Influence of nanofluid application on wheel wear, coefficient of friction and redeposition phenomenon in surface grinding of Ti-6Al-4V

Setti, Dinesh; Ghosh, Sudarsan; Rao, P.V.

doi:10.1177/0954405416636039

Cited by 22 publications

(10 citation statements)

References 30 publications

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“…Thus, the addition of nanosized solid particles to grinding fluids can enhance the heat exchange capability of grinding fluids which in turn help in better cooling of the grinding zone by dissipating the heat generated. This is evident from the works carried out by various researchers, [3][4][5][6][7][8][9][10] in which MQL grinding performance was improved by adding various nanoparticles such as copper, nickel, Al 2 O 3 and carbon nanotubes. In all these studies, addition of nanoparticles resulted in the reduction of specific grinding energy and improvement in wheel life and quality of the workpiece surface.…”

Section: Introductionmentioning

confidence: 97%

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Pavan

Gopal

Amrita

et al. 2017

Proceedings of the Institution of Mechanical Engineers, Part B:

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The main objective of this work is to assess the performance of graphene nanoplatelets–based cutting fluid in minimum quantity lubrication grinding of Inconel 718. Nanocutting fluids with varying concentrations and different specific surface areas of graphene nanoplatelets were developed, and basic properties like viscosity and thermal conductivity were evaluated at different temperatures. The role of graphene nanoplatelets concentration and specific surface area is investigated by comparing force generated during grinding, surface roughness, grinding temperature, grinding coefficient and specific grinding energy. The experimental results show that graphene nanoplatelets significantly lower the grinding force, temperature, specific grinding energy and roughness of the finished surface. Nanocutting fluid with 0.3 wt% graphene nanoplatelets and 750 mm2/g was found effectively improved the surface quality of the Inconel 718 compared to dry grinding and minimum quantity lubrication grinding with soluble oil.

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Section: Introductionmentioning

confidence: 97%

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Pavan

Gopal

Amrita

et al. 2017

Proceedings of the Institution of Mechanical Engineers, Part B:

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“…The same was observed as well during the grinding of Ti-6Al-4V alloys with water-dispersed multiwall carbon nanotube (MWCNT) and Al 2 O 3 nanofluids used as cutting fluids in SQCL mode. 19 The versatility of nanofluid-assisted MQL as a cooling lubrication stratagem could be understood further from the findings of Setti et al, 20 where the use of aqueous Al 2 O 3 nanofluid arrested wheel loading and re-deposition on the surface of the specimen. Water-dispersed MoS 2 nanofluids also displayed the same tendency to stick to the periphery of the wheel as was observed during grinding of AISI 52100.…”

Section: Introductionmentioning

confidence: 99%

Suitability of aqueous MoS₂ nanofluid for small quantity cooling lubrication–assisted diamond grinding of WC-Co cermets

Paul

Ghosh

2017

Proceedings of the Institution of Mechanical Engineers, Part B:

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In contrary to the common notion that MoS2 is ineffective in water environment, this study evidentially justifies the potential of aqueous MoS2 nanofluid as a cutting fluid in grinding application. The ceramic-metal composite, WC-Co has been ground under small quantity cooling lubrication environment using this nanofluid. Parameters like grinding forces, surface roughness, chip, surface morphology and residual stress were under the focus of the study to assess the performance of the nanofluid beside commonly used soluble oil. The suitability of aqueous MoS2 nanofluid as a lubricant and coolant was first evaluated by conducting tribological and hot plate experiments, respectively. The cooling capability of MoS2 nanofluids, when dosed in aerosol form at the grinding interface extended grit sharpness which led to prolonged shearing action of the grits as compared to rapid grit dulling observed in alternative environments like flood cooling and small quantity cooling and lubrication using soluble oil. The chips formed during MoS2 nanofluid aerosol were also finer due to strain hardening of the cobalt phase leading to premature, stunted ductile fracture of the material. The residual stress of ground surface under nano-small quantity cooling lubrication environment was less compressive than small quantity cooling lubrication with soluble oil due to reduced rubbing by sharper grits. The overall outperformance of aqueous MoS2 nanofluid over soluble oil as cutting fluid is thus established.

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“…However, no significantly lower temperatures could be found using nanofluids instead of pure water for cooling. Setti et al [100] also suggested the use of Al 2 O 3 ÁH 2 O nanofluids in the sophisticated grinding process of Ti6Al-4V showing that wheel life can be increased. Paul et al [101] suggested using magnetorheological fluids to reduce tool vibration in material processing.…”

Section: Materials Processingmentioning

confidence: 96%

Nanofluids revisited

Eggers

Kabelac

2016

Applied Thermal Engineering

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h i g h l i g h t s Thermophysical properties bring nanofluids into various engineering applications. Quantity of variable parameters hinder comprehensive equations, e.g. for viscosity. Coordinated research can help to overcome debates about thermophysical properties. Missing experience for nanofluids in large scale plants. Lack of studies about high pressure/temperature applications and long term behavior. a b s t r a c tIn the roughly two decades from the first publication until today, nanofluids have found their way into various research fields. To-date published documents range from basic research to high-tech applications. This contribution aims at outlining current fields of research regarding nanofluid research. These range from fundamental property data studies presented in the first section to a listing of numerous applications of different fields of engineering. It is shown that nanofluid science pushes increasingly into the scientific world providing plenty of new questions and challenges.

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Influence of nanofluid application on wheel wear, coefficient of friction and redeposition phenomenon in surface grinding of Ti-6Al-4V

Cited by 22 publications

References 30 publications

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Suitability of aqueous MoS₂ nanofluid for small quantity cooling lubrication–assisted diamond grinding of WC-Co cermets

Nanofluids revisited

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Influence of nanofluid application on wheel wear, coefficient of friction and redeposition phenomenon in surface grinding of Ti-6Al-4V

Cited by 22 publications

References 30 publications

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Experimental investigation of graphene nanoplatelets–based minimum quantity lubrication in grinding Inconel 718

Suitability of aqueous MoS2 nanofluid for small quantity cooling lubrication–assisted diamond grinding of WC-Co cermets

Nanofluids revisited

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Suitability of aqueous MoS₂ nanofluid for small quantity cooling lubrication–assisted diamond grinding of WC-Co cermets