Old Version
AiM

Advances in Manufacturing >

2025 , Vol. 13 >Issue 1: 1 - 42

DOI: https://doi.org/10.1007/s40436-023-00477-7

Nanobiolubricant grinding: a comprehensive review

  • Yu-Xiang Song ,
  • Chang-He Li ,
  • Zong-Ming Zhou ,
  • Bo Liu ,
  • Shubham Sharma ,
  • Yusuf Suleiman Dambatta ,
  • Yan-Bin Zhang ,
  • Min Yang ,
  • Teng Gao ,
  • Ming-Zheng Liu ,
  • Xin Cui ,
  • Xiao-Ming Wang ,
  • Wen-Hao Xu ,
  • Run-Ze Li ,
  • Da-Zhong Wang
Expand
  • 1. School of Mechanical and Automotive Engineering, Qingdao University of Technology, Qingdao 266520, Shandong, People's Republic of China;
    2. Hanergy (Qingdao) Lubrication Technology Co., Ltd., Qingdao 266200, Shandong, People's Republic of China;
    3. Sichuan Future Aerospace Industry LLC., Shifang 618400, Sichuan, People's Republic of China;
    4. Department of Mechanical Engineering, IK Gujral Punjab Technical University, Punjab 144603, India;
    5. Mechanical Engineering Department, Ahmadu Bello University, Zaria, Nigeria;
    6. Department of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA;
    7. School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201620, People's Republic of China

Received date: 2023-07-25

  Revised date: 2023-09-19

  Online published: 2025-02-26

Supported by

This study was financially supported by the National Natural Science Foundation of China (Grant Nos. 52205481, 51975305, and 52105457), Shandong Natural Science Foundation (Grant Nos. ZR2020ME158, ZR2023QE057, ZR2022QE028, ZR2021QE116, ZR2020KE027, and ZR2022QE159), Qingdao Science and Technology Planning Park Cultivation Plan (Grant No. 23-1-5-yqpy-17-qy), and China Postdoctoral Science Foundation (Grant No. 2021M701810).

Fold

Abstract

Minimum quantity lubrication (MQL), which considers the cost, sustainability, flexibility, and quality, has been actively explored by scholars. Nanoadditive phases have been widely investigated as atomizing media for MQL, aimed at enhancing the heat transfer and friction reduction performance of vegetable-oil-based biolubricants. However, the industrial application of nano-enhanced biolubricants (NEBL) in grinding wheels and workpiece interfaces as a cooling and lubricating medium still faces serious challenges, which are attributed to the knowledge gap in the current mapping between the properties and grindability of NEBL. This paper presents a comprehensive literature review of research developments in NEBL grinding, highlighting the key challenges, and clarifies the application of blind spots. Firstly, the physicochemical properties of the NEBL are elaborated from the perspective of the base fluid and nanoadditive phase. Secondly, the excellent grinding performance of the NEBL is clarified by its distinctive film formation, heat transfer, and multiple-field mobilization capacity. Nanoparticles with high thermal conductivity and excellent extreme-pressure film-forming properties significantly improved the high-temperature and extreme-friction conditions in the grinding zone. Furthermore, the sustainability of applying small amounts of NEBL to grinding is systematically evaluated, providing valuable insights for the industry. Finally, perspectives are proposed to address the engineering and scientific bottlenecks of NEBL. This review aims to contribute to the understanding of the effective mechanisms of NEBL and the development of green grinding technologies.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-023-00477-7

Key words: Grinding; Minimum quantity lubrication (MQL); Nanobiolubricant; Physicochemical properties

Cite this article

Yu-Xiang Song , Chang-He Li , Zong-Ming Zhou , Bo Liu , Shubham Sharma , Yusuf Suleiman Dambatta , Yan-Bin Zhang , Min Yang , Teng Gao , Ming-Zheng Liu , Xin Cui , Xiao-Ming Wang , Wen-Hao Xu , Run-Ze Li , Da-Zhong Wang . Nanobiolubricant grinding: a comprehensive review[J]. Advances in Manufacturing, 2025 , 13(1) : 1 -42 . DOI: 10.1007/s40436-023-00477-7

References

[1] Krolczyk GM, Maruda RW, Krolczyk JB et al (2019) Ecological trends in machining as a key factor in sustainable production-a review. J Clean Prod 218:601-615
[2] Tripathi V, Chattopadhyaya S, Mukhopadhyay AK et al (2022) A sustainable methodology using lean and smart manufacturing for the cleaner production of shop floor management in Industry 4.0. Mathematics 10(3):347. https://doi.org/10.3390/math10030347
[3] Jha K, Tyagi YK, Kumar R et al (2021) Assessment of dimensional stability, biodegradability, and fracture energy of bio-composites reinforced with novel pine cone. Polymers 13(19):3260. https://doi.org/10.3390/math10030347
[4] Kim JH, Kim EJ, Lee CM (2020) A study on the heat affected zone and machining characteristics of difficult-to-cut materials in laser and induction assisted machining. J Manuf Process 57:499-508
[5] Pervaiz S, Ahmad N, Ishfaq K et al (2022) Implementation of sustainable vegetable-oil-based minimum quantity cooling lubrication (MQCL) machining of titanium alloy with coated tools. Lubricants 10(10):235. https://doi.org/10.3390/polym13193260
[6] Setti D, Arrabiyeh PA, Kirsch B et al (2020) Analytical and experimental investigations on the mechanisms of surface generation in micro grinding. Int J Mach Tool Manu 149:103489. https://doi.org/10.1016/j.ijmachtools.2019.103489
[7] Yu H, Zhang W, Zhang S et al (2022) Optimization of hydrodynamic properties of structured grinding wheels based on combinatorial bionics. Tribol Int 173:107651. https://doi.org/10.1016/j.triboint.2022.107651
[8] Wu X, Li C, Zhou Z et al (2021) Circulating purification of cutting fluid: an overview. Int J Adv Manuf Tech 117(9/10):2565-2600
[9] Leiden A, Arafat R, Callegari M et al (2023) Development and testing of novel mineral oil-and biocide-free glycerol-and propanediol-based fluids for drilling and tapping aluminium alloys. Int J Adv Manuf Tech 126(5/6):2323-2336
[10] Sharma AK, Tiwari AK, Dixit AR (2016) Effects of minimum quantity lubrication (MQL) in machining processes using conventional and nanofluid based cutting fluids: a comprehensive review. J Clean Prod 127:1-18
[11] Ghosh S, Rao PV (2015) Application of sustainable techniques in metal cutting for enhanced machinability: a review. J Clean Prod 100:17-34
[12] Sharma J, Sidhu BS (2014) Investigation of effects of dry and near dry machining on AISI D2 steel using vegetable oil. J Clean Prod 66:619-623
[13] Ding WF, Zhu YJ, Zhang LC et al (2015) Stress characteristics and fracture wear of brazed CBN grains in monolayer grinding wheels. Wear 332:800-809
[14] M’Saoubi R, Axinte D, Soo SL et al (2015) High performance cutting of advanced aerospace alloys and composite materials. CIRP Ann 64(2):557-580
[15] Barczak L, Batako A, Morgan M (2010) A study of plane surface grinding under minimum quantity lubrication (MQL) conditions. Int J Mach Tool Manu 50(11):977-985
[16] Hamran NN, Ghani J, Ramli R et al (2020) A review on recent development of minimum quantity lubrication for sustainable machining. J Clean Prod 268:122165. https://doi.org/10.1016/j.jclepro.2020.122165
[17] Makhesana M, Patel K, Mawandiya B (2021) Environmentally conscious machining of Inconel 718 with solid lubricant assisted minimum quantity lubrication. Met Powder Rep 76:S24-S29
[18] Zhou S, Wang D, Wu S et al (2023) Minimum quantity lubrication machining nickel base alloy: a comprehensive review. Int J Adv Manuf Tech. https://doi.org/10.1007/s00170-023-11721-6
[19] Sen B, Mia M, Krolczyk GM et al (2021) Eco-friendly cutting fluids in minimum quantity lubrication assisted machining: a review on the perception of sustainable manufacturing. Int J Pr Eng Man-Gt 8:249-280
[20] Abellan-Nebot JV, Rogero MO (2019) Sustainable machining of molds for tile industry by minimum quantity lubrication. J Clean Pro 240:118082. https://doi.org/10.1016/j.jclepro.2019.118082
[21] Hadad MJ, Tawakoli T, Sadeghi MH et al (2012) Temperature and energy partition in minimum quantity lubrication-MQL grinding process. Int J Mach Tool Manu 54:10-17
[22] Ghosh S, Rao P (2018) Specific cutting energy modeling for turning nickel-based nimonic 90 alloy under MQL condition. Int J Mech Sci 146:25-38
[23] de Souza RR, de Paiva RL, Gelamo RV et al (2021) Study on grinding of Inconel 625 and 718 alloys with cutting fluid enriched with multilayer graphene platelets. Wear 476:203697. https://doi.org/10.1016/j.wear.2021.203697
[24] Khanna N, Airao J, Nirala CK et al (2022) Novel sustainable cryo-lubrication strategies for reducing tool wear during ultrasonic-assisted turning of Inconel 718. Tribol Int 174:107728. https://doi.org/10.1016/j.triboint.2022.107728
[25] Liu M, Li C, Yang M et al (2023) Mechanism and enhanced grindability of cryogenic air combined with biolubricant grinding titanium alloy. Tribol Int 187:108704. https://doi.org/10.1016/j.triboint.2023.108704
[26] Arafat R, Madanchi N, Thiede S et al (2021) Supercritical carbon dioxide and minimum quantity lubrication in pendular surface grinding-a feasibility study. J Clean Prod 296:126560. https://doi.org/10.1016/j.est.2022.104906
[27] Ali Khan M, Jaffery SHI, Khan M et al (2019) Statistical analysis of energy consumption, tool wear and surface roughness in machining of titanium alloy (Ti-6Al-4V) under dry, wet and cryogenic conditions. Mech Sci 10(2):561-573
[28] Anqi AE, Li C, Dhahad HA et al (2022) Effect of combined air cooling and nano enhanced phase change materials on thermal management of lithium-ion batteries. J Energy Storage 52:104906. https://doi.org/10.1016/j.est.2022.104906
[29] Liu M, Li C, Zhang Y et al (2023) Analysis of grain tribology and improved grinding temperature model based on discrete heat source. Tribol Int 180:108196. https://doi.org/10.1016/j.triboint.2022.108196
[30] Gupta MK, Sood PK, Sharma VS (2016) Retraction notice to: optimization of machining parameters and cutting fluids during nano-fluid based minimum quantity lubrication turning of titanium alloy by using evolutionary techniques. J Clean Prod 135:1276-1288
[31] Xu W, Li C, Zhang Y et al (2022) Electrostatic atomization minimum quantity lubrication machining: from mechanism to application. Int J Extreme Manuf 4(4):042003. https://doi.org/10.1088/2631-7990/ac9652
[32] Alawi OA, Sidik NAC, Xian HW et al (2018) Thermal conductivity and viscosity models of metallic oxides nanofluids. Int J Heat Mass Tran 116:1314-1325
[33] Yalçın G, Öztuna S, Dalkılıç AS et al (2022) Measurement of thermal conductivity and viscosity of ZnO-SiO2 hybrid nanofluids. J Therm Anal Calorim 147:8243-8259
[34] Fayaz U, Manzoor S, Dar AH et al (2023) Advances of nanofluid in food processing: preparation, thermophysical properties, and applications. Food Res Int 170:112954. https://doi.org/10.1016/j.foodres.2023.112954
[35] Chinchanikar S, Kore SS, Hujare P (2021) A review on nanofluids in minimum quantity lubrication machining. J Manuf Process 68:56-70
[36] Hegab H, Kishawy HA (2018) Towards sustainable machining of Inconel 718 using nano-fluid minimum quantity lubrication. J Manuf Mater Proc 2(3):50. https://doi.org/10.3390/jmmp2030050
[37] Said Z, Gupta M, Hegab H et al (2019) A comprehensive review on minimum quantity lubrication (MQL) in machining processes using nano-cutting fluids. Int J Adv Manuf Tech 105:2057-2086
[38] Bai X, Jiang J, Li C et al (2023) Tribological performance of different concentrations of Al2O3 nanofluids on minimum quantity lubrication milling. Chin J Mech Eng-En 36(1):1-12
[39] Dambatta YS, Sayuti M, Sarhan AA et al (2019) Tribological performance of SiO2-based nanofluids in minimum quantity lubrication grinding of Si3N4 ceramic. J Manuf Process 41:135-147
[40] Jiang L, Wang D (2019) Finite-element-analysis of the effect of different wiper tool edge geometries during the hard turning of AISI 4340 steel. Simul Model Pract Theory 94:250-263
[41] Tang LZ, Zhang YB, Li CH et al (2022) Biological stability of water-based cutting fluids: progress and application. Chin J Mech Eng-En 35(1):3-27
[42] Mao C, Zhang J, Huang Y et al (2013) Investigation on the effect of nanofluid parameters on MQL grinding. J Manuf Process 28(4):436-442
[43] Najiha MS, Rahman MM, Yusoff AR (2016) Environmental impacts and hazards associated with metal working fluids and recent advances in the sustainable systems: a review. Renew Sust Energ Rev 60:1008-1031
[44] Zhang Y, Li HN, Li CH et al (2022) Nano-enhanced biolubricant in sustainable manufacturing: from processability to mechanisms. Friction 10(6):803-841
[45] Bagherzadeh A, Kuram E, Budak E (2021) Experimental evaluation of eco-friendly hybrid cooling methods in slot milling of titanium alloy. J Clean Prod 289:125817. https://doi.org/10.1016/j.jclepro.2021.125817
[46] Ruggiero A, D’Amato R, Merola M et al (2017) Tribological characterization of vegetal lubricants: comparative experimental investigation on Jatropha curcas L. oil, rapeseed methyl ester oil, hydrotreated rapeseed oil. Tribol Int 109:529-540
[47] Rozga P, Beroual A, Przybylek P et al (2020) A review on synthetic ester liquids for transformer applications. Energies 13(23):6429. https://doi.org/10.3390/en13236429
[48] Taha-Tijerina J, Ribeiro H, Aviña K et al (2020) Thermal conductivity performance of 2D h-BN/MoS2/-hybrid nanostructures used on natural and synthetic esters. Nanomaterials 10(6):1160. https://doi.org/10.3390/nano10061160
[49] Gryglewicz S, Piechocki W, Gryglewicz G (2003) Preparation of polyol esters based on vegetable and animal fats. Bioresource Technol 87(1):35-39
[50] Dodos GS, Karonis D, Zannikos F et al (2015) Renewable fuels and lubricants from Lunaria annua L. Ind Crop Prod 75:43-50
[51] Wang B, Tao Dh (2005) Rheological and tribological characteristics of the synthesized lubricants derived from vegetable oils. J Shanghai Univ (Eng Ed) 9:462-465
[52] Wang Y, Li C, Zhang Y et al (2016) Experimental evaluation of the lubrication properties of the wheel/workpiece interface in MQL grinding with different nanofluids. Tribol Int 99:198-210
[53] Soltani ME, Shams K, Akbarzadeh S et al (2020) A comparative investigation on the tribological performance and physicochemical properties of biolubricants of various sources, a petroleum-based lubricant, and blends of the petroleum-based lubricant and crambe oil. Tribol Int 63(6):1121-1134
[54] Talib N, Rahim EA (2018) Experimental evaluation of physicochemical properties and tapping torque of hexagonal boron nitride in modified jatropha oils-based as sustainable metalworking fluids. J Clean Prod 171:743-755
[55] Padmini R, Krishna PV, Rao GKM (2016) Effectiveness of vegetable oil based nanofluids as potential cutting fluids in turning AISI 1040 steel. Tribol Int 94:490-501
[56] Zhang YB, Li CH, Jia DZ et al (2015) Experimental evaluation of MoS2 nanoparticles in jet MQL grinding with different types of vegetable oil as base oil. J Clean Prod 87:930-940
[57] Yin QG, Li CH, Dong L et al (2021) Effects of physicochemical properties of different base oils on friction coefficient and surface roughness in MQL milling AISI 1045. Int J Pr Eng Man-Gt 8(6):1629-1647
[58] Borda FLG, de Oliveira SJR, Lazaro L et al (2018) Experimental investigation of the tribological behavior of lubricants with additive containing copper nanoparticles. Tribol Int 117:52-58
[59] Erhan SZ, Sharma BK, Perez JM (2006) Oxidation and low temperature stability of vegetable oil-based lubricants. Ind Crop Prod 24(3):292-299
[60] Yang M, Li C, Zhang Y et al (2018) A new model for predicting neurosurgery skull bone grinding temperature field. J Mech Eng 54(23):215-222
[61] Quinchia LA, Delgado MA, Franco JM et al (2012) Low-temperature flow behaviour of vegetable oil-based lubricants. Ind Crop Prod 3(1):383-388
[62] Bahari A, Lewis R, Slatter T (2018) Friction and wear phenomena of vegetable oil-based lubricants with additives at severe sliding wear conditions. Tribol Int 61(2):207-219
[63] Zhang YB, Li CH, Jia DZ et al (2016) Experimental study on the effect of nanoparticle concentration on the lubricating property of nanofluids for MQL grinding of Ni-based alloy. J Mater Process Tech 232:100-115
[64] Sajeeb A, Rajendrakumar PK (2019) Comparative evaluation of lubricant properties of biodegradable blend of coconut and mustard oil. J Clean Prod 240:118255. https://doi.org/10.1016/j.jclepro.2019.118255
[65] Jia DZ, Li CH, Zhang YB et al (2017) Performance evaluation of grinding ductile iron under nanofluids minimum quantity lubrication. Int J Mach Tool Manu 12:40-43
[66] Ozcelik B, Kuram E, Cetin MH et al (2011) Experimental investigations of vegetable based cutting fluids with extreme pressure during turning of AISI 304L. Tribol Int 44(12):1864-1871
[67] Sani ASA, Abd Rahim E, Sharif S et al (2019) Machining performance of vegetable oil with phosphonium- and ammonium-based ionic liquids via MQL technique. J Clean Prod 209:947-964
[68] Pal A, Chatha SS, Singh K (2020) Performance evaluation of minimum quantity lubrication technique in grinding of AISI 202 stainless steel using nano-MoS(2)with vegetable-based cutting fluid. Int J Adv Manuf Tech 110(1/2):125-137
[69] Shahnazar S, Bagheri S, Abd Hamid SB (2016) Enhancing lubricant properties by nanoparticle additives. Int J Hydrogen Energ 41(4):3153-3170
[70] Soares JW, Whitten JE, Oblas DW et al (2008) Novel photoluminescence properties of surface-modified nanocrystalline zinc oxide: toward a reactive scaffold. Langmuir 24(2):371-374
[71] Tang E, Cheng G, Ma X et al (2006) Surface modification of zinc oxide nanoparticle by PMAA and its dispersion in aqueous system. Appl Surf Sci 252(14):5227-5232
[72] Köhn C, Arafat R, Jean-Fulcrand A et al (2022) Surface interactions of SiO2-nanofluids with 100Cr6-steel during machining. Procedia CIRP 108:13-18
[73] Arafat R, Köhn C, Jean-Fulcrand A et al (2023) Physical-chemical properties and tribological characterization of water-glycerine based metal oxide nanofluids. J Mater Res Technol 25:2112-2126
[74] Cui X, Li CH, Ding WF et al (2022) Minimum quantity lubrication machining of aeronautical materials using carbon group nanolubricant: from mechanisms to application. Chin J Aeronaut 35(11):85-112
[75] Bai MJ, Liu JL, He J et al (2020) Heat transfer and mechanical friction reduction properties of graphene oxide nanofluids. Diam Relat Mater 108:107982. https://doi.org/10.1016/j.diamond.2020.107982
[76] Padgurskas J, Rukuiza R, Prosycevas I et al (2013) Tribological properties of lubricant additives of Fe, Cu and Co nanoparticles. Tribol Int 60:224-232
[77] Jamil M, Khan AM, Hegab H et al (2019) Effects of hybrid Al2O3-CNT nanofluids and cryogenic cooling on machining of Ti-6Al-4V. Int J Adv Manuf Tech 102:3895-3909
[78] Souza RR, Faustino V, Goncalves IM et al (2022) A review of the advances and challenges in measuring the thermal conductivity of nanofluids. Nanomaterials 12(15):2526. https://doi.org/10.3390/nano12152526
[79] Ali HM, Babar H, Shah TR et al (2018) Preparation techniques of TiO2 nanofluids and challenges: a review. Appl Sci-Basel 8(4):587-617
[80] Sandhya SU, Nityananda SA (2013) A facile one step solution route to synthesize cuprous oxide nanofluid. Nanomater Nanotechno 3:5-12
[81] Yucel A, Yildirim CV, Sarikaya M et al (2021) Influence of MoS2 based nanofluid-MQL on tribological and machining characteristics in turning of AA 2024 T3 aluminum alloy. J Mater Res Technol 15:1688-1704
[82] Bakthavatchalam B, Habib K, Saidur R et al (2020) Comprehensive study on nanofluid and ionanofluid for heat transfer enhancement: a review on current and future perspective. J Mol Liq 305:112787. https://doi.org/10.1016/j.molliq.2020.112787
[83] Sidik NAC, Mohammed HA, Alawi OA et al (2014) A review on preparation methods and challenges of nanofluids. Int Commun Heat Mass 54:115-125
[84] Duan ZJ, Yin QG, Li CH et al (2020) Milling force and surface morphology of 45 steel under different Al2O3 nanofluid concentrations. Int J Adv Manuf Tech 107(3/4):1277-1296
[85] Gupta M, Singh V, Kumar S et al (2018) Up to date review on the synthesis and thermophysical properties of hybrid nanofluids. J Clean Prod 190:169-192
[86] Huang BT, Li CH, Zhang YB et al (2021) Advances in fabrication of ceramic corundum abrasives based on sol-gel process. Chin J Aeronaut 34(6):1-17
[87] Kim HJ, Bang IC, Onoe J (2009) Characteristic stability of bare Au-water nanofluids fabricated by pulsed laser ablation in liquids. Opt Laser Eng 47(5):532-538
[88] Sidik NAC, Jamil MM, Japar W et al (2017) A review on preparation methods, stability and applications of hybrid nanofluids. Renew Sust Energ Rev 80:1112-1122
[89] Vignesh S, Iqbal UM (2022) Preparation and characterization of bio-based nano cutting fluids for tribological applications. J Disper Sci Technol 44(9):1725-1737
[90] Li X, Zhu D, Wang X (2007) Evaluation on dispersion behavior of the aqueous copper nano-suspensions. J Colloid Interf Sci 310(2):456-463
[91] Navarrete N, Nithiyanantham U, Hernandez L et al (2022) K2CO3-Li2CO3 molten carbonate mixtures and their nanofluids for thermal energy storage: an overview of the literature. Sol Energ Mat Sol C 236:111525. https://doi.org/10.1016/j.solmat.2021.111525
[92] Sharif MZ, Azmi WH, Ghazali MF et al (2023) Numerical and thermo-energy analysis of cycling in automotive air-conditioning operating with hybrid nanolubricants and R1234yf. Numer Heat Tr A-Appl 83(9):935-957
[93] Kalita P, Malshe AP, Rajurkar KP (2012) Study of tribo-chemical lubricant film formation during application of nanolubricants in minimum quantity lubrication (MQL) grinding. CIRP Ann 61(1):327-330
[94] Sadeghi R, Etemad SG, Keshavarzi E et al (2015) Investigation of alumina nanofluid stability by UV-vis spectrum. Microfluid Nanofluid 18(5-6):1023-1030
[95] Izadi N, Koochi MM, Amrollahi A (2019) Investigation of functionalized polyelectrolyte polymer-coated Fe3O4 nanoparticles stabilized in high salinity brine at high temperatures as an EOR agent. J Petrol Sci Eng 178:1079-1091
[96] Yang CD, Feng JM, Liu ZQ et al (2023) Lubricant-entrenched slippery surface-based nanocarriers to avoid macrophage uptake and improve drug utilization. J Adv Res 48:61-74
[97] Kole M, Khandekar S (2021) Engineering applications of ferrofluids: a review. J Magn Magn Mater 537:1168222. https://doi.org/10.1016/j.jmmm.2021.168222
[98] Song YY, Bhadeshia H, Suh DW (2015) Stability of stainless-steel nanoparticle and water mixtures. Powder Technol 272:34-44
[99] Aydin DY, Ciftci E, Guru M et al (2021) The impacts of nanoparticle concentration and surfactant type on thermal performance of a thermosyphon heat pipe working with bauxite nanofluid. Energ Source Part A 43(12):1524-1548
[100] Mao C, Zou HF, Zhou X et al (2014) Analysis of suspension stability for nanofluid applied in minimum quantity lubricant grinding. Int J Adv Manuf Tech 71(9/12):2073-2081
[101] Gao T, Li CH, Zhang YB et al (2019) Dispersing mechanism and tribological performance of vegetable oil-based CNT nanofluids with different surfactants. Tribol Int 131:51-63
[102] Zhou MZ, Xia GD, Li J et al (2012) Analysis of factors influencing thermal conductivity and viscosity in different kinds of surfactant solutions. Exp Therm Fluid Sci 36:22-29
[103] Khairul MA, Shah K, Doroodchi E et al (2016) Effects of surfactant on stability and thermo-physical properties of metal oxide nanofluids. Int J Heat Mass Tran 98:778-787
[104] Cacua K, Ordonez F, Zapata C et al (2019) Surfactant concentration and pH effects on the zeta potential values of alumina nanofluids to inspect stability. Colloid Surface A 583:123960. https://doi.org/10.1016/j.colsurfa.2019.123960
[105] Ghadimi A, Metselaar IH (2013) The influence of surfactant and ultrasonic processing on improvement of stability, thermal conductivity and viscosity of titania nanofluid. Exp Therm Fluid Sci 51:1-9
[106] Jain S, Dongave SM, Date T et al (2019) Succinylated β-lactoglobuline-functionalized multiwalled carbon nanotubes with improved colloidal stability and biocompatibility. ACS Biomater Sci Eng 5(7):3361-3372
[107] Chakraborty S, Sengupta I, Sarkar I et al (2019) Effect of surfactant on thermo-physical properties and spray cooling heat transfer performance of Cu-Zn-Al LDH nanofluid. Appl Clay Sci 168:43-55
[108] Wang J, Li GL, Li T et al (2021) Effect of various surfactants on stability and thermophysical properties of nanofluids. J Therm Anal Calorim 143(6):4057-4070
[109] Amrita M, Kamesh B, Srikant RR et al (2019) Thermal enhancement of graphene dispersed emulsifier cutting fluid with different surfactants. Mater Res Express 6(12):125030. https://doi.org/10.1088/2053-1591/ab5517
[110] Wang BG, Wang XB, Lou WJ et al (2012) Thermal conductivity and rheological properties of graphite/oil nanofluids. Colloid Surface A 414:125-131
[111] Saeedinia M, Akhavan-Behabadi MA, Razi P (2012) Thermal and rheological characteristics of CuO-base oil nanofluid flow inside a circular tube. Int Commun Heat Mass 39(1):152-159
[112] Sandhya M, Ramasamy D, Sudhakar K et al (2021) A systematic review on graphene-based nanofluids application in renewable energy systems: preparation, characterization, and thermophysical properties. Sustain Energy Techn 44:101058. https://doi.org/10.1016/j.seta.2021.101058
[113] Sen S, Moazzen E, Acuna S et al (2022) Nickel hydroxide nanofluid cathodes with high solid loadings and low viscosity for energy storage applications. Energies 15(13):4728. https://doi.org/10.3390/en15134728
[114] Jeong J, Li C, Kwon Y et al (2013) Particle shape effect on the viscosity and thermal conductivity of ZnO nanofluids. Int J Refrig 36(8):2233-2241
[115] Mashaei PR, Taheri-Ghazvini M, Moghadam RS et al (2017) Smart role of Al2O3-water suspension on laminar heat transfer in entrance region of a channel with transverse in-line baffles. Appl Therm Eng 112:450-463
[116] Hamid KA, Azmi WH, Nabil MF et al (2018) Experimental investigation of thermal conductivity and dynamic viscosity on nanoparticle mixture ratios of TiO2-SiO2 nanofluids. Int J Heat Mass Tran 116:1143-1152
[117] 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 Tech 92(1/4):371-391
[118] Yang M, Li CH, Zhang YB et al (2018) Microscale bone grinding temperature by dynamic heat flux in nanoparticle jet mist cooling with different particle sizes. Mater Manuf Process 33(1):58-68
[119] Maheshwary PB, Handa CC, Nernade KR (2017) A comprehensive study of effect of concentration, particle size and particle shape on thermal conductivity of titania/water based nanofluid. Appl Therm Eng 119:79-88
[120] Sun CZ, Bai BF, Lu WQ et al (2013) Shear-rate dependent effective thermal conductivity of H2O+SiO2 nanofluids. Phys Fluids 25(5):052002. https://doi.org/10.1063/1.4802049
Options
Outlines

/

Copyright © Advances in Manufacturing
Address:P. O. Box 124, Shanghai University, 99 Shangda Road, Shanghai 200444, China

Tel: 86-21-66135510  Fax: 86-21-66132736  E-mail: aim@oa.shu.edu.cn