含氟聚氨酯的合成及其纳米纤维化的超双疏性能研究

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静电纺双疏型聚丙烯腈基纳米纤维膜制备及其性能仝伟;方汝仙;李家炜;易玲敏【摘要】为制备耐磨性能良好的双疏型纤维膜并将其应用于油/水、油/油分离领域,以静电纺丝方法制备的聚丙烯腈(PAN)纳米纤维为基材,采用多巴胺(DA)与十三氟辛基三乙氧基硅烷(G617)对纤维膜进行改性制得双疏型PAN纤维膜.借助扫描电子显微镜、接触角测量仪、X射线光电子能谱仪等手段探讨纺丝条件、DA与G617用量等对改性前后PAN纤维膜表面形貌以及疏水疏油性能的影响.结果表明:纺丝液中PAN质量分数为13.8％、纺丝电压为18 kV时,纤维形貌最佳;改性后PAN纤维膜的乙二醇接触角可达135.1°,甲苯接触角为0°,水接触角可达141.9°,色拉油接触角可达131.2°;摩擦20次后PAN纤维膜的水、色拉油接触角均大于125°,可顺利实现水/甲苯、甲苯/乙二醇以及甲苯/水乳液的分离.【期刊名称】《纺织学报》【年(卷),期】2019(040)001【总页数】8页(P1-8)【关键词】静电纺丝;聚丙烯腈;纳米纤维膜;多巴胺改性;油/水分离;油/油分离【作者】仝伟;方汝仙;李家炜;易玲敏【作者单位】浙江理工大学材料与纺织学院、丝绸学院,浙江杭州 310018;浙江理工大学先进功能涂层研究所,浙江杭州 310018;浙江理工大学先进纺织材料与制备技术教育部重点实验室,浙江杭州 310018;浙江理工大学生态染整技术教育部工程研究中心,浙江杭州 310018;浙江理工大学材料与纺织学院、丝绸学院,浙江杭州 310018;浙江理工大学先进功能涂层研究所,浙江杭州 310018;浙江理工大学先进纺织材料与制备技术教育部重点实验室,浙江杭州 310018;浙江理工大学生态染整技术教育部工程研究中心,浙江杭州 310018;浙江理工大学材料与纺织学院、丝绸学院,浙江杭州 310018;浙江理工大学先进功能涂层研究所,浙江杭州310018;浙江理工大学先进纺织材料与制备技术教育部重点实验室,浙江杭州310018;浙江理工大学生态染整技术教育部工程研究中心,浙江杭州 310018;浙江理工大学材料与纺织学院、丝绸学院,浙江杭州 310018;浙江理工大学先进功能涂层研究所,浙江杭州 310018;浙江理工大学先进纺织材料与制备技术教育部重点实验室,浙江杭州 310018;浙江理工大学生态染整技术教育部工程研究中心,浙江杭州 310018【正文语种】中文【中图分类】TQ340.649近年来，人们在进行膜蒸馏或过滤实验时发现，许多疏水膜容易吸附杂质而导致膜污染或润湿而降低其使用性能。

[19]中华人民共和国国家知识产权局[12]发明专利申请公开说明书[11]公开号CN 1315483A[43]公开日2001年10月3日[21]申请号00103573.8[21]申请号00103573.8[22]申请日2000.03.29[71]申请人中国科学院化学研究所地址100080北京市海淀区中关村北1街2号郑家玉转[72]发明人刘必前 宋延林 江雷 [51]Int.CI 7C09K 3/18权利要求书 2 页 说明书 6 页[54]发明名称一种超双疏（疏水、疏油）表面处理剂和用途[57]摘要本发明一种超双疏(疏水、疏油)表面处理剂是由含氟有机硅氧烷化合物(C n F 2n+1X)2N[CH 2CH 2N(C n F 2n+1X)]y CH 2CH 2CH 2Si(OR)340－80份(其中y=0,1,2;n=2－10的整数;R=－CH 3,－C 2H 5;X=－CH 2CH 2－,或－SO 2NR 1CH 2CH 2－：R 1=H,或C 1－C 4的烷基);硅酸酯(CH 3)m Si(OR 4)4－m 4－12份(其中R 4=－CH 3,－C 2H 5;m=0,1,2);全氟代乙烷(CF 2ClCFCl 2,CF 2ClCF 2Cl,CFCl 2CFCl 2或CF 3CCl 3)100－500份,水0－2份和浓H 2SO 4 0－2份组成。

本发明可用于玻璃、陶瓷、金属、纸制品、塑料、纤维和纺织物表面的防油、防水处理及鱼雷、舰船和输油、输水管道的减阻处理。

00103573.8权 利 要 求 书第1/2页1．一种超疏水、疏油表面处理剂，其特征在于所述的表面处理剂由以下组分和含量(重量份数)组成：(1)氟代有机硅氧烷化合物 40-80份；所述的氟代有机硅氧烷化合物的结构式为：(C n F2n+1X)2N[CH2CH2N(C n F2n+1X)]y CH2CH2CH2Si(OR)3其中y=0,1,2；n=2-10的整数；R=-C H3,-C2H5；X=-C H2C H2-，或-S O2N R1C H2C H2-； R1为H，或C1-C4的烷基(2)硅酸酯(CH3)m Si(OR4)4-m 4-12份其中R4=-CH3,-C2H5；m=0,1,2。

含氟聚氨酯材料的制备方法及其应用研究（一）含氟聚氨酯材料是一类新型高分子功能材料。

由于氟基团的引入，具有表面能低、化学性质稳定和憎水憎油等特性，含氟聚氨酯兼具有含氟聚合物和聚氨酯的优点，自从在1958年Lovelace以非氟化异氰酸酯与氟化二醇反应首次合成含氟聚氨酯以来便立即引起了高分子科研界的广泛兴趣，现如今含氟聚氨酯的研究已在国内外形成了研究热潮。

本文重点论述了含氟聚氨酯的合成及性能方面的研究，并简要介绍含氟聚氨酯材料在不同领域的应用。

含氟聚氨酯制备性能应用Synthesis, properties and application of fluorinated polyurethaneAbstractFluorinated polyurethane (FPU) is a species of novel macromolecule functional materials.Due to the introduction of fluorinated groups,FPU has very low surface energy,excellent resisitance to chemicals,water and oil.Fluorinated polyurethane combines virtues of polyurethane and fluorinated polymers, such as excellentresistance to ultraviolet radiation and nuclear radiation and excellent flexility, good wearability, lower surface energy and high weatherability. Therefore, the study of fluorinated polyurethane has attracted considerable interest more and more in recent years. The synthesis, properties and applications of fluorinated polyurethane were reviewed.Key words：fluorinated polyurethane,synthesis,properties,application1.含氟聚氨酯的合成1.1 含氟聚氨酯的研究背景含氟聚氨酯（FPU）兼具有含氟化合物和聚氨酯的优点。

静电纺纳米纤维空气过滤材料1多级结构纳米纤维膜在纤维表面构筑多级结构有助于提升其表面粗糙度，从而可有效增大纳米纤维膜的比表面积、孔体积和孔隙率，使固体颗粒物与纤维发生碰撞或黏附的概率增大，最终实现纳米纤维膜过滤性能的大幅提升。

如图3-4所示，通过将浓度为6wt%的PAN溶液与添加SiO纳米颗粒（SNP）的浓度为12wt%的PAN溶液进行肩并肩纺丝，获得了具有多级结构的PAN-6/PAN-12—SiO复合纳米纤维膜。

图3-4 PAN-6/PAN-12—SiO复合纤维膜的（a）制备示意图；（b）结构模拟图；（c）场发射扫描电子显微镜（FE-SEM）图通过调控PAN-6/PAN-12喷头数量比可以得到具有无规堆积结构的PAN纤维膜，其中纤维直径为600～700nm的PAN-12作为纤维膜的骨架纤维，并且随着PAN-12喷头比例的增加，粗纤维数量逐渐增多，纤维直径在100～200nm的PAN-6穿插于骨架纤维之间。

因此，PAN-6/PAN-12的喷头数量比直接决定了纤维膜的堆积密度，从而影响纤维膜的过滤性能。

从图3-5（a）中可以看出，当PAN-6/PAN-12的喷头数量比从4/0变化至0/4时，PAN纤维膜的过滤效率从73.64%降低到11.1%，阻力压降从64.5Pa降低到8.2Pa。

当PAN-6/PAN-12的喷头数量比为3/1时，纤维膜具有最佳的过滤效率，其对应的QF值为0.0229Pa。

进一步研究中，固定PAN-6/PAN-12的喷头数量比为3/1，通过调控PAN-12纺丝溶液中SiO纳米颗粒的含量（0、4wt%、8wt%、12wt%）构筑了具有多级结构的PAN/SNP复合纳米纤维膜。

如图3-5（b）所示，复合纳米纤维膜的N吸附—脱附等温曲线均呈现IV型的等温线，其吸附行为包括单分子层吸附、多层吸附和毛细管冷凝阶段，说明了所制备复合纤维具有介孔结构。

此外，随着SiO纳米颗粒含量的增加，纤维膜的比表面积从6.56m/g增加至26.97m/g，说明SiO纳米颗粒能够有效增加纤维膜的比表面积，如3-5（b）插图所示。

综述与专论合成纤维工业,2024,47(2):58CHINA㊀SYNTHETIC㊀FIBER㊀INDUSTRY㊀㊀收稿日期:2023-06-08;修改稿收到日期:2024-02-28㊂作者简介:陈海通(1999 ),男,硕士研究生,主要从事纳米纤维材料及功能性纺织品的研究㊂E-mail:chtloik@㊂基金项目:陕西省重点研发计划项目(2023-YBGY-487)㊂㊀∗通信联系人㊂E-mail:1141101240@㊂纳米材料在纺织领域的应用陈海通,王进美∗,王㊀丞,魏玲玲,何志宽(西安工程大学纺织科学与工程学院,陕西西安710048)摘㊀要:综述了纳米材料在纺织领域的应用现状及存在的问题,对今后的发展方向进行了展望㊂目前,纳米材料在纺织领域的应用非常广泛,将具有特殊功能的纳米材料与纺织原料进行复合,可以制备具有各种功能的织物,如抗菌㊁拒水拒油㊁抗紫外线㊁抗静电等㊂但在应用中也存在一些问题,如安全性㊁稳定性㊁可持续性和环境友好性㊁可操作性和成本,以及纺织品的可回收性等㊂今后,纳米材料在纺织品中的应用发展趋势和研究方向主要包括新材料和新技术的应用㊁环保型纳米材料及应用技术的开发㊁提高应用技术的可操作性和降低成本㊂关键词:纳米材料㊀纳米技术㊀功能纺织品㊀应用中图分类号:TQ342+.8㊀㊀文献标识码:A㊀㊀文章编号:1001-0041(2024)02-0058-06㊀㊀随着纳米技术的不断进步,纳米材料得到不断开发,将纳米材料整合到纺织品基材中,为纺织品带来了许多新功能,如抗菌㊁防污㊁抗紫外线㊁自清洁㊁抗静电㊁导电等,这些功能纺织品可应用于包括医疗保健㊁体育㊁军事和时尚等多方面领域㊂近年来,智能纺织品越来越多地受到人们关注,许多纺织材料如棉㊁丝㊁合成纤维被用于集成智能性纳米材料的基材,利用纳米材料开发了通过电㊁颜色或生理信号感知和响应外部刺激的智能纺织品[1]㊂传统的功能化方法难以使纺织品产生永久性的功能效果,如纺织品经洗涤后功能会降低,这是纺织行业目前面临的技术难题,而纳米材料以其高强度和韧性可以无缝融入纺织品中,并响应机械㊁化学㊁电㊁热㊁光或磁刺激㊂将具有特殊功能的纳米材料应用到纺织品中,不仅可以提高纺织品的性能,还可拓展纺织品在不同领域的应用潜力㊂1㊀纳米材料在纺织领域的应用纳米材料是一种全新的超微固体材料,由纳米粒子构成,其纳米粒子尺寸为1~100nm,具有表面效应㊁小尺寸效应和宏观量子隧道效应㊂纳米技术是在100nm 以下的微小结构上对物质和材料进行研究处理,即用单个原子㊁分子制造物质的科学技术㊂纳米材料在纺织领域的应用非常广泛,将具有特殊功能的纳米材料与纺织原料进行复合,可以制备具有各种功能的织物,如抗菌㊁拒水拒油㊁抗紫外线㊁抗静电等[2]㊂1.1㊀抗菌纳米材料用于纺织品的抗菌纳米材料很多,如二氧化钛(TiO 2)[3]㊁壳聚糖[4]㊁银(Ag )[5]㊁氧化亚铜(Cu 2O)[6]和大麻纤维[7]等㊂将这些活性纳米材料以化学或物理方式掺入织物中,如通过静电纺丝㊁纳米沉淀或自组装方法可开发各种各样的抗菌纺织品㊂无机抗菌纳米材料是一类长效㊁广谱㊁高效㊁安全的新型抗菌剂,且其耐高温特性是其他类型的抗菌剂所不能达到的,目前以纳米Ag㊁纳米TiO 2为主㊂1.1.1㊀纳米Ag 无机抗菌剂纳米Ag 是最早应用于纺织品的抗菌纳米材料之一,其作为抗菌剂掺入到织物中可在不改变织物机械性能的情况下表现出高效的抗菌活性[8]㊂纳米Ag 颗粒的尺寸非常小,这有助于Ag 颗粒通过细胞壁和细胞膜扩散到细胞质中,并与细胞膜上的含硫蛋白质结合,从而在结构上改变细胞壁的形态[9],由于渗透压的变化,细胞膜将细胞质释放到细胞外液中,从而起到抗菌作用㊂此外,Ag +可与含磷酸盐的蛋白质结合,与硫醇基蛋白质发生反应导致细胞死亡[10]㊂A.H.PATIL 等[11]采用化学合成和沉积方法获得Ag 纳米粒子涂层棉织物,发现Ag纳米粒子稳定㊁单分散㊁均匀沉积在棉织物上并表现出最高的抗菌活性㊂MENG M等[12]通过在蚕丝表面引入聚丙烯酸(PAA)/聚二甲基二烯丙基氯化铵(PDDA)多层膜作为基质,在此基础上原位还原合成高密度纳米银(AgNPs),所制备的蚕丝可以在长达120h 内持续释放Ag+,具有一定的抗菌持久性㊂孔祥宇[13]采用超声溶胀-原位还原法将纳米Ag中的Ag+吸附在聚对苯二甲酰对苯二胺(PPTA)纤维内部制备纳米Ag抗菌PPTA纤维,纤维对金黄色葡萄球菌和大肠杆菌的抑菌率在99%以上㊂纳米Ag抗菌剂具有优异的抗菌效果和更高的操作安全性,因此含Ag纳米材料的应用广泛㊂1.1.2㊀纳米TiO2TiO2属于光催化型无机抗菌剂,同样可以赋予纺织品抗菌性㊂TiO2可以产生活性氧(ROS),如超氧化物或羟基自由基[14],这些ROS可以与细菌的细胞壁和细胞膜相互作用破坏细菌的细胞膜,同时降解细胞产生的毒素,最终导致细胞死亡㊂ROS还可以分解有机物或油性污垢,赋予纺织品自清洁性能㊂在TiO2中掺杂一些其他活性物质,如Ag㊁二氧化硅(SiO2)㊁氧化锌(ZnO)等,可以进一步增强这种自清洁性能[15]㊂S.RIAZ 等[16]将TiO2纳米颗粒经含环氧基团的硅烷偶联剂(GPTS)和长链疏水剂(QASC)功能化处理后应用于棉织物的处理,发现经过处理的棉织物表现出持久的超疏水性㊁自清洁性和抗菌性㊂孙正琪等[17]采用快速溶胶-凝胶法制备硫㊁氮共掺杂TiO2溶胶,通过浸渍和热处理将掺杂TiO2负载于棉织物上制得抗菌织物,经抗菌测试,所得抗菌织物对大肠杆菌的抑菌率达99.5%,经20次洗涤后,其抑菌率仍达93.3%㊂S.MIRUNA等[18]用水热法制备的氮铁共掺杂TiO2纳米粒子修饰氧化还原石墨烯,抗菌测试发现其对金黄色葡萄球菌和粪肠球菌菌株的生长有较强的抑制作用,可用于开发创新的自清洁抗菌纺织品㊂TiO2纳米粒子虽然无毒且具备高效的杀菌性能,但仅在紫外光下表现出光催化活性,这限制了其在光催化领域的潜在应用㊂目前,抗菌纺织品的生产主要有两种方法:一种是纺丝法,即在纺丝过程中加入纳米抗菌剂制备抗菌纤维,由纤维制成相应的抗菌纱线和织物,利用此方法生产的抗菌织物耐洗㊁抗菌持久;另外一种方法是后整理法,即将纳米抗菌整理剂通过印花㊁浸渍㊁浸轧等方法化学接枝或物理附着到织物上,此方法生产的抗菌织物通常耐洗性较差,且织物原有的物化性能容易被改变㊂1.2㊀拒水拒油纳米材料织物的拒水性是指织物不易被水润湿的特性[19]㊂拒油性与拒水性相似,是指织物不易被油浸湿,防止油及油污沾污纺织品㊂纳米材料技术应用于拒水拒油整理基于 荷叶效应 原理,荷叶效应主要源于其微观结构和纳米结构㊂采用纳米技术可以直接对织物进行表面处理,使纤维表面形成特殊的几何形状互补的界面结构(如凸与凹相间),由于纳米尺寸的低凹表面可以吸附气体分子,并且使气体分子稳定附着存在,所以在织物表面上形成了一层稳定的气体薄膜,使得油或水无法与织物的表面直接接触,从而使材料的表面呈现出超常规的双疏性,这时水滴或油滴与界面的接触角趋于最大值,实现纤维织物的超疏水㊁超疏油功能㊂目前应用最广泛的拒水拒油整理剂主要有脂肪烃类[20](金属皂㊁蜡和蜡状物质㊁金属络合物㊁吡啶衍生物㊁羟甲基化合物等)㊁有机硅类和含氟化合物类㊂脂肪烃类和有机硅类只有拒水性,含氟化合物兼具拒水性和拒油性㊂1.2.1㊀拒水纳米材料目前市场上常用的拒水纳米材料包括有机氟和有机硅两大类㊂有机氟整理剂可以使被整理织物表面具有非常低的表面张力,且碳-氟键不被极化,因此,其除可使被整理织物获得优异的防水㊁防油㊁防污等特性外,还具有良好的化学稳定性和热稳定性㊂传统含氟整理剂大多为长氟碳链的(甲基)丙烯酸酯类聚合物㊂将该类聚合物整理到织物上,织物具有良好的拒水㊁拒油和防污效果,而且可以保持自身原有的优良性质[21]㊂侯再坚等[22]合成季戊四醇三(全氟己基丙基)酸,并以此为含氟单元制备含氟聚丙稀酸酯乳液,经该乳液整理的棉布水接触角为134ʎ,具有一定疏水性,但含氟整理剂的氧化降解产物会导致全氟辛酸(PFOA)和全氟辛烷磺酸(PFOS)的产生,这两种物质有很强的化学毒性㊁生物累积性㊁远距离迁移性,且生物半衰期长,会对人类健康和生态环境造成严重的威胁㊂相比于有机氟整理剂,有机硅整理剂不易在生物体内沉积㊁易降解㊁对人体无害,是更加安全环保的产品㊂有机硅是20世纪50年代发展起来95第2期㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀陈海通等.纳米材料在纺织领域的应用的以线型含氢聚甲基硅氧烷为基础的耐洗拒水整理剂,反应性能比较活泼㊂有机硅整理通常是将有机硅拒水整理剂和辛酸锌或钛的有机化合物等催化剂配制成乳浊液浸轧织物,烘干后在150ħ焙烘数分钟,再进行水洗;在焙烘过程中,含氢聚甲基硅氧烷在纤维上形成网状聚合物;甲基在纤维表面作垂直的密集定向排列,使织物具有良好而且较耐洗的拒水性能㊂卢业炜等[23]以异佛尔酮二异氰酸酯㊁聚氧化丙烯二醇㊁双端羟乙基封端有机硅为主要原料,合成了有机硅改性水性聚氨酯拒水整理剂,并将其用于涤棉织物的防水整理,经整理后织物的水接触角为167.99ʎ,证明其具有疏水性㊂WANG Y C等[24]在工业废气中的煤灰(FA)上涂覆TiO2壳层,通过电荷吸附形成核(FA)-壳(TiO2)结构;然后将FA-TiO2接枝聚二甲基硅氧烷(PDMS)分子,形成FA-TiO2-PDMS超疏水颗粒;将超疏水FA-TiO2-PDMS颗粒与PDMS 混合形成均匀的涂层溶液,再将其涂覆到织物上获得超疏水表面织物㊂有机硅类拒水剂在分子结构中含有一定的反应性基团,整理过程中在催化剂的作用下,通过氧化㊁水解或交联成膜,或与纤维素上的羟基进行化学结合,使之达到耐久性拒水效果㊂有机硅类拒水剂在合成纤维织物上的拒水效果及耐久性均较好,而在棉和黏胶织物上稍差㊂1.2.2㊀拒油纳米材料要使织物具有不易被油性污垢沾污的性能,需提高纤维或织物表面的拒油性㊂由于油类物质的表面张力极低,因此硅烷类㊁氟化物类㊁丙烯酸类等常用于纺织品拒油整理[25],这些化学物质能够与材料表面相互作用,形成一层保护膜,从而实现拒水㊁拒油的效果[26]㊂一般采用含氟有机化合物作为拒油整理剂㊂XIONG D等[27]制备了3-(三异丙基氧基硅)甲基丙烯酸丙酯和全氟辛基乙基甲基丙烯酸酯段共聚物,然后利用共聚物链段中的硅烷链段的可水解特性,将其与棉织物表面的羟基发生缩合反应,从而得到了化学接枝的超双疏涂层,织物涂层上的水和油以164ʎ和156ʎ的接触角在涂层棉织物上形成珠状,疏水性和疏油性优异㊂LI Y C等[28]通过对SiO2纳米微球进行表面改性处理,然后将其与疏油的含氟基团交联,在织物表面成功构建了具有疏油功能的光子晶体涂层,织物具有出色的疏水性及疏油性㊂经含氟均聚物乳液整理的织物的拒水拒油性虽然较好,但存在抗静电性差㊁耐久性低下等不足㊂近年来,人们通过选择共聚单体,加入添加剂和交联剂,利用架桥反应等途径,对含氟聚合物进行了多方面的改性,加入第二单体和第三单体于含氟单体中形成的三元共聚物基本上可以克服上述不足㊂1.3㊀抗紫外线纳米材料传统的抗紫外纺织品主要通过添加有机抗紫外添加剂共混熔融纺丝处理或进行表面整理得到,常用的有机抗紫外添加剂多为有机酚类化合物(水杨酸酯类㊁二苯甲酮类㊁苯三唑类和羟基苯基三嗪类等),这类添加剂长期使用后有分解失效可能,且容易产生化学性过敏,不同程度地存在毒性及刺激性等问题㊂近年来,抗紫外添加剂已逐步发展为无机紫外线遮蔽剂㊂随着锦纶㊁维纶㊁涤纶和腈纶等化纤品种的发展,超微粉体材料逐渐作为纺织助剂得到广泛的应用,特别是多种纳米尺度的金属氧化物颗粒在抗紫外功能纤维中的应用㊂许多纳米微粒对紫外线有强烈的吸收作用,其原因主要是其在紫外线照射下,电子被激发由价带向导带跃迁引起的紫外光吸收㊂作为紫外线吸收剂的纳米无机材料主要有纳米ZnO㊁TiO2㊁SiO2㊁氧化铝等㊂这些材料既能与化纤形成良好的结合,又能生成具有各种色彩的织物㊂特别是这些材料制成超细粉体或纳米尺度的颗粒时,其对收紫外的吸收显著增强㊂有机抗紫外整理剂主要通过吸收紫外线并进行能量转换,将紫外线变成低能量的热能或波长较短的电磁波,从而达到防紫外线辐射的目的㊂这类抗紫外线整理剂代表有苯酮类化合物㊁水杨酸类化合物等㊂苯酮类能吸收280~400nm的紫外线,但对280nm以下紫外线吸收较少,且有时易泛黄,价格较贵,应用较少,不过由于其具有多个羟基,对一些纤维有较好的吸附能力㊂张朋[29]通过正交试验对2-羟基-4-甲氧基-3-硝基二苯甲酮的合成工艺进行优化,合成含有紫外吸收剂结构的活性染料,用于棉纤维和丝绸染色来提高织物的抗紫外线性能,结果表明,未染色棉织物的紫外线防护系数(UPF)为1.3,染色后棉织物的UPF为17~20,抗紫外线性能明显提高㊂无机抗紫外吸收剂多为对紫外线不具活性的金属化合物的粉体,如TiO2㊁ZnO㊁氧化铝㊁陶瓷粉㊁滑石粉等,考虑到消光㊁色泽㊁透明性等使用要06㊀合㊀成㊀纤㊀维㊀工㊀业㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀2024年第47卷求,多采用ZnO和TiO2的纳米粉体作为抗紫外吸收剂㊂张永文等[30]研究了多种表面活性剂㊁酸碱度㊁超声时间等因素对纳米ZnO分散稳定性的影响,通过复配得到抗紫外整理剂,整理剂粒径分布均匀(平均粒径为111.4nm),整理后的纯棉织物的UPF达到50以上,且手感柔和,耐久性良好㊂韩克清等[31]将金红石型TiO2添加至聚合反应体系中进行原位聚合,得到PET/纳米TiO2复合材料,将复合材料纺制成纤维,金红石型TiO2在基体中分散较均匀,基本呈纳米尺寸分散;PET/纳米TiO2纤维中TiO2质量分数为1%时,纤维织物对紫外线具有优异的屏蔽效果,UPF可达50以上㊂无机纳米抗紫外剂不仅对紫外线产生屏蔽,同时也能屏蔽400~900nm波长的太阳光,所以无机纳米抗紫外剂还具有遮热功能,而有机抗紫外剂虽然具有良好的化学稳定性和与高聚物的相容性,但是紫外光吸收率较低,因此应用较少㊂目前国内已经成功开发了纳米TiO2抗紫外纤维,该技术制成的抗紫外织物对紫外线具有反射作用,而且还有特殊的选择㊁吸收性能,可将紫外线能量转换成热能或其他无害低能形式,予以释放或消耗,具有防暑㊁隔热等性能㊂将来使用纳米级无机微粒子对传统纺织纤维进行改性,将可开发出功能更新㊁更强的纺织品㊂1.4㊀抗静电纳米材料纳米材料用于纺织品的抗静电处理主要是通过材料的导电使得电荷快速传导㊁消耗,从而使织物达到抗静电的效果㊂目前,实现纺织品的抗静电性能主要有三个途径:一是在聚合或纺丝过程中加入抗静电材料制备抗静电纤维,然后进行纺纱㊁织造,生产抗静电织物;二是使用抗静电整理剂对织物进行浸轧或涂层,得到抗静电织物;三是在纱线中混纺导电纤维或者在织物中交织具有导电性能的长丝或纱线,使纺织品具有抗静电性能㊂常用于纺织品的抗静电材料有金属粉末㊁金属氧化物㊁高分子材料㊁碳系材料等㊂金属粉末主要有金㊁Ag㊁铜㊁镍等,在纺织品中掺入金属粉末是利用金属的导电性导走静电,达到抗静电目的㊂谢勇[32]以镀银纤维作为功能组分和涤纶长丝进行嵌织,分别设计了镀银纤维的嵌织距离㊁织物的组织结构㊁织物的纬向密度不同的抗静电织物,织物经30次洗涤后仍具有很好的抗静电性能㊂金属导电材料大多容易氧化,且价格偏高,因此使用的场合并不多㊂金属氧化物主要有ZnO晶须㊁TiO2纳米粒子㊁锑(Sb)掺杂的氧化锡(SnO2)纳米粒子等㊂这些纳米材料具有良好的导电特性,可以消除纺织品上的静电荷,实现纺织品的抗静电性能㊂M. WASIM等[33]研究了Sb掺杂SnO2用于聚丙烯腈(PAN)纤维的抗静电改性,发现这些纳米粒子在扩散到纤维中时会产生导电通道,最终实现抗静电特性㊂碳系材料主要有碳纳米管㊁石墨烯㊁石墨等㊂石墨烯㊁石墨具有优良的导电性能,且分散性好,将其结合到织物中可以使织物具有良好的抗静电性能㊂黄海涛[34]采用超声氧化剥离法制备氧化石墨烯,通过浸轧-还原法得到一种高效㊁简单制备还原氧化石墨烯导电棉织物的方法㊂碳纳米管具有极好的导电性,织物中加入少量碳纳米管即可获得很好的抗静电效果,但是碳纳米管分散性较差,容易产生团聚㊂沈计成等[35]将氨基改性的碳纳米管分散在含有1,3,5-苯三甲酰氯的极性溶剂和四氢呋喃的混合溶剂中得到碳纳米管分散液;将织物浸没其中,再置于超临界二氧化碳流体装置中进行超临界处理;处理后进行水洗㊁干燥处理得到抗静电织物,织物具有较好的抗静电性能和耐水洗性能㊂金属材料虽然具有良好的导电性和优秀的抗静电效果,但是由于金属大多容易氧化,且价格也偏高,因此使用的场合并不多[36]㊂金属氧化物的抗氧化能力相对于金属材料要好很多,且价格较金属材料要低廉很多,但是金属氧化物本身多为半导体材料,导电性较差,因此需要掺杂较多的量才能达到理想的效果㊂碳系材料虽然应用比较广泛,但对于织物颜色要求较高㊂因此,金属氧化物和碳系材料的应用空间和研究价值要高于金属材料㊂2㊀纳米材料在纺织领域应用中的注意事项随着纳米技术的不断发展,纳米材料在纺织工业领域中的应用越来越广泛,但在应用中也存在一些问题需高度重视㊂(1)安全性㊂安全性是利用纳米材料及纳米技术改善纺织品功能中的首要问题㊂尽管纳米材料给纺织品带来了许多功能和性能,但纳米材料本身可能存在一定的安全风险㊂在选择纳米材料时,需考虑其毒性和生物相容性,确保使用的纳米材料对人体和环境无害,以避免潜在的健康风险,16第2期㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀㊀陈海通等.纳米材料在纺织领域的应用如纳米Ag粒子可通过非特异性的物理穿透作用跨过细胞膜在生物体内沉积[37];进入细胞的纳米材料可能与生物大分子发生相互作用,从而诱导遗传毒性㊁细胞凋亡㊁细胞自噻及炎症等毒性效应[38]㊂(2)稳定性㊂稳定性是纳米材料应用于纺织品的另一个重要问题㊂许多纳米材料在大气中或湿润环境下容易发生聚集或氧化反应,从而导致其功能减低或丧失㊂因此,在选择纳米材料时,应考虑其稳定性和耐久性,保证纳米材料在纺织品中可以保持其功能和性能的有效时间,以实现长期的功能改进效果㊂(3)可持续性和环境友好性㊂在一些纳米材料的制备过程及在纺织品的应用过程中可能涉及对环境的负面影响㊂因此,在选择纳米材料时,需考虑其可持续性和环境友好性,尽量选择能够降低环境污染和气源消耗的纳米材料,严格控制制备及应用过程中的废物排放㊂(4)可操作性和成本㊂纳米材料虽然可以给予纺织品多种功能和性能,但其制备及集成过程往往比较复杂,成本高,这也是限制其广泛应用的主要因素㊂因此,在选择纳米材料改善纺织品功能时应考虑其可操作性和成本,控制成本在可接受的范围内㊂3　展望随着消费者对纺织品性能要求的不断提高,纳米材料在纺织品中的应用越来越受到重视㊂纳米材料可以显著提高纺织品的功能,如抗菌㊁拒水拒油㊁自清洁㊁抗紫外㊁抗静电等,但纳米材料的制造成本较高,应用过程中可能会对人体健康㊁环境造成一定的影响㊂其次,纳米材料在纺织品中的应用可能会影响纺织品的可回收性㊂随着纳米技术的不断发展,未来纳米材料在纺织品中的应用研究和发展方向主要有以下三点:(1)新材料和新技术的应用,新型纳米材料和纳米技术的应用将为纺织品的功能化提供更多的可能性,推动纳米材料在纺织品中应用的创新和发展;(2)环保型的纳米材料及应用技术,针对纳米材料的制备及应用过程中的环保问题,未来的发展方向应致力于开发环保型的纳米材料及生产技术,以降低对环境的影响;(3)提高可操作性和降低成本,目前纳米材料的制备及在纺织品中的应用过程较为复杂,生产成本较高,因此,提高应用技术的可操作性和降低成本也是今后的研究方向㊂参㊀考㊀文㊀献[1]㊀YETISEN AK,QU H,MANBACHI A,et al.Nanotechnology intextiles[J].ACS Nano,2016,10(3):3042-3068. 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超疏水材料的研究现状及应用超疏水材料的研究现状及应用摘要: 超疏水表面材料具有防水、防污、可减少流体的粘滞等优良特性，是目前功能材料研究的热点之一。

由于超疏水表面在自清洁表面、微流体系统和生物相容性等方面的潜在应用,有关超疏水表面的研究引起了极大的关注，本文简述了超疏水表面的制备方法，归纳了超疏水表面的应用,对超疏水表面研究的发展进行了展望。

关键词:超疏水表面材料;微流体系统;表面制备方法;表面应用Superhydrophobic materials Researchand ApplicationLi Yongliang(Jiangnan University, College of Chemistry and Materials Engineering JiangsuWuxi 214122,China)Abstract: Superhydrophobic surface material with a waterproof, anti-fouling, can reduce the viscosity of the fluid and other excellent features, is currently one of the hot functional materials. As super-hydrophobic surface in the self-cleaning surfaces, microfluidic systems, biocompatibility and other potential applications, research on super-hydrophobic surface caused a great deal of attention, this paperoutlines the super-hydrophobic surface preparation methods, summarized the super-hydrophobic surface application of research for the development of super-hydrophobic surfaces were discussed.Keywords: Superhydrophobic surface material; Microfluidic systems; Surface preparation methods; Surface application近年来，植物叶表面的超疏水现象引起了人们的关注。

仿荷叶超疏水高分子材料设计综述摘要近年来,由于超疏水表面在自清洁表面、微流体系统和生物相容性等方面的潜在应用,有关超疏水表面的研究引起了极大的关注。

本文综述了超疏水表面研究的新进展:简单介绍了表面浸润性的表征手段和影响因素,归纳了超疏水表面的制备方法和相关的理论分析,对超疏水表面研究的发展进行了展望。

关键词超疏水仿荷叶多级结构滞后接触角滚动角Summary of lotus-like super-hydrophobicpolymer materials designAbstract In the last decade, surfaces with ultra hydrophobicity have aroused much research interests owing to their potential application in self-cleaning coatings , microfluidics and biocompatible materials and so on. The recent progress in the study of superhydrophobic surface is summarized in three parts. In the first part the characterization and influences of wettability are briefly introduced ; in the second part new development of superhydrophobic surfaces is summarized from both experimental and theoretical aspects ; in the third part the prospect of the development in this field is proposed.Key words superhydrophobic ; lotus-like ; hierarchical structure ; hysteresis ; contact angle ; sliding angle1．引言我们用扫描电子显微镜观察到荷叶表面存在着微米和纳米级的双微观结构 ,即乳突形成的表面微米结构和蜡晶体形成的纳米结构[1],乳突的直径为 5～15μm ,蜡晶体特征尺度为20～500nm。

超疏水性表面的制备方法1模板法 (1)2溶胶-凝胶法 (2)3自组装法 (3)4化学气相沉积法 (3)5蚀刻法 (4)6粒子填充法 (5)疏水涂料要达到超疏水性，必须使用特定的工艺技术来提高固体表面的粗糙度。

目前为止通过提高固体表面粗糙度来增强疏水性表面的主要方法有模板法、溶胶-凝胶法、自组装法、化学沉积法、蚀刻法等方法。

1模板法模板法是国内最为常用的制备超疏水涂膜的方法，是一种整体覆盖的表面技术。

模板法以具有粗糙结构的固体为模板，将疏水材料在特定的模板上通过挤压或涂覆后光固化等技术在粗糙固体表面成型、脱模而制得超疏水薄膜。

模板法制备超疏水性涂层具有操作简单、重复性好、纳米线径比可控等优点。

江雷等[1]以多孔氧化铝为模板，通过新的模板挤压法制备了聚丙烯腈纳米纤维。

该纤维表面在没有任何低表面能物质修饰时即具有超疏水性，与水的接触角高达173.8°。

此外，研究者还以亲水性聚合物(聚乙烯醇) 制备了超疏水性表面，打破了传统上利用疏水材料才能得到超疏水性表面的局限。

刘斌等[2]以复制了荷叶表面结构的聚二甲基硅氧烷(PDMS) 弹性体为软模板，在模板压印条件下，利用紫外光交联预聚物固化成型，得到了具有微乳突结构的仿荷叶表面，与水的接触角达到150°以上，并在此基础上对其表面疏水性进行了优化。

研究表明，随着紫外光固化体系中单体稀释剂含量的增加，样品表面接触角先增大再减小，含量为10%左右时达到最大值；随着交联剂含量的增加，样品接触角起初保持在一定值，含量超过20%后开始减小；随着光引发剂含量的增加，样品表面接触角逐渐增大，引发剂含量大于0.7%之后保持不变；当曝光时间长于10min后，样品表面接触角保持稳定。

Shang等[3]用直径200nm、长10μm的聚碳酸酯微孔膜作模板，放在由正硅酸乙酯及甲基丙烯酰氧基三甲氧基硅烷(MPS) 配置好的溶胶上，利用毛细管作用将溶胶吸入微孔中，溶剂蒸发后，经500 ℃热处理去除模板，得到如图1所示均一竖直排列的纳米棒状表面。

神奇的超疏水材料：我虐水滴千百遍，水滴待我如初恋！神奇的超疏水材料：我虐水滴千百遍，水滴待我如初恋！一盆水泼向一块金属板，水珠像钢珠一样滚落，金属板仍然干爽；一只船桨浸入水缸，拿出来竟然未带出一滴水珠，就像是从没放进去过一样；一杯水倒在一块经过特殊处理的玻璃板上，水紧紧靠在中央“不越雷池半步”，即使用手搅出来一两滴也立即跑回去……这些违背我们肉眼“常识”的现象，就是“超疏水材料”捣的鬼。

这种通过改变材料的表面自由能和表面粗糙度获得的新型材料，灵感来自于自然界中的荷叶。

由于其防水、防腐蚀、抗菌的特殊效果，如今已经成为国际热门的研究领域，可以在环保、工业、医疗等各种你想象不到的领域大展身手。

一、超疏水简介超疏水技术是一种具有特殊表面性质的新型技术，具有防水、防雾、防雪、防污染、抗氧化、防腐蚀和自清洁以及防止电流传导等重要特点，在科学研究和生产、生活等诸多领域中有极为广泛的应用前景。

超疏水技术对于建筑工业、汽车工业、金属行业等的防腐防锈及防污也很有现实意义。

特别是近年来的微电子系统、光电子元器件及纳米科技等高新技术的高速发展，给超疏水涂层的研究和应用于勃勃生机。

超疏水材料的研究以诗句“出淤泥而不染，灌清涟而不妖”为契机，以科学的手段向我们解释这一奇特的自然现象，荷花表面覆盖的天然超疏水薄膜，使得水滴聚集成股，顺势流下，冲刷着荷叶表面的淤泥，营造了出淤泥而不染的状态。

因此荷叶在雨后会变得一尘不染，这种现象在生活中很常见，我们称之为“荷叶效应”。

二、超疏水现象荷叶效应--超疏水性原理为什么“粗糙”表面能产生超疏水性呢?对于一个疏水性的固体表面来说，当表面有微小突起的时候，有一些空气会被“关到”水与固体表面之间，导致水珠大部分与空气接触，与固体直接接触面积反而大大减小。

由于水的表面张力作用使水滴在这种粗糙表面的形状接近于球形，其接触角可达150度以上，并且水珠可以很自由地在表面滚动。

即使表面上有了一些脏的东西，也会被滚动的水珠带走，这样表面就具有了“自清洁”的能力。