Several studies are being carried out to curtail the heat generated in machining. Among the various alternatives available, cutting fluids remain to be the choice. However, the various limitations of the cutting fluids restrict their application. Hence, different techniques are being explored to replace the use of cutting fluids, minimum quantity lubrication being one of them. This present article tries to review the available literature and examine nanofluids as potential candidates for minimum quantity lubrication.
Soluble oils are the largest class of oils used in metal cutting industry. Flood cooling involves problems related to its treatment and disposal. Minimum quantity lubrication in the form of mist application can be used to replace flood cooling. But as less amount of cutting fluid is used in minimum quantity lubrication, its capacity to carry away heat and providing adequate lubrication is limited. Hence, the heat-carrying and lubricating ability of soluble oil has to be enhanced. Graphite has better lubricating and cooling properties and hence inclusion of graphite nanoparticles in cutting fluid may help in formulating a better coolant in machining operation. This article compares the performance of mist application of nanographite-soluble oil with dry lubrication, flood lubrication and mist application of soluble oil without nanographite in turning AISI 1040 steel. Performance is evaluated based on experimental measurement of average chip–tool interface temperature, tool wear and cutting forces. The results showed that use of nanographite-soluble oil in mist application has greatly improved the cutting conditions by lowering the temperature generated, reducing the tool wear and reducing the cutting forces.
Soluble oils are the most popularly used oils in metal-cutting industry. However, the regular application strategy, flood cooling, involves the problem related to its disposal. Hence, mist application can be seen as an alternative procedure. Since less amount of cutting fluid is used, its capacity to carry away heat and provide adequate lubrication is limited. Therefore, the heat carrying and lubricating abilities of soluble oil need to be enhanced. Graphite has better lubricating and cooling properties, and hence inclusion of graphite nano particles in cutting fluid may help in formulating a better coolant in machining operation. This paper consists of two parts. The first part consists of preparation of nano cutting fluid by different methods followed by their stability evaluation, and second part consists of characterization of the basic properties of nano cutting fluid.
Liberation of heat and generation of friction associated with any machining operation ever pose a problem which not only reduce the tool life but also impair quality of the product. Cutting fluids have been the conventional choice to curtail friction and temperatures in machining because of its lubrication and cooling actions. However, considering health hazards posed by the conventional cutting fluids to health of the workers and ecology, the quest is towards identifying alternative strategies to the usual flood application. Selection and use of proper lubricant that can improve the overall cutting phenomena which is an important aspect in reducing the cutting forces and temperatures The present work studies the use of nano cutting fluids in MQL which is a minimal cutting fluid technique, for turning operation using HSS and cemented carbide tools. Development of nano materials by nanotechnology technique, dispersing them in the cutting fluid improve the effectiveness of the cutting fluid and hence nano graphite powder is selected of particle size 80 nm in varying proportions i.e. 0.0%, 0.1%, 0.3% and 0.5% by weight are mixed in water soluble oil and applied drop by drop. Experimentation is carried out at different flow rates like 5 ml/min 10 ml/min and 15 ml/min with nanoparticle suspended fluids along with dry machining, flood coolant machining under constant cutting conditions. Experimental results are very encouraging with much reduction in surface roughness, tool flank wear, temperatures and cutting forces is observed in fluids with nanoparticle inclusions. Different properties of the nanofluids are estimated through a series of standard tests.
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