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Cutting Fluid Selection for a Given Machining Application

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Part of the Springer Series in Advanced Manufacturing book series (SSAM)

Keywords

Machine Tool Tool Life Surface Roughness Tangential Force Minimum Quantity Lubrication 
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References

  1. Bartz WJ (2001) Ecological and environmental aspects of cutting fluids. Lubrication Engineering 57:13–16Google Scholar
  2. Belluco W, de Chiffre L (2001) Testing of vegetable based cutting fluids by hole making operations. Lubrication Engineering 57:12–16Google Scholar
  3. Bennett BG (1987) Effects of coolants and application in using vitrified CBN grinding wheels. Carbide and Tool Journal 19:23–26.Google Scholar
  4. Brinksmeier E, Waiter A, Janssen R, Diersen P (1999) Aspects of cooling lubrication reduction in machining advanced materials. Proc. IME., Journal of Engineering Manufacture 213:769–778.CrossRefGoogle Scholar
  5. Chen Z, Wong K, Li W, Liang SY, Stephenson DA (2001) Cutting fluid aerosol generation due to spin-off in turning operation: analysis for environmentally conscious machining. Journal of Manufacturing Science and Engineering 123:507–512Google Scholar
  6. Cholakov GS, Guest TL, Rowe GW (1992) Lubricating properties of grinding fluids. 1. Comparison of fluids in surface grinding experiments. STLE Transactions 48:155–163Google Scholar
  7. Davinson JF (1995) Cutting fluids and coolants. Tooling and Production 60:4–8Google Scholar
  8. de Chiffre L (1978) Testing the overall performance of cutting fluids. STLE Transactions 34:244–251Google Scholar
  9. de Chiffre L, Lassen S, Pedersen KB, Skade S (1994) Reaming test for cutting fluid evaluation. Journal of Synthetic Lubrication 11:17–34CrossRefGoogle Scholar
  10. de Chiffre L, Belluco W, Zeng Z (2001) An investigation of reaming test parameters used for cutting fluid evaluations. Lubrication Engineering 57:24–28Google Scholar
  11. Dhar NR, Kamruzzaman M (2006) Cutting temperature, tool wear, surface roughness and dimensional deviation in turning AISI-4037 steel under cryogenic condition. International Journal of Machine Tools and Manufacture doi:10.1016/j.ijmachtools.2006.09.018Google Scholar
  12. Dhar NR, Kamruzzaman M, Ahmed M (2006) Effect of minimum quantity lubrication (MQL) on tool wear and surface roughness in turning AISI-4340 steel. Journal of Materials Processing Technology 172:299–304CrossRefGoogle Scholar
  13. Ebbrell S, Woolley NH, Tridimas YD, Allanson DR, Rowe WB (2000) The effects of cutting fluid application methods on the grinding process. International Journal of Machine Tools & Manufacture 40:209–223CrossRefGoogle Scholar
  14. Edwards W, Newman JR, Snapper K, Seaver D (1982) Multiattribute Evaluation. SAGE Publications, Newbury Park, CaliforniaGoogle Scholar
  15. Eppert JJ, Gunter KL, Sutherland JW (2001) Development of a cutting fluid classification system using cluster analysis. Tribology Transactions 44:375–382Google Scholar
  16. Ghio F (1986) Cutting fluids for operations on metal with flexible abrasive belts. Australian Machinery and Production Engineering 38:19–20Google Scholar
  17. Haq AN, Tamizharasan T (2005) Investigation of the effects of cooling in hard turning operations. International Journal of Advanced Manufacturing Technology 30:808–816Google Scholar
  18. Heinemann N, Hinduja S, Barrow G, Petuelli G (2006) Effect of MQL on the tool life of small twist drills in deep-hole drilling. International Journal of Machine Tools and Manufacture 46:1–6CrossRefGoogle Scholar
  19. Lorenz G (1985) Reliable cutting fluid rating. CIRP Annals 34:95–99CrossRefGoogle Scholar
  20. Maekawa K (1998) Computational aspects of tribology in metal machining. Proc. of I. Mech. E., Journal of Engineering Tribology 212:307–318CrossRefGoogle Scholar
  21. Nagpal BK, Sharma CS (1973) Evaluation of four common, commercially available cutting fluids used in flooding. Journal of the Institution of Engineers (India) 23:249–253Google Scholar
  22. Narheim Y, Kendig M (1987) Evaluation of the cutting fluid effectiveness in machining using electrochemical techniques. Wear 114:51–57CrossRefGoogle Scholar
  23. Obikawa T, Kamata Y, Shinozuka J (2006) High-speed grooving with applying MQL. International Journal of Machine Tools and Manufacture 46:1854–1861CrossRefGoogle Scholar
  24. Okuyama S, Nakamura Y, Kawamura S (1993) Cooling action of grinding fluid in shallow grinding. International Journal of Machine Tools & Manufacture 33:13–23CrossRefGoogle Scholar
  25. Peters J, Aerens R (1976) An objective method for evaluating grinding coolants. CIRP Annals 25:247–250Google Scholar
  26. Rao RV (2004) Performance evaluation of cutting fluids for green manufacturing using a combined multiple attribute decision making method. International Journal of Environmentally Conscious Design and Manufacturing 12:526–535Google Scholar
  27. Rao RV, Gandhi OP (2001) Digraph and matrix method for selection, identification and comparison of metal cutting fluids. Proc. IME, Journal of Engineering Tribology 212:307–318Google Scholar
  28. Rapp W (1984) Selection of cooling lubricants. VDI-Z 126:213–220Google Scholar
  29. Reddy NSK, Rao PV (2006) Experimental investigation to study the effect of solid lubricants on cutting forces and surface quality in end milling. International Journal of Machine Tools and Manufacture 46:189–198CrossRefGoogle Scholar
  30. Rowe GW (1982) Lubricant testing for grinding operations. Wear 77:73–80CrossRefGoogle Scholar
  31. Sheng PS, Oberwalleney S (1997) Life-cycle planning of cutting fluids-a review. Journal of Manufacturing Science and Engineering 119:791–800Google Scholar
  32. Sokovic M, Mijanovic K (2001) Ecological aspects of the cutting fluids and its influence on quantifiable parameters of the cutting processes. Journal of Materials Processing Technology 109:181–189CrossRefGoogle Scholar
  33. Sun J, Ge P, Zhenchang L (2001) Two-grade fuzzy synthetic decision-making system with use of an analytic hierarchy process for performance evaluation of grinding fluids. Tribology International 34:683–688CrossRefGoogle Scholar
  34. Sutcliffe T, Barber SJ, Dycan W (1979) Coolants laboratory evaluation by drill test technique using high speed drills. STLE Transactions 35:145–152Google Scholar
  35. Tan XC, Liu F, Cao HJ, Zhang H (2002) A decision-making framework model of cutting fluid selection for green manufacturing and a case study. Journal of Materials Processing Technology 129:467–470CrossRefGoogle Scholar
  36. Upton DP (2000) Optimization of cutting fluid performance. International Journal of Production Research 38:1219–1223zbMATHCrossRefGoogle Scholar
  37. Varadarajan AS, Philip PK, Ramamoorthy B (2002) Investigations on hard turning with minimal cutting fluid application (HTMF) and its comparison with dry and wet turning. International Journal of Machine Tools and Manufacture 42:193–200CrossRefGoogle Scholar
  38. Wakabayashi T, Ogura S (1990) Evaluation of cutting fluids by consumption energy in tapping test. STLE Transactions 46:715–720Google Scholar
  39. Webster JA, Cui C, Mindek RB (1995) Grinding fluid application system design. CIRP Annals 4:333–338Google Scholar
  40. Yamanaka Y, Oi T, Sakai Y, Mukai D (1996) Development of a new grinding fluid for the CBN grinding wheel. Part I. STLE Transactions 52:359–364Google Scholar
  41. Yamanaka Y, Hayama M, Oi T, Sakai Y, Satoh M (1997) Development of a new grinding fluid for the CBN grinding wheel. Part II. STLE Transactions 53:20–26Google Scholar
  42. Yamanaka Y, Hayama M, Oi T, Imai J, Satoh M (1998) Development of a new grinding fluid for the CBN grinding wheel. Part III. STLE Transactions 54:24–30Google Scholar
  43. Yamanaka Y, Hayama M, Oi T, Imai J, Satoh M (2000) Development of a new grinding fluid for the CBN grinding wheel. Part IV. STLE Transactions 56:17–24Google Scholar
  44. Yamanaka Y, Oi T, Nanao H, Satoh M (2000) Development of a new grinding fluid for the CBN grinding wheel. Part V. STLE Transactions 56:25–31Google Scholar
  45. Yuhta T, Igarashi S, Hukushima, H, Satoh T (1984) On the influence of grinding fluid in grinding carbon steel with a diamond wheel. Japan Society of Precision Engineering 1:363–368Google Scholar

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