Prediction and Optimization of Quality of Drilled Holes During Magnetic Drilling Operation of Glass Fiber Reinforced Polymer Composite

Yusuf, Suleiman Mohammed

IUT Repository Home
→
Mechanical and Production Engineering (MPE)
→
Thesis
→
Graduate
→
2015
→
View Item

dc.contributor.author	Yusuf, Suleiman Mohammed
dc.date.accessioned	2021-01-01T09:00:19Z
dc.date.available	2021-01-01T09:00:19Z
dc.date.issued	2015-11-15
dc.identifier.citation	[1] Çoğun, C., Özses, B., 2002, “Effect Of Machining Parameters On Surface Roughness In CNC Machine Tools”, Gazi Üniv.Müh.Mim.Fak. Der. Vol. 17, No1, 59 – 75. [2] D. M. Miller. “Glass Fibers, Engineered Materials Handbook,” Vol. 1 – Composites, ASM International. 1987, pp. 45-48. G. J. Mohr, and W. P. Rowe, “Fiber Glass,” Van Nostrand Reinhold Co., (1978), pp. 207 [3] K. L. Lowenstein, “The Manufacturing Technology of Continuous Glass Fibers.” Elsevier, (1973), pp. 28-30. [4] R. D. Lowrie, Glass Fibers for High-Strength Composites, in “Modern Composite Materials,” Addison-Wesley Publishing Co., (1967), pp. 270-323. [5] G.Boothroyd, Fundamentals of Metal Machining, Arnold, Paris (1986) [6] Abrate S, Machining of Composites. In: Mallick PK, editor Composites engineering hand book, New York, Marcel Deckker Inc, 1997, pp. 777- 780. [7] Abrate S, Machining of Composites. In: Mallick PK, editor Composites engineering hand book, New York, Marcel Deckker Inc, 1997, pp. 781- 789. [8] Abrate S, Machining of Composites. In: Mallick PK, editor Composites engineering hand book, New York, Marcel Deckker Inc, 2001, pp. 292- 295. [9] Abrate S, Machining of Composites. In: Mallick PK, editor Composites engineering hand book, New York, Marcel Deckker Inc, 2001, pp. 352- 359. [10] Komaduri R, Machining of fibre-reinforced composites, Mechanical Engineering, 115(4),1993, PP.58-66 [11] Komaduri R, Machining of fibre-reinforced composites, Mechanical Engineering, 115(4),1993, PP. 105-119 [12] Machining Handbook: adopted from Army’s ‘’handbook fundamentals of machine tools’’ Chapter 6: Drilling Machines [13] Box and Draper, 1987: RSM Chapter 3 [14] Magnetic field :From Wikipedia, the free encyclopedia [15] Kalpakjian, S., Schmid, S. R., Manufacturing Processes for Engineering Materials, 5th edition, Pearson Education Inc., New Delhi (2008). [16] Sonbaty, B. Mulgrew, U. Khashaba and T. Machaly, “Factors affecting the machinability of GFR/epoxy composites,” Composite Structures, vol. 63, pp. 329-338, March 2004. [17] Tagliaferri V, Caprino G, Diterlizzi A (1990) Effect of drilling parameters on the finish and mechanical properties of GFRP composites, Int J of Mach Tool & Manuf, 30(1), pp. 77 -84. [18]. Palanikumar K, Karunamoorthy L, Karthikeyan R., 2006. Assessment of factors influencing surface roughness on the machining of glass fiber-reinforced polymer composites. Mater Des 27:862–871 [19] Khoathane, M C, Vorster, O C and Sadiku E.R, Hemp Fiber-Reinforced 1 Pentene/Polypropylene Copolymer: The Effect of Fiber Loading on the Mechanical and Thermal Characteristics of the Composites, Journal of Reinforced Plastics and Composites, 2008, Vol. 27, pp.1533-1544. [20] A Market Assessment and Impact Analysis of the Owens Corning Acquisition of Saint Gobain's Reinforcement and Composites Business". August 2007. Retrieved2009-07-16 [21] Malkapuram, R, Kumar, V and Yuvraj, S N, Recent Development in Natural Fibre Reinforced Polypropylene Composites, Journal of Reinforced Plastics and Composites, 2008, Vol. 28, pp. 1169-1189. [22] Palanikumar, K. (2010). Modeling and analysis of delamination factor and surface roughness in drilling GFRP composites. Materials and Manufacturing [23] S. C. Lin and I. K. Chen, “Drilling Carbon Fiber-Rein- forced Composite Material at High Speed,” Wear, Vol. 194, No. 1-2, 1999, pp. 156-162. doi:10.1016/0043-1648(95)06831 7 [24]. Mohan, N.S., Ramachandra, A., and Kulkarni, S.M., “Influence of process parameters on cutting force and torque during drilling of glass-fiber polyester reinforced composites”, Composite Structures, vol. 71, pp. 407–413, 2005. [25] Asif Iqbal, A.K.M., Ahsan Ali Khan, 2010. Modelling and Analysis of MRR, EWR and Surface Roughness in EDM Milling through Response Surface Methodology. American journal of Engineering and Applied Sciences 3, 611-619 (2010) [26] Chen W C, Tsao CC. Cutting performance of different coated twist drills. J Mater Process Technol. (1999) 88 : 203-207 [27] El-Sonbaty I., Khashaba U., Machaly T., 2004. Factors affecting the machinability of GFR/epoxy composites. Composite Struc‘tures 63:329–338 [28] B.R.N, Murthy., L.R. Rodrigues, L., &Devineni, A. Process Parameters Optimization in GFRP Drilling through Integration of Taguchi and Response Surface Methodology. Research Journal of Recent Sciences, 1(6), 2012, 7-15. [29] J. Campos Rubio, a. M. Abrao, P. E. Faria, a. E. Correia, and J. P. Davim, Effects of high speed in the drilling of glass fibre reinforced plastic: Evaluation of the delamination factor, Int. J. Mach. Tools Manuf., May 2008, vol. 48, no. 6, pp. 715–720 [30] Graham T. Smith,” Cutting Tool Technology”, Springer-Verlag London Limited 2008. [31] Tsao, C.C., Hocheng, H. (2007). Effect of tool wear on delamination in drilling composite materials. International Journal of Mechanical Sciences, vol. 49, no. 8, p. 983 988, DOI:10.1016/j.ijmecsci.2007.01.001. [32] Abrao, A.M., Faria, P.E., Rubio, J.C., Reis, P.,Davim, J.P. (2007). Drilling of fiber reinforced plastics: A Review. Journal of Material Processing Technology, vol. 186, no. 1-3, p. 1-7, DOI:10.1016/j. jmatprotec.2006.11.146. [33] C. Tsao and H. Hocheng, Evaluation of thrust force and surface roughness in drilling composite material using Taguchi analysis and neural network, Journal of Materials Processing Technology, Vol. 203, No. 1-3, 2008, pp. 342-348. [34] Turgay KIVAK1, Kasım HABALI , Ulvi SEKER, The Effect of Cutting Paramaters on The Hole Quality and,Tool Wear During The Drilling of Inconel 718, Gazi University Journal of Science, 25(2):533-540 (2012) [35] Nouari M.; List, G.; Girot, F. & Gehin, D. 2005, Effect of machining parameters and coating on wear mechanisms in dry drilling of aluminium alloys. International Journal of Machine Tools & Manufacture, Vol. 45, No. 12-13, pp. 1436-1442, ISSN 0890-6955 [36] Anil Jindal, Dr. V. K. Singla, Experimental Investigation of Process Parameters in drilling operation using different software technique, Research Cell: An International Journal of Engineering Sciences ISSN: 2229-6913 Issue July 2011, Vol. 1/135-154 [37] B. Shivapragash, K. Chandrasekharan, C. Parthasarathy and M. Samuel, Multiple Response Optimizations in Drilling Using Taguchi and Grey Relational Analysis, International Journal of Modern Engineering Research, Vol. 3, No. 2, 2013, pp.765-768. [38] Dillio A, Tagliaferri V, Veniali F (1991) Cutting mechanism in drilling of aramide composites, Int J of Mach Tool & Manuf, 31(2), pp. 155-165. [39] E. S. Lee, Precision Machining of Glass Fibre Reinforced Plastics with Respect to Tool Characteristics, The International Journal of Advanced Manufacturing Technology, Vol 17, Issue 11,2011, pp 791-798 [40] E. Ugo. Enemuoh, A. S. Gizawy and A. C Okafor, “An approach for development of damage-free drilling of carbon fiber reinforced thermosets”, International Journal of Machine Tools and Manufacture, vol. 41(12), pp. 1795-1814, February 2001. [41] Mohan, NS; et al: Delamination analysis in drilling process of glass fiber reinforced plastic (GFRP) composite materials, ’Journal of Materials Processing Technology’,vol. 186, 2007, 265-271. [42] S.C. Lin and IK. Chen (2005) ‘Drilling carbon fiberreinforced composite material at high speed’ Composite Structures 71 (2005) 407–413 [43] U. A. Khashsba, “Delamination in drilling GFR-thermoset composites”, Composite Structure, vol. 63, pp. 313-327, March 2004. [44] U.A. Khashaba, M.A. Seif and M.A. Elhamid (2006) ‘Drilling analysis of chopped composites’ Elsevier - Composites: Part A 38 (2007) 61–70 [45] Marta Fernandes and Chris Cook (2006) ‘Drilling of carbon composites using a one shot drill bit - Part II: empirical modeling of maximum thrust force’ Elsevier – International Journal of Machine Tools & Manufacture 46 (2006) 76–79. [46] Islam S, Sein L S, Devid A, Sam B.,(2010), Effect of laminate configuration and feed rate on cutting performance when drilling holes in carbon fiber reinforced plastic composites. Journal of Material Process Technology, 210, 1023-1034. [47] Lin R. J, VanHouts. J, Bhattacharyya. D, Machinability investigations of medium density fiberboard, Holzforschung, 60 (2006) 71-77. [48] Piquet R, Ferret B, Lachaud F, Swider P (2003) Experimental analysis of drilling damage in thin carbon/epoxy plate using special drills, Composites Part A: Appl. Sci. Manufact, 31(10), pp.1107-1115. [49] Tsao CC, Hocheng H (2004) Taguchi analysis of delamination associated with various drill bits in drilling of composite material, Int. j. of Mach tools and Manuf, 44, pp.1085-1090 [50] Palanikumar K, PrakashS,Shanmugan K.,(2008), Evaluation of delamination in drilling GFRP Composites, Materials and Manufacturing Process, 8, 858-64. [51] V. N. Gaitonde & S. R. Karnik & B. Siddeswarappa, B. T. Achyutha, Integrating Box Behnken design with genetic algorithm to determine the optimal parametric combination for minimizing burr size in drilling of AISI 316L stainless steel, Int Journal of Advanced Manufacturing Technology 37(2008),230–240. [52] Abrao A.M., Faria P.E., Rubio J.C.C., Reis P., Davim J.P., 2007. Drilling of fiber reinforced plastics: a review. J. Mater. Process. Technol. 186 (1–3), 1–7. [53] Erisken E, (1999), Influence from production parameters on the surface roughness of a machine. Short fibre reinforced thermoplastic, International Journal of Machine Tools Manufacturing, 39, 1611-1618. [54] U. A. Khashsba, “Delamination in drilling GFR-thermoset composites”, Composite Structure, vol. 63, pp. 313-327, March 2004. [55] Sonbaty Mulgrew B, Khashaba U, Machaly T, (2004), Factors affecting the machinabilityof GFR/epoxy composites, Composites Structures, 63,329-338. [56] Isik B. and Ekici E., 2010. Experimental investigations of damage analysis in drilling of woven glass fiber-reinforced plastic composites. Int J Adv Manuf Technol 49:861–869 [57] El-Sonbaty I., Khashaba U., Machaly T., 2004. Factors affecting the machinability of GFR/epoxy composites. Composite Struc‘tures 63:329–338 [58] Gokay Nemli, Ismail Aydin, Emir Zekovic, “Evaluation of some of the properties of particle board as function of manufacturing parameters, Journal of Materials and Design vol 28(2007) pp 1169-1176. [59] Taghi Tabarsa,Alireza Ashori, Maria Gholamzadeh, “Evaluation of surface roughness and mechanical properties of particle board panels made from bagesse”, Journal of composites, Part B (2011) doi 10.1016/j.compositesb.2010.12.018. [60] Bhattacharya D, Horrigan DPW (1998) A study of hole drilling in Kevlar Composites, Comp sci & Tech, 58, pp. 267-283. [61] Tsao CC, Hocheng H (2003) Comprehensive analysis of delamination in drilling of composite materials with various drill bits, J of Mat Proc Tech, 140, pp.335-339. [62] Khasbaba UA, 2004. Delamination in drilling GFR-thermoset composites. Compos Struct 63:313–327 [63] Wang XM, Zhang LC, 2003. An experimental investigation into the orthogonal cutting of unidirectional fibre reinforced plastics. Int J Mach Tools Manuf 43:1015–1022 [64] Chen, Y. F., Lin, Y. J., Lin, Y. C., Chen, S. L., Hsu, L. R., ―Optimization of electrodischarge machining parameters on ZrO2 ceramic using the Taguchi method,‖ DOI:10.1243/09544054JEM1437 (2009). [65] Kassab, S. Y. and Khoshnaw, Y. K., ―The Effect of Cutting Tool Vibration on Surface Roughness of Work piece in Dry Turning Operation”, Engineering and Technology, Vol. 25(7), pp. 879-889 (2007). [66] Palanikumar K, (2007), Modeling and analysis for surface roughness in machining glass fiber reinforced plastics using response surface methodology, Materials and Design, 28, 2611-2618. [67] Bagchi, P.K., Ghosh, A., ―Mechanism of a cutting tool in presence of a magnetic field‖,Indian Journal of Technology, Vol. 9, pp. 165-168 (1971). Chakrabarti, S., ―Why Magnetic Cutting Tool Has Greater Life- Probable Cause‖, ‖, Institution of Engineers (India) Journal (PR), Vol. 52, pp. 118-123 (1971). [68] Pal, D.K. and Gupta, N.C, ―some experimental studies on drill wear in the presence of alternating magnetic field‖, Institution of Engineers (India) Journal (PR), Vol.53, pp. 195-200 (1973). [69] M.K. Muju, A. Ghosh, ―Effect of magnetic field on diffusive wear of cutting tool‖,Wear, Vol. 58, pp. 137-145 (1980). [70] M.E.L. Mansori, K. Lafdi, D. Paulmier, “Metal Cutting and High Speed Machining”,Kluwer Academicy Plenum Publishers, New York, 2002, p. 301. [71] A.U. Patwari, M. N. Mahmood, and M.D Arif, “Improvement of Machinability of mild steel during turning operation by magnetic cutting”, International Journal on Advanced Science, Engineering and information technology, ISSN 2088- 5334, Vol-2, No-3, pp 9-12. 2012 [72] Ngai Hoon Hoon Serene, “Effect of magnetic field on drilling”, Thesis submitted to National University of Singapore,(2007/2008) [73] Shafi N. et al, ‘’improvement of machinability responses of mild steel during electromagnet assisted turning process’’. BSc student project IUT. Oct 2012 [74] E. U. Enemuoh, A. S. Gizawy and A. C Okafor, “An approach for development of damage-free drilling of carbon fiber reinforced thermosets”, International Journal of Machine Tools and Manufacture, vol. 41(12), pp. 1795-1814, February 2001. [75] J. P Davim and P. Reis, “Study of delamination in drilling carbon fiber-reinforced plastics (CFRP) using design experiments”, Composite Structure, vol. 59, pp. 481-487, March 2003. [76] Yang et al, Delamination-free drilling of composite laminates, Trans. ASME J. Eng. Ind. 116 (4) (1994) 475–481. [77] Choudhury,I.A., El.Baradie,M.A.,(1997), Surface roughness predication in the turning of high strength steel by factorial design of experiments, J.Mater.Process.Technol,67,55-61 [78] Thomas,M., Bcauchamp, Y.,Youssef,Y.A.,Masounave,J.,(1997).An experimental design for surface roughness and built up edge formation in lathe dry turning, Int.J.Qual.Sci.2(3),167-180 [79] Palanikumar K. and Davim J. P., 2009 . Assessment of some factors influencing tool wear on the machining of glass fiber - reinforced plastics by coated cemented carbide tools . J. Mater. Process. Technol. 209 (1), 511–519. [80] Palanikumar K, Karunamoorthy L, Karthikeyan R., 2006. Assessment of factors influencing surface roughness on the machining of glass fiber-reinforced polymer composites. Mater Des 27:862–871 [81] Mustafa Kurt, Eyup Bagei,Yusuf Kaynak, (2009), Application of taguchi methods in the optimization of cutting parameters for surface finish and hole diameter accuracy in dry drilling process, International Journal of Advances in Manufacturing Technology, 40, 458 469. [82] Krishnamoorthy A., Rajendra B., Palanikumar K. 2011, Delamination prediction in drilling of CFRP composites using artificial neural network , J. Eng. Sci. and Tech. Vol. 6, No. 2 : 191 – 203. [83] S.Prakash,K.PalaniKumar, “Modeling for prediction of surface roughness in drilling MDF panels using response surface methodology”,Journal of Composite materials, 2010, doi:10.1177/0021998310385026 [84] T V Rajamurugan, K Shanmugam, S Rajakumar, K Palanikumar. Modelling and analysis of thrust force in drilling of GFRP Composites using Response Surface Methodology (RSM). Procedia Engineering 38 ( 2012 ) 3757 – 3768. [85] Lin, W. S., Lee B. Y., Wu C. L.,Modeling the surface roughness and cutting force for turning”, Journal of Materials Processing Technology, Vol. 108, pp. 286-293(2001). [86] Lee, S. S. and Chen, J. C., “Online surface roughness recognition system using artificial neural networks system in turning operations”, International Journal of Advanced Manufacturing Technology, Vol. 22, pp. 498–509 (2003). [87] Kirby, E. D., Zhang, Z. and Chen, J. C., Development of An Accelerometer based surface roughness Prediction System in Turning Operation Using Multiple Regression Techniques‖, Journal of Industrial Technology, Vol. 20 (4), pp. 1-8 (2004). [88] Özel, T. and Karpat, Y.,Predictive modeling of surface roughness and tool wear in hard turning using regression and neural networks‖, International Journal of Machine Tools and Manufacture, Vol.45, pp. 467–479 (2005). [89] Ahmed, S. G., Development of a Prediction Model for Surface Roughness in Finish Turning of Aluminium, Sudan Engineering Society Journal,Vol. 52 (45), pp. 1-5 (2006). [90] Abburi, N. R. and Dixit, U. S.,A knowledge-based system for the prediction of surface roughness in turning process”, Robotics and Computer-Integrated Manufacturing, Vol. 22, pp. 363–372 (2006). [91] Zhong, Z. W., Khoo, L. P. and Han, S. T.,Prediction of surface roughness of turned surfaces using neural networks”, International Journal of Advance Manufacturing Technology, Vol. 28, pp. 688–693(2006). [92] Al-Ahmari, A. M. A., Predictive machinability models for a selected hard material in turning operations‖, Journal of Materials Processing Technology, Vol. 190, pp. 305– 311(2007). [93] Sahoo, P., Barman, T. K. and Routara, B. C., Taguchi based practical dimension modeling and optimization in CNC turning‖, Advance in Production Engineering and Management, Vol. 3( 4), pp. 205-217 (2008). [94] Lan Yan & Jie Sun & Song Zhang, Optimizing end-milling parameters for surface roughness under different cooling/lubrication conditions, Int Journal of Advanced Manufacturing Technology 51(2010),841–851. [95] Thamma, R., (2008), Comparison between Multiple Regression Models to Study Effect of Turning Parameters on the Surface Roughness‖, Proceedings of the IJME International Conference, ISBN 978-1-60643-379-9, Paper 133, ENG 103, pp. 1- 12(2008). [96] Biswas, C. K., Chawla, B. S., Das N. S., Srinivas, E. R. K. N. K.,―Tool Wear Prediction using Neuro-Fuzzy System‖, Institution of Engineers (India) Journal (PR), Vol. 89, pp. 42-46 (2008). [97] Doniavi, A., Eskanderzade, M. and Tahmsebian, M.,Empirical Modeling of Surface Roughness in Turning Process of 1060 steel using Factorial Design Methodology‖,Journal of Applied Sciences, Vol. 7 (17), pp. 2509-2513 (2007). [98] M. Pirtini, I. Lazoglu, Forces and hole quality in drilling, International Journal of Machine Tools & Manufacture 45 (2005) 1271–1281 [99]. Arul, S., Samuel, R., Vijayaraghavan, L., Malhotra, S.K., Krishnamurthy, R. (2006). Modeling and Optimization of Process Parameters for Defect Toleranced Drilling of GFRP Composites. Materials and Manufacturing Processes, vol. 21, no. 4, p. 357- 365, DOI:10.1080/10426910500411587. [100] Kim, K-J., Lin, D. K. J., Simultaneous optimization of mechanical properties of steel by maximizing exponential desirability functions,‖ Appl. Statist., Vol. 49, Issue 3, pp. 311 325 (2000). [101] Vejandla, D. T., Optimizing the automated plasma cutting process by design of experiment, Masters Thesis, Texas State University-Sam Marcos, Thesis and Dissertations Ingram School of Engineering, Paper 1 (2009).)	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/754
dc.description	Supervised by Dr. Md. Anayet Ullah Patwari Professor Department of Mechanical & Chemical Engineering (MCE) Islamic University of Technology (IUT), OIC Board Bazar, Gazipur Dhaka, Bangladesh	en_US
dc.description.abstract	This study presents the results of an investigation of the use of Box Behnken design approach to plan the experiments for drilling GFRP composite under different magnetic conditions with an overall objective of optimizing the process to yield better surface quality. Response Surface methodology (RSM) has been adopted to express the output parameters (responses) that are decided by the input process parameters. RSM also quantifies the relationship between the variable input parameters and the corresponding output parameters. RSM designs allow us to estimate interaction and even the quadratic effects, and hence, give us an idea of the shape of the response surface we are investigating. Box-Behnken design is having the maximum efficiency for an experiment involving three factors and three levels; further, the number of experiments conducted for this is much lesser compared to a central composite design. The proposed Box-Behnken design requires 17 runs of experiment for data acquisition and modeling the response surface. Design expert software 6.8.0 was used to design the experiment and randomize the runs. A nonlinear model was developed and its adequacy was verified to predict the output values at nearly all conditions. Further the model was validated by performing experiments, taking three sets of random input values. The output parameters measured through experiments (actual) are in good match with the predicted values using the model. Using ‘Design-expert’ software, 3D plots were generated for the RSM evolved. Such plots explicitly give an idea of the dominating process variable over others and the order of dominance; further the plots exhibit the trend of variables’ interaction in the process. This work resulted in identifying the optimised set of drilling parameters for GFRP composite material using HSS twist drill to achieve better surface quality. This work gains significance in the sense with minimum number of experiments, reliable model has been generated, validated and further, the process has been optimised. The observations of effect of magnetic field lead to the conclusion that magnetic drilling improves the factors significantly.	en_US
dc.language.iso	en	en_US
dc.publisher	Department of Mechanical and Production Engineering, Islamic University of Technology, Gazipur, Bangladesh	en_US
dc.subject	optimization, GFRP composite, Box-Behnken Design, RSM, 3D plots, HSS twist drill bit, magnetic field	en_US
dc.title	Prediction and Optimization of Quality of Drilled Holes During Magnetic Drilling Operation of Glass Fiber Reinforced Polymer Composite	en_US
dc.type	Thesis	en_US