茂金属 乙烯的流变性与加工性

研究了丁烯－１共聚的茂金属聚乙烯（mＰＥ）的流变性,发现茂金属聚乙烯的窄分子量分 布导致它在挤出加工剪切范围里熔体粘度高、对剪切敏感性差以及熔体从牛顿型转为非牛顿型所需的剪切速率、转变应力高,在挤出加工条件下流动性差,加工困难。对茂金属聚乙烯（mＰＥ）进行改性制得ＭmＰＥ,ＭmＰＥ熔体对温度、剪切速率的敏感性提高,在加工温 度、加工剪切范围里的天观粘度降低,加工流动性得到了显著的改进,可在普通聚乙烯加工     

茂金属聚乙烯的流变性与加工性

研究了丁烯 １ 共聚的茂金属聚乙烯（ｍＰＥ） 的流变性,发现茂金属聚乙烯的窄分子量分布导致它在挤出加工剪切速率范围里熔体粘度高、对剪切敏感性差以及熔体从牛顿型转为非牛顿型所需的剪切速率、转变应力高,在挤出加工条件下流动性差,加工困难．对茂金属聚乙烯（ｍＰＥ） 进行改性制得ＭｍＰＥ,ＭｍＰＥ 熔体对温度、剪切速率的敏感性提高,在加工温度、加工剪切速率范围里的表观粘度降低,加工流动性得到了显著的改进,可在普通聚乙烯加工设备上,制备性能优良的茂金属聚乙烯薄膜制品．     

超高分子量聚苯乙烯的流变性能

以毛细管流变仪和Hakke转矩流变仪对稀土催化合成的超高分子量聚苯乙烯 (UHMWPS)的流变与加工性能进行了研究 .结果表明 ,UHMWPS最显著的流变特征为超高的熔体粘度和低剪切速率下出现不稳定流动 .不稳定流动与超高分子量聚合物长的松弛时间有关 ,并提出了临界剪切速率与分子量和温度的定量关系式 .较低的分子量和较高的温度有利于提高临界剪切速率 ,改善挤出物外观质量和降低熔体粘度 .分子链极度缠结不仅导致超高的熔体粘度 ,也使UHMWPS链解缠加快 ,导致更高的剪切速率敏感性 .UHMWPS塑化时熔体粘度高 ,转矩大 ,加工性能劣于通用聚苯乙烯 (GPPS)     

紫外光辐照高温熔融态聚乙烯的结构与性能

采用螺杆均化段料筒可装设透明石英玻璃的双螺杆挤出机作为反应挤出装置,通过改变喂料量、二苯甲酮(BP)含量和三羟甲基丙烷三丙烯酸酯(TMPTA)含量三个参数,得到不同交联程度的新型聚乙烯材料。紫外光辐照聚乙烯反应挤出后,产物发生了交联,交联产物为假塑性流体,随着剪切速率的增加,表观黏度减小。交联结构的存在使产物的熔体强度有了很大的提升,达7.76 cN,极大的改善了LDPE在高温下的加工性能。     

线型聚乙烯及其共聚物的挤出畸变与熔体粘弹性的关系

采用恒速型双筒毛细管流变仪研究了一类线型聚乙烯熔体的挤出畸变与熔体非线性粘弹性的关系。实验研究了发生畸变时挤出压力的振荡规律,发现线型大分子或带小侧基的大分子熔体,容易发生壁滑和挤出压力振荡;而有较大侧基、或分子量分布宽、或带大量短支链的熔体,挤出畸变现象较轻。挤出畸变与熔体的弹性及熔体．壁面吸附状态紧密相关。容易发生壁滑和挤出压力振荡的熔体,弹性较大(入口压力降大);在壁面的吸附作用强(壁面临界剪切应力大)。稳态剪切粘度大小与挤出畸变和压力振荡的关系不大;而拉伸应力和拉伸粘度大的熔体较易发生壁滑和挤出压力振荡。     

成型方式对不同木塑复合体系的性能影响研究

以木粉为填充材料,以PE(聚乙烯)、PP(聚丙烯)为塑料基体,分别采用混炼-模压工艺和挤出-注塑工艺制备木塑复合材料,对比研究不同复合材料的力学性能、热性能以及流变性。结果表明,混炼-模压工艺制备的PE基复合材料综合性能较优,而挤出-注塑工艺制备的PP基复合材料综合性能较优,且在PE塑料系列中,HDPE(高密度聚乙烯)基复合材料综合力学性能最好,LLDPE(线性低密度聚乙烯)基复合材料的冲击韧性最好,但其综合力学性能较差。     

聚乙烯/超高分子量聚乙烯共混体系相行为的动态流变学研究

研究了高密度聚乙烯(HDPE)/超高分子量聚乙烯(UHMWPE)、线性低密度聚乙烯(LLDPE)/UHMWPE、低密度聚乙烯(LDPE)/UHMWPE三种共混物的动态流变性能。从弹性模量、复数粘度、特征频率和松弛时间的对数线性加和性、Cole-Cole曲线、Han曲线以及时温等效原理的分析表明LDPE/UHMWPE共混物在熔体状态是相容的,而LLDPE/UHMWPE和HDPE/UHMWPE共混物在熔体状态下发生分相过程。     

热塑性塑料熔体质量流动速率测量不确定度的评定

以聚乙烯为例讨论了热塑性塑料熔体质量流动速率测量不确定度的来源,依据JJF 1059-1999对熔体流动速率测试过程中的测量不确定度分量进行了分析和评定。7149型聚乙烯熔体质量流动速率测量结果的扩展不确定度为0.096 g/(10 m in)。     

预辐射聚丙烯反应挤出接枝丙烯酸的研究

利用电子束(EB)预辐照方法和反应挤出技术制备了聚丙烯接枝丙烯酸共聚物PP-g-AA. 采用化学滴定、红外光谱、偏光显微镜(PLM)、DSC和广角X射线衍射(WAXD)对接枝产物进行了表征. 研究结果表明, 接枝率随辐照剂量增加而增大并逐渐达到平台值, 但随单体浓度增大而表现为线性增加, 接枝链能起到异相成核作用, 从而提高了结晶速率并细化了球晶. 同时, 熔体流动速率(MFR)和力学性能测试结果表明, 预辐射和挤出过程造成了PP严重降解, 据此可认为接枝反应主要发生在聚丙烯断裂分子链的末端.     

通用聚丙烯的偶联反应

通过熔融接枝的方法在聚丙烯(PP)分子链上接枝甲基丙烯酸缩水甘油酯(GMA),制得PP接枝物PP-g-GMA,然后采用多个胺基的偶联剂聚六亚甲基胍(PHMG)对其进行偶联反应,制备偶联的聚丙烯(MPP)。通过与通用聚丙烯(EPS)以及进口专用料(PF-814)的对比,考察了经过偶联改性的MPP熔体的流变特性。结果表明:与原料EPS和PF-814相比,改性后MPP熔体的低频剪切区储能模量、挤出胀大、稳态柔量、零剪切黏度及熔体强度等都有明显增大。     

Molecular structure development of metallocene‐catalyzed linear low density polyethylene under ultrasonic irradiation

In this work, the effect of ultrasonic irradiation on molecular structure development of metallocene‐catalyzed linear low density polyethylene (mLLDPE) was studied. GPC results show that ultrasonic irradiation have influence on molecular weight and molecular weight distribution of mLLDPE. Molecular weight of mLLDPE decreases slightly at the initial 30 s of ultrasonic irradiation and then increases obviously; its distribution becomes wider with the increase of ultrasonic irradiation time. The power and frequency of ultrasonic irradiation have the distinct influence on molecular weight and its distribution of mLLDPE. DSC results show that ultrasonic irradiation has distinct influence on multiple step crystallizing behaviors of mLLDPE because of the change of branched chain in mLLDPE molecules. Thermal stability of mLLDPE is improved greatly because of micro‐crosslinking structure in mLLDPE molecule, which is formed in the presence of ultrasonic irradiation. A possible mechanism for molecular structure development of mLLDPE in the presence of ultrasonic irradiation is also proposed in this paper. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 2121–2129, 2005     

Linear viscoelastic properties of high‐density polyethylene/polyamide‐6 blends extruded in the presence of ultrasonic oscillations

Blends of high‐density polyethylene (HDPE) and polyamide‐6 (PA6) were produced by ultrasonic extrusion. Ultrasonic irradiation leads to degradation of polymers and in situ compatibilization of blends as confirmed by variations in linear viscoelastic properties. The results showed that the effect of ultrasonic irradiation on dynamic rheological properties depends on the composition and experimental temperature. At the same time, the relationship between storage modulus and loss modulus indicated the effect of ultrasonic irradiation on compatibility of HDPE/PA6 blends. Based on an emulsion model, the interfacial tension between the matrix and the dispersed phase was predicted. The data obtained showed that ultrasonic irradiation can decrease the interfacial tension and then enhance the compatibility of HDPE/PA6 blends. This finding was consistent with our previous work. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 1260–1269, 2005     

Influence of ultrasonic field on microcystins produced by bloom-forming algae

Under the background of algae removal and growth inhibition by ultrasonic irradiation, the effects of ultrasonic irradiation on removal of Microcystis, the concentration variation of microcystins (MC) produced by Microcystis in Microcystis suspension, and sonochemical degradation of microcystins in water, were studied in the paper. The results showed that ultrasonic irradiation could efficiently inhibit the growth of Microcystis, and ultrasonic irradiation shorter than 5 min would not introduce the increase of microcystins dissolved in Microcystis suspension simultaneity. Also, microcystins dissolved in Microcystis suspension would not increase as ultrasonic power increasing. Further research showed that microcystins were effectively degraded in ultrasonic fields. After 20 min ultrasonic irradiation at 150 kHz and 30 W, the removal rate of microcystins reached 70%.     

Effect of solvent on radiation grafting and crosslinking of polyethylene

Crosslinking of polyethylene influences its swelling properties. It could be expected that pre-crosslinking of polyethylene influences the rate and yield of grafting as well. This is demonstrated by pre-crosslinking of polyethylene and by its subsequent grafting with styrene after the trapped radicals had been annealed out.In order to obtain more direct information about the influence of swelling agent on polyethylene crosslinking, the elastic modulus of the crosslinked polyethylene was investigated. Stress–strain curves of polyethylene samples irradiated in different environments were recorded in molten state at 165 °C. The results show that irradiation of swollen polyethylene produces fewer effective crosslinks than does irradiation of dry polymer.     

Kinetic approach to radiation-induced grafting in the polyethylene-styrene system. V. The behavior of initiator radicals

With high-density polyethylene (HDPE) and low-density polyethylene (LDPE) films the grafting reactions were performed by the preirradiation method. By holding the total absorption dose constant irradiation time was varied. The initial rate of grafting decreased with irradiation time. The relative concentration of alkyl radical in the polyethylene film also decreased with irradiation time, but the relative concentration of allyl increased. The differences in the ESR spectrum before and after the introduction of styrene indicate that the allyl-type radical reacted with styrene. To elucidate these results the allyl radical in the amorphous region was considered.     

超声波照射激活亚甲基蓝(MB)声动力损伤牛血清白蛋白(BSA)

超声波;亚甲基蓝(MB);牛血清白蛋白(BSA);损伤     

低频超声波照射下卟啉锰(HP-Mn)配合物对牛血清白蛋白(BSA)损伤的研究

应用紫外-可见(UV-vis)光谱和荧光光谱研究了卟啉-锰(HP-Mn)配合物与牛血清白蛋白(BSA)的相互作用及在超声波作用下HP-Mn对BSA的损伤作用,并探讨了超声波照射时间,HP-Mn浓度,酸度,离子种类和强度等因素对BSA损伤的影响。结果表明,HP-Mn对BSA荧光的猝灭属于静态猝灭,两者主要通过静电作用相互结合,同时也存在着配位作用,作用距离(r)为3.49 nm。另外,在超声波作用下,HP-Mn能够明显损伤BSA。损伤程度随着超声波照射时间的增长,酸度的升高和HP-Mn浓度的增大而增大,但离子种类和强度的影响较为复杂。这一结果为声动力学(SDT)疗法治疗肿瘤应用于临床具有重要的意义。     

Polymerization of methyl methacrylate under ultrasonic irradiation. Part V. Effect of ultrasonic irradiation on stereoregularity of the polymers and oligomers produced by grignard catalyst in toluene–dioxane mixed solvent

Polymerization of methyl methacrylate with Grignard reagent in toluene–dioxane mixed solvent was carried out under ultrasonic irradiation. The effects of ultrasonic irradiation and the order of catalyst addition on Grignard reagent and the microstructure in the reacting sites were examined on the basis of the stereoregularity of polymers and oligomers produced. The formation of oligomers was also discussed on the basis of the consumption of initiator. The stereoregularity of the polymers in series A (no ripening of catalyst with solvent) is higher than that in series B (ripening of catalyst with solvent). The effect of ultrasonic irradiation on the stereoregularity was completely reversed in series A and B; it increased in the former and decreased in the latter with ultrasonic irradiation. Similar results were obtained for the stereoregularity of the oligomers, but the stereoregularity of the oligomers was lower than that of polymers.     

超声辐照下PEO与NaMAA嵌段共聚反应的研究

本文研究了在超声波辐照下聚氧化乙烯与甲基丙烯酸钠在水溶液中的嵌段共聚反应和共聚物结构。共聚反应按自由基聚合机理进行。反应动力学方程可用-(d[M]/(dt))=k[R·]^(1/6)[M]表示。随辐照时间或单体浓度的增加,共聚物产率和共聚物中NaMAA含量增大。将1％PEO-105％NaMAA水溶液在频率21.5kHz、阴极电流0.7A的超声强度下辐照15分钟,共聚物的产率为24.0％。用IR、MS、NMR、DSC、TEM等分析了共聚物的化学结构和聚集态结构,表明所得共聚产物为嵌段共聚物。     

Effects of ultrasonic oscillations on linear viscoelastic behaviors of metallocene‐catalyzed linear low density polyethylene and its blends with low density polyethylene

The effects of ultrasonic oscillations on linear viscoelastic behaviors of metallocene‐catalyzed linear low density polyethylene (mLLDPE) and its blends with low density polyethylene (LDPE) were investigated in this article. The experimental results showed that ultrasonic oscillations can increase the cross modulus, characteristic time, plateau modulus, complex viscosity, zero shear viscosity, and flow activation energy of mLLDPE. Molecular weight of mLLDPE increases but molecular polydispersity index decreases in the presence of ultrasonic oscillations. It has been found for mLLDPE/LDPE blends that the addition of LDPE as well as ultrasonic oscillations can decrease the cross modulus but increase the characteristic time of the blends. The complex viscosity, zero shear viscosity, and flow activation energy of the blends increase by the addition of LDPE, but decrease in the presence of ultrasonic oscillations. Shear thinning effect of the blends is improved because of the addition of LDPE. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 3030–3043, 2005