新型材料——IPN

IPN是互穿网络聚合物(Interpenetrating Polymer Network)的简称,这个名称是1960年由Millar首先提出来的.在70年代它基本上还处于研究阶段,到80年代它已经发展成为能实际应用的一种新型材料.所谓IPN,是两种以上的聚合物,通过物理或化学的交联分别形成网络,而各网络链之间又相互贯穿、缠结,形成具有不同相容性微区结构的多相体系.IPN的最大特点是能理想地使两种以上的聚合物网络相互缠结、互穿而不失去原聚     

聚氨酯/环氧树脂互穿网络聚合物的性能研究

互穿聚合物网络（Interpenetrating polymer net-work,简称IPN）广泛应用的为聚氨酯基的互穿网络聚合物。其合成多集中在弹性体方面。本文用同步法合成的聚氨酯／环氧树脂互穿网络硬质泡沫塑料材料（简称PU／ERIPNF）,机械性能较好,并研究了其动态力学性能及形态变化。     

粘弹性阻尼材料中互穿聚合物网络技术的应用

阐述了粘弹性材料在振动波作用下的阻尼机理,指出声波法和模量法的统一性。综述了互穿聚合物网络技术要点,并解释相分离体系宽玻璃化转变区间的形成机理;介绍了互穿聚合和网络技术形成的新途径及梯度互穿聚合物网络技术要点。     

互穿网络聚合物的某些进展

综述近年来热塑性互穿网络聚合物及以蓖麻油为原料合成的互穿网络聚合物的进展。     

氧化淀粉的氧化度对其交联海藻酸钠/明胶互穿网络膜性能的影响

以氧化淀粉为交联剂交联明胶、以氯化钙为交联剂交联海藻酸钠,采用分步交联的方法制备了海藻酸钠/明胶互穿网络膜.通过红外光谱仪表征了氧化淀粉、海藻酸钠/明胶互穿网络膜的结构;研究了氧化淀粉的氧化度对互穿网络膜力学性能、热稳定性能、微观形貌、交联度、吸水保水性能等各种性能的影响.结果表明,随着氧化淀粉氧化度的增加,互穿网络膜的拉伸强度、断裂伸长率、交联度呈现先增加后降低的趋势,氧化度为60%的氧化淀粉交联制备的互穿网络膜的以上性能达到最大值;吸水保水性能呈现先降低后增加的趋势,这主要是因为随着互穿网络膜交联度的增加,使两相间形成了均匀、致密的网络结构,两者分子链上大量的羟基和羧基受到束缚,导致互穿网络膜吸水率、保水率的下降.同时也说明了该体系的交联度并不是随着氧化淀粉氧化度的提高而逐渐提高,对于该体系氧化淀粉存在最佳氧化度.     

互穿结构及混合配体对金属-有机骨架材料分离性能的影响

在以前的工作中, 我们利用蒙特卡洛和分子动力学模拟计算了具有互穿性结构及混合配体的金属-有机骨架材料(metal-organic frameworks, MOFs)分离CH₄/H₂的吸附选择性及扩散选择性. 研究了材料的互穿结构及混合配体对材料用于分离CH₄/H₂性能的影响. 在本工作中, 我们将以前的工作进行了扩展, 详细研究了材料的互穿结构及混合配体对材料用于分离CO₂/CH₄, CO₂/N₂和CO₂/H₂等含有CO₂的气体混合物性能的影响. 此外, 为了进一步阐明材料的结构对于其分离性能的影响, 我们亦研究了材料用于分离CH₄/H₂及CH₄/N₂. 从我们的结果可以看出, 相比无互穿结构的MOFs材料, 具有互穿结构的MOFs材料对所研究的所有混合气体的渗透选择性明显提高. 这是因为具有互穿结构的MOFs材料对混合气体的吸附选择性明显高于无互穿结构的MOFs材料. 结果表明, 如果将材料作为膜用于气体混合物分离, 使材料产生互穿结构是提高材料分离性能的一个很好的策略.     

高分子阻尼涂料的研究进展

介绍了高分子阻尼涂料的阻尼机理和组成,以及阻尼涂料的高分子改性方法,包括共聚、共混和互穿网络(IPN)等以及国内外发展现状。重点介绍了目前通用的树脂基料和填料,详细介绍了互穿网络改性方法和乳液聚合物互穿网络,以及环境友好水性阻尼涂料的研究现状和发展。     

邻甲酚醛环氧树脂/聚氨酯互穿聚合物网络的形态与性能

邻甲酚醛环氧树脂/聚氨酯互穿聚合物网络的形态与性能;互穿聚合物网络; 邻甲酚醛环氧树脂; 聚氨酯; 力学性能; 玻璃化转变温度     

聚丙烯酰胺/聚异丙基丙烯酰胺互穿网络水凝胶的制备与性能

采用分步法用电子加速器辐射合成了聚丙烯酰胺(PAAm)/聚异丙基丙烯酰胺(PNIPAAm)互穿网络水凝胶,并考察了温度、pH值、离子强度对其溶胀性能的影响.研究表明:互穿水凝胶具有温度敏感性,且其体积相变与互穿网络中PAAm和PNIPAAm含量有关,随着网络中PAAm含量的增加水凝胶的体积相变趋于平缓,可以通过改变PAAm和PNIPAAm的组成比来控制水凝胶的体积相变行为.此外,互穿水凝胶还具有pH敏感性和一定的抗盐性.     

微波辐照合成互穿聚合物网络及形态性能研究

微波辐照合成互穿聚合物网络及形态性能研究李卫华，王静媛，李跃先，刘福安，李玉玮，汤心颐（吉林大学化学系，长春，１３００２３）关键词微波辐照，互穿聚合物网络（ＩＰＮｓ），形态性能互穿聚合物网络（ＩＰＮｓ），是一种新型的高分子复合材料，因具有独特的消声、...     

Preparation of epoxy-acrylic latex based on bisphenol F epoxy resin

Bisphenol F based epoxy-acrylic latex with different amount of epoxy resin was successfully prepared by semi-continuous seeded emulsion polymerization. The resulting composite latexes had a narrow size distribution of about 105 nm in diameter. The DSC result showed that the epoxy resin and polyacrylate were grafting copolymerization. The FTIR spectra showed that the epoxy group had been introduced into the epoxy acrylic latex system, and the composite latex could be crosslinked with epoxy hardener at room temperature. The crosslinked composite latex film exhibited a high Tg compared to epoxy-acrylic latexes. The surface of the films with the epoxy resin was regular, and diffused into the polyacrylate phase in the epoxy-acrylic latexes films. Since the curing reactions occurred before latex particle coalescence stage, the surfaces of the cured epoxy-acrylate latex films had a number of interface particle. Compared with the acrylic latex, the thermal stability of the epoxy-acrylate latex was increased, and the stability of the cured film increased with increasing epoxy content.     

Mechanical and thermal properties of (Ag/C nanocable)/epoxy resin composites

A novel Ag/C nanocable and epoxy resin composite was obtained by compounding Ag/C nanocables and epoxy resin. The nanocable is composed of a nanowire (core) wrapped with one or more outer layers (shell). Scanning electron microscopy images proved that the nanocables consisted of a silver nanowire core and a carbon outer shell. The Ag/C nanocables were modified by hyperbranched poly (amine ester) to improve their mechanical properties for further application. We separately compounded raw and modified Ag/C nanocables with epoxy resin, and then tested the thermal performance, tensile properties, and fracture morphology of each composite. We found that the tensile strengths of the two composite systems were enhanced by the epoxy resin, with the modified (Ag/C)/epoxy resin composite system improving more significantly. Differential scanning calorimeter (DSC) results showed that the glass transition temperature of the unmodified (Ag/C)/epoxy resin composite is increased when the Ag/C nanocable is filled, while that of the modified system slightly decreased. Fracture morphology results showed that both (Ag/C)/epoxy composite systems featured increased toughness. The modified Ag/C nanocables had better compatibility with the epoxy resin. The relationship between the properties and microstructure of the composites were discussed in detail to explain the mechanism behind the observed changes in material properties.     

UV-cured coatings for functional protection

Photopolymerizing formulations of urethane-acrylate and epoxy-acrylate oligomers with active diluents of varied functionality and molecular mass were studied. It was found that the functionality of the monomers strongly affects the mechanism by which protective properties of a coating are formed. The limits of the range of optimal concentrations of the active monomers were found. It was confirmed that the maximum protective properties of the coatings are observed when unifunctional and bifunctional active diluents are used in the mixture formulation in a stoichiometric or nearly so ratio. The possibility of creating formulations with nanosize particles of functional additives determining the purpose of a formulation (anticorrosive, decorative) was revealed and substantiated.     

一种液晶环氧增韧环氧树脂的研究

环氧树脂具有优异的机械性能 ,耐高温以及良好的加工工艺性 .被广泛用于机械、航天、船舶等领域 .由于环氧树脂固化后断裂延伸率小 ,脆性大 ,使其应用受到了一定的限制 .为此 ,国内外学者对环氧树脂进行了大量的改性研究工作 .用含有“柔性链段”的固化剂固化环氧 ,在交联网络中引入柔性链段[1] ;在环氧基体中加入橡胶弹性体[2 ] 、热塑性树脂[3 ,4] 、液晶聚合物[5,6] 等分散相或用热固性树脂连续贯穿于环氧树脂网络中形成互穿、半互穿网络结构[7] ,以改善环氧树脂的韧性 .本文采用液晶环氧化合物原位复合增韧环氧树脂 ,考察了液晶环氧对环…     

一种新型室温固化、耐高温环氧树脂体系及其性能

采用1-己基-3-甲基咪唑四氯化铁盐([C₆mim]FeCl₄)与混合胺复配室温(20 ℃)固化双酚A型环氧树脂E-51,并与其它脂肪胺类室温固化E-51体系在力学性能、热性能、耐老化性能方面的数据进行了比较,同时分析了[C₆mim]FeCl₄不同添加量对固化体系性能的影响,结果显示:[C₆mim]FeCl₄/混合胺复配室温固化E-51体系的室温拉伸强度可达90 MPa,高温(120 ℃)下也保持了良好的力学性能,热失重(5%)分解温度为310 ℃,200 ℃老化7 d后,拉伸强度为28 MPa,是一种可在高温下使用的新型环氧树脂室温固化体系。     

Diglycidyl ether of bisphenol-A epoxy resin–polyether sulfone/polyether sulfone ether ketone blends: phase morphology, fracture toughness and thermo-mechanical properties

The properties of diglycidyl ether of bisphenol-A epoxy resin toughened with poly(ether sulfone ether ketone) (PESEK) and poly(ether sulfone) (PES) polymers were investigated. PESEK was synthesised by the nucleophilic substitution reaction of 4,4’-difluorobenzophenone with dihydroxydiphenylsulfone using sulfolane as solvent and potassium carbonate as catalyst at 230 °C. The T _g–composition behaviour of the homogeneous epoxy resin/PESEK blend was modelled using Fox, Gordon–Taylor and Kelley–Bueche equations. A single relaxation near the glass transition of epoxy resin was observed in all the blend systems. From dynamic mechanical analysis, the crosslink density of the blends was found to decrease with increase in the thermoplastic concentration. The storage modulus of the epoxy/PESEK blends was lower than that of neat resin, whilst it is higher for epoxy/PES blends up to glass transition temperature, thereafter it decreases. Scanning electron microscopic studies of the blends revealed a homogeneous morphology. The homogeneity of the blends was attributed to the similarity in chemical structure of the modifier and the cured epoxy network and due to the H-bonding interactions between the blend components. The fracture toughness of epoxy resin increased on blending with PESEK and PES. The increase in fracture toughness was due to the increase in ductility of the matrix. The thermal stability of the blends was comparable to that of neat epoxy resin.     

Micro phase separated epoxy/poly(ε-caprolactone)-block-poly(dimethyl siloxane)-block-poly(ε-caprolactone)/4,4′-diaminodiphenylsulfone systems: Morphology,viscoelasticity, thermo-mechanical properties and surface hydrophobicity

Epoxy resin/4,4′-diaminodiphenylsulfone (DDS) system was modified by the incorporation of poly(ε-caprolactone)-block-poly(dimethyl siloxane)-block-poly(ε-caprolactone) (PCL–PDMS–PCL) triblock copolymer (TBCP). Morphology, viscoelasticity, thermo-mechanical and surface properties of these blends were investigated. All the blends were opaque after curing. PCL blocks of the TBCP were miscible with epoxy resin while the PDMS fraction was immiscible. However in the cured state, both PCL and PDMS blocks were phase separated from epoxy/DDS matrix. The blends exhibited matrix-droplet morphology in which TBCP phase dispersed as spherical domains in epoxy matrix. Addition of TBCP had profound impact on the cure reaction kinetics. Storage modulus and glass transition temperature (T_g) decreased while impact strength significantly increased. Incorporation of 15 phr of TBCP resulted in 80% improvement in impact strength. Further, thermal stability was unaffected while surface hydrophobicity of the blends increased.     

环氧树脂在热塑性树脂改性中的应用

本文综述了国内外有关利用环氧树脂改性热塑性树脂共混体系研究的最新进展。着重阐述了环氧树脂在热塑性树脂之间的增容作用,如尼龙6(PA6)合金体系,改性聚苯乙烯塑料(ABS)合金体系,以及聚对苯二甲酸丙二醇酯(PTT)合金体系等。同时,介绍了利用环氧树脂的反应活性提高无机填料在聚合物中分散性研究的情况,如二氧化硅纳米粒子在聚醚砜(PES)中,以及滑石粉在聚丙烯(PP)中分散性的提高。最后,简介了环氧树脂改性热塑性树脂提高热塑性树脂物理机械性能方面的研究方向和成果并展望了环氧树脂在热塑性树脂改性研究中的前景。     

动态固化聚丙烯/环氧树脂共混物的研究

将动态硫化技术应用于热塑性树脂 热固性树脂体系 ,制备了动态固化聚丙烯 (PP) 环氧树脂共混物 .研究了动态固化PP 环氧树脂共混物中两组分的相容性、力学性能、热性能和动态力学性能 .实验结果表明 ,马来酸酐接枝的聚丙烯 (PP g MAH)作为PP和环氧树脂体系的增容剂 ,使分散相环氧树脂颗粒变细 ,增加了两组分的界面作用力 ,改善了共混物的力学性能 .与PP相比 ,动态固化PP 环氧树脂共混物具有较高的强度和模量 ,含 5 %环氧树脂的共混物拉伸强度和弯曲模量分别提高了 30 %和 5 0 % ,冲击强度增加了 15 % ,但断裂伸长率却明显降低 .继续增加环氧树脂的含量 ,共混物的拉伸强度和弯曲模量增加缓慢 ,冲击强度无明显变化 ,断裂伸长率进一步降低 .动态力学性能分析 (DMTA)表明动态固化PP 环氧树脂共混物是两相结构 ,具有较高的储能模量 (E′)     

Fracture toughness and surface morphology of micro/nano sized fibrils-modified epoxy resin

Two kinds of micro/nano sized fibrils based on cellulose (MFC) and polyvinyl alcohol (PVA) were used as reinforcer for epoxy resin (EP) with different contents in the range from 0 to 0.3 wt %. PVA nanofibers with diameter about 40–80 nm were fabricated by electrospinning technique. The analysis of mechanical properties showed that by both adding MFC and PVA to EP the fracture toughness was increased. The SEM results showed that micro/nano sized fibers dispersed throughout epoxy resin, prevented and changed the path of crack growth.