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The International Journal of Advanced Manufacturing Technology

Erschienen in:

13.11.2019 | ORIGINAL ARTICLE

Performance of SAE 52100 steel grinding using MQL technique with pure and diluted oil

verfasst von: Douglas Lyra de Moraes, Mateus Vinicius Garcia, José Claudio Lopes, Fernando Sabino Fonteque Ribeiro, Luiz Eduardo de Angelo Sanchez, Cesar Renato Foschini, Hamilton José de Mello, Paulo Roberto Aguiar, Eduardo Carlos Bianchi

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 10/2019

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Abstract

Grinding is one of the highest dimensional accuracy machining processes in the industry. To obtain the smallest form and geometrical workpiece deviation, it is necessary to add cutting fluids as the aim of ensuring the tolerances established for this process, by reducing the machining temperature, due to its cooling capacity, facilitating the cutting by its capacity lubricant. Currently, it is known that together with conventional fluid, there are problems related to environmental pollution and damage to the operator’s health. Some techniques have come up to alleviate these problems; one of them is the minimum quantity lubricant (MQL) that has been outstanding for obtaining results close to flood application. This technique has stood out concerning the surface integrity and geometric and dimensional precision of the machined workpiece since a smaller quantity of cutting fluid is directed precisely in the cutting region. However, the reduced cooling capacity of MQL has promoted the researches to perfect this technique. In this way, this research aims to analyze the consequences of the water addition in this method to minimize the probability of thermal damages in the workpiece when applied in the grinding of SAE 52100 steel which is widely used in the manufacture of bearings, shafts, blades, and various other components where there is a need for high hardness and high abrasion resistance. The analysis of the output parameters evaluated the performance of the technique: surface roughness (Ra), roundness error, diametrical wheel wear, viscosity, cutting power, metallography, and microhardness. Beyond this, it evaluated the behavior of each lubri-refrigeration method concerning the ground surface through scanning electron and confocal microscopy, and it used optical microscopy to analyze of the grinding wheel cutting surface. The results of the water increment in the MQL were superior to those of the MQL (oil-pure) in almost all aspects, remaining inferior only in the cutting power. Also, the 1:5 dilution (oil-water) presented close and satisfactory results when compared to traditional cutting fluid (flood); it becomes an excellent alternative for insertion environmentally correct cutting fluids in today’s industry.

Vorheriger Artikel Prediction of surface variation field in face milling via finite element model updating with considering force-deformation coupling

Nächster Artikel Experimental investigation of driver material on electromagnetic welding of alloy D9 SS tube to SS316L(N) plug

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Titel: Performance of SAE 52100 steel grinding using MQL technique with pure and diluted oil
verfasst von: Douglas Lyra de Moraes
Mateus Vinicius Garcia
José Claudio Lopes
Fernando Sabino Fonteque Ribeiro
Luiz Eduardo de Angelo Sanchez
Cesar Renato Foschini
Hamilton José de Mello
Paulo Roberto Aguiar
Eduardo Carlos Bianchi
Publikationsdatum: 13.11.2019
Verlag: Springer London
Erschienen in: The International Journal of Advanced Manufacturing Technology / Ausgabe 10/2019
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-019-04582-5

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