吸湿解吸循环过程中木材水分吸附特性

doi:10.11707/j.1001-7488.LYKX20220793

摘要/Abstract

摘要：

目的: 探究吸湿解吸循环过程中木材水分吸附特性，阐释湿度循环对木材细胞壁及其吸着水分子的影响机制，为木材的实际使用和合理开发提供理论依据和数据参考。方法: 以杉木和马尾松木材为试验材料，采用动态水分吸附分析仪在3或5次吸湿解吸循环（0%→95%→0%）过程中实时测定木材水分吸附数据，绘制水分吸着-解吸等温线，借助H-H模型对其吸湿平衡含水率进行非线性拟合分析。结果: 1）吸湿解吸循环前后，木材平衡含水率最大值呈降低趋势，其差值范围为0.21%~1.76%；初次循环过程木材吸湿平衡含水率低于后续循环过程，相对湿度40%~95%时尤为明显；2）随着吸湿解吸循环次数增加，木材单次循环所需时间减少，且降低幅度也明显变小；与块状试样相比，粉末状试样单次循环所需时间较少；3）初次循环过程木材吸湿滞后现象相比后续循环过程更明显，随着循环次数增加，吸湿滞后最大值减小，吸湿滞后率均值增大；4） H-H模型可用于分析吸湿解吸循环过程中木材水分等温吸附，其拟合度（R²）均高于0.996；随着循环次数增加，代表含有单位摩尔吸附位点的绝干木材质量（W）参数呈降低趋势，木材单分子层吸附水最大质量分数呈增大趋势，多分子层吸附水最大质量分数和吸附水总质量分数最大值均呈降低趋势。结论: 随着吸湿解吸循环次数增加，湿度循环对木材细胞壁的影响减弱：木材吸湿性能降低，其平衡含水率最大值呈降低趋势；单次循环所需时间减少；吸湿滞后现象减弱。

关键词: 杉木, 马尾松, 湿度循环, 水分吸附, H-H模型

Abstract:

Objective: The variations of water vapor sorption behavior of wood was investigated during cyclic adsorption-desorption processes, aiming at clarifying the response mechanism of wood cell wall and its adsorbed water to the cyclical humidity variation, and providing theoretical guidance and data reference for the actual usage and rational development of wood. Method: The moisture adsorption/desorption isotherms of Chinese fir (Cunninghamia lanceolata) and masson pine (Pinus massoniana) were measured synchronously by Dynamic vapor sorption analysis during three or five adsorption-desorption cycles among 0% to 95% to 0%. The equilibrium moisture content (EMC) data of samples in the adsorption process were nonlinearly fitted by H-H model. Result: 1) Before and after the sorption cycles, the maximum EMC of samples showed a decreasing trend, and the difference value was ranged from 0.21% to 1.76%. The EMC in the initial cycle was lower than that in the subsequent cycles, especially between 40% and 95% relative humidity. 2) With the increase of the number of sorption cycles, the time required for one single sorption cycle of samples decreased, and the reduction degree also became obviously smaller. Compared with the solid samples, the single sorption cycle of the powder samples required less time. 3) The hygroscopic hysteresis of samples in the initial cycle was more obvious than that in the subsequent cycles. The maximum value of absolute hysteresis decreased and the mean hysteresis coefficient increased with the increase of the number of sorption cycles. 4) The H-H model could be used to describe the water adsorption isotherms of samples during the sorption cycles with R² above 0.996. With the increase of the number of sorption cycles, the parameter W which means the apparent molecular mass of the absolute dry wood per sorption sites decreased, the maximum amount of monolayer molecules water increased, and while the maximum amount of polylayer molecules water and the total amount of adsorbed water decreased. Conclusion: With the increase of the number of sorption cycles, the response of wood cell wall to cyclical humidity variation of samples were weakened: the hygroscopicity of samples decreased, and the maximum EMC showed a decreasing trend; the time required for one single sorption cycle was reduced; and the hygroscopic hysteresis of samples decreased.

Key words: Chinese fir, masson pine, cyclical humidity variation, water adsorption, H-H model

中图分类号:

S781

都亚敏,李珠,蒋佳荔,殷方宇,吕建雄. 吸湿解吸循环过程中木材水分吸附特性[J]. 林业科学, 2024, 60(9): 150-158.

Yamin Du,Zhu Li,Jiali Jiang,Fangyu Yin,Jianxiong Lü. Water Vapor Sorption Characteristics of Wood During Cyclic Adsorption-Desorption Processes[J]. Scientia Silvae Sinicae, 2024, 60(9): 150-158.

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参考文献 0

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试样Samples	循环次数Cycle times	W/(g·mol^?1)	M_h,max(%)	M_s,max(%)	M_t,max(%)
CF-S	第1次吸湿解吸循环Cycle 1	336.73	4.71	15.59	20.30
	第2次吸湿解吸循环Cycle 2	297.92	5.39	13.93	19.32
	第3次吸湿解吸循环Cycle 3	294.35	5.45	13.52	18.96
CF-P	第1次吸湿解吸循环Cycle 1	334.62	4.47	15.26	19.74
	第2次吸湿解吸循环Cycle 2	277.34	5.07	13.99	19.05
	第3次吸湿解吸循环Cycle 3	271.81	5.11	13.81	18.92
MS-NW	第1次吸湿解吸循环Cycle 1	416.18	3.84	13.17	17.01
	第2次吸湿解吸循环Cycle 2	310.91	4.53	12.20	16.73
	第3次吸湿解吸循环Cycle 3	298.14	4.64	12.16	16.80
	第4次吸湿解吸循环Cycle 4	286.26	4.73	11.70	16.43
	第5次吸湿解吸循环Cycle 5	297.14	4.67	11.72	16.39
MS-CW	第1次吸湿解吸循环Cycle 1	332.27	4.82	18.97	23.80
	第2次吸湿解吸循环Cycle 2	270.98	5.51	16.79	22.30
	第3次吸湿解吸循环Cycle 3	265.52	5.44	16.62	22.06

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