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Journal of Natural Fibers Volume 20, 2023 - Issue 1
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Research Article

Flexible Insulation Mats from Zostera marina Seagrass

Aldi KuqoDepartment of Wood Biology and Wood Products, Faculty of Forest Sciences and Forest Ecology, University of Goettingen, Göttingen, GermanyORCID Iconhttps://orcid.org/0000-0002-2698-1682
ORCID Icon &
Carsten MaiDepartment of Wood Biology and Wood Products, Faculty of Forest Sciences and Forest Ecology, University of Goettingen, Göttingen, GermanyCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-1540-4185
ORCID Icon
Article: 2154303 | Published online: 07 Dec 2022

References

  • Ayadi, M., R. Zouari, C. Segovia, A. Baffoun, S. Msahli, and N. Brosse. 2022. Development of airlaid non-woven panels for building’s thermal insulation. Construction Technologies and Architecture 1:772–15. www.scientific.net/CTA.1.772.
  • Benthien, J. T., and M. Ohlmeyer. 2017. Influence of face-to-core layer ratio and core layer resin content on the properties of density-decreased particleboards. European Journal of Wood and Wood Products 75 (1):55–62. doi:10.1007/s00107-016-1059-5.
  • DIN EN 12667. 2001. Thermal performance of building materials and products - determination of thermal resistance by means of guarded hot plate and heat flow meter methods - products of high and medium thermal resistance;. In German version EN, Vol. 12667, 2001. Berlin, Germany.
  • DIN EN 1607. 2013. Thermal insulating products for building applications - determination of tensile strength perpendicular to faces. In German version EN 1607:2013. Berlin, Germany.
  • DIN EN 826. 2013. Thermal insulating products for building applications - determination of compression behaviour. In German version EN, Vol. 826, 2013. Berlin, Germany.
  • Ebadi-Dehaghani, H., and M. Nazempour. 2012. Thermal conductivity of nanoparticles filled polymers. London, UK: INTECH Open Access Publisher.
  • Graupner, N., and J Müssig. 2010. Technical applications of natural fibres: An overview Müssig, J. In Industrial applications of natural fibres: Structure, properties and technical applications. West Sussex, UK: John Wiley & Sons, Ltd 73–86.
  • Hamdaoui, O., L. Ibos, A. Mazioud, M. Safi, and O. Limam. 2018. Thermophysical characterization of posidonia oceanica marine fibers intended to be used as an insulation material in mediterranean buildings. Construction and Building Materials 180:68–76. doi:10.1016/j.conbuildmat.2018.05.195.
  • Hung Anh, L. D., and Z. Pásztory. 2021. An overview of factors influencing thermal conductivity of building insulation materials. Journal of Building Engineering 44:102604. doi:10.1016/j.jobe.2021.102604.
  • Imken, A. A., R. Kraft, and C. Mai. 2021. Production and characterisation of wood-fibre insulation boards (WFIB) from hardwood fibres and fibre blends. Wood Material Science & Engineering 1–7. doi:10.1080/17480272.2021.1958919.
  • ISO 5560-1. 2002. Reaction-to-fire tests - heat release, smoke reduction and mass loss rate - part 1 - heat release rate (cone calorimeter method), 5660–1. Geneva, Switzerland.
  • Jedidi, M., and A. Abroug. 2020. ”Valorization of Posidonia oceanica Balls for the Manufacture of an Insulating and Ecological Material.” Jordan Journal of Civil Engineering 14.3.
  • Korjenic, A., J. Zach, and J. Hroudová. 2016. The use of insulating materials based on natural fibers in combination with plant facades in building constructions. Energy and Buildings 116:45–58. doi:10.1016/j.enbuild.2015.12.037.
  • Kumar, D., M. Alam, P. X. Zou, J. G. Sanjayan, and R. A. Memon. 2020. Comparative analysis of building insulation material properties and performance. Renewable and Sustainable Energy Reviews 131:110038. doi:10.1016/j.rser.2020.110038.
  • Kumar, N. M., T. G, P. S, and V. V. 2021. Development of needle punched nonwovens from natural fiber waste for thermal insulation application. Journal of Natural Fibers 19 (14):1–9. doi:10.1080/15440478.2021.1990175.
  • Kuqo, A., A. Korpa, and N. Dhamo. 2019. Posidonia oceanica leaves for processing of PMDI composite boards. Journal of Composite Materials 53 (12):1697–703. doi:10.1177/0021998318808024.
  • Kuqo, A., and C. Mai. 2022. Seagrass leaves: An alternative resource for the production of insulation materials. Materials 15 (19):6933. doi:https://doi.org/10.3390/ma15196933.
  • LeVan, S. L., and J. E. Winandy. 1990. Effects of fire retardant treatments on wood strength: A review. Wood and Fiber Science 22:113–31.
  • Mayer, A. K., A. Kuqo, T. Koddenberg, and C. Mai. 2022. Seagrass-and wood-based cement boards: A comparative study in terms of physico-mechanical and structural properties. Composites Part A, Applied Science and Manufacturing 156:106864. doi:10.1016/j.compositesa.2022.106864.
  • Mehrez, I., H. Hachem, R. Gheith, and A. Jemni. 2022. Valorization of Posidonia-Oceanica leaves for the building insulation sector. Journal of Composite Materials. 56:1973–1985. doi:10.1177/2F00219983221087793
  • Rowell, R. M. 2005. Handbook of wood chemistry and wood composites. London, UK: CRC press.
  • Samanta, K. K., I. Mustafa, S. Debnath, E. Das, G. Basu, and S. K. Ghosh. 2021. Study of thermal insulation performance of layered jute nonwoven: A sustainable material. Journal of Natural Fibers 19 (11):1–14. doi:10.1080/15440478.2020.1856274.
  • Schulte, M., I. Lewandowski, R. Pude, and M. Wagner. 2021. Comparative life cycle assessment of bio‐based insulation materials: Environmental and economic performances. GCB Bioenergy 13 (6):979–98. doi:10.1111/gcbb.12825.
  • Shi, J. L., S. Y. Zhang, B. Riedl, and G. Brunette. 2005. Flexural properties, internal bond strength, and dimensional stability of medium density fiberboard panels made from hybrid poplar clones. Wood and Fiber Science 37:629–37.
  • Teppand, T. G., D. Jones and C. Brischke. 2017. Performance of bio-based building materials. Duxford, UK: Woodhead Publishing.
  • Thilagavathi, G., N. Muthukumar, S. Neela Krishnanan, and T. Senthilram. 2020. Development and characterization of pineapple fibre nonwovens for thermal and sound insulation applications. Journal of Natural Fibers 17 (10):1391–400. doi:10.1080/15440478.2019.1569575.
  • Tsemekidi-Tzeiranaki, S., N. Labanca, B. Cuniberti, A. Toleikyte, P. Zangheri, and P. Bertoldi. 2019. Analysis of the annual reports 2018 under the energy efficiency directive—summary report. Publications Office of the European Union: Luxembourg.
  • Wang, S., P. M. Winistorfer, T. M. Young, and C. Helton. 2001. Step-closing pressing of medium density fiberboard;part 1. Influences on the vertical density profile. Holz als roh-und Werkstoff 59 (1–2):19–26. doi:10.1007/s001070050466.
  • Wyllie-Echeverria, S., and P. Alan Cox. 1999. l’industrie de l’ailleul (zostera marina zosteraceae) de la nouvelle-Écosse (1907–1960). Economic Botany 53 (4):419–26. doi:10.1007/BF02866721.
  • Xie, Y., Q. Tong, Y. Chen, J. Liu, and M. Lin. 2011. Manufacture and properties of ultra-low density fibreboard from wood fibre. BioResources 6:4055–66.
  • Zannen, S., M. T. Halimi, M. B. Hassen, E. H. Abualsauod, and A. M. Othman. 2022. Development of a multifunctional wet laid nonwoven from marine waste posidonia oceanica technical fiber and CMC binder. Polymers 14 (5):865. doi:10.3390/polym14050865.
  • Zou, S., H. Li, L. Liu, S. Wang, X. Zhang, and G. Zhang. 2021. Experimental study on fire resistance improvement of wheat straw composite insulation materials for buildings. Journal of Building Engineering 43:103172. doi:10.1016/j.jobe.2021.103172.

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