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Journal of Coatings Technology and Research

Erschienen in:

20.04.2022

Pigmented silicone/epoxy novel blends for preparation of stratified nontoxic foul release coatings

verfasst von: Sushil S. Pawar, R. Baloji Naik, Sangram K. Rath, T. K. Mahato, Balasubramanian Kandasubramanian

Erschienen in: Journal of Coatings Technology and Research | Ausgabe 4/2022

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Abstract

Incompatible polymer blends of epoxy and silicone were used for the preparation of single-coating system having anticorrosive and foul release properties by self-stratifying process. The single-coat application consists of a fixed 20 pigment volume concentration (PVC) anticorrosive bottom coat based on epoxy with a mixture of pigments like iron oxide, barytes, and zinc phosphate, and a fixed 10 PVC hydrophobic topcoat consisting of silicone resin and titanium dioxide pigment. Both the coatings were prepared separately in triple role and ball mill, respectively. Three different coating compositions were prepared by mixing silicone and epoxy coatings in different weight ratios (70:30, 80:20, and 90:10). Required amount of hardener, crosslinker, and catalyst were added to these prepared compositions separately prior to application and were thoroughly mixed and applied on mild steel and glass specimens. The prepared stratified coatings were named as STR-1, STR-2, and STR-3. The formation of self-stratification was confirmed by optical microscopy, FE-SEM, FTIR spectroscopy, and contact angle measurement. The coating systems were evaluated for adhesion, tensile strength, corrosion resistance, pseudobarnacle adhesion properties, and accumulation of foulant studies by immersion of test coupons in seawater. It is confirmed that there exists a most favorable stratified coating composition in terms of silicone and epoxy weight ratios which showed performance enhancement in terms of the hydrophobicity and foul release properties compared to other coating compositions.

Graphical abstract

Vorheriger Artikel Barrier and mechanical properties of water-based polyurethane-coated hydroentangled cotton nonwovens

Nächster Artikel Validation of adhesion characterization methods for antistick coatings applied in cooking systems

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Sarkar, PK, Kandasubramanian, B, “Metals to polymer composites for submerged hull: a paradigm shift.” Polym. Technol. Mater., 60 (16) 1785 (2021)

Sarkar, P, Kandasubramanian, B, “Fluorine-free superhydrophobic characterized coatings: a mini review.” Marit. Technol. Res., 3 (4) 365 (2021)CrossRef

Bangar, GY, Ghule, D, Singh, RKP, Kandasubramanian, B, “Thermally triggered transition of fluid atomized micro- and nanotextured multiscale rough surfaces.” Colloids Surf. A Physicochem. Eng. Asp., 549 212 (2018)CrossRef

Korde, JM, Sreekumar, AV, Kandasubramanian, B, “Corrosion inhibition of 316L-type stainless steel under marine environments using epoxy/waste plastic soot coatings.” Appl. Sci.,. https://doi.org/10.1007/s42452-020-3096-2 (2020)CrossRef

SharmaGoreKandasubramanian, APMB, “Reduction of carbon dioxide (CO₂) using ‘p’ & ‘d’ block electro-catalysts: a review.” J. Environ. Chem. Eng., 9 (1) 104798 (2021)CrossRef

Gore, PM, Gawali, P, Naebe, M, Wang, X, Kandasubramanian, B, “Polycarbonate and activated charcoal-engineered electrospun nanofibers for selective recovery of oil/solvent from oily wastewater.” SN Appl. Sci., 2 (11) 1786 (2020)CrossRef

Gore, PM, Balakrishnan, S, Kandasubramanian, B, Superhydrophobic Polym. Coatings (Elsevier, 2019), pp. 223–243

Gore, PM, Purushothaman, A, Naebe, M,Wang, X, Kandasubramanian, B, Nanotechnology for Oil-Water Separation. 299 (2019)

KakulitePanwarKandasubramanian, KKSSB, “A review: advancements in fluoro-based polymers for aggrandizing anti-galling and wear resistant characteristics.” Appl. Sci., https://doi.org/10.1007/s42452-019-0924-3 (2019)CrossRef

10.

Kakulite, KK, Kandasubramanian, B, “Rudiment of ‘galling: Tribological phenomenon’ for engineering components in aggregate with the advancement in functioning of the anti-galling coatings.” Surf. Interfaces, 17 100383 (2019)CrossRef

11.

Gore, PM, Zachariah, S, Gupta, P, K, B, “Multifunctional nano-engineered and bio-mimicking smart superhydrophobic reticulated ABS/fumed silica composite thin films with heat-sinking applications.” RSC Adv., 6 (107) 105180 (2016)CrossRef

12.

Gore, PM, Kandasubramanian, B, “Heterogeneous wettable cotton based superhydrophobic Janus biofabric engineered with PLA/functionalized-organoclay microfibers for efficient oil–water separation.” J. Mater. Chem. A, 6 (17) 7457 (2018)CrossRef

13.

GoreNaebeWangKandasubramanian, PMMXB, “Nano-fluoro dispersion functionalized superhydrophobic degummed & waste silk fabric for sustained recovery of petroleum oils & organic solvents from wastewater.” J. Hazard. Mater., 426 127822 (2021)

14.

Udayakumar, KV, Gore, PM, Kandasubramanian, B, “Foamed materials for oil-water separation.” Chem. Eng. J. Adv., 5 100076 (2021)CrossRef

15.

Gore, PM, Naebe, M, Wang, X, Kandasubramanian, B, “Silk fibres exhibiting biodegradability & superhydrophobicity for recovery of petroleum oils from oily wastewater.” J. Hazard. Mater., 389 121823 (2019)CrossRef

16.

Gore, PM, Naebe, M, Wang, X, Kandasubramanian, B, “Progress in silk materials for integrated water treatments: fabrication, modification and applications.” Chem. Eng. J., 374 437 (2019)CrossRef

17.

Verkholantsev, VV, “Nonhomogeneous-in-layer coatings.” Prog. Org. Coat., 13 (2) 71 (1985)CrossRef

18.

Funke, W, “Preparation and properties of paint films with special morphological structure.” J. Oil Colour Chem. Assoc., 59 (1) 398 (1976)

19.

Verkholantsev, V, Flavian, M, “Polymer structure and properties of heterophase and self-stratifying coatings.” Prog. Org. Coat., 29 (1–4) 239 (1996)CrossRef

20.

Verkholantsev, VV, “Self-stratifying coatings for industrial applications.” Pigment Resin Technol., 32 (5) 300 (2003)CrossRef

21.

Misev, TA, “Thermodynamic analysis of phase separation in selfstratifying coatings-solubility parameters approach.” J. Coat. Technol., 63 (795) 23 (1991)

22.

Carr, C, “Multilayered paint films from single coat systems.” J. Oil Colour Chem. Assoc., 73 (10) 403 (1990)

23.

LUBBE, W, “Tailor-made epoxy resin binders for adhesive formulations.” Paintindia, 53 (11) 49 (2003)

24.

Carr, C, Wallstöm, E, “Theoretical aspects of self-stratification.” Prog. Org. Coat., 28 (3) 161 (1996)CrossRef

25.

Benjamin, S, Carr, C, Walbridge, D, “Self-stratifying coatings for metallic substrates.” Prog. Org. Coat., 28 (3) 197 (1996)CrossRef

26.

Walbridge, D, “Self-stratifying coatings — an overview of a European Community Research Project.” Prog. Org. Coat., 28 (3) 155 (1996)CrossRef

27.

Pawar, SS, Baloji Naik, R, Rath, SK, Mahato, TK, Kandasubramanian, B, “Photoinduced hydrophilicity and self-cleaning characteristics of silicone-modified soya alkyd/TiO₂ nanocomposite coating.” J. Coat. Technol. Res., 17 (3) 719 (2020)CrossRef

28.

Salunke, A, Sasidharan, S, Gopinathapanicker, JC, Kandasubramanian, B, Anand, A, “Cyanate ester epoxy blends for structural and functional composites.” Ind. Eng. Chem. Res., 60 (8) 3260 (2021)CrossRef

29.

Tirumali, M, Kandasubramanian, B, Kumaraswamy, A, Subramani, NK, Suresha, B, “Fabrication, physicochemical characterizations and electrical conductivity studies of modified carbon nanofiber-reinforced epoxy composites: effect of 1-butyl-3-methylimidazolium tetrafluoroborate ionic liquid.” Polym. - Plast. Technol. Eng., 57 (3) 218 (2018)CrossRef

30.

Beaugendre, A, Degoutin, S, Bellayer, S, Pierlot, C, Duquesne, S, Casetta, M, Jimenez, M, “Self-stratifying coatings: a review.” Prog. Org. Coat., 110 210 (2017)CrossRef

31.

VinkBots, PT, “Formulation parameters influencing self-stratification of coatings.” Prog. Org. Coat., 28 (3) 173 (1996)CrossRef

32.

Kuczyńska, H, Langer, E, Kamińska-Tarnawska, E, Kulikov, DA, Indeikin, EA, “Study of self-stratifying compositions.” J. Coat. Technol. Res., 6 (3) 345 (2009)CrossRef

33.

Langer, E, Kuczyńska, H, Kamińska-Tarnawska, E, Łukaszczyk, J, Kamińska-Bach, G, “Changes of solubility parameters during evaporation of solvents as a factor influencing the self-stratification of epoxy/acrylic systems.” Prog. Org. Coat., 66 (3) 228 (2009)CrossRef

34.

Lewis, JA, “Marine biofouling and its prevention on underwater surfaces.” Mater. Forum, 22 41 (1998)

35.

Munk, T, Kane, D, Yebra DM, Adv. Mar. Antifouling Coatings Technol. (Elsevier, 2009), pp. 148–176.

36.

Yebra, DM, Kiil, S, Dam-Johansen, K, “Antifouling technology - Past, present and future steps towards efficient and environmentally friendly antifouling coatings.” Prog. Org. Coat., 50 (2) 75 (2004)CrossRef

37.

Callow, JA, Callow, ME, “Trends in the development of environmentally friendly fouling-resistant marine coatings.” Nat. Commun., 2 (1) 244 (2011)CrossRef

38.

Lejars, M, Margaillan, A, Bressy, C, “Fouling release coatings: a nontoxic alternative to biocidal antifouling coatings.” Chem. Rev., 112 (8) 4347 (2012)CrossRef

39.

Grozea, CM, Walker, GC, “Approaches in designing non-toxic polymer surfaces to deter marine biofouling.” Soft Matter, 5 (21) 4088 (2009)CrossRef

40.

RosenhahnSchilpKreuzerGrunze, ASHJM, “The role of ‘inert’ surface chemistry in marine biofouling prevention.” Phys. Chem. Chem. Phys., 12 (17) 4275 (2010)CrossRef

41.

Krishnan, S, Weinman, CJ, Ober, CK, “Advances in polymers for anti-biofouling surfaces.” J. Mater. Chem., 18 (29) 3405 (2008)CrossRef

42.

Nurioglu, AG, Esteves, ACC, de With, G, “Non-toxic, non-biocide-release antifouling coatings based on molecular structure design for marine applications.” J. Mater. Chem. B, 3 (32) 6547 (2015)CrossRef

43.

Schultz, MP, Kavanagh, CJ, Swain, GW, “Hydrodynamic forces on barnacles: Implications on detachment from fouling-release surfaces.” Biofouling, 13 (4) 323 (1999)CrossRef

44.

Brady, RF, Singer, IL, “Mechanical factors favoring release from fouling release coatings.” Biofouling, 15 (1–3) 73 (2000)CrossRef

45.

Rath, SK, Chavan, JG, Sasane, S, Srivastava, A, Patri, M, Samui, AB, Chakraborty, BC, Sawant, SN, “Coatings of PDMS-modified epoxy via urethane linkage: Segmental correlation length, phase morphology, thermomechanical and surface behavior.” Prog. Org. Coat., 65 (3) 366 (2009)CrossRef

46.

Rath, SK, Chavan, JG, Sasane, S, Jagannath, PM, Samui, AB, Chakraborty, BC, “Two component silicone modified epoxy foul release coatings: Effect of modulus, surface energy and surface restructuring on pseudobarnacle and macrofouling behavior.” Appl. Surf. Sci., 256 (8) 2440 (2010)CrossRef

47.

Chen, Z, Chisholm, B, Kim, J, Stafslien, S, Wagner, R, Patel, S, Daniels, J, Vander Wal, L, Li, J, Ward, K, Callow, M, Thompson, S, Siripirom, C, “UV-curable, oxetane-toughened epoxy-siloxane coatings for marine fouling-release coating applications.” Polym. Int., 57 (6) 879 (2008)CrossRef

48.

Fang, J, Kelarakis, A, Wang, D, Giannelis, EP, Finlay, JA, Callow, ME, Callow, JA, “Fouling release nanostructured coatings based on PDMS-polyurea segmented copolymers.” Polymer (Guildf), 51 (12) 2636 (2010)CrossRef

49.

Chavan, JG, Rath, SK, Praveen, S, Kalletla, S, Patri, M, “Hydrogen bonding and thermomechanical properties of model polydimethylsiloxane based poly(urethane-urea) copolymers: Effect of hard segment content.” Prog. Org. Coat., 90 350 (2016)CrossRef

50.

Rath, SK, Chavan, JG, Ghorpade, TJ, Umasankar Patro, T, Patri, M, “Structure–property correlations of foul release coatings based on low hard segment content poly(dimethylsiloxane–urethane–urea).” J. Coat. Technol. Res., 15 (1) 185 (2018)CrossRef

51.

Sommer, S, Ekin, A, Webster, DC, Stafslien, SJ, Daniels, J, anderWal, LJ, Thompson, SEM, Callow, ME, Callow, JA, “A preliminary study on the properties and fouling-release performance of siloxane-polyurethane coatings prepared from poly(dimethylsiloxane) (PDMS) macromers.” Biofouling, 26 (8) 961 (2010)CrossRef

52.

Bodkhe, RB, Thompson, SEM, Yehle, C, Cilz, N, Daniels, J, Stafslien, SJ, Callow, ME, Callow, JA, Webster, DC, “The effect of formulation variables on fouling-release performance of stratified siloxane–polyurethane coatings.” J. Coat. Technol. Res., 9 (3) 235 (2012)CrossRef

53.

Stein, J, Truby, K, Wood, CD, Takemori, CD, Vallance, M, Swain, G, Kavanagh, C, Kovach, B, Schultz, M, Wiebe, D, Holm, E, Montemarano, J, Wendt, D, Smith, C, Meyer, A, “Structure-property relationships of silicone biofouling-release coatings: effect of silicone network architecture on pseudobarnacle attachment strengths.” Biofouling, 19 (2) 87 (2003)CrossRef

54.

OwensWendt, DKRC, “Estimation of the surface free energy of polymers.” J. Appl. Polym. Sci., 13 (8) 1741 (1969)CrossRef

55.

Inamdar, A, Cherukattu, A, Anand, Kandasubramanian, B, “Thermoplastic toughened high temperature cyanate esters and its application in advanced composites.” Ind. Eng. Chem. Res., 57 (13) 4479–4504 (2018)CrossRef

56.

Sahoo, BN, Kandasubramanian, B, “Recent progress in fabrication and characterisation of hierarchical biomimetic superhydrophobic structures.” RSC Adv., 4 (42) 22053 (2014)CrossRef

57.

Sahoo, BN, Kandasubramanian, B, Thomas, A, “Effect of TiO₂ Powder on the Surface Morphology of Micro/Nanoporous Structured Hydrophobic Fluoropolymer Based Composite Material.” J. Polym., 2013 1 (2013)CrossRef

58.

Gupta, P, Kandasubramanian, B, “Directional fluid gating by janus membranes with heterogeneous wetting properties for selective oil-water separation.” ACS Appl. Mater. Interfaces, 9 (22) 19102 (2017)CrossRef

59.

SandhyaSureshRamdayalBK, PGYY, “Quantitative evolution of wetting phenomena for super hydrophobic surfaces.” Mater. Focus, 7 (3) 305 (2018)CrossRef

60.

Palaniappan, N, Alphonsa, J, Cole, IS, Balasubramanian, K, Bosco, IG, “Rapid investigation expiry drug green corrosion inhibitor on mild steel in NaCl medium.” Mater. Sci. Eng. B Solid-State Mater. Adv. Technol., 249 112243 (2019)CrossRef

61.

Palaniappan, N, Cole, IS, Caballero-Briones, F, K, B, Lal, C, “Praseodymium-decorated graphene oxide as a corrosion inhibitor in acidic media for the magnesium AZ31 alloy.” RSC Adv., 8 (60) 34275 (2018)CrossRef

62.

McIntyre, JM, Pham, HQ, “Electrochemical impedance spectroscopy; a tool for organic coatings optimizations.” Prog. Org. Coat., 27 (1–4) 201 (1996)CrossRef

63.

Zhang, J-T, Hu, J-M, Zhang, J-Q, Cao, C-N, “Studies of water transport behavior and impedance models of epoxy-coated metals in NaCl solution by EIS.” Prog. Org. Coat., 51 (2) 145 (2004)CrossRef

64.

Macedo, MCSS, Margarit-Mattos, ICP, Fragata, FL, Jorcin, J-B, Pébère, N, Mattos, OR, “Contribution to a better understanding of different behaviour patterns observed with organic coatings evaluated by electrochemical impedance spectroscopy.” Corros. Sci., 51 (6) 1322 (2009)CrossRef

65.

Bierwagen, GP, He, L, Li, J, Ellingson, L, Tallman, DE, “Studies of a new accelerated evaluation method for coating corrosion resistance — thermal cycling testing.” Prog. Org. Coat., 39 (1) 67 (2000)CrossRef

66.

Mayilswam, N, Boney, N, Kandasubramanian, B, “Fabrication and molecular dynamics studies of layer-by-layer polyelectrolytic films.” Eur. Polym. J., 163 110945 (2022)CrossRef

67.

Kumar, P, Gore, PM, Magisetty, R, Kandasubramanian, B, Shunmugam, R, “Poly(1,6-heptadiyne)/ABS functionalized microfibers for hydrophobic applications.” J. Polym. Res., 27 (1) 14 (2020)CrossRef

Titel: Pigmented silicone/epoxy novel blends for preparation of stratified nontoxic foul release coatings
verfasst von: Sushil S. Pawar
R. Baloji Naik
Sangram K. Rath
T. K. Mahato
Balasubramanian Kandasubramanian
Publikationsdatum: 20.04.2022
Verlag: Springer US
Erschienen in: Journal of Coatings Technology and Research / Ausgabe 4/2022
Print ISSN: 1547-0091
Elektronische ISSN: 1935-3804
DOI: https://doi.org/10.1007/s11998-022-00610-4

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