聚氨酯/氮化硼纳米片复合材料的制备及形状记忆性能研究

在聚氨酯(PU)制备过程中,加入球磨法制备得到的氮化硼纳米片(BNNS)分散液,制备PU/BNNS复合材料体系。采用X-射线衍射、傅里叶红外光谱和扫描电子显微镜对样品的分子结构和微观形貌进行表征,并考察样品的力学性能、形状记忆性能和自修复性能。结果表明：BNNS引入后,复合材料的力学性能得到显著提升。当加入BNNS含量为0.5 wt%时,拉伸强度达到14.8±1.5 MPa,比纯PU提升了138.7%。BNNS具有良好导热性能,能改善复合材料的形状记忆性能。在引入BNNS后,复合材料的形状固定率、形状回复率均能得到提高。     

液化MDI/PHMA体系形状记忆聚氨酯结构与性能的研究

用聚已二酸已二酯(PHMA)为软段,液化MDI和BDO为硬段,采用两步溶液法合成了具有形状记忆功能的多嵌段聚氨酯,利用DSC,WAXD等测试手段分析了该体系的形态结构,同时讨论了该体系的形状记忆行为、拉伸力学性能及动态力学性能.结果发现,该体系SMPU的硬段以无定形存在,软段具有很好的结晶性能;具有很好的形状记忆性能,形状固定率可达100%,形状回复率在97%以上,回复温度在35~45℃;同时它兼有较高的拉伸强度(约为28~50 MPa)和断裂伸长率(约为900%~1400%);动态力学性能卓越,其室温模量可达279.8 MPa,软段熔融前后模量比可达140.     

新型光、 热双响应形状记忆聚合物的制备与性能

通过多巴胺表面原位聚合反应修饰玻璃微珠, 利用X光电子能谱仪(XPS)和傅里叶变换红外光谱仪 (FTIR)对修饰前后玻璃微珠表面的化学组成进行了表征, 用热失重分析仪(TGA)对其热稳定性进行了测试, 并利用透射电子显微镜(TEM)和扫描电子显微镜(SEM)对其形貌进行了观察; 研究了改性玻璃微珠对形状记忆共混物聚己内酯和聚氨酯(PCL/TPU)的热性能、 力学性能和形状记忆性能的影响. 结果表明, 成功制备了表面包覆聚多巴胺的玻璃微珠(PHGM), 改性玻璃微珠的加入不仅增强了复合材料的力学性能(当改性玻璃微珠含量为3%时, 材料的拉伸强度提高到53.3 MPa, 杨氏模量提高到178.4 MPa), 还赋予了复合材料优异的光热效应. 所制备的形状记忆复合材料在808 nm近红外光的照射下, 可以在短时间内(7 s)升高到材料的开关温度并回复到初始形状.     

聚甲基乙撑碳酸酯/氧化石墨烯纳米复合材料的制备及性能研究

本文采用改进Hummers法制备氧化石墨烯(GO),通过原子力显微镜对GO片层形貌进行表征;以聚甲基乙撑碳酸酯(PPC)、聚乙烯醇(PVA)和氧化石墨烯(GO)为原料,采用溶液和熔融共混法相结合,制备PPC/PVA/GO纳米复合材料,研究其力学性能、热学性能和动态流变行为。结果表明,当GO含量为0.5 wt%时,拉伸强度达到了22.03 MPa,与纯PPC相比提高了25.8%;当GO含量增大到1.0 wt%时,拉伸强度开始降低;断裂伸长率随GO的加入呈现降低的趋势。GO含量为1.0%时复合材料的热学性能最好,与纯PPC相比,复合材料的完全热分解温度从350℃提高到了400℃以上,并且热分解速率下降了12%/min;复合材料的复数黏度、储能模量和损耗模量随PVA及GO的引入也有一定程度的提高。     

石墨烯-聚酰亚胺复合薄膜的制备及性能表征

首先制备可均匀分散于N,N’-二甲基甲酰胺(DMF)中的氧化石墨烯片(GO),将GO的DMF分散液与聚酰胺酸(PAA)的DMF溶液进行液相共混,然后流延成膜制得GO-PAA复合薄膜,最后将PAA进行热酰亚胺化处理,在此过程中GO被原位还原为石墨烯(GS),从而获得石墨烯-聚酰亚胺(GS-PI)复合薄膜.将具有不同石墨烯含量的复合薄膜样品分别进行热重分析及力学和电学性能测试.结果表明,随着GS含量的增加GS-PI复合薄膜的表面电阻率逐渐降低.使用1.0 wt%的GO制备的GS-PI复合薄膜的表面电阻率降至106Ω,此后趋于稳定.在GO不高于0.6 wt%的用量下制备的复合薄膜的拉伸强度和断裂伸长率可发生同步增加;至GO用量为0.6 wt%二者的增强都达到最高值.此后继续增加GS含量,拉伸模量持续提高,断裂伸长率出现下降.在实验涉及的范围内,复合薄膜保持良好的延展性和热稳定性.     

形状记忆聚偏氟乙烯/丙烯酸酯/碳纳米管纳米复合材料的导电及导热性能

利用聚偏氟乙烯(PVDF)微小结晶的物理交联点作用,制备了形状记忆性能优异的聚偏氟乙烯/丙烯酸酯聚合物(PVDF/ACM)共混材料,为提高其导电及导热性能,于其中引入了碳纳米管(CNT),系统研究了PVDF/ACM/CNT三元体系纳米复合材料的导热及导电性能。结果表明,碳纳米管在PVDF/ACM体系中分散均匀;在基本保持其形状记忆性能的前提下,碳纳米管的加入使材料导热性能及导电性能有较大程度的提高:质量分数为4%的CNT使材料25℃的电阻值降低至5000Ω/square,导热系数提高至0.157 W/(m·K)。     

纳米复合形状记忆聚合物

形状记忆聚合物(SMPs)是一种刺激响应型智能材料,在受到热、电、交变磁场、光、湿度或化学等外界刺激时,材料能够发生较大的可回复形变,在生物医用材料、航天航空、汽车、纺织等领域有广泛的应用。但SMPs强度和模量低,形状回复应力小,回复速度较慢等缺点限制了其应用,纳米复合可以克服SMPs的这些缺点。本文在介绍SMPs的基础理论基础上,从纳米改性的目的和激发方式出发,综述了不同纳米颗粒与SMPs的作用机理,并展望了纳米复合SMPs的研究和发展趋势。     

碳纳米管改性聚苯硫醚熔纺纤维的结构与性能研究

将多壁碳纳米管(MWCNTs)和聚苯硫醚(PPS)经过熔融挤出后制备成复合材料切片,并采用熔融纺丝法制得碳纳米管改性聚苯硫醚复合纤维.采用扫描电镜(SEM)、拉曼光谱、示差扫描量热分析(DSC)、动态机械分析(DMA)以及力学性能测试等表征手段研究了复合纤维中碳管的分散状态,与基体的界面作用,复合纤维的结晶性能以及力学性能,从而探讨了聚苯硫醚/碳纳米管复合纤维体系的微观结构与宏观性能之间的关系.研究表明,聚苯硫醚分子结构与碳纳米管之间具有的π-π共轭作用使碳管较为均匀的分散在基体中,界面结合较为紧密.同时熔融纺丝过程中的拉伸作用使碳管进一步解缠并使碳管沿纤维拉伸方向取向.另一方面,拉曼光谱显示拉伸作用有效地增强了界面作用,有利于外界应力的传递.碳管的良好分散以及强的界面作用使复合纤维力学性能得到大幅度的提高,当碳管含量达到5 wt%时,复合纤维的模量有了明显的提高,拉伸强度较纯PPS纤维提高了近220%.     

形状记忆聚偏氟乙烯/丙烯酸酯/碳纳米管纳米复合材料的导电及导热性能

利用聚偏氟乙烯（PVDF）微小结晶的物理交联点作用,制备了形状记忆性能优异的聚偏氟乙烯/丙烯酸酯聚合物（PVDF/ACM）共混材料,为提高其导电及导热性能,于其中引入了碳纳米管（CNT）,系统研究了PVDF/ACM/CNT三元体系纳米复合材料的导热及导电性能。 结果表明,碳纳米管在PVDF/ACM体系中分散均匀;在基本保持其形状记忆性能的前提下,碳纳米管的加入使材料导热性能及导电性能有较大程度的提高：质量分数为4%的CNT使材料25 ℃的电阻值降低至5000 Ω/square,导热系数提高至0.157 W/(m·K)。     

木质素/氧化锌复合颗粒的制备及在水性聚氨酯中的应用

通过沉淀法以季铵化木质素(LQAs)、醋酸锌和NaOH为原料制备了不同木质素负载量的木质素/氧化锌(LQAs/ZnO)复合颗粒.测试结果表明,LQAs/ZnO复合颗粒是由LQAs和ZnO形成的杂化结构,且NaOH用量对LQAs/ZnO复合颗粒的形貌有显著影响.与纯ZnO相比,复合颗粒对紫外光的吸收明显增强.此外,探究了复合颗粒掺杂改性的水性聚氨酯(WPU)复合薄膜的光学和力学性能.与0.6%(质量分数)的LQAs/ZnO复合颗粒均匀共混成膜的WPU复合薄膜的断裂拉伸强度和断裂伸长率相较于纯WPU薄膜,分别提高了81.5%和10.9%.经过192h紫外光老化测试后,断裂拉伸强度保持在25 MPa以上,断裂伸长率保持在360%以上,表明LQAs/ZnO复合颗粒可有效提高WPU薄膜的紫外屏蔽性能和抗紫外老化性能.     

表面改性对VGCF分散性质的影响

针对气相生长碳纤维极易团聚及与树脂基体界面结合能力较差的难题,采用双氧水-浓硝酸二步法对VGCF进行表面改性处理。利用X射线衍射仪、热重分析仪、傅立叶红外光谱仪、紫外可见分光光度计等测试分析了改性前后VGCF的表面结构和在溶剂中的分散性,并以形状记忆聚氨酯为基体,采用溶液混合法制备了气相生长碳纤维/形状记忆聚氨酯的复合材料,测试了复合材料的力学性能。经过改性后,VGCF的石墨晶型结构几乎没有改变,VGCF表面的含氧官能团浓度得到较大提高,且其在有机溶剂中的分散性及分散稳定性也得到很大提高;在气相生长碳纤维/形状记忆聚氨酯的复合材料截面中,扫描电镜观察表明表面改性使得VGCF在基体中的分散性及与基体的界面结合能力都得到一定程度的提高;经二步法改性处理后的气相生长碳纤维比未处理气相生长碳纤维对复合材料的力学性能的增强效果更为明显。     

SHAPE MEMORY EFFECT OF SLIGHTLY-CROSSLINKED POLYETHYLENE

A series of slightly crosslinked polyethylenes (SXLPE) was prepared by aone-step method using dicumyl peroxide as crosslinking agent in a Haake Mixer. The gelcontents G (Soxhlet extracted) of the samples are in the range from 5% to 20% by weight.Their shear viscosity, crystallization and melting behavior, dynamic mechanical propertiesand shape recovery effect were systematically investigated in terms of the content of thecrosslinking agent. It shows that under certain experimental conditions the SXLPE's mayexhibit good shape fixation ability and shape memory properties, which are similar to thoseof the commercially available shape memory polyethylenes prepared by gamma-irradiationtechnique. However the shape memory behavior of these samples is not very stable due totheir low crosslinking degree, or gel content. Thus their application is limited in specialcases with fast strain fixing procedures.     

Mechanical and shape memory performance of shape memory polyurethane-based aligned nanofibers

In recent years, shape memory polyurethane (SMPU) as a smart material has been used in various applications owing to its desirable shape memory effect and biocompatibility. In this study, unidirectional SMPU nanofibers are innovated by electrospinning to clarify the mechanical and shape memory properties with nanofiber directions. The results showed that when the nanofiber alignment degree is 0° (parallel to the tensile direction), the aligned SMPU nanofibers achieved the obvious improvement of tensile strength (increased to 135%) and elastic modulus (increased to 313%), compared with the random SMPU nanofiber. Moreover, the developed aligned nanofibers exhibited good ability against stress relaxation and creep under constant strain or constant stress conditions in cyclic loading. The aligned SMPU nanofibers with a 0° alignment degree exhibited excellent shape memory properties with shape recovery rates larger than 93% and shape fixity rates larger than 90%, and a dramatic increase of shape recovery stress.     

Enhanced thermal and tensile behaviour of MWCNT reinforced palm oil polyol based shape memory polyurethane

Shape memory polyurethane (SMPU) has received tremendous interest because of its low cost, low density, as well as easy processing. However, its inferior mechanical properties compared to shape memory alloys have constrained its application in a broad range of engineering areas. Nanofillers are commonly added to polymers to overcome the problem associated with low mechanical characteristics. This study aims to examine the effect of various loadings of multiwalled carbon nanotubes (MWCNT) on the thermal stability, soft segment crystallinity, tensile and shape memory behaviour of palm oil polyol based SMPU nanocomposites. The SMPU nanocomposites were synthesised using a two-step polymerisation process. Microphase-separated SMPU nanocomposites obtained as the differential scanning calorimetric analysis showed two melting transitions, which belonged to the soft and hard phase domains. Furthermore, it was found that MWCNT had acted as a nucleating agent, which promoted the crystallisation process of SMPU nanocomposites. The thermal stability and tensile properties of SMPU/MWCNT nanocomposites were enhanced significantly as the MWCNT was added to the SMPU matrix. A considerable enhancement in the shape fixity (SF) value was revealed for PU-30 and PU-40 samples with the addition of MWCNT. The shape recovery (SR) time of SMPU was faster for samples reinforced with MWCNT, whereas SF increased while SR decreased upon increasing the shape memory cycle. The SMPU nanocomposites produced demonstrated enhanced thermal and tensile properties, which has the potential as smart material in many industrial applications.     

SHAPE MEMORY EFFECT OF PU IONOMERS WITH IONIC GROUPS ON HARD-SEGMENTS

SMPU （shape memory polyurethane） non-ionomers and ionomers, synthesized with poly（c-caprolactone） （PCL）, 4, 4＇-diphenylmethane diisocyanate （MDI）, 1,4-butanediol （BDO）, dimethylolpropionic acid （DMPA） were measured with cyclic tensile test and strain recovery test. The relations between the structure and shape memory effect of these two series were studied with respect to the ionic group content and the effect of neutralization. The resulting data indicate that, with the introduction of asymmetrical extender, the stress at 100% elongation is decreased for PU non-ionomer and ionomer series, especially lowered sharply for non-ionomer series; the fixation ratio of ionomer series is not affected obviously by the ionic group content; the total recovery ratio of ionomer series is decreased greatly. After sufficient relaxation time for samples stretched beforehand, the switching temperature is raised slightly, whereas the recovery ratio measured with strain recovery test method is lowered with increased DMPA content. The characterization with FT-IR, DSC, DMA elucidated that, the ordered hard domain of the two series is disrupted with the introduction of DMPA which causes more hard segments to dissolve in soft phase; ionic groups on hard segment enhance the cohesion between hard segments especially at high ionic group content and significantly facilitate the phase separation compared with the corresponding non-ionomer at moderate ionic group content.     

Competing and decisive roles of 1D/2D/3D sp2-carbons in controlling the shape switching,contact sliding,and functional properties of polymers

Stimuli-controllable shape-shifting polymers, such as shape memory polyurethane (SMPU), are promising for robotics, aerospace, sensing, automobiles, and many other applications. However, slow actuation or high shape recovery time, low recovery stress, and inadequate understanding of friction and wear characteristics of SMPU limit its widespread practical uses. Further, SMPU has been engineered with diverse foreign materials but inconsistent results and ambiguous underlying mechanisms, especially when SMPU is modified with sp²-carbon materials, are also major concerns. Here we determine and simultaneously cross-compare the role of 1D/2D/3D graphitic carbons, namely carbon nanotubes, multilayer graphene and graphite, in controlling the properties of SMPU. The designed SMPU-composites display 8–15-folds faster shape recovery in different mediums, higher recoverable stress, faster healing of the dents, 2–3-folds lower friction, better wear resistance, and improved thermal, wettability, and dielectric properties than pristine SMPU. Further, while the introduction of 2D/3D graphitic carbons massively degrade the elongation, 1D carbon nanotubes maintains the stretchability of SMPU. Eventually, we develop a novel heat alarm device employing SMPU-composite as a major component that acts as a heat sensor, an actuator, and enables the closure of the circuit. Our results uncover many unknown phenomena of engineered SMPU and pave the way for the development of smart-technologies.     

具有热致形状记忆功能的热塑性多嵌段聚氨酯

以ＰＣＬ为软段、ＴＤＩ－ＢＤＯ为硬段，采用溶液聚合的方法合成了具有形状记忆功能的线性多嵌段聚氨酯．利用ＤＳＣ、ＤＭＴＡ、ＷＡＸＤ等测试手段对体系的结晶性、微相分离行为进行了研究．结果发现：聚氨酯中硬段的存在对软段的结晶有着很大的影响，当软段序列的平均分子量达到３０００以上时，软段才可以很好地结晶；并且，硬段含量也必须高于一定值才能形成较为完善的物理交联点．符合这些条件的试样能显示很好的形状记忆特征．此外还就拉伸比、多次形变以及组成等对材料的形状回复性能的影响进行了详细的研究．     

可生物降解多嵌段聚(酯-氨酯)的合成及其热致形状记忆性质

以端羟基L-丙交酯/乙交酯共聚物(PLLG-diol)和端羟基ε-己内酯/乙交酯共聚物(PCG-diol)为硬段和软段,通过与二异氰酸酯反应制得了软、硬分子量和组成均可调的多嵌段聚(酯-氨酯),表征了它们的形状记忆行为.多嵌段聚(酯-氨酯)具有良好的形状记忆性质,应变固定率达98%~99.5%,应变恢复率达93%~98.5%;通过转变温度的调节,可使多嵌段聚(酯-氨酯)在37℃体温下不发生形状变化,而在稍高于体温的温度(40~50℃)下恢复原始形状,其形状恢复速率可通过温度和升温速率来调节.     

芳纶纤维/SMPU-SiO2复合材料的界面性能研究

选用形状记忆聚氨酯(SMPU)和正硅酸乙酯(TEOS)为前驱体,固体酸对甲基苯磺酸(PTSA)为催化剂,利用空气中的水分为水解水源,通过溶胶-凝胶法原位制备了形状记忆聚氨酯与二氧化硅( SMPU-SiO2)杂化材料,并将杂化材料应用于芳纶纤维增强的柔性复合材料中,以期改善芳纶纤维与基体的界面性能.同时,针对芳纶纤维表面...