聚氯乙烯/α-甲基苯乙烯-丙烯腈共混体系的相容性和性能研究

选用腈基含量为30%的α-甲基苯乙烯-丙烯腈(α-MSAN)作为聚氯乙烯(PVC)的耐热改性剂,通过熔融共混制备了PVC/α-MSAN共混材料.通过SEM、DSC、DMA及透光率测试等手段系统研究了α-MSAN的含量对PVC/α-MSAN共混体系相容性的影响,发现在高达60%(wt)的α-MSAN的含量范围内它们具有良好的相容性,并从分子结构上解释了其相容性良好的原因;随α-MSAN含量增加,共混体系的维卡软化温度(VST)和拉伸强度上升,冲击强度下降;α-MSAN的引入会导致共混体系及PVC静态热稳定时间下降,共混体系的颜色加深.同时分析了α-MSAN对共混体系耐热性能、热稳定性能和力学性能产生影响的机理.     

含氯聚合物和乙烯-醋酸乙烯酯共聚物共混体系的红外光谱研究

关于氯化聚乙烯(CPE)或聚氯乙烯(PVC)与乙烯—醋酸乙烯酯共聚物(EVA)共混体系相容性的研究,已有不少报道,其中Coleman等人运用FTIR方法研究了含VA45％的EVA与CPE、PVC的共混体系,测定了该体系的低临界共溶温度(LCST)。一般认为,如果VA含量更低,由于EVA本身的结晶,共混体系将变得难以     

反相气相色谱法研究聚合物共混物的相溶性

 用反相气相色谱法测定了聚氯乙烯(PVC)／ 乙烯-醋酸乙烯共聚物(EVA)共混体系中分子间表观热力学相互作用参数χ′23,并以χ′23 为判定依据,研究了共混物的相溶性。 初步探讨了共混物的组成、聚合物分子 链结 构、温度与χ′23的关系以及探针分子性质 对χ′23参数的影响。结果表明：χ[ HT6〗′23值能够准确有效地判定PVC与EVA共混物的 相溶性,醋酸乙烯质量分数低的EVA与PVC的共混物是热力学不相溶的;而醋酸乙烯质量 分数中等的EVA与PVC的共混物则具有部分相溶性。结果与其它方法得到的结论是一致的 。     

PVC/EVA-g-VC共混物的形态与加工条件和性能的关系

PVC/EVA(-14)及 PVC/EVA(-14)-g-VC的等速升温Brabender塑化曲线上有两个扭矩峰,分别标志着EVA和PVC的塑化,对应着共混形态经历的三个变化:(1)EVA塑化——PVC粉粒破碎;(2)EVA呈连续相——PVC集结粒子解体;(3)EVA呈分散相——PVC初级粒子熔化。聚合投料比(VC/EVA)越小,EVA-g-VC的塑化温度和熔体粘性越高,两个扭矩峰靠得越近。实验结果表明,EVA-g-VC与EVA相比,不仅与PVC有更好的相容性,而且有较好的均匀可混性。冲击强度的测定结果表明:EVA连续网——PVC初级粒子结构具有较高的冲击强度。VC/EVA较小时所得EVA-g-VC改性的PVC可在较宽的加工温度范围保持EVA连续网结构和较高的冲击强度。     

PBT/POE-g-MAH/PP共混体系的相态结构与性能

采用马来酸酐接枝乙烯-辛烯共聚物弹性体(POE-g-MAH)与聚丙烯(PP)在双螺杆挤出机上进行熔融共混,制备了3种新型增韧改性剂.研究了增韧改性剂的种类及其用量对共混物的力学性能、相形态结构、熔融与结晶行为的影响.力学性能测试表明,POE-g-MAH与适量PP并用具有显著的协同增韧作用,当POE-g-MAH与PP的配比为70/30时,所得增韧改性剂(POEg2)具有最佳的增韧效果.当POEg2含量达到15%时,共混物的缺口冲击强度(Is)从纯PBT的7.5 kJ/m2提高到51.2 kJ/m2,与15%的纯POE-g-MAH弹性体增韧PBT具有相近的缺口冲击强度值.同时,共混物的拉伸强度(σb)损失最小.采用AFM和SEM观察发现,新型增韧改性剂作为分散相具有软壳-硬核结构.DSC测试表明,随增韧改性剂中PP含量增加到一定值时,壳-核结构中软壳层出现不完整现象,导致界面作用力减小,共混物的Is和σb都出现明显下降.     

聚氯乙烯和EVA树脂共混体系相容性的研究

用扭摆分析研究了EVA树脂和PVC共混体系中,VA含量和共混物组成对其相容性的影响.共混的两组分的分子间相互作用对其相容性有关键的影响.用FTIR测定羰基伸缩振动谱带的位移,可表征EVA-PVC分子链间的相互作用.     

丙烯酸丁酯/4-乙烯基吡啶共聚物与聚氯乙烯共混相容性的研究

合成了系列丙烯酸丁酯/4-乙烯基吡啶共聚物[P(BAVP)].以四氢呋喃为溶剂,用溶剂浇铸法制备了一系列P(BAVP)与聚氯乙烯(PVC)的共混物.动态力学性能测试表明:共混物中吡啶环含量高于1%(摩尔百分含量)的共混物呈均相,即共聚物与PVC相容.P(BAVP)/PVC共混物的T_g随PVC含量和乙烯基吡啶链段含量增加而提高.由红外光谱分析推论出:P(BAVP)分子间的作用力比PBA分子间作用力弱,从而使P(BAVP)与PVC的相容性提高.     

PVC/MBS共混物的紫外光交联及光氧化反应

PVC及其共混物应用广泛,MBS作为PVC制品的透明抗冲改性剂,在提高PVC抗冲性能的同时,必然影响PVC在紫外光照下发生的光化学反应过程,我们用紫外可见光研究了MBS对PVC紫外光解脱HCl动力学,发现MBS对PVC光解脱HCl有抑制作用,本文利用FTIR光谱研究PVC／MBS共混体系中,MBS对PVC光氧化、光交联及光降解过程的影响。     

EVA-g-VC的结构和动态粘弹性

本文研究了聚乙烯-醋酸乙烯酯(EVA,VAc:14％)与氯乙烯(VC)接枝共聚物(EVA-g-VC)的相结构和分子结构。接枝物EVA-g-VC由游离EVA、均聚PVC和EVA-VC接枝高分子三者组成,EVA呈连续相,PVC呈分散微粒。EVA-g-VC中EVA的含量越高,PVC粒子体积越小。实验结果表明,接枝物中“凝胶”的EVA玻璃化温度,随投料比(VC/EVA)的减小而升高;另外随VC/EVA减小,凝胶中PVC的含量和PVC的分子量也减小。这些结果说明,VC/EVA较小时得到的接枝物中,EVA上VC接枝点的数目较多,而PVC接枝链的长度较短。EVA-VC是不相容两相——EVA和PVC的“粘着剂”,其作用表现在:VC/EVA越小,接枝物中EVA和PVC的玻璃化温度越靠近。     

无水AlCl_3催化PVC/PS反应性增容的研究

以无水AlCl3为催化剂,通过聚氯乙烯(PVC)与聚苯乙烯(PS)之间Friedel-Crafts反应,实现了PVC/PS共混体系的反应性增容,使PVC与PS熔融共混温度由160℃降为140℃;通过预碾磨和加入苯乙烯(St)的方法,提高材料韧性,制备了综合力学性能良好的PVC/PS合金材料.应用FTIR、DSC、SEM和力学性能测试等手段表征了合金材料的结构与性能.结果表明,FTIR出现了1943和838 cm-12个苯环对位被取代的特征吸收峰;DSC在89℃出现了玻璃化转变;SEM证明PVC/PS两相界面粘接性随AlCl3、St的加入越来越好.在PS、AlCl3和St的质量分数分别为6%,0.6%和9%时,实现了对PVC的增强增韧.合金拉伸强度达到60.54MPa,比PVC的49.35 MPa提高了22.7%;缺口冲击强度达到5.3 kJ/m2,比PVC的3.9 kJ/m2提高了35.9%.     

Broad line NMR investigation of compatibility using powdered and milled samples of PVC and EVA, and the effects of heat-treatment

The limited miscibility of poly(vinyl chloride) (PVC) and ethylene-vinyl acetate copolymer (EVA) observed for milled samples has now been demonstrated for samples in powdered form by means of broad line NMR. The changes in the phase relations are mainly dependent on two processes, viz. the phase separation and the development of the interactions between PVC and EVA chains. The stable level of the phase relations is dependent upon the thermal history. We assume this to be an effect of the varying degrees of entanglement between PVC and EVA chains. It has also been demonstrated that the fraction of EVA staying in the free phase increases both for the milled and powdered samples when the degree of grafting between PVC and EVA decreases. A method for the quantitative investigation of the solubility conditions of polymer two-phase systems in bulk is also presented.     

A dielectric study of poly(ethylene-co-vinylacetate)–poly(vinyl chloride) blends. I. Miscibility and phase behavior

Measurements of the complex permittivity were used to study miscibility and phase behavior in blends of poly(vinyl chloride) (PVC) with two random ethylene—vinyl acetate (EVA) copolymers containing 45 and 70 wt % of vinyl acetate. The dielectric β relaxation of the pure polymers and blends was followed as a function of temperature and frequency for different blend compositions and thermal treatments. Blends of EVA 70/PVC were found to be miscible for compositions of about 25% EVA 70 and higher. Blends of lower EVA 70 content showed evidence of two-phase behavior. EVA 45/PVC blends were found to be miscible only at the composition extremes; at intermediate compositions these blends were two-phase, partially miscible. Both blend systems showed lower critical solution temperature behavior. Phase separation studies revealed that in the EVA 45/PVC blends, PVC was capable of diffusing into the higher T_g phase at temperatures below the T_g of the upper phase. In the blends, ion transport losses were significant above the loss peak temperatures, and in the two-phase systems, often obscured the upper temperature loss process. It was shown possible, however, to correct the loss curves for this transport contribution.     

Effect of Different Organic Modifiers on the Tensile Properties of PVC／EVA／Montmorillonite Composites

Poly (vinyl chloride)/ethylene-vinyl acetate/montmorillonite (PVC/EVA/OMMT) composites were prepared by melt blending method. Two kinds of montmorillonites were organically modified by trimethyloctadecyl ammonium and dimethyl bis (hydrogenated tallow) ammonium, respectively. The morphology and tensile properties of the resultant composites were discussed in terms of the modifier type and OMMT content. The PVC/EVA/OMMT composites have intercalated structure, which is independent of the polarity of the modifiers, while the tensile properties show strong dependence on the modifier type. The OMMT modified by polar modifier gives higher tensile ductile and strength of PVC/EVA/OMMT composites.     

A dielectric study of poly(ethylene-co-vinyl acetate)–poly(vinyl chloride) blends. II. Loss curve broadening and correlation parameters

Normalized dielectric loss curves for blends of PVC with an EVA copolymer containing 70% vinyl acetate showed significant broadening with increasing PVC content. In conjunction with phase separation studies it was concluded that increasing loss curve broadness correlated with increasing tendency toward phase separation. Calculation of correlation parameters for the blends revealed differences in intermolecular correlations with blend composition.     

PVC/EVA/SBS共混体系研究

利用溶液成膜法制备了PVC/SBS薄膜 ,对其表观形态、力学性能进行了研究 ,并讨论了EVA对体系的增容作用。发现EVA在一定浓度范围内能增加PVC与SBS的相容性 ,提高断裂伸长率 .测量了溶液的相对粘度 ,得出了相反转浓度点。     

Comparative study of pyrolytic decomposition of polymers alone or in EVA/PS,EVA/PVC and EVA/cellulose mixtures

The behavior of mixtures of EVA–PS, EVA–PVC and EVA–cellulose in various proportions were investigated under pyrolysis. A kinetic model with an independent pathway is proposed for the weight loss and compared with the experimental and theoretical results obtained in a previous study with individual polymers. The kinetic parameters were determined and online IR spectrometric analysis used to follow the evolution of the gaseous pyrolysis products versus the temperature. The result shows good agreement for the EVA–PS mixture and confirms the hypothesis of an independent pathway. However, in the case of EVA–PVC and EVA–cellulose mixtures, the polymers affect one other in the pyrolysis reaction.     

Morphological,rheological, crystalline and mechanical properties of ethylene-vinyl acetate copolymer/linear low-density polyethylene/amphiphilic graphene oxide nanocomposites

Chemical modification of graphene oxide has become a popular method for imparting unique properties to extend its application. Here, we show a simple way to synthesize amphiphilic graphene oxide (AGO) by grafting quaternary ammonium salt onto GO sheets. The AGO sheets not only showed high thermal stability and good dispersion in many polar and non-polar solvents in comparison to GO sheets but also the chemical modification maintained the two-dimensional structure. As a result, the AGO sheets improve the interfacial interaction between ethylene-vinyl acetate copolymer (EVA) and linear low-density polyethylene (LLDPE). Because of the large size of AGO, the location of AGO is very dependent on the mixing strategy. The AGO was dispersed in the EVA phase when AGO was mixed first with EVA and then with LLDPE, whereas it was confined in the LLDPE phase when AGO was mixed first with LLDPE and then with EVA. AGO sheets were found at the interface of LLDPE and EVA when AGO, EVA, and LLDPE were mixed together, suggesting that AGO has a high interfacial interaction with both LLDPE and EVA. These high interfacial interactions lead to high tensile strength, Young's modulus, complex viscosity and crystallization temperature in comparison to the EVA/LLDPE blends without AGO sheets.