聚乳酸/聚氨酯共混体系相容性研究

采用热塑性聚氨酯弹性体(TPU)作为改性剂来增韧聚乳酸(PLA),通过溶度参数法、聚合物混合焓变法预测了TPU和PLA的相容性,并且通过稀溶液粘度法、动态热机械分析(DMA)及扫描电镜(SEM)对两者相容性进行表征,结果显示PLA和TPU为部分相容体系.共混溶液的粘度与组成含量的变化呈非线性关系;PLA/TPU共混膜的...     

改性酚氧树脂/聚(甲基丙烯酸丁酯-co-4-乙烯基吡啶)共混物的相容-络合行为和表面表征

合成了一系列不同4-乙烯基吡啶含量的聚(甲基丙烯酸丁酯-co-4-乙烯基吡啶)(BVPy)共聚物,并对酚氧树脂(Phenoxy)的仲羟基进行了不同乙酰化程度的改性.用粘度法和激光光散射(LLS)研究了BVPy/改性Phenoxy共混物在溶液中的络合行为对氢键相互作用基团密度的依赖性,并用DSC研究了共混体系在本体中的相容性.将粘度法及LLS的结果结合起来,得到了改性Phenoxy/BVPy共混体系的不相容-相容-络合转变相图.在此基础上,用XPS初步考察了共混物的相容性对其表面组成的影响.结果表明,大分子间的络合相互作用可抑制共混物的表面富集.     

聚偏氟乙烯-磺化聚醚砜相容性及其成膜性能

研究了聚偏氟乙烯(PVDF)-磺化聚醚砜(SPES)的相容性及其成膜性能.首先通过溶解度参数、粘度法和目测法研究共混溶液的相容性,接着采用浊度法测定了共混溶液的热力学性质,最后采用浸没沉淀法制备了共混膜并探讨了成膜性能.结果显示,PVDF和SPES为部分相容体系,随着SPES含量的增加,共混溶液相容性逐渐减小,当SPES含量增加到50wt%时,体系发生分相.共混溶液的成膜性能良好,SPES含量增加有利于体系发生液液分相,生成高孔隙率膜,并且极大的提高了PVDF膜的亲水性和水通量.     

聚醚砜/酚酞基聚醚砜共混相容性及凝胶特性研究

采用混合热焓法和稀溶液粘度法预测了聚醚砜/酚酞基聚醚砜体系相容性,并观察了聚醚砜/酚酞基聚醚砜共混制膜液的凝胶值与共混比的关系.聚醚砜/酚酞基聚醚砜为部分相容体系,其相容性与组成有关.共混制膜液的凝胶值受共混组成的影响,并非纯组分制膜液凝胶值的线性加和.     

一种加成固化型热固性树脂PN-PAA固化过程和热稳定性研究

研究了炔丙基醚化酚醛树脂(PN)与聚芳基乙炔树脂(PAA)的反应性共混物(以下简称PN-PAA共混树脂)的相容性,并对共混树脂的固化过程和固化物的耐热性进行了表征.相态、DSC、SEM、TEM等测试结果均表明共混树脂及其固化物是完全相容的均相体系.凝胶时间、粘度、DSC等结果表明共混树脂固化工艺性优良,适合多种成型工艺(如RTM),显著改善了PAA树脂的固化工艺缺陷.DMA、TGA等分析表明共混树脂固化物具有很高的耐热性,可作为新型的防热复合材料和高温结构材料的基体.     

聚乳酸/聚己内酯/聚(ε-己内酯-L-丙交酯)共聚物三元共混体系的结构与性能

通过开环共聚合,合成了3种不同单元比例的ε-己内酯(ε-CL)与L-丙交酯(L-LA)的共聚物P(CLco-LA)。通过熔融共混制备了聚乳酸(PLA)/聚己内酯(PCL)/P(CL-co-LA)三元共混材料,研究了P(CL-coLA)对共混材料微观形貌、热性能以及力学性能的影响。结果表明,共聚物P(CL-co-LA)作为PLA/PCL不相容体系的界面增容剂,减小了PCL分散相的尺寸,改善了PLA/PCL共混体系的相容性,提高了共混材料的韧性。固定m(PLA)∶m(PCL)∶m(P(CL-co-LA))=80∶20∶10时,以P(CL49/LA51)(其中数字代表摩尔分数(%))作为界面增容剂效果最佳,共混材料的断裂伸长率可达到(210±30)%。     

固相法氯化聚乙烯增韧聚氯乙烯的研究

研究了聚氯乙烯与固相法氯化聚乙烯的相容性与氯含量、共混方式以及ＣＰＥ链结构的关系，动态力学性能表明ＰＶＣ／ＣＰＥ为部分相容体系，ＣＰＥ中类似ＰＶＣ的链段与ＰＶＣ形成相间过渡层，共混方式影响共混体系的相容程度，透射电镜结构表明ＣＰＥ呈连续网络结构分布于ＰＶＣ粒子表面，共混条件一定时，共混物的抗张强度随相容性的改改善而增加。     

聚[(双-甘氨酸乙酯)膦腈]/聚酯共混相容性研究

采用溶液混合法制备了聚[(双－甘氨酸乙酯）膦腈]（PGP）与丙交酯均聚物（PLA）或丙交酯／乙交酯共聚物（PLGA）的共混体系，利用示差扫描量热仪、傅里叶红外光谱仪和相差显微镜研究了两体系的共混相容性。实验结果表明，PGP与PLA不相容，但通过氢键相互作用可与PLGA达到部分相容，且PGP／PLGA的共混相容性随着PLGA含量的增加而有所改善。     

固相法氯化聚乙烯增韧聚氯乙烯的研究Ⅱ．CPE的氯含量及共混方式与PVC／CPE相容性的关系

研究了聚氯乙烯（ＰＶＣ）与固相法氯化聚乙烯（ＣＰＥ）的相容性与氯含量、共混方式以及ＣＰＥ链结构的关系。动态力学性能表明ＰＶＣ／ＣＰＥ为部分相容体系，ＣＰＥ中类似ＰＶＣ的链段与ＰＶＣ形成相间过渡层，共混方式影响共混体系的相容程度。透射电镜结果表明ＣＰＥ呈连续网络结构分布于ＰＶＣ粒子表面。共混条件一定时，共混物的抗张强度随相容性的改善而增加。     

SSBR/TPI共混体系中TPI的结晶、成核及动力学研究

研究了不相容共混体系溶聚丁苯橡胶(SSBR)/反式-1,4-聚异戊二烯(TPI)共混体系的结晶行为.当SSBR含量较低时,SSBR/TPI共混物的成核密度降低,晶体生长速率降低,等温结晶速率降低,非等温结晶峰移向低温,SSBR抑制了α-TPI的生成,SSBR/TPI共混体系总结晶度降低,但TPI的相对结晶度升高,结晶行为与热力学相容的结晶/非晶共混体系一致;当SSBR含量较高时,随着SSBR含量增加,体系的成核密度增加,球晶的生长速率显著降低,SSBR显著抑制了α-TPI的生成,共混体系以β晶为主.     

The miscibility of poly(vinyl alcohol)/poly(N-vinylpyrrolidone) blends investigated in dilute solutions and solids

Poly(vinyl alcohol) (PVA) (polymer A) and poly(N-vinylpyrrolidone) (PVP) (polymer B) are known to form a thermodynamically miscible pair. In the present study the conclusion on miscibility of PVA/PVP solid blends, confirmed qualitatively (DMTA, FTIR) and quantitatively (DSC, χ_AB = − 0.69 at 503 K) is compared with the miscibility investigations of PVA/PVP solution blends by the technique of dilute solution viscometry. The miscibility of the ternary (polymer A/ polymer B/ solvent) system is estimated on the basis of experimental and ideal values of the viscosity parameters k, b and [η]. It is found that the conclusions on miscibility or nonmiscibility drawn from viscosity measurements in dilute solution blends depend: (i) on the applied extrapolation method used for the determination of the viscosity interaction parameters, (ii) on the assumed definition of the ideal values and (iii) on the thermodynamic quality of the solvent, which in the case of PVA depends on its degree of hydrolysis. Hence, viscometric investigations of dilute PVA/PVP solution blends have revealed that viscometry, widely used in the literature for estimation of polymer-polymer miscibility can not be recommended as a sole method to presume the miscibility of a polymer pair.     

Miscibility studies on the blends of collagen/chitosan by dilute solution viscometry

The viscosity behavior of collagen, chitosan and their blends at several compositions (2/8, 4/6, 5/5, 6/4, 8/2) has been studied. The miscibility of this polymer system was investigated on the basis of the sign of the criteria ΔB, Δb, Δ[η], α and β determined by dilute solution viscosity. These investigations indicate that collagen/chitosan is miscible at any composition in HAc at 25 °C. According to the “memory effect”, we can conclude that collagen/chitosan is also miscible in the solid state.     

The evaluation of miscibility of blends of poly(ether imide) (Ultem1000) and a copolyester of bisphenol-A with terephthalic and isophthalic acid (ArdelD-100) by viscosimetry

The intermolecular interactions and miscibility behavior between poly(ether imide) (Ultem^®1000) and a copolyester of bisphenol-A with a mixture of terephthalic and isophthalic acid (Ardel^®D-100) in compositions of 100/0, 80/20, 60/40, 40/60, 20/80 and 0/100 have been investigated in dilute solutions in chloroform. An Ubbelohde-type home-made viscometer was used to determine the specific viscosities of the blends in a constant temperature bath. Several viscosity interaction parameters used as the criteria of miscibility were determined from viscosity measurements. The parameters suggested that Ultem^®1000 and Ardel^®D-100 were miscible. The miscibility of the polymers was confirmed by the results of differential scanning calorimetry measurements.     

Miscibility Studies of Dextran/Poly(vinyl pyrrolidone) Blend in Solution

The miscibility of dextran (Dex)/poly(vinyl pyrrolidone) (PVP) in solution has been investigated in different percentages of the blend components by employing viscosity, density, refractive index and ultrasonic velocity methods at 30 and 50°C, respectively. Ultrasonic velocity and adiabatic compressibility against blend compositions were plotted and found to be linear. The interaction parameters μ and α have been obtained by using the viscosity data. The results indicated that the Dex/PVP blends are miscible in the entire composition range and it was further confirmed by ultrasonic velocity, density, refractive index studies. In addition, the results revealed that the change in temperature has no significant effect on the miscibility of Dex/PVP polymer blend.     

Phase behavior of poly(ethylene oxide) and sulfonated polystyrene blends with and without solvent

The phase behavior of poly (ethylene oxide) (PEO) and poly(styrene-co-sodium sulfonated styrene) (SPS) blends has been examined as a function of copolymer composition. The mixtures show complex coacervation in dilute benzene/methanol (9/1, v/v) solution. The presence of intermolecular interactions between PEO and SPS in solution is verified by viscometry. Interaction between PEO and SPS in the solid state was supported by small-angle x-ray scattering; however, binary blends containing low PEO content show high miscibility, whereas the blends with high PEO content show phase separation.     

Characterization and Miscibility Dynamics of Dextran-Poly(vinylpyrrolidone)-Water System

Summary: The miscibility behavior and intermolecular interactions among Dextran (Dx) with different molecular weight and Polyvinylpyrrolidone (PVP) blends were studied as dilute aqueous solutions at 25 °C by viscosity method. The intrinsic viscosity and the interaction coefficient were experimentally measured for each polymer-water as well as for Dx-PVP-water systems. These results served for the prediction of miscibility of the Dx/PVP blends with various blend compositions by using , , , , and parameters. Except Dx4/PVP with its all compositions (Dx4 with nominal molecular weight of 110 000), other blend systems are found to be almost miscible. The density measurements of these polymer solutions and their blends were conducted in order to compare with the viscosity findings. Lastly, all Dx with different molecular weight, PVP and their blends were characterized by infrared spectroscopy (FT-IR), and differential scanning calorimetry (DSC).     

Prediction of miscibility regions in ternary blends of poly(styrene-stat-acrylonitrile), poly(acrylonitrile-stat-methyl methacrylate), and poly(styrene-stat-methyl methacrylate)

The miscibilities of ternary copolymer blends prepared from poly(styrene-stat-acrylonitrile), poly(styrene-stat-methyl methacrylate), and poly(methyl methacrylate-stat-acrylonitrile) were predicted by calculating the interaction parameter, χ_blend, for various blend combinations, from the corresponding binary segmental interaction parameters estimated from previous work. Binodal and spinodal curves were calculated using the Flory-Huggins theory and it was observed that the most accurate estimate of the boundary between miscible and immiscible blends was given by the spinodal. It has also been demonstrated that in some of the ternary blends with fixed copolymer compositions the miscibility of the blend can be altered by changing the ratio of the three components in the mixture. Conditions for miscibility in this ternary system, and possibly a general feature of all such systems, are (a) that at least two of the binary interaction parameters χ_ij are less than the critical value χ_crit, while the third should not be too much larger, that is, one of the copolymers may act as a compatibilizer for the other two copolymers, (b) that the difference Δχ = /χ₁₂ ? χ₁₃/ is small. © 1992 John Wiley & Sons, Inc.     

Interactions in SMA-SAN blends

Styrene/maleic anhydride (SMA) and styrene/acrylonitrile (SAN) copolymers have previously been shown to form miscible blends when the MA and AN contents do not differ too greatly. It is shown here that this is the result of a weak exothermic interaction between the MA and AN units by measuring the heats of mixing for appropriate liquid analogs of the various monomer units. The region of copolymer compositions for miscibility of SMA-SAN blends is predicted from the Sanchez-Lacombe mixture theory using net interaction parameters calculated from the analog calorimetry results via a simple binary interaction model for copolymers. Lower critical solution temperature behavior was observed for blends of copolymers having compositions near the edge of the miscibility region. Various glass transition, volumetric, and FTIR results are discussed in terms of the interactions observed.     

PPEKK/PEI共混物的相容性及拉伸性能

作为相容体系 ,聚芳醚酮与聚醚酰亚胺 (ＰＥＩ)共混物体系的研究受到了研究者的重视[1～ 4] .由于现在已商品化的聚芳醚酮基本上都是半结晶型聚合物 ,所以有有关无定型聚芳醚酮与聚醚酰亚胺共混物的研究鲜见报道 .含二氮杂萘酮结构聚芳醚酮酮 (ＰＰＥＫＫ)是一种新型耐高温聚合物 ,相比于已经商品化的各种聚芳醚酮 ,ＰＰＥＫＫ除具有优异的综合性能外 ,它最大的特点表现在以下两方面 ,ＰＰＥＫＫ耐热性突出 ,玻璃化转变温度 (Ｔｇ)为 2 4 5℃左右 ,远高于各种商品化的聚芳醚酮 ;ＰＰＥＫＫ为无定型聚合物 ,易溶于多种有机极性溶剂 ,大大的扩…     

聚联苯酰亚胺/聚硫醚酰亚胺共混体系的相容性

<正> 聚酰亚胺是一种性能极其优异的高性能树脂,它在许多高技术领域有着极其重要的应用价值。在80年代以前,人们工作的重点是合成出一系列分子结构不同的聚酰亚胺,研究分子结构与性能间的关系,开发聚酰亚胺新品种。自80年代后期,有关高性能树脂聚酰亚胺共混物的研究日益引起人们的关注,其中有关不同分子结构的聚酰亚胺/聚酰亚胺共