原态竹材湿热应变响应

doi:10.11707/j.1001-7488.20190715

摘要/Abstract

摘要： [目的]分析原态竹材对环境温度和相对湿度的应变响应，为原态竹材的尺寸稳定性和环境适用性研究提供基础依据。[方法]以我国6个城市的年均温度和相对湿度为基础数据，通过湿热图谱研究原态竹材的湿热应变行为，采用静态应变仪采集直径相似（96.52 mm±1.46 mm）但长度不同（500、400、300和200 mm）原态竹材依次经历6个阶段温湿度变化（5℃、66%；13℃、50%；20℃、70%；20℃、80%；30℃、80%；9℃、36%）过程中端部和中部的周向应变以及原态竹材的轴向应变数据，分析讨论温度、湿度和长度对原态竹材应变响应行为的影响。[结果]初始状态应变值设定为零，竹材水分蒸发收缩时应变为负，吸湿膨胀时应变为正，当温湿度骤然下降时，试样端部和中部膨胀应变急剧减小甚至开始收缩。竹材的周向应变为-500~3000με，轴向应变为-50~225με。原态竹材端部周向应变较敏感，中部周向应变出现滞后现象。长度为500和400 mm试样端部和中部的最大应变差较大，相比300和200 mm试样端部应变差差异显著；较短试样端部和中部的应变差从正值缩小为零后变为负值，端部和中部应变行为出现此消彼长现象。[结论]原态竹材能够对温湿度变化做出即时响应，温度、湿度和长度对原态竹材的应变响应具有明显影响，温度的影响主要依赖湿度导致竹材含水率变化来体现。周向应变与轴向应变行为相似，但明显大于轴向应变，端部对温湿度的响应更为敏感，中部响应有滞后现象，长度越长的竹材内部干缩或湿胀应力越不均衡。温湿度变化引起原态竹材内应力不均衡是原态竹材应变不均甚至开裂的主要原因。

关键词: 原态竹材, 湿热环境, 周向应变, 轴向应变, 应力分布

Abstract: [Objective] Environmental temperature and relative humidity (RH)play important roles in dimension deformation and physical mechanical properties of bamboo culm, the investigation of strain property of bamboo culm can provide a basis for dimensional stability and environmental adaptability of bamboo culm utilization in original status.[Method] Annual mean temperature and RH of six cities in China were selected and analyzed to research hygrothermal strain behavior of bamboo culm (Phyllostachys edulis). Bamboo culms with similar diameter (96.52 mm±1.46 mm)and different lengths (500,400,300 and 200 mm)were placed in test chamber undergoing the temperature and humidity environment which were successively changed with six stages (5℃,66%; 13℃,50%; 20℃,70%; 20℃,80%; 30℃,80%; 9℃,36%). The circumferential strain value of the top and middle parts and the axial strain value of bamboo culm were collected by static strain indicator, and the influence of temperature, humidity and length on bamboo culm response behavior were analyzed and discussed.[Result] The initial value of strain was set as zero, and the bamboo culm was shrinkage from laboratory environment to test chamber, the strain value was negative. Subsequently, the bamboo culm showed swelling with the increase of temperature and humidity for moisture adsorption, and the strain value was positive. Swelling strain value was declined quickly and even indicated shrinkage with the sharp decrease of temperature and humidity. Circumferential strain value range was -500-3 000 με,while axial strain value ranged from -50 to 225 με. Especially, the circumferential strain of top part displayed more sensitive to the temperature and humidity change, while the strain of middle part was hysteresis. The max strain difference between top and middle parts of bamboo culm with length of 500 and 400 mm was significantly larger than that of bamboo culm with length of 300 and 200 mm. The difference values of bamboo culm with length of 300 and 200 mm changed from positive to negative, and the strain displayed wane and wax.[Conclusion] Bamboo culm could make immediately response to environment changes, temperature, humidity and length had significant impacts on the swelling and shrinkage strain behaviors of bamboo culm and the influences of temperature were always reflected by humidity which was associated to moisture content of bamboo culm. Circumferential strain behavior was similar with that of axial strain, while its value was obviously greater than axial strain value, top part of bamboo culm was more sensitive to temperature and humidity, and the longer length means more strain difference between top and middle parts. The stress unequilibrium in longer bamboo culm induced by moisture element adsorption and release is the main reason for bamboo culm deformation and rupture.

Key words: bamboo culm, hygrothermal environment, annular strain, axial strain, stress distribution

中图分类号:

S781

闫薇, 张彬, 傅万四, 周建波. 原态竹材湿热应变响应[J]. 林业科学, 2019, 55(7): 137-145.

Yan Wei, Zhang Bin, Fu Wansi, Zhou Jianbo. Hygrothermal Strain Response of Bamboo Culm[J]. Scientia Silvae Sinicae, 2019, 55(7): 137-145.

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