Abstract

1. INTRODUCTION

CNC machining has established an unbeatable position in recent years by providing improved dependability, accuracy, and productivity. Additionally, CNC milling offers greater freedom in selecting the levels of the cutting parameters. Various milling procedures are used in industries. Out of these, the CNC end milling technique is unavoidable in the automotive, aerospace, and metal processing industries as it delivers high precision, accuracy, and dependability. End milling attained an unrivalled position in the manufacturing industry by meeting demands. Numerous criteria that regulate the process are included in every machining operation. Both controllable and non-controllable characteristics fall under this category. S_s, C_s, F_r, D_c, and other variables are examples of controllable parameters that can be adjusted in accordance with requirements. Non-controllable parameters are those that can be regulated indirectly by controllable parameters rather than being directly controlled. A few examples include chip formation vibrations, tool wear (T_w), and S_r.

Surface integrity was the subject of an experimental research on Al2014-T6 by WANG and CHANG et al. [¹[1] WANG, M.Y., CHANG, H.Y., “Experimental study of surface roughness in slot end milling AL2014-T6”, International Journal of Machine Tools & Manufacture, v. 44, n. 1, pp. 51–57, Jan. 2004. doi: http://dx.doi.org/10.1016/j.ijmachtools.2003.08.011.
https://doi.org/10.1016/j.ijmachtools.20... ]. Slot end milling was used for trial runs. The study found that the main determinants of S_r are vibrations during milling and the F_r. PALANISAMY et al. [²[2] PALANISAMY, P., RAJENDRAN, I., SHANMUGASUNDARAM, S., “Optimization of machining parameters using genetic algorithm and experimental validation for end-milling operations”, International Journal of Advanced Manufacturing Technology, v. 32, n. 7–8, pp. 644–655, Apr. 2007. doi: http://dx.doi.org/10.1007/s00170-005-0384-3.
https://doi.org/10.1007/s00170-005-0384-... ] analyzed the parameter effect of CNC milling and proposed optimum settings. The study used a genetic algorithm, and the experimental analysis proved that F_r and D_c played significant role in governing S_r. MUTHUKRISHNAN and DAVIM [³[3] MUTHUKRISHNAN, N., DAVIM, J.P., “Optimization of machining parameters of Al/SiC-MMC with ANOVA and ANN analysis”, Journal of Materials Processing Technology, v. 209, n. 1, pp. 225–232, Jan. 2009. doi: http://dx.doi.org/10.1016/j.jmatprotec.2008.01.041.
https://doi.org/10.1016/j.jmatprotec.200... ] conducted an extensive study in adaptive control of CNC machining. The development of research into maintaining the precision and dependability of machining parameters was thoroughly covered in this study. The article provided a summary of the methods created thus far to increase the effectiveness of CNC machining. QUINTANA et al. [⁴[4] QUINTANA, G., CIURANA, J.D., RIBATALLADA, J., “Surface roughness generation and material removal rate in ball end milling operations”, Materials and Manufacturing Processes, v. 25, n. 6, pp. 386–398, May. 2010. doi: http://dx.doi.org/10.1080/15394450902996601.
https://doi.org/10.1080/1539445090299660... ] provided a strategy for surface integrity prediction. The study was limited to one objective function, and potential consequences of other responses were not taken into account. MANSOUR and ABDALLA [⁵[5] MANSOUR, A., ABDALLA, H., “Surface roughness model for end milling: a semi-free cutting carbon casehardening steel (EN32) in dry condition”, Journal of Materials Processing Technology, v. 124, n. 1–2, pp. 183–191, Jun. 2002. doi: http://dx.doi.org/10.1016/S0924-0136(02)00135-8.
https://doi.org/10.1016/S0924-0136(02)00... ] created an analytical model. SURESH et al. [⁶[6] SURESH, K.R., SENTHIL, K.S., MURUGAN, K., et al., “Green machining characteristics study of Al-6063 in CNC milling using Taguchi method and grey relational analysis”, Advances in Materials Science and Engineering, v. 2021, pp. 1–12, Dec. 2021. doi: http://dx.doi.org/10.1155/2021/4420250.
https://doi.org/10.1155/2021/4420250... ] studied single-response and multi-response optimization using the Taguchi design and grey relational analysis (GRA) while working on Al6063 using green machining techniques.

The study implicated C_s, F_r, and D_c as the regulating parameters. The optimization exploration employing DOE on S_r was acknowledged by CHANG et al. [⁷[7] CHANG, H.K., KIM, J.H., KIM, I.H., et al., “In-process surface roughness prediction using displacement signals from spindle motion”, International Journal of Machine Tools & Manufacture, v. 47, n. 6, pp. 1021–1026, May 2007. http://dx.doi.org/10.1016/j.ijmachtools.2006.07.004.
https://doi.org/10.1016/j.ijmachtools.20... ]. In a different study, GOLOGLU and SAKARYA [⁸[8] GOLOGLU, C., SAKARYA, N., “The effects of cutter path strategies on surface roughness of pocket milling of 1.2738 steel based on Taguchi method”, Journal of Materials Processing Technology, v. 206, n. 1–3, pp. 7–15, Sep. 2008. doi: http://dx.doi.org/10.1016/j.jmatprotec.2007.11.300.
https://doi.org/10.1016/j.jmatprotec.200... ] and DHOKIA et al. [⁹[9] DHOKIA, V.G., KUMAR, S., VICHARE, P., et al., “An intelligent approach for the prediction of surface roughness in ball-end machining of polypropylene”, Robotics and Computer-integrated Manufacturing, v. 24, n. 6, pp. 835–842, Dec. 2008. doi: http://dx.doi.org/10.1016/j.rcim.2008.03.019.
https://doi.org/10.1016/j.rcim.2008.03.0... ] employed DOE to forecast the ideal degree of S_r. By utilizing the taguchi based GRA [¹⁰[10] VISWANATHAN, R., RAMESH, S., MANIRAJ, S., et al., “Measurement and multi-response optimization of turning parameters for magnesium alloy using hybrid combination of Taguchi-GRA-PCA technique”, Measurement, v. 159, pp. 107800, Jul. 2020. doi: http://dx.doi.org/10.1016/j.measurement.2020.107800.
https://doi.org/10.1016/j.measurement.20... ], optimization was performed to arrive at minimum corrosion rate and weight loss of Al/SiCp. It was a metal matrix composite experimented as per L9 orthogonal array involving volume % of SiCp, NaCl solution and time factor for determining the effects on corrosion rate and weight loss incurred. The review also sheds light on the sophisticated optimization methods like GA, ANN, and fuzzy [¹¹[11] ABU-MAHFOUZ, I., BANERJEE, A., RAHMAN, E., “Evolutionary optimization of machining parameters based on surface roughness in end milling of hot rolled steel”, Materials (Basel), v. 14, n. 19, pp. 5494, Sep. 2021. doi: http://dx.doi.org/10.3390/ma14195494. PubMed PMID: 34639893.
https://doi.org/10.3390/ma14195494... , ¹²[12] VISHNU, V.S., VARGHESE, K.G., GURUMOORTHY, B., “A data-driven digital twin of CNC machining processes for predicting surface roughness”, Procedia CIRP, v. 104, pp. 1065–1070, Jan. 2021. doi: http://dx.doi.org/10.1016/j.procir.2021.11.179.
https://doi.org/10.1016/j.procir.2021.11... , ¹³[13] SAVKOVIC, B., KOVAC, P., RODIC, D., et al., “Comparison of artificial neural network, fuzzy logic and genetic algorithm for cutting temperature and surface roughness prediction during the face milling process”, Advances in Production Engineering & Management, v. 15, n. 2, pp. 137–150, Jun. 2020. doi: http://dx.doi.org/10.14743/apem2020.2.354.
https://doi.org/10.14743/apem2020.2.354... ] to determine the best set of parameters for machining. A study on low-carbon mold steel (UNS T51620) was carried out using BBD and GRA for the optimization of R_a and M_rr and P_c. The result showed significant improvement in the optimized set of parameters with a 10% deviation proving the reliability of the developed model [¹⁴[14] SURYARAJ, G.K., PRINCE, M., MANIRAJ, J., “Optimization of boriding process on AISI 1015 steel using response surface methodology”, Matéria (Rio de Janeiro), v. 28, n. 2, pp. e20230086, Jun. 2023. doi: http://dx.doi.org/10.1590/1517-7076-rmat-2023-0086.
https://doi.org/10.1590/1517-7076-rmat-2... , ¹⁵[15] NADALE, H.C., SVOBODA, H.G., “Fatigue life of PAW welded joints of high strength microalloyed boron steels”, Matéria (Rio de Janeiro), v. 23, n. 2, pp. e11996, 2018., ¹⁶[16] ANAND, T., RAGUPATHY, K., RANGANATHAN, L., “Optimization of drilling parameters using GRA for polyamide 6 nanocomposites”, Matéria (Rio de Janeiro), v. 28, n. 2, pp. e20220337, May 2023. doi: http://dx.doi.org/10.1590/1517-7076-rmat-2022-0337.
https://doi.org/10.1590/1517-7076-rmat-2... ]. A literature study was exclusively carried [¹⁷[17] PANWAR, V., SHARMA, D.K., KUMAR, K.P., et al., “Experimental investigations and optimization of surface roughness in turning of en 36 alloy steel using response surface methodology and genetic algorithm”, Materials Today: Proceedings, v. 46, pp. 6474–6481, Jan. 2021. doi: http://dx.doi.org/10.1016/j.matpr.2021.03.642.
https://doi.org/10.1016/j.matpr.2021.03.... ] on GA and their use in CNC milling for the optimization of machining parameters.

A vivid picture on machining relationship [¹⁸[18] ZAHOOR, S., AZAM, H.A., MUGHAL, M.P., et al., “WEDM of complex profile of IN718: multi-objective GA-based optimization of surface roughness, dimensional deviation, and cutting speed”, International Journal of Advanced Manufacturing Technology, v. 114, n. 7–8, pp. 2289–2307, Jun. 2021. doi: http://dx.doi.org/10.1007/s00170-021-06916-8.
https://doi.org/10.1007/s00170-021-06916... ] was presented a work based on cloud computing assisting a thorough analysis of cutting tool measurement in the turning process. In this research, the interaction effect between the parameters and responses were studied. A single objective function optimization was performed using GA by OKTEM et al. [¹⁹[19] OKTEM, H., ERZURUMLU, T., ERZINCANLI, F., “Prediction of minimum surface roughness in end milling mold parts using neural network and genetic algorithm”, Materials & Design, v. 27, n. 9, pp. 735–744, Jan. 2006.] to determine the optimal value for minimizing R_a. SINGH et al. [²⁰[20] SINGH, T., SHARMA, V.K., RANA, M., et al., “Multi response optimization of process variables in MQL assisted face milling of EN31 alloy steel using grey relational analysis”, Materials Today: Proceedings, v. 47, pp. 4062–4066, Jan. 2021. doi: http://dx.doi.org/10.1016/j.matpr.2021.05.408.
https://doi.org/10.1016/j.matpr.2021.05.... ] used taguchi resilient design to implement a multi-objective strategy for cyclone separator optimization, validated through numerical simulation. In another work ideal tool-stress model for EN8 steel in CNC turning was proposed. One may see substantial research in machining employing higher-order techniques in terms of optimization. However, it is important to remember that the majority of the labour done is restricted to single-objective tasks. In actuality, there are usually several, incongruent responses to any machining operation. As a result, it becomes necessary to interpret the results of parameter interaction effects to arrive at the key machining settings.

Another research was performed on EN8 steel for sustainable manufacturing using multi-criteria decision making (MCDM) approach for optimization of machining parameters [²¹[21] SHAIKH, M.B.N., ALI, M., KHAN, Z.A., et al., “An MCDM approach for multi-response optimisation of machining parameters in turning of EN8 steel (AISI-1040) for sustainable manufacturing”, International Journal on Interactive Design and Manufacturing, v. 17, n. 6, pp. 3159–3176, Jun. 2023. doi: http://dx.doi.org/10.1007/s12008-023-01368-8.
https://doi.org/10.1007/s12008-023-01368... ]. The study focused on optimizing M_rr, S_r, noise level and cutting force. The experiments were performed aligned to L27 orthogonal array with controllable parameters as C_s, F_r and D_c. The result showed that the responses were highly influenced by F_r followed by D_c and C_s. A study on the optimization of process parameters was performed by Mian and team for Near Dry Turning (NDT) of two steel grades, EN8 and EN31 [²²[22] MIAN, T., MAGO, J., SHAIKH, M.B.N., et al., “Near dry turning of EN8 and EN31 steel: multi-objective optimization using grey relational analysis”, Engineering Research Express, v. 4, n. 3, pp. 035053, Sep. 2022. doi: http://dx.doi.org/10.1088/2631-8695/ac90a0.
https://doi.org/10.1088/2631-8695/ac90a0... ]. Near Dry Turning was adopted with minimal amount of coolant with a predominant use of compressed air. In this study, Al₂O₃ nanofluid was employed as a coolant along with compressed air. The primary machining parameters investigated were C_s, F_r and D_c, with a focus on achieving efficient cooling. The result showed a reduction in S_r of 12.3% and 14.6% for EN8 and EN31 in dry machining using nanofluid. Also, the result showed a reduction of 7% temperature in cutting area. These results appealed the significance of optimization and recommended the used nanofluid in near dry turning of steels.

A detailed review [²³[23] SHAIKH, M.B.N., ALI, M., “Turning of steels under various cooling and lubrication techniques: a review of literature, sustainability aspects, and future scope”, Engineering Research Express, v. 3, n. 4, pp. 042001, Nov. 2021. doi: http://dx.doi.org/10.1088/2631-8695/ac2e10.
https://doi.org/10.1088/2631-8695/ac2e10... ] was carried out on cutting fluids and their methods of application during various machining operations. The review also consolidated issues associated with conventional and concerned sustainability metrics. Precisely, techniques like dry machining, minimum quantity cooling and lubrication, gas based coolant, solid lubricants, cryogenic means provided superior machinability compared to conventional means. The review also summarized demands and challenges involved in sustainability techniques.

1.1. Literature gap identified

The extensive literature survey performed gave an insight towards tool steel where only few research has been performed. Tool steel is a type of high-quality carbon and alloy steel that is specifically designed for the production of tools and dies. These steels are engineered to have the necessary properties for cutting, shaping, and forming materials in various industrial processes. Tool steels are known for their exceptional hardness, wear resistance, and toughness. They are hardened to withstand the repeated impacts and stresses encountered in cutting, forming, and shaping operations. They can be heat-treated to achieve high levels of hardness. Resistance towards wear, abrasion, and deformation is very crucial for maintaining sharp cutting edges and prolonging the life of the tool. These steels are specifically designed for use in mold and die applications where good machinability, weldability, and surface finish are essential.

SAE-AISI P3 steel also known as UNS T51603 is suitable for higher stress applications like stamping, forging and cutting as it offers best suited combination of. The superior qualities in terms of resistance to wear, toughness, and hardness makes it unique in such applications. Moreover, these steels are highly stable to deformation and cracking when subjected to heat treatment processes. T51603 finds its applications in almost all industries requiring higher precision and dependability. Since this material is universally used in varied industry applications, the need to provide machinability solutions towards sustainability is inevitable. From literature survey, it is also found that few research was performed in T51603 addressing towards optimization and sustainability. The proposed work is a single and multi-objective function, and an attempt towards optimizing three seemingly incongruent responses: S_r, M_rr, and P_c while machining Low-Carbon Mold Steel UNS T51603. This study involves application of BBD for performing the experimental runs followed by arriving at the optimized parameters through multi-objective optimization involving contradictory responses using GRA. The application of BBD and GRA in the study of T51603 is unique as no previous research has been made in this segment.

2. METHODOLOGY AND IMPLEMENTATION

2.1. Work material and tool

The primary alloying components, viz. nickel and chromium dominant the low-carbon mold steels, which are categorized as group P steels. For these steels to develop the desired properties, nitriding or carburizing is typically used. Due to their ease of machining into intricate and substantial molds and dies, these steels have good machinability. They are mostly utilized in die casting and injection molds. Pre-hardened UNS T51603 steel is chosen as the work material due to its broad application. The hardness of the work material is determined in the laboratory using Brinell Hardness Testing Machine and found to be 341 HB. For machining, a rectangular work piece with the following measurements is used: 75×30×12 (dimensions in mm). The chemical constituents of the work material are evaluated in SITARC (Scientific and Industrial Testing and Research Center), Coimbatore and is shown in Table 1. The selected material finds its applications in clinching fasteners, studs, nuts, bolt, screws etc.

2.2. Controllable & non-controllable parameters

The S_s, F_r, D_c, tool rake angle (T_ra), C_fr, S_r, L_t, etc., all have a significant impact on machining operations [²⁴[24] JOEL, C., JEYAPOOVAN, T., “Optimization of machinability parameters in abrasive water jet machining of AA7075 using Grey-Taguchi method”, Materials Today: Proceedings, v. 37, pp. 737–741, Jan. 2021. doi: http://dx.doi.org/10.1016/j.matpr.2020.05.741.
https://doi.org/10.1016/j.matpr.2020.05.... , ²⁵[25] BELLUBBI, S., SATHISHA, N., MALLICK, B., “Multi response optimization of ECDM process parameters for machining of microchannel in silica glass using Taguchi-GRA technique”, Silicon, v. 14, n. 8, pp. 4249–4263, Jun. 2022. doi: http://dx.doi.org/10.1007/s12633-021-01167-4.
https://doi.org/10.1007/s12633-021-01167... ]. Out of them, some parameters, known as controllable parameters can be managed prior to the execution of machining. Uncontrollable parameters are those which are indirectly controlled through controllable parameters like S_r, M_rr, P_c etc. The present study involves S_s, D_c, F_r, and C_fr as the controllable parameters. The uncontrollable parameters or responses are S_r, M_rr, and P_c. The levels of the chosen adjustable parameters are set in accordance with the manufacturer’s recommendations and current research. The F_r (mm/min), S_s (rpm), D_c (mm), and C_fr (l/min) are the controllable parameters that have been recognized and taken into account. The experiments were performed in a 3-axis vertical milling center and the sample are machined as per the design matrix shown in Figure 1. The bed size of the machine used was 700 × 400 mm, with X, Y, Z travel of 700 mm/min, 400 mm/min and 300 mm/min respectively. The maximum spindle speed of the machine was restricted to 16,000 rpm. The machined surface is evaluated using surface testing equipment of MITUTOYO brand with resolution between 0.01 µm to 0.3 µm. The Sr was measured in three different locations and the average value was taken for further analysis as shown in Figure 2.

Figure 1
Runs conducted.

Figure 2
Surface roughness testing.

2.3. Scanning Electron Microscope (SEM)

2.4. Design matrix

Table 2 highlights the factors and levels assigned for each parameters. The runs were performed as per BBD sequences as shown in Table 3 with responses measured.

3. RESULTS AND DISCUSSIONS

The next sections cover each distinct parametric effect on the responses. Based on the desirability function, the machining parameters were optimized. Analysis of Variance (ANOVA) validates the desirability function’s competence.

3.1. RSM for S_r

According to the analysis shown above, “F-value” of 627600 and a “P-value” less than 0.0001 adheres to the desirability as enlisted in Table 4. The insignificance of the model arises when the values records more than 0.10. In other words, only 0.01% chance exists that noise will have a negligible influence [¹²[12] VISHNU, V.S., VARGHESE, K.G., GURUMOORTHY, B., “A data-driven digital twin of CNC machining processes for predicting surface roughness”, Procedia CIRP, v. 104, pp. 1065–1070, Jan. 2021. doi: http://dx.doi.org/10.1016/j.procir.2021.11.179.
https://doi.org/10.1016/j.procir.2021.11... , ²⁶[26] BAI, L., CHENG, X., YANG, Q., et al., “Predictive model of surface roughness in milling of 7075Al based on chatter stability analysis and back propagation neural network”, International Journal of Advanced Manufacturing Technology, v. 126, n. 3-4, pp. 1347–1361, May 2023. doi: http://dx.doi.org/10.1007/s00170-023-11133-6.
https://doi.org/10.1007/s00170-023-11133... , ²⁷[27] TLHABADIRA, I., DANIYAN, I.A., MASU, L., et al., “Process design and optimization of surface roughness during M200 TS milling process using the Taguchi method”, Procedia CIRP, v. 84, pp. 868–873, Jan. 2019. doi: http://dx.doi.org/10.1016/j.procir.2019.03.200.
https://doi.org/10.1016/j.procir.2019.03... ]. Additionally, R², Adj R², and Pred R² values near to 1 justifies the efficiency of the model. The surface graphs presented below provides vivid picture towards interaction between machining parameters and S_r.

3.1.1. Parameter interaction effects

Figure 3 displays the interaction plot between S_s and D_c on S_r. When level of D_c is assigned between 0.45 to 0.60 mm and S_s is between 1800 to 2500 rpm, the least amount of R_a is produced. Any departure from the aforementioned level had a negative impact on the reaction R_a. Figure 4 depicts the interaction of F_r and C_fr on S_r. The graphical view highlights that higher level of C_fr aids in getting better S_r. Whereas, in the case of F_r, all levels significantly contributes towards better S_r. However, it also depends on the level assigned for other controllable parameters [¹³[13] SAVKOVIC, B., KOVAC, P., RODIC, D., et al., “Comparison of artificial neural network, fuzzy logic and genetic algorithm for cutting temperature and surface roughness prediction during the face milling process”, Advances in Production Engineering & Management, v. 15, n. 2, pp. 137–150, Jun. 2020. doi: http://dx.doi.org/10.14743/apem2020.2.354.
https://doi.org/10.14743/apem2020.2.354... , ²⁸[28] FEDAI, Y., KAHRAMAN, F., KIRLI, A.K.I.N., et al., “Optimization of machining parameters in face milling using multi-objective Taguchi technique”, Technical Journal, v. 12, n. 2, pp. 104–108, Jun. 2018.]. When additional parameters are taken into account for measurement, it is discovered that the effect of parameter F_r has the least impact on S_r.

Figure 3
Interaction plot: S_s & D_c on S_r.

Figure 4
Interaction plot: F_r & C_fr on S_r.

The interaction plot between S_s and C_fr on S_r is depicted in Figure 5. The least S_r is achieved when both parameters are maintained at higher levels between 2200 to 2500 rpm and 6 to 8 l/min. When parameter S_s and parameter C_fr are steadily increased, better results are obtained.

Figure 5
Interaction plot: S_s & C_fr on S_r.

The influence between F_r and D_c on S_r is shown in Figure 6. A thorough examination reveals that parameter F_r has a stronger influence on the response S_r than D_c. It may be concluded from trial runs 3 and 6, that lowering the level of F_r lowers the S_r. It is noteworthy to state that when other parameters are maintained at the same level (as observed in runs 3, 6 and 28) the effect of S_s on S_r is higher. This offers a clear picture on the leading parameter impacting S_r. In this instance, the most important parameter impacting S_r are in the following order: S_s, F_r, D_c, and C_fr.

Figure 6
Interaction plot: F_r & D_c on S_r.

3.1.2. Optimized parameters for S_r

The optimized (single response) parameters for S_r is listed in the Table 5. From the experimental analysis though F_r had a much stronger influence on S_r compared to S_s and D_c, for achieving minimum S_r, the best combination was found to be a medium F_r that provided a good balance between chip formation and tool engagement, minimizing tool deflections and chatter that can worsen S_r. Moreover, T51603 steel having specific characteristics makes it less sensitive to S_s and D_c within certain ranges. Additionally, the chosen tool geometry and material might have been particularly well-suited for these higher cutting parameters while maintaining good surface finish.

3.2. RSM for M_rr

M_rr is calculated theoretically using the relation given below:

where, D_c1 is axial depth of cut, D_c2 is the radial depth of cut, F_z is the feed per tooth, n is the spindle speed and Z_effc is the number of effective tooth.

Table 6 highlights the ANOVA for M_rr. According to the analysis shown above, F-value of 678091.19 and a P-value less than 0.0001 adheres to the desirability function. The insignificance of the model arises when the values records more than 0.10. In other words, only 0.01% chance exists that noise will have a negligible influence. Additionally, R², Adj R², and Pred R² values near to 1 justifies the efficiency of the model. The interaction of parameters and M_rr is clearly seen in the surface interaction charts that are presented below [²⁹[29] MOGANAPRIYA, C., RAJASEKAR, R., SATHISH KUMAR, P., et al., “Achieving machining effectiveness for AISI 1015 structural steel through coated inserts and grey-fuzzy coupled Taguchi optimization approach”, Structural and Multidisciplinary Optimization, v. 63, n. 3, pp. 1169–1186, Mar. 2021. doi: http://dx.doi.org/10.1007/s00158-020-02751-9.
https://doi.org/10.1007/s00158-020-02751... , ³⁰[30] VENKATESH, S., KUMAR, R.S., SIVAPIRAKASAM, S.P., et al., “Multi-objective optimization, experimental and CFD approach for performance analysis in square cyclone separator”, Powder Technology, v. 371, pp. 115–129, Jun. 2020. doi: http://dx.doi.org/10.1016/j.powtec.2020.05.080.
https://doi.org/10.1016/j.powtec.2020.05... , ³¹[31] SRINIVASAN, A., PRABU, R., RAMESH, S., et al., “Investigation and optimization on micro and nano Al2O3 reinforced aluminium composites using GRA coupled PCA technique”, Journal of Ceramic Processing Research, v. 23, n. 6, pp. 783–793, Dec. 2022.].

3.2.1. Parameter interaction effects

The impact of the parameters on M_rr is seen in the interaction graphs below. The interaction effect between S_s and D_c on M_rr is depicted in Figure 7. When S_s is assigned with level 1 and D_c is steadily increased (as observed in trial 1, 16, and 17) demonstrate a steady increase in M_rr. On the other hand, when S_s is altered and other parameters are maintained at level 1 (5, 11, and 13), one can witness a rise in M_rr however, the rate of growth is significantly slower than former condition. This proof validates that F_r is more significant compared to S_s.

Figure 7
Interaction plot: D_c & S_s on M_rr.

Figure 8 illustrates how parameter F_r and D_c have an impact on M_rr during machining. When S_s and D_c are kept at 2500 rpm and 0.4 mm, and F_r is steadily increased (runs 4, 5, and 29), a steady raise in M_rr can be observed. In contrast, when the levels of S_s and F_r are held constant (1850 rpm, 1500 mm/min) and D_c is changed (runs 8, 9, and 26), D_c showed significant contribution towards rapid increase in M_rr. This observation validates the significant role of D_c compared to F_r. The machining impact of C_fr and F_r on M_rr is depicted in Figure 9. Runs 8, 13, 18, 23, 26, and 28 shows the significant effect of C_fr when other parameters are held constant. An increase in M_rr can be seen in the experimental runs mentioned above. The use of coolant improves M_rr in comparison to F_r, but also depends on D_c and S_s.Figure 10 illustrates how parameters S_s and C_fr related to machining affected M_rr. When other parameters are held constant, the effects of C_fr are clearly shown in the experimental runs 8 and 13, 18 and 28, 23 and 26, and so on. The M_rr has increased in the trial runs mentioned above. On the other hand, when S_s is changed while leaving all other parameters constant, experimental runs 11 & 22, 3 & 29, and 14 & 20 demonstrate an increase in M_rr.

Figure 8
Interaction plot: F_r & D_c on M_rr.

Figure 9
Interaction plot: C_fr & F_r on M_rr.

Figure 10
Interaction plot: S_s & C_fr on M_rr.

3.2.2. Optimized parameters for M_rr

The optimized parameters are enlisted in Table 7. The experimental analysis showed that higher D_c had a significantly stronger influence on M_rr compared to S_s and F_r. This combination provided the best combination offering least tool wear or deflections that could counteract the depth benefit. The medium S_s and F_r provided a good balance between maximizing chip removal per unit time and maintaining tool stability. Higher S_s and F_r might lead to faster M_rr but at the cost of faster tool wear or deflections, ultimately reducing overall M_rr in T51603.

3.3. RSM for P_c

P_c can be measured by theoretical method and by calculation of instantenous power during machining. In the case of theoretical approach, the following equation 3 is used

where, W_c is the width of cut, K_c is the specific cutting force in N/mm².

In the case of calculation of instantenous power, forces and moments are measured with the help of Kistler dynamometer. The measured values are then compared with force and moments measured with QZZ2 dynamometer. In this study, P_c is determined using dynamometer.

According to the analysis shown in Table 8, “F-value” of 565600.00 and a “P-value” less than 0.0001 adheres to the desirability function as shown in Table 8. The insignificance of the model arises when the values records more than 0.10. In other words, only 0.01% chance exists that noise will have a negligible influence. Additionally, R², Adj R², and Pred R² values near to 1 justifies the efficiency of the model [²⁰[20] SINGH, T., SHARMA, V.K., RANA, M., et al., “Multi response optimization of process variables in MQL assisted face milling of EN31 alloy steel using grey relational analysis”, Materials Today: Proceedings, v. 47, pp. 4062–4066, Jan. 2021. doi: http://dx.doi.org/10.1016/j.matpr.2021.05.408.
https://doi.org/10.1016/j.matpr.2021.05.... , ³⁰[30] VENKATESH, S., KUMAR, R.S., SIVAPIRAKASAM, S.P., et al., “Multi-objective optimization, experimental and CFD approach for performance analysis in square cyclone separator”, Powder Technology, v. 371, pp. 115–129, Jun. 2020. doi: http://dx.doi.org/10.1016/j.powtec.2020.05.080.
https://doi.org/10.1016/j.powtec.2020.05... , ³²[32] RAVIKUMAR, N., VIJAYAN, R., VISWANATHAN, R., “Multi-response optimisation for turning of magnesium alloy with untreated and cryogenic treated carbide inserts by grey relational analysis”, Journal of Ceramic Processing Research, v. 24, n. 1, pp. 142–152, Feb. 2023.]. The connection between the machining parameters and P_c is clearly seen in the interaction graphs below.

3.3.1. Parameter interaction effects

The interaction effect on P_c is interpreted in the following figures. Figure 11 displays the impact of S_s and D_c on P_c. When D_c is increased while other parameters are held constant, as seen in experimental runs 8 and 9, 12 and 22, and 11 and 15, P_c increases quickly. This demonstrates that increasing parameter D_c will increase cutting force and increase power consumption. On the other hand, when parameter S_s level is altered in experimental runs 12, 15, and 17 while all other parameters are held constant, a rise in P_c is seen. However, compared to parameter D_c, the effect on power usage is a little less significant. The impact of D_c & F_r on P_c is shown in Figure 12. When F_r alone is varied as seen in experimental runs 4, 5, and 29, P_c increases quickly. This shows that the large fluctuations in cutting forces caused by a rise in parameter F_r significantly increase power usage. However, in runs 8, 9, and 26, S_s is altered while all other parameters are given fixed values. The experimental results showed that S_s directly impacts power consumption followed by D_c and F_r.

Figure 11
Interaction plot: S_s & D_c on P_c.

Figure 12
Interaction plot: F_r & D_c on P_c.

The influence of C_fr & F_r on P_c is depicted in Figure 13. When other parameters are held constant, the effects of parameter C_fr are clearly shown in the experimental runs 8 and 13, 18 and 28, 23 and 26, and so on. An incremental rise in P_c is seen in the afore mentioned runs. This validates that in this study C_fr makes a very small difference in reducing power use. On the other hand, it is noted that an increase in F_r raises P_c in runs 3 & 6, 17 & 28. The influence of S_s and C_fr is shown in Figure 14. Runs (8, 13), (18, 28), and (23, 26) clearly show the effect of C_fr. In the afore mentioned experimental runs, it was found that coolant behaviour varied according to how many other parameters were combined. On the other hand, when S_s is increased, Pc decreases in experimental runs 11 and 22, 3 and 29, and 14 and 20.

Figure 13
Interaction plot: C_fr & F_r on P_c.

Figure 14
Interaction plot: S_s & C_fr on P_c.

3.3.2. Predicted optimized set for P_c

Optimized level of parameters for P_c is given in Table 9 below. The medium S_s found the best relationship between minimizing friction and maximizing chip removal per unit energy. Alongside, Lower D_c and F_r directly reduce cutting forces and chip removal rate, consequently minimizing P_c. Also, lower cutting forces and temperatures at these settings likely resulted in less tool wear, further reducing P_c by maintaining cutting efficiency. Additionally, lower friction allowed for lower to medium coolant flow rates, contributing to energy savings.

4. GRA OPTIMIZATION

where,

m – number of data

n – responses

max zi(ι) – highest value of zi(ι)

min zi(ι) – lowest value

Zi(ι) – post data pre-processing value

where,

γi(y) – grey relational coefficient

Δmin – minimum value of absolute differences

Δmin – maximum value of absolute differences

4.1. Parameter optimization

Ranking is performed in this stage for identification of optimized solution. The highest rank is taken as the optimized solution. GRA executed is highlighted in Table 10.

4.2. GRA optimized result

Table 10 shows that 4th experimental run scores the highest rank and it represents the optimal sequence of parameters. In the case of multi objective optimization, higher S_s resulted in lower S_r through minimized shearing effect offering better M_rr, while addressing potential trade-offs with P_c and tool wear. Lower D_c supported the process by reducing the cutting forces, contributing to lower P_c and potentially smoother surfaces. Medium F_r represented a balanced role between chip formation and tool engagement, influencing both S_r and M_rr without incurring excessive P_c or tool wear thereby providing the optimized results was given in Table 11.

4.3. SEM image analysis for GRA

Figure 15 shows the SEM images of four different experimental runs conducted closer to the multi-objective optimized parameters arrived by GRA. Figure 15(a) shows the SEM image for optimized levels viz experimental run 4 (S_s = 2000 rpm, D_c = 0.2 mm, F_r = 750 mm/min, C_fr = 6 l/min).

Figure 15
SEM images a) experimental run 2; b) experimental run 4; c) experimental run 20.

The confirmatory run shows average S_r = 2.867 µm, P_c = 0.231 HP and M_rr = 0.278 IPM. The image shows presence of burrs due to hardness of the work material. During the progress of machining process, as the cutting tool wears down at faster rate continuously, it becomes less sharp and starts to tear or scrape at the material instead of cleanly shearing it. This tearing action often leaves behind small fragments of material as burrs. Moreover, when higher levels are assigned, it results in higher cutting force paving way for deformation of material at faster rate leading to tear resulting in burr formation as seen in the images. The SEM images also shows reduction in burrs cutting forces are maintained at steady pace.

In few areas smeared materials could be found may be due to lower thermal conductivity of the material. Figure 15(b) shows the SEM image experimental run 20 (S_s = 1750 rpm, D_c = 0.2 mm, F_r = 500 mm/min, C_fr = 6 l/min). The confirmatory run shows average S_r = 4.211 µm, P_c = 0.218 HP and M_rr = 0.2411 IPM. The image shows presence of burrs, adhered chip particles and smeared materials compared to Figure 15(a). Due to reduction of S_s and F_r (maintained at level 2) increased the S_r significantly. Smeared materials are also known as glazing occurs due to rubbing action of the deformed material on to the tool surface affecting the surface texture. The experimental runs and SEM images clearly shows that the formation of smeared materials is significantly influenced by nature of tool followed by F_r and D_c. Higher the levels higher are the chances of formation of smeared materials. Figure 15(c) shows the SEM image experimental run 2 (S_s = 1750 rpm, D_c = 0.2 mm, F_r = 750 mm/min, C_fr = 4 l/min). The confirmatory run shows average S_r = 4.641 µm, P_c = 0.261 HP and M_rr = 0.2123 IPM. The image shows formation of more burrs, and smeared materials along with smeared materials. The reduction in C_fr resulted in reduced removal of material during machining resulting in enhanced formation of smeared materials and adhered chip particles. Moreover, tearing also known as chip tearing or gouging, occurs when the material is ripped instead of being cleanly sheared off by the cutting tool leading to uneven surfaces with poor accuracy. Micro fractures and localized stresses arising during higher level machining leads to formation of micro pores. Presence of micro pores provides more surface area for contaminants and corrosive agents to attach, potentially leading to faster degradation and decreased lifespan. Also these pores acts as stress concentration points resulting in weakening of the material and making it susceptible to failure under load.

5. CONFIRMATORY RUNS

The optimized values attained by BBD and GRA are validated through confirmatory runs to establish the deviation amid the predicted and achieved values as shown in Table 12.

6. CONCLUSIONS

6.1. Future scope of work

7. Acknowledgment

This project is funded by DST-FIST (2022), Government of India vide Ref. No: SR/FST/College-/2022/1300.

8. BIBLIOGRAPHY

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