智能检测与增材制造研究所

智能检测与增材制造研究所

敬晨晨

敬晨晨



预聘助理教授

博导 硕导

机械工程专业

办公地址

北京理工大学求是楼106

100081

办公电话

010-68914692

jingchenchen@bit.edu.cn

研究方向

研究方向为智能制造,聚焦增材制造工艺机理、熔池形貌在线检测与动态调控、智能装备研发。在悬空熔池热--流耦合机理、热丝与脉冲电弧协同增材制造等方面取得系列创新成果。共发表学术论文18篇,其中一作/通讯论文8篇(含顶刊4篇),申请发明专利15项(授权7项),参编十四五高等教育系列教材1部。主持博士后面上基金、KGJ专项课题、嘉兴市重点研发计划等项目多项,深度参与国家重点研发计划等重大项目。

课题组聚焦智能制造前沿、项目经费充足、学术氛围融洽,可招收本部、长三角研究院的硕士,欢迎感兴趣的同学前来深造。

代表性论文及研究项目

代表性论文:

[1] Jing C, Mao H, Xu T, et al. Fabrication strategy and mechanical behavior of large-size 316L stainless steel lattice structures via directed energy deposition-arc[J]. Additive Manufacturing Frontiers, 2026: 200296.

[2] Xu T, Mao H, Jing C*, et al. Bending performance of large-scale lattice sandwich structure based on multi-arc directed energy deposition[J]. Structures, 2026, 88: 111941.

[3] Jing C, Mao H, Xu T, et al. Fabricating 316 L stainless steel unsupported rods by controlling the flow of molten pool via wire arc additive manufacturing[J]. Journal of Materials Processing Technology, 2023: 118066.

[4] Jing C, Mao H, Xu T, et al. Impact of process parameters on forming quality and deposition efficiency of unsupported rods in wire arc additive manufacturing[J]. Journal of Manufacturing Processes, 2024, 124: 12-23.

[5] Xu T, Jing C, Mao H, et al. Parallel multi arc directed energy deposition: New way to achieve efficient manufacturing of large-size lattice sandwich structure[J]. Additive Manufacturing, 2024, 90: 104322.

[6] Si J, Guo Y*, Hu J, Jing C*, Lu J, Liu C. Enhanced high-temperature strength and ductility of wire arc additive manufactured Al–Ce–Mg alloys with fine α-Al/Al11Ce3 eutectics. Journal of Materials Research and Technology202430, 4929–4938.

[7] Fu R, Han X, Jing C, et al. Heat input adjustment process for unsupported aluminum alloy lattice struts continuous forming by wire arc-directed energy deposition[J]. Journal of Materials Processing Technology, 2024, 332: 118550.

[8] Mao H, Jing C, Kong F, et al. Improve the manufacturing efficiency of steel bars by using hot-wire pulse arc additive manufacturing[J]. Journal of Manufacturing Processes, 2023, 89: 430-443.

[9] Jing C, Chen Z, Liu B, et al. Improving mechanical strength and isotropy for wire-arc additive manufactured 304L stainless steels via controlling arc heat input[J]. Materials Science and Engineering A, 2022, 845.

[10] Jing C, Zhu Y, Wang J, et al. Investigation on Morphology and Mechanical Properties of Rod Units in Lattice Structures Fabricated by Selective Laser Melting[J]. Materials, 2021, 14(14): 3994.

发明专利:

[1] 敬晨晨, 齐霖, 张慕辰, 庞璐, 卢继平. (2026). 一种移动式增材制造与修复方法及系统, CN202610175672.9 (受理)

[2] 敬晨晨,张慕辰,卢继平. (2025) 异质金属增强杆件的增材制造系统及方法, 2025102205339 (受理)

[3] 刘长猛, 敬晨晨, 徐田秋, 毛昊, 李坤. (2022). 任意角度空间无支撑金属杆件的电弧增材制造方法及系统. CN202210789371.7. (受权)

[4] 刘长猛, 敬晨晨, 徐田秋, 毛昊, 李坤. (2022).一种电弧辅助热丝空间无支撑杆高效增材制造设备及方法. CN202210789343.5. (受权)

[5] 刘长猛, 徐田秋, 敬晨晨, 韩骁. (2022). 一种薄壁与杆结合的锥形抗弹点阵夹芯板及其制备方法. CN115157821A. (受权)

[6] 刘长猛, 徐田秋, 敬晨晨, 韩骁. (2022). 一种梯度金字塔型点阵夹芯板及其制备方法. CN115157822A. (受权)

[7] 刘长猛, 徐田秋, 黄俊锦, 敬晨晨. (2021) 一种三明治板的芯体与面板节点连接工艺. CN113682026A. (受权)

[8] 廉艳平, 韩松宇, 刘长猛, 陈嘉伟, 敬晨晨. (2021). 一种加强单胞结构及其制备方法与应用,夹芯板. CN112848553A. (受权)

[9] 周晓华, 王敏, 范庆辉, 钟诚, 敬晨晨, 李宝林等. (2019). 一种用于大型增材制造的密封门及密封方法. CN109812193A. (受权)

研究项目:

[1] 博士后面上基金 无支撑增材制造不锈钢悬空熔池热--流耦合机理与动态调控机制

[2] KGJXXX安全发展专项课题 设备XXXX技术及规范研究

[3] 嘉兴市重点研发项目 钣金零件在线质量检测及智能分拣技术研究

[4] KGJXXX安全发展专项课题 安全非毁伤立体仓储关键基础技术研究

[5] 国家重点研发计划项目 金属与混凝土复合增材制造工艺与机理

[6] GF科技创新特区项目 XXXXX快速架设关键机构设计

社会职务

[1] 中国机械工程学会 会员

[2] 中国机械工程学会增材制造(3D打印)分会 会员

[3] SCI期刊 Measurement Science and Technology 客座编辑

[4] AMMSEAJMP SCI期刊审稿