Surface modification of nano-alumina and its application in preparing polyacrylate water-based wood coating
-
Ling Long
,
Xianglong Wan
Abstract
In order to solve weakness, undesirable abrasion resistance, and hardness of a water-based wood coating film, modified surface nano-alumina was made in the water-based wood coating. The effect of surfactant type and amount on the performance of nano-alumina slurry was investigated. How the performance of the polyacrylate wood coating was affected by the size, amount, and mixing method of nano slurry was studied, as well as the characterization of nano-alumina slurry and modified polyacrylate wood coating. The results showed that, by compounding the non-ionic surfactant polyoxyethylene octylphenol ether (OPEO) and anionic surfactant sodium polyacrylate of surface modification of nano-alumina, the nano-alumina slurry had excellent performance and good stability when the amount of nano-alumina was 0.6 wt% and 3.2 wt%, respectively. When 1.5 wt% of nano slurry was mixed with the water-based polyacrylate emulsion to a hybrid during the pre-emulsification phase, the wood coating film had high performance, and good abrasion resistance and hardness.
The authors gratefully acknowledge the financial support of the State Forestry National Commonweal Research of CAF (NO. 201304501).
References
[1] Feng F, Feng J, Liang H. Wood Coating and Coating Technology, Chemical Industry Press: Beijing, 2008.Search in Google Scholar
[2] Désor D, Krieger S, Apitz G, Kuropka R. Surf. Coat. Int. 1999, 82, 488–496.Search in Google Scholar
[3] Philipp C, Eschig S. Prog. Org. Coat. 2012, 74, 705–711.Search in Google Scholar
[4] Bongiovanni R, Montefusco F, Priola A, Macchioni N, Lazzeri S, Sozzi L, Ameduri B. Prog. Org. Coat. 2002, 45, 359–363.Search in Google Scholar
[5] Custodio JEP, Eusebio MI. Prog. Org. Coat. 2006, 56, 59–67.Search in Google Scholar
[6] Zhang x, Wang F, Huan J. Paint Coat. Industry 2004, 8, 37–40.Search in Google Scholar
[7] Yuan j. Shanghai Build. Mater. 2010, 6, 18–21.Search in Google Scholar
[8] Wu Z, Ye R. China Coat. 2009, 1, 64–66.Search in Google Scholar
[9] Zhang Y, Qiu Y. Chem. Ind. Eng. Prog. 2010, 29, 918–921.Search in Google Scholar
[10] Ji T. Dispersion-type Inorganic Nano-particles. Science Press: Beijing, 2009.Search in Google Scholar
[11] HG/T 3828-2006. Water Based Coatings for Indoor Woodenware. Chemical Industry Press: Beijing, 2007.Search in Google Scholar
[12] Wan X. Preparation and Properties of Waterborne Wooden Nano-Coating. China University of Mining and Technology: Beijing, 2007.Search in Google Scholar
©2013 by Walter de Gruyter Berlin Boston
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Articles in the same Issue
- Masthead
- Masthead
- Original articles
- Grafting of maleic anhydride on polypropylene by reactive extrusion: effect of maleic anhydride and peroxide concentrations on reaction yield and products characteristics
- An optical system for measuring the residence time distribution in co-rotating twin-screw extruders
- Effect of processing technology on the morphological, mechanical and electrical properties of conductive polymer composites
- Thermodynamic modeling of polyamide-6 (PA-6)/cellulose acetate (CA) blend membrane prepared via casting technique
- Monte Carlo simulation of ionic conductivity in polyethylene oxide
- Impact fracture toughness and morphology of polypropylene/Mg(OH)2 composites
- High impact toughness of polyamide 6/poly (vinylidene fluoride) blends induced by an ionic liquid
- Application of chemically-cross-linked chitosan for the removal of Reactive Black 5 and Reactive Yellow 84 dyes from aqueous solutions
- Flame retardation behaviors of UV-curable phosphorus-containing PU coating system
- Preparation and characterization of modified chitosan for in vitro controlled release of vitamin B12
- Surface modification of nano-alumina and its application in preparing polyacrylate water-based wood coating
