Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition
Surface integrity and tool wear is important to determine the quality of machine surface in order to achieve optimum cutting parameter. This project was conducted to study the optimum of cutting parameters on tool wear and surface roughness using AISI 1045 steel under dry turning process. The cuttin...
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2017
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Salleh, Mohd Shukor |
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T Technology (General) TJ Mechanical engineering and machinery Ab Ghani, Mohd Khairul Nizam Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
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Surface integrity and tool wear is important to determine the quality of machine surface in order to achieve optimum cutting parameter. This project was conducted to study the optimum of cutting parameters on tool wear and surface roughness using AISI 1045 steel under dry turning process. The cutting tool that has been selected was coated carbides insert and the size of the AISI 1045 steel is 300 mm X ϕ55 mm. HAAS SL-20 CNC lathe machine was utilized in this project to remove the surface of material. The main controllable turning parameters that have been investigated in this project were cutting speed, feed rate and depth of cut. The machining parameters used in this experiment are cutting speed (150 m/min, 200 m/min and 250 m/min), feed rate (0.05 mm/rev, 0.1 mm/rev and 0.15 mm/rev) and depth of cut (1.0 mm). In this experiment, multilevel factorial design used to get the optimum parameters. Mitutoyo surface roughness tester was used to determine the average of surface roughness. The surface integrity of the workpiece and the tool wear rate of the cutting tool is analyse using the stereo microscope. Analysis was performed using experimental result, graph, and ANOVA. This project has explained the effect of dry machining condition on surface roughness and tool wear of the workpiece. Based on the analysis, the optimum cutting parameter to get the minimum surface roughness was cutting speed (200 m/min), feed rate (0.1 mm/rev) and depth of cut (1.0mm). It shows that the feed rate is the most influence parameter that contributed to the highest effect of surface roughness and followed by the cutting speed and depth of cut. |
| format |
Thesis |
| qualification_name |
Master of Philosophy (M.Phil.) |
| qualification_level |
Master's degree |
| author |
Ab Ghani, Mohd Khairul Nizam |
| author_facet |
Ab Ghani, Mohd Khairul Nizam |
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Ab Ghani, Mohd Khairul Nizam |
| title |
Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
| title_short |
Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
| title_full |
Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
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Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
| title_full_unstemmed |
Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition |
| title_sort |
evaluation on machining performance of aisi 1045 steel under dry condition |
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Universiti Teknikal Malaysia Melaka |
| granting_department |
Faculty Of Manufacturing Engineering |
| publishDate |
2017 |
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http://eprints.utem.edu.my/id/eprint/23972/1/Evaluation%20On%20Machining%20Performance%20Of%20AISI%201045%20Steel%20Under%20Dry%20Condition.pdf http://eprints.utem.edu.my/id/eprint/23972/2/Evaluation%20On%20Machining%20Performance%20Of%20AISI%201045%20Steel%20Under%20Dry%20Condition.pdf |
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my-utem-ep.239722022-02-18T15:00:04Z Evaluation On Machining Performance Of AISI 1045 Steel Under Dry Condition 2017 Ab Ghani, Mohd Khairul Nizam T Technology (General) TJ Mechanical engineering and machinery Surface integrity and tool wear is important to determine the quality of machine surface in order to achieve optimum cutting parameter. This project was conducted to study the optimum of cutting parameters on tool wear and surface roughness using AISI 1045 steel under dry turning process. The cutting tool that has been selected was coated carbides insert and the size of the AISI 1045 steel is 300 mm X ϕ55 mm. HAAS SL-20 CNC lathe machine was utilized in this project to remove the surface of material. The main controllable turning parameters that have been investigated in this project were cutting speed, feed rate and depth of cut. The machining parameters used in this experiment are cutting speed (150 m/min, 200 m/min and 250 m/min), feed rate (0.05 mm/rev, 0.1 mm/rev and 0.15 mm/rev) and depth of cut (1.0 mm). In this experiment, multilevel factorial design used to get the optimum parameters. Mitutoyo surface roughness tester was used to determine the average of surface roughness. The surface integrity of the workpiece and the tool wear rate of the cutting tool is analyse using the stereo microscope. Analysis was performed using experimental result, graph, and ANOVA. This project has explained the effect of dry machining condition on surface roughness and tool wear of the workpiece. Based on the analysis, the optimum cutting parameter to get the minimum surface roughness was cutting speed (200 m/min), feed rate (0.1 mm/rev) and depth of cut (1.0mm). It shows that the feed rate is the most influence parameter that contributed to the highest effect of surface roughness and followed by the cutting speed and depth of cut. 2017 Thesis http://eprints.utem.edu.my/id/eprint/23972/ http://eprints.utem.edu.my/id/eprint/23972/1/Evaluation%20On%20Machining%20Performance%20Of%20AISI%201045%20Steel%20Under%20Dry%20Condition.pdf text en public http://eprints.utem.edu.my/id/eprint/23972/2/Evaluation%20On%20Machining%20Performance%20Of%20AISI%201045%20Steel%20Under%20Dry%20Condition.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=114782 mphil masters Universiti Teknikal Malaysia Melaka Faculty Of Manufacturing Engineering Salleh, Mohd Shukor 1. Amini, S., Khakbaz, H., and Barani, A., 2015. Improvement of Near-Dry Machining and Its Effect on Tool Wear in Turning of AISI 4142. Materials and Manufacturing Processes, 30 (2), pp. 241-247. 2. Atul, K., Sudhir, K. and Rohit, G., 2011. Statistical Modelling of Surface Roughness in Turning Process. Engineering Science and Technology, 3 (5), pp. 4246-4252. 3. Boubekri, N., and Shaikh, V., 2012. Machining Using Minimum Quantity Lubrication: A Technology for Sustainability. International Journal of Applied Science and Technology, 2 (1), pp. 111-115. 4. Debnath, S., Reddy, M. M., and Yi, Q. S., 2016. Influence of Cutting Fluid Conditions And Cutting Parameters on Surface Roughness and Tool Wear in Turning Process Using Taguchi Method. Measurement, 78, pp. 111-119. 5. DIJET Catalogue., 2016. ISO Tooling Insert. DIJET industries, LTD. 6. Elmunafi, M. H. S., Kurniawan, D., and Noordin, M. Y., 2015. Use of Castor Oil as Cutting Fluid in Machining of Hardened Stainless Steel with Minimum Quantity of Lubricant. Procedia CIRP, 26, pp. 408-411. 7. Gaitonde, V. N., Karnik, S. R., Maciel, C. H. A., Rubio, J. C. C., and Abrão, A. M., 2016. Machinability Evaluation in Hard Milling of AISI D2 Steel. 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Optimization of Cutting Parameters on Tool Wear, Workpiece Surface Temperature and Material Removal Rate in Turning of AISI D2 Steel, Advanced Mechanical Engineering, 4, pp. 291-298. 18. Mikell P. Groover, 2012. Fundamentals of Modern Manufacturing, Fifth Edition. Prentice Hall International. 19. Najiha, M. S., Rahman, M. M., Kamal, M., Yusoff, A. R., and Kadirgama, K., 2012. Minimum Quantity Lubricant Flow Analysis In End Milling Processes: A Computational Fluid Dynamics Approach. Journal of Mechanical Engineering and Sciences, 3, pp. 340-345. 20. Neha, K., Keshva, N., Karanvir, S., & Ramagopal, V. S., 2014. Experimental Investigation on Uncontrollable Parameters for Surface Finish During Diamond Turning. Journal Material and Manufacturing Processes, 30(2), pp. 232-240. 21. Noordin, M. Y., Venkatesh, V.C., Sharif, S., and Elting, S., 2014. Application of Response Surface Methodology in Describing the Performance of Coated Carbide Tools when Turning AISI 1045 Steel. Journal of Materials Processing Technology, 145 (1), pp. 46–58. 22. Okokpujie, I. P., Okonkwo, U. C., 2013. Cutting Parameters Effects on Surface Roughness During End Milling of Aluminium 6061 Alloy Under Dry Machining Operation. International Journal of Science and Research, 4(5), pp. 2937-2942. 23. Pantazopoulos, G., Toulfatzis, A., Vazdirvanidis, A., and Rikos, A., 2015. Accelerated Carbide Tool Wear Failure During Machining Of Hot Work Hardened Tool Steel. International Journal of Structural Integrity, 6 (2), pp. 290-299. 24. Ranjit, K. R., 2001. Design of Experiments Using the Taguchi Approach. John Wiley & sons, Inc, 1-500. 25. Rao, S. R., & Padmanabhan, G., 2012. Application of Taguchi Methods and ANOVA in Optimization of Process Parameters for Metal Removal Rate in Electrochemical Machining of Al/5% SiC Composites. International Journal of Engineering Research and Application, 2(3), pp.192–197. 26. Sahoo, A. K., 2014. Application of Taguchi And Regression Analysis on Surface Roughness in Machining Hardened AISI D2 Steel, International Journal of Industrial Engineering Computations, 5, pp. 295–304. 27. Shahrom, M. S., Yahya, N. M., and Yusoff, A. R., 2013. Taguchi Method Approach on Effect of Lubrication Condition on Surface Roughness in Milling Operation, Procedia Engineering, 53, pp. 594-599 28. Sreejith, P. S., 2008. Machining of 6061 Aluminum Alloy with MQL, Dry and Flooded Lubrificant Conditions. Mater Lett 62(2), pp. 276–278. 29. Srithar, A., Palanikumar, K., and Durgaprasad, B., 2014. Experimental Investigation and Surface roughness Analysis on Hard turning of AISI D2 Steel using Coated Carbide Insert, Procedia Engineering, 97, pp. 72-77. 30. Suresh, R., Basavarajappa, S., Gaitonde, V. N., and Samuel, G. L., 2012. Machinability Investigations on Hardened AISI 4340 Steel Using Coated Carbide Insert. International Journal of Refractory Metals and Hard Materials, 33, pp. 75-86. 31. Thamizhmanii, S., Mohideen, R., Zaidi, A. M. A., and Hasan, S., 2015. Surface Roughness and Tool Wear on Cryogenic Treated CBN Insert on Titanium and Inconel 718 Alloy Steel, 3rd International Conference of Mechanical Engineering Research, 100, pp. 12058. 32. Vishwakarma, A., Jain, S., and Sharma, P. K., 2014. Analysis of effect of Minimum Quantity Lubrication on Different Machining Parameters Cutting Force, Surface Roughness and Tool Wear by Hard Turning of AISI-4340 Alloy Steel a Review. International Journal of Advanced Engineering Research and Technology (IJAERT),2 (9), ISSN No: 2348-8190 33. Waydande, P., Ambhore, N., and Chinchanikar, S., 2016. A Review on Tool Wear Monitoring System, Journal of Mechanical Engineering and Automation, 6(5A), pp. 49-53. 34. Wernsing, H., and Büskens, C., 2015. Parameter Identification For Finite Element Based Models In Dry Machining Applications. Procedia CIRP, 31, pp. 328-333. 35. Villeta, M., Rubio, E. M., De Pipaón, J. M. S., & Sebastián, M. A., 2011. Surface Finish Optimization of Magnesium Pieces Obtained by Dry Turning Based on Taguchi Techniques and Statistical Tests. Materials and Manufacturing Processes, 26(12), pp.1503–1510. 36. Yang, W. H., & Tarng, Y. S., 1998. Design Optimization of Cutting Parameters for Turning Operations Based on the Taguchi Method. Journal of Materials Processing Technology, 84, pp. 122–129. 37. Yazid, M. Z. A., Ibrahim, G. A,. Said, A. Y. M., CheHaron, C.H., and Ghani, J. A., 2011. Surface Integrity Of Inconel 718 When Finish Turning With PVD Coated Carbide Tool Under MQL. Procedia Engineering , 19, pp. 396-401. |