Experimental investigation of Material Removal Rate and Tool wear in turning of hardened AISI52100 steel using Taguchi Technique

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IOSR Journal of Engineering (IOSRJEN) ISSN (e): 2250-302, ISSN (p): 2278-879 Vol. 04, Issue 05 (May. 204), V5 PP 3-8 www.iosrjen.org Experimental investigation of Material Removal Rate and Tool wear in turning of hardened AISI5200 steel using Taguchi Technique Vijaykumar H.K, Ahamed Kabir 2 and Ganesh Raj 3, 2&3 Department of Mechanical Engineering, Bearys Institute of Technology, Mangalore, Karnataka-57453, India. Abstract: - The objective of this paper is to investigate experimentally the optimum process parameters (cutting speed, feed rate and depth of cut) resulting in an optimization of material removal rate (MRR) and tool wear while turning of hardened AISI 5200 steel under dry cutting conditions using Taguchi method. A L9 orthogonal array, signal-to-noise(s/n) ratio and analysis of variances (ANOVA) are applied with the help of Minitab.v.6.2.0 software to study performance characteristics of process parameters with consideration of Material Removal Rate (MRR) and Tool wear. The results obtained from the experiments are changed into signal-to-noise ratio(s/n) ratio and used to optimize the value of MRR and tool wear The ANOVA is performed to identify the importance of parameters. The conclusions arrived at are considerably discussed at the end. Keywords: - ANOVA, Hardened, MRR, Tool wear, Taguchi technique I. INTRODUCTION In metal cutting industries the foremost drawback is not operating the machine tool to their optimum operating conditions and the operating conditions continue to be chosen solely on the basis of the handbook values or operator s experience. In metal cutting industries turning is the majorly used process for removing the material from the cylindrical work piece. In turning that to turning of hardened steels such as AISI5200 is a challenging process. Turning of hardened material is a process, in which materials in the hardened state (above 45HRC) are machined with single point cutting tools. This has become possible with the availability of the new cutting tool materials (cubic boron nitride and ceramics). The traditional method of machining the hardened materials includes rough turning, heat treatment followed by the grinding process. Turning of hardened material eliminates a series of operations required to produce the component and thereby reducing the cycle time and hence resulting in productivity improvement [,2]. Turning of hardened material is an alternative to conventional grinding process; it is a flexible and economic process for hardened steels [3]. The advantages of tuning of hard materials are higher productivity, reduced set up times, surface finish closer to grinding and the ability to machine complex parts. Rigid machine tools with adequate power, very hard and tough tool materials with appropriate tool geometry, tool holders with high stiffness and appropriate cutting conditions are some of the prerequisites for hard turning [4].Material Removal Rate (MRR) is a vital factor to be considered in hard turning of steels since it is directly affects the machining time. It also had been reported that the resulting machining time reduction is as high as 60% in hard turning compared to grinding [5]. Tool wear specifically flank wear results in changes in tool geometry that affect cutting forces, cutting power, and surface finish. It is the main factor that determines the economics in metal cutting. A lower rate of flank wear means increased tool life, better surface finish, reduced tooling cost and lower cost of production. The turning of hardened components are used in many applications such as gears, shafts, bearings, cams, forgings, dies and molds, which significantly reduce the manufacturing costs, lead times and improve overall product quality [6 9]. The hard turning is generally performed without a coolant using coated carbides, ceramics and cubic boron nitride cutting tools due to the required tool material hardness. The cutting tools required for hard turning are relatively expensive as compared to grinding operations and hence there is a need to investigate the flank wear to assure the economic justification for hard turning. The hard turning can provide a relatively high accuracy for hardened components but the problems occur with surface finish and flank wear. Numerous investigators have been conducted to determine the effect of parameters such as feed rate, tool nose radius, cutting speed and depth of cut on surface roughness in hard turning operation [0,].Taguchi s Parameter design suggests an efficient approach for optimization of various parameters with regard to performance, quality and cost [2,3]. Taguchi recommends the use of S/N ratio for the determination of the quality characteristics implemented in engineering design problems. The addition to S/N ratio, a statistical analysis of variance (ANOVA) can be employed to indicate the impact of process parameters on MRR and surface roughness. In this paper Taguchi s DOE approach is used to analyze the effect of turning process 3 P a g e

Experimental investigation of Material Removal Rate and Tool wear in turning of hardened parameters-cutting speed, feed and depth of cut while machining for hardened AISI5200 steel and to obtain an optimal setting of the parameters that results in optimizing MRR and flank wear. II. DETAILS OF EXPERIMENT 2.Workpiece Material, Cutting Tool and Machine The AISI 5200 steel work piece material is selected for the present work and the chemical composition of work piece material includes C-0.93%,Cr-.43%,Mn-0.43%,Si-0.2%,P-0.08%,S-0.0047% and balance Fe. The work pieces of diameter 8mm and 00mm length has been used for trials. For all the work pieces heat treatment was carried out. Initially before the heat treatment average hardness of the work piece was 22HRC. The heat treatment includes Hardening at 850 0 C for two hours and quenched with oil and also Tempering at 200 0 C for one hour. After heat treatment the average hardness value of 48HRC was obtained. The cutting tool insert used for machining AISI 5200 was carbide insert of ISO number: CCMT 32.52 MT TT8020 of Taegu Tec make under dry cutting conditions. The Cutting Tool holder used was of Specification SCLCR22H09 D 4C of WIDIA make. The machine used for turning was all geared Head Precision lathe (Preci-Turnmaster -350) of OM JINA MACHINE TOOLS make. The instrument used for measuring weight of the specimen and flank wear was weighing balance and Tool maker s microscope respectively. Machining time is noted by stopwatch and measured final weight of all jobs. Material removal rate (MRR) is calculated by using relation MRR = (Wi. Wf) Machining Time, where W i is the initial weight of the workpiece and W f is the final weight of the work piece. The Taguchi method developed by Genuchi Taguchi is a statistical method used to improve the product quality in industries [4].With the Taguchi method it is possible to significantly reduce the number of experiments. The Taguchi method is not only an experimental design technique, but also a beneficial technique for high quality system design [5]. 2.2 Taguchi Method The Taguchi technique includes the following steps: determine the control factors, determine the levels belonging to each control factor and select the appropriate orthogonal array, assign the control factors to the selected orthogonal matrix and conduct the experiments, analyze data and determine the optimal levels of control factors, perform the confirmation experiments and obtain the confidence interval, improve the quality characteristics. The Taguchi method uses a loss function to determine the quality characteristics. Loss function values are also converted to a signal-to-noise (S/N) ratio (η). In general, there are three different quality characteristics in S/N ratio analysis, namely Nominal is the best, Larger is the better and Smaller is the better. For each level of process parameters, signal-to-noise ratio is calculated based on S/N analysis. 2.3 Selection of Control factors and orthogonal array In this study Cutting speed, Feed rate and Depth of cut (DOC) was selected as control factors and their levels were determined as shown in the Table. Table Turning Parameters and their levels Factors Level Level 2 Level 3 Cutting Speed(rpm) 450 70 20 Feed rate(mm/rev) 0.05 0.2 0.8 Depth of cut(mm) 0.2 0.3 0.4 The first step of the Taguchi method is to select an appropriate orthogonal array. The most appropriate orthogonal array (L9) was selected to determine the optimal turning parameters based on the total degree of freedom (DOF) and to analyze the effects of these parameters. The L9 orthogonal array has eight DOF and can handle three level design parameter. The L9 orthogonal array is as shown in the Table2. Table 2 Orthogonal L9 array of Taguchi Experiment P P2 P3 2 2 2 3 3 3 4 2 2 4 P a g e

Mean of SN ratios Experimental investigation of Material Removal Rate and Tool wear in turning of hardened 5 2 2 3 6 2 3 7 3 3 8 3 2 9 3 3 2 III. ANALYSIS AND DISUSSION OF EXPERIMENTAL RESULTS Table 3 shows the experiment results for the flank wear and MRR and corresponding S/N ratios were obtained with the help of Minitab.v.6.2.0 software. 3. Cause of Cutting speed, feed rate and Depth of cut on MRR From the response Table 4 and Fig. it is clear that cutting speed is the most influencing factor followed by depth of cut and feed rate for MRR. The optimum for MRR is cutting speed of 20rpm, feed rate of 0.2mm/rev and depth of cut of 0.4mm. Table 3 Experimental results for the flank wear, MRR and corresponding S/N ratios Sl.No SPEED (rpm) FEED (mm/rev) DOC (mm) Flank wear(mm) S/N Ratio for flank wear MRR(g/min) S/N Ratio for MRR 450 0.05 0.2 0. 9.7 0.008-4.89 2 450 0.2 0.3 0.03 30.45 0.296-0.55 3 450 0.8 0.4 0.64 3.87 0.086-2.23 4 70 0.05 0.3 0.4 7.07 0.02-38.06 5 70 0.2 0.4.23 -.79 0.3-8.87 6 70 0.8 0.2 0.07 23.09 0.067-23.37 7 20 0.05 0.4 0.32 9.89 0.542-5.30 8 20 0.2 0.2 0. 20.00 0.089-2.00 9 20 0.8 0.3 0.97 0.26 0.233-2.63 Table 4 Response Table for Signal to Noise Ratios (Larger is better) Level Speed(rpm) Feed(mm/rev) DOC(mm) -24.56-28.42-28.76 2-26.77-6.8* -20.42 3-2.98* -9.08-5.4* Delta 3.79.6 3.62 Rank 3 2 * indicates optimum level Main Effects Plot for SN ratios Data Means SPEED(rpm) FEED(mm/rev) -5-20 -25-30 450 70 DOC(mm) 20 0.05 0.2 0.8-5 -20-25 -30 0.2 0.3 0.4 Signal-to-noise: Larger is better Figure Main effects plots for MRR 5 P a g e

Mean of SN ratios Experimental investigation of Material Removal Rate and Tool wear in turning of hardened 3.2 Cause of Cutting speed, feed rate and Depth of cut on flank wear From the response Table 5 and Fig. 2 it is clear that depth of cut is the most influencing factor followed by cutting speed and feed for flank wear. The optimum conditions for flank wear are 450 rpm feed rate of 0.2mm/rev and depth of cut of 0.2mm Table 5 Response Table for Signal to Noise Ratios (Smaller is better) Level Speed(rpm) Feed(mm/rev) DOC(mm) 7.83* 5.38 20.75* 2 2.79 6.22* 5.93 3 0.05 9.08 3.99 Delta 7.78 7.4 6.76 Rank 2 3 * indicates optimum level Main Effects Plot for SN ratios Data Means 20 SPEED(rpm) FEED(mm/rev) 5 0 5 20 450 70 DOC(mm) 20 0.05 0.2 0.8 5 0 5 0.2 0.3 Signal-to-noise: Smaller is better 0.4 Figure 2 Main effects plots for Flank wear 3.3 Analysis of variances (ANOVA) Taguchi method cannot judge and determine effect of individual parameters on entire process while percentage contribution of individual parameters can be well determined using ANOVA.Using Minitab.v.6.2.0 software ANOVA module can be employed to investigate effect of parameters. It is clear from the Table6 cutting speed (rpm) it is contributing of about 28.33%, depth of cut 24.3% and feed rate 9.55% on Material Removal Rate (MRR). Table 6 ANOVA for S/N ratio for MRR Source DOF SS MS F P % contribution Speed(rpm) 2 329.2 64.6.02 0.495 28.33% Feed(mm/rev) 2 227.2 3.6 0.70 0.587 9.55% DOC(mm) 2 282.8 4.4 0.88 0.533 24.3% Error 2 322.5 6.2 27.7% Total 8 6.7 _ 00% 6 P a g e

Experimental investigation of Material Removal Rate and Tool wear in turning of hardened It is evident from Table 7 depth of cut is the most significant factor contributing of about 45.52 %, followed by cutting speed 9.5% and feed rate 9.3% on flank wear. Table 7 ANOVA for S/N ratio for flank wear Source DO SS MS F P % contribution F Speed(rpm) 2 93.5 46.7 0.27 0.789 9.54% Feed(mm/rev) 2 9.4 45.7 0.26 0.793 9.32% DOC(mm) 2 446.9 223.5.28 0.439 45.52% Error 2 349.9 74.9 35.62% Total 8 98.7 _ 00% IV. VALIDATION OF EXPERIMENTS After obtaining optimum conditions from Taguchi method of both MRR and flank wear the prediction was made for MRR and flank wear. The predicted value of MRR for optimum conditions of cutting speed 20rpm feed rate0.2mm/rev and depth of cut 0.4mm is 0.782g/min and when the actual experiment was done using these optimum conditions the MRR obtained is 0.807g/min therefore the error obtained is 2.5% as shown in Table8. Table 8 Confirmation test for MRR Optimum Values S/N ratio obtained Predicted MRR(g/min) Actual MRR(g/min) obtained Error% Speed:20rpm Feed:0.2mm/rev DOC:0.4mm -2.05574 0.782 0.807 2.5% The predicted value of flank wear for optimum conditions of cutting speed 450rpm feed rate0.2mm/rev and depth of cut 0.2mm is 0.042mm and when the actual experiment was done using these optimum conditions the surface roughness obtained is 0.04mm therefore the error obtained is.2% as shown in Table 9.From these confirmation tests, good agreement between the predicted machining performance and the actual performance were observed. Optimum Values Speed:450rpm Feed:0.2mm/rev DOC:0.2mm Table 9 Confirmation test for flank wear S/N ratio Predicted flank Actual flank Error% obtained wear(mm) wear(mm) obtained 27.69 0.042 0.04.2% V. CONCLUSION The optimum conditions obtained from Taguchi method for optimizing Material Removal Rate (MRR) during turning of hardened AISI5200 steel under dry condition are cutting speed of 20rpm Feed rate of 0.2mm/rev and depth of cut of 0.4mm. From response table for S/N ratio of MRR it is clear that cutting speed is the most significant factor influencing MRR followed by Depth of cut and Feed rate is the least significant factor. Analysis of Variances (ANOVA) for S/N ratio for MRR clearly indicates that the cutting speed is majorly contributing of about 28.33% in obtaining optimal MRR followed by depth of cut 24.3% and feed rate 9.55%. Optimum conditions for optimizing flank wear are cutting speed of 450rpm Feed rate of 0.2mm/rev and depth of cut of 0.2mm From response table for S/N ratio of surface roughness it is clear that depth of cut is the most significant factor influencing flank wear followed by cutting speed and feed rate which is the least significant factor. Analysis of Variances (ANOVA) for S/N ratio for surface roughness clearly indicates that the depth of cut is majorly contributing of about 45.52% in obtaining optimal flank wear followed by cutting speed 9.54% and feed rate 9.32%. 7 P a g e

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