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Polymer Bulletin

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27-04-2020 | Original Paper

Influence of different structures of palm oil-based polyol on the mechanical and thermal properties of hybrid resin from polyurethane-/polysiloxane-modified epoxy

Authors: Evi Triwulandari, Muhammad Ghozali, Witta Kartika Restu

Published in: Polymer Bulletin | Issue 4/2021

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Abstract

Hybrid resin from polyurethane-/polysiloxane-modified epoxy (PPME) has been synthesized by using palm oil-based polyol as the polyurethane component. The palm oil-based polyol used are glycerol monooleate, polyethylene glycol monooleate, 1,4-butanediol monooleate and 1,4-butanediol,9-hydroxy-10-methoxy-monostearate. These polyols have a different chemical structure with each other. Here, we studied the influence of palm oil-based polyol structure on the mechanical and thermal properties of hybrid resin from PPME. Characterization of palm oil-based polyols structure was conducted by analysis FTIR and NMR. The qualitative analysis of palm oil-based polyols was carried out by determining acid value, ester value, iod value and hydroxyl value. The mechanical properties showed that PPME hybrid resin from 1,4-butanediol,9-hydroxy-10-methoxy-monostearate has the highest mechanical properties, while the thermal properties of hybrid resin showed that there is no significant influence of the polyols structure, but all of the PPME hybrid resins have higher thermal properties than unmodified epoxy. Nevertheless, the thermal degradation of PPME hybrid resin from 1,4-butanediol,9-hydroxy-10-methoxy-monostearate at 400–450 °C has the highest residual weight. It means that it shows the highest thermal stability.

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Bakhshandeh E, Jannesari A, Ranjbar Z, Sobhani S, Saeb MR (2014) Anti-corrosion hybrid coatings based on epoxy-silica nano-composites: toward relationship between the morphology and EIS data. Prog Org Coat 77(7):1169–1183CrossRef

Corcione CE, Freuli F, Frigione M (2014) Cold-curing structural epoxy resins: analysis of the curing reaction as a function of curing time and thickness. Materials (Basel) 6(9):6832–6842CrossRef

Gupta P, Bajpai M (2011) Development of siliconized epoxy resins and their application as anticorrosive coatings. Adv Chem Eng Sci 01(03):133–139CrossRef

Khurana P, Aggarwal S, Narula AK, Choudhary V (2003) Studies on the curing and thermal behaviour of DGEBA in the presence of bis(4-carboxyphenyl) dimethyl silane. Polym Int 52(6):908–917CrossRef

Hua R, Jianzhong S, Binjie W, Qiyun Z (2007) Synthesis and curing properties of a novel novolac curing agent containing naphthyl and dicyclopentadiene moieties. Chin J Chem Eng 15(1):127–131CrossRef

Liu B, Wang Y (2014) A novel design for water-based modified epoxy coating with anti-corrosive application properties. Prog Org Coat 77(1):219–224CrossRef

Dubois RA, Wang DS (1993) Effect of structure on coating performance properties of novel alkylenedioxydiphenol based epoxy resins. Prog Org Coat 22(1–4):161–179CrossRef

García SJ, Fischer HR, Van Der Zwaag S (2011) A critical appraisal of the potential of self healing polymeric coatings. Prog Org Coat 72(3):211–221CrossRef

García SJ, Suay J (2007) Epoxy powder clearcoats used for anticorrosive purposes cured with ytterbium III trifluoromethanesulfonate. Corrosion 63(4):379–390CrossRef

10.

Ho TH, Wang CS (1996) Modification of epoxy resins with polysiloxane thermoplastic polyurethane for electronic encapsulation: 1. Polymer (Guildf) 37(13):2733–2742CrossRef

11.

Lin S-T, Huang SK (1997) Thermal degradation study of siloxane-DGEBA epoxy copolymers. Eur Polym J 33(3):365–373CrossRef

12.

Thomas R, Yumei D, Yuelong H, Le Y, Moldenaers P (2008) Miscibility, morphology, thermal, and mechanical properties of a DGEBA based epoxy resin toughened with a liquid rubber. Polymer 49:278–294CrossRef

13.

Yang JP, Chen ZK, Yang G, Fu SY, Ye L (2008) Simultaneous improvements in the cryogenic tensile strength, ductility and impact strength of epoxy resins by a hyperbranched polymer. Polymer (Guildf) 49(13–14):3168–3175CrossRef

14.

dell’Erba IE, Williams RJJ (2007) Synthesis of oligomeric silsesquioxanes functionalized with (β-carboxyl)ester groups and their use as modifiers of epoxy networks. Eur Polym J 43(7):2759–2767CrossRef

15.

Malshe VC, Waghoo G (2004) Weathering study of epoxy paints. Prog Org Coat 51(4):267–272CrossRef

16.

Jin F-L, Park S-J (2008) Thermomechanical behavior of epoxy resins modified with epoxidized vegetable oils. Polym Int 57:577–583CrossRef

17.

Ghozali M, Triwulandari E, Haryono A (2015) Preparation and characterization of polyurethane-modified epoxy with various types of polyol. Macromol Symp 353(1):154–160CrossRef

18.

Triwulandari E, Ramadhan MK (2016) Influence of reaction condition on viscosity of polyurethane modified epoxy based on glycerol monooleate. AIP Conf Proc 1904(1):020053-1–020053-7

19.

Bakar M, Kostrzewa M, Pawelec Z (2012) Preparation and properties of epoxy resin modified with polyurethane based on hexamethylene diisocyanate and different polyols. J Thermoplast Compos Mater 27(5):620–631CrossRef

20.

Akindoyo JO, Beg MDH, Ghazali S, Islam MR, Jeyaratnam N, Yuvaraj AR (2016) Polyurethane types, synthesis and applications—a review. RSC Adv 6:114453–114482CrossRef

21.

Chattopadhyay DK, Kothapalli RV (2007) Structural engineering of polyurethane coatings for high performance applications structural engineering of polyurethane coatings for high performance applications. Prog Polym Sci 32:352–418CrossRef

22.

Mohammadi A, Barikani M, Barmar M (2013) Effect of polyol structure on the properties of the resultant magnetic polyurethane elastomer nanocomposites. Polym Adv Technol 24:978–985CrossRef

23.

Hepburn C (1992) Polyurethane elastomers, vol 2. Springer, BerlinCrossRef

24.

Prociak A et al (2020) Influence of chemical structure of petrochemical polyol on properties of bio-polyurethane foams. J Polym Environ 27:2360–2368CrossRef

25.

Badan A, Majka TM (2017) The influence of vegetable-oil based polyols on physico-mechanical and thermal properties of polyurethane foams. Proc MDPI 1:1–7

26.

Ionescu M (2016) Chemistry and technology of polyols for polyurethanes, vol 2. Smithers Rapra Publishing, Akron

27.

Gurunathan T, Mohanty S, Nayak SK (2015) Effect of reactive organoclay on physicochemical properties of vegetable oil-based waterborne polyurethane nanocomposites. RSC Adv 5(15):11524–11533CrossRef

28.

Alagi P, Choi YJ, Hong SC (2016) Preparation of vegetable oil-based polyols with controlled hydroxyl functionalities for thermoplastic polyurethane. Eur Polym J 78:46–60CrossRef

29.

Alagi P, Hong SC (2015) Vegetable oil-based polyols for sustainable polyurethanes. Macromol Res 23(12):1079–1086CrossRef

30.

Fridrihsone-Girone A, Stirna U, Misane M, Lazdiņa B, Deme L (2016) Spray-applied 100% volatile organic compounds free two component polyurethane coatings based on rapeseed oil polyols. Prog Org Coat 94:90–97CrossRef

31.

Ionescu M, Radojčić D, Wan X, Shrestha ML, Petrović ZS, Upshaw TA (2016) Highly functional polyols from castor oil for rigid polyurethanes. Eur Polym J 84:736–749CrossRef

32.

Triwulandari E, Ramadhan MK, Ghozali M (2017) Effect of reaction time and polyethylene glycol monooleate-isocyanate composition on the properties of polyurethane-polysiloxane modified epoxy. AIP Conf Proc 1904:020046-1–020046-7

33.

Triwulandari E, Ghozali M, Restu WK, Meliana Y (2019) Hydrolysis and condensation of alkoxysilane for the preparation of hybrid coating based on polyurethane/polysiloxane-modified epoxy. Polym Sci Ser B 61(2):180–188CrossRef

34.

Byczyński Ł, Dutkiewicz M, Maciejewski H (2016) Thermal and surface properties of hybrid materials obtained from epoxy-functional urethane and siloxane. Polym Bull 73(5):1247–1265CrossRef

35.

Thomas A (2017) Improving polyurethane surface coatings part 1: polyurethane and polyisocyanate. Surf Coat Int 98(4):170–178

36.

Gama NV, Ferreira A, Barros-Timmons A (2018) Polyurethane foams: past, present, and future. Materials 11:1841CrossRef

37.

Gopalakrishnan S, Fernando TL (2012) Influence of polyols on properties of bio-based polyurethanes. Bull Mater Sci 35(2):243–251CrossRef

38.

Gogoi R, Alam S (2013) Effect of soft segment chain length on tailoring the properties of isocyanate terminated polyurethane prepolymer, a base material from polyurethane bandage. Int J Res Eng Technol 2:395–398

39.

Prabu AA, Alagar M (2004) Mechanical and thermal studies of intercross-linked networks based on siliconized polyurethane-epoxy/unsaturated polyester coatings. Prog Org Coat 49(3):236–243CrossRef

40.

Wang T, Hsieh T (1997) Effect of polyol structure and molecular weight on the thermal stability of segmented poly (urethaneureas). Polym Degrad Stab 55:95–102CrossRef

41.

Triwulandari E, Ghozali M (2015) Mechanical and thermal properties of hybrid coating products from polyurethane and/or polysiloxane modified epoxy based on acrylic polyol and tolonate. In: Proceedings international conference on innovation in polymer science and technology 2013 (IPST2013), pp 285–295

Title: Influence of different structures of palm oil-based polyol on the mechanical and thermal properties of hybrid resin from polyurethane-/polysiloxane-modified epoxy
Authors: Evi Triwulandari
Muhammad Ghozali
Witta Kartika Restu
Publication date: 27-04-2020
Publisher: Springer Berlin Heidelberg
Published in: Polymer Bulletin / Issue 4/2021
Print ISSN: 0170-0839
Electronic ISSN: 1436-2449
DOI: https://doi.org/10.1007/s00289-020-03203-6

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