硼酚醛树脂的合成与固化机理的研究

本文研究了硼酚醛树脂的合成与固化反应过程的机理, 结果表明, 甲阶段的硼酚醛树脂主要是硼酸苄酯, 固化过程中形成硼酸苯酯, 反应过程中有醚键生成, 醚键断裂产生羰基。     

硼酚醛树脂热分解动力学及其耐热性

用热重法研究了固化硼酚醛树脂的热分解动力学。并用红外光谱法跟踪硼酚醛树脂的固化过程；结果表明，热分解过程为一级反应，由于硼酯键代替了醚键和次甲基键使得热氧化裂解速率常数随硼含量的增加而减小。     

FTIR研究不同固化程度SiO_2/酚醛杂化材料官能团的变化

采用FTIR光谱吸收峰的波数位移、A/A1612表示的吸收强度和半峰宽Δ1/2(O—H)/Δ1/2(C C)表示的谱带宽度,比较不同固化程度SiO2/酚醛树脂杂化材料官能团的变化.在相同固化条件下(120℃,2 h),杂化材料的氢键作用比酚醛树脂的强得多,羟基含量更高,而且杂化材料发生邻位取代缩合反应的比例特别高.正是因为杂化材料中未反应的官能团多,作为底漆使用时能与面漆中的官能团反应,实现无层间界面交联,获得层间结合力.过固化过程(160℃,1 h)能够有效降低杂化材料中的羟基含量,但醚键含量比酚醛树脂的高得多,而且过固化过程中酚环主要发生对位取代缩合反应.杂化材料固化后的颜色比热固性酚醛树脂的淡得多,与热塑性酚醛树脂的相当.在相同氧化程度下,杂化材料中无游离酚,比酚醛树脂更环保.     

几种酚醛树脂热裂解的研究

采用热失重、差热分析、热机分析、裂解气体容积分析及组分的色谱分析等方法,对几种热固性酚醛树脂的热裂解进行了研究。结果表明酚醛树脂的热稳定性与二亚甲基醚键的存在很有关系,随着醚键的增多而热稳定性降低。对树脂的热裂解机理进行了讨论。     

氨基聚酯树脂固化过程的FTIR跟踪

用FTIR内标法跟踪氨基聚酯树脂的固化过程,选取815cm~(-1)的三嗪环面外振动峰作内标峰,913cm~(-1)处的甲氧基变形振动峰和3500cm~(-1)左右的羟基伸缩振动峰为特征吸收峰。结果表明,随着固化的进行,涂膜的羟基、甲氧基和羧基递减,醚键和羰基递增,说明固化过程是以交联反应为主,伴有自缩合反应和酯化反应的复杂过程。     

酚醛树脂/蒙脱土纳米复合材料的制备及固化反应动力学研究

利用自制的有机蒙脱土 ,采用浇模固化成型法制备酚醛树脂 /六次甲基四胺 /蒙脱土纳米复合材料 ,并用XRD观察有机蒙脱土分别在热塑性和热固性酚醛树脂中复合行为 .研究发现 ,由于两种树脂的固化反应机理不同 ,热固性酚醛树脂与蒙脱土复合 ,可得插层型纳米复合材料 ;而采用热塑性酚醛树脂进行固化 ,则得到部分剥离的纳米复合材料 .通过DSC进一步研究热塑性酚醛树脂 /蒙脱土复合体系的固化反应动力学 .运用Kissinger ,Flynn Wall Ozawa ,Crane方法求出活化能和反应级数等动力学参数 .结果发现 ,加入蒙脱土使固化反应活化能下降 ,反应级数减小 ,从而有利于固化工艺的实现 ,便于纳米复合材料实际应用 .     

铁粉促进断裂Se—Se键及其应用于合成α-芳硒基羰基化合物

在铁粉存在下,以商用N,N-二甲基甲酰胺(DMF)作溶剂,90℃、氮气保护下,二芳基二硒醚与α-溴代羰基化合物反应,得到一系列α-芳硒基羰基化合物.考察了温度、时间、溶剂及铁粉用量对反应的影响,其中,温度对反应的影响最为明显.α-溴代羰基化合物中羰基上取代基对反应有很大影响,取代基为苯基时,转化率较甲基或烷氧基时低.反应机理可能是铁插入Se—Se键中形成亲核性Se Fe Se,随后与亲电底物α-溴代羰基化合物发生亲核取代.本方法使用铁粉促进断裂Se—Se键具有原料安全无毒、廉价易得、实验操作简便等优点.     

双酚A甲醛酚醛环氧树脂与二氨基二苯醚的固化反应及热降解

用傅里叶红外光谱、差示扫描量热仪和热重分析测试技术研究了双酚A甲醛酚醛环氧树脂(bis-ANER)与二氨基二苯醚(DDE)的固化反应及其固化产物的热降解性能。在等温固化反应中环氧基团红外光谱吸收强度随固化时间延长而逐渐减弱,羟基吸收强度逐渐增强,固化反应后期出现羰基红外吸收,其强度随固化时间的延长而增强。用Kissinger法和Ozawa-Flynn-Wall法计算出的bis-ANER/DDE非等温固化反应活化能分别为57.6和61.5kJ/mol。固化产物的热降解首先是醚键的断裂,在N2气和O2气气氛下起始阶段的热降解反应均符合g(α)=[-ln(1-α)]2/3的核增长反应机理,2种气氛下高温阶段的热降解机理不同,O2气在降解过程中产生氧化作用。     

脲醛树脂合成反应过程的FTIR研究

利用傅里叶变换红外(FTIR)光谱研究了脲醛树脂合成中不同结构形成和变化情况. 对FTIR谱图解析和分析的结果表明, 在脲醛树脂预聚物合成过程中, 随着甲醛与尿素反应的进行, 红外谱图特征峰发生有规律的变化, 酰胺II带特征峰波数逐渐低移, 有更多羟甲基、醚键和—NHCH2—结构基元形成, 固化反应使上述结构基元相应减少. 着重分析了不同甲醛与尿素摩尔比(nF/nU)下尿素与甲醛反应产物结构的变化, 随nF/nU的增加, 酰胺II带特征峰波数逐渐低移, 碱性条件下醚键和—NHCH2—结构基元明显增加, 在较强酸性条件下Uron环、亚甲基桥和羟甲基显著增加, 而—NHCH2—结构基元含量下降.     

酸性沸石分子筛催化Knoevenagel综合反应

在高硅／铝比的酸性沸石分子筛HY上实现了Knoevenagel缩合反应，Bronsted酸和Lewis酸均可催化Knoevenagel缩合反应。考察了羰基化合物和活泼亚甲基化合物的反应活性顺序。结果表明，羰基化合物的羰基极化程度越高，反应越容易进程,示同于碱催化时的Knoevenagel缩合反应，活泼亚甲基化合物的活泼氢的酸性并不是影响其反应活性的重要因素。     

Structural characteristics of p‐t‐Octylphenol formaldehyde resole resins using molecular simulation

p‐t‐Octylphenol formaldehyde resole resins have two linkage types of methylene‐ and dimethylene ether‐linkages and have three terminal types of hydrogen, methylol, and o‐methylene quinone. Variation of structural characteristics of the resins due to different types of linkages and terminals were studied using molecular dynamics and molecular mechanics. The structural characteristics of the methylene‐bridged resins were intramolecular hydrogen bonds between hydroxyl groups of the adjacent p‐t‐octylphenols. In the dimethylene ether‐bridged resin, the intramolecular hydrogen bonds between oxygen atoms of the dimethylene ether‐linkages and hydroxyl groups of the neighboring phenolic units were found. For the resins with both methylol terminals, one of both terminals of the resins was hidden at the center of the molecule when the resin size is large. The number of hydrogen bonds in the resins with the methylol terminal was larger than for the resins with the o‐methylene quinone terminal. Variation of the structural characteristics of the resins by dehydration of the terminal methylol was discussed. Using the calculated results, dissociation of the dimethylene ether linkage and crosslinking reaction of rubber chains by the resin were explained. Copyright © 2002 John Wiley & Sons, Ltd.     

苯基二氨三嗪-甲醛树脂高温固化过程的红外光谱研究

本文通过不同平均加成度的A阶苯基二是三嗉甲醛树脂的红外光谱分析,对其红外吸收峰的归属进行了讨论。应用高温红外光谱和差谱技术对两种树脂样品的交联行为进行跟踪观察,由的红外吸收变化和反应体系中甲醛的检测推论了树脂的热固化反应。     

Changes in curing behaviour of aminoresins during storage

Summary The curing behaviour of commercial UF and MUF resins, stored at room temperature nearly up to gelation, is studied by simultaneous TG-DTA technique and structural changes of resins are also followed during aging. On the basis of ¹³C NMR spectra, the main chemical reaction during UF resin storage is the formation of methylenes and dimethylene ethers linked to secondary amino groups. Aging of resins results in a decrease of cure rate which is related to lower concentration of active functional groups and decrease in molecular mobility. On DTA curve, the resin with higher content of methylol groups reveals the curing exotherm earlier. With decreasing methylol content during storage, the peak maximum of exotherm is shifted to higher temperature value. Advanced polycondensation and sedimentation processes during storage produce partly locked in macromolecule structure water, and the water evaporation endotherm on DTA curve shifts to considerably higher temperature. The aged MUF resins are chemically less changed than UF resins and the aging process mainly involves noncovalent network formation due to complex molecular structure.     

Melamine–formaldehyde resins: Constitutional characterization by fourier transform 13C-NMR spectroscopy

The random chemical structures of melamine–formaldehyde resins, including methylated melamine–formaldehyde resins and urea–melamine formaldehyde resins, were investigated by ¹³C-NMR spectroscopy (Fourier transform). All the combined formaldehydes, methylol and methyl ether groups, methylene structures, and dimethylene ether structures were assigned. A ¹³C chemical shift of methylene carbon occurred by substitution of other constituents of the methylene group for a proton of the adjacent monosubstituted nitrogen atom, as shown in a ¹³C-NMR spectrum of urea–formaldehyde resins. It was found that the chemical shift of each corresponding carbon of both melamine resins and urea–melamine resins was almost superimposed with that of urea resins.     

Urea-formaldehyde resins. III. Constitutional characterization by 13C fourier transform NMR spectroscopy

¹³C Fourier transform NMR has been used to characterize a random chemical structure of ureaformaldehyde resins. By comparison of ¹³C chemical shifts with synthesized standard derivatives from urea and formaldehyde the analysis of reacted formaldehyde was completed. In a ¹³C spectrum of resin each signal due to reacted formaldehyde (e.g., methylol group, methylene group, and dimethylene ether group) was isolated. Measurement of a ¹³C spectrum of resin by the gated decoupling of proton without nuclear Overhauser effect made a quantitative analysis of reacted formaldehyde possible. In this quantitative analysis a ¹³C quantity of carbonyl groups in urea residue can be directly compared with that of each combined formaldehyde.     

Mass spectrometric monitoring of change of resole structures by compounding and curing of EPDM compound

Change of resole structures in a rubber compound by compounding and curing processes were investigated using ethylene-propylene-diene terpolymer (EPDM) compound and atmospheric pressure chemical ionization-mass spectrometry (APCI-MS). Resole structures were divided into three groups of reactive, pendent, and unreactive species to examine in detail the structural changes. Reasonable resole species of the major resole species having two possible structures were determined using variations of the relative abundances by compounding and curing. Of the major resole species, there was no resole species having both terminals of methylol. It was found that resole was not simply mixed in a rubber matrix and reactive resole species were diversified and activated through the compounding process. Almost all reactive resole species participated in crosslinking reactions, but some reactive resole species still remained in the vulcanizate.