纤维表面改性及其表征手段研究进展
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摘要
综述了纤维表面改性的主要途径及发展趋势,着重阐述了物理法、化学法和生物改性法,同时对纤维改性效果的最新表征手段进行了论述及分析。具有能耗低、绿色环保、操作条件简单等优点的生物改性法以及研究开发纤维改性效果的新型表征手段将是今后该领域发展的主要方向。
The main ways and development trend of fiber surface modification are reviewed;the physical,chemical and biological modification methods are emphasized.At the same time,the latest characterization methods of fiber modification effect are discussed and analyzed.The biological modification method,which has the advantages of low energy consumption,green environmental protection and simple operating conditions,and the new characterization methods of fiber modification effect will be the main direction of the future development in this field.
The main ways and development trend of fiber surface modification are reviewed;the physical,chemical and biological modification methods are emphasized.At the same time,the latest characterization methods of fiber modification effect are discussed and analyzed.The biological modification method,which has the advantages of low energy consumption,green environmental protection and simple operating conditions,and the new characterization methods of fiber modification effect will be the main direction of the future development in this field.
引文
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[2]Saha P,Manna S,Chowdhury S R,et al.Enhancement of tensile strength of lignocellulosic jute fibers by alkalisteam treatment[J].Bioresour Technol,2010,101(9):3182-3187.
[3]Zhou X Y,Zheng F,Li H G,et al.An environment-friendly thermal insulation material from cotton stalk fibers[J].Energy and Buildings,2010,42(7):1070-1074.
[4]Li Y,Mai Y W,Ye L.Sisal fibre and its composites:a review of recent developments[J].Composite Science and Technology,2000,60:2037-2055.
[5]Kanelli M,Vasilakos S,Ladas S,et al.Surface modification of polyamide 6.6 fibers by enzymatic hydrolysis[J].Process Biochemistry,2017,59:97-103.
[6]Paul R.Functional Finishes for Textiles:An Overview[M].London:Woodhead Publishing,2015:1-14.
[7]Copponnex T J.Analysis and evaluation of the single-fiber fragmentation test[J].Composites Science and Technology,1996,56(8):893-909.
[8]Varelidis P C,Mccullough R L,Papaspyrides C D.The effect of temperature on the single-fiber fragmentation test with coated carbon fibers[J].Composites Science and Technology,1998,58(9):1487-1496.
[9]Srensen B F.Micromechanical model of the single fiber fragmentation test[J].Mechanics of Materials,2017,104:38-48.
[10]Sui W J,Chen H Z.Effects of water states on steam explosion of lignocellulosic biomass[J].Bioresource Technology,2016,199:155-163.
[11]Brugnago R J,Satyanarayana K G,Wypych F,et al.The effect of steam explosion on the production of sugarcane bagasse/polyester composites[J].Composites Part A:Applied Science and Manufacturing,2011,42(4):364-370.
[12]Seng H L,Zaidon A,Aik F A,et al.Effects of two-step post heat-treatment in palm oil on the properties of oil palm trunk particleboard[J].Industrial Crops and Products,2018,116:249-258.
[13]Oumarou N,Kocaefe D,Kocaefe Y.Some investigations on moisture injection,moisture diffusivity and thermal conductivity using a three-dimensional computation of wood heat treatment at high temperature[J].International Communications in Heat and Mass Transfer,2015,61:153-161.
[14]Shen M,Wang L,Chen F,et al.Effect of low-temperature oxygen plasma on the degumming of ramie fabric[J].Journal of Cleaner Production,2015,92:318-326.
[15]Correia D M,Ribeiro C,Sencadas V,et al.Influence of oxygen plasma treatment parameters on poly(vinylidene fluoride)electrospun fiber mats wettability[J].Progress in Organic Coatings,2015,85:151-158.
[16]Jiang J,Yao X,Xu C,et al.Influence of electrochemical oxidation of carbon fiber on the mechanical properties of carbon fiber/grapheme oxide/epoxy composites[J].Composites:Part A,2017,95:248-256.
[17]李素敏,张新立.氧化改性对碳纤维结构及性能影响的研究[J].化工管理,2015(21):56-57.
[18]Arslan C,Dogan M.The effects of silane coupling agents on the mechanical properties of basalt fiber reinforced poly(butylene terephthalate)composites[J].Composites Part B:Engineering,2018,146:145-154.
[19]Yang W,Zhang Y R,Yuen C Y,et al.Synthesis of phosphorus-containing silane coupling agent for surface modification of glass fibers:Effective reinforcement and flame retardancy in poly(1,4-butylene terephthalate)[J].Chemical Engineering Journal,2017,321:257-267.
[20]Kang H,Liu R,Huang Y.Graft modification of cellulose:Methods,properties and applications[J].Polymer,2015,70:A1-A16.
[21]Beyaz K,Charton M,Rouilly A,et al.Synthesis of graftcopolymers from palm cellulose and solketal acrylate and their characterization[J].Industrial Crops and Products,2017,97:32-40.
[22]Lucolano F,Liguori B,Aprea P,et al.Evaluation of biodegummed hemp fibers as reinforcement in gypsum plaster[J].Composites Part B:Engineering,2018,138:149-156.
[23]Bledzki A K,Mamun A A,Jaszkiewicz A,et al.Polypropylene composites with enzyme modified abaca fibre[J].Composites Science and Technology,2010,70(5):854-860.
[24]Wen Y,Niu M,Zhang B,et al.Structural characteristics and functional properties of rice bran dietary fiber modified by enzymatic and enzyme-micronization treatments[J].LWT-Food Science and Technology,2017,75:344-351.
[25]Mamun A A,Heim H P,Beg D H,et al.PLA and PP composites with enzyme modified oil palm fibre:A comparative study[J].Composites Part A:Applied Science and Manufacturing,2013,53(19):160-167.
[26]Kelly A,Tyson W R.Tensile properties of fibre-reinforced metals:Copper/tungsten and copper/molybdenum[J].Journal of the Mechanics and Physics of Solids,1965,13(6):329-350.
[27]Feillard P,Désarmot G,Favre J P.Theoretical aspects of the fragmentation test[J].Composites Science and Technology,1994,50(2):265-279.
[28]Ramirez F A,Carlsson L A,Acha B A.A method to measure fracture toughness of the fiber/matrix interface using the single-fiber fragmentation test[J].Composites Part A:Applied Science and Manufacturing,2009,40(6/7):679-686.
[29]Graciani E,Mantiˇc V,París F,et al.Numerical analysis of debond propagation in the single fibre fragmentation test[J].Composites Science and Technology,2009,69(15/16):2514-2520.
[30]Nishikawa M,Okabe T,Takeda N.Determination of interface properties from experiments on the fragmentation process in single-fiber composites[J].Materials Science and Engineering:A,2008,480(1/2):549-557.
[31]Torres F G,Cubillas M L.Study of the interfacial properties of natural fibre reinforced polyethylene[J].Polymer Testing,2005,24(6):694-698.