用于芳香胺和醇NMR对映体检测的松香基膦试剂的合成

以松香为原料通过三步反应高产率合成手性二醇3和手性单醇6,将它们用作手性助剂现场制备有机膦衍生试剂,分别对单官能团手性底物(单胺、单醇)和双官能团底物(双胺、双醇及氨基醇)进行衍生,通过31P NMR测定,其芳基底物非对映体衍生物的膦化学位移差异值(Δδp)在3.08～0.10之间,均能够在测定条件下实现对映体峰的基线分离.用于α-萘乙胺和1,1’-联二萘酚(BINOL)样品对映体过量值测定,相对误差小于±2%.     

氢化松香与HEMA酯化物自聚与共聚研究

用氢化松香(HR)与甲基丙烯酸-2-羟乙酯(HEMA)进行酯化反应,得到了酯化物(HRH),然后对其进行了在甲苯中的自由基自聚反应、以及与甲基丙烯酸甲酯(MMA)或与苯乙烯(St)的共聚反应,制备了自聚物和共聚物,用IR和核磁共振氢谱(1HNMR)对产物进行了表征,用综合热分析仪表征了产物的热稳定性和玻璃化转变温度.结果表明:成功合成了HRH自聚物(PolyHRH)、以及共聚物[Poly(HRH-co-St)和Poly(HRH-co-MMA)].产物的热稳定性顺序为:HRH>PolyHRH>Poly(HRH-co-St)>Poly(HRH-co-MMA).     

松香改性酚醛环氧树脂的固化物结构及性能表征

以自制的松香改性酚醛环氧树脂（RPAE）为对象,采用FT-IR跟踪了RPAE与三种固化剂4,4-二氨基二苯砜、邻苯二甲酸酐和聚酰胺的固化过程,得到了较佳的固化工艺,并在最佳工艺条件下对RPAE与三种固化剂组成的固化体系进行固化,并用FT-IR、TG等表征手段考察了固化物的结构和性能。研究发现,RPAE是一种耐热性和电绝缘性能优良的环氧树脂。     

丙烯酸松香蔗糖聚氨酯/聚丙烯酸酯IPN的合成与性能

丙烯酸松香蔗糖聚氨酯/聚丙烯酸酯IPN的合成与性能     

杂多酸催化松香裂解产物中非挥发性油成分分析

杂多酸 (HPA)可有效催化松香的裂解 ,其主产物为中性、非挥发性油状物。文章利用气相色谱 /质谱 (GC/MS)联用技术对该产物成分进行了分析 ,共分离出 67个峰 ;通过与数据库标准图谱进行对照 ,鉴定出了绝大部分化合物 ;其中 2 1种化合物含量较高 ,占油状物总含量的 88.2 3 % ,主要是由松香裂解和氧化产生的环烯烃、芳香烃和芳香酮等。     

导数光谱法测定歧化松香中树脂酸异构体

用紫外（UV）导数光谱法建立了同时测定歧化松香中五种树脂酸异构体的新方法。通过选择合适的求导阶数（n）、微分波长差（△λ）、扫描速度和定量方法,对不同批号的歧化松香中的主成分脱氢枞酸和微量组分枞酸、新枞酸、左旋海松酶及长叶松酸进行了测定（其中左旋海松酸和长叶松酸测定的是合量）,实验结果令人满意。该法可消除树脂酸各异构体及同系物的背景干扰,对迭加的树脂酸的检出和定量很有效。方法的平均回收率为99．0％,相对标准偏差小于0．2％。     

松香扩链双马来酰亚胺的合成与表征

双马来酰亚胺齐聚物;松香酯;松香扩链双马来酰亚胺的合成与表征     

聚合松香的制备及其含量测定

以工业松香为原料,用硫酸-无水氯化锌作催化剂制备聚合松香.在70℃下,用甲苯溶解松香(松香和甲苯的重量比为1∶1),加入n(H2SO4)∶n(ZnCl2)=0.6的催化剂,120℃温度聚合反应10 h和270℃减压蒸馏(200 Pa)的条件下,所得一级聚合松香的二聚松香的含量≥90.5%,软化点182℃,酸值150.6 mg KOH/g,收率≥74%;二级聚合的二聚松香的含量≥65%,软化点135℃,酸值157 mg KOH/g,收率≥95%.用GC-MS分离出二聚体中的14个异构体;通过测定松香单体和二聚体的相对校正因子,采用面积归一法测定产品二聚体的含量.     

Epoxy resins from rosin acids: synthesis and characterization

A series of multifunctional cycloaliphatic glycidyl ester and ether epoxy resins were synthesized by reaction of condensed rosin acid‐formaldehyde resins with epichlorohydrin. The chemical structure of the produced resins was determined by IR and ¹H‐NMR analysis. The molecular weight of the produced resins was determined by gel permeation chromatography (GPC). A series of poly‐ (amide‐imide) hardeners were prepared from condensation of Diels–Alder adducts of rosin acid‐maleic anhydride and acrylic acid with triethylene tetramine and pentaethylene hexamine. These amines were also condensed with Diels–Alder adducts of rosin ketones. The curing exotherms of the produced epoxy resins with poly(amide‐imide) hardeners were investigated. The data of mechanical properties, solvent and chemical resistance indicate the superior adhesion of the cured epoxy resins. Copyright © 2004 John Wiley & Sons, Ltd.     

UV-curing behavior and adhesion performance of polymeric photoinitiators blended with hydrogenated rosin epoxy methacrylate for UV-crosslinkable acrylic pressure sensitive adhesives

UV-crosslinkable polyacrylates were synthesized for use as pressure sensitive adhesives (PSAs). These polyacrylates acted as polymeric photoinitiators due to the benzophenone incorporated into their backbones. Hydrogenated rosin epoxy methacrylate (HREM; based on hydrogenated rosin and glycidyl methacrylate) was also synthesized as a tackifier, and blended at different levels with the synthesized, UV-crosslinkable polyacrylates for use as PSAs. The effect of the new tackifier, HREM, on the properties of the UV-crosslinkable PSAs was examined in comparison with the properties exhibited by PSA/hydrogenated rosin blends. The characteristics of these PSA/tackifier blends were examined by Fourier-transform infrared (FTIR) spectroscopy, differential scanning calorimetry (DSC) and an advanced rheometric expansion system (ARES). In addition, the adhesion performance of the PSA blends was investigated using probe tack tests. DSC and ARES revealed all the PSA blends with HREM or hydrogenated rosin to be miscible at the molecular level. The glass transition temperature (T_g) of HREM was −25.6 °C, which is lower than that of other commercially available rosin tackifiers. FTIR revealed changes in the relative concentration of benzophenone groups in the PSAs at 1580 cm⁻¹, which demonstrated that the crosslinking efficiency is proportional to the benzophenone content and UV dose, but decreases with increasing hydrogenated rosin content. However, the reduced crosslinking reaction efficiency was improved in the PSA/HREM blends due to the low T_g of HREM which only slightly increased the T_g of the PSA blends. Moreover, the relative initial decrease in the probe tack of the PSA/HREM blends was lower than that of the PSA/hydrogenated rosin blends after UV irradiation.