聚醚醚酮醚酮的合成与表征

聚醚醚酮（ＰＥＥＫ）自工业化以来［１］，由于其优异的性能已在机械、航天等领域得到广泛应用．各种聚芳醚酮类聚合物相继被开发出来．但以亲电缩聚路线制备聚醚醚酮醚酮（ＰＥＥＫＥＫ）的报道较少［２］．本文以二苯醚和４－氟苯甲酰氯为主要反应试剂，采取付氏酰基化...     

聚醚醚酮/聚醚醚酮酮共混体系的熔融和等温结晶行为

采用熔融共混方法制备了聚醚醚酮和聚醚醚酮酮的共混物,用DSC对共混物的熔融行为和等温结晶行为进行了研究.结果表明,共混物熔点随聚醚醚酮含量增加而降低,但与聚醚醚酮酮有相同的平衡熔点,二者共混没有改变其结晶的成核与生长机制.     

含联苯结构聚醚醚酮酮共聚物和共混物的制备及性能研究

聚醚醚酮（PEEK）是八十年代初投入市场的全芳香结构热塑性耐高温特种工程塑料，它的7’。一143“C，Tm一334C“‘，最大结晶度为48％，典型制品结晶度为20％～30％［”．PEEK可用通常的设备成型，其制件、纤维、涂料及复合材料在电子电器、机械设备、交通运输、宇航、原子能工程、军事等领域有广泛的用途［’j．聚醚醚酮酮（PEEKK）是继PEEK之后，由德国Hoechst公司开发出来的又一种全芳香结构热塑性耐高温特种工程塑料［‘j．为了研究该类聚合物的结构和性能的关系，我们在实验室中合成了PEEKK和含联苯结构聚醚醚酮酮（PE－＊…     

聚醚砜醚酮的合成与性能

以4,4′-二羟基二苯砜和4,4′-二氟二苯酮为单体, 通过溶液缩聚合成了聚醚砜醚酮(PESEK), 其分子结构相当于聚醚砜(PES)与聚醚醚酮(PEEK)的交替共聚物. 在共聚物分子中, 存在砜基、醚基和酮基, 整个结构单元形成了大共轭体系, 聚合物属无定形聚合物, 玻璃化转变温度(Tg)为198 ℃, 介于PEEK和PES的Tg之间, 其热稳定性和加工性能优于PES, 而力学性能与PES接近.     

聚醚醚酮酮和含联苯聚醚醚酮酮共聚物的熔融热

根据Ｆｌｏｒｙ热力学统计理论和比容－熔融热作国法，由ＤＳＣ结果得到了不同联苯含量的聚醚醚酮酮－含联苯聚醚醚酮酮（ＰＥＥＫＫ－ＰＥＢＥＫＫ）共聚物的熔融热，两种方法获得的结果吻合。在此基础上给出了ＰＥＥＫＫ－ＰＥＢＥＫＫ共聚物不同联苯含量的熔点计算表达式。结果还表明，随着联苯含量ｎＢ，的变化，明显改变；当ｎＢ＝０．３５时，ＰＥＥＫＫＰＥＢＥＫＫ共聚物的值最小。     

Microcellular processing and relaxation of poly(ether ether ketone)

The semicrystalline microcellular closed‐cell foams are prepared by a two‐stage batch foaming process from poly(ether ether ketone) and characterized by scanning electronic microscopy. It can be observed that there are two kinds of cells with obviously different cellular sizes in the same transect and the distribution of larger cells (about 7 μm) looks like sandwich. The effects of foaming temperatures and transfer times on the cellular sizes and cell densities of porous materials were discussed. Particular emphasis was given to the effects of crystalline on the microcellular morphology. The relaxation mechanism of microcellular materials was systemically investigated by dynamic mechanics analysis. A plain on the storage modulus curve before T_g was observed due to the densification of cells. © 2007 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 45: 2890–2898, 2007     

Selective cleavage of the linear ether bond in benzyl glycidyl ether and triphenylmethyl glycidyl ether by potassium alkalide as two-electron-transfer reagent

The linear ether bond was exclusively cleaved in benzyl glycidyl ether and triphenylmethyl glycidyl ether under the influence of K⁻, K⁺(15-crown-5)₂ (1), whereas the strongly strained three-membered oxacyclic ring remained undisturbed. Potassium glycidoxide and benzylpotassium were found as the primary reaction products of benzyl glycidyl ether with 1. Subsequently, benzylpotassium reacted with benzyl glycidyl ether giving the next potassium glycidoxide molecule and bibenzyl. Benzyl phenyl ether was used as a model compound to explain the mechanism of bibenzyl formation. The reaction of triphenylmethyl glycidyl ether with 1 resulted in potassium glycidoxide and stable triphenylmethylpotassium. After treating with a quenching agent a new glycidyl ether or glycidyl ester was obtained from potassium glycidoxide. These results were found when the reaction occurred at the excess of glycidyl ether. In another case, i.e. at the excess of 1 further reactions took place with the participation of potassium anions and various new compounds were observed in the reaction mixture after benzylation or methylation. Thus, the method of substrates delivery influences the course of studied processes in a decisive way.     

可交联含氟聚醚醚酮的合成

聚醚醚酮 (PEEK)是一种耐热等级高、耐化学药品、耐辐射并有优异的电性能及机械性能的特种工程塑料 .由于其综合性能优异 ,PEEK在航空航天、通信、电子和机械化工等领域获得成功应用 [1] .含氟芳香聚合物以其独特的性能而成为低介电常数微电子和低损耗光波导器件极具潜力的材料 [2 ] .聚合物良好的溶解性虽对光电集成电路的加工十分重要 ,但也要满足多层化操作过程 ,还要考虑器件成型后的抗化学药品性 .因而 ,在聚合物中引入可交联组分是必要和可行的方法 .另外 ,交联后的聚合物将有更高的玻璃化转变温度 (Tg)、更好的尺寸稳定性和防开…     

主链含酰亚胺结构的聚醚醚酮的合成及其性能

以1,4-二苯氧基苯为单体分别与N,N′-(4,4′-二苯甲烷)-双-(3,4-二甲酰亚胺基苯甲酰氯)和N,N′-(4,4′-二苯砜)-双-(3,4-二甲酰亚胺基苯甲酰氯),采用低温溶液缩聚合成了2种主链含酰亚胺结构的聚醚醚酮树脂,聚合物的比浓对数粘度分别为0.98和0.61 dL/g。 用FT-IR、¹H NMR和WAXD进行了结构表征,用DSC和TGA测试了热性能。 结果表明,聚合物有较高的玻璃化转变温度(T_g分别为236和263 ℃),N₂气气氛中热分解温度(5%T_d)分别为529和512 ℃,能溶于N,N-二甲基乙酰胺、N-甲基-2-吡咯烷酮、氯仿和间甲酚等常见的有机溶剂中。     

Thermal conductivity of poly(ether ether ketone) and its short-fiber composites

The effects of crystallinity, orientation, and short-fiber filler on the thermal diffusivity D and thermal conductivity K of poly (ether ether ketone) (PEEK) have been studied. Below the glass transition, D increases by less than 10% as the crystallinity increases from 0 to 0.3. For amorphous PEEK, there is an abrupt drop in D at the glass transition (T_g ? 420 K). The drop is less prominent for the 30% crystalline sample and occurs at 20 K higher. At a draw ratio of 2.5, the axial thermal conductivity is 2.3 times higher while the transverse thermal conductivity is 30% lower than that of the unoriented material. For an injection-molded bar of carbon fiber reinforced PEEK, the variation of D with position along the width or thickness direction is found to correlate well with the fiber orientation. By regarding the injection-molded bar as a multidirectional laminate comprising a large number of unidirectional plies, the thermal conductivities along the longitudinal and transverse direction are calculated and found to agree closely with the experimental data. © 1994 John Wiley & Sons, Inc.     

Effect of Antioxidants on the Stability of Poly(ether ether ketone) and the Investigation on the Effect Mechanism of the Antioxidants to Poly(ether ether ketone)

Two types of antioxidants (a phenolic antioxidant and a phosphorous antioxidant) were used to improve the stability of poly (ether ether ketone) (PEEK). To evaluate the effect of the antioxidants on the properties of PEEK and the stabilization mechanism, some characterization methods were carried out, such as rheometer, TGA, and electron spin resonance (ESR). The results indicated that the efficiency of the phosphorous antioxidant (DS) in improving the stability of PEEK was better than that of the phenolic antioxidant (DN) and the thermal stability of PEEK sample containing 0.07 wt% DS was the best among all samples due to the decrease of the free radicals density, as proven by ESR measurement. The possible stabilization mechanism of the antioxidants to PEEK was proposed to reveal the reason that caused the different performances of the two types of antioxidants to PEEK.     

聚醚醚酮酮结晶度研究

聚醚醚酮酮结晶度研究刘天西，王尚尔，张宏放，莫志深（中国科学院长春应用化学研究所高分子物理联合开放研究实验室长春１３００２２）那辉，王军佐，吴忠文（吉林大学化学系长春）关键词聚醚醚酮酮，广角Ｘ射线衍射，结晶度新型特种工程塑料聚醚醚酮酮（ＰＥＥＫＫ）具...     

新型含磷双酚A型共聚醚醚酮的合成与性能

新型含磷双酚A型共聚醚醚酮的合成与性能;溶液缩聚;含磷单体     

聚醚醚酮表面的亲水改性和胶原蛋白固定化

采用紫外光接枝法对聚醚醚酮(PEEK)表面进行化学修饰和生物分子固定化.首先向PEEK表面引入亲水性的丙烯酰胺,并以此为反应位点通过戊二醛将胶原和胶原蛋白固定在PEEK表面.用接触角测定仪、扫描电镜、荧光标记和X射线光电子能谱等对改性薄膜进行了表征.结果表明,PEEK上丙烯酰胺的接枝密度高达50.9μg/cm~2;改性薄膜表面浸润性显著提高,水接触角最低降至(22±3)°.荧光标记胶原固定的PEEK薄膜荧光发射光谱强度最高,并在X射线光电子能谱中检测到N元素,表明胶原已固定化,固定胶原蛋白的浓度为10.2μg/cm~2.     

可控交联聚醚醚酮的合成与热性能研究

聚醚醚酮因其优异的综合性能 (耐热性、耐水解、耐辐射等 )在许多领域得到应用 [1～ 4 ] .但聚醚醚酮的玻璃化转变温度 ( Tg)较低 ( 4 2 6K) ,导致其使用温度较低 (在 5 1 3K以下 ) .为进一步提高聚芳醚酮类材料的使用温度 ,人们在聚醚醚酮主链中引入刚性结构 ,通过提高聚芳醚酮的刚性度来提高聚芳醚酮的熔点 ( Tm)及 Tg,从而提高材料的使用温度 [5,6 ] .文献 [7]中聚芳醚酮的 Tm 已经高达 741 K,但此材料很难加工成型 .通常热塑性材料具有优异的加工性能 ,但使用温度较低 .热固性材料的使用温度较高 ,但在加工固定尺寸形状铸件时存在困…     

Radiochemical ageing of poly(ether ether ketone)

Thin (60 μm) and thick (250 μm) samples of poly(ether ether ketone) were subjected to radiochemical ageing at 24 kGy h⁻¹ dose rate for doses up to 30.7 MGy at 60 °C in air. FTIR spectrophotometry (hydroxyl and carbonyl build-up), ATR microscopy (oxidation profiles), ammonia gaseous treatment (determination of carbonyl nature), density, DSC (glass transition temperature, cold crystallization and melting point changes), and gel content measurements (crosslinking) were conducted for examination of polymer degradation. Thin samples were shown to undergo principally chain scission process whereas thick ones undergo mainly crosslinking. This difference can be attributed to the kinetic control of oxidation by oxygen diffusion. A mechanistic scheme was proposed from radiochemical yields estimations.     

高磺化度芳香聚醚醚酮的合成与表征

用3,3'-二磺酸钠基-4,4-二氟二苯酮合成了具有高磺化度的荷电聚醚醚酮.用红外吸收光谱及DSC对其进行了表征.研究了共聚物的组成、热稳定性、溶解性、成膜性及磺化度对共聚物性能的影响.     

含氟聚醚醚酮酮的制备及其性能

以邻氟对苯二酚和4,4′-二氟三苯二甲酮为原料通过亲核缩聚反应,合成含氟聚醚醚酮酮(FPEEKK)材料。 用FTIR、1H NMR和WAXD进行了结构表征,用DSC、TGA测试了热性能,并研究了聚合物的溶解性、吸水性、介电性能及光学性能。 结果表明,含氟聚醚醚酮酮具有较好的热性能（N2气气氛中,5%热分解温度为505 ℃）;能溶于氯仿、四氢呋喃和N,N-二甲基甲酰胺等有机溶剂;具有较低的吸水率(0.24%)和介电常数（ε=3.0）;在近红外区1300和1550 nm处吸收非常弱。     

可控交联聚醚醚酮动态流变学行为的研究

聚芳醚酮类材料因其优异的综合性能在许多领域得到广泛应用 [1,2 ] .许多研究者通过提高聚芳醚酮分子链的刚性度来实现进一步提高其使用温度 ,但由于其在高温时流动性下降 ,熔体粘度增大 ,给加工及应用带来很大困难[3] .基于此 ,我们将可在高温或辐照条件下发生交联反应的硫醚结构作为交联点引入到聚醚醚酮主链中 ,合成了可控交联的聚醚醚酮[4 ,5] .聚合物的分子结构及其熔体中分子的内部作用可以用流变学进行研究 .因此 ,我们用动态流变学实验监测跟踪聚合物的交联反应过程 ,研究可控交联聚醚醚酮的交联反应动力学 ,为设计改造分子结构以满…     

含间位聚醚酮醚酮酮的合成与结晶

聚芳醚酮类聚合物因其综合性能优异而在高技术领域得到广泛应用．这些高聚物的主链大都为全对位连接,使其熔点较高以至加工难度增大．如果在聚合物主链中引入间位结构,则可在对玻璃化转变温度影响较小的情况下降低熔点来改善加工条件［１］．含间位聚醚酮醚酮酮（ＰＥＫＥＫｍＫ）也是其中一种．本文主要研究ＰＥＫＥＫｍＫ的合成、基本物性与结晶行为．样品的合成与制备：单体４,４′双（对苯氧基）二苯甲酮按文献［２］方法合成．聚合物参照文献［３］合成．将粉末样品在油压机上熔融后快速取出投入冰水中淬火得无定形样品,或将熔融…