压缩率对杨木重组木表面硬度的影响

doi:10.11707/j.1001-7488.LYKX20220720

摘要/Abstract

摘要：

目的: 以速生人工林杨木为试验材料，利用定向重组技术制备高硬度重组木，揭示压缩率对杨木重组木表面硬度的影响规律，为杨木表面改性及其重组木制备工艺优化提供可靠的方法和科学依据。方法: 利用定向重组技术制备压缩率50%、55%和59%共3种杨木重组木，选取杨木、红榉和俄罗斯柞木为对照样，采用万能力学试验机测定3种木材和3种不同压缩率杨木重组木样品表面的金氏硬度；应用超景深三维显微镜（UDTM）、场发射扫描电镜（SEM）观察样品表面的宏观和微观形貌以及样品金氏硬度测试过程中破坏面的宏观和微观形貌；运用压汞法（MIP）测试样品孔隙率；使用激光共聚焦显微镜（LSCM）和透射电子显微镜（TEM）表征酚醛树脂在重组木中的分布情况。结果: 杨木重组木的金氏硬度随压缩率增大而增大，与杨木相比，压缩率59%杨木重组木的金氏硬度增加12.63倍，其硬度高于俄罗斯柞木和红榉。金氏硬度测试过程中的应力-应变曲线显示，压缩率越大，重组木的比例极限应力越大。场发射扫描电镜（SEM）和超景深三维显微镜（UDTM）观察可知，杨木原木的破坏面呈韧性断裂，制备的重组木随压缩率增大其破坏模式逐渐变为脆性断裂。压汞法（MIP）测试样品孔隙率可知，定向重组可显著降低杨木的孔隙率，压缩率越大，重组木的孔隙率越低。激光共聚焦显微镜（LSCM）和透射电子显微镜（TEM）观察可知，随压缩率增大，酚醛树脂沿胶层带分布的宽度和深度逐渐增加，且渗透到导管、木射线和纤维细胞的细胞腔中。通过纳米压痕测试重组木细胞壁力学性能，当重组木压缩率为55%、施胶量为15%时，其细胞壁硬度和弹性模量相较原木分别提高54.65%和20.14%。重组木表面硬度增大主要是因为杨木经定向重组后，其导管和木纤维细胞被压缩密实，孔隙率降低，单位体积内的细胞实质密度增加，细胞之间的结合面积增大，连接更紧密；同时，引入的酚醛树脂不仅将压缩的细胞结构固定，而且通过形成的胶钉可提高细胞之间的连接强度，浸入细胞壁的酚醛树脂还能够增强其硬度和弹性模量，从而赋予重组木表面较高的硬度。结论: 定向重组技术可有效解决速生人工林杨木木材材质软、表面硬度低的问题，且可通过控制压缩率调控重组木硬度，以满足不同应用场景对材料硬度的需求。

关键词: 速生杨木, 定向重组, 压缩率, 硬度, 重组木

Abstract:

Objective: In order to provide reliable methods and scientific basis for the modification of poplar wood surface and the optimization manufacturing process of wood scrimber, the directional recombination technology was applied to manufacture the wood scrimber of poplar with high-hardness, and then the effect of compression ratios (CR) on the surface hardness of wood scrimber was studied. Method: The wood scrimber with compression ratios of 50%, 55% and 59% were prepared by the directional recombination technology, and the poplar, beech and Russian oak were taken as the control samples. The values of Janka hardness was measured by the universal mechanical testing machine. And the macroscopic and microscopic morphology of samples, as well as the damaged surface for samples during the testing process of Janka hardness were observed by ultra-depth-of-field three-dimensional microscope (UDTM) and field emission scanning electron microscope (SEM). Additionally, the porosity of the samples was tested by mercury injection porosimetry (MIP) and distribution of phenol-formaldehyde resin (PF) within the wood scrimber was characterized by laser scanning confocal microscopy (LSCM) and transmission electron microscopy (TEM). Result: The Janka hardness values of wood scrimber increased with increasing compression ratios. The Janka hardness value of wood scrimber with compression ratio of 59% increased by 12.63 times compared with that of poplar wood. Furthermore, the Janka hardness value of wood scrimber was much higher than those of Russian oak and beech. In practical applications, the appropriate compression ratio of the wood scrimber can be determined according to the needs in different area. The analysis of stress-strain curve of Janka hardness showed that the proportional ultimate stress of wood scrimber increased with increasing compression ratio. The observation of SEM and UDTM revealed that the failure surface of poplar wood was ductile fracture, but changed to brittle fracture for the wood scrimber. The porosity of the samples tested by MIP showed that directed recombination technology significantly reduced the porosity of poplar wood, and the porosity of the wood scrimber decreased with increasing compression ratio. The observation of LSCM and TEM showed that the width and depth of PF resin distributed along the glue layer band gradually increased with increasing compression ratio and penetrated into the vessel, wood rays and fiber cells. The cell wall mechanical properties of the wood scrimber were tested by nanoindentation. When the compression ratio of the wood scrimber was 55% and the resin content was 15%, the hardness and elastic modulus of the cell wall were increased by 54.65% and 20.14% compared with the poplar wood, respectively. The reasons for the increase in surface hardness of wood scrimber were as following: In the manufacturing process, the vessels and fiber cells of poplar wood were compressed, and the porosity of wood scrimber was reduced. Therefore, the parenchymal density of wood cells in per unit volume was increased. Additionally, the binding area between the wood cells is increased and the connections are tighter. Meanwhile, the PF not only fixed the compressed cell structure, but also increases the strength of the connection between the wood cells through the formed glue nails, the PF resin immersed in the cell wall also enhanced its hardness and elastic modulus, which effectively improved the surface hardness of the wood scrimber. Conclusion: The directional recombination technology can be applied to solve the soft problem and low surface hardness of poplar wood, and the surface hardness of the wood scrimber can be adjusted through the compression ratio, so that the products prepared by the directional recombination technology can meet the needs of different applications.

Key words: fast-growing poplar wood, directional reorganization, compression ratio, hardness, wood scrimber

中图分类号:

S781

贺颖奇,王鲁飞,张亚梅,余养伦,于文吉. 压缩率对杨木重组木表面硬度的影响[J]. 林业科学, 2024, 60(9): 141-149.

Yingqi He,Lufei Wang,Yamei Zhang,Yanglun Yu,Wenji Yu. Effect of Compression Ratios on the Surface Hardness of Poplar Wood Scrimber[J]. Scientia Silvae Sinicae, 2024, 60(9): 141-149.

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材料Material	压痕深度 Indentation depth/mm	回弹深度 Rebound depth/mm
杨木Poplar wood	1.85	0.97
压缩率50%的重组木 Wood scrimber with a compression ratio of 50%	1.39	1.43
压缩率55%的重组木 Wood scrimber with a compression ratio of 55%	1.22	1.60
压缩率59%的重组木 Wood scrimber with a compression ratio of 59%	1.08	1.74

材料Material	压入汞的总体积 Total intrusion volume/ (mL·g^?1)	平均孔径 Average pore diameter (4V/A)/nm	孔隙率 Porosity(%)
杨木Poplar wood	1.369 7	285.52	65.195 2
压缩率50%的重组木 Wood scrimber with a compression ratio of 50%	0.448 6	82.23	37.882 1
压缩率55%的重组木 Wood scrimber with a compression ratio of 55%	0.313 2	50.70	30.897 9
压缩率59%的重组木 Wood scrimber with a compression ratio of 59%	0.223 6	30.40	24.367 4

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