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The International Journal of Advanced Manufacturing Technology
Erschienen in: The International Journal of Advanced Manufacturing Technology 9-10/2020

14.01.2020 | ORIGINAL ARTICLE

Metal cutting lubricants and cutting tools: a review on the performance improvement and sustainability assessment

verfasst von: Ali H. Abdelrazek, I. A. Choudhury, Yusoff Nukman, S. N. Kazi

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 9-10/2020

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Abstract

The quality enhancement during massive production of the traditional machining products is a risky challenge when the cost and environmental impact must be considered. The tool life, material recycling, energy consumption, space, and environmental pollution are the direct and indirect factors to increase the cost during different machining processes. Treatment of cooling liquids to be eco-friendly and cheaper, and machining tools to enhance their surface morphology and increase their lives are the keys of the sustainable machining. This paper reviews the sustainability evaluation and the performance of different types of cooling fluids and lubricants, and surface texture modification of tool surfaces and their effects on the machining outputs and environment as well.
Vorheriger Artikel A predictive approach to investigating effects of ultrasonic-assisted burnishing process on surface performances of shaft targets
Nächster Artikel Stability of micro dry wire EDM: OFAT and DOE method

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Literatur
1.
Kalpakjian S (2001) Manufacturing engineering and technology. Pearson Education India, Bengaluru
2.
Trent EM, Wright PK (2000) Metal cutting. Butterworth-Heinemann, Oxford
3.
Adler DP, Hii WW-S, Michalek DJ, Sutherland JW (2006) Examining the role of cutting fluids in machining and efforts to address associated environmental/health concerns. Mach Sci Technol 10(1):23–58
4.
Andriankaja H, Le Duigou J, Eynard B (2015) Sustainable machining approach by integrating the environmental assessment within the CAD/CAM/CNC Chain. In: ICoRD’15–Research into Design Across Boundaries, vol 2. Springer, Berlin, pp 227–236
5.
Kovoor PP, Idris MR, Hassan MH, Yahya TFT (2012) A study conducted on the impact of effluent waste from machining process on the environment by water analysis. Int J Energy Environ Eng 3(1):21
6.
Haider J, Hashmi MSJ (2014) Health and environmental impacts in metal machining processes. Compr Mater Process 8:7–33
7.
Camposeco-Negrete C, de Dios Calderón-Nájera J (2019) Sustainable machining as a mean of reducing the environmental impacts related to the energy consumption of the machine tool: a case study of AISI 1045 steel machining. Int J Adv Manuf Technol 102(1–4):27–41
8.
Sugihara T, Singh P, Enomoto T (2017) Development of novel cutting tools with dimple textured surfaces for dry machining of aluminum alloys. Procedia Manuf 14:111–117
9.
Bhuiyan M, Choudhury I, Dahari M (2014) Monitoring the tool wear, surface roughness and chip formation occurrences using multiple sensors in turning. J Manuf Syst 33(4):476–487
10.
Sharma VS, Dogra M, Suri NM (2009) Cooling techniques for improved productivity in turning. Int J Mach Tools Manuf 49(6):435–453
11.
Boothroyd G (1988) Fundamentals of metal machining and machine tools, vol 28. Crc Press, Boca Raton
12.
Liew PJ, Shaaroni A, Sidik NA, Yan JC (2017) An overview of current status of cutting fluids and cooling techniques of turning hard steel. Int J Heat Mass Transf 114:380–394
13.
Silliman JD (1992) Cutting and grinding fluids: selection and application. Society of manufacturing engineers, Dearborn
14.
Chan CY, Lee WB, Wang H (2013) Enhancement of surface finish using water-miscible nano-cutting fluid in ultra-precision turning. Int J Mach Tools Manuf 73:62–70
15.
Sreejith PS (2008) Machining of 6061 aluminium alloy with MQL, dry and flooded lubricant conditions. Mater Lett 62(2):276–278
16.
Satheesh Kumar B, Padmanabhan G, Vamsi Krishna P (2016) Multi response optimization for turning AISI 1040 steel with extreme pressure additive included vegetable oil based cutting fluids using grey relational analysis. J Adv Res Mater Sci 23(1):1–14
17.
Bienkowski K (1993) Coolants & lubricants staying pure. Manuf Eng (USA) 110(4):55–56
18.
Anton S, Andreas S, Friedrich B (2015) Heat dissipation in turning operations by means of internal cooling. Procedia Eng 100:1116–1123
19.
Deng J, Wenlong S, Hui Z (2009) Design, fabrication and properties of a self-lubricated tool in dry cutting. Int J Mach Tools Manuf 49(1):66–72
20.
Klocke FAEG, Eisenblätter G (1997) Dry cutting. CIRP Annals 46(2):519–526
21.
Bouzakis K-D, Michailidis N, Skordaris G, Bouzakis E, Biermann D, M'Saoubi R (2012) Cutting with coated tools: coating technologies, characterization methods and performance optimization. CIRP Ann 61(2):703–723
22.
Bobzin K (2017) High-performance coatings for cutting tools. CIRP J Manuf Sci Technol 18:1–9
23.
Kustas FM, Fehrehnbacher LL, Komanduri R (1997) Nanocoatings on cutting tools for dry machining. CIRP Ann 46(1):39–42
24.
Ducros C, Sanchette F (2006) Multilayered and nanolayered hard nitride thin films deposited by cathodic arc evaporation. Part 2: mechanical properties and cutting performances. Surf Coat Technol 201(3–4):1045–1052
25.
Yashar PC, Sproul WD (1999) Nanometer scale multilayered hard coatings. Vacuum 55(3–4):179–190
26.
Yao S-H, Su Y-L, Kao W-H, Liu T-H (2006) Tribology and oxidation behavior of TiN/AlN nano-multilayer films. Tribol Int 39(4):332–341
27.
PalDey S, Deevi SC (2003) Single layer and multilayer wear resistant coatings of (Ti,Al)N: a review. Mater Sci Eng A 342(1–2):58–79
28.
Andersen KN, Bienk EJ, Schweitz KO, Chevallier J, Reitz H, Kringhøj P, Bøttiger J (2000) Deposition, microstructure and mechanical and tribological properties of magnetron sputtered TiN/TiAlN multilayers. Surf Coat Technol 123(2–3):219–226
29.
Knutsson A, Jõesaar MPJ, Karlsson L, Odén M (2011) Machining performance and decomposition of TiAlN/TiN multilayer coated metal cutting inserts. Surf Coat Technol 205(16):4005–4010
30.
Çalışkan H, Kurbanoglu C, Panjan P, Čekada M, Kramar D (2013) Wear behavior and cutting performance of nanostructured hard coatings on cemented carbide cutting tools in hard milling. Tribol Int 62:215–222
31.
Sharma V, Pandey PM (2016) Recent advances in turning with textured cutting tools: a review. J Clean Prod 137:701–715
32.
Demircioglu P (2017) In: Hashmi MSJ (ed) 3.17 Topological evaluation of surfaces in relation to surface finish, in comprehensive materials finishing. Elsevier, Oxford, pp 243–260
33.
Gachot C, Rosenkranz A, Hsu SM, Costa HL (2017) A critical assessment of surface texturing for friction and wear improvement. Wear 372-373:21–41
34.
Arulkirubakaran D, Senthilkumar V, Lomesh CV, Senthil P (2019) Performance of surface textured tools during machining of Al-Cu/TiB2 composite. Measurement 137:636–646
35.
Debnath S, Reddy MM, Yi QS (2016) Influence of cutting fluid conditions and cutting parameters on surface roughness and tool wear in turning process using Taguchi method. Measurement 78:111–119
36.
Çakīr O, Yardimeden A, Ozben T, Kilickap E (2007) Selection of cutting fluids in machining processes. J Achiev Mater Manuf Eng 25(2):99–102
37.
Smith GT (2008) Cutting tool technology: industrial handbook. Springer Science & Business Media, Berlin
38.
Dennison MS, Sivaram NM, Barik D, Ponnusamy S (2019) Turning operation of AISI 4340 steel in flooded, near-dry and dry conditions: a comparative study on tool-work interface temperature. Mech Mech Eng 23(1):–172
39.
Krolczyk GM, Maruda RW, Krolczyk JB, Mia M, Wojciechowski S, Nieslony P, Budzik G (2019) Ecological trends in machining as a key factor in sustainable production—a review. J Clean Prod 218:601–615
40.
Revuru RS, Posinasetti NR, Venkata Ramana VSN, Amrita M (2017) Application of cutting fluids in machining of titanium alloys—a review. Int J Adv Manuf Technol 91(5):2477–2498
41.
Elmunafi MHS, Noordin M, Kurniawan D (2015) Tool life of coated carbide cutting tool when turning hardened stainless steel under minimum quantity lubricant using castor oil. Procedia Manuf 2:563–567
42.
Anuja Beatrice B, Kirubakaran E, Thangaiah PRJ, Wins KLD (2014) Surface roughness prediction using artificial neural network in hard turning of AISI H13 steel with minimal cutting fluid application. Procedia Eng 97:205–211
43.
Arulraj JGA, Wins KLD, Raj A (2014) Artificial neural network assisted sensor fusion model for predicting surface roughness during hard turning of H13 steel with minimal cutting fluid application. Procedia Mater Sci 5:2338–2346
44.
Alden Kendall L (1998) Friction and wear of cutting tools and cutting tool materials. ASM Metal Handbook, ASM International, The Materials Information Society 18:609–620
45.
Boswell B, Islam MN, Davies IJ, Ginting YR, Ong AK (2017) A review identifying the effectiveness of minimum quantity lubrication (MQL) during conventional machining. Int J Adv Manuf Technol 92(1):321–340
46.
ASME (1952) Manual on Cutting of Metals: With Single-point Tools. ASME, New York
47.
Debnath S, Reddy MM, Yi QS (2014) Environmental friendly cutting fluids and cooling techniques in machining: a review. J Clean Prod 83:33–47
48.
Lawal S, Choudhury I, Nukman Y (2012) Application of vegetable oil-based metalworking fluids in machining ferrous metals—a review. Int J Mach Tools Manuf 52(1):1–12
49.
Hosseini SB, Dahlgren R, Ryttberg K, Klement U (2014) Dissolution of iron-chromium carbides during white layer formation induced by hard turning of AISI 52100 steel. Procedia CIRP 14:107–112
50.
O’sullivan D, Cotterell M (2001) Temperature measurement in single point turning. J Mater Process Technol 118(1–3):301–308
51.
Satheesh Kumar B, Padmanabhan G, Vamsi Krishna P (2016) Performance assessment of vegetable oil based cutting fluids with extreme pressure additive in machining. J Adv Res Mater Sci 19:1–13
52.
Nizamuddin M, Agrawal SM, Patil N (2018) The effect of Karanja based soluble cutting fluid on chips formation in orthogonal cutting process of AISI 1045 steel. Procedia Manuf 20:12–17
53.
Soković M, Mijanović K (2001) Ecological aspects of the cutting fluids and its influence on quantifiable parameters of the cutting processes. J Mater Process Technol 109(1–2):181–189
54.
Klocke F, Kuchle A (2009) Manufacturing processes, 2nd edn. Springer, Berlin, p 433
55.
Kuram E, Ozcelik B, Bayramoglu M, Demirbas E, Simsek BT (2013) Optimization of cutting fluids and cutting parameters during end milling by using D-optimal design of experiments. J Clean Prod 42:159–166
56.
Kuram E, Ozcelik B, Demirbas E (2013) Environmentally friendly machining: vegetable based cutting fluids. In: Green manufacturing processes and systems. Springer, pp 23–47
57.
Singh R, Bajpai V (2015) Coolant and lubrication in machining. In: Nee AYC (ed) Handbook of manufacturing engineering and technology. Springer London, London, pp 981–1018
58.
Gajrani KK, Suvin PS, VasuKailas S, Sankar MR (2019) Hard machining performance of indigenously developed green cutting fluid using flood cooling and minimum quantity cutting fluid. J Clean Prod 206:108–123
59.
Gajrani KK, Ram D, Ravi Sankar M (2017) Biodegradation and hard machining performance comparison of eco-friendly cutting fluid and mineral oil using flood cooling and minimum quantity cutting fluid techniques. J Clean Prod 165:1420–1435
60.
Dhar NR, Kamruzzaman M, Ahmed M (2006) Effect of minimum quantity lubrication (MQL) on tool wear and surface roughness in turning AISI-4340 steel. J Mater Process Technol 172(2):299–304
61.
Shankar S, Mohanraj T, Ponappa K (2017) Influence of vegetable based cutting fluids on cutting force and vibration signature during milling of aluminium metal matrix composites. J Tribol 12:1–17
62.
Talib N, Sasahara H, Rahim EA (2017) Evaluation of modified jatropha-based oil with hexagonal boron nitride particle as a biolubricant in orthogonal cutting process. Int J Adv Manuf Technol 92(1):371–391
63.
Agrawal SM, Patil NG (2018) Experimental study of non edible vegetable oil as a cutting fluid in machining of M2 steel using MQL. Procedia Manuf 20:207–212
64.
Lokesh Srinivasan S, Vimalathithan R, Manojkumar MV (2018) Alternative cutting fluids for metal cutting operations. Mater Today Proc 5(2, Part 2):7758–7764
65.
Mamidi V, Xavior A (2012) A review on selection of cutting fluids. 1:2277–1174
66.
Grzesik W (2017) Chapter Ten—cutting fluids. In: Grzesik W (ed) advanced machining processes of metallic materials, 2nd edn. Elsevier, pp 183–195
67.
Fernandes A, Vinhal JO, Dutra AJB, Cassella RJ (2019) Study of the extraction of Ca, Mg and Zn from different types of lubricating oils (mineral, semi-synthetic and synthetic) employing the emulsion breaking strategy. Microchem J 145:1112–1118
68.
Abdelrazek AH, Alawi OA, Kazi SN, Yusoff N, Chowdhury Z, Sarhan AAD (2018) A new approach to evaluate the impact of thermophysical properties of nanofluids on heat transfer and pressure drop. Int Commun Heat Mass Transfer 95:161–170
69.
Mohammed H, Alawi O, Sidik NC (2016) Mixed convective nanofluids flow in a channel having forward-facing step with baffle. J Adv Res Appl Mech 24:1–21
70.
Maryam H, Ali RS, Abdelrazek H, Mallah AR, Kazi SN, Chew BT, Rozali S, Yusoff N (2018) Numerical study of turbulent heat transfer of nanofluids containing eco-friendly treated carbon nanotubes through a concentric annular heat exchanger. Int J Heat Mass Transf 127:403–412
71.
Rad Sadri MH, Kazi SN, Bagheri S, Abdelrazek AH, Ahmadi G, Zubir N, Ahmad R, Abidin NIZ (2017) A facile, bio-based, novel approach for synthesis of covalently functionalized graphene nanoplatelet nano-coolants toward improved thermo-physical and heat transfer properties. J Colloid Interface Sci
72.
Masuda H, Ebata A, Teramae K, Hishinuma N (1993) Alteration of thermal conductivity and viscosity of liquid by dispersing ultrafine particles (dispersion of c-Al2O3, SiO2, and TiO2ultra-fine particles). Netsu Bussei 7(4):227–233
73.
Choi SUS, Eastman J (1995) Enhancing thermal conductivity of fluids with nanoparticles. Argonne National Lab, Lemont
74.
Kolade B, Goodson KE, Eaton JK (2009) Convective performance of nanofluids in a laminar thermally developing tube flow. J Heat Transfer
75.
Kazi SN, Badarudin A, Zubir MN, Ming HN, Misran M, Sadeghinezhad E, Mehrali M, Syuhada NI (2015) Investigation on the use of graphene oxide as novel surfactant to stabilize weakly charged graphene nanoplatelets. Nanoscale Res Lett 10:212
76.
Yarmand H, Zulkifli NWBM, Gharehkhani S, Shirazi SFS, Alrashed AAAA, Ali MAB, Dahari M, Kazi SN (2017) Convective heat transfer enhancement with graphene nanoplatelet/platinum hybrid nanofluid. Int Commun Heat Mass Transfer 88:120–125
77.
Alawi OA, Sidik NAC, Xian HW, Kean TH, Kazi SN (2018) Thermal conductivity and viscosity models of metallic oxides nanofluids. Int J Heat Mass Transfer 116(Supplement C):1314–1325
78.
Sharma AK, Singh RK, Dixit AR, Tiwari AK (2017) Novel uses of alumina-MoS2 hybrid nanoparticle enriched cutting fluid in hard turning of AISI 304 steel. J Manuf Process 30:467–482
79.
Sidik NAC, Samion S, Ghaderian J, Yazid MNAWM (2017) Recent progress on the application of nanofluids in minimum quantity lubrication machining: a review. Int J Heat Mass Transf 108:79–89
80.
Joly-Pottuz L, Bucholz EW, Matsumoto N, Phillpot SR, Sinnott SB, Ohmae N, Martin JM (2009) Friction properties of carbon nano-onions from experiment and computer simulations. Tribol Lett 37(1):75
81.
Agapiou JS (2018) Performance evaluation of cutting fluids with carbon nano-onions as lubricant additives. Procedia Manuf 26:1429–1440
82.
Li G, Yi S, Li N, Pan W, Wen C, Ding S (2019) Quantitative analysis of cooling and lubricating effects of graphene oxide nanofluids in machining titanium alloy Ti6Al4V. J Mater Process Technol 271:584–598
83.
Gajrani KK, Suvin PS, Kailas SV, Mamilla RS (2019) Thermal, rheological, wettability and hard machining performance of MoS2 and CaF2 based minimum quantity hybrid nano-green cutting fluids. J Mater Process Technol 266:125–139
84.
De Oliveira D, Da Silva RB, Gelamo RV (2019) Influence of multilayer graphene platelet concentration dispersed in semi-synthetic oil on the grinding performance of Inconel 718 alloy under various machining conditions. Wear 426-427:1371–1383
85.
Yıldırım ÇV (2019) Experimental comparison of the performance of nanofluids, cryogenic and hybrid cooling in turning of Inconel 625. Tribol Int 137:366–378
86.
Singh R k, Sharma AK, Bishwajeet, Mandal V, Gaurav K, Nag A, Kumar A, Dixit AR, Mandal A, Das AK (2018) Influence of graphene-based nanofluid with minimum quantity lubrication on surface roughness and cutting temperature in turning operation. Mater Today Proc 5(11, Part 3):24578–24586
87.
Bystrzejewska-Piotrowska G, Golimowski J, Pawel L (2009) Urban, nanoparticles: their potential toxicity, waste and environmental management. Waste Manag 29(9):2587–2595
88.
Podgorkov VV, Kapustin AS, Godlevski VA (1998) Water steam lubrication during machining. Tribologia 6:890–901
89.
Çakır O, Kıyak M, Altan E (2004) Comparison of gases applications to wet and dry cuttings in turning. J Mater Process Technol 153:35–41
90.
Altan E, Kiyak M, Cakir O (2002) The effect of oxygen gas application into cutting zone on machining. in Proceedings of Sixth Biennial Conference on Engineering system Design and Analysis (ESDA2002), Istanbul
91.
Liu J, Han R, Sun Y (2005) Research on experiments and action mechanism with water vapor as coolant and lubricant in green cutting. Int J Mach Tools Manuf 45(6):687–694
92.
Liu J, Liu H, Han R, Wang Y (2010) The study on lubrication action with water vapor as coolant and lubricant in cutting ANSI 304 stainless steel. Int J Mach Tools Manuf 50(3):260–269
93.
Tazehkandi AH, Shabgard M, Kiani G, Pilehvarian F (2016) Investigation of the influences of polycrystalline cubic boron nitride (PCBN) tool on the reduction of cutting fluid consumption and increase of machining parameters range in turning Inconel 783 using spray mode of cutting fluid with compressed air. J Clean Prod 135:1637–1649
94.
Mia M, Gupta MK, Singh G, Królczyk G, Pimenov DY (2018) An approach to cleaner production for machining hardened steel using different cooling-lubrication conditions. J Clean Prod 187:1069–1081
95.
Dilbag S, Rao PV (2008) Performance improvement of hard turning with solid lubricants. Int J Adv Manuf Technol 38(5–6):529–535
96.
Sam Paul P, Varadarajan AS (2013) Performance evaluation of hard turning of AISI 4340 steel with minimal fluid application in the presence of semi-solid lubricants. Proc Inst Mech Eng J J Eng Tribol 227(7):738–748
97.
Ginting YR, Boswell B, Biswas W, Islam MN (2015) Investigation into alternative cooling methods for achieving environmentally friendly machining process. Procedia CIRP 29:645–650
98.
Benedicto E, Carou D, Rubio EM (2017) Technical, economic and environmental review of the lubrication/cooling systems used in machining processes. Procedia Eng 184:99–116
99.
Tazehkandi AH, Shabgard M, Pilehvarian F (2015) Application of liquid nitrogen and spray mode of biodegradable vegetable cutting fluid with compressed air in order to reduce cutting fluid consumption in turning Inconel 740. J Clean Prod 108:90–103
100.
Berk Z (2009) Chapter 20—Refrigeration, equipment and methods. In: Berk Z (ed) Food process engineering and technology. Academic Press, San Diego, pp 413–428
101.
Yildiz Y, Nalbant M (2008) A review of cryogenic cooling in machining processes. Int J Mach Tools Manuf 48(9):947–964
102.
Hong SY (2001) Economical and ecological cryogenic machining. J Manuf Sci Eng 123(2):331–338
103.
Wang ZY, Rajurkar KP (2000) Cryogenic machining of hard-to-cut materials. Wear 239(2):168–175
104.
Dix M, Wertheim R, Schmidt G, Hochmuth C (2014) Modeling of drilling assisted by cryogenic cooling for higher efficiency. CIRP Ann 63(1):73–76
105.
Sivaiah P, Chakradhar D (2019) Performance improvement of cryogenic turning process during machining of 17-4 PH stainless steel using multi objective optimization techniques. Measurement 136:326–336
106.
Sivaiah P, Chakradhar D (2018) Effect of cryogenic coolant on turning performance characteristics during machining of 17-4 PH stainless steel: a comparison with MQL, wet, dry machining. CIRP J Manuf Sci Technol 21:86–96
107.
Damir A, Shi B, Attia MH (2019) Flow characteristics of optimized hybrid cryogenic-minimum quantity lubrication cooling in machining of aerospace materials. CIRP Ann
108.
Damir A, Sadek A, Attia H (2018) Characterization of machinability and environmental impact of cryogenic turning of Ti-6Al-4V. Procedia CIRP 69:893–898
109.
Suhaimi MA, Yang G-D, Park K-H, Hisam MJ, Sharif S, Kim D-W (2018) Effect of cryogenic machining for titanium alloy based on indirect, internal and external spray system. Procedia Manuf 17:158–165
110.
Pušavec F, Grguraš D, Koch M, Krajnik P (2019) Cooling capability of liquid nitrogen and carbon dioxide in cryogenic milling. CIRP Ann 68(1):73–76
111.
Kirsch B, Basten S, Hasse H, Aurich JC (2018) Sub-zero cooling: a novel strategy for high performance cutting. CIRP Ann 67(1):95–98
112.
Sharif MN, Pervaiz S, Deiab I (2017) Potential of alternative lubrication strategies for metal cutting processes: a review. Int J Adv Manuf Technol 89(5):2447–2479
113.
Haider J, Hashmi MSJ (2014) Health and environmental impacts in metal machining processes. In: Hashmi S et al (eds) Comprehensive materials processing. Elsevier, Oxford, pp 7–33
114.
Vamsi Krishna P, Srikant RR, Rao DN (2011) Solid lubricants in machining. Proc Inst Mech Eng J J Eng Tribol 225(4):213–227
115.
Lathkar GS, Bas USK (2000) Clean metal cutting process using solid lubricants. In: Proceeding of the 19th AIMTDR Conference. Narosa, Madras
116.
Sterle L, Kalin M, Pušavec F (2018) Performance evaluation of solid lubricants under machining-like conditions. Procedia CIRP 77:401–404
117.
Essa FA, Zhang Q, Huang X (2017) Investigation of the effects of mixtures of WS2 and ZnO solid lubricants on the sliding friction and wear of M50 steel against silicon nitride at elevated temperatures. Wear 374:128–141
118.
Sartori S, Ghiotti A, Bruschi S (2018) Solid lubricant-assisted minimum quantity lubrication and cooling strategies to improve Ti6Al4V machinability in finishing turning. Tribol Int 118:287–294
119.
Yang J-F, Jiang Y, Hardell J, Prakash B, Fang Q-F (2013) Influence of service temperature on tribological characteristics of self-lubricant coatings: a review. Front Mater Sci 7(1):28–39
120.
Gunda RK, Narala SKR (2017) Evaluation of friction and wear characteristics of electrostatic solid lubricant at different sliding conditions. Surf Coat Technol 332:341–350
121.
Nageswara Rao D, Vamsi Krishna P (2008) The influence of solid lubricant particle size on machining parameters in turning. Int J Mach Tools Manuf 48(1):107–111
122.
Makhesana MA, Patel KM (2019) Performance assessment of CaF2 solid lubricant assisted minimum quantity lubrication in turning. Procedia Manuf 33:43–50
123.
World Commission on Environment Development “WCED” (1987) Report of the World Commission on Environment and Development: Our Common Future. Part I: Common Concerns. Part 2. Towards Sustainable Development. United Nations General Assembly, Geneva
124.
Chetan, Ghosh S, Rao PV (2015) Application of sustainable techniques in metal cutting for enhanced machinability: a review. J Clean Prod 100:17–34
125.
Assenova E, Majstorovic V, Vencl A, Kandeva M (2012) Green tribology and quality of life, in International Convention on Quality – ICQ. Belgrade
126.
Schwarz M, Dado M, Hnilica R, Veverková D (2015) Environmental and health aspects of metalworking fluid use. Pol J Environ Stud 24(1):37–45
127.
Madanhire I, Mbohwa C (2016) Mitigating environmental impact of petroleum lubricants. Springer, Berlin-Germany
128.
Pervaiz S, Kannan S, Kishawy OA (2018) An extensive review of the water consumption and cutting fluid based sustainability concerns in the metal cutting sector. J Clean Prod 197:134–153
129.
Zhao F, Ogaldez J, Sutherland JW (2012) Quantifying the water inventory of machining processes. CIRP Ann 61(1):67–70
130.
Chen JL, Chen Y-B, Huang H-C (2015) Quantifying the life cycle water consumption of a machine tool. Procedia CIRP 29:498–501
131.
132.
(2010) Chapter 1—deposition technologies: an overview. In: Martin PM (ed) Handbook of deposition technologies for films and coatings (Third Edition). William Andrew Publishing, Boston, p 1–31
133.
Klocke F, Krieg T (1999) Coated tools for metal cutting—features and applications. CIRP Ann 48(2):515–525
134.
Dinesh Kumar D, Kumar N, Kalaiselvam S, Dash S, Jayavel R (2017) Wear resistant super-hard multilayer transition metal-nitride coatings. Surf Interfaces 7:74–82
135.
Abdoos M, Yamamoto K, Bose B, Fox-Rabinovich G, Veldhuis S (2019) Effect of coating thickness on the tool wear performance of low stress TiAlN PVD coating during turning of compacted graphite iron (CGI). Wear 422-423:128–136
136.
Zhao J, Liu Z (2018) Effects of thermo-physical properties of Ti0.41Al0.59N coating on transient and steady cutting temperature distributions in coated cemented carbide tools. Int Commun Heat Mass Transfer 96:80–89
137.
Vereschaka A, Grigoriev S, Sitnikov N, Oganyan G, Sotova C (2018) Influence of thickness of multilayer composite nano-structured coating Ti-TiN-(Ti,Al,Cr)N on tool life of metal-cutting tool. Procedia CIRP 77:545–548
138.
Kumar CS, Patel SK (2019) Effect of duplex nanostructured TiAlSiN/TiSiN/TiAlN-TiAlN and TiAlN-TiAlSiN/TiSiN/TiAlN coatings on the hard turning performance of Al2O3-TiCN ceramic cutting tools. Wear 418-419:226–240
139.
Kumar CS, Patel SK (2018) Effect of chip sliding velocity and temperature on the wear behaviour of PVD AlCrN and AlTiN coated mixed alumina cutting tools during turning of hardened steel. Surf Coat Technol 334:509–525
140.
Kumar CS, Patel SK (2018) Performance analysis and comparative assessment of nano-composite TiAlSiN/TiSiN/TiAlN coating in hard turning of AISI 52100 steel. Surf Coat Technol 335:265–279
141.
Wang S, Guo W, Ma H-a, Jia X (2014) Direct coating of cubic boron nitride with titanium powder under high pressure and high temperature. Mater Lett 123:210–213
142.
Mei HY, Cai XH, Tang M, Hui Q, Song Q, Wang M (2019) Electronic and mechanic properties of a new cubic boron nitride. Comput Mater Sci 162:111–115
143.
Ji H, Li Z, Zhu Y, Sun K, Li L, Zhao Y (2019) Mechanical property enhancement of cubic boron nitride composites through additive diamond. Diam Relat Mater 96:20–24
144.
Donnet C, Erdemir A (2004) Solid lubricant coatings: recent developments and future trends. 17:389–397
145.
Ammar Farhan, MS. Kasim Intan Sharhida Othman, Mohd Rody Mohamad Zin, and Jariah Mohamad Juoi, Various quarry dust content influences the tribological properties of Ni-P composite coating, in Mechanical Engineering Research Day 2019. Aug. 2019: Malaysia. p. 344–346
146.
Othman IS, Azhar MZE, Jun LP (2018) Tribological properties of malaysian quarry dust reinforced nickel matrix composite coatings. In: Proceedings of Asia International Conference on Tribology, Kuching, Sarawak, Malaysia, pp 87–89
147.
Nalbant M, Gökkaya H, Toktaş İ, Sur G (2009) The experimental investigation of the effects of uncoated, PVD- and CVD-coated cemented carbide inserts and cutting parameters on surface roughness in CNC turning and its prediction using artificial neural networks. Robot Comput Integr Manuf 25(1):211–223
148.
Evans CJ, Bryan JB (1999) “Structured”, “textured” or “engineered” surfaces. CIRP Ann 48(2):541–556
149.
Kawasegi N, Sugimori H, Morimoto H, Morita N, Hori I (2009) Development of cutting tools with microscale and nanoscale textures to improve frictional behavior. Precis Eng 33(3):248–254
150.
Arumugaprabu V, Ko TJ, Kumaran ST, Kurniawan R, Uthayakumar M (2018) A brief review on importance of surface texturing in materials to improve the tribological performance. Rev Adv Mater Sci 53(1):40–48
151.
Arslan A, Masjuki HH, Kalam MA, Varman M, Mufti RA, Mosarof MH, Khuong LS, Quazi MM (2016) Surface texture manufacturing techniques and tribological effect of surface texturing on cutting tool performance: a review. Crit Rev Solid State Mater Sci 41(6):447–481
152.
Sugihara T, Enomoto T (2017) Performance of cutting tools with dimple textured surfaces: a comparative study of different texture patterns. Precis Eng 49:52–60
153.
Fatima A, Mativenga PT (2013) Assessment of tool rake surface structure geometry for enhanced contact phenomena. Int J Adv Manuf Technol 69(1–4):771–776
154.
Sugihara T, Enomoto T (2013) Crater and flank wear resistance of cutting tools having micro textured surfaces. Precis Eng 37(4):888–896
155.
Zhanjiang Yu, Q. Cai, Yiquan Li, Zhitong Wang, Wang X and Huadong Yu. Micro texture cutting tool simulation and experimental study on high speed micro-turnning. in 2016 IEEE International Conference on Mechatronics and Automation. 2016. IEEE
156.
Dhage S, Jayal AD, Sarkar P (2019) Effects of surface texture parameters of cutting tools on friction conditions at tool-chip interface during dry machining of AISI 1045 steel. Procedia Manuf 33:794–801
157.
Mishra SK, Ghosh S, Aravindan S (2019) Performance of laser processed carbide tools for machining of Ti6Al4V alloys: a combined study on experimental and finite element analysis. Precis Eng 56:370–385
158.
Zhang K, Deng J, Xing Y, Li S, Gao H (2015) Effect of microscale texture on cutting performance of WC/Co-based TiAlN coated tools under different lubrication conditions. Appl Surf Sci 326:107–118
159.
Obikawa T, Kamio A, Takaoka H, Osada A (2011) Micro-texture at the coated tool face for high performance cutting. Int J Mach Tools Manuf 51(12):966–972
160.
Youqiang Xing JD, Jun Zhao GZ, Zhang K (2014) Cutting performance and wear mechanism of nanoscale and microscale textured Al2O3/TiC ceramic tools in dry cutting of hardened steel. Int J Refract Met Hard Mater 43:46–58
161.
Bagaber SA, Yusoff AR (2017) Effect of cutting parameters on sustainable machining performance of coated carbide tool in dry turning process of stainless steel 316. AIP Conf Proc 1828(1):020013
162.
Kasim MS, Haron CHC, Ghani JA, Hadi MA, Izamsha R, Anand TJS, Mohamed SB (2016) Cost evaluation on performance of a PVD coated cutting tool during end-milling of Inconel 718 under MQL conditions. Trans IMF 94(4):175–181
Metadaten
Titel
Metal cutting lubricants and cutting tools: a review on the performance improvement and sustainability assessment
verfasst von
Ali H. Abdelrazek
I. A. Choudhury
Yusoff Nukman
S. N. Kazi
Publikationsdatum
14.01.2020
Verlag
Springer London
Erschienen in
The International Journal of Advanced Manufacturing Technology / Ausgabe 9-10/2020
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI
https://doi.org/10.1007/s00170-019-04890-w

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