文献类型：期刊文献

中文题名：水热处理温度对马尾松早材与晚材拉伸蠕变行为的影响

英文题名：Effect of Hydrothermal Treatment Temperature on Tensile Creep Behavior of Earlywood and Latewood of Pinus massoniana

作者：黄鹤[1] 李珠[1] 蒋佳荔[1] 李媛[1]

第一作者：黄鹤

机构：[1]中国林业科学研究院木材工业研究所,北京100091

年份：2025

卷号：39

期号：1

起止页码：22-29

中文期刊名：木材科学与技术

外文期刊名：Chinese Journal of Wood Science and Technology

收录：;北大核心:【北大核心2023】；

基金：国家自然科学基金“基于生长轮尺度的早材与晚材机械吸湿蠕变行为及其互作机制”(32071689)。

语种：中文

中文关键词：饱水木材;早材;晚材;温度;瞬时弹性变形;黏弹变形;Burger模型

外文关键词：water-saturated wood;earlywood;latewood;temperature;instantaneous elastic deformation;viscoelastic deformation;Burger model

分类号：S791.248;S781.2

摘要：在不同温度水平下开展饱水马尾松(Pinus massoniana)同一生长轮内早材与晚材拉伸蠕变行为的对比研究,在生长轮尺度上揭示饱水木材的拉伸蠕变特性,并运用Burger模型对饱水早材与晚材的拉伸蠕变特性进行模拟预测。结果表明:任一温度水平下,无论沿轴向还是弦向拉伸时,饱水早材比晚材更易发生瞬时弹性变形与黏弹变形;在30~80℃温度范围内,饱水早材与晚材的瞬时弹性变形受温度影响不显著,黏弹变形随温度的升高而增大,且晚材的黏弹变形对温度变化较为敏感,拉伸蠕变初始阶段所需时间较短。Burger模型可以模拟饱水早材与晚材沿轴向与弦向的拉伸蠕变过程,拟合的决定系数(R2)大于0.956。
A comparative study on the tensile creep behavior of earlywood(EW)and latewood(LW)obtained from the same growth ring of Masson pine(Pinus massoniana)was carried out at different temperature levels of hydrothermal treatment,to reveal the characteristics of the tensile creep behavior of water-saturated wood at the growth ring level.The tensile creep characteristics were then simulated using the Burger model for prediction.The results showed that EW was more prone to generate instantaneous elastic deformation and viscoelastic deformation than LW at each temperature level,regardless of tangential or longitudinal tension.The temperature ranging from 30℃to 80℃had no significant effect on the instantaneous elastic deformation of both EW and LW from Masson pine while the viscoelastic deformation and the plastic deformation heightened with the increasing temperature.The viscoelastic deformation of LW was more sensitive to temperature change than that of EW.The time required for the initial creep stage in LW was shorter than that in EW.The Burger model was approved to simulate the creep characteristic of water-saturated EW and LW under tangential and longitudinal tension,with a coefficient of determination(R2)of greater than 0.956.