Effects of Soft Monomers on the Water Resistance and Moisture Permeability of Hydrophilic Polyurethane

Six groups of segmented polyurethanes with amorphous soft segment domains based on mixed hydrophobic polyester and hydrophilic polyether soft monomers were prepared from 4, 4′ diphenylmethane diisocyanate （MDI）, polybutylene adipate glycol 2000 （PBA2000）, polytetramethylene glycol 1000 （PTMG1000） and polyethylene glycol 1000 （PEG1000） with 1,4-butanediol （BDO） as the chain extender. Furthermore, the representative properties of the hydrophilic polyurethanes, moisture permeability and water resistance, were investigated. The results show that the chemical structure, molecular weight and concentration of soft monomers have remarkable effects on the main application properties of hydrophilic polyurethane. The important factors in diffusion are the content of hydrophilic ether bond and the mobility of hydrophilic chain in the soft phase, which is represented with a good approximation by the average mean molecular weight of soft segment. On the contrary, the functional properties of the hydrophilic polyurethane are almost not affected by its hard segment.

A Structure-properties Study of MDI-based Hydrophilic Polyether-polyester Polyurethane

A series of segmented polyether-polyester polyurethane with amorphous hydrophilic soft segment domains were prepared from 4,4'- diphenylmethane diisocyanate (MDI), polybutylene adipate (Glycol) 2000 (PBA2000), and polyethylene glycol 1000 (PEG1000), with 1,4-butanediol (BDO) as the chain extender. Furthermore, several representative properties of the polyurethanes, such as moisture permeability, water resistance, hydrophilic property, and phase inversion temperature, were investigated. The studies show that the structure and concentration of soft segment have a remarkable effect on the main application properties of polyurethane. On the contrary, the functional properties of the polyurethane are almost not affected by its hard segment.

Preparation of waterborne polyurethane/β-cyclodextrin composite nanosponge by ion condensation method and its application in removing of dyes from wastewater

Currently,polymer nanosponges have received extensive attention.However,developing new synthetic techniques for novel nanosponges remains a challenge.Furthermore,to date,composite nanosponge adsorbents based on waterborne polyurethane(WPU)andβ-cyclodextrin(β-CD)have not been reported.Herein,a novel green method,ion condensation method,was developed in this study for the preparation of polymer nanosponge adsorbents for efficient removal of dyes from wastewater.Based on the principle of charge repulsion between nanoparticles to maintain emulsion stability,waterborne polyurethane/β-cyclodextrin composite nanosponges(WPU-x,y)were prepared by coagulating the emulsions synthesized from 2,2-dimethylolpropionic acid,polypropylene glycol and hexamethylene diisocyanate as raw materials in a mixture of hydrochloric acid and anhydrous ethanol.The structure and appearance of WPU-x,y were characterized by attenuated total reflectance Fourier transform infrared spectroscopy,thermal gravimetric analyzer,scanning electron microscope and mercury intrusion porosimetry.The adsorption capacity of WPU-x,y was tested by parameters such as cross-linking degree,β-CD dosage,contact time,initial dye concentration and p H value.The study found that WPU-4,4.62 had the best adsorption effect on methylene blue(MB),the maximum removal rate was 93.42%,and the maximum adsorption capacity was 136.03 mg·g^(-1).Moreover,the Sips isotherm and pseudo-second-order-model were suitable for MB adsorption.Therefore,this study provides some perspectives for the fabrication of nanosponge adsorbents.

Erratum to： A new ecological control method for Pisha sandstone based on hydrophilic polyurethane

In this Erratum, we correct the family name of the first author that was spelled as “LINAG” in Journal of Arid Land and the correction is “LIANG”.

环保型亲水聚氨酯防渗封堵剂的研制

以大分子量多官能度亲水聚醚多元醇为软段、甲苯二异氰酸酯(TDI)为预聚物封端剂、二苯基甲烷二异氰酸酯(MDI)为游离异氰酸酯、三亚乙基二胺(A33)为催化剂、二乙二醇二甲醚(GDC)为亲水剂,开发了环保型亲水聚氨酯防渗封堵剂,研究了TDI和MDI用量对聚氨酯封堵剂固结体性能的影响。结果表明:在TDI中异氰酸酯基团与聚醚多元醇中羟基摩尔比(n_(T-NCO)∶n_(OH))为1.6、MDI中异氰酸酯基团与聚醚多元醇中羟基摩尔比(n_(M-NCO)∶n_(OH))为6、GDC质量分数为20%、催化剂A33质量分数为0.5%条件下,制备的亲水聚氨酯防渗封堵剂具有黏度低、包水倍率高、反应活性高的特点,聚氨酯防渗封堵剂浆液黏度为800mPa·s左右,遇水凝胶时间可控制在50s左右,反应后固结体发泡率大于400%,包水倍率超过30g/g,遇水膨胀率约为57%。

聚乳酸基水性聚氨酯的制备及其在合成革中的应用研究

以聚乳酸二元醇(PLA⁃OH)和六亚甲基二异氰酸酯(HDI)为原料,2,2⁃二羟甲基丁酸(DMBA)为亲水扩链剂合成了亲水扩链剂含量不同的聚乳酸(PLA)基水性聚氨酯(PLA⁃WPU)乳液,制备了PLA⁃WPU胶膜和超细纤维合成革。结果表明,随DMBA含量的增加,PLA⁃WPU乳液粒径减小、固含量增大,PLA⁃WPU超细纤维合成革拉伸强度和最大负荷增大,水接触角减小。当DMBA含量为5.5%时,PLA⁃WPU乳液固含量达到35.4%,粒径为196.37 nm,PLA⁃WPU超细纤维合成革的拉伸强度提高到29.9 MPa,约为超细纤维基布的1.7倍,水接触角降低到73°。

衣康酸聚乙二醇单醚酯封端水性聚氨酯织物涂层剂的制备及其性能

为丰富水性聚氨酯亲水单体的来源与种类,从而提高涂层织物水蒸气透过率,以聚乙二醇单醚(MPEG)和衣康酸(IA)为原料,通过酯化反应合成含碳碳双键的衣康酸聚乙二醇单醚酯(IM)。将IM和甲基丙烯酸羟乙酯型水性聚氨酯(HWPU)混合,经紫外线接枝得到IM封端水性聚氨酯织物涂层剂(WPU-IM),采用直接涂覆法将其涂布于涤纶织物。通过吸水率、拉伸、耐静水压和水蒸气透过率测试对WPU-IM涂膜、织物涂层的性能进行分析。结果表明:当IM质量分数为2.1%时,WPU-IM涂膜断裂强度为8.61 MPa,断裂伸长率为325%,吸水率为17.4%,水接触角为79.2°;WPU-IM涂层织物耐静水压值为18.86 kPa,透湿率为4086.3 g/(m^(2)·d),综合性能达到最佳。

WPU-g-SAN的合成及其对HNIW的包覆

为了降低六硝基六氮杂异伍兹烷(HNIW,CL-20)的撞击感度,利用原位种子乳液聚合,以异佛尔酮二异氰酸酯(IPDI)、甲基丙烯酸-β-羟乙酯(HEMA)、苯乙烯(S)、丙烯腈(AN)等为原料合成了用于降感的接枝型水性聚氨酯(WPU-g-SAN),采用红外光谱(FTIR)、核磁共振(1H NMR)、X-射线衍射(WAXD)及动态力学分析(DMA)对产物结构进行表征。结果显示所得产物为非晶结构,且存在微相分离。用制备的产物对HNIW进行包覆,通过X-射线光电子能谱(XPS)、扫描电镜(SEM)对包覆效果进行评价,并用GJB772A-1997方法测试了HNIW包覆前后的撞击感度。结果表明,包覆后的HNIW的特性落高H50由13.6 cm提高到28.5 cm。

互穿网络结构WPUA复合乳液在织物整理和涂料印花中的应用

采用甲苯二异氰酸酯(TDI)和聚酯多元醇218为原料,二羟甲基丙酸(DMPA)为扩链剂,三乙胺为中和剂制备水性聚氨酯(WPU)。再采用"预乳化溶胀法",利用自制的水性聚氨酯和丙烯酸酯类单体制备互穿网络结构水性聚氨酯-丙烯酸酯复合乳液(WPUA)。将制备的WPU和WPUA复合乳液用于织物整理和涂料印花,探讨了工艺参数对织物整理和印花效果的影响,并对整理后织物的手感、白度、抗皱性、抗起毛起球性、印花织物的耐干/湿摩擦牢度以及耐皂洗牢度等进行测试。结果表明,WPUA的使用能显著改善织物抗皱性和抗起毛起球性以及印花织物的干湿摩擦牢度和耐皂洗牢度。

抗起毛起球整理用热反应型WPU的合成及应用

以异佛尔酮二异氰酸酯(IPDI)、聚多元醇为主要原料,以异丙醇为溶剂,合成了反应型水性聚氨酯整理剂,既保持了聚氨酯的弹性,又具有极好的反应活性,可以赋予织物各种功能,提高纺织品的附加价值。介绍了该类整理剂在纯棉针织物抗起毛起球整理中的应用。

WPU/WEP共混乳液稳定性研究

初步探索了水性聚氨酯(WPU)与水性环氧树脂(WEP)共混乳液的制备工艺,研究了共混乳液的高温稳定性、机械稳定性、酸碱稳定性和盐稳定性,并通过对共混乳液性能的测试,寻求最佳配比。研究共混体系的含固粒径分布与固化行为和机理,WEP:WPU=3:1,对固化膜进行了TG分析。结果表明:凝胶时间与固化温度、固化剂含量有很大关系,共混物的固化速率受温度的影响很大。

包覆HNIW用WPU/SBB复合乳液的合成与表征

以异佛尔酮二异氰酸酯(IPDI)、聚氧化丙烯二醇(PPG)、苯乙烯(St)、甲基丙烯酸丁酯(BMA)和丙烯酸丁酯(BA)等为主要原料,采用种子乳液聚合法合成了WPU/SBB(水性聚氨酯/苯丙)复合乳液;然后以此为高能炸药——HNIW(六硝基六氮杂异伍兹烷)颗粒的包覆剂和胶粘剂。采用红外光谱(FT-IR)法、X-射线衍射(XRD)法及差示扫描量热分析(DSC)法等手段对WPU/SBB复合乳液的结构进行了表征,并采用扫描电镜(SEM)、特性落高值(H50)和X-射线光电子能谱(XPS)法等分析了WPU/SBB复合乳液对HNIW的包覆效果。结果表明:包覆后HNIW的H50由13.6 cm升至34.8 cm,说明该环保型WPU/SBB复合乳液对HNIW具有明显的降感作用。

非线性阳离子聚氨酯改性有机硅柔软剂的制备及其应用性能

针对聚硅氧烷与聚氨酯分子极性差异较大、二者的复配物在焙烘过程中易发生微相分离导致纺织品的亲水性和手感均差的问题,以三乙醇胺、羟烃基硅油、聚乙二醇2000、异佛尔酮二异氰酸酯为原料,设计合成了非线性阳离子型聚氨酯改性有机硅柔软剂。对合成产物进行表征,并将其用于棉织物和锦纶/氨纶织物的柔软整理。分析了整理后织物的形貌、元素分布、折皱回复角、亲水性和综合手感。结果表明:氨基硅油(AS)与支化型阳离子聚氨酯改性有机硅柔软剂(BS)复配物的最大质量损失速率温度由AS的334℃提升至397℃,且该复配物整理后的锦纶/氨纶织物表面硅元素的质量分数由1.4%降低至0.8%;经支化结构阳离子聚氨酯改性有机硅柔软剂(BS)整理后,棉织物的折皱回复角为190.0°、锦纶/氨纶织物的亲水时间为20.1 s;BS与AS复合后整理织物,棉织物的折皱回复角为129.1°,锦纶/氨纶织物的亲水时间为48.6 s。与用氨基硅油整理相比,经非线性阳离子聚氨酯改性有机硅柔软剂与氨基硅油的复配物整理,锦纶/氨纶织物的亲水性、弹性、平滑度、蓬松感和暖感都有明显提升,其在高级时尚服装面料和运动服装面料领域均有较好的应用前景。

HDI固化剂蒸馏残液制备水性聚氨酯

为解决六亚甲基二异氰酸酯(HDI)固化剂生产废弃物回收利用的问题,以HDI固化剂蒸馏残液、聚四氢呋喃二醇(PTMEG)、亲水扩链剂二羟甲基丙酸(DMPA)、一元醇/多元醇、多元胺等原料合成水性聚氨酯树脂。研究了一元醇的种类、多元醇和多元胺的种类及官能度对预聚体黏度、乳液稳定性、漆膜耐水性及力学性能影响。研究发现,先采用庚醇将多官能度的HDI固化剂蒸馏残液部分NCO封端有利于制备低黏度预聚体,以壬二醇和三羟甲基丙烷作为前段扩链交联剂,三乙烯四胺作为后段交联剂制备的水性聚氨酯漆膜性能最好。

临海富水砂层盾尾刷更换聚氨酯环试验研究

在盾构施工中,注浆法更换盾尾刷需要形成封闭且稳定的止水环,包括聚氨酯环和浆液环。本文结合临海富水砂层盾构施工实例,采集原位地下水对聚氨酯初凝时间、发泡倍率、固体强度等进行室内试验,结果表明:亲水型聚氨酯与地下水反应迅速,形成的固结体密实均匀,发泡率不高,且强度较低,疏水型聚氨酯呈相反状态;现场实际注入可考虑二者同时使用,先注入亲水型聚氨酯,后注入疏水型聚氨酯,并按照5∶1的用量进行控制。现场应用证明,形成的包裹体稳定且质量较佳。

两种聚氨酯材料在工程裂缝灌浆止水应用中的对比与分析

以介绍疏水性聚氨酯灌浆材料的工程应用实例为主,对疏水性聚氨酯灌浆液和亲水性聚氨酯灌浆液的性能特点以及应用范围进行了对比分析,旨在通过以上分析,以期在裂缝灌浆止水应用工程中能够选择最适合的材料,取得最佳的防水效果,并可为同类工程提供参考。

PUC固化路基融化夹层强度及耐冻融性能研究

多年冻土退化导致路基融化夹层(SSLT)数量增加、范围扩大、埋深加剧,其含水量高、压缩性大、承载力低的特点,威胁多年冻土区基础设施安全运行。因此,开展融化夹层的处置研究工作,对寒区基础设施的维护和修复至关重要。为此,本文提出借鉴软土加固技术对其进行加固,采用亲水性聚氨酯(WPU)及改性水泥基地聚物材料(PUC)为固化剂,研究对SSLT的加固效果。结果表明,WPU固化SSLT试样呈弹性特征,压缩强度随WPU掺量增加而增大;当SSLT含水量分别为35%、40%和50%时,WPU最佳掺量分别为6%、10%和15%;冻融循环降低固化土无侧限抗压强度,冻融循环15次,掺入WPU和未掺入WPU固化土强度损失率分别为43.11%和49.38%;微观分析表明,PUC固化剂固化SSLT强度的增加,一部分是WPU充填、包裹、胶结土颗粒增加土体密实度,一部分来自水泥水化过程。本文为寒区老旧路基改造及提高其安全稳定运营提供一种新的解决思路。

内乳化-外乳化结合法制备高固含量WPU分散体

以不同离子型和不同HLB(亲水亲油平衡)值的外乳化剂作为试验对象,采用内乳化-外乳化法合成高固含量的WPU(水性聚氨酯)分散体。研究结果表明:当外乳化剂在预聚体乳化前加入且w(阴离子型外乳化剂)≤2%(相对于反应原料质量而言)时,可获得黏度适中、储存稳定、耐介质性能和力学性能较好的高固含量WPU。

纺织基材上P(St-MAA)/WPU复合光子晶体生色结构的快速制备及其性能

为快速制备兼顾结构色效果和结构稳定性的光子晶体生色结构,提出了一种采用填充法制备复合光子晶体的方法。先将聚(苯乙烯-甲基丙烯酸)(P(St-MAA))胶体微球预组装液喷涂于涤纶基材上制备光子晶体,再利用水性聚氨酯(WPU)对P(St-MAA)光子晶体上进行二次喷涂,最终得到P(St-MAA)/WPU复合光子晶体。探究WPU质量分数对光子晶体排列、结构色效果、结构稳定性的影响,并分析P(St-MAA)/WPU复合光子晶体的光学性能。结果表明:喷涂WPU不会破坏光子晶体原有的规整排列,其会优先渗入P(St-MAA)微球间的缝隙中,逐渐替代原光子晶体内中的空气,最终实现对P(St-MAA)微球的包裹;WPU的填充使得P(St-MAA)/WPU复合光子晶体的平均折射率增加,结构色色相产生红移现象;P(St-MAA)/WPU复合光子晶体的结构稳定性高于P(St-MAA)光子晶体,且WPU的质量分数越大,稳定性改善程度越明显;喷涂WPU后所得的复合光子晶体结构仍呈现出良好的结构色效果且虹彩效应明显。研究结果为在纺织基材上快速制备兼具鲜艳结构色和稳定结构的光子晶体提供了简便方法,可推动光子晶体生色结构的实际应用。

Robust Waterborne Polyurethane/Wool Keratin/Silk Sericin Freeze-Drying Composite Membrane for Heavy Metal Ions Adsorption

Wool keratin(WK)and silk sericin(SS)have the ability to interact with metal ions.In order to take advantage of this potential,a novel environmentally friendly waterborne polyurethane(WPU)/WK/SS membrane named as WPU&WK&SS membrane with crosslinked structure was constructed by freeze-drying via self-assembly style.Surface morphology and chemical structure characterization were investigated by scanning electron microscopy(SEM)and Fourier transform infrared spectroscopy(FT-IR).In addition,the adsorption experiments of Cu2+and Cr6+were performed to evaluate the adsorption of WPU&WK&SS membrane,including adsorption kinetics,adsorption isotherm models and various factors affecting adsorption.Further investigation indicates that the maximum adsorption capacity of Cu2+and Cr6+can reach 54.21 mg·g-1and 85.21 mg·g-1,respectively,which are higher than most of the reported adsorbents.Through adsorption kinetics and thermodynamic analysis,it is find that the pseudo-second-order kinetic equation and the Langmuir adsorption isotherm model are more suitable for the static adsorption of Cu2+and Cr6+by WPU&WK&SS membrane.