氯化聚丙撑碳酸酯增容聚丙撑碳酸酯/秸秆粉复合材料的制备及性能

聚丙撑碳酸酯(PPC)是一种新型热塑性生物降解材料,但其热性能及力学性能较差,应用受到限制。以秸秆粉这种农作物副产品作为增强体改性PPC,既可以提高PPC的力学性能同时又可开发利用秸秆资源。氯化聚丙撑碳酸酯(CPPC)是聚丙撑碳酸酯(PPC)经过氯化得到的,对天然纤维表面具有良好的浸润性和粘结性。本文以CPPC为增容剂,通过熔融共混法制备了PPC/秸秆粉复合材料。采用扫描电子显微镜(SEM)、拉伸实验、动态力学性能测试(DMA)及转矩流变仪对复合材料的结构及性能进行了表征,重点考察了CPPC的添加量对复合材料力学和流变性能的影响。结果表明,当CPPC质量分数为1.8%时,可使添加质量分数为30%秸秆粉的PPC复合材料拉伸强度提高38%,模量提高30%。同时,CPPC的引入使复合材料的粘度下降,改善了PPC/秸秆粉复合材料的加工性能。因此,作为增容剂的CPPC为制备高性能PPC/天然纤维复合材料提供了新的解决办法。     

聚丙撑碳酸酯的辐射效应

研究了室温条件下聚丙撑碳酸酯(PPC)在钴-60和电子加速器辐照过程中的响应行为。结果表明,聚丙撑碳酸酯是一种辐射裂解型聚合物,其分子量随着辐射剂量的增加而减小。1mm厚PPC片材在室温和N2气保护条件下,其裂解G值为Gs,γ-ray=10.81;Gs,EB=4.9。不同的裂解G值表明,O2气在聚丙撑碳酸酯的辐射裂解过程中有重要影响。红外光谱研究表明,辐射后聚丙撑碳酸酯在3474cm-1处的峰宽峰高增加,表明其裂解后端—OH基增加。由于裂解作用,辐射后聚丙撑碳酸酯的抗张强度和断裂伸长率均下降。在通常的辐射消毒剂量范围内(25~50kGy),PPC的保留抗张强度大于23MPa,断裂伸长率大于4%,裂解后试样的力学性能依然能够满足实际应用需要,因此PPC可以经受辐射消毒。     

新型单组分磷-氮膨胀型阻燃剂的合成及其阻燃性能

以氯化螺环磷酸酯(1)和对甲苯胺(2)为原料,经亲核取代反应合成了三源一体的新型单分子磷-氮膨胀型阻燃剂——季戊四醇螺环磷酰对甲苯胺(3),其结构经1H NMR和IR表征。考察了溶剂、原料配比、反应温度、反应时间和缚酸剂对3产率的影响。合成3的最佳反应条件为:乙腈为溶剂,三乙胺为缚酸剂,1 10mmol,n(1)∶n(2)=1∶3,于80℃反应4 h,产率79.3%。阻燃性能研究结果表明,3的初始分解温度为220℃,500℃成炭率达43.3%。     

磷系阻燃共聚酯的结构与性能

采用磷系阻燃剂2-羧乙基苯基次磷酸（CEPPA）作为第3单体,通过聚合反应制备了含磷的阻燃共聚酯。采用核磁共振、DSC、元素分析和极限氧指数仪表征阻燃共聚酯的化学组成、序列分布、结晶性能、磷含量和极限氧指数。结果表明：大部分CEPPA单元以无规分布的形式共聚到聚酯分子链中,小部分CEPPA单元以短嵌段的形式共聚在聚酯分子链中,且随着阻燃剂含量增加,无规系数变小。由于分子链的规整性下降,与聚对苯二甲酸乙二酯（PET）相比,阻燃共聚酯的Tg和Tm下降,结晶度减小。随阻燃剂含量的增加,极限氧指数值增加,当阻燃共聚酯中的磷含量达到9．08mg／g时,极限氧指数值达到33％以上。     

MgAlZnFe-CO3 LDHs对PBS膨胀阻燃体系性能的影响

采用恒定pH值共沉淀法在自制反应器中合成了不同原料配比的碳酸根型镁铝锌铁层状双羟基金属氧化物（MgAlZnFe-CO₃ LDHs）,并通过熔融共混MgAlZnFe-CO₃ LDHs、聚磷酸铵（APP）、三聚氰胺（MA）和全降解材料聚丁二酸丁二醇酯（PBS）制备出PBS膨胀阻燃材料. 采用傅里叶红外光谱（FTIR）、热失重（TG）、X射线衍射（XRD）、扫描电子显微镜（SEM）及元素分析（ICP）对MgAlZnFe-CO₃ LDHs进行了表征,并对PBS膨胀体系进行了力学性能和阻燃性能等测试. 结果表明,当Mg²⁺,Zn²⁺,Al³⁺和Fe³⁺的摩尔比为9：3：3：1时,合成的MgAlZnFe-CO₃ LDHs热稳定性最好,晶态结构规整,呈形貌规则的六边形片状;当MgAlZnFe-CO₃ LDHs的添加质量分数为1%时（阻燃剂的总添加质量分数为20%）时,PBS膨胀阻燃体系的极限氧指数（LOI）达到35%,垂直燃烧测试达到UL-94 V-0级别,力学性能得到较大改善. 实验结果表明,低添加量的MgAlZnFe-CO₃ LDHs与膨胀阻燃剂（IFR）协效阻燃PBS,一方面能够改善膨胀阻燃剂恶化PBS力学性能的现象,另一方面协同效应能够明显提高PBS的阻燃性能.     

Thermal Degradation and Flammability Properties of Poly(propylene)/Carbon Nanotube Composites

Nanocomposites based on poly(propylene) and multi‐wall carbon nanotubes (up to 2 vol.‐%) were melt blended, yielding a good dispersion of nanotubes without using any organic treatment or additional additives. Carbon nanotubes are found to significantly enhance the thermal stability of poly(propylene) in nitrogen at high temperatures. Specifically, the nanotube additive greatly reduced the heat release rate of poly(propylene). They are found to be at least as effective a flame‐retardant as clay/poly(propylene) nanocomposites.     

线性聚酯酰胺对聚碳酸亚丙酯的改性

通过己内酯和氨基己酸开环、缩合反应制备了酯段含量为81%的线性聚酯酰胺（PEA）,并用熔融共混的方法制备了PEA/聚碳酸亚丙酯（PPC）共混物,考察了PEA的引入对共混体系相容性、热力学稳定性和机械性能的影响。 结果表明,PEA与PPC之间有较好的相容性,共混物的热力学稳定性比PPC有显著提高,当PEA质量分数为3%时,共混体系的起始分解温度（T-5%）和最大分解速率时的温度（Tmax）比PPC分别提高了52.7%和46.4%。 通过调节PEA的含量可以使共混体系同时达到增强和增韧的效果。     

Thermophysical Properties of Poly(propylene)-based Composite Polymer

The thermal diffusivity and the thermal conductivity of polypropylene-based composite polymer were simultaneously measured with a temperature wave analysis method. We can measure the thermal properties under cooling process which are important to consider the polymer processing. The effect of filler in the composite was analyzed by thermal diffusivity and thermal conductivity as a function of temperature. The thermal conductivity of particle dispersed composite was confirmed as a reasonable value and was explained with a series model. This revised version was published online in July 2006 with corrections to the Cover Date.     

Isothermal Crystallization of Isotactic Poly(propylene) Studied by Superfast Calorimetry

The isothermal crystallization behavior and the structure and morphology of isotactic poly(propylene) (iPP) and iPP/hydrogenated hydrocarbon resin (HR) 90/10 blend were analyzed. To cover the entire temperature range, isothermal crystallizations were studied using superfast calorimetry at a high cooling rate in the range 0 to 110 °C, and by conventional DSC at a low cooling rate in the range 120 to 140 °C. Structural and morphological changes due to the different thermal treatments were also analyzed. The complete crystallization curve ranging from T_g to T_m showed bimodal crystallization behaviors for both iPP and iPP/HR 90/10 blend. This result is explained by taking into consideration the polymorph properties of iPP. It is in fact assumed that the curve from T_g to 60 °C referred mainly to the crystallization kinetics of the iPP mesomorphic form by homogeneous nucleation, whereas the curve from 60 °C to T_m mainly represented the crystallization kinetic curve for the monoclinic α form by heterogeneous nucleation. This hypothesis is confirmed by the analysis of the structures obtained using wide angle X‐ray experiments. Moreover, the addition of HR to iPP causes a drastic reduction in the crystallization rate of iPP in both regions due to the diluent effect of the miscible resin.

     

含亚胺结构新型磷-氮协效阻燃化合物的合成及对环氧树脂的阻燃作用

采用醛胺缩合反应,以4-(5,5-二甲基-1,3-二氧杂环己内磷酰基)苯甲醛(PCHO)分别与对苯二胺、乙二胺反应合成两种磷酸酯-亚胺双官能化合物阻燃剂(FR:N¹,N⁴-二[4-(5,5-二甲基-1,3-二氧杂环己内磷酰氧基)苯基亚甲基]-1,4-苯二胺(PNB)和N¹,N²-二[4-(5,5-二甲基-1,3-二氧杂环己内磷酰氧基)苯基亚甲基]-1,2-乙二胺(PNE)),研究了FR对4,4'-二氨基二苯砜(DDS)固化双酚A二缩水甘油醚型环氧树脂(DGEBA)体系的阻燃作用及阻燃机理。 研究发现FR的引入显著提高了DGEBA/DDS在700 ℃时的残炭率(R_c),同时提升了材料的阻燃性能,其中以乙二胺合成的PNE阻燃性能显著优于以苯二胺合成的PNB。 当磷添加质量分数为1.5%时,PNE-1.5/DGEBA/DDS在N₂气下的R_c为35.1%,在空气下的R_c为14.4%,极限氧指数(LOI)为33.2%,并可达阻燃等级UL-94最高阻燃级别V-0级。 同时,PNE-1.5/DGEBA/DDS相较于DGEBA/DDS保持了弯曲强度和76%以上的冲击强度,机械性能显著优于PNB-1.5/DGEBA/DDS。 通过阻燃机理分析FR在DGEBA/DDS体系中具有凝聚相、气相及磷-氮协效共同作用的阻燃特点。 磷酸酯-亚胺双官能团化合物FR对环氧树脂体系具有良好的阻燃作用,其中PNE阻燃效率高、机械性能负面影响小,具有潜在应用价值。     

新型树状单分子磷-氮膨胀阻燃剂的合成及阻燃性能研究

以六氯环三磷腈、对羟基苯甲醚、新戊二醇以及三氯氧磷等为原料, 合成一种新型树状单分子磷-氮膨胀阻燃剂六(4-(5,5-二甲基-1,3-二氧杂环己内磷酸酯基苯氧基))环三磷腈(Ⅵ). 标题化合物结构经IR、MS 及¹H NMR 证实. 热失重分析表明标题化合物具有较高的热稳定性和良好的成炭性, 氮气氛下的起始分解温度为270 ℃, 600 ℃时炭残余量达45.2%. 实验表明, 标题化合物对环氧树脂呈现出良好的阻燃效果.     

高密度聚乙烯/蒙脱土纳米复合材料膨胀阻燃体系的性能

使用以乙烯/醋酸乙烯共聚物(EVA)为相容剂的高密度聚乙烯/蒙脱土(HDPE/OMT)纳米复合材料作为基体,制备了含不同成炭剂的聚磷酸铵(APP)膨胀阻燃体系,对其阻燃性能进行了比较和研究,并分析了蒙脱土与膨胀阻燃剂协效作用的机理。热重分析(TGA)、垂直燃烧(UL-94)、极限氧指数(LOI)、锥形量热计结果表明:APP/季戊四醇(PER)体系熔融过程较短可形成蒙脱土增强炭层;PER/PA/OMT体系中较高的有机物含量有利于蒙脱土迁移和堆积。     

膨胀型环状类磷酸酯蜜胺盐阻燃剂的合成及阻燃聚丙烯的结构与性能

以双季戊四醇、三季戊四醇、多聚磷酸、五氧化二磷和三聚氰胺为原料,合成了膨胀型环状类磷酸酯蜜胺盐阻燃剂,并与聚丙烯共混制成阻燃聚丙烯.红外分析表明该阻燃剂具有环状结构.通过扫描电镜和X射线衍射对阻燃聚丙烯进行了结构分析和表面纹理的表征.实验结果表明：该阻燃剂阻燃性能良好,但在聚丙烯中的分散性较差;用甲基纤维素对该阻燃剂进行表面化学修饰以后,该阻燃剂在聚丙烯中的分散性及阻燃材料的机械性能得到了明显的改善.     

Micellization and Thermogelation of Poly(ether urethane)s Comprising Poly(ethylene glycol) and Poly(propylene glycol)

A series of multiblock poly(ether urethane)s comprising poly(ethylene glycol) (PEG), and poly(propylene glycol) (PPG) segments were synthesized. Their aqueous solutions exhibited thermogelling behavior at critical gelation concentrations (CGC) ranging from 8 to 12 wt%. The composition and structural information of the copolymers were studied by GPC and ¹H NMR. The critical micellization concentration (CMC) and thermodynamic parameters for micelle formation were determined at different temperatures. The temperature response of the copolymer solutions were studied and found to be associated with the composition of the copolymers.     

偶联剂对聚氯乙烯－聚丙撑碳酸酯共混体系力学性能的影响

偶联剂对聚氯乙烯－聚丙撑碳酸酯共混体系力学性能的影响王胜杰，黄玉惠，丛广民（中国科学院广州化学研究所广州５１０６５０）关键词聚氯乙烯，聚丙撑碳酸酯，偶联剂，丁腈胶，过氧化苯甲酰，共混聚氯乙烯（ＰＶＣ）是用量巨大的通用塑料，其软性制品需用大量的增塑剂，...     

Thermal and dynamic mechanical properties of poly(propylene carbonate)

Summary Thermal and dynamic mechanical properties of carbon dioxide and propylene oxide alternative copolymer, poly(propylene carbonate) (PPC), and the end-capped PPC with maleic anhydride were investigated by means of TG and DMA. A master curve of the storage modulus vs. frequency can be deduced from the isochronal curves. Physical parameters of both plain and MA end-capped PPC were discussed. The results showed that for maleic anhydride (MA) end-capping PPC, an improvement of its thermal stability and mechanical properties accompanied with some modifications of the viscoelastic behavior were obtained.     

Effect of a Nanoclay on the Mechanical,Thermal and Flame Retardant Properties of Rigid Polyurethane Foam

Water blown rigid polyurethane foams (PUF) with organoclay/organically modified nanoclay (ONC) were prepared and their properties such as density, mechanical, morphological, insulation, thermal and flame retardant properties were studied. In this investigation, the ONC content was varied from 1 to 10 parts per hundred of polyol (php) by weight. It was observed that the compressive strength of ONC filled PUF increased up to 3 php of ONC loading and then it decreased. Wide angle X-ray diffraction and transmission electron microscopy studies indicated the exfoliated dispersion of ONC in PUF. The thermal conductivity of ONC filled PUF decreases up to 5 php and then increases. The glass transition temperature (Tg) of PUF decreases on loading of ONC. The TGA analysis shows that there is slight increase in degradation temperature with increase in ONC loading. The flame retardant properties (LOI and flame spread rate) are improved slightly on addition (3 php) of ONC filled PUF.