硅溶胶与GU/GMU树脂复合改性橡胶木的性能

doi:10.11707/j.1001-7488.20211011

摘要/Abstract

摘要：

目的: 采用硅溶胶与乙二醛-尿素（GU）/乙二醛-三聚氰胺-尿素（GMU）树脂混合溶液浸渍处理橡胶木，探究改性剂种类和浓度对橡胶木物理力学性能和热稳定性的影响，以扩大橡胶木的应用范围，提升橡胶木的附加值。方法: 以乙二醛、三聚氰胺和尿素为主要原料，分别合成GU、GMU树脂，与硅溶胶以不同比例配制成均一稳定的水溶性混合溶液。采用混合溶液浸渍处理橡胶木，并与硅溶胶改性橡胶木的增重率、尺寸稳定性和力学性能进行比较，通过热重（TG）、傅里叶变换红外光谱（FTIR）和场发射扫描电子显微镜-X射线能谱仪（FESEM-EDS）等手段，分析改性材的热性能、化学分子结构变化和微观构造。结果: 1）混合溶液改性材的增重率和尺寸稳定性随改性剂浓度增加而增大，当改性剂浓度相同时，S-GMU改性材的增重率和尺寸稳定性优于S-GU改性材；S-20% GMU改性材的增重率（28.32%）和抗胀缩率（42.02%）最大，相比S-20% GU改性材分别提高16.98%和14.40%。2）混合溶液改性材的抗弯强度随增重率增大而增加，S-20% GMU改性材的抗弯强度（114.96 MPa）相比S-20% GU改性材提高11.97%，弹性模量变化不大。3）S-GMU混合溶液起到稳定木材残留物的作用，S-GMU改性材热稳定性增强，S-20% GMU改性材残灰率分别是素材、硅溶胶改性材和S-20% GU改性材的5.25、1.20和1.12倍。4）S-GMU改性材在470 cm^-1和1 110 cm^-1附近出现Si—O—Si键和C—O—C醚键，说明硅溶胶和GMU树脂能够进入木材；同时，改性材在1 656 cm^-1和1 510 cm^-1处波峰强度下降，说明改性材的木质素和碳水化合物发生一定程度降解，其中S-20% GMU改性材降解程度最低。5）改性剂成功渗透并沉积在木材细胞腔和细胞壁中，S-20% GMU改性材中Si元素较多，Si元素与混合溶液分布均匀，改性剂浸渍效果更好；S-20% GMU改性材中N元素含量增多，说明GMU树脂能够进入木材。结论: 1）硅溶胶与GU/GMU树脂混合溶液浸渍处理橡胶木的增重率、尺寸稳定性和力学性能均优于硅溶胶改性材，且相同质量分数S-GMU改性材的性能优于S-GU改性材；2）硅溶胶和GMU树脂成功渗透并沉积在木材细胞腔和细胞壁中，S-GMU混合溶液起到稳定木材残留物的作用，S-GMU改性材热稳定性增强。

关键词: 橡胶木, 改性, 硅溶胶, GU树脂, GMU树脂

Abstract:

Objective: Rubber wood was modified by silica sol combined with glyoxal-urea(GU) resin, and by silica sol combined with glyoxal-melamine-urea(GMU) resin. The effects of type and solution concentration of modifiers on the physico-mechanical and thermal properties of rubber wood were studied. Method: GU resin and GMU resin were prepared by adopting glyoxal, melamine and urea as the modified monomer. By controlling the mass ratio of GU/GMU resin to silica sol, a homogeneous, stable, and water-soluble solution was prepared. Furthermore, weight percent gain, dimensional stability and mechanical properties of modified rubber wood with the mixture of GU/GMU resin and silica sol were determined, and the performances of the thermal stability, chemical structure, and microcosmic structure were also investigated by thermogravimetry(TG), Fourier transform infrared spectroscopy(FTIR), and field emission scanning electron microscopy-energy dispersive X-ray spectroscopy(FESEM-EDS). Furthermore, those properties of silica sol modified rubber were compared. Result: 1) With the increase of solution concentration of modifier, the weight percent gain and dimensional stability of modified wood with the mixture increased. The weight percent gain and dimensional stability of S-GMU modified wood were superior than those of S-GU modified wood with the same fraction of solution for modified wood. The highest values of weight percent gain and anti-swelling efficiency were 28.32% and 42.02% under S-20%GMU modified wood, which raised 16.98% and 14.40% than those of modified rubber with S-20%GU modified wood, respectively. 2) With the increase of weight percent gain, the bending strength of modified wood with the mixture increased. The bending strength of S-20%GMU modified wood was 114.96 MPa, which raised 11.97% than that of modified rubber with S-20%GU modified wood, and no obvious difference in elasticity modulus was observed between unmodified wood and modified wood. 3) S-GMU mixture played a role in stabilizing wood residues, and the thermal stability of S-GMU modified wood was enhanced. The wood residues rates of S-20%GMU modified wood, were 5.25, 1.20 and 1.12 times that of unmodified wood, silica sol modified wood and S-20%GU modified wood, respectively. 4) The absorption peak of Si-O-Si and C-O-C could be seen near to 470 cm^-1 and 1 110 cm^-1, respectively, which proved that the silica sol and GMU resin had entered into S-GMU modified wood. Simultaneously, the absorption peak intensities near to 1 656 cm^-1 and 1 510 cm^-1 were weakened, which indicated that the lignin and carbohydrates of modified wood were degraded to a certain extent. While S-20%GMU modified wood had the lowest degree of degradation. 5) The solution for modified wood was entered into and deposited in the cell lumen and cell wall. There were more Si elements in S-20%GMU modified wood. The Si elements and mixture were evenly distributed of S-20%GMU modified wood, and the modification effect was better. The content of N elements in S-20%GMU modified wood increased, indicating that GMU resin entered the wood. Conclusion: The weight percent gain, dimensional stability and mechanical properties of modified wood with the silica sol combined with GU/GMU resin were superior than those of silica sol modified wood. The properties of S-GMU modified wood were superior than those of S-GU modified wood with the same fraction of solution for modified wood. The silica sol and S-GMU resin were entered into and deposited in the cell lumen and cell wall of S-GMU modified wood. The S-GMU mixture played a role in stabilizing wood residues, and the thermal stability of modified wood was enhanced. Therefore, this study produced evidences of improvement in physico-mechanical and thermal properties of rubber wood treated with S-GMU.

Key words: rubber wood, modification, silica sol, glyoxal-urea resin, glyoxal-melamine-urea resin

中图分类号:

S781.7

平立娟,柴宇博,刘君良,孙柏玲. 硅溶胶与GU/GMU树脂复合改性橡胶木的性能[J]. 林业科学, 2021, 57(10): 111-119.

Lijuan Ping,Yubo Chai,Junliang Liu,Bailing Sun. Performance of Modified Rubber Wood by Silica Sol in Combination with GU/GMU Resin[J]. Scientia Silvae Sinicae, 2021, 57(10): 111-119.

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树脂Resin	外观Appearance	黏度Viscosity/(mPa·s)	pH	固含量Nonvolatile solid content(%)
GU	浅黄色溶液 Light yellow solution	2.47	7.5~8.5	45.27
GMU	浅黄色溶液 Light yellow solution	2.60	7.5~8.5	46.22

波数Wavenumber/cm^-1	吸收峰归属Assignments of absorption peaks
3 200~3 600	N—H和O—H伸缩振动N—H and O—H stretching vibration
2 900	CH₂和CH₃的C—H振动C—H bending vibration in CH₂ and CH₃
1 740	非共轭CO伸缩振动CO dis-conjugation stretching
1 656	木质素苯环共轭CO伸缩振动CO conjugation stretching vibration of benzene ring in lignin
1 590	N—H变形振动N—H deformation vibration
1 510	木质素苯环的骨架伸缩振动Stretching vibration of benzene ring in lignin
1 460	木质素、聚糖CH₂中C—H弯曲振动C—H bending vibration in CH₂ in lignin and polysaccharide
1 244	木质素中苯环-氧键伸缩振动和C—N伸缩振动Stretching vibration of benzene ring-oxygen bond in lignin and C—N stretching vibration
1 110	纤维素和半纤维素C—O—C伸缩振动C—O—C stretching vibration in cellulose and hemicellulose
1 055	C—O伸缩振动C—O stretching vibration
470	Si—O—Si弯曲振动Si—O—Si bending vibration

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