聚环氧氯丙烷氨酯阻尼材料的阻尼性能研究

<正> 一般来讲,聚合物材料的阻尼性能来源于分子链运动带来的内摩擦力以及分子间物理键的破坏与再生,分子链运动所产生的阻尼在聚合物的玻璃化转变温度范围内最为有效。因此具有极性较强、体积较大的一CH_2Cl侧基的环氧氯丙烷聚合物应具有优异的阻尼性能,专利文献[1—2]报道过由多羟基(官能度≥2)聚环氧氯丙烷预聚物为原料制得的聚氨酯泡沫具有良好的阻燃性能,作者在聚环氧氯丙烷氨酯阻尼材料方面进行了尝试。     

聚四氢呋喃/聚苯乙烯交联嵌段及接枝共聚物的合成与阻尼性能

合成接枝共聚物和嵌段共聚物是研究阻尼材料的重要途径,这是由于可以在较广的范围内,调整共聚物的结构,使之具有良好的阻尼性能。这里我们选择了端羟基聚四氢呋喃与顺丁烯二酸酐反应,制成端乙烯基大分子单体及端乙烯基遥爪低聚物。然后与苯乙烯共聚,制成接枝共聚物和嵌段共聚物。从两者的比较中探讨各种因素对共聚物阻尼性能的影响规律。认为研究结果将有益于阻尼材料的分子设计,在反应体系及合成方法上,都比较简便,适于工业生产,便于推广应用。     

阻尼材料研究进展

对各种阻尼材料的研究进展进行了概述,内容涉及材料阻尼性能的评价方法,各种材料的阻尼机理及其影响因素,还简单介绍了先进的阻尼材料———智能阻尼材料及先进的阻尼技术———等离子真空沉积技术的研究概况。     

（甲基）丙烯酸酯及其共聚体系L′IPN的合成和性能研究Ⅱ．（甲基）丙烯酸酯及其共聚体系L′IPN的阻尼性能和力学性能

通过动态力学谱试验（ＤＭＳ）、应力－应变测量，研究了以丙烯腈、苯乙烯、醋酸乙烯酯等单体为共聚组分引入全（甲基）丙烯酸酯Ｌ′ＩＰＮ（胶乳型互穿聚合物网络）中对共混体系阻尼性能、力学性能的影响，发现通过无规共聚引进不同链结构能有效调节材料室温域的阻尼水平；初步探讨了ＩＰＮ（互穿聚合物网络）中某些组分侧链（基）结构对阻尼性能的影响规律及可能原因；本文所研究的ＩＰＮ体系在力学（物理）状态上处于皮革态，而交联密度、组分含量等对ＩＰＮ的力学性能具有较为复杂的影响。     

PMPS/PMAc相容性与同步互贯聚合物网络的阻尼性能研究

互贯聚合物网络是一种聚合物合金 ,其组分的热力学性质决定组分间的相容性和微相结构 ,从而影响材料的阻尼性能 .采用同步互贯聚合物网络 (SIN)技术制备了一种新型的聚苯基硅氧烷 (PMPS) 聚甲基丙烯酸酯 (PMAc)阻尼材料 ,用DMA和AFM等表征研究了其玻璃化温度转变行为与微观相态结构 .结果表明 ,由相容性好的组分制备的SIN材料阻尼值最高 ,tanδmax 可达 1 4,只有一个玻璃化温度转变峰 ,其微相结构为双相连续 ;组分介于相容与不相容之间时 ,所构成的SIN样品的tanδ≥ 0 3的温度区间最宽 ,可达 170℃ ,微相结构为单相连续 ;由相容性差的组分制得的SIN阻尼材料的内耗峰裂分为两个区间 .PMPS PMAcSIN材料的阻尼性能可以通过调节组分的相容性进行控制 .     

橡胶阻尼材料的研究进展

阻尼材料,特别是橡胶阻尼材料,作为一种减振降噪,改善人机工作环境和设计制造水平的特殊功能材料,在高铁快轨、航空航天、海军舰船、机械工程和国家安全等诸多领域都得到了广泛的应用。然而随着社会文明程度和设计制造水平的提高及高新技术的迅速发展,对橡胶阻尼材料的要求越来越高,使新型高性能橡胶阻尼材料成为竞相研发的材料之一。本文将从橡胶基体的选择、分子结构和微观结构的设计、特殊阻尼机制的构筑等方面介绍橡胶阻尼材料的最新研究进展。     

胶乳型互穿聚合物网络(LIPN)阻尼材料

详细讨论了LIPN体系的阻尼原理。高分子材料在发生玻璃化转变时,大分子链段在玻璃化转变温度Tg附近的运动可以把振动能转化为热能耗散掉,借此可以达到减振、降噪的目的。这也是LIPN作为阻尼材料的依据。阻尼笥能是分子运动的结果,LIPN组分间的相容性及相互作用是影响阻尼性能的重要因素;采用不同的合成方法,将形成不同的微观形态,也会导致材料阻尼性能的差异。因此本文又深入探讨了各种合成参数及合成条件对体系性能的影响,并且指出了合成过程中特别需要注意的几个问题。     

CIIR/PMAc IPNs阻尼性能

CIIR/PMAc IPNs阻尼性能;氯化丁基橡胶; 互贯聚合物网络; 聚(甲基)丙烯酸酯; 阻尼性能     

交联密度对聚硅氧烷/聚丙烯酸酯同步互穿聚合物网络阻尼材料性能的影响

阻尼性能;交联密度对聚硅氧烷/聚丙烯酸酯同步互穿聚合物网络阻尼材料性能的影响     

聚氯乙烯-丁腈羟共混物的阻尼性质

高分子阻尼材料的特点是玻璃化转变区宽,阻尼因子大。采用共混的方法制备阻尼材料,是改进高聚物阻尼性能的一个简单易行的方法。但是,目前所报道的共混工作多以高聚物与高聚物共混为主,对于低聚物与高聚物共混方面的研究,尚未见系统阐述。     

Poly(vinyl alcohol) obtained through polymerization of some vinyl esters

Bulk and/or solution polymerizations of a series of vinyl esters, e.g., vinyl acetate, vinyl propionate, vinyl butyrate, vinyl pivalate, and vinyl benzoate were conducted. Iodine-coloration, 1,2-glycol structure, molecular weight, and tacticity (triad and pentad) were measured for the resulting poly(vinyl alcohol)s (PVAs). The iodine-coloration abilities of PVAs, derived from poly(vinyl ester)s that were obtained through bulk polymerization at 60°C, depended on the starting monomer, increasing in the following order: vinyl benzoate < vinyl acetate < vinyl propionate < vinyl butyrate < vinyl pivalate. In solution polymerizations of vinyl propionate and vinyl butyrate, it was revealed that the tacticity of the derived PVAs apparently depended on the type and amount of polymerization solvent employed, as found previously in the case for vinyl acetate. The iodine-coloration of these PVA samples varied in the same order as their syndiotactic content, while no relationship was observed toward their 1,2-glycol content. The probabilities of the syndiotactic propagation at 60°C were estimated as 0.49 (benzoate), 0.54 (acetate), 0.55 (propionate), 0.56 (butyrate), and 0.60 (pivalate), respectively.     

Interaction of water in polymers: Poly(ethylene‐co‐vinyl acetate) and poly(vinyl acetate)

We studied the interaction of water in poly(ethylene‐co‐vinyl acetate) of various vinyl acetate compositions and poly(vinyl acetate), on the basis of the infrared spectrum of the water dissolved therein. The spectrum shows a very sharp and distinct band at about 3690 cm^?1 (named as A), and less‐sharp two bands around 3640 (B) and 3550 cm^?1 (C), the A band being outstanding especially at a low vinyl acetate composition. As the vinyl acetate composition increases, the A band decreases in intensity relative to the C band, whereas the B band increases contrarily. Analysis of the spectral change has elucidated that one‐bonded water (of which one OH is hydrogen‐bonded to the C?O of an ester group and the other OH is free) and two‐bonded water (each OH of which is hydrogen‐bonded to one C?O) coexist in the copolymer and that two‐bonded water increases in relative population with increasing vinyl acetate composition. Dissolved water is entirely two‐bonded in poly(vinyl acetate), in which C?O groups are densely distributed in the matrix. We proved that dissolved water in polymers is hydrogen‐bonded through one or two OH groups to the possessed functional groups but does not cluster. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 777–785, 2005     

Multiple Internal Reflectance and Chemical Determinations of Poly(vinyl Acetate) Binder on Non-Woven Polyester Battings

Abstract

A multiple internal reflectance method and a chemical method for the quantitative determination of poly(vinyl acetate) binder on non-woven polyester battings are described. The band assignments, poly (vinyl acetate) concentration, and standard battings preparation are discussed.     

Poly(vinyl chloride) Nanocomposites

Poly(vinyl chloride) is one of the major thermoplastics beside other commodities polymers like polyethylene and polystyrene. However, some of its main characteristics such as plasticity, thermal and photo stability are inferior to other commodity polymers. Adding nano scale inorganic fillers to poly(vinyl chloride) or other polymers in view to obtain polymer nanocomposites with superior properties has drawn the attention of many researchers in the last decades. Poly(vinyl chloride) nanocomposites are obtained mainly by in situ polymerization, solution based or mixing techniques. The resulting products show improvement of most important properties of poly(vinyl chloride) such as thermal, mechanical, rheological, flammability, antibacterial, etc. This paper presents preparation ways of poly(vinyl chloride) nanocomposites using different nano fillers and the improved properties compared with those of virgin poly(vinyl chloride).     

Long branching in poly(vinyl acetate) and poly(vinyl alcohol). II. Polymerization of vinyl acetate in the presence of crosslinked poly(vinyl alcohol)

It is a common view that poly(vinyl acetate) has many branches at the acetyl side group, but that the corresponding poly(vinyl alcohol) has little branching. In order to study the branching in poly(vinyl acetate) and poly(vinyl alcohol) which is formed by chain transfer to polymer, the polymerization of ¹⁴C-labeled vinyl acetate in the presence of crosslinked poly(vinyl acetate), which was able to be decrosslinked to give soluble polymers, was investigated at 60°C and 0°C. This system made it possible to separate as well as to distinguish the graft polymer from the newly polymerized homopolymer. Furthermore, the degree of grafting onto the acetoxymethyl group and onto the main chain were estimated. It became clear that, in the polymerization of vinyl acetate, chain transfer to the polymer main chain takes place about 2.4 times as frequently at 60°C as that to the acetoxy group and about 4.8 times as frequently at 0°C.     

聚甲基丙烯酸甲酯与聚醋酸乙烯酯共混的红外光谱研究

用红外光谱(FTIR)研究了聚甲基丙烯酸甲酯(PMMA)与聚醋酸乙烯酯(PVAc)共混体系相容性,在160℃以上共混体系发生相分离;分相体系与非分相体系的FTIR谱明显不同;共混体系的FTIR谱不能从两统组分红外光谱简单加和得到;结果表明大分子构象发生了变化,PMMA/PVAc体系相容可能是大分子构象熵变所致。     

Synthesis and Characterization of Poly(N-isopropylacrylamide) and Poly(vinyl acetate) Diblock Copolymers via MADIX Process

The synthesis of diblock copolymers of poly(N-isopropylacrylamide) (PNIPAM) and poly(vinyl acetate) (PVAc) was performed by macromolecular design via interchange of xanthates (MADIX) process. Following the preparation of methyl (isopropoxycarbonothioyl) sulfanyl acetate (MIPCTSA) as chain transfer agent, it was reacted with vinyl acetate to obtain PVAc macro-chain transfer agent. Then, block copolymerization was completed by successive addition of N-isopropylacrylamide (NIPAM). ¹H NMR spectroscopy confirmed the presence of both blocks in the copolymer structure, with the expected composition based on the feed ratio. Size Exclusion Chromatography (SEC) was used to investigate the relative values of molecular characteristics. Only 20% of PVAc was converted to block copolymer. The resultant block copolymer structures were further examined in terms of their morphologies as well as critical micelle concentration (CMC) by using ESEM and Fluorescence Excitation Spectroscopic techniques, respectively. Morphological characterization confirmed amphiphilic block copolymer formation with the existence of mainly ca. 100 nm well distributed micelles. The thermo responsive amphiphilic behavior of the block copolymer solutions were followed by Dynamic Light Scattering (DLS) technique.     

Poly(vinyl alcohol) star polymers prepared via MADIX/RAFT polymerisation

Poly(vinyl acetate) stars were prepared using MADIX/RAFT polymerisation mediated by xanthates. The polymerisation shows living characteristics with molecular weight increasing with conversion. The subsequent hydrolysis of these three and four arm stars led to the formation of poly(vinyl alcohol) stars.     

Synthesis and Characterization of a Hydrophilic/Hydrophobic IPN Composed of Poly（vinyl alcohol） and Polystyrene

A hydrophilic/hydrophobic interpenetrating polymer network （IPN） of poly （vinyl alcohol） / polystyrene was prepared by conversion of the IPN of poly （vinyl acetate）/polystyrene. The hydrophilic/hydrophobic IPN was characterized by FT-IR and DSC, and the swelling ratios of the IPN in different solvents were measured.     

Compatibility of binary systems of poly(methyl methacrylate), poly(vinyl chloride) and poly(vinyl acetate)

The influence of the thermal treatment on the stability in time of the dispersion degree of films containing binary polymer mixtures, poly(vinyl chloride)/poly(methyl methacrylate), poly(vinyl chloride)/poly(vinyl acetate) and poly(vinyl acetate)/poly(methyl methacrylate), was studied by thermogravimetry and optical microscopy with phase contrast. The dispersion degree depends particularly on the composition of the polymer mixture and can be improved by thermal treatment at temperatures above the glass temperatures of both homopolymers. It seems that this thermal treatment yields exclusively metastable structures with a general tendency to phase separation in a short time after thermal treatment, the heterogeneity mixtures (as film) being more pronounced.