Hardened AISI 4140 steel is widely used in automotive industries due to its high strength, high hardness, and good formability. It can be subjected to cryogenic treatments to increase wear resistance, increase the toughness and decrease the residual stress. Although many studies have been performed related to the machinability of AISI 4140 steel, the number of studies that considered four responses simultaneously are limited. In this study, the effects of cutting speeds, feed rates, and depths of cut on the vibration, motor current, machining noise, and surface roughness were investigated in turning hardened AISI 4140 steel using coated carbide insert under dry cutting conditions. Besides, the attempt was made to predict surface roughness based on machining noise, motor current, and chuck vibration during the turning process. Analysis of variance and response surface methods were carried out to analyze the experimental results and the prediction models were developed. The machining test revealed that the most effective parameter on the surface roughness value was the feed rate with a 96.07% contribution. The depth of cut and the feed rate affected vibration with 57.61% and 26.44% contribution, respectively. The machining noise was dominantly affected by the depth of cut with 76.15% contribution, it was followed by feed rate with 17.67% contribution. However, feed rate and depth of cut significantly affect motor current with 54.53% and 36.64% contribution, respectively. The graphical analysis of the effect of vibration, motor current, and machining noise on the surface roughness was presented. Based on the results, there is a direct relationship between machining noise, vibration, and motor current with surface roughness. As the level of the aforementioned responses increases the quality of the machined surface deteriorates.
BartaryaGChoudhuryS. State of the art in hard turning. Int J Mach Tools Manuf2012; 53: 1–14.
2.
TönshoffHArendtCAmorRB. Cutting of hardened steel. CIRP Ann2000; 49: 547–566.
3.
SoodRGuoCMalkinS. Turning of hardened steels. J Manuf Process2000; 2: 187–193.
4.
AouiciHYalleseMAChaouiK,et al.Analysis of surface roughness and cutting force components in hard turning with CBN tool: prediction model and cutting conditions optimization. Measurement2012; 45: 344–353.
5.
KumarPChauhanSRPruncuCI, et al.Influence of different grades of CBN inserts on cutting force and surface roughness of AISI H13 die tool steel during hard turning operation. Materials (Basel)2019; 12: 177.
6.
TangLSunYLiB,et al.Wear performance and mechanisms of PCBN tool in dry hard turning of AISI D2 hardened steel. Tribol Int2019; 132: 228–236.
7.
BensouilahHAouiciHMeddourI,et al.Performance of coated and uncoated mixed ceramic tools in hard turning process. Measurement2016; 82: 1–18.
8.
FerreiraRCarouDLauroC,et al.Surface roughness investigation in the hard turning of steel using ceramic tools. Mater Manuf Processes2016; 31: 648–652.
9.
SubbaiahKVRajuCSureshC. Parametric analysis and optimization of hard turning at different levels of hardness using wiper ceramic insert. Measurement2020; 158: 107712.
10.
RafighiMÖzdemirMAl ShehabiS,et al.Sustainable hard turning of high chromium AISI D2 tool steel using CBN and ceramic inserts. Trans Indian Inst Met2021; 74: 1639–1653.
11.
GintingASkeinRCuacaD,et al.The characteristics of CVD-and PVD-coated carbide tools in hard turning of AISI 4340. Measurement2018; 129: 548–557.
12.
AlokADasM. Multi-objective optimization of cutting parameters during sustainable dry hard turning of AISI 52100 steel with newly develop HSN2-coated carbide insert. Measurement2019; 133: 288–302.
13.
BoingDde OliveiraAJSchroeterRB. Limiting conditions for application of PVD (TiAlN) and CVD (TiCN/Al2O3/TiN) coated cemented carbide grades in the turning of hardened steels. Wear2018; 416: 54–61.
14.
ÖzbekNAÖzbekOKaraF. Statistical analysis of the effect of the cutting tool coating type on sustainable machining parameters. J Mater Eng Perform2021; 30: 7783–7795.
15.
DasAKamalMDasSR, et al.Comparative assessment between AlTiN and AlTiSiN coated carbide tools towards machinability improvement of AISI D6 steel in dry hard turning. Proc Inst Mech Eng C J Mech Eng Sci2021. DOI: 10.1177%2F09544062211037373
16.
İynenOEkşiAKÖzdemirM,et al.Experimental and numerical investigation of cutting forces during turning of cylindrical AISI 4340 steel specimens. Mater Test2021; 63: 402–410.
17.
MeysamiAGhasemzadehRSeyedeinS,et al.An investigation on the microstructure and mechanical properties of direct-quenched and tempered AISI 4140 steel. Mater Des2010; 31: 1570–1575.
18.
WangBLiuBZhangX,et al.Enhancing heavy load wear resistance of AISI 4140 steel through the formation of a severely deformed compound-free nitrided surface layer. Surf Coat Technol2018; 356: 89–95.
19.
ElbahMYalleseMAAouiciH,et al.Comparative assessment of wiper and conventional ceramic tools on surface roughness in hard turning AISI 4140 steel. Measurement2013; 46: 3041–3056.
20.
ŞahinoğluARafighiM. Investigation of tool wear, surface roughness, sound intensity and power consumption during hard turning of AISI 4140 using multilayer-coated carbide inserts. J Eng Res2021; 9: 377–395.
21.
KamMŞeremetM. Experimental and statistical investigation of surface roughness and vibration during finish turning of AISI 4140 steel workpiece under cooling method. Surf Rev Lett2021; 28: 1–11.
22.
KamMDemirtaşM. Analysis of tool vibration and surface roughness during turning process of tempered steel samples using taguchi method. Proc Inst Mech Eng E J Proc Mech Eng2021; 235: 1429–1438.
23.
KamMDemi˙rtaşM. Experimental analysis Of The effect Of mechanical properties And microstructure On tool vibration And surface quality In Dry turning Of hardened aisi 4340 steels. Surf Rev Lett2021; 28: 1–13.
24.
SalimiaslARafighiM. Titreşim ve kesme kuvveti esaslı takım aşınmasının bulanık mantıkla İzlenmesi ve tahmini. Politeknik Dergisi2016; 20: 111–120.
25.
ChavoshiSZTajdariM. Surface roughness modelling in hard turning operation of AISI 4140 using CBN cutting tool. IntJ Mater Form2010; 3: 233–239.
26.
DasSRDhupalDKumarA. Study of surface roughness and flank wear in hard turning of AISI 4140 steel with coated ceramic inserts. J Mech Sci Technol2015; 29: 4329–4340.
27.
AkgünMKaraF. Analysis and optimization of cutting tool coating effects on surface roughness and cutting forces on turning of AA 6061 alloy. Adv Mater Sci Eng2021; 2021. DOI: 10.1155/2021/6498261
28.
ÖzdemirM. Modelling and prediction of effect of machining parameters on surface roughness in turning operations. Tehnički vjesnik2020; 27: 751–760.
29.
IkhlasMAthmaneYMHamzaB,et al.Prediction of surface roughness and cutting forces using RSM, ANN, and NSGA-II in finish turning of AISI 4140 hardened steel with mixed ceramic tool. Int J Adv Manuf Technol2018; 97: 1931–1949.
30.
AslanECamuşcuNBirgörenB. Design optimization of cutting parameters when turning hardened AISI 4140 steel (63 HRC) with Al2O3+TiCN mixed ceramic tool. Mater Des2007; 28: 1618–1622.
31.
KamMŞeremetM. Experimental investigation of the effect of machinability on surface quality and vibration in hard turning of hardened AISI 4140 steels using ceramic cutting tools. Proc Inst Mech Eng E J Proc Mech Eng2021; 235: 1565–1574.
32.
GhoshPSChakrabortySBiswasAR,et al.Empirical modelling and optimization of temperature and machine vibration in CNC hard turning. Mater Today Proc2018; 5: 12394–12402.
33.
ŞahinoğluARafighiM. Investigation of vibration, sound intensity, machine current and surface roughness values of AISI 4140 during machining on the lathe. Arab J Sci Eng2020; 45: 765–778.
34.
TekınerZYeşılyurtS. Investigation of the cutting parameters depending on process sound during turning of AISI 304 austenitic stainless steel. Mater Des2004; 25: 507–513.
35.
SeemuangNMcLeayTSlatterT. Using spindle noise to monitor tool wear in a turning process. Int J Adv Manuf Technol2016; 86: 2781–2790.
36.
ŞahinoğluAUlasE. An investigation of cutting parameters effect on sound level, surface roughness, and power consumption during machining of hardened AISI 4140. Mech Ind2020; 21: 523.
37.
KaraaslanFŞahinoğluA. Determination of ideal cutting conditions for maximum surface quality and minimum power consumption during hard turning of AISI 4140 steel using TOPSIS method based on fuzzy distance. Arab J Sci Eng2020; 45: 9145–9157.
38.
KalsiNSSehgalRSharmaVS. Cryogenic treatment of tool materials: a review. Mater Manuf Processes2010; 25: 1077–1100.
39.
DeshpandeYVAndhareABPadolePM. Experimental results on the performance of cryogenic treatment of tool and minimum quantity lubrication for machinability improvement in the turning of inconel 718. J Braz Soc Mech Sci Eng2018; 40: 1–21.
40.
AkincioğluSGökkayaHUygurİ. A review of cryogenic treatment on cutting tools. Int J Adv Manuf Technol2015; 78: 1609–1627.
41.
ChopraSASargadeV. Metallurgy behind the cryogenic treatment of cutting tools: an overview. Mater Today Proc2015; 2: 1814–1824.
42.
ÖzbekNA. Effects of cryogenic treatment types on the performance of coated tungsten tools in the turning of AISI H11 steel. J Mater Res Technol2020; 9: 9442–9456.
43.
ÇiçekAKıvakTEkiciE,et al.Performance of multilayer coated and cryo-treated uncoated tools in machining of AISI H13 tool steel—part 1: tungsten carbide End mills. J Mater Eng Perform2021; 30: 3436–3445.
44.
ÇiçekAEkiciEKıvakT,et al.Performance of multilayer coated and cryo-treated uncoated tools in machining of AISI H13 tool steel—part 2: HSS end mills. J Mater Eng Perform2021; 30: 3446–3457.
45.
KaraFKarabatakMAyyıldızM,et al.Effect of machinability, microstructure and hardness of deep cryogenic treatment in hard turning of AISI D2 steel with ceramic cutting. J Mater Res Technol2020; 9: 969–983.
46.
ÇiçekAKaraFKivakT,et al.Evaluation of machinability of hardened and cryo-treated AISI H13 hot work tool steel with ceramic inserts. Int J Refract Met Hard Mater2013; 41: 461–469.
47.
KarthikRMalghanRLKaraF,et al.Influence of support vector regression (SVR) on cryogenic face milling. Adv Mater Sci Eng2021; 2021. DOI: 10.1155/2021/9984369
48.
KamM. Effects of deep cryogenic treatment on machinability, hardness and microstructure in dry turning process of tempered steels. Proc Inst Mech Eng E JProc Mech Eng2021; 235: 927–936.
49.
GunesICicekAAslantasK,et al.Effect of deep cryogenic treatment on wear resistance of AISI 52100 bearing steel. Trans Indian Inst Met2014; 67: 909–917.
50.
DasDDuttaARayK. Optimization of the duration of cryogenic processing to maximize wear resistance of AISI D2 steel. Cryogenics2009; 49: 176–184.
51.
SelvarajDPChandramohanPMohanrajM. Optimization of surface roughness, cutting force and tool wear of nitrogen alloyed duplex stainless steel in a dry turning process using taguchi method. Measurement2014; 49: 205–215.
52.
ChinchanikarSChoudhuryS. Effect of work material hardness and cutting parameters on performance of coated carbide tool when turning hardened steel: an optimization approach. Measurement2013; 46: 1572–1584.
53.
CiftciI. Machining of austenitic stainless steels using CVD multi-layer coated cemented carbide tools. Tribol Int2006; 39: 565–569.
54.
Abd RahmanMAliMYKhairuddinAS. Effects on vibration and surface roughness in high speed micro End-milling of inconel 718 with Minimum quantity lubrication. IOP Conf Ser Mater Sci Eng2017; 184: 1–7.
55.
ŞahinoğluARafighiM. Optimization of cutting parameters with respect to roughness for machining of hardened AISI 1040 steel. Mater Test2020; 62: 85–95.
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