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DOI: THE INFLUENCE OF COOLANT TYPES ON SURFACE ROUGHNESS IN THE TURNING PROCESS
Khalid Abdulkhaliq M. Alharbi , Mechanical Engineering Department, College Of Engineering, Umm Al-Qura University, Makkah, Kingdom Of Saudi Arabia Tarki Jufayn Z. Alotaibi , Mechanical Engineering Department, College Of Engineering, Umm Al-Qura University, Makkah, Kingdom Of Saudi ArabiaAbstract
To lessen the friction that forms between the tool and the workpiece during the turning process, a variety of coolants are utilized. Each coolant type has benefits and drawbacks. The kind of coolant used directly affects how smooth or rough the surface of workpiece is. Two popular types of coolants were employed in this investigation. Emulsion is a mixture of 90% water and 10% oil. The first operation employed this kind of coolant. For the second procedure, synthetic oil is employed as coolant. The third procedure, known as a dry operation, uses no coolant to compare various types. The identical tools and conditions were utilized in all three types of operations to create 30 pieces of work for each. To obtain the results, each sample was evaluated using a surface roughness tester. The findings of this investigation indicated that when it comes to surface roughness, emulsion operations are the best coolant to employ.
Keywords
Surface quality, machining coolants, turning process
References
Junior, J. K. K., Schueller, J. K., Pinto, F. D. A. C., & Villibor, G. P. (2020). Monitoring of Flank Wear and Damage on Turning Cutting Tools By Image Processing. The Journal of Engineering and Exact Sciences, 6(2), 0098-0106.
Liew, P. J., Shaaroni, A., Sidik, N. A. C., & Yan, J. (2017). An overview of the current status of cutting fluids and cooling techniques of turning hard steel. International Journal of Heat and Mass Transfer, 114, 380-394.
Maurya, R. K., Niranjan, M. S., Maurya, N. K., & Dwivedi, S. P. (2021). Development of a system to control flow of coolant in turning operation. Journal of Mechanical Engineering (IMechE), 17(1), 17-31.
Devaraj, S., Malkapuram, R., & Singaravel, B. (2021). Performance analysis of micro-textured cutting insert design parameters on machining of Al-MMC in turning process. International Journal of Lightweight Materials and Manufacture, 4(2), 210217.
Özbek, O., & Saruhan, H. (2020). The effect of vibration and cutting zone temperature on surface roughness and tool wear in eco-friendly MQL turning of AISI D2. Journal of Materials Research and Technology, 9(3), 2762-2772.
Li, Z., Zhao, C., Lu, Z., & Liu, F. (2019). Thermal Performances Prediction Analysis of High Speed Feed Shaft Bearings Under Actual Working Condition. IEEE Access, 7, 168011-168019.
Fatima, A., & Mativenga, P. T. (2017). On the comparative cutting performance of nature-inspired structured cutting tool in dry cutting of AISI/SAE 4140. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 231(11), 1941-1948.
Ejieji, T., Adedayo, S. M., Bello, O. W., & Abdulkareem, S. (2018, September). Effect of machining variables and coolant application on HSS tool temperature during turning on a CNC lathe. In IOP Conference Series: Materials Science and Engineering (Vol. 413, No. 1, p. 012004). IOP Publishing.
Naje, J. M., Jasim, H. B., & Alfatlawy, F. A. (2021). Study the effect of metal cutting fluids in operating machines on operator health and the environment. Periodicals of Engineering and Natural Sciences (PEN), 9(2), 649-656.
Islam, S., & Motaleb, I. A. (2019, October). Investigation of the Dynamics of Liquid Cooling of 3D ICs. In 2019 8th International Symposium on Next-Generation Electronics (ISNE) (pp. 1-3). IEEE.
Kaynak, Y., Gharibi, A., Yılmaz, U., Köklü, U., & Aslantaş, K. (2018). A comparison of flood cooling, minimum quantity lubrication and high-pressure coolant on machining and surface integrity of titanium Ti-5553 alloy. Journal of Manufacturing Processes, 34, 503-512.
Dong, Jianwei & Pei, Weichi & Ji, Hongchao & Long, Haiyang & Fu, Xiaobin & Duan, Hailong. (2020). Fatigue crack propagation experiment and numerical simulation of 42CrMo steel. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science. 234. 095440622091045. 10.1177/0954406220910458.
Chen, Yuanyuan & Qi, Huiping & Li, Yongtang & Hua, Lin. (2021). Establishment of Thermal Ductile Fracture Criterion for As-Cast 42CrMo Steel and Its Application in Hot Ring Rolling Process. Advances in Materials Science and Engineering. 2021. 10.1155/2021/9120018.
Alsoufi, Mohammad & Suker, Dhia & Alsabban, Abdulaziz & Azam, Sufyan. (2016). Experimental Study of Surface Roughness and Micro-Hardness Obtained by Cutting Carbon Steel with Abrasive WaterJet and Laser Beam Technologies. American Journal of Mechanical Engineering. 4. 173-181. 10.12691/ajme-4-5-2.
Suker, Dhia & Alsoufi, Mohammad & Alhusaini, Majdi & Azam, Sufyan. (2016). Studying the Effect of Cutting Conditions in Turning Process on Surface Roughness for Different Materials. World Journal of Research and Review (WJRR). 2. 16-21.
Alsoufi, Mohammad & Suker, Dhia. (2018). Experimental Investigation of Wire-EDM Process Parameters for Surface Roughness in the Machining of Carbon Steel 1017 and Aluminum Alloy 6060. American Journal of Mechanical Engineering. 6. 132-147. 10.12691/ajme-6-3-6
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Copyright (c) 2022 Khalid Abdulkhaliq M. Alharbi, Tarki Jufayn Z. Alotaibi
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