Evaluation of minimum quantity lubrication grinding with nano-particles and recent related patents

Recent Patents on Nanotechnology

Volumn 7, Issue 2, 2013, Pages 167-181

  Li, Changhe ^a   Wang, Sheng ^a   Zhang, Qiang ^a   Jia, Dongzhou ^a  

^a QINGDAO TECHNOLOGICAL UNIVERSITY   (China)

Author keywords

Cooling performance; Friction coefficient; G ratio; Grinding; Grinding zone temperature; Lubricating properties; Minimum quantity lubrication (MQL); Nano particles; Specific grinding energy; Tribological features

Indexed keywords

COOLING PERFORMANCE; FRICTION COEFFICIENTS; G RATIO; GRINDING ZONE TEMPERATURES; LUBRICATING PROPERTIES; MINIMUM QUANTITY LUBRICATION; SPECIFIC GRINDING ENERGY; TRIBOLOGICAL FEATURES;

ATMOSPHERIC TEMPERATURE; COOLING; DROPS; EXPERIMENTS; FRICTION; INTERFACES (MATERIALS); LUBRICATING OILS; NANOPARTICLES; PATENTS AND INVENTIONS; SEALS; SOLID LUBRICANTS; TRIBOLOGY; WEAR RESISTANCE;

GRINDING (MACHINING);

NANOPARTICLE;

CHEMISTRY; FRICTION; HYDRODYNAMICS; LUBRICATION; PATENT; REVIEW; SURFACE PROPERTY; THERMODYNAMICS;

FRICTION; HYDRODYNAMICS; LUBRICATION; NANOPARTICLES; PATENTS AS TOPIC; SURFACE PROPERTIES; THERMODYNAMICS;

EID: 84888060362     PISSN: 18722105     EISSN: None     Source Type: Journal    
DOI: 10.2174/18722105113079990001     Document Type: Article

References (60)

1. Kopac J, Krajnik P. High-performance grinding-A review. Mater Process Technol 2006, 175 (1-3), 278-284.
2. Varghese B, Hare S P, Gao R, Guo C and Malkin S. Development of a sensor-integrated 'Intelligent' grinding wheel for in-process monitoring. Ann CIRP 2000, 49 (1), 265-270.
3. Brinksmeier E, Mutlugunes Y, Klocke F, et al. Ultra-precision grinding. CIRP Ann Manuf Technol 2010. 59 (2), 652-671.
4. Wegener K, Hoffmeister H-W, Karpuschewski B, et al. Conditioning and Monitoring of Grinding Wheels. CIRP Ann Manuf Technol 2011. 60 (2), 757-778.
5. Oliveira F G, Silva E J, Guo C, et al. Industrial challenges in grinding. CIRP Ann Manuf Technol 2009. 58 (2), 663-680.
6. Liu J H, Pei Z J, Graham R F. Grinding wheels for manufacturing of silicon wafers: A literature review. Int J Mach Tool Manu 2007, 47 (1), 1-13.
7. Li C H, Cai G Q and Xiu S C. Auto-correlation study on the surface profile finished by abrasive jet with grinding wheel as restraint. Int J Comput Appl T 2007, 29 (2-4), 262-265.
8. Li C H, Hou Y L, Du C and Ding Y C. An analysis of the electric spindle's dynamic characteristics of high speed grinder. J Adv Manufac Sys 2011, 10 (1), 159-166.
9. Jin T. and Cai G. Q. Analytical thermal models of oblique moving heat source plane for deep grinding and cutting. J Manufac Sci Eng A Soc Mechan Eng 2001, 123 (1), 185-190.
10. Malkin S, Guo C. Thermal Analysis of Grinding. CIRP Ann Manuf Technol 2007. 56 (2), 760-782.
11. Brinksmeier E, Aurich J C, Govekar E, et al. Advances in Modeling and Simulation of Grinding Processes. CIRP Ann Manuf Technol 2006. 55 (2), 667-697.
12. Klocke F, Brinksmeier E, Weinert K. Capability Profile of Hard Cutting and Grinding Processes. CIRP Ann Manuf Technol 2005. 54 (2), 557-581.
13. Xiu S C, Chao C X and Pei S Y. Experimental research on surface integrity with less or non fluid grinding process. Key Eng. Mater 2011; 487 (8), 89-93.
14. Li C H, Hou Y L, Ding Y C, Cai G Q. Feasibility investigations on compound process: a novel fabrication method for finishing with grinding wheel as restraint. Int J Compu Mat Sci Sur Eng 2011; 4(1), 55-68.
15. Li C H, Wang S, Zhang Q and Ding Y C. Influence of Unbalanced Response of Ultra-high Speed Grinder Spindle on Dynamic Performance. Int J Mat Prod Technol 2012, 45 (1/2/3/4), 119-131.
16. Aurich S C, Braun O and Warnecke G. Development of a superabrasive grinding wheel with defined grain structure using kinematic simulation. Ann CIRP 2003, 52(1), 275-280.
17. Malkin S., Guo C. Grinding Technology: The Way Things Can Work: Theory and Application of Machining with Abrasives. Industrial Press Inc., 2008.
18. Huang H and Liu T C. Experimental investigations of machining characteristics and removal mechanisms of advanced ceramics in high speed deep grinding. Int J Machine T Manuf 2003, 43 (8), 811-823.
19. Xu X P, Yu Y Q and Xu H J. Effect of grinding temperature on the surface integrity of a nickel-based superalloy. J. Mater. Process. Technol. 2002, 129 (1-3), 359-363.
20. Webster J, Tricard M. Innovations in Abrasive Products for Precision Grinding. CIRP Ann Manuf Technol 2004. 53 (2), 597-618.
21. Evans C J, Paul E, Dornfeld D, et al. Material Removal Mechanisms in Lapping and Polishing. CIRP Ann Manuf Technol 2003. 52 (2), 611-634.
22. Hwang T W, Evans C J and Malkin S. An investigation of high speed grinding with electroplated diamond wheels. Ann CIRP 2000, 49(1), 245-248.
23. Li C H, Liu Z R, Liu G Y, and Ding Y C. Experimental Investigations of Mechanical Characteristics and Tribological Mechanisms of Nanometric Zirconia Dental Ceramics. The Open Mat Sci J 2011; 5, 178-183.
24. 2 Dental Ceramic Grinding. Int. J. Machin Machinab Mat 2012; 11(4), 342-352.
25. Zhu L D, Wang W S. Modeling and Experiment of Dynamic Performance of the Linear Rolling Guide in Turn-milling Centre. Adv Sci Lett 2011; 4(6), 1913-1917.
26. Byrne G, Dornfeld D, Denkena B. Advancing Cutting Technology. CIRP Ann Manuf Technol 2003. 52 (2), 483-508.
27. Hou Y L, Li C H, Han Z L, Li J Y and Ding Y C. Examination of the Material Removal Mechanisms During the Abrasive Jet Finishing of 45 Steel. Adv Sci Lett 2011, 4(4-5), 1478-1484.
28. Hou Y L, Li C H and Zhang Q. Investigation of structural parameters of high speed grinder spindle system on dynamic performance. Int. J. Mat Prod Technol 2012; 44 (1/2), 92-114.
29. Li C H, Liu Z R, Hou Y L, Ding Y C. Analytical and Experimental Investigation into Material Removal Mechanism of Abrasive Jet Precision Finishing with Grinding Wheel as Restraint. Int. J. Machin Machinab Mat 2012, 12 (3), 266-279.
30. Hou Y L, Li C H, Zhou Y. Applications of High-Efficiency Abrasive Process with CBN Grinding Wheel. Eng 2010. 2(3), 184-189.
31. Gu R J, Shillor M, Barber G C. Thermal Analysis of the Grinding Process. Math Comput Model 2004; 39 (9/10), 991-1003.
32. Li C H, Hou Y L, Liu Z R, Ding Y C. (2011b) 'Investigation into temperature field of nano-zirconia ceramics precision grinding', Int J Abrasive Technol, Vol. 4, No. 1, pp. 77-89.
33. Kalita P, Malshe A P, Kumar S A, et al. Study of specific energy and friction coefficient in minimum quantity lubrication grinding using oil-based nanolubricants[J]. J Manufact Processes 2012. 14(2): p. 160-166.
34. Tawakoli T, Hadad M J, Sadeghi M. H. Influence of oil mist parameters on minimum quantity lubrication-MQLgrinding process. Int J Mach Tools Manuf 2010, 50(6): 521-531.
35. Barczak L M, Batako A D L, Morgan M N. A study of plane surface grinding under minimum quantity lubrication (MQL) conditions. Int J Mach Tools Manuf 2010, 50(11): 977-985.
36. Wang Sheng, Li Changhe and Zhang Qiang. Evaluation of Grinding Performance in Minimum Quantity Lubrication with Nanoparticles. Manufact Technol Mach Tool 2013, 2: 86-89.
37. Li C H, Hou Y L, Xiu S C, et al. Application of lubrication theory to near-dry-green grinding-feasibility analysis. Adv Mater Res. 2008, 135(4): p. 44-46.
38. Weinert K, Inasaki I, Sutherl J W, et al. Dry Machining and Minimum Quantity Lubrication. Ann CIRP 2004, Vol. 53(2): p. 323-349.
39. Sadeghi M H, Haddad M J, Tawakoli T, et al. Minimal quantity lubrication-MQL in grinding of Ti-6Al-4V titanium alloy. Int. J. Adv. Manuf. Technol 2009, Vol. 44, p. 487-500.
40. Kalita P, Malshe A P, Rajurkar K P. Study of tribo-chemical lubricant film formation during application of nanolubricants in minimum quantity lubrication (MQL) grinding. CIRP Ann Manuf Technol 2012; 61(1): 327-30.
41. Shen B, Shih A J, Tung S C. Application of Nanofluids in Minimum Quantity Lubrication Grinding. Tribol Trans 2008; 51(6): 730-737.
42. Li C H, Li J Y, Wang S, et al. Modeling and Numerical Simulation of the Grinding Temperature Field with Nano-particle Jet of MQL. Volume 2013 (2013), Article ID 986984, 9 pages.
43. Barczak L M & Batako A D. Application of Minimum Quantity Lubrication in Grinding. Mater Manuf Processes 2012, 27(4): 406-411.
44. Tawakoli T, Hadad M J, Sadeghi M. H, et al. An experimental investigation of the effects of workpiece and grinding parameters on minimum quantity lubrication-MQL grinding. Int J Mach Tools Manuf 2009, 49(12/13): 924-932.
45. Zhang Qiang, Li Changhe and Wang Sheng. Analysis of Cooling Characteristic for Minimum Quantity Lubrication with Nanoparticles. Manuf Technol Mach Tool 2013, 3: 91-96.
46. Wen D, Ding Y. Experimental investigation into the pool boiling heat transfer of aqueous based-alumina nanofluids. J Nanopart Res 2005; 7(2): 265-74.
47. Lee S, Choi Li S. Measuring thermal conductivity of fluids containing oxide nanoparticles. ASME J Heat Trans 1999, vol. 121, no. 2: 280-289.
48. Liu Z-H, Qiu Y-H. Boiling heat transfer characteristics of nanofluids jet impingement on a plate surface. Heat Mass Transfer 2007; 43(7): 699-706.
49. Mohammadjafar Hadad, Banafsheh Sadeghi. Thermal analysis of minimum quantity lubrication-MQL grinding process. Int J Mach Tools Manuf 2012, 63 (12), 1-15.
50. Liu Zhanrui. The Research of Heat Transfer Theory by Nanofluids Jet Lubrication and the Evaluation of the Surface Integrity in Grinding. Qingdao Technological University, 2010, 12.
51. Cheol C, Mihee J, Youngmin C, et al. Tribological Properties of Lubricating Oil-Based Nanofluids with Metal/Carbon Nanoparticles[J]. J Nanosci Nanotechnol 2011; 11: 368-74.
52. Li Changhe, Wang Sheng, Zhang Qiang. Nanoparticle jet flow minimum quantity lubrication grinding lubricant supply system. CN102658526A (2012).
53. Suda Satoshi, Yokota Hideo, Kochu Tomoyasu, Matsuura Yoshiaki. Oil Composition for Use in Trace Oil Supply Cutting/Grinding Work. US8173582B2 (2012).
54. Li Changhe, Wang Sheng, Zhang Qiang. Method and device for the prediction of the grinding surface roughness under nano-particle jet MQL. CN102954756A(2013).
55. Li Changhe, Han Zhenlu, Li Jingyao, et al. Three-phase flow supply system of nano-particle jet MQL grinding. CN102287606A (2011).
56. Li Changhe, Jia Dongzhou, Wang sheng, et al. The technology and device of the formation of micro-bulge oil film on the workpiece surface under nano-particles jet flow. CN102954645A (2013).
57. Li Changhe, Hou Yali and Ding Yucheng. Technique of carbon nano tube (CNT) jet for the grinding of nickel-base alloy. CN102267098A (2011).
58. Li Changhe, Liu Zhanrui, Hou Yali, et al. grinding process and equipment with nano-fluids. CN101722477A (2011).
59. Li Changhe, Li Jingyao, Han Zhenlu, et al. A measuring equipment of thermal characteristics of nano-fluids. 102323293A (2012).
60. Shibata Junichi, Sembongi Norio, Ibi Masanori, et al. Oil composition, and trace amount oil supply type cutting/grinding processing method. EP2546325A1 (2013).