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Tribology Letters

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01.06.2021 | Original Paper

Improved Load-Bearing Capacity and Tribological Properties of PTFE Coatings Induced by Surface Texturing and the Addition of GO

verfasst von: Zeda Chen, Zhibin Wu, Jianfang Sun, Chuan Mao, Fenghua Su

Erschienen in: Tribology Letters | Ausgabe 2/2021

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Abstract

The PTFE coatings with excellent corrosion-resistance and lubrication properties often stop functioning under high load conditions. In this study, a composite coating of PTFE filled with silane coupling agent modified graphene oxide (mGO/PTFE) was prepared by a simple spin-coating process on textured stainless steel (SS) substrate to protect the substrate from failure under high load rubbing. The grafting reaction between GO and silane coupling agent was analyzed by FTIR, Raman, XRD, TGA, and XPS. The morphologies and tribological properties of the mGO/PTFE coatings on the untextured and textured SS substrates were characterized by SEM and UMT tribometer. The results showed that GO surfaces were successfully grafted by silane coupling agent, resulting in that the composite coating of mGO/PTFE was denser than the pure PTFE coating. The tribo-test results confirmed that the groove texture processed by laser surface texture technology greatly improved the load-bearing capacity and anti-wear life of the PTFE coatings. The PTFE coating on the untextured SS surface fails within half an hour of rubbing at the applied load of 10 N, while the one on the groove-textured surface can maintain low and stable friction coefficient for a long time even under the load of 50 N. In addition, the results showed that the loading of mGO further improve the friction reduction and wear resistance of the PTFE coating on the textured SS surface. The wear scar width and the friction coefficient are significantly reduced by 70% and 30%, respectively, as the PTFE coating was filled by 1.0 wt% mGO. Finally, the mechanisms for achieving outstanding properties of the composite coating of mGO/PTFE on the textured SS surface were illustrated by analyzing the wear surfaces of the coating and the counterpart balls by SEM and EDS.

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Vorheriger Artikel Investigation of the Tribological Performances of Graphene and WS2 Nanosheets as Additives for Perfluoroalkylpolyethers Under Simulated Space Environment

Nächster Artikel On the Effect of Shear Loading Rate on Contact Area Shrinking in Adhesive Soft Contacts

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Baddoo, N.R.: Stainless steel in construction: a review of research, applications, challenges and opportunities. J Constr. Steel Res. 64, 1199–1206 (2008)

Nip, K.H., Gardner, L., Davies, C.M., Elghazouli, A.Y.: Extremely low cycle fatigue tests on structural carbon steel and stainless steel. J. Constr. Steel Res. 66, 96–110 (2010)

Li, L.X., Liu, S., Yee, B., Hu, S.D., Zhou, Z.F.: Quantitative analysis of strength and plasticity of a 304 stainless steel based on the stress-strain curve. Met. Mater. Int. 22, 391–396 (2016)

Dalmau, A., Richard, C., Igual-Munoz, A.: Degradation mechanisms in martensitic stainless steels: wear, corrosion and tribocorrosion appraisal. Tribol. Int. 121, 167–179 (2018)

Ardila, M.A.N., Labiapari, W.S., Costa, H.L., de Mello, J.D.B.: Influence of stainless steel specimen topography on micro-abrasion and micro-abrasion-corrosion. Wear 426, 1482–1495 (2019)

She, Z.X., Li, Q., Wang, Z.W., Li, L.Q., Chen, F.A., Zhou, J.C.: Researching the fabrication of anticorrosion superhydrophobic surface on magnesium alloy and its mechanical stability and durability. Chem. Eng. J. 228, 415–424 (2013)

Wang, N., Xiong, D.S., Deng, Y.L., Shi, Y., Wang, K.: Mechanically robust superhydrophobic steel surface with anti-icing, UV-durability, and corrosion resistance properties. ACS Appl. Mater. Interfaces 7, 6260–6272 (2015)

Asri, R.I.M., Harun, W.S.W., Samykano, M., Lah, N.A.C., Ghani, S.A.C., Tarlochan, F., et al.: Corrosion and surface modification on biocompatible metals: a review. Mater. Sci. Eng. C Mater. Biol. Appl. 77, 1261–1274 (2017)

Groche, P., Kleemann, A., Kohler, S.: Surface pre-treatment and its influence on electric functionality and the formability of screen printed steel sheet. Prod. Eng. Res. Dev. 12, 789–795 (2018)

10.

Major, L., Lackner, J.M., Kot, M., Major, B.: Bio-tribological properties and microstructure characterization of the polytetrafluorethylene (PTFE) coatings on polyaryletheretherketone (PEEK) substrate. Tribol. Int. 104, 309–320 (2016)

11.

Wan, Y., Yu, Y., Cao, L., Zhang, M., Gao, J., Qi, C.: Corrosion and tribological performance of PTFE-coated electroless nickel boron coatings. Surf. Coat. Technol. 307, 316–323 (2016)

12.

Feng, S.S., Zhong, Z.X., Wang, Y., Xing, W.H., Drioli, E.: Progress and perspectives in PTFE membrane: preparation, modification, and applications. J. Membr. Sci. 549, 332–349 (2018)

13.

Li, B., Jiang, X.F., Wan, H.Q., Chen, L., Ye, Y.P., Zhou, H.D., et al.: Fabrication and tribological behaviors of a novel environmental friendly water-based PAI-PTFE-LaF3 bonded solid lubricating composite coating. Tribol. Int. 121, 400–409 (2018)

14.

Liang, Y.Y., Ju, J.G., Deng, N.P., Zhou, X.H., Yan, J., Kang, W.M., et al.: Super-hydrophobic self-cleaning bead-like SiO₂@PTFE nanofiber membranes for waterproof-breathable applications. Appl. Surf. Sci. 442, 54–64 (2018)

15.

Pan, D., Fan, B.L., Qi, X.W., Yang, Y.L., Hao, X.H.: Investigation of PTFE tribological properties using molecular dynamics simulation. Tribol. Lett. 67, 28 (2019)

16.

Miller, C., Choudhury, D., Zou, M.: The Effects of surface roughness on the durability of polydopamine/PTFE solid lubricant coatings on NiTiNOL 60. Tribol. Trans. 62, 919–929 (2019)

17.

Lu, C., Feng, X.C., Yang, J.J., Jia, J.H., Yi, G.W., Xie, E.Q., et al.: Influence of surface microstructure on tribological properties of PEO-PTFE coating formed on aluminum alloy. Surf. Coat. Technol. 364, 127–134 (2019)

18.

Choudhury, D., Niyonshuti, I.I., Chen, J.Y., Goss, J.A., Zou, M.: Tribological performance of polydopamine plus Ag nanoparticles/PTFE thin films. Tribol Int 144, 106097 (2020)

19.

Choudhury, D., Miller, C., Zou, M.: Tribological performance of PDA/PTFE + graphite particle coatings on 60NiTi. Appl. Surf. Sci. 527, 146731 (2020)

20.

Peng, S.G., Guo, Y., Xie, G.X., Luo, J.B.: Tribological behavior of polytetrafluoroethylene coating reinforced with black phosphorus nanoparticles. Appl. Surf. Sci. 441, 670–677 (2018)

21.

Li, J.B., Liu, S., Yu, A.B., Xiang, S.T.: Effect of laser surface texture on CuSn₆ bronze sliding against PTFE material under dry friction. Tribol. Int. 118, 37–45 (2018)

22.

Rosenkranz, A., Costa, H.L., Baykara, M.Z., Martini, A.: Synergetic effects of surface texturing and solid lubricants to tailor friction and wear—a review. Tribol Int 155, 106792 (2021)

23.

Gujba, A.K., Medraj, M.: Laser peening process and its impact on materials properties in comparison with shot peening and ultrasonic impact peening. Materials 7, 7925–7974 (2014)

24.

Zheng, L., Zhang, C.W., Zhang, C., Dai, F.Z.: Performance of micro-dent array fabricated by laser shock peening on the surface of A304 stainless steel. Vacuum 138, 93–100 (2017)

25.

Bocharov, G.S., Dedov, A.V., Eletskii, A.V., Zaharenkov, A.V., Zilova, O.S., Nuha, A., et al.: Laser strengthening of a steel surface with fullerene coating. Dokl. Phys. 63, 489–492 (2018)

26.

Braun, D., Greiner, C., Schneider, J., Gumbsch, P.: Efficiency of laser surface texturing in the reduction of friction under mixed lubrication. Tribol. Int. 77, 142–147 (2014)

27.

Gachot, C., Rosenkranz, A., Hsu, S.M., Costa, H.L.: A critical assessment of surface texturing for friction and wear improvement. Wear 372, 21–41 (2017)

28.

Zhan, X., Yi, P., Liu, Y., Xiao, P., Zhu, X., Ma, J.: Effects of single- and multi-shape laser-textured surfaces on tribological properties under dry friction. Proc. Inst. Mech. Eng. C J. Mech. Eng. Sci. 234, 1382–1392 (2019)

29.

Arslan, A., Masjuki, H.H., Kalam, M.A., Varman, M., Mufti, R.A., Mosarof, M.H., et al.: Surface texture manufacturing techniques and tribological effect of surface texturing on cutting tool performance: a review. Crit. Rev. Solid State Mater. Sci. 41, 447–481 (2016)

30.

Zhang, N., Yang, F.Z., Jiang, F.L., Liu, G.H.: Study of the effect of surface laser texture on tribological properties of cemented carbide materials. Proc. Inst. Mech. Eng. B J. Eng. 234, 993–1006 (2020)

31.

Xu, Y.F., Yu, J.Y., Geng, J., Abuflaha, R., Olson, D., Hu, X.G., et al.: Characterization of the tribological behavior of the textured steel surfaces fabricated by photolithographic etching. Tribol Lett 66, 55 (2018)

32.

Ye, J.X., Zhang, K.S., Gao, T.Y., Zhang, Y.F., Liu, X.J., Liu, K.: Self-competing and coupled effect of laser-engraved counterface groove depth and density on wear of alumina PTFE. Tribol. Lett. 67, 56 (2019)

33.

Ding, L., Axinte, D., Butler-Smith, P., Hassan, A.A.: Study on the characterisation of the PTFE transfer film and the dimensional designing of surface texturing in a dry-lubricated bearing system. Wear 448, 203238 (2020)

34.

Kolhe, S., Deshpande, A., Wangikar, K.: Wear behavior of polytetrafluoroethylene composites: a review. Smart Technol. Energy Environ. Sustain. Dev (2019). https://doi.org/10.1007/978-981-13-6148-7_55CrossRef

35.

Ye, J., Moore, A.C., Burris, D.L.: Transfer film tenacity: a case study using ultra-low-wear alumina—PTFE. Tribol. Lett. 59, 50 (2015)

36.

Pitenis, A.A., Harris, K.L., Junk, C.P., Blackman, G.S., Sawyer, W.G., Krick, B.A.: Ultralow wear PTFE and alumina composites: it is all about tribochemistry. Tribol. Lett. 57, 4 (2015)

37.

Beckford, S., Cai, J., Fleming, R.A., Zou, M.: The effects of graphite filler on the tribological properties of polydopamine/PTFE coatings. Tribol. Lett. 64, 42 (2016)

38.

Ye, J., Burris, D., Xie, T.: A review of transfer films and their role in ultra-low-wear sliding of polymers. Lubricants 4, 4 (2016)

39.

Qu, M., Yao, Y., He, J., Ma, X., Feng, J., Liu, S., et al.: Tribological study of polytetrafluoroethylene lubricant additives filled with Cu microparticles or SiO₂ nanoparticles. Tribol. Int. 110, 57–65 (2017)

40.

Yu, C., Wan, H., Chen, L., et al.: Marvelous abilities for polyhedral oligomeric silsesquioxane to improve tribological properties of polyamide-imide/polytetrafluoroethylene coatings. J. Mater. Sci. 53, 12616–12627 (2018)

41.

Kandanur, S.S., Rafiee, M.A., Yavari, F., Schrameyer, M., Yu, Z.Z., Blanchet, T.A., et al.: Suppression of wear in graphene polymer composites. Carbon 50, 3178–3183 (2012)

42.

Fan, K., Chen, X., Wang, X., Liu, X., Liu, Y., Lai, W., et al.: Toward excellent tribological performance as oil-based lubricant additive: particular tribological behavior of fluorinated graphene. ACS Appl. Mater. Interfaces 10, 28828–28838 (2018)

43.

Zhao, F.Y., Zhang, L.G., Li, G.T., Guo, Y.X., Qi, H.M., Zhang, G.: Significantly enhancing tribological performance of epoxy by filling with ionic liquid functionalized graphene oxide. Carbon 136, 309–319 (2018)

44.

Yuan, J.Y., Zhang, Z.Z., Yang, M.M., Li, P.L., Men, X.H., Liu, W.M.: Graphene oxide-grafted hybrid-fabric composites with simultaneously improved mechanical and tribological properties. Tribol. Lett. 66, 28 (2018)

45.

Zhao, B., Bai, T.: Improving the tribological performance of epoxy coatings by the synergistic effect between dehydrated ethylenediamine modified graphene and polytetrafluoroethylene. Carbon 144, 481–491 (2019)

46.

Zhao, L., Yang, H.M., Liu, C., Xue, S.Q., Deng, Z., Li, J.S., et al.: The correlation between molecular structure and tribological properties of graphene oxide with different oxidation degree. Tribol. Lett. 67, 85 (2019)

47.

Bandeira, P., Monteiro, J., Baptista, A.M., Magalhaes, F.D.: Influence of oxidized graphene nanoplatelets and [DMIM][NTf2] ionic liquid on the tribological performance of an epoxy-PTFE coating. Tribol. Int. 97, 478–489 (2016)

48.

Chen, X.M., Shaw, C., Gelman, L., Grattan, K.T.V.: Advances in test and measurement of the interface adhesion and bond strengths in coating-substrate systems, emphasising blister and bulk techniques. Measurement 139, 387–402 (2019)

49.

Hu, C., Liu, Y., Yang, Y., Cui, J., Huang, Z., Wang, Y., et al.: One-step preparation of nitrogen-doped graphene quantum dots from oxidized debris of graphene oxide. J. Mater. Chem. B 1, 39–42 (2013)

50.

Paz, E., Ballesteros, Y., Forriol, F., Dunne, N.J., Del Real, J.C.: Graphene and graphene oxide functionalisation with silanes for advanced dispersion and reinforcement of PMMA-based bone cements. Mater. Sci. Eng. C Mater. Biol. Appl. 104, 109946 (2019)

51.

Stobinski, L., Lesiak, B., Malolepszy, A., Mazurkiewicz, M., Mierzwa, B., Zemek, J., et al.: Graphene oxide and reduced graphene oxide studied by the XRD, TEM and electron spectroscopy methods. J. Electron. Spectrosc. Relat. Phenom. 195, 145–154 (2014)

52.

Choi, E.Y., Han, T.H., Hong, J.H., Kim, J.E., Lee, S.H., Kim, H.W., et al.: Noncovalent functionalization of graphene with end-functional polymers. J. Mater. Chem. 20, 1907–1912 (2010)

53.

Hu, X.H., Ma, X.H., Tan, H.P., Li, D.: Preparation of water-soluble and biocompatible graphene. Micro Nano Lett. 8, 277–279 (2013)

54.

Wan, Y.J., Gong, L.X., Tang, L.C., Wu, L.B., Jiang, J.X.: Mechanical properties of epoxy composites filled with silane-functionalized graphene oxide. Compos. Pt A Appl. Sci. Manuf. 64, 79–89 (2014)

55.

Ma, P.C., Kim, J.K., Tang, B.Z.: Functionalization of carbon nanotubes using a silane coupling agent. Carbon 44, 3232–3238 (2006)

56.

Al-Gaashani, R., Najjar, A., Zakaria, Y., Mansour, S., Atieh, M.A.: XPS and structural studies of high quality graphene oxide and reduced graphene oxide prepared by different chemical oxidation methods. Ceram. Int. 45, 14439–14448 (2019)

57.

Meng, Y., Su, F., Chen, Y.: Supercritical fluid synthesis and tribological applications of silver nanoparticle-decorated graphene in engine oil nanofluid. Sci. Rep. 6, 31246 (2016)

58.

Treossi, E., Melucci, M., Liscio, A., Gazzano, M., Samori, P., Palermo, V.: High-contrast visualization of graphene oxide on dye-sensitized glass, quartz, and silicon by fluorescence quenching. J. Am. Chem. Soc. 131, 15576–15577 (2009)

59.

Sarno, M., Scarpa, D., Senatore, A., Ahmed Abdalglil Mustafa, W.: rGO/GO nanosheets in tribology: from the state of the art to the future prospective. Lubricants 8(3), 31 (2020)

60.

Gong, X.Y., Liu, Y.Y., Wang, Y.S., Xie, Z.M., Dong, Q.L., Dong, M.Y., et al.: Amino graphene oxide/dopamine modified aramid fibers: preparation, epoxy nanocomposites and property analysis. Polymer 168, 131–137 (2019)

61.

Ye, J., Khare, H.S., Burris, D.L.: Transfer film evolution and its role in promoting ultra-low wear of a PTFE nanocomposite. Wear 297, 1095–1102 (2013)

62.

Uruena, J.M., Pitenis, A.A., Harris, K.L., Sawyer, W.G.: Evolution and wear of fluoropolymer transfer films. Tribol. Lett. 57, 9 (2015)

Titel: Improved Load-Bearing Capacity and Tribological Properties of PTFE Coatings Induced by Surface Texturing and the Addition of GO
verfasst von: Zeda Chen
Zhibin Wu
Jianfang Sun
Chuan Mao
Fenghua Su
Publikationsdatum: 01.06.2021
Verlag: Springer US
Erschienen in: Tribology Letters / Ausgabe 2/2021
Print ISSN: 1023-8883
Elektronische ISSN: 1573-2711
DOI: https://doi.org/10.1007/s11249-021-01424-y

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