摘要
<正>夏双双等[25]利用DNA水溶胶对聚乳酸织物进行阻燃整理,工艺流程是浸轧(带液率为70%~80%)→烘干(50℃)。处理织物的性能按JISL1091—1999测试,结果如下:未处理的聚乳酸织物炭化面积为5.2 cm2,布样损毁面积较大;5 g/L DNA处理织物的炭化面积为2.0 cm2,与未处理织物相比有较大的改善,10 g/L和15 g/L DNA处理织物的炭
引文
[1]陈水林,杜鹃.溶胶-凝胶技术在纺织品上的应用[J].印染助剂,2010(4):49.
[2]黄仲涛.无机膜技术及其应用[M].北京:中国石化出版社,1999.
[3]徐壁,蔡再生.溶胶-凝胶技术及其在纺织品多功能整理中的应用[J].印染助剂,2008(9):2.
[4]吕凯,陈冲林,王潮霞.涤棉织物的改性硅溶胶/有机硅聚氨酯疏水整理[J].印染,2017,43(17):7-10.
[5] ZHAO Q, WU LYL, HUANG H, LIU Y. Ambient-curable superhydrophobic fabric coatingprepared by water-based non-fluorinated formulation[J]. Materials&Design,2016,92:541-545.
[6]薛朝华,贾顺田,张静,等.二氧化钛溶胶-凝胶法制备含氟超疏水棉织物[J].印染,2009,35(23):1-3.
[7] XUE CH, LI M, GUO XJ, LI X, AN QF, JIA ST. Fabrication of superhydrophobic textiles with high water pressure resistance[J].Surface and Coatings Technology,2017,310:134-142.
[8] HAO L, GAO T, XU W,et al.Preparation of crosslinked polysiloxane/SiO2nanocomposite via in-situ condensation and its surface modification on cotton fabrics[J]. Applied Surface Science,2016,371:281-288.
[9] ZHANG J, LI B, WU L,et al.Facile preparation of durable and robust superhydrophobictextiles by dip coating in nanocomposite solution of organosilanes[J]. Chemical Communications,2013,49(98):11509-11511.
[10] VASIL JEVIC J, GORJANC M, JERMAN I, et al.Influence of oxygen plasma pre-treatment on the water repellency of cotton fiberscoated with perfluoroalkyl-functionalized polysilsesquioxane[J].Fibers and Polymers,2016,17(5):695-704.
[11] PRZYBYLAK M, MACIEJEWSKI H, DUTKIEWICZ A.Preparation of highly hydrophobic cottonfabrics by modification with bifunctional silsesquioxanes in the sol-gel process[J]. Applied Surface Science,2016,387:163-174.
[12] XUE CH, JIA ST, CHEN HZ, WANG M. Superhydrophobic cotton fabrics prepared by sol-gel coating of TiO2and surface hydrophobization[J]. Science and Technology of Advanced Materials,2008,9(3):1-4.
[13] ONAR N, METE G. Development of water repellent cotton fabric with application of ZnO, Al2O3, TiO2and ZrO2nanoparticles modified with ormosils[J]. Tekstil ve Konfeksiyon, 2016, 26(3):295-302.
[14] ONAR N, METE G, AKSIT A, et al. Water-and oil-repellency properties of cotton fabric treated with silane, Zr, Ti based nanosols[J]. International Journal of Textile Science, 2015, 4(4):84-96.
[15] COLLEONI C, GUIDO E, MIGANI V, et al. Hydrophobic behaviour of non-fluorinatedsol-gel based cotton and polyester fabric coatings[J]. Journal of Industrial Textiles, 2015, 44(6):815-834.
[16]庄伟,徐丽慧,方晓华,等.棉织物的改性Si02水溶胶耐久超疏水整理[J].印染,2011,37(17):10-13.
[17] COLLEONI C,GUIDO E, MIGANI V, et al. Hydrophobic behaviour of non-fluorinatedsol-gel based cotton and polyester fabric coatings[J]. Journal of Industrial Textiles,2015,44(6):815-834.
[18]徐丽慧,蔡再生,沈勇,等.超疏水棉织物的硅水溶胶制备法[J].印染,2014,40(5):5-8.
[19] TELI MD, ANNALDEWAR BN.Superhydrophobic and ultraviolet protective nylon fabricsby modified nano silica coating[J]. The Journal of the Textile Institute, 2016:1-8.
[20]林志华,倪海燕,李永贵,等.涤纶织物的溶胶-凝胶法易清洁整理[J].印染,2017,43(5):40-43.
[21] DE FERR L, LORENZI A, CARCANO E, et al. Silk fabrics modification by sol-gel method[J].Textile Research Journal. 2018(1):99-107.
[22]蒲泽佳,侯建硕,陈迎春,等.涤纶织物的有机硅改性硅溶胶超疏水整理[J].印染,2015,41(20):1-3.
[23] VASILJEVIC J, ZORKO M, TOMSIC B, et al.Fabrication of the hierarchicallyroughened bumpy-surface topography for the longlasting highly oleophobic“lotus effect”on cotton fibres[J]. Cellulose, 2016, 23(5):3301-3318.
[24]皮婷婷,陈煌煌,吴雯,等.蒙脱土与DNA复合溶胶对涤棉织物阻燃整理[J].针织工业,2016(9):53-54.
[25]夏双双,吴丽.DNA水溶胶对聚乳酸织物的阻燃整理[J].中国纤检,2016(2):143-144.
[26] GRANCARIC AM, COLLEONI C, GUIDO E, et al. Thermal behaviour and flameretardancy of monoethanolamine-doped sol-gel coatings of cotton fabric[J].Progress in Organic Coatings, 2017,103:174-181.
[27]皮婷婷,王宇航,李敏,等.涤棉织物的蒙脱土/乳清蛋白复合溶胶阻燃整理[J].印染,2015,41(6):28-31.
[28] BOUKHRISS A, GMOUH S, HANNACH H, et al.Treatment ofcotton fabrics by ionic liquid with PF6-anion for enhancing their flame retardancy andwater repellency[J]. Cellulose, 2016, 23(5):3355-3364.
[29]郑成志,赵曙辉,陈晓渝.蒙脱土杂化硅溶胶整理织物的热性能[J].印染,2013,39(16):6-9.
[30] KAPPES RS, URBAINCZYK T, ARTZ U, et al. Flame retardants basedon amino silanes and phenylphosphonic acid[J]. Polymer Degradation and Stability, 2016, 129:168-179.
[31]赵静然,张胜,谷晓昱,等.尼龙66的阻燃水溶胶整理[J].印染,2015,41(10):6-11.
[32] ZHANG QH, GU J, CHEN GQ, XING TL. Durable flame retardant finish for silk fabric usingboron hybrid silica sol[J]. Applied Surface Science, 2016, 387:446-453.
[33]张维,张强华,邓典,等.羊毛织物的含磷硅溶胶阻燃整理[J].印染,2014(11):1-5.
[34]?EHIC A, TOM?IC B, JERMAN I, et al. Synergistic inhibitoryaction of P-and Si-containing precursors in sol-gel coatings on the thermal degradationof polyamide 6[J]. Polymer Degradation and Stability, 2016, 128:245-252.
[35] DEH S, G?HR F, BUCHMEISER MR. Synergistic effects in the pyrolysis of phosphorus-basedflame-retardants:the role of Si-and N-based compounds[J]. Polymer Degradation andStability, 2016,130:155-164.
[36] LIU Y, PAN YT, WANG X, et al.Effect of phosphorus-containing inorganic-organic hybrid coating on the flammability of cotton fabrics:synthesis, characterization and flammability[J]. Chemical Engineering Journal, 2016, 294:167-175.
[37] REN Y, ZHANG Y, ZHAO J, et al. Phosphoru-doped organic-inorganichybrid silicon coating for improving fire retardancy of polyacrylonitrile fabric[J]. Journa lof Sol-Gel Science and Technology,2017(4):280-288.
[38] LIU S, ZHANG Q, XU Z, et al. Surface modification of TiO2/SiO2composite hydrosol stabilized with polycarboxylic acid on Kroyprocess wool fabric[J]. Journal of Adhesion Science and Technology, 2017(11):1209-1228.
[39]盛国旗,侯强.棉织物的纳米Ti02溶胶在抗紫外整理[J].印染,2006,32(19):32-34.
[40] DHINESHBABU NR, ARUNMETHA S, MANIVASAKAN P, et al. Enhanced functional properties of cotton fabrics using TiO2/SiO2nanocomposites[J]. Journal of Industrial Textiles, 2016, 45(5):674-692.
[41]叶凤英,黄雅婷,王黎明,等.棉织物纳米TiO2溶胶自清洁功能整理工艺[J].印染,2013,39(22):11-14.
[42] RILDA Y, FADHLI F, SYUKRI S, et al. Self-cleaning TiO2-SiO2clusters on cotton textile prepared by dip-spin coating process.Journal Tecknology,2016,78(7):113-120.
[43] WANG L, SHEN Y, XU L, et al. Thermal crystallization of lowtemperaturepreparedanatase nano-TiO2and multifunctional finishing of cotton fabrics[J]. The Journal of the Textile Institute,2016,107(5):651-662.
[44] SHABAN M, ABDALLAH S, KHALEK AA. Characterization and photocatalytic properties ofcotton fibers modified with ZnO nanoparticles using sol-gel spin coating technique[J]. Beni-Suef University Journal of Basic and Applied Sciences, 2016, 5(3):277-283.
[45] NOORIAN SA, HEMMATINEJAD N, BASHARI A. One-pot synthesis of Cu2O/ZnO nano particles at present of folic acid to improve UV-protective effect of cotton fabrics[J]. Photo chemistry and Photobiology, 2015, 91(3):510-517.
[46]尹用飞,徐壁,蔡再生.N-TiO2/SiO2气凝胶整理棉织物的抗紫外和自清洁性能[J].印染,2014,40(13):14-17.
[47] POLI R, COLLEONI C, CALVIMONTES A, et al. Innovative sol–gel route in neutral hydroalcoholic condition to obtain antibacterial cotton finishing byzinc precursor[J]. Journal of Sol-Gel Science and Technology,2015,74(1):151-160.
[48]吉友美,邢彦军,戴瑾瑾,等.基于溶胶-凝胶技术的棉织物银锌复合抗菌整理[J].印染,2008,34(6):7-9.
[49] MAHLTIG B, GRETHE T, HAASE H. Handbook of Sol-Gel Science and Technology[M]. Kluwer academic, 2002.
[50]徐利蓉,李登新,陈小立,等.棉织物的Ag/TiO2复合溶胶抗菌整理[J].印染,2006,32(19):4-7.
[51]高晓红,孟臣,孟康.等.丝胶/纳米银溶胶的制备及其对涤纶的改性[J].印染,2015,41(12):1-3.
[52]李慧,龚国利,弓太生.等.抗菌整理剂溶胶的稳定性及其整理工艺[J].印染,2012,38(9):1-3.
[53]赵晓伟.棉织物的TiO2/ZnO水溶胶-凝胶抗菌整理.印染,2015,41(11):35-37.
[54] SCHRAMM C, BINDER WH, TESSADRI R. Durable press finishing of cotton fabric with 1,2,3,4-butanetetracarboxylic acid and TEOS/GPTMS[J]. Journal of Sol-Gel Science and Technology,2004, 29:155-165.
[55]郑成辉,陈国强,李辉棉.织物溶胶-凝胶法抗紫外线/防皱整理[J].印染,2010,36(20):10-13.
[56]代欣欣,闵洁,邢彦军,等.锦纶织物的SiO2/TiO2复合水溶胶超亲水整理[J].印染,2012,38(6):32-35.
[57]徐鹏,王晓文,陈水林.溶胶-凝胶法改善涤纶抗静电性能初探[J].印染,2005,31(21):4-6.
[58]汪青,王明,陈水林.涤纶织物掺杂La3+的TiO2/SiO2水溶胶抗静电整理[J].印染,2010,36(13):12-15.
[59]祝曙升,陈志祥,阎克路.棉针织物的溶胶-凝胶法抗起球整理[J].印染,2008,34(23):9-11.
[60]林桂凤,阎克路.纳米Al2O3/GPTMS复合溶胶的羊毛防毡缩整理[J].印染,2006,32(20):1-5.
[61]蔡淑君,杜鹃,赵曙辉.纳米TiO2溶胶在负离子整理中的应用[J].印染,2009,35(8):15-18.
[62]李青,马晓光.氧化硅-脂肪醇复合溶胶制备蓄热调温织物[J].印染,2009,35(15):6-10.
[63]吴海培,高晓红,刘其霞.羊毛和蚕丝织物的TiO2水溶胶防泛黄整理[J].印染,2016,42(22):29-32.
[64]林辉敏,方熙,赵曙辉.棉织物的PhTES改性硅溶胶热致变色整理[J].印染,2012,38(12):9-12.
[65] MAHLTIG B, TEXTOR T, KUMBASAR PA.Photo bactericidal and photochromic textile materials realized by embedding of advantageous dye using sol-gel technology[J].Celal BayarUniversity Journal of Science,2015,11(3):306-315.
[66] MEMON H, YASIN S, KHOSO NA, et al. Study of wrinkle resistant, breathable, anti-UV nanocoated woven polyester fabric[J].Surface Review and Letters, 2016, 23(03):1-8.
[67]杨世玉,卢坤,郭爱兰,等.真丝织物的钛氟溶胶抗紫外拒水整理[J].印染,2013,39(3):10-12.
[68] ONAR N, METE G. Development of water-, oil-repellent and flame-retardant cotton fabrics by organic-inorganic hybrid materials[J].The Journal of the Textile Institute,2016,107(11):1463-1477.
[69] IBAHIM NA, EID BM, EL-AZIZ EA, et al. Functionalization of linen/cotton pigment prints using inorganic nanostructure materials.Carbohydrate Polymers,2013,97:537-545.
[70] PAN C, SHEN L, SHANG S, et al. Preparation of super hydrophobic and UV blocking cotton fabric via sol-gel method and self-assembly. Applied Surface Science, 2012,259:110-117.
[71] SIMONCIC B, TOMSIC B, CERNE L, et al. Multifunctional water and oil repellent and antimicrobial properties of finished cotton:influence of sol–gel finishing procedure[J]. Journal of Sol-Gel Science and Technology.2012;61:340-354.
[72] MAHLTIG B, FISCHER A. Inorganic/organic polymer coatings for textiles to realize water repellent and antimicrobial properties—a study with respect to textile comfort. Journal of Polymer Science Part B:Polymer Physics, 2010, 48(14):1562-1568.
[73] TEXTOR T, MAHLTIG B. A sol-gel based surface treatment for preparation of water repellent antistatic textiles[J]. Applied Surface Science,2010,256:1668-1674.
[74] EL-SHAFEIM A, ELSHEMYA, ABOU-OKEIL. Eco-friendly finishing agent for cotton fabrics to improve flame retardant and antibacterial properties[J].Carbohydrate Polymers,2015,118(3):83-90.
[75] RANA M, HAO B, MU L, et al. Development of multi-functional cotton fabrics with Ag/AgBr-TiO2nanocomposite coating[J].Composites Science and Technology,2016,122:104-112.
[76] EL-NAGGAR ME, SHAHEEN TI, ZAGHLOUL S, et al. Antibacterial activities and UV protection of the in situ synthesized titanium oxide nanoparticles on cotton fabrics[J]. Industrial&Engineering Chemistry Research,2016,55(10):2661-2668.
[77] SIVAKUMAR A, MURUGAN R, PERIYASAMY S. Evaluation of multifunctional properties of polyester/cotton blend treated with unmodified and modified nano-TiO2particles. Materials Technology,2016,31(5):286-298.
[78] BEHZADNIA A, MONTAZER M, MAHMOUDI RAD M. In-situ photos on synthesis of organic/inorganic nanocomposites on wool fabric introducing multifunctional properties. Photochemistry and Photobiology. 2016;92(1):76-86.
[79] GU JL, ZHANG QH, CHEN YB, et al. Thermal properties and water repellency of cotton fabric prepared through sol-gel method[J].Thermal Science,2016;20(3):863-866