Structure, Mechanical, Thermal and Fire Behavior Assessments of Environmentally Friendly Crude Glycerol-Based Rigid Polyisocyanurate Foams - Publication - Bridge of Knowledge

Your account

login

Search

Structure, Mechanical, Thermal and Fire Behavior Assessments of Environmentally Friendly Crude Glycerol-Based Rigid Polyisocyanurate Foams

Abstract

In this work, rigid polyisocyanurate foams were prepared at partial substitution (0–70 wt%) of commercially available petrochemical polyol, with previously synthesized biopolyol based on crude glycerol and castor oil. Influence of the biopolyol content on morphology, chemical structure, static and dynamic mechanical properties, thermal insulation properties, thermal stability and flammability was investigated. Incorporation of 35 wt% of crude glycerol-based polyol had reduced average cell size by more than 30% and slightly increased closed cell content, simultaneously reducing thermal conductivity coefficient of foam by 12% and inhibiting their thermal aging. Applied modifications showed also positive impact on the mechanical performance of rigid foams. Increase of crosslink density resulted in enhancement of compressive strength by more than 100%. Incorporation of prepared biopolyol resulted in enhancement of thermal stability and changes in degradation pathway. Up to 35 wt% share of crude glycerol-based polyol, foams showed similar flammability as reference sample, which can be considered very beneficial from the environmental point of view.

Citations

  • 3 4

    CrossRef

  • 0

    Web of Science

  • 3 3

    Scopus

Authors (7)

Cite as

Full text

download paper
downloaded 57 times
Publication version
Accepted or Published Version
License
Creative Commons: CC-BY open in new tab

Keywords

Details

Category:
Articles
Type:
artykuł w czasopiśmie wyróżnionym w JCR
Published in:
JOURNAL OF POLYMERS AND THE ENVIRONMENT no. 26, pages 1854 - 1868,
ISSN: 1566-2543
Language:
English
Publication year:
2018
Bibliographic description:
Hejna A., Kosmela P., Kirpluks M., Cabulis U., Klein M., Haponiuk J., Piszczyk Ł.: Structure, Mechanical, Thermal and Fire Behavior Assessments of Environmentally Friendly Crude Glycerol-Based Rigid Polyisocyanurate Foams// JOURNAL OF POLYMERS AND THE ENVIRONMENT. -Vol. 26, nr. 5 (2018), s.1854-1868
DOI:
Digital Object Identifier (open in new tab) 10.1007/s10924-017-1086-2
Bibliography: test
  1. Hoekman SK, Broch A, Robbins C, Ceniceros E (2012) Renew Sust Energ Rev 16:143 open in new tab
  2. Petrović Z (2008) Polym Rev 48:109 open in new tab
  3. Kurańska M, Prociak A, Kirpluks M, Cabulis U (2015) Ind Crop Prod 74:849 open in new tab
  4. Kurańska M, Prociak A (2016) Ind Crop Prod 89:182 open in new tab
  5. Zlatanić A, Lava C, Zhang W, Petrović ZS (2004) J Polym Sci B 42:809
  6. Chuayjuljit S, Sangpakdee T, Saravari O (2007) J Met Mater Miner 17:17 open in new tab
  7. Campanella A, Bonnaillie LM, Wool RP (2009) J Appl Polym Sci 112:2567 open in new tab
  8. Fan H, Tekeei A, Suppes GJ, Hsieh FH (2013) J Appl Polym Sci 127:1623 open in new tab
  9. Calvo-Correas T, Mosiewicki MA, Corcuera MA, Eceiza A, Aranguren MI (2015) J Renew Mater 3:3 open in new tab
  10. Palanisamy A, Karuna MSL, Satyavani T, Rohini Kumar DB (2011) J Am Oil Chem Soc 88:541 open in new tab
  11. Silva VR, Mosiewicki MA, Yoshida MI, Silva MC, Stefani PM, Marcovich NE (2013) Polym Test 32:665
  12. Yang LT, Zhao CS, Dai CL, Fu LY, Lin SQ (2012) J Polym Environ 20:230 open in new tab
  13. Tu YC, Fan H, Suppes GJ, Hsieh FH (2009) J Appl Polym Sci 114:2577 open in new tab
  14. Guo A, Demydov D, Zhang W, Petrovic ZS (2002) J Polym Environ 10:49 open in new tab
  15. Tran P, Graiver D, Narayan R (2005) J Am Oil Chem Soc 82:653 open in new tab
  16. Desai SD, Patel JV, Sinha VK (2003) Int J Adhes Adhes 23:393
  17. Puri M, Abraham RE, Barrow CJ (2012) Renew Sust Energ Rev 16:6022 open in new tab
  18. Ragauskas AJ, Williams CK, Davison BH, Britovsek G, Cairney J, Eckert CA, Frederick WJ Jr, Hallett JP, Leak DJ, Liotta CL, Mielenz JR, Murphy R, Templer R, Tschaplinski T (2006) Sci- ence 311:484 open in new tab
  19. Fan X, Burton R (2009) Open Fuels Energy Sci J 2:100 open in new tab
  20. Nik Siti MNMD, Idris Z, Shoot KY, Hassan HA (2013) J Oil Palm Res 25:289
  21. Cheng D, Wang L, Shahbazi A, Xiu S, Zhang B (2014) Fuel 130:251 open in new tab
  22. Hu S, Li Y (2014) Ind Crop Prod 57:188 open in new tab
  23. Ionescu M, Petrovic ZS (2010) J Cell Plast 46:223 open in new tab
  24. Luo X, Hu S, Zhang X, Li Y (2013) Bioresour Technol 139:323 open in new tab
  25. Li C, Luo X, Li T, Tong X, Li Y (2014) Polymer 55:6529 open in new tab
  26. Piszczyk Ł, Strankowski M, Danowska M, Hejna A, Haponiuk JT (2014) Eur Polym J 57:143 open in new tab
  27. European Comission (2017) Thermal insulation-green pub- lic procurement product sheet. Accessed 25 June 2017 http:// ec.europa.eu/environment/gpp/pdf/thermal_insulation_GPP_ product_sheet.pdf.
  28. Piszczyk Ł, Danowska M, Haponiuk J, Strankowski M (2014) Polish patent application P.408610 open in new tab
  29. Andersons J, Kirpluks M, Stiebra L, Cabulis U (2015) Theor Appl Fract Mech 78:8 open in new tab
  30. Kirpluks M, Cabilis U, Zeltins V, Stiebra L, Avots A (2014) Autex Res J 14:259 open in new tab
  31. Miyata A, Tsutsui T, Konga N, Matsumoto S, Ohkubo K (2012) Patent EP2080778
  32. Wirpsza Z, Banasiak S (2012) Patent PL 210779
  33. Hejna A, Kirpluks M, Kosmela P, Cabulis U, Haponiuk J, Piszc- zyk Ł (2017) Ind Crop Prod 95:113 open in new tab
  34. Zieleniewska M, Leszczyński MK, Kurańska M, Prociak A, Szc- zepkowski L, Krzyżowska M, Ryszkowska J (2015) Ind Crop Prod 74:887 open in new tab
  35. Sormana JL, Meredith JC (2004) Macromolecules 37:2186 open in new tab
  36. Fournier D, Du Prez F (2008) Macromolecules 41:4622 open in new tab
  37. Jiao L, Xiao H, Wang Q, Sun J (2013) Polym Degrad Stabil 98:2687 open in new tab
  38. Samborska-Skowron R, Balas A (2003) Polimery 48:371 open in new tab
  39. Pretsch T, Jakob I, Müller W (2009) Polym Degrad Stabil 94:61 open in new tab
  40. Mosiewicki MA, Dell'Arciprete GA, Aranguren MI, Marcovich MA (2009) J Compos Mater 43:3057 open in new tab
  41. Modesti M, Lorenzetti A (2003) Eur Polym J 39:263 open in new tab
  42. Kong X, Yue J, Narine SS (2007) Biomacromolecules 8:3584 open in new tab
  43. Guo H, Gao Q, Ouyang C, Zheng K, Xu W (2015) J Appl Polym Sci 132:42349 open in new tab
  44. Bagdi K, Molnar K, Sajo I, Pukanszky B (2011) Express Polym Lett 5:417 open in new tab
  45. Narine SS, Kong X, Bouzidi L, Sporns P (2007) J Amer Oil Chem Soc 84:65 open in new tab
  46. Tan S, Abraham T, Ference D, Macosko CW (2011) Polymer 52:2840 open in new tab
  47. Bindu P, Thomas S (2013) J Phys Chem B 117:12632 open in new tab
  48. Javni I, Zhang W, Petrović ZS (2004) J Polym Environ 12:123 49. Szycher M (1999) Szycher's handbook of polyurethanes, 1st edn. CRC Press, Boca Raton open in new tab
  49. Randall D, Lee S (2002) The polyurethanes book. Wiley, New York open in new tab
  50. Glicksman LR (1994) Heat transfer in foams. In: Hylyard NC, Cunningham A (eds) Low density cellular plastics. Kluwer Aca- demic Publishers, Dordrecht, pp 115-116t;/bib> open in new tab
  51. Bogdan M, Hoerter J, Moore FO (2005) J Cell Plast 41:41 open in new tab
  52. Singh S, Ntiru M, Dedecker K (2002) Long term thermal resist- ance of pentane blown polyisocyanurate laminate boards. In: API proceedings, Salt Lake City, pp 19-26 open in new tab
  53. Murphy J (2010) Long term aging of closed-celled foam insula- tion. In: Proceedings of polyurethane technical conference, Hou- ston, p 320 open in new tab
  54. Wrześniewiska-Tosik K, Zajchowski S, Bryśkiewicz A, Rysz- kowska J (2014) Fibres Text East Eur 22:119
  55. Septevani AA, Evans DAC, Chaleat C, Martin DJ, Annamalai PK (2015) Ind Crop Prod 66:16 open in new tab
  56. Somania KP, Kansaraa SS, Patelb NK, Rakshit AK (2003) Int J Adhes Adhes 23:269
  57. Tanaka R, Hirose S, Hatakeyama H (2008) Bioresource Technol 99:3810 open in new tab
  58. Cervantes-Uc JM, Moo Espinosa JI, Cauich-Rodriguez JV, Avila-Ortega A, Vazquez-Torres H, Marcos-Fernandez A, San Roman J (2009) Polym Degrad Stab 94:1666 open in new tab
  59. Pawlik H, Prociak A (2012) J Polym Environ 20:438 open in new tab
  60. Zhang L, Zhang M, Zhou Y, Hu L (2013) Polym Degrad Stab 98:2784 open in new tab
  61. Berta M, Lindsay C, Pans G, Camino G (2006) Polym Degrad Stab 91:1179 open in new tab
  62. Babrauskas V, Peacock RD (1992) Fire Saf J 18:255 open in new tab
  63. Schartel B, Hull TR (2007) Fire Mater 31:327 open in new tab
  64. Qian L, Feng F, Tang S (2014) Polymer 55:95 open in new tab
Verified by:
Gdańsk University of Technology

seen 144 times

Recommended for you

The influence of crude glycerol and castor oil-based polyol on the structure and performance of rigid polyurethane-polyisocyanurate foams

2017

The Influence of Substitution of a Phosphorus-Containing Polyol with the Bio-polyol on the Properties of Bio-based PUR/PIR Foams

2018

Study on the Structure-Property Dependences of Rigid PUR-PIR Foams Obtained from Marine Biomass-Based Biopolyol

2020

The study on application of biopolyols obtained by cellulose biomass liquefaction performed with crude glycerol for the synthesis of rigid polyurethane foams

2018
Meta Tags