详细介绍
陈卓婷
| 姓 名 | 陈卓婷 | 职 称 | 讲师 | |
学历/学位 | 博士 | 硕导/博导 | 无 | ||
行政职务 | 无 | ||||
教研室 | 机械制造极其自动化 | ||||
研究方向 | 先进制造,3D打印(增材制造),多场多尺度模拟, | ||||
研究生招生学科专业 | 机械制造极其自动化,机械工程 | ||||
电子邮件/联系电话 | cztkatherine@outlook.com | ||||
个人简介 | |||||
【个人简介】 陈卓婷,女,汉族,四川南充人,助理研究员,美国怀俄明大学机械工程博士,2025年4月起在西南石油大学机电工程学院任教。 长期从事复合材料先进制造与智能制造技术的研究。其研究重点为前端聚合(Frontal Polymerization, FP)在复合材料与增材制造中的应用,结合热–化学–机械多物理场耦合建模方法,探索制造过程中的反应机理、残余应变与性能优化,并开展复合材料制造过程的实时监测与闭环控制研究。 在学术研究方面,已发表SCI论文4篇,其中以第一作者身份在国际权威期刊 Additive Manufacturing 与 Composites Science and Technology 发表多篇高水平论文。她受邀在IMECE、AIAA、EMI等十余个国际会议上作学术报告, 担任IMECE2025会议分会场主席。研究成果在航空航天、汽车制造、高性能复合材料及智能制造等领域具有重要应用前景。 【论文著作】 l Z. Chen, M. Ziaee, M. Yourdkhani, X. Zhang, “Multiphysics Modeling of Frontal Polymerization based Layer-by-Layer 3D Printing of Thermoset Polymer Components”, Additive Manufacturing, 59, Part B (2022). (SCI) l Z. Chen, X. Zhang, “Manufacturing multifunctional vascularized composites by through-thickness frontal polymerization and depolymerization: A numerical study on the impact of sacrificial fiber configurations”, Composite science and technology, 247 (2024). (SCI) l Z. Chen, X. Zhang, et al., “Residual Strain Development in Rapid Frontally Curing Polymers”, ACS Applied Engineering Materials, 2024. l Z. Chen, M. Ziaee, et al.. Coupled Thermo-Chemical Modeling of Frontal Polymerization-Assisted Additive Manufacturing of Thermoset Polymer Components. American Institute of Aeronautics and Astronautics (AIAA) Scitech 2023 Forum l P. Centellas, M. Garg, Z. Chen, X. Zhang, N. Parikh, P. Geubelle, N. Sottos. Energy-Efficient Manufacturing of Multifunctional Vascularized Composites. The Journal of Composite Materials, 57(2022). (SCI) 会议报告 l Z. Chen, X. Zhang. A Numerical Study on Adaptive Printing Velocity Control in Frontal Polymerization-assisted Layer-by-Layer Additive Manufacturing. International Mechanical Engineering Congress and Exposition (IMECE), Portland, Oregon, 2024, Nov. 17 – Nov. 21. l Z. Chen, B. Koohbor, L. Dean, P. Geubelle, N. Sottos, X. Zhang. Multiphysics Modeling and Experimental Characterization of Induced Residual Deformations in Frontal Polymerization. International Mechanical Engineering Congress and Exposition (IMECE), Portland, Oregon, 2024, Nov. 17 – Nov. 21. l Z. Chen, X. Zhang. A Numerical Study on Closed-loop Control System for Frontal Polymerization-assisted Layer-by-Layer Additive Manufacturing. International Mechanical Engineering Congress and Exposition (IMECE), New Orleans, LA, Oct. 29 – Nov. 2. l Z. Chen, X. Zhang. A Numerical Study on Through-thickness Frontal Polymerization and Depolymerization of Multi-Sacrificial Fiber Embedded Vascular Composite System. International Mechanical Engineering Congress and Exposition (IMECE), 2023 New Orleans, LA, Oct. 29 – Nov. 2. l Z. Chen, M. Ziaee, M. Yourdkhani, X. Zhang. Multiphysics Modeling of Frontal Polymerization-based 3D printing of Polymer Components. AIAA Rocky Mountain Annual Technical Symposium, Fort Collins, Colorado, 2023, Sep. 22. l Z. Chen, M. Ziaee, M. Yourdkhani, X. Zhang. Multiphysics Modeling of Frontal Polymerization-based 3D printing of Polymer Components. 2023 American Chemical Society (ACS) Rocky Mountain Regional Meeting, Laramie, Wyoming, 2023, Sep. 15? Sep.17. l Z. Chen, M. Ziaee, M. Yourdkhani, X. Zhang. Coupled Thermo-Chemical Modeling of Frontal Polymerization-Assisted Additive Manufacturing of Thermoset Polymer Components. AIAA SciTech Forum, National Harbor, Maryland & Online, 2023, Jan 23-Jan 27. l Z. Chen, M. Ziaee, M. Yourdkhani, X. Zhang, Multiphysics Modeling of Frontal Polymerization based Layer-by-Layer 3D Printing of Thermoset Polymer Components. Engineering Mechanics Institute Conference (EMI), Baltimore, Maryland, 2022, May 31-June 3. l Z. Chen, M. Garg, P. Centellas, N. Sottos, J. Moore, P. Geubelle, X. Zhang. Multiphysics modeling of a concurrent polymerization and vascularization process for manufacturing polymer and polymer composites with Embedded Microvascular System. International Mechanical Engineering Congress and Exposition (IMECE), virtual, 2021,11. l Z. Kou, H. Wang, J. Guo, Z. Chen, “Transient pressure analysis of multiple fractured wells in stress-sensitive coal seam gas reservoirs with stimulated reservoir volume,” Bulletin of the American Physical Society 2020, online. l S. Zhao, K. Liao, Z. Chen, F. Zhou. Study on corrosion mechanisms of welds seam in submarine pipeline expansion bend pipe section. International Conference “Corrosion in the Oil & Gas Industry”-Corrosion Oil & Gas, Saint Petersburg, Russia, 2019, 22-24 May. 【荣誉奖励】 · 2024.08-2024.12 怀俄明大学计算学院研究生奖学金 (Scholarship) 【课题成果】 l FP-VaSC 模拟研究 与美国工程院 Nancy Sottos 院士团队合作,提出一种快速(几分钟)、节能且可扩展的室温方法,通过二环戊二烯(DCPD)前端聚合的放热反应驱动牺牲纤维(PPC)解聚,制备血管状微网络碳纤维复合材料。基于 MOOSE 建立热化学耦合模型,揭示了高碳纤维含量复合材料在冷却阶段对牺牲纤维解聚的重要作用。 l 牺牲纤维配置效应 利用热化学耦合模型,系统模拟多通道微网络结构复合材料的制备,揭示牺牲纤维与同步聚合的相互作用,提出快速估算最大纤维体积分数的方法,为高性能血管通道复合材料的快速制备及航空航天自愈应用提供理论基础。 l FP-3D 打印建模 开发首个多物理有限元模型,模拟 FP 辅助增材制造过程,研究打印速度与固化前沿的耦合关系,揭示其自适应特性,并通过敏感性分析明确工艺参数对层间固化行为的影响,为打印精度与质量优化提供指导。 l 闭环控制系统 提出基于 FP 的 3D 打印闭环控制方法,数值复现红外监测与速度调控过程。系统通过 MOOSE、Paraview 与 MATLAB 的联合调用,实现信息提取、速度更新与迭代模拟自动化,达到实时优化打印速度与固化前沿匹配的目标。 l 残余变形模拟 与 Nancy Sottos 团队合作,实验与建模结合研究 FP 固化引起的残余变形,捕获应变演化,并提出预加热策略,有效缓解多前沿相遇时的过量残余应变。 【研究方向】 l 基于前端聚合技术的高性能材料先进制造过程的多物理多尺度模拟 l 多物理多尺度模拟及优化高性能聚合物及复合材料的前端聚合与3D打印过程 l 高性能聚合物在前端聚合过程中的热化学力学多物理耦合行为模拟
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