Abstract
A new category of corrosion inhibitors has been formulated. It uses water to propagate and it has been generically referred as V-active VCI®. These inhibitors promote a greater lubricity and detergency effect, used as cutting fluids; it results in less diametrical grinding wheel wear and better workpiece finishing. It can also promote the corrosion protection of the workpiece and the machine tool since the referred substance creates a protective film on the metallic surfaces, eliminating protective oils application on the parts; thus, it permits the elimination of degreasing step, reducing the number of process steps, and minimizing the environmental impact. Furthermore, it has no risk to human’s health and it is biodegradable. This paper compares the performance of the cutting fluid with V-active VCI® to a synthetic standard fluid in grinding process of AISI 4340 steel using aluminum oxide (Al2O3) grinding wheel at three different feed rates (0.25, 0.50, and 0.75 mm/min). The comparison was carried out based on the surface roughness, roundness deviation, diametrical wheel wear, acoustic emission, optical microscopy, and microhardness. The results showed that the fluid with corrosion inhibitor kept stable as the feed rate increased, which evidence the high performance of the tested fluid in severe conditions. In addition, the fluid with corrosion inhibitor was superior in almost all evaluated variables; it was unexpected since the standard fluid is consolidated in industry.
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References
Soares DD, Oliveira JFG (2002) Diagnóstico de processos de retificação pela análise de sinais. Rev Máquinas Metais 436:140–157
Silva VF, Batista LN, De Robertis E, Castro CS, Cunha VS, Costa MA (2016) Thermal and rheological behavior of ecofriendly metal cutting fluids. J Therm Anal Calorim 123(2):973–980
Estevao LRM, Nascimento RSV (2001) Modifications in the volatilization rate of volatile corrosion inhibitors by means of host–guest systems. Corros Sci 43(6):1133–1153
Fodor GE (1985) The inhibition of vapor-phase corrosion. A Review (No. BFLRF-209). Southwest Research Inst San Antonio Txbelvoir Fuels And Lubricants Researchfacility
Bastidas DM, Cano E, Mora EM (2005) Volatile corrosion inhibitors: a review. Anti-Corros Methods Mater 52(2):71–77
Valdez SB, Zlatev RK, Schorr WM, Rosas GN, Dobrev T, Monev M, Krastev I (2006) Rapid method for corrosion protection determination of VCI films. Anti-Corros Methods Mater 53(6):362–366
Skinner W (1993) A new method for quantitative evaluation of volatile corrosion inhibitors. Corros Sci 35(5–-8):1491–1494
Genovez MC, Araújo LH, Pinto TD, Hrdina R (2015) New concept of corrosion protection in the presence of water: V-active VCI. Concept and application. Anti-Corros Methods Mater 62(1):53–58
Davis JR, Associates (1996) ASM specialty handbook – carbon and alloy steels. ASM International, Metals Park
Bianchi EC, Sato BK, Sales AR, Lopes JC, de Mello HJ, de Angelo Sanchez LE et al (2018) Evaluating the effect of the compressed air wheel cleaning in grinding the AISI 4340 steel with CBN and MQL with water. Int J Adv Manuf Technol 95(5–-8):2855–2864
De Martini Fernandes L, Lopes JC, Volpato RS, Diniz AE, de Oliveira RFM, de Aguiar PR et al (2018) Comparative analysis of two CBN grinding wheels performance in nodular cast iron plunge grinding. Int J Adv Manuf Technol 98(1–-4):237–249
De Mello HJ, de Mello DR, Rodriguez RL, Lopes JC, da Silva RB, de Angelo Sanchez LE et al (2018) Contribution to cylindrical grinding of interrupted surfaces of hardened steel with medium grit wheel. Int J Adv Manuf Technol 95(9–-12):4049–4057
Lopes JC, Ventura CE, Rodriguez RL, Talon AG, Volpato RS, Sato BK et al (2018) Application of minimum quantity lubrication with addition of water in the grinding of alumina. Int J Adv Manuf Technol 97(5–-8):1951–1959
Silva LR, Corrêa EC, Brandão JR, de Ávila RF (2013) Environmentally friendly manufacturing: bBehavior analysis of minimum quantity of lubricant-MQL in grinding process. J Clean Prod. https://doi.org/10.1016/j.jclepro.2013.01.033
Puerto P, Fernández R, Madariaga J, Arana J, Gallego I (2013) Evolution of surface roughness in grinding and its relationship with the dressing parameters and the radial wear. Procedia Eng 63:174–182
Tawakoli T, Hadad MJ, Sadeghi MH, Daneshi A, Stöckert S, Rasifard A (2009) An experimental investigation of the effects of workpiece and grinding parameters on minimum quantity lubrication—MQL grinding. Int J Mach Tools Manuf 49(12–-13):924–932
Rowe WB (2014) Principles of modern grinding technology, 2ª edn. Willian Andrew, Elsevier, UK
Yoshimura H, Itoigawa F, Nakamura T, Niwa K (2005) Development of nozzle system for oil-on-water droplet metalworking fluid and its application to practical production line. JSME Int J Ser C Mech Syst Mach Elem Manuf 48(4):723–729
Belentani RDM, Funes Júnior H, Canarim RC, Diniz AE, Hassui A, Aguiar PR, Bianchi EC (2014) Utilization of minimum quantity lubrication (MQL) with water in CBN grinding of steel. Mater Res 17(1):88–96
Ding K, Fu Y, Su H, Gong X, Wu K (2014) Wear of diamond grinding wheel in ultrasonic vibration-assisted grinding of silicon carbide. Int J Adv Manuf Technol 71(9–-12):1929–1938
Iceri DM, Sousa RM, Destro RS, Oikawa MH, Bianchi EC, de Aguiar PR, Fortulan CA (2012) Comparação entre os métodos de aplicação de fluido de corte convencional e otimizado na retificação plana de cerâmicas. Cerâmica 58:84–89
Da Silva LR, Bianchi EC, Fusse RY, Catai RE, Franca TV, Aguiar PR (2007) Analysis of surface integrity for minimum quantity lubricant—MQL in grinding. Int J Mach Tools Manuf 47(2):412–418
Marinescu ID, Hitchner M, Uhlmann E, Rowe WB, Inasaki I (2006) Handbook of machining with grinding wheels. 1st ed. New York: CRC Press, 2007.
De Jesus Oliveira D, Guermandi LG, Bianchi EC, Diniz AE, de Aguiar PR, Canarim RC (2012) Improving minimum quantity lubrication in CBN grinding using compressed air wheel cleaning. J Mater Process Technol 212(12):2559–2568
Lee DE, Hwang I, Valente CM, Oliveira JFG, Dornfeld DA (2006) Precision manufacturing process monitoring with acoustic emission. Int J Mach Tools Manuf 46(2):176–188
Marinescu ID, Rowe WB, Dimitrov B, Inasaki I (2004) Tribology of abrasive machining processes, 1ª edn. William Andrew Inc, Norwich
Acknowledgments
Thanks to VCI Brasil for the donation of cutting fluids, for the support provided, and the opportunity for scientific and technological development provided by this research.
Funding
This study was financially supported by the Sao Paulo Research Foundation (FAPESP) (process 2017/03788-9). One of the authors thanks the CAPES (Coordination for the Improvement of HigherLevel Education Personnel) for the financial support given.
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Talon, A.G., Lopes, J.C., Tavares, A.B. et al. Effect of hardened steel grinding using aluminum oxide wheel under application of cutting fluid with corrosion inhibitors. Int J Adv Manuf Technol 104, 1437–1448 (2019). https://doi.org/10.1007/s00170-019-04005-5
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DOI: https://doi.org/10.1007/s00170-019-04005-5