高温中木材顺纹弦面抗剪强度

doi:10.11707/j.1001-7488.20220112

摘要/Abstract

摘要：

目的: 研究高温中大截面承重木构件最外侧炭化层保护下内部受热区木材顺纹弦面抗剪强度及其劣化规律, 为木结构抗火性能精细化设计和过火结构构件剩余承载力评估提供数据支撑。方法: 以木结构建筑常用进口兴安落叶松和花旗松以及强度等级较高、具有结构用材潜在应用价值的国产速生杨木3种木材为研究对象, 采用环境试验箱内充满氮气的方法模拟绝氧环境, 在20、50、70、110、150、200、220、250和280 ℃共9个温度水平下测试216个试件的顺纹抗剪强度, 以及150、180和200 ℃下木材主要化学组分变化。结果: 木材顺纹抗剪强度随着温度升高而降低, 常温时兴安落叶松、花旗松和杨木的顺纹抗剪强度分别为9.65、8.94和9.48 MPa, 温度升至150 ℃时, 分别降至初始值的60.7%、68.0%和65.6%, 当温度高于150 ℃时, 木材顺纹抗剪强度下降速度加快, 280 ℃时兴安落叶松、花旗松和杨木的顺纹抗剪强度分别为1.05、0.91和0.61 MPa, 仅为初始值的9.0%、10.2%和6.4%; 木材主要化学组分中纤维素热稳定性最高, 半纤维素热稳定性最低, 常温时兴安落叶松、花旗松和杨木的半纤维素含量分别为25.3%、25.7%和16.3%, 150 ℃时半纤维素开始热解, 其含量减少1.3%~9.1%, 温度升至200 ℃时热解加剧, 其含量分别降低29.4%、18.6%和25.9%, 高温中半纤维素严重热解是导致木材顺纹抗剪强度降低的主要因素; 随着温度升高, 密度对木材顺纹抗剪强度的影响逐渐降低, 常温时木材抗剪强度-密度关系系数为14.2 MPa·(g·cm^-3)^-1, 当温度高于200 ℃时, 抗剪强度-密度关系系数降至1.1~3.1; 高温中3种木材的相对顺纹抗剪强度劣化规律相似。结论: 高温对木材顺纹抗剪强度具有显著劣化作用, 其主要原因是木材半纤维素含量大幅度降低; 试验采用绝氧方式导致木材顺纹抗剪强度高温折减系数较欧标规定小; 基于试验数据, 提出绝氧条件下木材顺纹抗剪强度高温劣化模型。

关键词: 结构用木材, 化学组分, 顺纹弦面抗剪强度, 高温, 绝氧环境

Abstract:

Objective: In order to provide data for the refined design on fire resistance of timber structures and the evaluation on residual bearing capacity of structural members exposed to fire, the parallel-to-grain tangential shear strength of heated wood within structural member with a large cross section under the protection of the outermost charred layer was tested, and its degradation model was built. Method: Imported Larix gmelinii and Pseudotsuga menziesii, and domestic fast-growing Populus spp. with a high strength grade and potential application in timber structure, were selected as the research objects. A test chamber filled with nitrogen was used in this study to simulate the oxygen-free conditions. The temperatures were set to nine levels, such as 20, 50, 70, 110, 150, 200, 220, 250 and 280 ℃. As many as 216 specimens were tested to determine the parallel-to-grain shear strength of wood specimens at temperatures between 20 and 280 ℃ under oxygen-free conditions. The main chemical compositions of wood specimens at 150, 180 and 220 ℃ was also determined. Result: At room temperature, the shear strengths of Larix gmelinii, Pseudotsuga menziesii, and Populus spp. wood specimens were 9.65, 8.94 and 9.48 MPa, respectively. When the temperature reached 150 ℃, the shear strength of Larix gmelinii, Pseudotsuga menziesii, and Populus spp. of wood specimens decreased to 60.7%, 68.0% and 65.6% of the initial values, respectively. The shear strength of wood specimens decreased faster, as the temperature was 150 ℃ and higher. The shear strengths of Larix gmelinii, Pseudotsuga menziesii, and Populus spp. of wood specimens were determined as 1.05, 0.91 and 0.61 MPa at 280 ℃, respectively, which were only 9.0%, 10.2% and 6.4% of the initial values. The thermal stability of cellulose was the highest and that of hemicellulose was the lowest among the main chemical compositions within wood. The hemicellulose contents of Larix gmelinii, Pseudotsuga menziesii, and Populus spp. of wood specimens were 25.3%, 25.7% and 16.3% at room temperature, respectively. At 150 ℃, hemicellulose started to be decomposed and its content decreased by 1.3%-9.1%. Hemicellulose was decomposed rapidly at 200 ℃, and its content decreased by 29.4%, 18.6% and 25.9%, respectively. The degradation on parallel-to-grain shear strength of wood specimens was attributed to the serious pyrolysis of hemicellulose at high temperature. With the increase of temperature, the effects of wood density on parallel-to-grain shear strength gradually decreased. The ratio of shear strength to wood density was determined as 14.2 MPa·(g·cm^-3)^-1 at room temperature, and decreased to 1.1- 3.1 MPa·(g·cm^-3)^-1 at 200 ℃ and above. The degradation on relative shear strength of three wood species was similar with each other at elevated temperatures. Conclusion: High temperature might be negatively related with parallel-to-grain shear strength, causing by the reduction in hemicellulose content. The reduction factor of wood shear strength at a high temperature is less than that in European standard due to the oxygen-free conditions used in this study. Based on the test data, a bilinear model of wood parallel-to-grain shear strength deterioration at a high temperature was proposed.

Key words: structural wood, chemical composition, parallel-to-grain tangential shear strength, high temperature, oxygen-free condition

中图分类号:

岳孔,陆栋,胡文杰,戴长路,吴鹏,陆伟东. 高温中木材顺纹弦面抗剪强度[J]. 林业科学, 2022, 58(1): 111-118.

Kong Yue,Dong Lu,Wenjie Hu,Changlu Dai,Peng Wu,Weidong Lu. Parallel-to-Grain Tangential Shear Strength of Wood at Elevated Temperatures under Oxygen-Free Conditions[J]. Scientia Silvae Sinicae, 2022, 58(1): 111-118.

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指标 Index	兴安落叶松 Larix gmelinii	花旗松 Pseudotsuga menziesii	杨木 Populus spp.
顺纹抗压强度 Parallel-to-grain compressive strength	61.3	56.2	46.5
顺纹抗拉强度 Parallel-to-grain tensile strength	98.2	128.9	96.4
抗弯强度 Bending strength	104.7	90.0	78.4
抗弯弹性模量 Modulus of elasticity in bending	13 833	14 324	11 720

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