Investigation of surface parameters using green coolant in drilling process

Akram, Rana Muhammad Hassnain

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dc.contributor.author	Akram, Rana Muhammad Hassnain
dc.date.accessioned	2021-09-08T05:57:31Z
dc.date.available	2021-09-08T05:57:31Z
dc.date.issued	2013-11-15
dc.identifier.citation	[1] Fulton, C.D., Ranque's Tube, Journal of the American Society of Refrigeration Engineering, Vol. 5, 1950, pp. 473-479. [2] Stong, C. L., The "Hilsch" Vortex Tube, The Amateur Scientist, Heinemann Educational Books, Chapter IX, Section 4, 1962, pp. 514-519. [3] AiRTEX International Ltd., How Vortex Tubes Work, www.airtexinternational.com. [4] Ranque, G. L., Method and Apparatus for Obtaining from a Fluid under Pressure Two Currents of Fluids at Different Temperatures, U.S. Patent No.1952281, 1934. [5] Exair, Vortex Tubes and Spot Cooling Products, www.exair.com. [6] Hilsch, R., The Use of the Expansion of Gases in a Centrifugal Field as a Cooling Process, Review of Scientific Instruments, Vol. 18, No. 2, 1947, pp. 108-113. [7] Gao, C. M., Experimental Study on the Ranque ± Hilsch Vortex Tube, Technische Universiteit Eindhoven, 2005. [8] Arif, M. D., Patwari, A. U., Chowdhury, N. A., ―Surface roughness characterization using digital image processing technique,‖ Proceedings of the 13th Annual Paper Meet (APM), Mechanical Engineering Division, The Institution of Engineers, Bangladesh, Vol. 13, pp. 29-35 (2010). [9] N. I. Galanis1, D. E. Manolakos1, N. M. Vaxevanidis2 COMPARISON BETWEEN DRY AND WET MACHINING OF STAINLESS STEEL School of Mechanical Engineering, National Technical University of Athens, Greece, Department of Mechanical Engineering Educators, School of Pedagogical and Technological Education, Greece. [10] J.A.Ghani, K. Othman, M.N.A. Rahman, B.M. Deros and C.H.C.Haron “MACHINED SURFACE OF FCD 700 DUCTILE CAST IRON IN A DRY TURNING ENVIRONMENT USING CARBIDE TOOLS” International Journal of Mechanical and Materials Engineering (IJMME), Vol.6 (2011), No.3, 362-366 [11] N. R. Dhar, M. H. Rashid and A.T. Siddiqui “EFFECT OF HIGH PRESSURE COOLANT ON CHIP, ROUNDNESS DEVIATION AND TOOL WEAR IN DRILLING AISI-4340 STEEL” ARPN Journal of Engineering and Applied Sciences, VOL.1, NO.3, OCTOBER 2006. 77 Department of Mechanical and Chemical Engineering, IUT. [12] vieira, J.M., Machado, A.R., Ezugwu, E.O., „Performance of cutting fluid during Face Milling of Steels,” Journal of Materials Processing Technology, Vol.116, 2001, pp 244-251. [13] Paul, S., Dhar, N.R., Chattopadhyay, A.B, “Beneficial effects of cryogenic Cooling over Dry and Wet Machining on Tool Wear and Surface Finish in Turning AISI 1060 Steel,” Journal of Materials Processing Technology, 2007. [14] Diniz, A.E., Micaroni, R., “Cutting Conditions for Finish Turning Process Aiming the use of Dry Cutting,” International Journal of Machine Tools and Manufacture, Vol.42, 2002, pp 899-904. [15] Rowe, G.W., SMART, E.F., “The Importance of Oxygen in Dry Machining of Metal on a Lathe,” British Journal of Applied Physics, Vol.14, 1963. [16] Kovacevic, R., Cherukuthota, C., Mazurkiewicz, M., High Pressure Water jet cooling/Lubrication to improve Machining Efficiency in Milling,” Journal of Machine Tools Manufacturing, Vol.35, No. 10, 1995, pp 1459 – 1473. [17] Klocke, F., Eisenblatter, G., “Keynote Papers,” RWTH Aachen, Germany. [18] Sreejith, P.S., Ngoi, B.K.A., “Dry machining: machining of the Future,” Journal of Materials Processing Technology, Vol. 101, 2000, pp 287-291 [19] Aronson, R. B. (1995), Why Dry Machining, Manufacturing Engineering, pg 33-36. [20] Braga, D.U., A.E. Diniz, G.W.A. Miranda, & N.L. Coppini, (2002), Using a Minimum Quantity of Lubricant (MQL) and a Diamond Coated Tool in the Drilling of Aluminum-Silicon Alloys, Journal of Materials Processing and Technology, Vol. 122, pg. 127-138. [21] Hidetaka, K. & T. Hideyo, (1996), Drilling of a Small and Deep Hole Using a Twist Drill, The Japan Society of Mechanical Engineers, Vol. 62, pg. 3691-3697. [22] Obikawa, T., Y. Kamata, & J. Shinozuka, (2006), High-Speed Grooving with Applying MQL, International Journal of Machine Tool and Manufacture, Vol.46, pg. 1854- 1861. [23] Davim, J.P., P. S. Sreejith, R. Gomes and C. Peixoto. "Experimental Studies on Drilling of Aluminum (AA1050) Under Dry, Minimum Quantity of Lubricant, and Flood-Lubricated Conditions." Experimental Studies on Drilling of Aluminium (AA1050) under Dry, Minimum Quantity of Lubricant, and Flood-Lubricated Conditions (2006): 1605-11. 78 Department of Mechanical and Chemical Engineering, IUT. [24] Zeilmann, R. P. and W. L. Weingaertner. "Analysis of Temperature During Drilling of Ti6Al4V with Minimum Quantity of Lubricant." Journal of Material Processing Technology 179 (2006): 124-27. [25] Rahim, E. A. and H. Sasahara. "Surface Integrity when Drilling Nickel-Based Superalloy under MQL Supply." Key Engineering Materials 443 (2010): 365-70. [26] Obikawaa, Toshiyuki, et al. “High-speed grooving with applying MQL.” International Journal of Machine Tools & Manufacturer 46, (January 2006): 1854-1861. [27] Dhar, N. R., et al. “The influence of minimum quantity lubrication (MQL) on cutting temperature, chip and dimensional accuracy in turning AISI-1040 steel.” Journal of Materials Processing Technology 171 (2006): 93-99. [28] Dhar, N. R., et al. “An experimental investigation on effect of minimum quantity lubrication in machining AISI 1040 steel.” International Journal of Machine tools & Manufacture 47, (2007): 748-753. [29] Ueda, Takashi, et al. “Effect of oil mist on tool temperature in cutting.” Journal of manufacturing science and engineering 128, (February 2006): 130-135. [30] Heinemann, R., et al. “Effect of MQL on the tool life of small twist drills in deep hole drilling.” International Journal of Machine Tool & Manufacture 46, (2006): 1-6. [31] Ribeiro, L. M. F., Horovistiz, A. L., Jesuino, G. A., de O. Hein, L. R., Abbade, N. P., Crnkovic, S. J., ―Fractal analysis of eroded surfaces by digital image processing,‖ Materials Letters, Vol. 56, Issue 4, pp. 512-517 (2002). [32] Kumar, R., Kulashekar, P., Dhanasekar, B., Ramamoorthy, B., ―Application of digital image magnification for surface roughness valuation using machine vision,‖ International Journal of Machine Tools and Manufacture, Vol. 45, Issue 2, pp. 228-234 (2005). [33] Patwari, A. U., Amin, A. K. M. N., Faris, W., ―Identification of instabilities of chip formation by image processing techniques,‖ Proceedings of ICME (2009), Dhaka, Bangladesh. [34] Souren Mitra, Soumya Sarkar, D.Bhaduri, Goutam Paul, Sampad Biswas, ―Electro discharge machining of Titanium nitride-aluminium oxide composite material for optimum process criteria yield‖	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/876
dc.description	Supervised By Prof. Dr. Md. Anayet Ullah Patwari, Department of Mechanical and Chemical Engineering(MCE), Islamic University of Technology(IUT), The Organization of Islamic Cooperation (OIC),	en_US
dc.description.abstract	Computer Numerical Control (CNC) is specialized and versatile form of soft Automation in which the functions and motions of a machine tool are controlled by means of a prepared program containing coded alphanumeric data. CNC can control the motions of the work-piece or tool, the input parameters such as feed, depth of cut, speed, and the functions such as turning spindle on/off, turning coolant on/off. CNC drilling machines are versatile and flexibly automatic drilling machines having box-column type rigid structure the work table movements and spindle are programmed and accomplished by CNC. Its programming and operation is simple and that is why it is increasingly popular. In addition, the CNC drilling machine can have built-in software that will calculate precise position of holes; these positions are important in making matrix, PCD patterns, line and skip drilling. This drilling machine can work at incredible speeds. Vortex tube is a non-conventional cooling device which will produce cold air and hot air from the source of compressed air without affecting the environment. When a high pressure compressed air is tangentially injected through the inlet nozzle. Swirl generators at the inlet plane create the vortex motion inside the tube. As the vortex moves along the tube, a temperature separation is formed. Hot air moves along the tube periphery, and cold air is in motion in the inner core. The hot air is then allowed to exit through the cone valve at the far end of the tube, while the cold air outlet is next to the inlet plane. This resulting radial temperature separation inside the vortex tube is also called the Ranque-Hilsch effect, named after its pioneers. 11 Department of Mechanical and Chemical Engineering, IUT. The author of this research endeavor, with the guidance of his supervisor and help from colleagues, has developed a unique mechanism to use vortex generated hot and cold air as coolant in drilling process instead of liquid coolant which is usually being used in daily work in drilling process. As coolant produced from vortex tube is totally environmentally friendly used in such a way that it doesn‟t disturb our environment and expresses less harm to human beings, animals and plants health. Holes of different diameters were drilled using green coolant instead of liquid coolant. Obtained results were then compared with the same process done with liquid coolant in terms of surface roughness, surface hardness.	en_US
dc.language.iso	en	en_US
dc.publisher	Department of Mechanical and Production Engineering (MPE),Islamic University of Technology(IUT), Board Bazar, Gazipur, Bangladesh	en_US
dc.title	Investigation of surface parameters using green coolant in drilling process	en_US
dc.type	Thesis	en_US