[1] UTHAYAKUMARL M, ADAM KHAN M, et al. Machinability of nickel-based superalloy by abrasive water jet machining[J]. Materials and Manufacturing Processes, 2016, 31:1733-1739.
[2] MANIMARAN G, KUMAR M P, VENKATASAMY R, Influence of cryogenic cooling on surface grinding of stainless steel 316[J]. Cryogenics, 2014, 59(1):76-83.
[3] CHEN J J, FU Y C, et al. Experimental investigation on high-efficiency grinding of Inconel 718 with heat pipe grinding wheel[J]. Machining Science and Technology, 2017, 21(1):86-102.
[4] LI B K, LI C H, ZHANG Y B, 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.
[5] KRZYSZTOF N. Small-dimensional sandwich grinding wheels with a centrifugal coolant provision system for traverse internal cylindrical grinding of steel 100Cr6[J]. Journal of Cleaner Production, 2015, 93:354-363.
[6] LI X. Application of self-inhaling internal cooling wheel in vertical surface grinding[J]. Chinese Journal of Mechanical Engineering, 2014, 27(1):86-91.
[7] OEZKAYA E, BEER N, BIERMANN D. Experimental studies and CFD simulation of the internal cooling conditions when drilling Inconel 718[J]. International Journal of Machine Tools & Manufacture, 2016, 108:52-65.
[8] FANG Z, OBIKAWA T. Turning of Inconel 718 using inserts with cooling channels under high pressure jet coolant assistance[J]. Journal of Materials Processing Technology, 2017, 247:19-28.
[9] FALLENSTEIN F, AURICH J C. CFD based investigation on internal cooling of twist drills[J]. Procedia CIRP, 2014, 14:293-298.
[10] AURICH J C, KIRSCH B, HERZENSTIEL P. Hydraulic design of a grinding wheel with an internal cooling lubricant supply[J]. Production Engineering, 2011, 5(2):119-126.
[11] SIENIAWSKI J, NADOLNY K. The effect upon grinding fluid demand and workpiece qualitywhen an innovative zonal centrifugal provision method is implemented in the surface grinding of steel CrV12[J]. Journal of Cleaner Production, 2016, 113:960-972.
[12] SHI C F, LI X, CHEN Z T. Design and experimental study of a micro-groove grinding wheel with spray cooling effect[J]. Chinese Journal of Aeronautics, 2014, 27(2):407-412.
[13] 彭锐涛,唐恒,唐新姿,等. 一种内冷却磨削砂轮:中国:ZL201410197728.8[P].2014-05-07. PENG Ruitao,TANG Heng,TANG Xinzi,et al. An internal cooling grinding wheel China:ZL201410197728.8[P]. 2014-05-07.
[14] 彭锐涛,张珊,唐新姿,等. 加压内冷却砂轮的研制及磨削性能研究[J]. 机械工程学报, 2017, 53(19):187-194. PENG Ruitao, ZHANG Shan, TANG Xinzi, et al. Development and grinding performance of a pressurized internal cooling slotted grinding wheel.[J]. Journal of Mechanical Engineering, 2017, 53(19):187-194.
[15] PENG R T, HUANG X F, TANG X Z, et al. Performance of a pressurized internal-cooling slotted grinding wheel system[J]. International Journal of Advanced Manufacturing Technology, 2018, 94:2239-2254.
[16] 芬尼莫尔. 流体力学及其工程应用[M]. 北京:机械工业出版社, 2006. FINNEMORE E J, FRANZINI J B. Fluid mechanics with engineering applications[M]. Beijing:China Machine Press, 2006.
[17] DING W F, BARBARA L, ZHU Y J, et al. Review on monolayer CBN superabrasive wheels for grinding metallic materials[J]. Chinese Journal of Aeronautics, 2017, 30(1):109-134.
[18] MALKIN S, GUO C. Thermal analysis of grinding[J]. CIRP Annals-Manufacturing Technology, 2007, 56(2):760-782.
[19] LI G X, RAHIM M Z B, YI S, et al. Wear mechanism of PCD tools of different grain sizes manufactured by conventionally abrasive grinding and electrical discharge grinding[J]. Materials Today Proceedings, 2017, 4(4):5248-5258. |