張國慶,工學博士,深圳大學機電與控制工程學院副教授,深圳大學工程訓練中心副主任,深圳大學機電與控制工程學院學科負責人。2014年畢業於香港理工大學超精密加工技術國家重點實驗室獲博士學位,2016年被深圳市認定為“孔雀計畫”海外高層次人才,主要研究方向為超精密加工工藝與裝備、機器人與機構學、氣體軸承等領域,共發表論文50餘篇,其中被SCI/EI收錄30餘篇;獲授權中國發明專利16項、美國發明專利14項;主持國家自然科學基金、廣東省自然科學基金、深圳市“孔雀計畫”科研啟動基金、深圳市孔雀技術創新項目、深圳市科技計畫項目各1項;多次受邀參加國際著名學術會議並做口頭報告;擔任多個國際著名期刊的文章評審專家。
基本介紹
- 中文名:張國慶
- 外文名:Guoqing Zang
- 別名:老師
- 國籍:中國
- 民族:漢
- 出生地:內蒙古扎蘭屯市
- 出生日期:1982年
- 職業:副教授
- 畢業院校:香港理工大學
- 主要成就:《基於超精密加工的仿生微納結構表面製備技術》
- 代表作品:《超精密飛刀銑削刀具磨損及工件表面特徵創成的線上評估新方法研究》
代表期刊論文:
SCI 論文:
1. Zhang G, To S, Xiao G. A novel spindle inclination error identification and compensation method in ultra-precision raster milling[J]. International Journal of Machine Tools and Manufacture, 2014, 78: 8-17.
2. Zhang G, To S, Xiao G. The relation between chip morphology and tool wear in ultra-precision raster milling[J]. International Journal of Machine Tools and Manufacture, 2014, 80: 11-17.
3. Zhang G, To S, Zhang S. Evaluation for tool flank wear and its influences on surface roughness in ultra-precision raster fly cutting[J], International Journal of Mechanical Sciences, 2016, 118:125-134.
4. Zhang G, To S. A novel surface quality evaluation method in ultra-precision raster milling using cutting chips[J]. Journal of Materials Processing Technology, 2015, 219: 328-338.
5. Zhang G, To S, Xiao G. Novel tool wear monitoring method in ultra-precision raster milling using cutting chips[J]. Precision Engineering, 2014, 38(3): 555-560.
6. Zhang G, To S, Zhang S, Zhu Z. Case study of surface micro-waves in ultra-precision raster fly cutting[J], Precision Engineering, 2016, 46:393-398.
7. Zhang G, To S, Zhang S. Relationships of tool wear characteristics to cutting mechanics, chip formation, and surface quality in ultra-precision fly cutting[J]. The International Journal of Advanced Manufacturing Technology, 2016, 83(1-4): 133-144.
8. Zhang G, To S. An in-process tool wear evaluation approach for ultra-precision fly cutting[J], International Journal of Advanced Manufacturing Technology, 2016, 86(1-4): 169-177.
9. Zhang G, Du J, To S. Study of the workspace of a class of universal joints[J]. Mechanism and Machine Theory, 2014, 73: 244-258.
10. Zhang G, Du J, To S. Calibration of a small size hexapod machine tool using coordinate measuring machine[J]. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 2016, 230(3):183-197.
11. Zhang G, To S. Relation between tool wear and workpiece modal vibration in ultra-precision raster fly cutting[J]. International Journal of Advanced Manufacturing Technology, 2017, 93(9-12):3505-3515.
12. To S, Zhang G*. Study of cutting force in ultra-precision raster milling of V-groove[J]. The International Journal of Advanced Manufacturing Technology, 2014, 75(5-8): 967-978.
13. Du J, Zhang G*, Liu T, To S. Improvement on load performance of externally pressurized gas journal bearings by opening pressure-equalizing grooves[J]. Tribology International, 2014, 73: 156-166.
14. Cheng CT, Zhang G, To S. Wetting characteristics of bare micro-patterned cyclic olefin copolymer surfaces fabricated by ultra-precision raster milling[J], RSC Advances, 2016, 6(2):1562-1570.
15. Xiao G, To S, Zhang G. Molecular dynamics modelling of brittle–ductile cutting mode transition: Case study on silicon carbide[J]. International Journal of Machine Tools and Manufacture, 2015, 88: 214-222.
16. Zhang SJ, To S, Zhang GQ, Zhu ZW. A review of machine-tool vibration and its influence upon surface generation in ultra-precision machining[J]. International Journal of Machine Tools and Manufacture, 2015, 91: 34-42.
17. Xiao G, To S, Zhang G. The mechanism of ductile deformation in ductile regime machining of 6H SiC[J]. Computational Materials Science, 2015, 98: 178-188.
18. Zhang SJ, To S, Zhang GQ. Diamond tool wear in ultra-precision machining[J], The International Journal of Advanced Manufacturing Technology, 2016. doi:10.1007/s00170-016-8751-9.
19. Zhang SJ, To S, Zhu ZW, Zhang GQ. A review of fly cutting applied to surface generation in ultra-precision machining[J], International Journal of Machine Tools and Manufacture, 2016, 103:13–27.
20. Zhang Q, To S, Zhao Q, Guo B., Zhang G. Impact of material microstructure and diamond grit wear on surface finish in micro-grinding of RB-SiC/Si and WC/Co carbides[J]. International Journal of Refractory Metals and Hard Materials, 2015, 51: 258-263.
21. Zhang SJ, To S, Wang SJ, Zhang GQ. A new representation with probability distribution for nanometric surface roughness in ultra-precision machining[J]. Precision Engineering, 2016, 45:445-449.
22. Zhu Z, To S, Xiao G, Zhang G. Rotary spatial vibration-assisted diamond cutting of brittle materials[J]. Precision Engineering, 2015, 44:211-219.
EI論文:
23. Zhang GQ, To S, Xiao GB. Cutting Force Evolution and its Power Spectrum Analysis with Tool Wear Progress in Ultra-Precision Raster Milling[C]. Key Engineering Materials,2014, 625: 20-25.
24. Zhang GQ, To S. Diamond tool wear detection method using cutting force and its power spectrum analysis in ultra-precision fly cutting[C]. 7th International Symposium on Advanced Optical Manufacturing and Testing Technologies (AOMATT 2014). International Society for Optics and Photonics, 2014: 928105-928105-10.
25. Zhang GQ, To S. A Novel Tool Wear Measurement Method in Ultra-Precision Raster Milling[J]. Key Engineering Materials, 2016, 679:123-127.
26. Xiao G, To S, Zhang G. A study of chip formation in ductile-regime machining of 6H silicon carbide by molecular dynamics[J]. International Journal of Nanomanufacturing, 2015, 11(1-2): 64-77.
27. 張國慶, 杜建軍. 精密裝配用並在線上器人標定及機構誤差分析[J], 哈爾濱工業大學學報, 2013, 45(02):47-52.
28. 張國慶, 杜建軍. 精密小型Hexapod並在線上器人標定實驗及精度分析[J], 納米技術與精密工程, 2013, 11(1):34-40. (EI)
29. 杜建軍, 張國慶, 劉 暾. 均壓槽與靜壓氣體軸頸軸承承載特性的關係研究[J], 機械工程學報, 2012, 48(15): 106-112.
1. Zhang G, To S, Xiao G. A novel spindle inclination error identification and compensation method in ultra-precision raster milling[J]. International Journal of Machine Tools and Manufacture, 2014, 78: 8-17.
2. Zhang G, To S, Xiao G. The relation between chip morphology and tool wear in ultra-precision raster milling[J]. International Journal of Machine Tools and Manufacture, 2014, 80: 11-17.
3. Zhang G, To S, Zhang S. Evaluation for tool flank wear and its influences on surface roughness in ultra-precision raster fly cutting[J], International Journal of Mechanical Sciences, 2016, 118:125-134.
4. Zhang G, To S. A novel surface quality evaluation method in ultra-precision raster milling using cutting chips[J]. Journal of Materials Processing Technology, 2015, 219: 328-338.
5. Zhang G, To S, Xiao G. Novel tool wear monitoring method in ultra-precision raster milling using cutting chips[J]. Precision Engineering, 2014, 38(3): 555-560.
6. Zhang G, To S, Zhang S, Zhu Z. Case study of surface micro-waves in ultra-precision raster fly cutting[J], Precision Engineering, 2016, 46:393-398.
7. Zhang G, To S, Zhang S. Relationships of tool wear characteristics to cutting mechanics, chip formation, and surface quality in ultra-precision fly cutting[J]. The International Journal of Advanced Manufacturing Technology, 2016, 83(1-4): 133-144.
8. Zhang G, To S. An in-process tool wear evaluation approach for ultra-precision fly cutting[J], International Journal of Advanced Manufacturing Technology, 2016, 86(1-4): 169-177.
9. Zhang G, Du J, To S. Study of the workspace of a class of universal joints[J]. Mechanism and Machine Theory, 2014, 73: 244-258.
10. Zhang G, Du J, To S. Calibration of a small size hexapod machine tool using coordinate measuring machine[J]. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 2016, 230(3):183-197.
11. Zhang G, To S. Relation between tool wear and workpiece modal vibration in ultra-precision raster fly cutting[J]. International Journal of Advanced Manufacturing Technology, 2017, 93(9-12):3505-3515.
12. To S, Zhang G*. Study of cutting force in ultra-precision raster milling of V-groove[J]. The International Journal of Advanced Manufacturing Technology, 2014, 75(5-8): 967-978.
13. Du J, Zhang G*, Liu T, To S. Improvement on load performance of externally pressurized gas journal bearings by opening pressure-equalizing grooves[J]. Tribology International, 2014, 73: 156-166.
14. Cheng CT, Zhang G, To S. Wetting characteristics of bare micro-patterned cyclic olefin copolymer surfaces fabricated by ultra-precision raster milling[J], RSC Advances, 2016, 6(2):1562-1570.
15. Xiao G, To S, Zhang G. Molecular dynamics modelling of brittle–ductile cutting mode transition: Case study on silicon carbide[J]. International Journal of Machine Tools and Manufacture, 2015, 88: 214-222.
16. Zhang SJ, To S, Zhang GQ, Zhu ZW. A review of machine-tool vibration and its influence upon surface generation in ultra-precision machining[J]. International Journal of Machine Tools and Manufacture, 2015, 91: 34-42.
17. Xiao G, To S, Zhang G. The mechanism of ductile deformation in ductile regime machining of 6H SiC[J]. Computational Materials Science, 2015, 98: 178-188.
18. Zhang SJ, To S, Zhang GQ. Diamond tool wear in ultra-precision machining[J], The International Journal of Advanced Manufacturing Technology, 2016. doi:10.1007/s00170-016-8751-9.
19. Zhang SJ, To S, Zhu ZW, Zhang GQ. A review of fly cutting applied to surface generation in ultra-precision machining[J], International Journal of Machine Tools and Manufacture, 2016, 103:13–27.
20. Zhang Q, To S, Zhao Q, Guo B., Zhang G. Impact of material microstructure and diamond grit wear on surface finish in micro-grinding of RB-SiC/Si and WC/Co carbides[J]. International Journal of Refractory Metals and Hard Materials, 2015, 51: 258-263.
21. Zhang SJ, To S, Wang SJ, Zhang GQ. A new representation with probability distribution for nanometric surface roughness in ultra-precision machining[J]. Precision Engineering, 2016, 45:445-449.
22. Zhu Z, To S, Xiao G, Zhang G. Rotary spatial vibration-assisted diamond cutting of brittle materials[J]. Precision Engineering, 2015, 44:211-219.
EI論文:
23. Zhang GQ, To S, Xiao GB. Cutting Force Evolution and its Power Spectrum Analysis with Tool Wear Progress in Ultra-Precision Raster Milling[C]. Key Engineering Materials,2014, 625: 20-25.
24. Zhang GQ, To S. Diamond tool wear detection method using cutting force and its power spectrum analysis in ultra-precision fly cutting[C]. 7th International Symposium on Advanced Optical Manufacturing and Testing Technologies (AOMATT 2014). International Society for Optics and Photonics, 2014: 928105-928105-10.
25. Zhang GQ, To S. A Novel Tool Wear Measurement Method in Ultra-Precision Raster Milling[J]. Key Engineering Materials, 2016, 679:123-127.
26. Xiao G, To S, Zhang G. A study of chip formation in ductile-regime machining of 6H silicon carbide by molecular dynamics[J]. International Journal of Nanomanufacturing, 2015, 11(1-2): 64-77.
27. 張國慶, 杜建軍. 精密裝配用並在線上器人標定及機構誤差分析[J], 哈爾濱工業大學學報, 2013, 45(02):47-52.
28. 張國慶, 杜建軍. 精密小型Hexapod並在線上器人標定實驗及精度分析[J], 納米技術與精密工程, 2013, 11(1):34-40. (EI)
29. 杜建軍, 張國慶, 劉 暾. 均壓槽與靜壓氣體軸頸軸承承載特性的關係研究[J], 機械工程學報, 2012, 48(15): 106-112.
代表專利:
已授權中國發明專利
1. 張國慶, 趙智明. 減速機構:中國, ZL 201010131550.9[P]. 2015.02.04.
2. 趙智明, 張國慶. 萬向節: 中國, ZL 201010565789.7[P]. 2014-04-30.
3. 張國慶. 機器人臂部件: 中國, ZL 201010283622.1[P]. 2014-03-26.
4. 趙智明, 張國慶, 戴家鵬. 減速機構: 中國, ZL 201010130422.2[P]. 2014-03-26.
5. 張國慶, 趙智明. 球頭關節: 中國, ZL 201010185478.8[P]. 2014-03-26.
6. 張國慶, 趙智明. 減速機構: 中國, ZL 200910312395.8[P]. 2014-03-26.
7. 張國慶, 戴家鵬. 磁齒輪: 中國, ZL 201010264809.7[P]. 2014-02-19.
8. 張國慶, 趙智明, 周炯. 並在線上器人: 中國, ZL 200910310233.0[P]. 2014-01-22.
9. 張國慶; 王其軍. 碼垛機器人: 中國, ZL 201010157207.1[P]. 2014-01-22.
10. 張國慶, 戴家鵬, 徐曉明. 六自由度運動平台: 中國, ZL 201010267976.7[P]. 2013-12-11.
11. 周炯, 趙智明, 張國慶. 減速機構及其採用的傳動裝置: 中國, ZL 200910310250.4[P]. 2013-11-20.
12. 張國慶, 趙智明, 馮勇. 並在線上構: 中國, ZL 200910309948.4[P]. 2013-11-20.
13. 張國慶, 徐曉明. 行星齒輪傳動機構: 中國, ZL 200910306355.2[P]. 2013-11-20.
14. 張國慶, 趙智明.並在線上器人: 中國, ZL 200910310013.8[P]. 2013-08-28.
15. 張國慶, 徐曉明. 偏心擺線型減速機構: 中國, ZL 200910306967.1[P]. 2013-06-05.
16. 張國慶. 連線機構: 中國, ZL 201010158341.3[P]. 2013-01-09.
已授權美國發明專利:
1. Zhou J, Zhao Z M, Zhang G Q. Deceleration mechanism and transmission device utilized thereby: U.S. Patent 8,820,183[P]. 2014-9-2.
2. Zhang G Q. Robotic arm assembly: U.S. Patent 8,607,659[P]. 2013-12-17.
3. Zhao Z M, Zhang G Q, Day C P. Deceleration mechanism: U.S. Patent 8,601,898[P]. 2013-12-10.
4. Zhang G Q, Zhao Z M. Deceleration mechanism: U.S. Patent 8,596,159[P]. 2013-12-3.
5. Zhang G Q. Robot arm system: U.S. Patent 8,511,198[P]. 2013-8-20.
6. Zhang G Q, Zhao Z M. Motion transmitting mechanism: U.S. Patent 8,511,187[P]. 2013-8-20.
7. Zhang G Q, Day C P, Xu X M. Mobile platform with six degrees of freedom: U.S. Patent 8,505,392[P]. 2013-8-13.
8. Zhang G Q, Wang Q J. Palletizing robot: U.S. Patent 8,491,250[P]. 2013-7-23.
9. Zhang G Q, Xu X M. Planetary gear transmission mechanism: U.S. Patent 8,475,318[P]. 2013-7-2.
10. Zhao Z M, Zhang G Q. Universal joint: U.S. Patent 8,469,830[P]. 2013-6-25.
11. Zhang G Q, Zhao Z M, Zhou J. Parallel robot: U.S. Patent 8,418,579[P]. 2013-4-16.
12. Zhang G Q, Zhao Z M. Universal ball joint: U.S. Patent 8,353,776[P]. 2013-1-15.
13. Zhang G Q, Zhao Z M. Parallel robot: U.S. Patent 8,272,290[P]. 2012-9-25.
14. Zhang G Q. Connecting mechanism: U.S. Patent 8,267,615[P]. 2012-9-18.
1. 張國慶, 趙智明. 減速機構:中國, ZL 201010131550.9[P]. 2015.02.04.
2. 趙智明, 張國慶. 萬向節: 中國, ZL 201010565789.7[P]. 2014-04-30.
3. 張國慶. 機器人臂部件: 中國, ZL 201010283622.1[P]. 2014-03-26.
4. 趙智明, 張國慶, 戴家鵬. 減速機構: 中國, ZL 201010130422.2[P]. 2014-03-26.
5. 張國慶, 趙智明. 球頭關節: 中國, ZL 201010185478.8[P]. 2014-03-26.
6. 張國慶, 趙智明. 減速機構: 中國, ZL 200910312395.8[P]. 2014-03-26.
7. 張國慶, 戴家鵬. 磁齒輪: 中國, ZL 201010264809.7[P]. 2014-02-19.
8. 張國慶, 趙智明, 周炯. 並在線上器人: 中國, ZL 200910310233.0[P]. 2014-01-22.
9. 張國慶; 王其軍. 碼垛機器人: 中國, ZL 201010157207.1[P]. 2014-01-22.
10. 張國慶, 戴家鵬, 徐曉明. 六自由度運動平台: 中國, ZL 201010267976.7[P]. 2013-12-11.
11. 周炯, 趙智明, 張國慶. 減速機構及其採用的傳動裝置: 中國, ZL 200910310250.4[P]. 2013-11-20.
12. 張國慶, 趙智明, 馮勇. 並在線上構: 中國, ZL 200910309948.4[P]. 2013-11-20.
13. 張國慶, 徐曉明. 行星齒輪傳動機構: 中國, ZL 200910306355.2[P]. 2013-11-20.
14. 張國慶, 趙智明.並在線上器人: 中國, ZL 200910310013.8[P]. 2013-08-28.
15. 張國慶, 徐曉明. 偏心擺線型減速機構: 中國, ZL 200910306967.1[P]. 2013-06-05.
16. 張國慶. 連線機構: 中國, ZL 201010158341.3[P]. 2013-01-09.
已授權美國發明專利:
1. Zhou J, Zhao Z M, Zhang G Q. Deceleration mechanism and transmission device utilized thereby: U.S. Patent 8,820,183[P]. 2014-9-2.
2. Zhang G Q. Robotic arm assembly: U.S. Patent 8,607,659[P]. 2013-12-17.
3. Zhao Z M, Zhang G Q, Day C P. Deceleration mechanism: U.S. Patent 8,601,898[P]. 2013-12-10.
4. Zhang G Q, Zhao Z M. Deceleration mechanism: U.S. Patent 8,596,159[P]. 2013-12-3.
5. Zhang G Q. Robot arm system: U.S. Patent 8,511,198[P]. 2013-8-20.
6. Zhang G Q, Zhao Z M. Motion transmitting mechanism: U.S. Patent 8,511,187[P]. 2013-8-20.
7. Zhang G Q, Day C P, Xu X M. Mobile platform with six degrees of freedom: U.S. Patent 8,505,392[P]. 2013-8-13.
8. Zhang G Q, Wang Q J. Palletizing robot: U.S. Patent 8,491,250[P]. 2013-7-23.
9. Zhang G Q, Xu X M. Planetary gear transmission mechanism: U.S. Patent 8,475,318[P]. 2013-7-2.
10. Zhao Z M, Zhang G Q. Universal joint: U.S. Patent 8,469,830[P]. 2013-6-25.
11. Zhang G Q, Zhao Z M, Zhou J. Parallel robot: U.S. Patent 8,418,579[P]. 2013-4-16.
12. Zhang G Q, Zhao Z M. Universal ball joint: U.S. Patent 8,353,776[P]. 2013-1-15.
13. Zhang G Q, Zhao Z M. Parallel robot: U.S. Patent 8,272,290[P]. 2012-9-25.
14. Zhang G Q. Connecting mechanism: U.S. Patent 8,267,615[P]. 2012-9-18.
