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Mechanical properties and constitutive relationship of the high-durable parallel strand bamboo

Sewar, Yousef Y. ; Zhang, Zhancheng ; Meng, Xinmiao ; Wahan, Mohammed Y. ; Qi, Hanxiao ; Al-Shami, Qahtan M. and Luo, Shijiao (2022) In Journal of Renewable Materials 10(1). p.219-235
Abstract

Engineered bamboo has recently received lots of attention of civil engineers and professional researchers due to its better mechanical performance than that of softwood timber. Parallel strand bamboo is one important part of engineered bamboo for its excellent durable performance compared to the laminated veneer bamboo. The required curing temperature in hot-pressing process is usually higher than 120°C to reduce the content of nutritional ingredients and hemy cellulose, and to avoid the decay from the environment and insects. Nonetheless, the appearance of engineered bamboo gets darker with the increase of temperature during the hot-pressing process. In order to minimize the color deepening while maintaining the durability, a... (More)

Engineered bamboo has recently received lots of attention of civil engineers and professional researchers due to its better mechanical performance than that of softwood timber. Parallel strand bamboo is one important part of engineered bamboo for its excellent durable performance compared to the laminated veneer bamboo. The required curing temperature in hot-pressing process is usually higher than 120°C to reduce the content of nutritional ingredients and hemy cellulose, and to avoid the decay from the environment and insects. Nonetheless, the appearance of engineered bamboo gets darker with the increase of temperature during the hot-pressing process. In order to minimize the color deepening while maintaining the durability, a high-durable parallel strand bamboo (HPSB) with relative high hot-pressing temperature (140°C) was produced and tested. The present study investigates the mechanical performance through tension, compression, shear and bending tests. The experimental behavior of the specimens was identified, including the failure mode and load-displacement relationship. It was demonstrated that the HPSB material had better mechanical performance parallel to grain, making it as a considerable structural material. The average elastic modulus parallel to grain was 14.1 GPa, and the tensile and compressive strengths were 120.7 MPa and 121.0 MPa, respectively. The tension perpendicular to grain should be avoided in the practical application due to the lower strength and elastic modulus. Two stress-strain relationships of tension and compression parallel to grain, including three-linear and quadratic function models, were proposed and compared with the experimental results. The three-linear model was then applied to the finite element model. The finite element analysis using ANSYS software was conducted to validate the feasibility of the constitutive relationship. The quadratic function model showed better agreement with the experimental results, but the three-linear relationship was also precise enough to analyze the bending tests of HPSB material, whereas being less accurate to describe the elastic-plastic compression behavior.

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Please use this url to cite or link to this publication:
author
; ; ; ; ; and
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Bamboo scrimber, Constitutive relationship, Engineered bamboo, Finite element model, Mechanical property
in
Journal of Renewable Materials
volume
10
issue
1
pages
17 pages
publisher
Tech Science Press
external identifiers
  • scopus:85111726215
ISSN
2164-6325
DOI
10.32604/jrm.2021.016013
language
English
LU publication?
no
id
19a2809b-20b0-4b43-ac4a-b7cc86f3b99f
date added to LUP
2021-08-26 14:14:06
date last changed
2022-04-27 03:26:02
@article{19a2809b-20b0-4b43-ac4a-b7cc86f3b99f,
  abstract     = {{<p>Engineered bamboo has recently received lots of attention of civil engineers and professional researchers due to its better mechanical performance than that of softwood timber. Parallel strand bamboo is one important part of engineered bamboo for its excellent durable performance compared to the laminated veneer bamboo. The required curing temperature in hot-pressing process is usually higher than 120°C to reduce the content of nutritional ingredients and hemy cellulose, and to avoid the decay from the environment and insects. Nonetheless, the appearance of engineered bamboo gets darker with the increase of temperature during the hot-pressing process. In order to minimize the color deepening while maintaining the durability, a high-durable parallel strand bamboo (HPSB) with relative high hot-pressing temperature (140°C) was produced and tested. The present study investigates the mechanical performance through tension, compression, shear and bending tests. The experimental behavior of the specimens was identified, including the failure mode and load-displacement relationship. It was demonstrated that the HPSB material had better mechanical performance parallel to grain, making it as a considerable structural material. The average elastic modulus parallel to grain was 14.1 GPa, and the tensile and compressive strengths were 120.7 MPa and 121.0 MPa, respectively. The tension perpendicular to grain should be avoided in the practical application due to the lower strength and elastic modulus. Two stress-strain relationships of tension and compression parallel to grain, including three-linear and quadratic function models, were proposed and compared with the experimental results. The three-linear model was then applied to the finite element model. The finite element analysis using ANSYS software was conducted to validate the feasibility of the constitutive relationship. The quadratic function model showed better agreement with the experimental results, but the three-linear relationship was also precise enough to analyze the bending tests of HPSB material, whereas being less accurate to describe the elastic-plastic compression behavior.</p>}},
  author       = {{Sewar, Yousef Y. and Zhang, Zhancheng and Meng, Xinmiao and Wahan, Mohammed Y. and Qi, Hanxiao and Al-Shami, Qahtan M. and Luo, Shijiao}},
  issn         = {{2164-6325}},
  keywords     = {{Bamboo scrimber; Constitutive relationship; Engineered bamboo; Finite element model; Mechanical property}},
  language     = {{eng}},
  number       = {{1}},
  pages        = {{219--235}},
  publisher    = {{Tech Science Press}},
  series       = {{Journal of Renewable Materials}},
  title        = {{Mechanical properties and constitutive relationship of the high-durable parallel strand bamboo}},
  url          = {{http://dx.doi.org/10.32604/jrm.2021.016013}},
  doi          = {{10.32604/jrm.2021.016013}},
  volume       = {{10}},
  year         = {{2022}},
}