Research Progresses on  Abrasive Fluid Jet Polishing Technology

Abstract

Abstract:

The mechanism of material removal in the process of polishing was discussed.The research results about jet machining system and platform were introduced.The development of mathematical model of abrasive fluid jet were described,including speed change model,material removal model,surface evolution model,surface roughness model,numerical simulation model.The effect laws of some major process parameters such as particle energy,jet pressure,abrasive,jet angle,stand-off distance,additive on machining results were analyzed,and the research progresses of abrasive jet polishing technology were summarized,and the probable further research was forecasted.

Key words: abrasive jet;abrasive , particle;fluid polishing;super-smooth machining;material , removal

摘要：

论述了磨料液体射流抛光过程中的材料去除机理，介绍了磨料液体射流加工系统平台的国内外研究成果。从速度变化、材料去除、表面演化、表面粗糙度、数值模拟五个方面阐述了磨料液体射流数学模型的构建状况。系统分析了主要工艺参数如磨粒动能、射流压力、磨料、喷射角度、喷射距离、添加剂对加工结果的影响规律,并总结了磨料液体射流抛光技术发展历程。最后针对其将来的研究方向与内容给出了进一步的建议与展望。

关键词: 磨料射流, 磨粒磨料, 流体抛光, 超光滑加工, 材料去除

CLC Number:

TH16

Chen Fengjun, Miao Xiangliang, Tang Yu, Yin Shaohui. Research Progresses on Abrasive Fluid Jet Polishing Technology[J]. China Mechanical Engineering, 2015, 26(22): 3116-3123.

陈逢军, 苗想亮, 唐宇, 尹韶辉. 磨料液体射流抛光技术研究进展[J]. 中国机械工程, 2015, 26(22): 3116-3123.

References

[1]邵飞,刘洪军,马颖,等.磨料水射流抛光技术及其发展[J].表面技术,2007，36(3)：64-66.
Shao Fei,Liu Hongjun,Ma Ying,et al.Polishing Techniques and Development of Abrasive Water Jet[J].Surface Technology,2007,36(3)：64-66.
[2]马占龙,刘健,王君林.射流抛光材料去除机理及影响因素分析[J].应用光学，2011，32(6)：1206-1211.
Ma Zhanlong，Liu Jian，Wang Junlin.Material Removal Mechanism and Influence Factor of Fluid Jet Polishing[J].Journal of Applied Optics, 2011,32(6)：1206-1211.
[3]张玲花.射流抛光用于纳米深度修形[J].光机电信息,2011,28(3):1-5.
Zhang Linghua.Jet Polishing for Nano-modification[J].OME Information,2011,28(3)：1-5.
[4]方慧,郭培基,余景池.液体喷射抛光材料去除机理的研究[J].光学技术，2004，30(2)：248-250.
Fang Hui,Guo Peiji,Yu Jingchi.Research on Material Removal Mechanism of Fluid Jet Polishing[J].Optical Technique,2004,30(2)：248-250.
[5]Song Xiaozong,Zhang Yong,Zhang Feihu.Study on Removal Mechanism of Nanoparticle Colloid Jet Machining[J].Advanced Materials Research,2008,53/54：363-368.
[6]刘增文,黄传真,朱洪涛.高压磨料水射流加工中材料去除机理研究[J].金刚石与磨料磨具工程,2010,30(4)：21-29.
Liu Zengwen,Huang Chuanzhen,Zhu Hongtao.Mechanism of Material Removal by High Pressure Abrasive Waterjet[J].Diamond & Abrasives Engineering,2010,30(4):21-29.
[7]施春燕，袁家虎，伍凡，等.射流抛光误差分析与材料去除稳定性研究[J].光学学报,2011,31(1)：170-174.
Shi Chunyan,Yuan Jiahu,Wu Fan,et al.Research of Errors Analysis and Material Removal Stability in Fluid Jet Polishing[J].Acta Optica Sinica,2011,31(1):170-174.
[8]施春燕，袁家虎，伍凡，等.射流抛光喷嘴的设计[J].光电工程,2008,35(12):131-135.
Shi Chunyan,Yuan Jiahu,Wu Fan，et al.Nozzle Design of Fluid Jet Polishing[J].Opto-electronic Engineering,2008,35(12)：131-135.
[9]Barletta M,Guarino S,Rubino G,et al.Progress in Fluidized Bed Assisted Abrasive Jet Machining (FB-AJM)：Internal Polishing of Aluminium Tubes[J].International Journal of Machine Tools & Manufacture,2007,47(3/4)：483-495.
[10]徐州浩通水射流科技有限公司.一种前混合磨料水射流磨料混合系统：中国，201410132350.3[P].2014-07-30.
[11]Beaucamp A,Namba Y.Super-smooth Finishing of Diamond Turned Hard X-ray Molding Dies by Combined Fluid Jet and Bonnet Polishing[J].CIRP Annals-Manufacturing Technology,2013,62(1)：315-318.
[12]李天生,徐慧.一种磨削抛光装置的设计及其试验[J].机床与液压,2009,37(9):34-36.
Li Tiansheng,Xu Hui.The Design of Grinding and Polishing Device and Its Experimentation[J].Machine Tool & Hydraulics, 2009, 37(9):34-36.
[13]Orbanic H,Junkar M,Bajsic I，et al.An Instrument for Measuring Abrasive Water Jet Diameter[J].International Journal of Machine Tools & Manufacture,2009,49(11)：843-849.
[14]Rabani A,Marinescu I,Axinte D.Acoustic Emission Energy Transfer Rate:A Method for Monitoring Abrasive Waterjet Milling[J]. International Journal of Machine Tools & Manufacture,2012,61:80-89.
[15]Fan J,Li H,Wang J,et al.A Study of the Flow Characteristics in Micro-abrasive Jets[J].Experimental Thermal and Fluid Science, 2011,35(6):1097-1106.
[16]Narayanan C,Balz R,Weiss D A,et al.Modelling of Abrasive Particle Energy in Water Jet Machining[J].Journal of Materials Processing Technology,2013,213(12)：2201-2210.
[17]Wang J.Particle Velocity Models for Ultra-high Pressure   Abrasive Waterjets[J].Journal of Materials Processing Technology, 2009, 209(9):4573-4577.
[18]Manu R,Babu N.An Erosion-based Model for Abrasive Waterjet Turning of Ductile Materials[J].Wear,2009,266(11/12)：1091-1097.
[19]Kumar N,Shukla M.Finite Element Analysis of Multi-particle Impact on Erosion in Abrasive Water Jet Machining of Titanium Alloy[J]. Journal of Computational and Applied Mathematics,2012,236(18)：4600-4610.
[20]Tyagi R.Abrasive Jet Machining by Means of Velocity Shear Instability in Plasma[J].Journal of Manufacturing Processes, 2012, 14(3): 323-327.
[21]Azmir M A,Ahsan A K.Investigation on Glass/Epoxy Composite Surfaces Machined by Abrasive Water Jet Machining[J].Journal of Materials Processing Technology,2008,198(1/3)：122-128.
[22]Chen Tianxiang,Wang Chengyong.Investigation into Roughness of Surface Polished by Abrasive Waterjetwith Taguchi Method and Dimensional Analysis[J].Materials Science Forum，2013,723：188-195.
[23]Che Cuilian,Huang Chuanzhen,Wang J,et al.Theoretical Model of Surface Roughness for Polishing Super Hard Materials with Abrasive Waterjet[J].Key Engineering Materials,2008,375/376:465-469.
[24]Getu H,Ghobeity A,Spelt J,et al.Abrasive Jet Micro-machining of Polymethylmethacrylate[J].Wear,2007,263(7/12):1008-1015.
[25]Ma C,Deam R.A Correlation for Predicting the Kerf   Profile from Abrasive Water Jet Cutting[J].Experimental Thermal and Fluid Science, 2006,30(4)：337-343.
[26]陈林,雷玉勇,郭宗环,等.基于FLUENT的后混合磨料水射流喷嘴内流场的数值模拟[J].润滑与密封,2012,37(4):66-69.
Chen Lin,Lei Yuyong,Guo Zonghuan,et al.Numerical Simulation of Post.Mixed Abrasive Water Jet Nozzle Based on Fluent[J]. Lubrication Engineering, 2012,37(4):66-69.
[27]刘国勇,陈欣欣,朱冬梅,等.前混合磨料水射流除鳞喷嘴混合腔内部流场[J].北京科技大学学报,2014,36(6)：830-837.
Liu Guoyong,Chen Xinxin,Zhu Dongmei,et al.Internal Mixing Chamber Flow Field of a Premixed Abrasive Water Jet Descaling Nozzle[J]. Journal of University of Science and Technology Beijing，2014，36(6)：830-837.
[28]Burzynski T,Papini M.Modelling of Surface Evolution in Abrasive Jet Micro-machining Including Particle Second Strikes:A Level Set Methodology[J].Journal of Materials Processing Technology，2012,212(5)：1177-1190.
[29]潘峥正,万庆丰，雷玉勇，等.基于后混合式磨料水射流磨料颗粒运动研究[J].机床与液压,2014,42(9):109-112.
Pan Zhengzheng,Wan Qingfeng,Lei Yuyong,et al.Research on Motion of Abrasive in Post-mixed Abrasive Water Jet[J].Machine Tool & Hydraulics,2014,42(9)：109- 112.
[30]杨国来,周文会,刘肥.基于 FLUENT的高压水射流喷嘴的流场仿真[J].兰州理工大学学报,2008,34(2):49-52.
Yang Guolai,Zhou Wenhui,Liu Fei.Simulation of Flow Field of High Pressure Water Jet from Nozzle with Fluent[J].Journal of Lanzhou University of Technology,2008,34(2)：49-52.
[31]陆金刚,龚辰,闫龙龙,等.高速水射流集束性的数值模拟及试验研究[J].工程热物理学报，2014，35(8)：1526-1529.
Lu Jingang,Gong Chen,Yan Longlong,et al.Numerical Simulation and Experimental Study of the Coherence of High-speed Water Jet[J]. Journal of Endineering Thermophysics,2014,35(8):1526-1529.
[32]李兆泽,李圣怡,戴一帆,等.磨料射流抛光中各工艺参数对材料去除率及抛光区形貌的影响[J].中国机械工程，2008,19(21)：2532-2535.
Li Zhaoze,Li Shengyi,Dai Yifan,et al.Effects of Various Parameters on Material Removal Rate and the Footprint in Abrasive Jet Polishing Process[J].China Mechanical Engineering,2008,19(21):2532-2535.
[33]Tsai F,Yan B,Kuan C,et al. A Taguchi and Experimental Investigation into the Optimal Processing Conditions for the Abrasive Jet Polishing of SKD61 Mold Steel[J].International Journal of Machine Tools & Manufacture,2008,48（7/8)：932-945.
[34]Azmir M,Ahsan A.A Study of Abrasive Water Jet Machining Process on Glass/Epoxy Composite Laminate[J].Journal of Materials Processing Technology,2009,209：6168-6173.
[35]Jafar R H M,Spelt J,Papini   M.Surface Roughness and Erosion Rate of Abrasive Jet Micro-machined Channels： Experiments and Analytical Model[J].Wear,2013,303（1/2):138-145.
[36]施春燕,袁家虎,伍凡,等.喷射距离对射流抛光去除函数的影响[J].红外与激光工程,2011,40(4):685-689.
Shi Chunyan,Yuan Jiahu,Wu Fan,et al.Influence of Stand Distance on Material Removal Function Fluid Jet Polishing[J].Infrared and Laser Engineering,2011，40(4)：685-689.
[37]袁卓林,雷玉勇,孙书蕾,等.微磨料水射流对工件表面抛光作用的研究[J]. 机床与液压,2010,38(21):4-6.
Yuan Zhuolin,Lei Yuyong,Sun Shulei,et al.Study on Surface Polishing Using Micro Abrasive Water Jet[J].Machine Tool & Hydraulics, 2010, 38(21):4-6.
[38]Fowler G,Pashby I,Shipway P.The Effect of Particle Hardness and Shape When Abrasive Water Jet Milling Titanium Alloy Ti6Al4V[J]. Wear,2009,266(7/8):613-620.
[39]施春燕，袁家虎，伍凡,等.冲击角度对射流抛光中材料去除面形的影响分析[J].光学学报,2010,30(2):513-517.
Shi Chunyan,Yuan Jiahu,Wu Fan,et al.Influence Analysis of Impact Angle on Material Removal Profile in Fluid Jet Polishing[J]. Acta Optica Sinica,2010,30(2)：513-517.
[40]Ally S,Spelt J,Papini M.Prediction of Machined Surface Evolution in the Abrasive Jet Micro-machining of Metals[J]. Wear, 2012, 292/293: 89-99.
[41]Palleda M.A Study of Taper Angles and Material Removal Rates of Drilled Holes in the Abrasive Water Jet Machining Process[J]. Journal of Materials Processing Technology,2007,189(1/3):292-295.
[42]Yan B H,Tsai F,Sun L,et al.AbrasiveJet Polishing on SKD61 Mold Steel using SiC Coated with Wax[J].Journal of Materials Processing Technology，2008,208(1/3):318-329.
[43]Mimura H,Yumoto H,Matsuyama S,et al.Surface Figuring and Measurement Methods with Spatial Resolution Close to 0.1mm for X-ray Mirror Fabrication[C]//Advances in Metrology for X-ray and EUV Optics,Proceedings of SPIE Vol.5921. San Diego, CA:SPIE, 2005:1-8.
[44]Zhang Feihu,Song Xiaozong,Zhang Yong，et al.Figuring of an Ultra-smooth Surface in Nanoparticle Colloid Jet Machining[J].Journal of Micromechanics and Microengineering,2009,19(5):1-6.
[45]Wang Junlin,Ultra-precision Optical Fabrication on Fused Silica[C]//6th International Symposium on Advanced Optical Manufacturing and Testing Technologies:Advanced Optical Manufacturing Technologies. Proceedings of SPIE Vol.8416.Xiamen,2012:1-6.
[46]宋岳干,宋丹路,王堃.后混合磨料水射流对金属的抛光机制及实验研究[J].机床与液压,2013，41(3)：17-20.
Song Yuegan,Song Danlu,Wang Kun.Experimental Study of   the Metal Polishing Mechanism of   the Post Mixed Abrasive Water Jet[J]. Machine Tool & Hydraulics,2013,41(3)：17-20.
[47]Boud F,Loo L F,Kinnell   P K.The Impact of Plain Waterjet Machining on the Surface Integrity of Aluminium 7475[J]. Procedia CIRP,2014,13：382-386.

Research Progresses on Abrasive Fluid Jet Polishing Technology

磨料液体射流抛光技术研究进展

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