Ti-6Al-4V ELI (Grade 23) is highly recommended for bio-materials and due to its low thermal conductivity and chemically reactive properties, machinability is poor. Thus the current work emphasized on the selection of appropriate cooling technique and optimal cutting parameters for machining of Ti-6Al-4V ELI alloy with sustainability analysis for surface roughness, flank wear and cutting power. Initially, the cutting performances under dry, flood and MQL environments are compared and MQL is observed to better performed. At lower speed (70 m/min), MQL exhibited 26.38% and 19.69% lesser surface roughness relative to dry and flood cooling individually. At the same cutting condition, MQL assisted cutting resulted in lower flank wear relative to dry (157. 33%) and flood cooling (40%). Further, a detailed investigation has been made under MQL through Taguchi L18 design of experiments. The major mechanisms for flank wear are found to be abrasion, chipping and notch wear. Optimal data set through Grey relational analysis is found to be v1 (70 m/min), f1 (0.1 mm/rev) and d1 (0.1 mm) and improved. Quadratic regression model is found to be significant for prediction of responses. Sustainability Pugh matrix assessment revealed that MQL environment enhanced the economical, technological as well as environmental and operator health aspects. Reduction of energy consumption by 53.96% and savings of carbon footprints by 68.46 kg of CO2 observed under MQL at optimal conditions and thus saves manufacturing cost.
ShinHGYooSHParkSW,et al.A study on the cutting characteristics and detection of the abnormal tool state in turning of Ti-6Al-4V ELI. Appl Mech Mater2013; 433–435: 2025–2030.
2.
PradhanSSinghSPrakashC,et al.Investigation of machining characteristics of hard-to-machine Ti-6Al-4V-ELI alloy for biomedical applications. J Mat Res Technol2019; 8: 4849–4862.
3.
PrasadVUVRaoKVMurthyPBGSN. Mechanistic models for prediction of cutting forces and power consumption considering chip geometry. Proc IMechE Part E: J Process Mechanical Engineering2021; 235: 479–488.
4.
BilgaPSSinghSKumarR. Optimization of energy consumption response parameters for turning operation using Taguchi method. J Clean Prod2016; 137: 1406–1417.
5.
AsiyahMSSulaimanMAShahmiR,et al.Performance of CVD coated carbide tool by optimizing machining parameters during turning titanium alloy TI-6AL-4V ELI in flooded condition. J Adv Manufact Technol2018; 12: 401–412.
6.
RahmanSSAshrafMZAminAN,et al.Tuning nanofluids for improved lubrication performance in turning biomedical grade titanium alloy. J Clean Prod2019; 206: 180–196.
7.
KechagiasJDAslaniKEFountaNA,et al.A comparative investigation of Taguchi and full factorial design for machinability prediction in turning of a titanium alloy. Measurement ( Mahwah N J)2020; 151: 107213.
8.
MishraRRKumarRSahooAK,et al.Machinability behaviour of biocompatible Ti-6Al-4V ELI titanium alloy under flood cooling environment. Mater Today: Proceed2020; 23: 536–540.
9.
ShahDRBhavsarSN. An experimental investigation of tool nose radius and machining parameters on TI-6AL-4V (ELI) using grey relational analysis, regression and ANN models. Int J Data Net Sci2019; 3: 291–304.
10.
GhaniJChe HaronCKasimM,et al.Wear mechanism of coated and uncoated carbide cutting tool in machining process. J Mat Res2016; 31: 1873–1879.
11.
SłodkiBZebalaWStruzikiewiczG. Turning titanium alloy, grade 5 ELI, with the implementation of high pressure coolant. Materials (Basel)2019; 12: 768–781.
12.
AnuragKRJoshiKKDasRK. Analysis of chip reduction coefficient in turning of Ti-6Al-4V ELI. IOP Conference Series: Mat Sci Eng2018; 390: 012113.
13.
SartoriSGhiottiABruschiS. Solid lubricant-assisted minimum quantity lubrication and cooling strategies to improve Ti6Al4V machinability in finishing turning. Tribo Int2018; 118: 287–294.
14.
IbrahimGAChe HaronCHGhaniJA. Evaluation of PVD-inserts performance and surface integrity when turning Ti-6Al-4V ELI under dry machining. Adv Mater Res2011; 264: 1050–1055.
15.
IbrahimGAChe HaronCHGhaniJA. The effect of dry machining on surface integrity of titanium alloy Ti-6Al-4V ELI. J Appl Sci2009; 9: 121–127.
16.
IbrahimGAChe HaronCHGhaniJA. Surface integrity of TI-6AL-4V ELI when machined using coated carbide tools under dry cutting condition. Int J Mech Mater Eng2009; 4: 191–196.
17.
IbrahimGAArinalHZulhanif,et al.Microstructure alterations of Ti-6Al-4V ELI during turning by using tungsten carbide inserts under dry cutting condition. Int J Eng Technol Dev2013; 1: 37–40.
18.
KarkalosNEGalanisNIMarkopoulosAP. Surface roughness prediction for the milling of Ti–6Al–4 V ELI alloy with the use of statistical and soft computing techniques. Measurement ( Mahwah N J)2016; 90: 25–35.
19.
SargadeVGNipanikarSRMeshramSM. Analysis of surface roughness and cutting force during turning of Ti6Al4V ELI in dry environment. Int J Ind Eng Comput2018; 7: 257–266.
20.
KumarRSahooAK. Pulsating minimum quantity lubrication assisted high speed turning on bio-medical Ti-6Al-4V ELI alloy: An experimental investigation. Mech Ind2020; 21: 625.
21.
BandapalliCSutariaBMBhattDVP. The Comparison of Cutting Tools for High Speed Machining of Ti-6Al-4V ELI Alloy (Grade 23). Titanium Alloys - Novel Aspects of Their Manufacturing and Processing, 2018. Maciej Motyka, Waldemar Ziaja and Jan Sieniawsk, IntechOpen, DOI: 10.5772/intechopen.80641. Available from: https://www.intechopen.com/chapters/63356.
22.
AkkusHYakaH. Experimental and statistical investigation of the effect of cutting parameters on surface roughness, vibration and energy consumption in machining of titanium 6Al-4 V ELI (grade 5) alloy. Measurement (Mahwah N J)2021; 167: 108465.
23.
SinghHSharmaVSSinghS,et al.Nanofluids assisted environmental friendly lubricating strategies for the surface grinding of titanium alloy: ti6Al4V-ELI. J Manuf Process2019; 39: 241–249.
24.
ShahDBhavsarS. Effect of tool nose radius and machining parameters on cutting force, cutting temperature and surface roughness – An experimental study of Ti-6Al-4V (ELI). Mat Today: Proc2020; 22: 1977–1986.
25.
SulaimanMAHaronCGhaniJA,et al.Optimization of turning parameters for Titanium alloy Ti-6Al-4V ELI using the response surface method (RSM). J Adv Manuf Technol2013; 7: 11–28.
26.
SenthilkumarMPrabukarthiAKrishnarajV. Machining of CFRP/Ti6Al4 V stacks under minimal quantity lubricating condition. J Mech Sci Technol2018; 32: 3787–3796.
27.
MoslehMShirvaniKASmithST,et al.A study of minimum quantity lubrication (MQL) by nanofluids in orbital drilling and tribological testing. J Manuf Mater Process2019; 3: 5.
28.
SettiDSinhaMKGhoshS,et al.An effective method to determine the optimum parameters for minimum quantity lubrication(MQL) grinding, 5 th International & 26th All India Manufacturing Technology, Design and Research Conference (AIMTDR 2014) December 12th–14th, 2014, IIT Guwahati, Assam, India, 67–6.
29.
ZhuGYuanSChenB. Numerical and experimental optimizations of nozzle distance in minimum quantity lubrication (MQL) milling process. Int J Adv Manuf Technol2019; 101: 565–578.
30.
SadeghiMHHadadMJTawakoliT,et al.An investigation on surface grinding of AISI 4140 hardened steel using minimum quantity lubrication-MQL technique. Int J Mater Form2010; 3: 241–251.
31.
KumarRSahooAKMishraPC,et al.Comparative investigation towards machinability improvement in hard turning using coated and uncoated carbide inserts: part I experimental investigation. Adv Manuf2018; 6: 52–70.
32.
KumarRSahooAKDasRK,et al.Modelling of flank wear, surface roughness and cutting temperature in sustainable hard turning of AISI D2 steel. Proc Manuf2018; 20: 406–413.
33.
AllaRKGinjupalliKUpadhyaN,et al.Surface roughness of implants: a review. Trend Biomater Artif Organs2011; 25: 112–118.
34.
RevankarGDShettyRRaoSS,et al.Analysis of surface roughness and hardness in titanium alloy machining with polycrystalline diamond tool under different lubricating modes. Mater Res2014; 17: 1010–1022.
35.
FadareDA. Effects of cutting parameters on surface roughness during high –speed turning of Ti-6AI-4 V alloy. J Appl Sci Res2009; 5: 757–764.
36.
NithyanandamJDasSLPalanikumarK. Influence of cutting parameters in machining of Titanium alloy. Ind J Sci Technol2015; 8: 556–562.
NurRNoordinMYIzmanS,et al.The effect of cutting parameters on power consumption during turning nickel based alloy. Adv Mater Res2014; 845: 799–802.
39.
ZangJZhaoJLiA,et al.Serrated chip formation mechanism analysis for machining of titanium alloy Ti-6Al-4V based on thermal property. Int J Adv Manuf Technol2017; 98: 119–127.
40.
XiuliFWenxingLYongzhiP,et al.Morphology evolution and micro-mechanism of chip formation during high-speed machining. Int J Adv Manuf Technol2018; 98: 165–175.
41.
DaymiABoujelbeneMSalemSB,et al.Effect of the cutting speed on the chip morphology and the cutting forces. Arc Comput Mat Sci Surf Eng2009; 1: 77–83.
42.
NouariMMakichH. On the physics of machining titanium alloys: interactions between cutting parameters, microstructure and tool wear. Metals (Basel)2014; 4: 335–358.
43.
GaoCYZhangLC. Effect of cutting conditions on the serrated chip formation in high speed cutting. Mach Sci Technol: An Int J2013; 17: 26–40.
44.
Kumar R, Sahoo AK, Mishra PC, et al. An investigation to study the wear characteristics and comparative performance of cutting inserts during hard turning. Int J Mach Machinability Mater 2018; 20: 320–344.
45.
Kumar R, Sahoo AK, Mishra PC, et al. A comparative study towards machinability improvement in hard turning using coated and uncoated carbide inserts: part-II (modeling, multi-response optimization, tool life and economic aspects. Adv Manuf 2018; 6: 155–175.
46.
MontgomeryDC. Design and analysis of experiments. 4th ed. New York: Wiley, 1997.
47.
KumarRSahooAKSatyanarayanaK,et al.Some studies on cutting force and temperature in machining Ti-6Al-4V alloy using regression analysis and ANOVA. Int J Ind Engg Comput2013; 3: 427–436.
48.
SahooAKMishraPC. A response surface methodology and desirability approach for predictive modelling and optimization of cutting temperature in machining hardened steel. Int J Ind Eng Comput2014; 5: 407–416.
49.
DogrusadikAAycicekCKentliA. Optimization of tool design parameters for thread tapping process of Ti-6Al-4V. Proc IMechE Part E: J Process Mechanical Engineering2020; 235: 870–878. https://doi.org/10.1177/0954408920974993
50.
RoySKumarRSahooAK,et al.Cutting tool failure and surface finish analysis in pulsating MQL-assisted hard turning. J Fail Anal Preven2020; 20: 1274–1291. https://doi.org/10.1007/s11668-020-00940-8
51.
BayatMAbootorabiMM. Comparison of minimum quantity lubrication and wet milling based on energy consumption modeling. Proc IMechE Part E: J Process Mechanical Engineering2021; 235: 1665–1675. https://doi.org/10.1177/09544089211014407
52.
YangXChengXLiY,et al.Machinability investigation and sustainability analysis of minimum quantity lubrication–assisted micro-milling process. Proc IMechE Part B: J Engineering Manufacture2020; 234: 1388–1401.
53.
DashLPadhanSDasA,et al.Machinability investigation and sustainability assessment in hard turning of AISI D3 steel with coated carbide tool under nanofluid minimum quantity lubrication-cooling condition. Proc IMechE Part C: J Mechanical Engineering Science2021. https://doi.org/10.1177/0954406221993844
54.
PadhanSDashLBeheraSK,et al.Modeling and optimization of power consumption for economic analysis, energy-saving carbon footprint analysis, and sustainability assessment in finish hard turning under graphene nanoparticle–assisted Minimum quantity lubrication. Process Integr Optim Sustain2020; 4: 445–463.
55.
PadhanSDasASantoshwarA,et al.Sustainability assessment and machinability investigation of austenitic stainless steel in finish turning with advanced ultra-hard SiAlON ceramic tool under different cutting environments. Silicon2021; 13: 119–147.
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