Influence of the outer skin on the flexural properties and thermal conductivity of densified Dendrocalamus asper bamboo

A.D. de Sá , M. Kadivar , G.H.A. Barbirato , A. Tarverdi , S. Kadivar , L.M. do Amaral , H. Savastano Júnior
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Abstract

In this work, the effect of densification and the maintenance of the outer skin on the flexural properties and thermal conductivity of Dendrocalamus asper Backer ex K.Heyne bamboo was investigated. The results showed improvements in bending resistance for the densified samples compared to the un-densified bamboo. Densified samples with the outer skin showed the highest bending strength. Samples with the outer culm wall in compression offered the best results, with an average modulus of rupture (MOR) of around 348.9 MPa and modulus of elasticity (MOE) of 28.4 GPa. These values are around 40% and 86% (MOR), and 17% and 30% (MOE) higher compared to densified samples without the skin and un-densified samples, respectively. The fracture sections of specimens after bending tests were analyzed using Scanning Electron Microscopy (SEM) to visualize crack propagation within the outer skin and bamboo tissues. Maintaining the skin increases the thermal conductivity, and the densified bamboo with the skin has a thermal conductivity of around 0.23 W/m.K, 12.8% higher than the densified bamboo without skin and 22.5% higher than un-densified bamboo. Although a reduction in thermal performance was achieved, it was concluded that is reasonable to keep the bamboo skin, as it improves the overall mechanical resistance and reduces material loss during bamboo processing.

表皮对致密化麻竹弯曲性能和导热性能的影响
本工作研究了致密化和外皮维护对松竹弯曲性能和热导率的影响。结果表明,与未致密的竹子相比,致密样品的抗弯性有所提高。具有外皮的致密样品显示出最高的弯曲强度。具有压缩外秆壁的样品提供了最好的结果,平均断裂模量(MOR)约为348.9MPa,弹性模量(MOE)为28.4GPa。与没有表皮和未致密样品的致密样品相比,这些值分别高出约40%和86%(MOR,17%和30%)。使用扫描电子显微镜(SEM)分析弯曲试验后试样的断裂截面,以观察裂纹在外皮和竹组织内的扩展。保持表皮增加了热导率,有表皮的致密竹子的热导率约为0.23W/m.K,比没有表皮的致密竹高12.8%,比未致密竹高22.5%。尽管热性能有所降低,但得出的结论是,保留竹皮是合理的,因为它提高了整体机械阻力,并减少了竹子加工过程中的材料损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
0.90
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