[1] 袁松梅,朱光远,王莉. 绿色切削微量润滑技术润滑剂特性研究进展[J]. 机械工程学报,2017,53(17):131-140. YUAN Songmei,ZHU Guangyuan,WANG Li. Research progress on lubricant characteristics of green cutting micro-lubrication technology[J]. Journal of Mechanical Engineering,2017,53(17):131-140.
[2] SHARMA A K, TIWARI A K,DIXIT A R.Effects of minimum quantity lubrication (MQL) in machining processes using conventional and nanofluid based cutting fluids:A comprehensive review[J]. Journal of Cleaner Production,2016,127:1-18
[3] WANG Y, LI C,ZHANG Y,et al. Experimental evaluation of the lubrication properties of the wheel/workpiece interface in minimum quantity lubrication (MQL) grinding using different types of vegetable oils[J].Journal of Cleaner Production,2016,127:487-499.
[4] SU Y,GONG L,LI B,et al. Performance evaluation of nanofluid MQL with vegetable-based oil and ester oil as base fluids in turning[J]. International Journal of Advanced Manufacturing Technology,2016,83(9-12):2083-2089.
[5] WANG Y,LI C,ZHANG Y,et al. Experimental evaluation of the lubrication properties of the wheel/workpiece interface in MQL grinding with different nanofluids[J]. Tribology International,2016,99:198-210.
[6] HÖHN B R,MICHAELIS K. Influence of oil temperature on gear failures[J]. Tribology International,2004,37(2):103-109.
[7] WANG Yufu,HUANG Yun,huang Zhi,et al. Belt grinding of TC4 based on the technology of cryogenic mist jet combined MQL[J]. Key Engineering Materials, 2009,416:8-12.
[8] De CHIFFRE L,ANDREASEN J L,LAGERBERG S. Performance testing of cryogenic CO2 as cutting fluid in parting/grooving and threading austenitic stainless steel[J]. Annals of the CIRP, 2007,56(1):101-104.
[9] YUAN Songmei,HOU Xuebo,ZHU Guangyuan,et al. A novel approach of applying copper nanoparticles in minimum quantity lubrication for milling of Ti-6Al-4V[J]. Advances in Production Engineering & Management,2017,12(2):139-150.
[10] VENUGOPAL K A,PAUL S,CHATTOPADHYAY A B. Tool wear in cryogenic turning of Ti-6Al-4V alloy[J]. Cryogenics,2007,47(1):12-18.
[11] PEREIRA O,CATALÀP,RODRÍGUEZ A. The use of hybrid CO2+MQL in machining operations[J]. Procedia Engineering,2015,132:92-499.
[12] SU Y,HE N,LI L,et al. An experimental investigation of effects of cooling/lubrication conditions on tool wear in high-speed end milling of Ti-6Al-4V[J]. Wear,2006,261(7-8):760-766.
[13] NGUYEN T,ZHANG L C. An assessment of the applicability of cold air and oil mist in surface grinding[J]. Journal of Materials Processing Technology,2003,140(1-3):224-230.
[14] SABERI A,RAHIMI A R,PARSA H,et al. Improvement of surface grinding process performance of CK45 soft steel by minimum quantity lubrication (MQL) technique using compressed cold air jet from vortex tube[J].Journal of Cleaner Production,2016,131:728-738.
[15] 董晋标. 微通道内流体的流动与换热的理论研究和数值分析[D]. 西安:西安电子科技大学,2007. DONG Jinbiao. Theoretical study and numerical analysis of fluid flow and heat transfer in microchannels[D]. Xi'an:Xidian University,2007.
[16] RINI D P,CHEN R H,CHOW L C. Bubble behavior and nucleate boiling heat transfer in saturated FC-72 spray cooling[J].Journal of Heat Transfer,2002,124:63-72.
[17] 刘江涛. 微通道内单相和相变传热机理与界面特性[D]. 北京:清华大学,2008. LIU Jiangtao. Single-phase and phase-change heat transfer mechanism and interface characteristics in microchannels[D]. Beijing:Tsinghua University,2008.
[18] PARK K H, EWALD B,KWON P Y. Effect of nano-enhanced lubricant in minimum quantity lubrication balling milling[J]. Journal of Tribology,2011,133(3):031803.
[19] 袁松梅,刘思,严鲁涛. 低温微量润滑技术在几种典型难加工材料加工中的应用[J]. 航空制造技术,2011(14):45-47. YUAN Songmei,LIU Si,YAN Lutao. Application of low temperature micro lubrication technology in processing of several typical difficult machining materials[J]. Aviation Manufacturing Technology,2011(14):45-47.
[20] NANDY A K,GOWRISHANKAR M C,PAUL S. Some studies on high-pressure cooling in turning of Ti-6Al-4V[J]. International Journal of Machine Tools & Manufacture,2009,49(2):182-198.
[21] YAN L T,YUAN S M,LIU Q. Effect of cutting parameters on minimum quantity lubrication machining of high strength steel[C]//Materials Science Forum. Trans Tech Publications,2009,626:387-392.
[22] PEREIRA O,RODRÍGUEZ A,BARREIRO J,et al. Nozzle design for combined use of MQL and cryogenic gas in machining[J]. International Journal of Precision Engineering and Manufacturing,2017,4(1):87-95.
[23] 袁松梅,朱光远,刘思,等. 低温微量润滑技术喷嘴方位正交试验研究[J]. 航空制造技术,2016,505(10):64-69. YUAN Songmei,ZHU Guangyuan,LIU Si,et al.Study on orthogonal test of nozzle azimuth in low temperature and micro lubrication technology[J]. Aeronautical Manufacturing Technology,2016,505(10):64-69.
[24] PARK K H.YANG G D,SUHAIMI M A,et al. The effect of cryogenic cooling and minimum quantity lubrication on end milling of titanium alloy Ti-6Al-4V[J]. Journal of Mechanical Science and Technology,2015,29(12):5121-5126.
[25] PARK K H, SUHAIMI M A,YANG G D,et al.Milling of titanium alloy with cryogenic cooling and minimum quantity lubrication (MQL)[J]. International Journal of Precision Engineering and Manufacturing,2017,18(1):5-14.
[26] 苏宇,何宁,李亮,等. 低温氮气射流对钛合金高速铣削加工性能的影响[J]. 中国机械工程,2006,17(11):1183-1187. SU Yu,HE Ning,LI Liang,et al. Effect of low temperature nitrogen jet on high speed milling performance of titanium alloy[J]. China Mechanical Engineering,2006,17(11):1183-1187.
[27] ITURBE A,HORMAETXE E,GARAY A,et al. Surface integrity analysis when machining Inconel 718 with conventional and cryogenic cooling[J]. 3rd CIRP Conference on Surface Integrity(CIRP CSI) 45(2016):67-70.
[28] CORDES S,HUBNER F,SCHAARSCHMIDT T. Next generation high performance cutting by use of carbon dioxide as cryogenics[J]. Procedia CIRP 14,2014:401-405.
[29] SANCHEZ J A,POMBO I,ALBERDI R,et al. Machining evaluation of a hybrid MQL-CO2 grinding technology[J]. Journal of Cleaner Production,2010,18(18):1840-1849.
[30] GIASIN K,AYVAR S S,HODZIC A. The effects of minimum quantity lubrication and cryogenic liquid nitrogen cooling on drilled hole quality in GLARE fibre metal laminates[J]. Materials & Design,2016(89):996-1006.
[31] 乔文凤. 纳米金属粉的制备及其润滑性能研究[D]. 南京:南京工业大学,2006. QIAO Wenfeng. Preparation and lubrication properties of nano metal powder[D]. Nanjing:Nanjing University of Technology,2006.
[32] 黄海栋. 片状纳米石墨和无机类富勒烯二硫化钼作为润滑油添加剂的摩擦学性能[D]. 杭州:浙江大学,2006. HUANG Haidong. Tribological properties of flake nanographite and inorganic fullerene molybdenum disulfide as lubricant additives[D]. Hangzhou:Zhejiang University,2006.
[33] WU Y Y,TSUI W C,LIU T C. Experimental analysis of tribological properties of lubricating oils with nanoparticle additives[J]. Wear,2007. 262(7-8):819-825.
[34] SHEN B,MALSHE A P,KALITA P,et al. Performance of novel MoS2 nanoparticles based grinding fluids in minimum quantity lubrication grinding[J]. Transactions of NAMRI/SME,2008,36:357-364.
[35] RAHMATI B,SARHAN A A D,SAYUTI M. Morphology of surface generated by end milling AL6061-T6 using molybdenum disulfide (MoS2) nanolubrication in end milling machining[J]. Journal of Cleaner Production,2014. 66:685-691.
[36] 张东坤,李长河,贾东洲,等. 球墨铸铁纳米粒子射流微量润滑磨削性能的试验研究[J]. 制造技术与机床,2014(11):98-103. ZHANG Dongkun,LI Changhe,JIA Dongzhou,et al. Experimental study on micro-lubrication grinding performance of nodular cast iron nano-particle jet[J]. Manufacturing Technology and Machine Tools,2014(11):98-103.
[37] NGUYEN T K,DO I,KWON P. A tribological study of vegetable oil enhanced by nano-platelets and implication in MQL machining[J]. International Journal of Precision Engineering and Manufacturing,2012, 13(7):1077-1083.
[38] LUAN G,QIAN Z. Friction and wear characteristics of water-based ZnO and Al2O3 nanofluids[J]. Tribology Transactions,2012,3(55):345-350.
[39] LI Changhe,WANG Sheng,ZHANG Qiang,et al. Evaluation of minimum quantity lubrication grinding with nano-particles and recent related patents[J]. Recent Patents on Nanotechnology,2013,2(7):167-181.
[40] SAYUTI M,ERH O M,SARHAN A A D,et al. Investigation on the morphology of the machined surface in end milling of aerospace AL6061-T6 for novel uses of SiO2 nanolubrication system[J]. Journal of Cleaner Production,2014,66(4):655-663.
[41] LEE K,HWANG Y,CHEONG S. Understanding the role of nanoparticles in nano-oil lubrication[J] Tribol. Lett., 2009,35:127-131.
[42] VAJJHA R S,DAS D K. A review and analysis on influence of temperature and concentration of nanofluids on thermophysical properties,heat transfer and pumping power[J]. International Journal of Heat and Mass Transfer,2012,55:4063-4078.
[43] PADMINI R,KRISHNA P V,KRISHNA G M R. Effectiveness of vegetable oil based nanofluids as potential cutting fluids in turning AISI 1040 steel[J]. Tribology International,2016. 94:490-501.
[44] LI B,LI C,ZHANG Y,et al. Heat transfer performance of MQL grinding with different nanofluids for Ni-based alloys using vegetable oil[J]. Journal of Cleaner Production,2017,154:1-11.
[45] LEE P,LEE S W,LIM S H,et al. An experimental study on micro-grinding process with nanofluid minimum quantity lubrication (MQL)[J]. International Journal of Precision Engineering and Manufacturing,2012. 13(3):331-338.
[46] WANG Y, LI C, ZHANG Y, et al. Experimental evaluation of the lubrication properties of the wheel/workpiece interface in MQL grinding with different nanofluids[J]. Tribology International,2016(99):198-210.
[47] HE Y,JIN Y,CHEN H,et al. Heat transfer and flow behaviour of aqueous suspensions of TiO2 nanoparticles (nanofluids) flowing upward through a vertical pipe[J]. International Journal of Heat and Mass Transfer 2007,50,2272-2281.
[48] YOO D H,HONG K S,YANG H S. Study of thermal conductivity of nanofluids for the application of heat transfer fluids[J]. Thermochimica Acta,2007,455(1-2),66-69.
[49] ZHANG X,LI C,ZHANG Y,et al. Lubricating property of MQL grinding of Al2O3/SiC mixed nanofluid with different particle sizes and microtopography analysis by cross-correlation[J]. Precision Engineering,2016(47):532-545.
[50] UMA M,REDDY P,YESU R M,et al.Measurement and analysis of surface roughness in WS2 solid lubricant assisted minimum quantity lubrication (MQL) turning of Inconel 718[J]. Procedia CIRP 40(2016) 138- 143.
[51] ZHANG Y,LI C,JIA D,et al. Experimental study on the effect of nanoparticle concentration on the lubricating property of nanofluids for MQL grinding of Ni-based alloy[J]. Journal of Materials Processing Technology,2016,232:100-115.
[52] 刘永姜. 油膜附水滴切削液雾化机理理论分析及其试验研究[D]. 太原:中北大学,2010. LIU Yongjiang. Theoretical analysis and experimental study on atomization mechanism of oil film with water droplet cutting fluid[D]. Taiyuan:North University of China,2010.
[53] NAKAMURA T,DHOKIA V,NEWMAN S T. Study of environmentally conscious machining fluids of minimum oils on water[C]. Proceedings of JSPE 1999 Vernal Meeting,Tokyo,Japan,550(in Japanese).
[54] LIN H,WANG C,YUAN Y,et al. Tool wear in Ti-6Al-4V alloy turning under oils on water cooling comparing with cryogenic air mixed with minimal quantity lubrication[J]. The International Journal of Advanced Manufacturing Technology,2015,81(1-4):87-101.
[55] WANG Chengyong,LIN Haisheng,WANG Xiang,et al. Effect of different oil-on-water cooling conditions on tool wear in turning of compacted graphite cast iron[J]. Journal of Cleaner Production,2017,148:477-489.
[56] 李文举,王彪,刘永姜,等. 1Cr18Ni9Ti不锈钢车削加工中油膜附水滴冷却润滑技术研究[J]. 中国机械工程,2014,25(6):747-750. LI Wenju,WANG Wei,LIU Yongjiang,et al. Study on cooling and lubrication technology of oil film with drops in 1Cr18Ni9Ti stainless steel turning[J]. China Mechanical Engineering,2014,25(6):747-750.
[57] CHETA N,BEHERA B C,GHOSH S,et al. Wear behavior of PVD TiN coated carbide inserts during machining of Nimonic 90 and Ti6Al4V superalloys under dry and MQL conditions[J]. Ceramics International,2016, 42(13):14873-14885.
[58] De SIMONE J M. Practical approaches to green solvents[J]. Science,2002,297(5582):799-803.
[59] STEPHENSON D A,SKERLOS S J,KING A S,et al. Rough turning Inconel 750 with supercritical CO2-based minimum quantity lubrication[J]. Journal of Materials Processing Technology,2014,214(3):673-680.
[60] VENUGOPAL K A,PAUL S,CHATTOPADHYAY A B. Growth of tool wear in turning of Ti-6Al-4V alloy under cryogenic cooling[J]. Wear,2007,262(9-10):1071-1078.
[61] 单忠德,樊东黎,范宏义,等. 机械装备工业节能减排制造技术[M]. 北京:机械工业出版社,2014. SHAN Zhongde,FAN Dongli,FAN Hongyi,et al. Energy-saving and emission-reduction manufacturing technology for mechanical equipment industry[M]. Beijing:China Machine Press,2014.
[62] LIU Qiang,XIA Yimin. Convective heat transfer and flow characteristics of Cu-water nanofluid[J]. Science in China (Series E),2002,45(4),408-416.
[63] ITOIGAWA F,CHILDS T H C,NAKAMURA T,et al. Effects and mechanisms in minimal quantity lubrication machining of an aluminum alloy[J]. Wear,2006,260(3):p.339-344. |