北省自然科学基金-青年基金,执行年限:2021.01-2023.12,项目负责人;
[3]中央引导地方科技发展资金项目,执行年限:2023.01-2025.12,项目负责人;
[4]校内科研培育项目-基础创新科研培育项目,执行年限:2023.01-2024.12,项目负责人;
[5]河北省自然科学基金-面上项目,执行年限:2024.01-2026.12,项目负责人;
[6]河北省高等学校科学研究项目,执行年限:2025.01-2027.12,项目负责人;
[7]航天三院横向课题,执行年限:2024.10-2024.12,项目负责人;
[8]河北省自然科学基金-重点项目,执行年限:2024.01-2026.12,执行负责人;
[9]企业委托横向课题,执行年限:2023.10-2024.12,执行负责人; - 完成项目信息
- [1]哈尔滨工业大学委托项目,执行年限:2021.12-2022.12,项目负责人;
- 专著、专利信息
- [1]毕江, 董国疆, 赵长财, 陈光.一种激光诱导电弧震荡的多丝同步增材制造方法.授权号:ZL202110721167.7
[2]毕江, 董国疆, 刘雷,赵长财.一种耐热铝合金粉末及其制备方法和一种铝合金成型件及其制备方法.授权号:ZL202110671236.8
[3]毕江, 董国疆, 孟世谦, 朱良金.一种高温合金与热障涂层一体化成型的方法及带有热障涂层的合金材料.授权号: ZL202110854386.2
[4]毕江, 李世德, 董国疆, 王海翔, 王佶.一种铝合金轮毂低压铸造模具的排气机构. 授权号: ZL202211442323.7 - 学术论文信息
- [1]第一作者 Microstructure and mechanical properties of a novel Sc and Zr modified 7075 aluminum alloy prepared by selective laser melting[J]. Materials Science and Engineering A, 2019, 768: 138478.(SCI, 中科院一区Top)
[2]第一作者. Densification, microstructure and mechanical properties of an Al-14.1Mg-0.47Si-0.31Sc-0.17Zr alloy printed by selective laser melting[J]. Materials Science and Engineering A, 2020, 774: 138931.(SCI, 中科院一区Top)
[3]第一作者. Microstructure, tensile properties and thermal stability of AlMgSiScZr alloy printed by laser powder bed fusion[J]. Journal of Materials Science and Technology, 2021, 69: 200-211. (SCI, 中科院一区Top)
[4]第一作者. An additively manufactured Al-14.1Mg-0.47Si-0.31Sc-0.17Zr alloy with high specific strength, good thermal stability and excellent corrosion resistance[J]. Journal of Materials Science and Technology, 2021, 67: 23-35.(SCI, 中科院一区Top)
[5]第一作者. Microstructure, tensile properties and heat-resistant properties of selective laser melted AlMgScZr alloy under long-term aging treatment [J].Materials Science and Engineering A, 2022,833: 142527.(SCI, 中科院一区Top)
[6]第一作者. Formability, surface quality and compressive fracture behavior of AlMgScZr alloy lattice structure fabricated by selective laser melting[J]. Journal of Materials Research and Technology, 2022, 19: 391-403.(SCI,中科院一区Top)
[7]第一作者. Formation mechanisms and control strategies of FQZ softening in Al–Li alloy welded joint[J].Journal of Materials Research and Technology, 2023, 23: 2810-2823.(SCI,中科院一区Top)
[8]第一作者. Beam shaping technology and its application in metal laser additive manufacturing: A review[J].Journal of Materials Research and Technology, 2023, 26: 4606-4628. (SCI,中科院一区Top)
[9]第一作者. Microstructure, mechanical properties and multiphase synergistic strengthening mechanisms of a novel laser additive manufactured AlNi6TiZr alloy[J]. Journal of Materials Science & Technology, 2024, 178: 59-69. (SCI,中科院一区Top)
[10]第一作者. Coupling effect of ultrasonic vibration and beam oscillation on FQZ soften inhibition of laser welded Al-Mg alloy joints[J]. Materials Letters: X, 2023, 18: 100197.
[11]第一作者. Effect of Al3(Sc, Zr) and Mg2Si precipitates on microstructure and tensile properties of selective laser melted Al-14.1Mg-0.47Si-0.31Sc-0.17Zr alloy[J]. Intermetallics, 2020,123: 106822.
[12]通讯作者. Effect of TiB2 content on microstructural features and hardness of TiB2/AA7075 composites manufactured by LMD[J]. Journal of Manufacturing Processes, 2020, 53: 283-292.
[13]通讯作者. Effect of energy density on formability, microstructure and micro-hardness of selective laser melted Sc- and Zr- modified 7075 aluminum alloy[J]. Powder Technology, 2019, 356: 594-606.
[14]第一作者. Effect of process parameters on formability and surface quality of selective laser melted Al-Zn-Sc-Zr alloy from single track to block specimen[J]. Optics and Laser Technology, 2019, 118: 132-139.
[15]第一作者. Microstructure and mechanical properties of TiB2-reinforced 7075 aluminum matrix composites fabricated by laser melting deposition[J]. Ceramics International, 2019, 45: 5680-5692.
[16]通讯作者. Melt flow and grain refining in ultrasonic vibration assisted laserwelding process of AZ31B magnesium alloy[J].Optics and Laser Technology, 2018, 108: 409-417.
[17]第一作者. Formability and strengthening mechanism of AA6061 tubular components under solid granule medium internal high pressure forming[J].Transactions of Nonferrous Metals Society of China, 2018, 28: 226-234.
[18]第一作者. Densification, microstructural features and tensile properties of selective laser melted Al Mg Si Sc Zr alloy from single track to block specimen[J].Journal of Central South University, 2021, 21: 1129-1143.
[19]第一作者. Heat treatment and granule medium internal high- pressure forming of AA6061 tube[J].Journal of Central South University, 2017, 24: 1140-1049.
[20]第一作者.Additive manufacturing of thermoelectric materials: materials, synthesis and manufacturing: a review[J]. Journal of Material Science, 2024, 59:359-381.
[21]通讯作者.铝车轮铸造模具水冷界面换热系数反算求解[J]. 有色金属学报. 2024
[22]第一作者.Enhancing tensile properties of MIG welded AA6061 joints: Effect of pulse mode and post-weld heat treatment[J]. Materials Today Communication, 2024, 39: 109156.(SCI, 中科院三区,ESI高被引)
[23]第一作者.Microstructure, mechanical properties and multiphase synergistic strengthening mechanisms of LPBF fabricated AlZnMgZr alloy with high Zn content[J]. Additive Manufacturing, 2024, 89: 104305.(SCI,中科院一区Top)
[24]通讯作者. Effect of double-pulse frequency and post-weld heat treatment on microstructure and mechanical properties of Metal-Inert Gas welded Al-Mg-Si alloy joints[J]. Materials Science and Engineering A, 2024, 913: 147029.(SCI, 中科院二区Top)
[25]通讯作者. Uneven distribution of cooling rate, microstructure and mechanical properties for A356-T6 wheels fabricated by low pressure die casting[J]. Journal of Manufacturing Processes, 2024: 127: 196-210.(SCI, 中科院一区Top)
[26]通讯作者.Investigation of grain boundary segregation evolution and corrosion behavior in 7050 aluminum alloy under oscillating laser melting[J].Journal of Alloys and Compounds, 2025, 1010: 177524.(SCI, 中科院二区Top)
[27]通讯作者.Inhibiting of softening behavior in AA2219 laser welded joints[J]. Materials Science and Engineering A, 2025, 913: 147742.(SCI, 中科院二区Top) - 科研获奖信息
- 2017年-燕山大学校级优秀硕士论文
2020年-博士研究生国家奖学金
2022年-有色金属学报优秀审稿专家
2023年-有色金属学报优秀审稿专家
2024年-有色金属学报优秀论文 - 社会信息
- 社会兼职信息
- 担任《Materials and Design》、《Materials Science and Engineering A》、《Journal of Materials Processing Technology》、《Journal of Materials Science and Technology》、《Journal of Materials Research and Technology》/《Journal of Manufacturing Processes》、《Optics and Laser Technology》《Journal of Materials Engineering and Performance》、《Materials Letters》、《Materials Characterization》、《Journal of Central South University》、《Transactions of Nonferrous Metals Society of China》、《Optik》等期刊审稿人
- 荣誉称号
- 学习工作简历
- [6] 2021.5--至今,燕山大学,机械工程学院,塑性成形工程系,材料加工工程专业,硕士生导师
[5] 2021.1--至今,燕山大学,机械工程学院,塑性成形工程系,材料加工工程专业,讲师
[4] 2017.3--2020.12,哈尔滨工业大学,材料加工工程专业,工学博士
[3] 2014.9--2017.1,燕山大学,材料加工工程专业,工学硕士
[2] 2012.8--2014.8,天津冶金集团,工程师
[1] 2008.9--2012.7,东北大学,材料成型及控制工程专业,工学学士
燕山大学机械工程学院版权所有
联系电话:0335-8057031 传真:0335-8074783 电子信箱:mec@ysu.edu.cn