Manufacturing of Bamboo Hybrids with High Strength, Superior Fire Retardancy, and Dimensional Stability

Wen He; Rui Wang; Wenxuan Li; Gangzheng Hu; Tripti Singh; Qiliang Fu

Back

Manufacturing of Bamboo Hybrids with High Strength, Superior Fire Retardancy, and Dimensional Stability

Conference paper

Peer reviewed

Manufacturing of Bamboo Hybrids with High Strength, Superior Fire Retardancy, and Dimensional Stability

Wen He, Rui Wang, Wenxuan Li, Gangzheng Hu, Tripti Singh and Qiliang Fu

Proceedings IRG Annual Meeting, pp.1-11

Annual Meeting of International Research Group on Wood Protection (IRG), 55th (Knoxville, United States, 19-May-2024 - 23-May-2024)

IRG Secretariate

2024

Files and links (2)

url

https://irg-wp.com/meetings/IRG55/IRG55.htmlView

Event Website

url

https://irg-wp.com/irgdocs/details.php?c4e74fdb-acd1-20e6-cafa-85a9e7e1624cView

Webpage

Abstract

Biocomposite

delignification

glulamination

mineralized hybrids

phenolic resin

Bamboo, renowned for its rapid growth, high strength-to-weight ratio, and eco-friendly attributes, has found extensive use in decorative building materials and glue-laminated beams. However, the inherent challenges of dimensional instability and flammability in natural bamboo restrict its broad application. This research introduces a range of environmentally friendly techniques aimed at producing functional bamboo hybrids with exceptional strength, outstanding dimensional stability, and flame-retardant properties. These hybrids are developed through processes including bamboo delignification, in-situ mineralization of CaCO3, and hot-pressing following impregnation with phenolic resin. The resulting bamboo hybrids exhibit highly aligned and densified nanocellulose stacking, fostering impressive tensile strength (583.6 MPa), flexural strength (374.8 MPa), and an exceptional specific strength of 486.3 MPa·cm 3 ·g-1. This specific strength surpasses that of reported bamboo materials and many structural materials. The enhanced dimensional stability of the bamboo hybrids is attributed to the impregnation of phenolic resin and CaCO3 mineralization, contributing to improved hydrophobicity. In comparison to natural bamboo, the bamboo hybrid demonstrates a 37.7% reduction in total heat release and a 50.0% decrease in smoke production rate. This study presents an environmentally conscious processing strategy for manipulating and functionalizing bamboo's microstructure, resulting in materials with high strength, superior fire-retardancy, and dimensional stability. The potential applications span diverse fields, including structural construction, aerospace, and automotive manufacturing.

Details

Title: Manufacturing of Bamboo Hybrids with High Strength, Superior Fire Retardancy, and Dimensional Stability
Authors: Wen He - Nanjing Forestry University
Rui Wang - Nanjing Forestry University
Wenxuan Li - Nanjing Forestry University
Gangzheng Hu - Nanjing Forestry University
Tripti Singh - University of the Sunshine Coast, Queensland, National Centre for Timber Durability and Design Life
Qiliang Fu - Nanjing Forestry University
Publication details: Proceedings IRG Annual Meeting, pp.1-11
Conference details: Annual Meeting of International Research Group on Wood Protection (IRG), 55th (Knoxville, United States, 19-May-2024 - 23-May-2024)
Publisher: IRG Secretariate
Date published: 2024
Organisation Unit: National Centre for Timber Durability and Design Life
Language: English
Record Identifier: 991081898802621
Output Type: Conference paper

Metrics

1 Record Views