Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids
Surface integrity is the surface condition of a workpiece after being modified by a manufacturing process and it can change the material’s properties. In surface topography, surface roughness (Ra) was concerned with the geometry of the outmost layer of the workpiece texture and interface exposed wit...
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T Technology (General) TJ Mechanical engineering and machinery Abdullah, Abd Halimnizam Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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Surface integrity is the surface condition of a workpiece after being modified by a manufacturing process and it can change the material’s properties. In surface topography, surface roughness (Ra) was concerned with the geometry of the outmost layer of the workpiece texture and interface exposed with the environment affects several functional attributes of parts, such as friction, wear and tear, heat transmission, ability of distributing and holding a lubricant, etc. Therefore, the desired surface finish was usually specified and appropriate processes were required to assess and maintain the quality of a component. The research was to investigate the influence of machining parameters and optimum process parameter to the surface roughness value of mild steel material in conventional turning using CVD (chemical vapor deposition) coated carbide insert in three condition (dry, wet and oil). Optimization of the cutting parameters is very important in determine the optimum cutting condition thus reduce machining cost and time consumed. From the results obtained, better surface roughness value was determined by combination of cutting speed 150 m/min, and feed rate 0.1 mm/rev with under coolant oil condition.
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Abdullah, Abd Halimnizam |
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Abdullah, Abd Halimnizam |
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Abdullah, Abd Halimnizam |
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Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids |
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surface roughness study on mild steel in conventional turning process under three condition cutting fluids |
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2019 |
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my-utem-ep.251572021-09-29T11:40:50Z Surface Roughness Study On Mild Steel In Conventional Turning Process Under Three Condition Cutting Fluids 2019 Abdullah, Abd Halimnizam T Technology (General) TJ Mechanical engineering and machinery Surface integrity is the surface condition of a workpiece after being modified by a manufacturing process and it can change the material’s properties. In surface topography, surface roughness (Ra) was concerned with the geometry of the outmost layer of the workpiece texture and interface exposed with the environment affects several functional attributes of parts, such as friction, wear and tear, heat transmission, ability of distributing and holding a lubricant, etc. Therefore, the desired surface finish was usually specified and appropriate processes were required to assess and maintain the quality of a component. The research was to investigate the influence of machining parameters and optimum process parameter to the surface roughness value of mild steel material in conventional turning using CVD (chemical vapor deposition) coated carbide insert in three condition (dry, wet and oil). Optimization of the cutting parameters is very important in determine the optimum cutting condition thus reduce machining cost and time consumed. From the results obtained, better surface roughness value was determined by combination of cutting speed 150 m/min, and feed rate 0.1 mm/rev with under coolant oil condition. Tags from this library: No tags from this library for this title. 2019 Thesis http://eprints.utem.edu.my/id/eprint/25157/ http://eprints.utem.edu.my/id/eprint/25157/1/Surface%20Roughness%20Study%20On%20Mild%20Steel%20In%20Conventional%20Turning%20Process%20Under%20Three%20Condition%20Cutting%20Fluids.pdf text en public http://eprints.utem.edu.my/id/eprint/25157/2/Surface%20Roughness%20Study%20On%20Mild%20Steel%20In%20Conventional%20Turning%20Process%20Under%20Three%20Condition%20Cutting%20Fluids.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=117860 mphil masters Universiti Teknikal Malaysia Melaka Faculty of Manufacturing Engineering Sulaiman, Mohd Amri 1. Anmark, N., Bjork, T., Ganea, A., Olund, P., Hogmark, S., Karasev, A., & Jonsson, P. G. (2015). The effect of inclusion composition on tool wear in hard part turning using PCBN cutting tools. 2. Balogh, Z., & Schmitz, G. (2014). Diffusion in metals and alloys. 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Toffler, L., Jacobson, S., & Norgren, S. (2017). Life time of cemented carbide inserts with Ni-Fe binder in steel turning. In Wear, Part B, Volume 376 - 377 (pp. 1822 - 1829). 35. Trent, E. M., & Wright, P. K. (2000). Metal Cutting. 4th ed. Woburn: Butterworth Heinamann. 36. Wasik, M., & Kolka, A. (2017). Machining Accuracy Improvement by Compensation of Machine Workpiece Deformation, Volume 11. 37. Yin, Y., Chen, Y.-X., & Lin, L. (2017). Lifetime prediction for the subsurface crack propagation using three-dimensional dynamic FEA model, mechanical systems and signal. Processing, Vol. 87, 54 - 70. |