环保快干型木蜡油的制备及其涂饰性能

doi:10.11707/j.1001-7488.LYKX20210570

摘要/Abstract

摘要：

目的: 制备一种绿色环保、快干型木蜡油，并对其漆膜性能进行表征，为木蜡油的发展与工业化应用提供理论依据和技术支持。方法: 以天然、可再生的植物油和蜡为主要成膜原料，以抗坏血酸棕榈酸酯（L-AsA₆P）和异辛酸铁（Fe-eh）作为协同催干剂，制备出一种环保快干型木蜡油；以商业木蜡油为对照组，对沙比利基材进行涂饰，测试木蜡油的干燥时间、硬度、附着力、耐水性、色度、粗糙度和接触角等；使用扫描电镜对基材涂饰前后的表面形貌进行表征，重点观察基材细胞腔及木蜡油对其的填充情况；应用傅里叶变换红外光谱仪扫描得到木蜡油及基材涂饰前后的FTIR 光谱，分析各试样特征峰的峰位、峰高、峰宽等变化。结果: L-AsA₆P与Fe-eh配比对木蜡油的干燥时间、光泽度和接触角均有较大影响。当L-AsA₆P与Fe-eh中Fe³⁺的摩尔比为5∶1时，木蜡油干燥速度最快，表干和实干时间分别为1.2和3.5 h，相比商业木蜡油分别缩短25%和34.3%；光泽度提高1.1倍，接触角长时间保持在95°以上，且其硬度、附着力、耐水性与商业木蜡油相当，色差总值（ΔE）低于商业木蜡油。扫描电镜分析表明，环保快干型木蜡油不仅能够填充基材表面裸露的细胞腔，还可通过纹孔渗透到木材内部；红外分析证实，木蜡油脂肪酸链中的羧基与基材中的羟基发生酯化反应，形成牢固化学结合，展现出优异的附着性能。结论: L-AsA₆P与Fe-eh协同催干剂对木蜡油具有较好催干效果，当L-AsA₆P与Fe-eh中Fe³⁺的摩尔比为5∶1时，制备的木蜡油干燥性能最佳，对基材的附着和保护能力强，且可有效提升基材表面效果。

关键词: 木蜡油, 涂饰, 环保, 快干, 木材

Abstract:

Objective: In order to protect the surface and improve the visual effect of wood, this paper presents a preparation method and properties of the green, environmentally-friendly and fast-drying wax oil for wood, which provides theoretical basis and technical supports for the development and industrialization of wood wax oil. Method: Taking natural and renewable vegetable oil and wax as the main film-forming materials, ascorbic acid 6-palmitate (L-AsA₆P) and iron[III] 2-ethylhexanoate (Fe-eh) were used as the synergistic drying agent to prepare an environmentally-friendly and fast-drying wood wax oil. Then the commercial wood wax oil as the control group, Entandrophragma cylindricum was used as the coating substrate, and the properties of the film were also evaluated. Result: The experimental results showed that the ratio of L-AsA₆P to Fe-eh had significant effects on the drying time, glossiness and contact angle of wood wax oil. It had the fastest dry speed when the molar ratio of L-AsA₆P to Fe³⁺ in Fe-eh was 5∶1, its surface dry time was 1.2 h and the actual dry time was 3.5 h; compared with the dry time of reference samples, it was decreased by 25% and 34.3%, respectively. Its glossiness was increased by 1.1 times, and the contact angle was always kept above 95°, so the purposes that improving the visual effect and hydrophobicity of wood was achieved. In addition, the hardness, adhesion, water resistance of the film were similar to those of control group, and the total color difference（ΔE) was lower. The analysis of digital images collected by scanning electron microscope (SEM) showed that the prepared wood wax oil not only filled the bare cell cavities on the surface of the substrate, but also penetrated into the inside of the wood through the pits. It was confirmed by FTIR spectroscopies that the esterification reaction took place between carboxyl groups in the fatty acid chains of wood wax oil and hydroxyl groups in the substrate, which formed strong chemical bonds, and presented excellent adhesion performance. Conclusion: L-AsA₆P and Fe-eh as the synergistic drying agents had positive effects on increasing the drying speed of the wood wax oil. When the molar ratio of L-AsA₆P to Fe³⁺ was 5∶1, the prepared wood wax oil had the best drying performance, strong adhesion and protection abilities to the substrate. Furthermore, it could improve the surface decoration effect of the substrate effectively.

Key words: wood wax oil, finishing, environment protection, fast-drying, wood

中图分类号:

TQ630.1

皇权飞,黄艳辉,刘颖,林欣雨. 环保快干型木蜡油的制备及其涂饰性能[J]. 林业科学, 2023, 59(7): 137-144.

Quanfei Huang,Yanhui Huang,Ying Liu,Xinyu Lin. Preparation and Finishing Properties of Environmentally-Friendly and Fast-Drying Wood Wax Oil[J]. Scientia Silvae Sinicae, 2023, 59(7): 137-144.

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参考文献 0

	贺克强. 涂料催干剂的进展与反应机理. 武汉工业大学学报, 2000, 18 (4): 16- 19.
	He K Q. The developments and reaction mechanism in driers for coating. Journal of Wuhan University of Technology, 2000, 18 (4): 16- 19.
	黄艳辉, 冯启明, 董天悦, 等. 浅析木蜡油的应用、研究现状及发展趋势. 林产工业, 2019, 46 (1): 7- 11.
	Huang Y H, Feng Q M, Dong T Y, et al. Brief analysis of the application, research status and development tendency of wood wax oil. China Forest Products Industry, 2019, 46 (1): 7- 11.
	彭云云, 武书彬. TG-FTIR联用研究半纤维素的热裂解特性. 化工进展, 2009, 28 (8): 1478- 1484. doi: 10.3321/j.issn:1000-6613.2009.08.037
	Peng Y Y, Wu S B. Characteristics and kinetics of sugarcana bagasse hemicellulose pyrolysis by TG-FTIR. Chemical Industry and Engineering Progress, 2009, 28 (8): 1478- 1484. doi: 10.3321/j.issn:1000-6613.2009.08.037
	王金满, 戴澄月, 刘一星. 木材纹孔膜微孔尺寸与数目计算. 东北林业大学学报, 1990, 18 (6): 46- 53.
	Wang J M, Dai C Y, Liu Y X. Calculation of pit opening radii and number of opening in wood pit membrane. Journal of Northeast Forestry University, 1990, 18 (6): 46- 53.
	薛晓明, 谢春平, 孙小苗, 等. 樟和楠木的木材解剖结构特征和红外光谱比较研究. 四川农业大学学报, 2016, 34 (2): 178- 184.
	Xue X M, Xie C P, Sun X M, et al. Comparason on anatomical structure and FTIR spectra between Cinnamomum camphora and Phoebe zhennan woods . Journal of Sichuan Agricultural University, 2016, 34 (2): 178- 184.
	朱建民, 余漂洋, 颜　杰. 影响木蜡油干燥时间因素的探讨. 化工技术与开发, 2015, 44 (8): 4- 6,16. doi: 10.3969/j.issn.1671-9905.2015.08.002
	Zhu J M, Yu P Y, Yan J. Discussion on influence factors of drying time of wood wax oil. Technology & Development of Chemical Industry, 2015, 44 (8): 4- 6,16. doi: 10.3969/j.issn.1671-9905.2015.08.002
	Arminger B, Jaxel J, Bacher M, et al. On the drying behavior of natural oils used for solid wood finishing. Progress in Organic Coatings, 2020, 148 (11): 105831.
	Chen H L, Ferrari C, Angiuli M, et al. Qualitative and quantitative analysis of wood samples by Fourier transform infrared spectroscopy and multivariate analysis. Carbohydrate Polymers, 2010, 82 (3): 772- 778. doi: 10.1016/j.carbpol.2010.05.052
	Chen C J, Luo J J, Huang X P, et al. Analysis on cellulose crystalline and FTIR spectra of Artocarpus heterophyllus lam wood and its main chemical compositions . Advanced Materials Research, 2011, 236/237/238, 369- 375.
	de Boer J W, Wesenhagen P V, Wenker E C M, et al. The quest for cobalt-free alkyd paint driers. European Journal of Inorganic Chemistry, 2013, 21, 3581- 3591.
	Gezici K Ö. In-depth study of drying solvent-borne alkyd coatings in presence of Mn- and Fe-based catalysts as cobalt alternatives. Materials Today Communications, 2016, 7 (1): 22- 31.
	Kalenda P, Veselý D, Kalendová A, et al. Ferrocene-based catalyst systems for alkyd paint drying. Pigment & Resin Technology, 2010, 39 (6): 342- 347.
	Li X, Wang D, Zhao L, et al. UV LED curable epoxy soybean-oil-based waterborne PUA resin for wood coatings. Progress in Organic Coatings, 2021, 151 (1): 105942.
	Lin R H, Sun J, Yue C, et al. Study on preparation and properties of phenol-formaldehyde-Chinese fir liquefaction copolymer resin. Maderas: Ciencia y Tecnología, 2014, 16 (2): 159- 174.
	Mihaila A, Lisa C, Ipate A M, et al. Determination of the effective diffusion coefficient during the drying of paint and varnish films applied on fir wood. Progress in Organic Coatings, 2019, 137 (1): 105344.
	Mandal M, Maji T K. Preparation, physical properties and ultraviolet resistance of wood nanocomposites based on modified soybean oil and bentonite. Wood Material Science & Engineering, 2019, 14 (6): 381- 391.
	Miccichè F, Oostveen E, Haveren J V, et al. The combination of reducing agents/iron as environmentally friendlier alternatives for co-based driers in the drying of alkyd paints. Progress in Organic Coatings, 2004, 53 (2): 99- 105.
	Miccichè F, Haveren J V, Oostveen E, et al. Oxidation and oligomerization of ethyl linoleate under the influence of the combination of ascorbic acid 6-palmitate/iron-2-ethylhexanoate. Applied Catalysis A:General, 2006, 297 (2): 174- 181. doi: 10.1016/j.apcata.2005.09.008
	Nussbaum R M, Sutcliffe E J, Hellgren A C, et al. Microautoradiographic studies of the penetration of alkyd, alkyd emulsion and linseed oil coatings into wood. Journal of Coatings Technology, 1998, 70 (878): 49- 57.
	Ou J H, Zhang M, Liu H L, et al. Matting films prepared from waterborne acrylic/micro-SiO₂blends . Journal of Applied Polymer Science, 2015, 132 (13): 41707- 41715.
	Pandey K K, Pitman A J. FTIR studies of the changes in wood chemistry following decay by brown-rot and white-rot fungi. International Biodeterioration & Biodegradation, 2003, 52 (3): 151- 160.
	Peng Y, Wang Y, Chen P, et al. Enhancing weathering resistance of wood by using bark extractives as natural photostabilizers in polyurethane-acrylate coating. Progress in Organic Coatings, 2020, 145 (1): 105665.
	Rosu L, Varganici C D, Mustata F R, et al. Enhancing the thermal and fungal resistance of wood treated with natural and synthetic derived epoxy resins. ACS Sustainable Chemistry & Engineering, 2018, 6 (4): 5470- 5478.
	Schwanninger M, Rodrigues J C, Pereira H, et al. Effects of short-time vibratory ball milling on the shape of FT-IR spectra of wood and cellulose - ScienceDirect. Vibrational Spectroscopy, 2004, 36 (1): 23- 40. doi: 10.1016/j.vibspec.2004.02.003
	Soucek D, Khattab T, Wu J, et al. Review of autoxidation and driers. Progress in Organic Coatings, 2012, 73 (4): 435- 454. doi: 10.1016/j.porgcoat.2011.08.021
	Stava V, Erben M, Vesely D, et al. Properties of metallocene complexes during the oxidative crosslinking of air drying coatings. Journal of Physics and Chemistry of Solids, 2006, 68 (5): 799- 802.
	Varganici C D, Rosu L, Rosu D, et al. Sustainable wood coatings made of epoxidized vegetable oils for ultraviolet protection. Environmental Chemistry Letters, 2021, 19 (1): 307- 328. doi: 10.1007/s10311-020-01067-w
	Xin Y, Mct A, Amv A. A comparative study on the artificial UV and natural ageing of beeswax and Chinese wax and influence of wax finishing on the ageing of Chinese ash (Fraxinus mandshurica) wood surfaces . Journal of Photochemistry and Photobiology B:Biology, 2019, 201, 111607. doi: 10.1016/j.jphotobiol.2019.111607
	Yilgor N, Dogu D, Moore R, et al. Evaluation of fungal deterioration in Liquidambar orientalis Mill . heartwood by FT-IR and light microscopy. BioResources, 2013, 8 (2): 2805- 2826.
	Yuan J, Hu Y C, Li L F, et al. The mechanical strength change of wood modified with DMDHEU. BioResources, 2013, 8 (1): 1076- 1088.

样品 Sample	硬度 Hardness	耐水性 Water resistance	光泽度 Glossiness	附着力 Adhesion
Z0	H	1级 Grade 1	17.48	0级Grade 0
Z3:1	H	1级 Grade 1	12.57	0级Grade 0
Z4:1	H	1级 Grade 1	15.44	0级Grade 0
Z5:1	H	1级 Grade 1	36.64	0级Grade 0
Z6:1	H	1级 Grade 1	22.33	0级Grade 0
基材Substrate	/	/	3.47	/

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