Volume 7, Issue 4, December 2019, Page: 71-87
A Review on Different Cooling/Lubrication Techniques in Metal Cutting
Mst. Nazma Sultana, Industrial and Production Engineering, Mechanical Engineering, Bangladesh University of Engineering & Technology (BUET), Dhaka, Bangladesh
Nikhil Ranjan Dhar, Industrial and Production Engineering, Mechanical Engineering, Bangladesh University of Engineering & Technology (BUET), Dhaka, Bangladesh
Prianka Binte Zaman, Industrial and Production Engineering, Mechanical Engineering, Bangladesh University of Engineering & Technology (BUET), Dhaka, Bangladesh
Received: Dec. 7, 2019;       Accepted: Dec. 23, 2019;       Published: Dec. 31, 2019
DOI: 10.11648/j.ajma.20190704.11      View  313      Downloads  220
Abstract
Various types cooling/lubrication techniques are used in machining processes for enhancing machining performances. Conventional way of cooling/lubrication requires higher coolant cost, waste and disposal cost. Not only has that it had many negative impacts on environment and operators health. For attaining highest efficiency of cutting fluids with minimum quantity, different sustainable strategies are tried to develop. In recent decades researchers are worked out on different cooling/lubrication strategies alternative to conventional cooling. This paper represents a comprehensive review of all presently practiced cooling/lubrication strategies and their effects on different aspects such as surface quality of machined component, tool wear, tool life, cutting temperature, cutting forces etc. through analyzing selected papers. The influence of different cutting fluids such as solid lubricants, nanofluids, ionic liquids etc. with their positive and negative impacts is also discussed. The research gaps are also identified for further research works. From review it is clear that the machining performance is highly affected by cooling techniques and coolant types. Selection of proper cooling technique with suitable cutting fluids depends on work material, tool material and cutting variables.
Keywords
Flood Cooling Conventional Cooling, Mist Cooling, High Pressure Cooling (HPC), Minimum Quantity Lubrication (MQL), Nanofluids, Ionic Liquids, Cryogenic Cooling, Hybrid Cooling
To cite this article
Mst. Nazma Sultana, Nikhil Ranjan Dhar, Prianka Binte Zaman, A Review on Different Cooling/Lubrication Techniques in Metal Cutting, American Journal of Mechanics and Applications. Vol. 7, No. 4, 2019, pp. 71-87. doi: 10.11648/j.ajma.20190704.11
Copyright
Copyright © 2019 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Reference
[1]
R. K. Jain, Production Technology, sixteenth ed., KHANNA publishers, Delhi, 1229.
[2]
Tschätsch, H. and Reichelt, A., “Cutting fluids (coolants and lubricants)”, In Applied Machining Technology, pp. 349-352, Springer, Berlin, Heidelberg, 2009.
[3]
Kuram, E., Ozcelik, B., Demirbas, E., Şik, E. and Tansel, I. N., “Evaluation of new vegetable-based cutting fluids on thrust force and surface roughness in drilling of AISI 304 using Taguchi method”, Materials and Manufacturing Processes, vol. 26, pp. 1136-1146, 2011.
[4]
Sharif, M. N., Pervaiz, S. and Deiab, I., “Potential of alternative lubrication strategies for metal cutting processes: a review”, The International Journal of Advanced Manufacturing Technology, vol. 89, pp. 2447-2479, 2017.
[5]
Chinchanikar, S. and Choudhury, S. K., “Machining of hardened steel—experimental investigations, performance modeling and cooling techniques: a review”, International Journal of Machine Tools and Manufacture, vol. 89, pp. 95-109, 2015.
[6]
Chetan, Ghosh, S. and Rao, P. V., “Application of sustainable techniques in metal cutting for enhanced machinability: a review”, Journal of Cleaner Production, vol. 100, pp. 17-34, 2015.
[7]
Debnath, S., Reddy, M. M. and Yi, Q. S., “Environmental friendly cutting fluids and cooling techniques in machining: a review”, Journal of cleaner production, vol. 83, pp. 33-47, 2014.
[8]
Sharma, A. K., Tiwari, A. K. and Dixit, A. R., “Effects of Minimum Quantity Lubrication (MQL) in machining processes using conventional and nanofluid based cutting fluids: A comprehensive review”, Journal of Cleaner Production, vol. 127, pp. 1-18, 2016.
[9]
Benedicto, E., Carou, D. and Rubio, E. M., “Technical, economic and environmental review of the lubrication/cooling systems used in machining processes”, Procedia engineering, vol. 184, pp. 99-116, 2017.
[10]
Krolczyk, G. M., Maruda, R. W., Krolczyk, J. B., Wojciechowski, S., Mia, M., Nieslony, P. and Budzik, G., “Ecological trends in machining as a key factor in sustainable production–a review”, Journal of Cleaner Production, vol. 218, pp. 601-615, 2019.
[11]
Tai, B. L., Stephenson, D. A., Furness, R. J. and Shih, A. J., “Minimum quantity lubrication (MQL) in automotive powertrain machining”, Procedia CIRP, vol. 14, pp. 523-528, 2014.
[12]
Schey, J. A., “Introduction to Manufacturing Processes”, Third ed., Singapore: Mc Graw Hill, 2000.
[13]
Shashidhara, Y. M. and Jayaram, S. R., “Vegetable oils as a potential cutting fluid—an evolution”, Tribology International, vol. 43, pp. 1073-1081, 2010.
[14]
Babic, D., Murray, D. B. and Torrance, A. A., “Mist jet cooling of grinding processes”, International Journal of Machine Tools and Manufacture, vol. 45, pp. 1171-1177, 2005.
[15]
An, Q. L., Fu, Y. C. and Xu, J. H., “Experimental study on turning of TC9 titanium alloy with cold water mist jet cooling” International Journal of Machine Tools and Manufacture, vol. 51, pp. 549-555, 2011.
[16]
Lv, D., Xu, J., Ding, W., Fu, Y., Yang, C. and Su, H., “Tool wear in milling Ti40 burn-resistant titanium alloy using pneumatic mist jet impinging cooling”, Journal of Materials Processing Technology, 229, pp. 641-650, 2016.
[17]
Nandgaonkar, S., Gupta, T. V. K. and Joshi, S., “Effect of water oil mist spray (WOMS) cooling on drilling of Ti6Al4V alloy using Ester oil based cutting fluid”, Procedia Manufacturing, vol. 6, pp. 71-79, 2016.
[18]
Kaminski, J. and Alvelid, B., “Temperature reduction in the cutting zone in water-jet assisted turning”, Journal of Materials Processing Technology, vol. 106, pp. 68-73, 2000.
[19]
Ezugwu, E. O., Machado, A. R., Pashby, I. R. and Wallbank, J., “The effect of high-pressure coolant supply when machining a heat-resistant nickel-based superalloy”, Lubrication Engineering, vol. 47, pp. 751-757, 1991.
[20]
Kramar, D. and Kopac, J., “High pressure cooling in the machining of hard-to-machine materials”, Journal of Mechanical Engineering, vol. 55, pp. 685-694, 2009.
[21]
Çolak, O., “Investigation on machining performance of Inconel 718 in high pressure cooling conditions”, Journal of Mechanical Engineering, vol. 58, pp. 683-690, 2012.
[22]
Çolak, O., “Optimization of machining performance in high-pressure assisted turning of Ti6Al4V alloy, ” Journal of Mechanical Engineering, vol. 60, pp. 675-681, 2014.
[23]
Xu, J., He, L., Su, H. and Zhang, L., “Tool wear investigation in high-pressure jet coolant assisted machining Ti2AlNb intermetallic alloys based on FEM”, International Journal of Lightweight Materials and Manufacture, vol. 1, pp. 219-228, 2018.
[24]
Alaxender, A., Varadarajan, A. S. and Philip, P. K., “Hard turning with minimum cutting fluid: a viable green alternative on the shop floor,” In Proc. of the 18th AIMTDR (pp. 152-155), 1998.
[25]
Cayli, T., Klocke, F. and Döbbeler, B., “Increasing Energy Efficiency in Turning of Aerospace Materials with High-Pressure Coolant Supply”, Procedia Manufacturing, vol. 21, pp. 405-412, 2018.
[26]
Alagan, N. T., Zeman, P., Hoier, P., Beno, T. and Klement, U., “Investigation of micro-textured cutting tools used for face turning of alloy 718 with high-pressure cooling, ” Journal of Manufacturing Processes, vol. 37, pp. 606-616, 2019.
[27]
Busch, K., Hochmuth, C., Pause, B., Stoll, A. and Wertheim, R., “Investigation of cooling and lubrication strategies for machining high-temperature alloys, ” Procedia CIRP, vol. 41, pp. 835-840, 2016.
[28]
Sørby, K. and Vagnorius, Z., “High-Pressure Cooling in Turning of Inconel 625 with Ceramic Cutting Tools”, Procedia CIRP, vol. 77, pp. 74-77, 2018.
[29]
Ezugwu, E. O. and Bonney, J., “Effect of high-pressure coolant supplies when machining nickel-base, Inconel 718, alloy with ceramic tools”, Tribology transactions, vol. 46, pp. 580-584, 2003.
[30]
Ezugwu, E. O., Bonney, J., Fadare, D. A. and Sales, W. F., “Machining of nickel-base, Inconel 718, alloy with ceramic tools under finishing conditions with various coolant supply pressures”, Journal of Materials Processing Technology, vol. 162, pp. 609-614, 2005.
[31]
Bruni, C., Forcellese, A., Gabrielli, F. and Simoncini, M., “Effect of the lubrication-cooling technique, insert technology and machine bed material on the workpart surface finish and tool wear in finish turning of AISI 420B, ” International Journal of Machine Tools and Manufacture, vol. 46, pp. 1547-1554. 2006.
[32]
Raykar, S. J., D’Addona, D. M. and Kramar, D., “Analysis of surface topology in dry machining of EN-8 steel”, Procedia materials science, vol. 6, pp. 931-938, 2014.
[33]
Rubio, E. M., Villeta, M., Carou, D. and Saá, A., “Comparative analysis of sustainable cooling systems in intermittent turning of magnesium pieces”, International journal of precision engineering and manufacturing, vol. 15, pp. 929-940, 2014.
[34]
List, G., Nouari, M., Géhin, D., Gomez, S., Manaud, J. P., Le Petitcorps, Y. and Girot, F., “Wear behavior of cemented carbide tools in dry machining of aluminium alloy”, Wear, vol. 259, pp. 1177-1189, 2005.
[35]
Bermudo, C., Trujillo, F. J., Herrera, M. and Sevilla, L., “Parametric analysis of the Ultimate Tensile Strength in dry machining of UNS A97075 Alloy, ” Procedia Manufacturing, vol. 13, pp. 81-88, 2017.
[36]
Davoodi, B. and Tazehkandi, A. H., “Experimental investigation and optimization of cutting parameters in dry and wet machining of aluminum alloy 5083 in order to remove cutting fluid”, Journal of Cleaner Production, vol. 68, pp. 234-242. 2014.
[37]
Devillez, A., Le Coz, G., Dominiak, S. and Dudzinski, D., “Dry machining of Inconel 718, workpiece surface integrity”, Journal of Materials Processing Technology, vol. 211, pp. 1590-1598, 2011.
[38]
Venkatesan, K. and Thakur, A., “A Comparative Study on Machinability Characteristics in Dry Machining Of Nimonic 263 Alloy Using Coated Carbide Inserts”. Materials Today: Proceedings, vol. 5, pp. 12443-12452, 2018
[39]
Sugihara, T., Singh, P. and Enomoto, T., “Development of novel cutting tools with dimple textured surfaces for dry machining of aluminum alloys”, Procedia Manufacturing, vol. 14, pp. 111-117, 2017.
[40]
Niketh, S. and Samuel, G. L., “Drilling performance of micro textured tools under dry, wet and MQL condition”, Journal of Manufacturing Processes, vol. 32, pp. 254-268, 2018.
[41]
Elmunafi, M. H. S., Kurniawan, D. and Noordin, M. Y., “Use of castor oil as cutting fluid in machining of hardened stainless steel with minimum quantity of lubricant”, Procedia CIRP, vol. 26, pp. 408-411, 2015.
[42]
Park, K. H., Olortegui-Yume, J., Yoon, M. C. and Kwon, P., “A study on droplets and their distribution for minimum quantity lubrication (MQL) ”, International Journal of Machine Tools and Manufacture, vol. 50, pp. 824-833, 2010.
[43]
Sai, S. S., Manoj Kumar, K. and Ghosh, A., “Assessment of spray quality from an external mix nozzle and its impact on SQL grinding performance”, International Journal of Machine Tools and Manufacture, vol. 89, pp. 132-141, 2015.
[44]
Sarıkaya, M. and Güllü, A., “Taguchi design and response surface methodology based analysis of machining parameters in CNC turning under MQL”, Journal of Cleaner Production, vol. 65, pp. 604-616, 2014.
[45]
Rahim, E. A., Ibrahim, M. R., Rahim, A. A., Aziz, S. and Mohid, Z., “Experimental investigation of minimum quantity lubrication (MQL) as a sustainable cooling technique”, Procedia CIRP, vol. 26, pp. 351-354, 2015.
[46]
Dureja, J. S., Singh, R., Singh, T., Singh, P., Dogra, M. and Bhatti, M. S., “Performance evaluation of coated carbide tool in machining of stainless steel (AISI 202) under minimum quantity lubrication (MQL) ”, International Journal of Precision Engineering and Manufacturing-Green Technology, vol. 2, pp. 123-129, 2015.
[47]
Sakharkar, S. N. and Pawade, R. S., “Effect of Machining Environment on Turning Performance of Austempered Ductile Iron”, CIRP Journal of Manufacturing Science and Technology, vol. 22, pp. 49-65, 2018.
[48]
Nouioua, M., Yallese, M. A., Khettabi, R., Belhadi, S. and Mabrouki, T., “Comparative assessment of cooling conditions, including MQL technology on machining factors in an environmentally friendly approach”, The International Journal of Advanced Manufacturing Technology, vol. 91, pp. 3079-3094, 2017.
[49]
Ekinovic, S., Prcanovic, H. and Begovic, E., “Investigation of influence of MQL machining parameters on cutting forces during MQL turning of carbon steel St52-3”, Procedia engineering, vol. 132, pp. 608-614, 2015.
[50]
Brinksmeier, E., Pecat, O. and Rentsch, R., “Quantitative analysis of chip extraction in drilling of Ti6Al4V,” CIRP Annals, vol. 64, pp. 93-96, 2015.
[51]
Tamang, S. K., Chandrasekaran, M. and Sahoo, A. K., “Sustainable machining: an experimental investigation and optimization of machining Inconel 825 with dry and MQL approach”, Journal of the Brazilian Society of Mechanical Sciences and Engineering, vol. 40, pp. 374. 2018.
[52]
Khatri, A. and Jahan, M. P., “Investigating tool wear mechanisms in machining of Ti-6Al-4V in flood coolant, dry and MQL conditions”, Procedia Manufacturing, 26, pp. 434-445, 2018.
[53]
Viswanathan, R., Ramesh, S. and Subburam, V., “Measurement and optimization of performance characteristics in turning of Mg alloy under dry and MQL conditions”, Measurement, vol. 120, pp. 107-113, 2018.
[54]
Chetan, Ghosh, S. and Rao, P. V., “Specific cutting energy modeling for turning nickel-based Nimonic 90 alloy under MQL condition”, International Journal of Mechanical Sciences, vol. 146, pp. 25-38, 2018.
[55]
Tai, B. L., “Workpiece temperature during deep-hole drilling of cast iron using high air pressure minimum quantity lubrication”, Journal of Manufacturing Science and Engineering, vol. 135, pp. 1–7, 2013.
[56]
Sakharkar, S. N. and Pawade, R. S., “Effect of Machining Environment on Turning Performance of Austempered Ductile Iron”, CIRP Journal of Manufacturing Science and Technology, vol. 22, pp. 49-65, 2018.
[57]
Hadad, M. and Sharbati, A., “Thermal aspects of environmentally friendly-MQL grinding process”, Procedia CIRP, vol. 40, pp. 509-515, 2016.
[58]
Chakule, R. R., Chaudhari, S. S. and Talmale, P. S., “Evaluation of the effects of machining parameters on MQL based surface grinding process using response surface methodology”, Journal of Mechanical Science and Technology, vol. 31, pp. 3907-3916, 2017.
[59]
Coupland, J. N. and McClements, D. J., “Physical properties of liquid edible oils”, Journal of the American Oil Chemists' Society, vol. 74, pp. 1559-1564, 1997.
[60]
Rahim, E. A. and Sasahara, H., “A study of the effect of palm oil as MQL lubricant on high speed drilling of titanium alloys”, Tribology International, vol. 44, pp. 309-317, 2011.
[61]
Yıldırım, Ç. V., Kıvak, T., Sarıkaya, M. and Erzincanlı, F., “Determination of MQL parameters contributing to sustainable machining in the milling of nickel-base superalloy waspaloy”, Arabian Journal for Science and Engineering, vol. 42, pp. 4667-4681, 2017.
[62]
Zhang, S., Li, J. F. and Wang, Y. W., “Tool life and cutting forces in end milling Inconel 718 under dry and minimum quantity cooling lubrication cutting conditions”, Journal of Cleaner Production, vol. 32, pp. 81-87, 2012.
[63]
Al-Wajidi, W., Deiab, I., Defersha, F. M. and Elsayed, A., “Effect of MQL on the microstructure and strength of friction stir welded 6061 Al alloy, ” The International Journal of Advanced Manufacturing Technology, vol. 101, pp. 901-912, 2019.
[64]
Sampaio, M. A., Machado, A. R., Laurindo, C. A. H., Torres, R. D. and Amorim, F. L., “Influence of minimum quantity of lubrication (MQL) when turning hardened SAE 1045 steel: a comparison with dry machining”, The International Journal of Advanced Manufacturing Technology, vol. 98, pp. 959-968, 2018.
[65]
Agrawal, S. M. and Patil, N. G., “Experimental study of non-edible vegetable oil as a cutting fluid in machining of M2 Steel using MQL, ” Procedia Manufacturing, vol. 20, pp. 207-212, 2018.
[66]
Vardhaman, B. A., Amarnath, M., Jhodkar, D., Ramkumar, J., Chelladurai, H. and Roy, M. K., “Influence of coconut oil on tribological behavior of carbide cutting tool insert during turning operation”, Journal of the Brazilian Society of Mechanical Sciences and Engineering, vol. 40, pp. 450, 2018.
[67]
Talib, N. and Rahim, E. A., “Performance evaluation of chemically modified crude Jatropha oil as a bio-based metalworking fluid for machining process”, Procedia CIRP, vol. 26, pp. 346-350, 2015.
[68]
Talib, N. and Rahim, E. A., “Performance of modified Jatropha oil in combination with hexagonal boron nitride particles as a bio-based lubricant for green machining”, Tribology International, vol. 118, pp. 89-104, 2018.
[69]
Reddy, N. S. K.; Rao, P. V., “Experimental investigation to study the effect of solid lubricants on cutting forces and surface quality in end milling”, International Journal of Machine Tools & Manufacture, vol. 46, pp. 189– 198, 2006.
[70]
Paturi, U. M. R., Maddu, Y. R., Maruri, R. R. and Narala, S. K. R., “Measurement and analysis of surface roughness in WS2 solid lubricant assisted minimum quantity lubrication (MQL) turning of Inconel 718”, Procedia CIRP, vol. 40, pp. 138-143, 2016.
[71]
Gunda, R. K., Reddy, N. S. K. and Kishawy, H. A., “A novel technique to achieve sustainable machining system”, Procedia CIRP, vol. 40, pp. 30-34, 2016.
[72]
Marques, A., Suarez, M. P., Sales, W. F. and Machado, Á. R., “Turning of Inconel 718 with whisker-reinforced ceramic tools applying vegetable-based cutting fluid mixed with solid lubricants by MQL”, Journal of Materials Processing Technology, vol. 266, pp. 530-543, 2019.
[73]
Sterle, L., Kalin, M. and Pušavec, F., “Performance Evaluation of Solid Lubricants under Machining-Like Conditions”, Procedia CIRP, vol. 77, pp. 401-404, 2018.
[74]
Sharma, A. K., Tiwari, A. K., Dixit, A. R., Singh, R. K. and Singh, M., “Novel uses of alumina/graphene hybrid nanoparticle additives for improved tribological properties of lubricant in turning operation”, Tribology International, vol. 119, pp. 99-111, 2018.
[75]
Salimi-Yasar, H., Heris, S. Z. and Shanbedi, M., “Influence of soluble oil-based TiO2 nanofluid on heat transfer performance of cutting fluid”, Tribology International, vol. 112, pp. 147-154, 2017.
[76]
JAFARI, N. M., Shekarian, E., Tarighaleslami, A. H., Khodaverdi, F. and BADINI, P. M., “The impact of application of heat transfer enhancement technologies on design of shell and tube heat exchangers”, Iran. Journal of Chemical Engineering, vol. 14, pp. 64-74, 2015.
[77]
Uysal, A., Demiren, F. and Altan, E., “Applying minimum quantity lubrication (MQL) method on milling of martensitic stainless steel by using nano MoS2 reinforced vegetable cutting fluid”, Procedia-Social and Behavioral Sciences, vol. 195, pp. 2742-2747, 2015.
[78]
Rabiei, F., Rahimi, A. R., Hadad, M. J. and Saberi, A., “Experimental evaluation of coolant-lubricant properties of nanofluids in ultrasonic assistant MQL grinding”, The International Journal of Advanced Manufacturing Technology, vol. 93, pp. 3935-3953, 2017a.
[79]
Wang, Y., Li, C., Zhang, Y., Yang, M., Li, B., Dong, L. and Wang, J., “Processing characteristics of vegetable oil-based nanofluid MQL for grinding different workpiece materials”, International Journal of Precision Engineering and Manufacturing-Green Technology, vol. 5, pp. 327-339, 2018.
[80]
Eltaggaz, A., Hegab, H., Deiab, I. and Kishawy, H. A., “Hybrid nano-fluid-minimum quantity lubrication strategy for machining austempered ductile iron (ADI)”, International Journal on Interactive Design and Manufacturing (IJIDeM), vol. 12, pp. 1273-1281, 2018.
[81]
Gutnichenko, O., Bushlya, V., Bihagen, S. and Ståhl, J. E., “Influence of GnP additive to vegetable oil on machining performance when MQL-assisted turning Alloy 718”, Procedia Manufacturing, vol. 25, pp. 330-337, 2018.
[82]
Hegab, H., Darras, B. and Kishawy, H. A., “Sustainability assessment of machining with nano-cutting fluids”, Procedia Manufacturing, vol. 26, pp. 245-254, 2018.
[83]
Zhang, X., Li, C., Zhang, Y., Wang, Y., Li, B., Yang, M., Guo, S., Liu, G. and Zhang, N., “Lubricating property of MQL grinding of Al2O3/SiC mixed nanofluid with different particle sizes and microtopography analysis by cross-correlation”, Precision Engineering, vol. 47, pp. 532-545, 2017.
[84]
Zhang, Y., Li, C., Jia, D., Zhang, D. and Zhang, X., “Experimental evaluation of the lubrication performance of MoS2/CNT nanofluid for minimal quantity lubrication in Ni-based alloy grinding”, International Journal of Machine Tools and Manufacture, vol. 99, pp. 19-33, 2015.
[85]
Lv, T., Huang, S., Hu, X., Ma, Y. and Xu, X., “Tribological and machining characteristics of a minimum quantity lubrication (MQL) technology using GO/SiO2 hybrid nanoparticle water-based lubricants as cutting fluids”, The International Journal of Advanced Manufacturing Technology, vol. 96, pp. 2931-2942, 2018.
[86]
Rabiei, F. A. R. S. H. A. D., Rahimi, A. R. and Hadad, M., “Performance improvement of eco-friendly MQL technique by using hybrid nanofluid and ultrasonic-assisted grinding”, The International Journal of Advanced Manufacturing Technology, vol. 93, pp. 1001-1015, 2017b.
[87]
Davis, B., Schueller, J. K. and Huang, Y., “Study of ionic liquid as effective additive for minimum quantity lubrication during titanium machining”, Manufacturing Letters, 5, pp. 1-6, 2015.
[88]
Goindi, G. S., Chavan, S. N., Mandal, D., Sarkar, P. and Jayal, A. D., “Investigation of ionic liquids as novel metalworking fluids during minimum quantity lubrication machining of a plain carbon steel”, Procedia CIRP, 26, pp. 341-345, 2015.
[89]
Pham, M. Q., Yoon, H. S., Khare, V. and Ahn, S. H., “Evaluation of ionic liquids as lubricants in micro milling–process capability and sustainability”, Journal of cleaner production, vol. 76, pp. 167-173, 2014.
[90]
Sani, A. S. A., Rahim, E. A., Sharif, S. and Sasahara, H., “Machining performance of vegetable oil with phosphonium-and ammonium-based ionic liquids via MQL technique”, Journal of Cleaner Production, vol. 209, pp. 947-964, 2019.
[91]
Huang, S., Wang, Z., Yao, W. and Xu, X., “Tribological evaluation of contact-charged electrostatic spray lubrication as a new near-dry machining technique”, Tribology International, vol. 91, pp. 74-84, 2015.
[92]
Mia, M., Razi, M. H., Ahmad, I., Mostafa, R., Rahman, S. M., Ahmed, D. H., Dey, P. R. and Dhar, N. R., “Effect of time-controlled MQL pulsing on surface roughness in hard turning by statistical analysis and artificial neural network”, The International Journal of Advanced Manufacturing Technology, vol. 91, pp. 3211-3223, 2017.
[93]
Mia, M., Singh, G., Gupta, M. K. and Sharma, V. S., “Influence of Ranque-Hilsch vortex tube and nitrogen gas assisted MQL in precision turning of Al 6061-T6”, Precision Engineering, vol. 53, pp. 289-299, 2018.
[94]
Xu, X., Huang, S., Wang, M. and Yao, W., “A study on process parameters in end milling of AISI-304 stainless steel under electrostatic minimum quantity lubrication conditions”, The International Journal of Advanced Manufacturing Technology, vol. 90, pp. 979-989, 2017.
[95]
Dhar, N. R., Paul, S. and Chattopadhyay, A. B., “Machining of AISI 4140 steel under cryogenic cooling—tool wear, surface roughness and dimensional deviation”, Journal of Materials processing technology, vol. 123, pp. 483-489, 2002.
[96]
Dhar, N. R. and Kamruzzaman, M., “Cutting temperature, tool wear, surface roughness and dimensional deviation in turning AISI-4037 steel under cryogenic condition”, International Journal of Machine Tools & Manufacture, vol. 47, pp. 754–759, 2007.
[97]
Fredj, N. B., Sidhom, H. and Braham, C., “Ground surface improvement of the austenitic stainless steel AISI 304 using cryogenic cooling”, Surface and Coatings Technology, vol. 200, pp. 4846-4860, 2006.
[98]
Umbrello, D., Micari, F. and Jawahir, I. S., 2012, “The effects of cryogenic cooling on surface integrity in hard machining: A comparison with dry machining”, CIRP annals, 61 (1), pp. 103-106.
[99]
Manimaran, G. and Pradeepkumar, M., “Influence of cryogenic cooling on surface grinding of stainless steel 316”, Cryogenics, vol. 59, pp. 76-83, 2014.
[100]
Dinesh, S., Senthilkumar, V., Asokan, P. and Arulkirubakaran, D., “Effect of cryogenic cooling on machinability and surface quality of bio-degradable ZK60 Mg alloy”, Materials & design, vol. 87, pp. 1030-1036, 2015.
[101]
Shokrani, A., Dhokia, V. and Newman, S. T., “Cryogenic high speed machining of cobalt chromium alloy”, Procedia CIRP, vol. 46, pp. 404-407, 2016.
[102]
Aramcharoen, A., “Influence of cryogenic cooling on tool wear and chip formation in turning of titanium alloy” Procedia CIRP, vol. 46, pp. 83-86, 2016.
[103]
Yousfi, M., Outeiro, J. C., Nouveau, C., Marcon, B. and Zouhair, B., “Tribological behavior of PVD hard coated cutting tools under cryogenic cooling condition”, Procedia CIRP, vol. 58, pp. 561-565, 2017.
[104]
Isakson, S., Sadik, M. I., Malakizadi, A. and Krajnik, P., “Effect of cryogenic cooling and tool wear on surface integrity of turned Ti-6Al-4V”, Procedia CIRP, vol. 71, pp. 254-259, 2018.
[105]
Mia, M., “Multi-response optimization of end milling parameters under through-tool cryogenic cooling condition”, Measurement, vol. 111, pp. 134-145, 2017.
[106]
Nie, G. C., Zhang, X. M., Zhang, D. and Ding, H., “An experimental study of the white layer formation during cryogenic assisted hard machining of AISI 52100 steel”, Procedia CIRP, 77, pp. 223-226, 2018.
[107]
Mia, M., Gupta, M. K., Lozano, J. A., Carou, D., Pimenov, D. Y., Królczyk, G., Khan, A. M. and Dhar, N. R., “Multi-objective optimization and life cycle assessment of eco-friendly cryogenic N2 assisted turning of Ti-6Al-4V”, Journal of Cleaner Production, vol. 210, pp. 121-133, 2018.
[108]
Sivaiah, P. and Chakradhar, D., “Performance improvement of cryogenic turning process during machining of 17-4 PH stainless steel using multi objective optimization techniques”, Measurement, vol. 136, pp. 326-336, 2019.
[109]
Dhananchezian, M., “Study the machinability characteristics of Nicked based Hastelloy C-276 under cryogenic cooling”, Measurement, vol. 136, pp. 694-702, 2019.
[110]
NALBANT, M. and YILDIZ, Y., “Effect of cryogenic cooling in milling process of AISI 304 stainless steel”, Trans. Nonferrous Met. Soc. China, vol. 21, pp. 72-79, 2011.
[111]
Murugappan, S., Arul, S. and Narayanan, S. K., “An experimental study on turning of AL6063 under cryogenic pre cooled condition”, Procedia CIRP, vol. 35, pp. 61-66, 2015.
[112]
Biermann, D. and Hartmann, H., “Reduction of burr formation in drilling using cryogenic process cooling,” Procedia CIRP, vol. 3, pp. 85-90, 2012.
[113]
Cordes, S., Hübner, F. and Schaarschmidt, T., “Next generation high performance cutting by use of carbon dioxide as cryogenics”, Procedia CIRP, vol. 14, pp. 401-405, 2014.
[114]
Rahim, E. A., Rahim, A. A., Ibrahim, M. R. and Mohid, Z., “Experimental investigation of supercritical carbon dioxide (SCCO2) performance as a sustainable cooling technique”, Procedia CIRP, vol. 40, pp. 637-641, 2016.
[115]
Pereira, O., Rodríguez, A., Barreiro, J., Fernández-Abia, A. I. and de Lacalle, L. N. L., “Nozzle design for combined use of MQL and cryogenic gas in machining”, International journal of precision engineering and manufacturing-green technology, vol. 4, pp. 87-95, 2017.
[116]
Park, K. H., Suhaimi, M. A., Yang, G. D., Lee, D. Y., Lee, S. W. and Kwon, P., “Milling of titanium alloy with cryogenic cooling and minimum quantity lubrication (MQL)”, International Journal of Precision Engineering and Manufacturing, vol. 18, pp. 5-14, 2017.
[117]
Hanenkamp, N., Amon, S. and Gross, D., “Hybrid Supply System for Conventional and CO2/MQL-based Cryogenic Cooling”, Procedia CIRP, vol. 77, pp. 219-222, 2018.
[118]
Iturbe, A., Hormaetxe, E., Garay, A. and Arrazola, P. J., “Surface integrity analysis when machining inconel 718 with conventional and cryogenic cooling”, Procedia CIRP, 45, pp. 67-70, 2016.
Browse journals by subject