Effect of Amine Type on Lignin Modification to Evaluate Its Reactivity in Polyol Construction for Non-Isocyanate Polyurethanes(NIPU)

Polyols are groups of organic compounds which contain carbon and are randomly linked to other atoms,especially carbon-carbon and carbon-hydrogen.These compounds are mainly used as reactants to make other polymers.Among biopolymers,lignin is regarded as the base of a new polymer in polyol construction.The present study aimed to investigate the effects of amine type(diethylenetriamine and ethylenediamine)on the modification of lignin-based polyols,so as to provide an alternative to petroleum polyols and,in turn,increase functional groups and reduce their harm to humans’health and the environment.To this aim,first,lignin was extracted from raw liquor.Next,the extracted lignin was reacted with diethylenetriamine(DETA)and ethylenediamine(EDA).Finally,the Mannich method was used for the reaction between amine lignin and propylene carbonate.The results of the Fourier Transform Infrared(FTIR)spectroscopy analysis showed that modification with DETA led to more structural change in lignin and peak 1100 indicates the presence of C–O bond related to urethane bonds in modified lignin.Moreover,adding propylene carbonate to aminated lignin did not result in much change in the results of the FTIR analysis.Additionally,urethane bonds can be seen in the results of GPC at 400℃–500℃.Furthermore,a slight decrease in thermal stability was observed in lignin modified with amine and propylene carbonate,compared to the raw lignin sample.

Hydrolysable Chestnut Tannin Extract Chemical Complexity in Its Reactions for Non-Isocyanate Polyurethanes(NIPU)Foams

Non-isocyanate polyurethane(NIPU)foams from a commercial hydrolysable tannin extract,chestnut wood tannin extract,have been prepared to determine what chemical species and products are taking part in the reactions involved.This method is based on two main steps:the reaction with dimethyl carbonate and the formation of urethane bonds by further reaction of the carbonated tannin with a diamine-like hexamethylene diamine.The hydroxyl groups on the tannin polyphenols and on the carbohydrates intimately linked with it and part of a hydrolysable tannin are the groups involved in these reactions.The carbohydrate skeleton of the hydrolysable tannin is also able to participate through its hydroxyl groups to the same two reactions rendering the whole molecular complex able to react to form NIPUs.The analysis by Matrix-Assisted Laser Desorption Ionization(MALDI-TOF)mass spectrometry and 13C Nuclear Magnetic Resonance(13C NMR)to further investigate the reaction mechanisms involved revealed the unsuspected complexity of chestnut hydrolysable tannin,with different fragments reacting in different manners forming a hardened network of considerable complexity.As the morphology and performance of these types of foams changes slightly with the change in the amount of glutaraldehyde and hexamine hardeners,the best performing foam formulation previously determined was scanned by SEM and analysed chemically for the structures formed.

Soy Protein Isolate Non-Isocyanates Polyurethanes(NIPU)Wood Adhesives

Soy-protein isolate(SPI)was used to prepare non-isocyanate polyurethane(NIPU)thermosetting adhesives for wood panels by reacting it with dimethyl carbonate(DMC)and hexamethylene diamine.Both linear as well as branched oligomers were obtained and identified,indicating how such oligomer structures could further cross-link to form a hardened network.Unusual structures were observed,namely carbamic acid-derived urethane linkages coupled with lactam structures.The curing of the adhesive was followed by thermomechanical analysis(TMA).It appeared to follow a two stages process:First,at a lower temperature(maximum 130℃),the growth of linear oligomers occurred,finally forming a physically entangled network.This appeared to collapse and disentangle,causing a decrease of MOE,as the temperature increases.This appears to be due to the ever more marked Brownian movements of the linear oligomer chains with the increase of the temperature.Second,chemical cross-linking of the chains appeared to ensue,forming a hardened network.This was shown by the thermomechanical analysis(TMA)showing two distinct MOE maxima peaks,one around 130℃ and the other around 220℃,with a very marked MOE decrease between the two.Plywood panels were prepared and bonded with the SPI-NIPU wood adhesive and the results obtained are presented.The adhesive appeared to pass comfortably the requirements for dry strength of relevant standards,showing to be suitable for interior grade plywood panels.It did not pass the requirements for wet tests.However,addition of 15%of glycerol diglycidyl ether improved the wet tests results but still not enough to satisfy the standards requirements.

有机硅改性环氧NIPU防腐涂料的制备及其性能研究

为解决传统环氧聚氨酯涂料中异氰酸酯毒性高、固化后涂层脆性大、韧性不佳、耐化学品性和耐盐雾性能差等问题,以有机硅改性的环氧树脂与CO_(2)反应制得的环氧-环碳酸酯为树脂基料(组分A),以聚氧化丙烯二胺(D-230)为固化剂基料(组分B),配以适量的填充材料和防腐助剂,制备一种新型有机硅改性环氧非异氰酸酯聚氨酯(NIPU)防腐涂料。采用FTIR对固化后涂层进行红外表征并对其性能进行测试。实验结果表明:涂料在80℃下实干时间为20 min,外观光滑平整,无起泡、裂纹、剥落等不良现象,再经室温固化7 d后,涂层硬度可达到2H,附着力为0级,耐盐雾时间高达1 500 h。所制备的有机硅改性NIPU防腐涂料具有良好的机械性能和防腐蚀性能。

Organosolv Lignin for Non-Isocyanate Based Polyurethanes (NIPU) as Wood Adhesive

A non-isocyanate-based polyurethane(NIPU)wood adhesive was produced from organosolv lignin,which is a bio-sourced raw material,available in large quantities and produced as a by-product of the paper industry.The formulation of this new lignin-based NIPU adhesive,which is presented,was chemically characterised by Matrix-Assisted Laser Desorption Ionization Time of Flight(MALDI ToF)mass spectrometry and by Fourier Transform Infra-Red(FTIR)spectrometry analyses.The oligomers formed were determined and showed that the three species involved in the NIPU adhesive preparation were formed by the co-reaction of the three reagents used:lignin,dimethyl carbonate,and hexamethylene diamine.Linear and branched structures were both identi-fied.Mechanical properties of the adhesive were determined using the Automated Bonding Evaluation System(ABES)and internal bond(IB)strength test of the laboratory particleboard bonded with it.The adhesive has shown satisfactory mechanical properties after hot pressing at 230℃.Such a temperature is used industrially in the most modern particleboard factories,but since it is hardly feasible for more conventional wood bonding equipment,the reactivity of the NIPU adhesive was successfully increased with the addition of a small percentage of a silane coupling agent.With the addition of the silane,the proposed NIPU adhesive could also be used at a hot-pressing temperature lower than 200℃.

聚氨酯泡沫注浆修复材料泡孔结构特征及抗压性能研究进展

聚氨酯泡沫(PUF)注浆修复材料以轻质高强、快凝高膨胀等优势,在基础设施修复加固领域得到了广泛的应用。抗压性能是工程修复材料十分重要的力学指标之一,而材料的微观结构对其宏观力学行为有决定性影响。近年来,国内外专家学者对PUF注浆修复材料的微观结构特性和抗压性能进行了大量研究,但尚未见到系统性总结。本文介绍了PUF注浆修复材料的定义及反应过程,综述了其微观泡孔结构特性、压缩应力-应变关系和本构模型,从宏微观角度讨论了其变形和破坏机理,总结了密度、试件尺寸、应变率和特殊环境工况对压缩性能的影响机理及规律,最后展望了PUF注浆修复材料未来的研究方向。

木质素低聚物衍生聚氨酯泡沫的制备及性能

针对木质素分子结构复杂、反应活性低、高值化利用不足等问题,从木质素高效可控降解、分子结构定向化学修饰以及复合功能化等方面出发,开展了木质素可控氢化降解以及基于木质素低聚物衍生聚氨酯泡沫(PUFs)材料的制备及性能调控研究。以Ni/ZrO_(2)/Hβ为催化剂,对木质素进行部分还原降解获得了高酚羟基含量的活性木质素低聚物,继而经氧丙基化改性,制备了高反应活性的木质素低聚物多元醇(LOP),通过^(31)P NMR和^(1)H NMR表征分析了木质素低聚物及LOP,探讨了木质素低聚物改性前后的结构变化。将LOP与大豆油多元醇复配构建了全生物基PUFs材料,考察了LOP的结构及用量等对PUFs材料的微观结构、形貌及其物理化学性能的作用与影响规律,探明了不同性能木质素低聚物衍生PUFs材料的制备工艺。研究结果表明,LOP的加入会导致PUFs材料的泡孔减小,闭孔率增加,进而有效改善PUFs力学性能和高温热稳定性,通过对LOP用量的调节,可实现不同强度PUFs的高效制备(压缩强度0.27~0.65 MPa)。

单组分湿固化型聚氨酯混合料的体积膨胀特性

为研究单组分湿固化型聚氨酯混合料的体积膨胀特性,提出了基于游标卡尺的体积膨胀特性表征方法,分析了体积膨胀后的宏微观形貌,研究了不同因素作用下体积膨胀的变化规律,以及体积膨胀对空隙率的影响,并提出了抑制体积膨胀的方法.结果表明:聚氨酯混合料会因空隙率较小,致使固化反应产生的二氧化碳气体难以完全逸出,在混合料内部会产生数量较多的宏微观气孔结构,1个马歇尔试样可产生高达1.5 mm的膨胀变形;提高压实温度、采用二次压实或添加氢氧化钙,均会显著降低混合料的体积膨胀,且对路用性能也有一定提升;增大胶石比,混合料的体积膨胀单调递增,空隙率则先减小后增大.为控制体积膨胀,建议压实温度为45~65℃,且胶石比不宜过大,添加氢氧化钙时,其质量分数不宜超过1%.

聚氨酯和环氧树脂涂层耐水性能对比研究

本文选择了不同类型的聚氨酯(PU)涂层和环氧树脂(EP)涂层作为代表,通过红外光谱、固态核磁共振、热失重分析和热力学性能分析,研究了长期水下浸泡对涂层结构和性能的影响,并进一步对比了上述不同材料的水解稳定性。结果表明,聚醚型聚氨酯(PTMG-PU)涂层具有最优的耐水性,并且其化学结构基本没发生化学水解作用,然而加入陶瓷增强颗粒会降低材料的耐水性,并可能加速水解作用对涂层结构和性能的影响;相同水解条件下,聚酯型聚氨酯(PEA-PU)和EP涂层在水中的耐水性较差,并且可能发生聚合物链的化学水解作用,进而导致材料储能模量的提高。

微胶囊化硅藻土吸附改性矿用聚氨酯泡沫

针对目前矿用聚氨酯泡沫(RPUF)易燃以及阻燃剂磷酸三(2-氯丙基)酯(TCPP)、甲基膦酸二甲酯(DMMP)的应用易引起材料“坍塌”和力学性能下降等问题,采用硅藻土吸附和仿贻贝材料表面包覆的方法对传统阻燃剂进行了改性,设计并制备了环境友好的微胶囊化硅藻土吸附阻燃剂(MDFR)。利用万能试验机研究了MDFR对RPUF力学性能的影响;采用极限氧指数、垂直燃烧、锥形量热的测试手段,研究MDFR对RPUF阻燃性能的影响;利用扫描电子显微镜和热重分析等表征,研究了MDFR对RPUF微观形貌以及热稳定性的影响,并探讨了阻燃机理。结果表明,阻燃剂MDFR的加入,相比于传统阻燃剂DMMP和TCPP,RPUF的力学性能得到能明显改善,微观泡孔结构完整,并且其热解活化能升高,热稳定性增加;同时,MDFR在抑制RPUF燃烧时的烟气释放和CO释放方面效果明显,降低了有毒有害气体的释放。机理分析显示,MDFR的加入使阻燃RPUF燃烧后炭层厚度和致密性增加,有效阻止了材料燃烧过程中的热交换和可燃性气体、有毒气体的释放,使之在使用过程中更加安全。对比两种改性阻燃剂MDFR-1和MDFR-2,以TCPP为原料改性的MDFR-2阻燃剂效果更优。

空气过滤用聚氨酯纳米纤维膜的制备及其性能

为拓展静电纺纳米纤维在空气过滤领域中的应用,以聚氨酯(PU)为原料,加入不同种类的盐,采用静电纺丝法制备树枝状PU纳米纤维膜。利用扫描电镜(SEM)、接触角测试仪、红外光谱仪、自动滤料测试仪测试纳米纤维膜的微观结构、亲疏水性、化学结构和过滤性能。结果表明:在PU质量分数14%条件下,添加有机盐TBAC,纺丝电压35 kV时,制备的纳米纤维膜的树枝状分叉结构明显;TBAC的加入使纤维膜的接触角由99.1°减小到82.8°;分叉结构使纳米纤维膜的过滤性能显著提高,与纯PU纳米纤维膜相比,过滤效率从50.8%提高到93.6%,品质因子从0.009提高到0.073,可满足高效低阻空气过滤材料的需求。

舞蹈器材用改性PU胶粘剂的耐老化性能测试分析

针对聚氨酯(PU)胶粘剂在使用与存储环节较容易出现的老化问题,研制改性剂TiO_(2)-TDI粒子,其原料为甲苯2,4-二异氰酸酯(TDI)与抗氧剂2246、纳米二氧化钛(TiO_(2),金红石型),通过对二氧化钛、TiO_(2)-TDI粒子结构的热失重分析(TGA)、傅里叶变换红外光谱(FTIR)、紫外-可见漫反射(UV-vis)等加以表征。结果显示,在二氧化钛表面,通过化学键作用与TDI成功键合,完成了该改性粒子制备。此粒子对可见光、紫外线有着更强水平的吸收能力,通过化学法成功完成抗热氧化、光氧化的改性剂,可以使得PU胶粘剂耐老化性能得到显著改善,更好地应用于舞蹈器材中。

聚氨酯涂料废弃物的化学降解及其资源化利用化

以一缩二乙二醇作为醇解剂对聚氨酯涂料废弃物进行醇解,回收低分子量的多元醇,并将再生多元醇与商用多元醇混合作为原料制备再生聚氨酯泡沫。采用FTIR、GPC、TG及SEM等对再生多元醇及再生聚氨酯泡沫进行了分析测试表征,对再生多元醇及再生聚氨酯泡沫进行表征分析。通过正交试验获得了最优工艺参数,并进一步将再生多元醇与商用多元醇混合,验证其性能。结果表明,再生多元醇与聚醚多元醇在分子结构上具有一致性,且符合制备聚氨酯泡沫的性能要求;正交试验获得的最优工艺参数为:反应试剂比1∶2,反应温度180℃,反应时间2 h,催化剂添加量1.3%,在此条件下,醇解产物的提取率为36.8%,羟值为384.6 mgKOH/g,黏度为476 mPa·s;当再生多元醇在总多元醇中的比例为33%时,所制备聚氨酯具有良好的孔隙结构及热稳定性。

水利工程用环氧树脂改性聚氨酯丙烯酸酯性能研究

水利工程金属结构和水工建筑物常遭受腐蚀、高速含沙水流磨蚀破坏,需对其进行便捷有效的防护。利用环氧树脂对聚氨酯丙烯酸酯(PUA)进行改性提高PUA与基体黏结性能,采用紫外光(UV)固化技术制备PUA涂层。研究了环氧树脂改性PUA的化学结构及环氧树脂用量对PUA的力学性能、热稳定性能、耐溶剂性能和抗冲磨性能的影响。结果表明,环氧树脂改性PUA的拉伸强度随着环氧树脂用量增加,呈下降趋势,当加入5%时,PUA拉伸强度为103.0 MPa,材料呈强而脆的特性。环氧树脂加入提升了PUA的拉伸剪切强度,由0.25 MPa增至1.60 MPa。同时,环氧树脂改性PUA具有良好的耐水性能、耐溶剂性能、抗冲磨性能,5%环氧树脂改性PUA抗冲磨强度为800 h/(kg·m^(2))。

植物油基聚氨酯包膜肥料研究进展

缓释肥包膜材料采用的聚氨酯主要由石油基原料制备,由于石油基聚氨酯成本高、环境风险较大,近年来逐渐被生物基聚氨酯所取代。在众多的生物基材料中,植物油因价格低廉、来源广泛、无毒性、可生物降解等特点,成为缓控释肥料膜材的研究热点。本文分别综述了植物油基多元醇的制备方法,植物油基聚氨酯包膜的分类,植物油基聚氨酯包膜肥料的改性及应用。环氧开环、酯交换反应、氨解法、加氢甲酰化以及臭氧氧化还原是植物油改性制备植物油基多元醇的常用技术手段。丙烯酸酯、环氧树脂、有机硅、氟改性、纳米材料等是植物油基聚氨酯包膜材料改性的常用原料,试验证明植物油基聚氨酯包膜肥料具有减少氨挥发、氮淋溶,提高氮素利用效率的作用。如何提高植物油基聚氨酯交联密度、降低生产成本、深入揭示缓释机理以及扩大在大田试验的应用场景将是今后研究的重点。

聚氨酯热熔胶用预聚体的合成

以二异氰酸酯和聚醚多元醇为原料,通过定时测定—NCO的含量,确定了合适的预聚反应时间和温度,制备了聚氨酯热熔胶用预聚体。对影响预聚体合成的因素:异氰酸酯的种类、—NCO的含量、水分的含量以及预聚体的贮存稳定性等进行了探讨。结果表明,最佳预聚反应条件为80℃、2 h,—NCO含量控制在9%~10%,物料中水分质量分数低于0.05%,制备的产物性能稳定。

聚氨酯改性水泥基材料研究进展

聚氨酯应用于水泥基材料中可以改善水泥基材料的弹韧性、抗冻和抗渗等性能。总结了聚氨酯对水泥基材料的工作性能、力学性能、微观结构及抗冻融性能的影响规律,提出了聚氨酯在水泥基材料中应用的局限性,并结合工程实际,探究了聚氨酯水泥基材料的应用场景,展望了聚氨酯水泥基材料的发展新趋势。

网状孔壁碳化硅基多孔陶瓷的制备及其颗粒物过滤研究

为了提高碳化硅基多孔陶瓷的过滤性能,以碳化硅粉体、氧化铝粉体、聚醚多元醇、多亚甲基多苯基异氰酸酯、二月桂酸二丁基锡、三乙烯二胺、稳泡剂硅油(阿拉丁)为原料,通过聚氨酯发泡技术,研制了三维(3D)网状孔壁结构的碳化硅基多孔陶瓷试样,并探索了料浆固含量(固相质量分数分别为45%、50%、55%和60%)对试样显微结构、物理性能和颗粒物过滤性能的影响。结果表明:1)随着固含量的升高,试样体积密度和常温耐压强度提高,显气孔率降低;2)聚氨酯发泡过程中产生的微孔会分布在陶瓷孔壁上形成网状孔壁结构,增大颗粒物与孔壁碰撞概率,提高试样的过滤效率;同时,网状孔壁结构还可以提高试样气孔贯通性,降低其压降;3)当固含量为55%(w)时,试样体积密度约为0.57 g·cm^(-3),显气孔率为79.2%,常温耐压强度为3.7 MPa;且对颗粒物的去除率高达91.2%,具有良好的再生性能。

塑胶跑道用超细纤维聚氨酯合成革的制备及性能测试

为改善塑胶跑道综合应用性能,优化超细纤维聚氨酯合成革物理机械性能,本文由聚氨酯树脂含浸无纺布制备了超细纤维聚氨酯合成革,并对其力学性能与卫生性能进行了测试表征。结果发现,随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布表观密度增大,密实程度提高,而压缩弹性率先增加后减少;随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布剥离强度逐渐升高,拉伸强度、断裂伸长率皆呈现先降低后升高再降低的曲线形态,而撕裂强度则表现为先降低后升高的态势;随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布透气性与透水汽性持续性下降;超细纤维聚氨酯合成革基布的干擦与湿擦色牢度均可达到5,而于氢氧化钠溶液中不溶色,表明基布耐碱性良好。

聚氨酯与稀释沥青相互作用的分子动力学模拟

为从分子尺度深入了解聚氨酯与稀释沥青的相互作用,采用Materials Studio软件,分别构建沥青、聚氨酯、聚氨酯-稀释沥青共混模型,并验证模型准确性。基于分子动力学模拟,开展温度和聚氨酯掺量对稀释沥青内聚能密度、溶解度参数、相互作用能、力学性能的影响研究。结果表明:建立的沥青和聚氨酯分子模型较合理,能够表征沥青和聚氨酯真实特性;随着温度的升高,稀释沥青和稀释沥青-聚氨酯共混体系的内聚能密度均呈下降趋势;在[-10℃,100℃]范围内,聚氨酯添加物能够降低稀释沥青的内聚能密度,不同温度下降低幅度平均为15%;在60℃时,稀释沥青与聚氨酯的溶解度参数δ差值最小,各总相互作用能和范德华势能最大,体系最稳定;聚氨酯能够提高稀释沥青的力学参数,并且力学参数与聚氨酯的掺量呈正相关关系。研究对树脂改性冷补沥青混合料具有参考价值。