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姓名: 陳光
性別:
英文名: Chen Guang
人才稱號:
職稱: 副教授,碩士/博士生導師
職務: 專業: 機械制造及其自動化
所在機構: 機械工程系、數字化制造與精密加工技術研究所 個人主頁:
郵箱: cgtju2009@tju.edu.cn 辦公地點:
傳真: 辦公電話:
主要學歷: 2009/03-2012/01,天津大學,機械工程,工學博士;
2007/07-2009/03,天津大學,機械工程,工學碩士;
2003/09-2007/07,天津大學,機械設計制造及其自動化,工學學士。

主要學術經歷: 2018/06至今, 天津大學機械工程學院,博士生導師
2016/06至今, 天津大學機械工程學院,副教授
2014/01至今, 天津大學機械工程學院,碩士生導師
2017/12-2018/12, 美國肯塔基大學, 訪問學者
2013/07-2013/12, 奧地利格拉茨技術大學,訪問學者
2012/03-2016/06, 天津大學機械工程學院,講師

主要研究方向: 1. 難加工材料高效切削技術與裝備
2. 航空材料切削變形屬性?
3. 高精度滾動軸承超精密加工技術與裝備

主要講授課程: 1. 《工程制圖基礎3》?(本科生56學時)
2. 《先進制造技術實驗》 (本科生 64學時)
3. 《Advanced Manufacturing Technology》(研究生32學時)


主要學術兼職: 擔任以下國內外期刊論文評審人:?
International Journal of Machine Tools & Manufacture,?
IMechE Part B: Journal of Engineering Manufacture,?
Machining Science and Technology,?
中國機械工程,
International Journal of Machining and Machinability of Materials,
International Journal of Thermal Sciences,
Journal of Computational Methods in Sciences and Engineering

主要學術成就: 主要從事航空材料切削變形屬性、難加工材料高效切削機理、工藝裝備等方面的研究工作。主持或參加國家、部委及橫向課題等10余項;在Int J Mach Tool Manuf、Mater Des,等高水平學術期刊發表被 SCI收錄論文20余篇、他引200余次;授權國內發明專利3項、國際專利6項。?

2015年入選“北洋學者-青年骨干教師”計劃
2015年入選天津市“131”創新型人才培養工程第三層次?
2015年天津大學本科生畢業設計(論文)優秀指導教師?
2018 CIRP CSI-4th CIRP Conference on Surface Integrity “Best Poster Award” (第四屆CIRP表面完整性國際會議 最佳海報獎)
2019年天津大學“教書育人”先進工作者

主要科研項目: 1. 國家自然科學基金面上項目,CFRP/鈦合金疊層超聲輔助螺旋銑孔表面性狀形成機理,64萬,2016.01-2019.12,項目負責人
2. 國家自然科學基金重點項目,軸承滾子高精度創成理論與實現方法,300萬,2020.01-2024.12, 子課題負責人
3. 國家自然科學基金青年基金,鈦合金超高應變率材料模型及其切削機理研究,25萬,2013.01-2015.12,項目負責人
4. 天津市自然科學基金青年基金,基于霍普金森壓桿的鈦合金動態沖擊超高速切削機理研究,6萬,2016.04-2019.03,項目負責人
5. 天津市裝備設計與制造技術重點實驗室開放基金,航空鋁合金切削過程超高應變率材料變形屬性研究,2013.4-2016.4,校內項目負責人
6. 天津大學創新基金,切削超高應變率2024-T351合金材料本構模型研究,2013.1-2014.12, 項目負責人
7. 國家重點研發計劃“制造基礎技術與關鍵部件”專項項目,滾動軸承超精密制造與檢測技術, 2019.01-2022.12, 參與人
8. 國家科技重大專項,數控機床誤差測量、分析與補償技術,2015.01-2017.12,參與人
9. 國家863計劃,復合材料/合金疊層構件高效精密制孔工藝技術,2013.01-2015.12;參與人
10. 國家863計劃,基于微細機構加工數控超精密機床子課題,2008.10-2012.12,參與人
11. 國家自然科學基金面上項目,基于界面細觀力學行為的纖維增韌陶瓷基復合材料磨削機理,2013.01-2016.12,參與人

代表性論著: 發表論文:
[1] Chen G, Chen S, J. Caudill, I.S. Jawahir, Effect of cutting edge radius and cooling strategies on surface integrity in orthogonal machining of Ti-6Al-4V alloy, Procedia CIRP, 2019, 82: 148-153.
[2] Chen G, Lu LP, Ke ZH, Qin XD, Ren CZ, Influence of constitutive models on finite element simulation of chip formation in orthogonal cutting of Ti-6Al-4V alloy. Procedia Manufacturing, 2019, 33, 530-537.
[3] Zou YH, Chen G*, Lu LP, Qin XD, Ren CZ, Kinematic view of cutting mechanism in hole-making process of longitude-torsional ultrasonic assisted helical milling, International Journal of Advanced Manufacturing Technology, 2019,103(1), 267-280.
[4] Chen G, Ren CZ, Zou YH, Qin XD, Lu LP, Li SP, Mechanism for material removal in ultrasonic vibration helical milling of Ti-6Al-4V alloy, International Journal of Machine Tools and Manufacture, 2019,138: 1-13.
[5] Chen G, Ren CZ, Lu LP, Ke ZH, Qin XD, Ge X, Determination of ductile damage behaviors of high strain rate compression deformation for Ti-6Al-4V alloy using experimental-numerical combined approach. Engineering Fracture Mechanics, 2018, 200:499-520.
[6] Chen G, Lu LP, Ren CZ, Ge X, Temperature dependent negative to positive strain rate sensitivity and compression behavior for 2024-T351 aluminum alloy, Journal of Alloys and Compounds, 2018,765: 565-585.
[7] Wang ZQ, Ren CZ*, Chen G, Zhang LF, Deng XF, A comparative study on state of oxide layer in ELID grinding with tool-cathode and workpiece-cathode, The International Journal of Advanced Manufacturing Technology, 2018, 94: 1299-1307.
[8] Chen G, Ke ZH, Ren CZ, Li J, Constitutive modeling for Ti-6Al-4V alloy machining based on the SHPB tests and simulation, Chinese Journal of Mechanical Engineering, 2016, 29(5):962-970.
[9] Chen G, Ren CZ, Ke ZH, Li J, Yang XP, Modeling of flow behavior for 7050-T7451 aluminum alloy considering microstructural evolution over a wide range of strain rates, Mechanics of Materials, 2016, 95:146-157.?
[10] Zhang L, Ren C Z*, Ji C, Wang Z, Chen G, Effect of fiber orientations on surface grinding process of unidirectional C/SiC composites. Applied Surface Science, 2016, 366: 424-431.
[11] Ren CZ, Ke ZH, Chen G*, Wu J, Modeling of the tool-chip contact length for orthogonal cutting of Ti-6Al-4V alloy considering the segmented chip formation, Transactions of Tianjin University, 2016, 22(6), 525-535.
[12] Chen G, Ren C Z, Qin X D, Li J, Temperature dependent work hardening in Ti-6Al-4V alloy over large temperature and strain rate ranges: Experiments and constitutive modeling, Materials & Design, 2015, 83:598-610.?
[13] Li J, Yang X, Ren CZ, Chen G, Wang Y, Multiobjective optimization of cutting parameters in Ti-6Al-4V milling process using non-dominated sorting genetic algorithm-II, International Journal of Advanced Manufacturing Technology, 2015,76: 941-953.?
[14] Chen G, Li J, He YL, Ren CZ, A new approach to the determination of plastic flow stress and failure initiation strain for aluminum alloys cutting process, Computational Materials Science, 2014, 95:568-578.?
[15] Liu J, Chen G, Ji C H, Qin X D, Li H, Ren C Z. An investigation of workpiece temperature variation of helical milling for carbon fiber reinforced plastics (CFRP), International Journal of Machine Tools and Manufacture, 2014, 86: 89-103.?
[16] Chen G; Ren C Z; Zhang P; Cui K; Li Y. Measurement and finite element simulation of micro-cutting temperatures of tool tip and workpiece, International Journal of Machine Tools and Manufacture. 2013, 75: 16-26.?
[17] Chen G; Ren C Z; Yu W; Yang XY; Zhang LF. Application of Genetic Algorithms for optimizing the Johnson-Cook constitutive model parameters when simulating titanium alloy machining process, Proceedings of IMechE, Part B: Journal of Engineering Manufacture. 2012, 226(8):1287-1297.?
[18] Chen G; Ren C Z; Yang XY; Jin XM; Guo T. Finite element simulation of high speed machining of titanium alloy (Ti-6Al-4V) based on ductile failure model, International Journal of Advanced Manufacturing Technology, 2011, 56(9): 1027–1038.?
[19] Chen G; Ren C Z; Yang X Y; Guo T. Evidence of thermoplastic instability about segmented chip formation process for Ti-6Al-4V alloy based on finite element method, Proceedings of IMechE, Part C: Journal of Mechanical Engineering Science, 2011, 255(6): 1407–1417.?
[20] Chen G; Ren CZ; Jin XM; Guo T. Experimental and finite element study of steady state micro- cutting characteristics of aluminum alloy (2A12), Transactions of Tianjin University, 2011, 17(5): 344–350.?
[21] Cui KH; Ren CZ; Chen G. Numerical simulation for peripheral milling of aero-aluminum alloy based on 3D FE model, Key Engineering Materials, 2014, 589-590.?
[22] Guo T; Chen G; Ren CZ. A numerical model to determine temperature distribution in aluminum alloy (2A12) micro-cutting, Solid State Phenomena, 2011, 175:330–334.?
國內外發明專利:
[1]陳光,楊新鵬,任成祖,靳新民,鄒云鶴,一種同時測量銑削過程銑刀及工件溫度的測量系統,ZL201610837003.X
[2]陳光,盧連朋,任成祖,靳新民,鄒云鶴,一種基于霍普金森壓桿裝置的模塊化高速切削實驗平臺,ZL201710426024.7
[3]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. 雙盤直槽圓柱形零件表面研磨盤. ZL201410783965.2
[4]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. 一種圓柱形零件研磨設備及其工件推進裝置和研磨方法. ZL201410784413.3
[5]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. Cylindrical-component grinding device, and workpiece advancing apparatus and grinding method thereof. US201715619498
[6]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. Double-disc straight groove cylindrical-component surface grinding disc. US201715619443
[7]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. ダブルディスク直線溝円筒狀部品表面研磨ディスク. JP2017526063
[8]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. 円筒狀部品研磨設備及びそのワークピース推進裝置、並び研磨方法. JP2017526065
[9]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. ??? ?? ?? ??? ??? ??? ?? ?? ?? ???. KR20177014857
[10]任成祖, 鄧曉帆, 賀英倫, 陳光, 靳新民. ??? ?? ??? ?? ?? ?? ? ? ??? ?? ??? ?? ??. KR20177014859

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