One-pot synthesis and structural characterization of urea-isobutyraldehyde-formaldehyde resin

Urea-isobutyraldehyde-formaldehyde (UIF) resin was synthesized from urea, isobutyraldehyde, and formaldehyde using sulfuric acid as a catalyst by one pot method. The effects of molar ratios of isobutyraldehyde to formaldehyde (n(I)/n(F)) and aldehyde to urea (n(A)/n(U)) on the yield, hydroxyl value (vs KOH) and softening point of the resin were investigated. The structure of the resin was characterized by FT-IR, 1H-NMR and 13C-NMR. The results show that when the molar ratio of urea to isobutyraldehyde to formaldehyde (n(U)/n(I)/n(F)) is 1.0/3.0/3.0, the yield UIF resin is 67.1%, and the softening point and hydroxyl value are 88 ℃ and 37 mg/g, respectively. The FT-IR, 1H-NMR and 13C-NMR results show that the lactam is formed by aminomethylation from urea, isobutyraldehyde, and formaldehyde.

Reaction Mechanism,Synthesis and Characterization of Urea-glyoxal(UG) Resin

The reaction mechanism of glyoxal （G） with urea （U） under weak acid condition was theoretically investigated at PW91/DNP/COSMO of quantum chemistry using density functional theory （DFT） method. The results show that the addition reaction of G with U under the conditions mainly involves the reactions of U with protonated glyoxal （p-G）, protonated 2,2-dihy- droxyacetaldehyde （p-G 1） and protonated bis-hemdiol （p-G2） to form two important carbocation reactive intermediates of C-p-UG and C-p-UG1, and two important hydroxyl compounds of UG and UG1. These compounds play important roles in the formation of UG resin. According to the result of quantum chemical calculation, UG resin was synthesized successfully under weak acid conditions. The UG resin was characterized by matrix assisted laser desorption ionization time of flight mass spectrometry （MALDI-TOF-MS）, ultraviolet and visible spectroscopy （UV-vis）, Fourier transform infrared spectroscopy （FT1R） and nuclear magnetic resonance spectroscopy （13CNMR and 1HNMR）. These instrumental analytical results agree with each other and further confirm the addition reaction pathway of glyoxal with urea proposed by quantum chemical calculation.

Factor Affecting Gel Time/Process-Ability of Urea Formaldehyde Resin Based Wood Adhesives

Urea-formaldehyde (UF) resin presents the most utilized adhesive system in the manufacture of plywood, particleboard and fiberboard. At the temperatures above 100°C in the presence of hardener, this resin undergoes cross-linking reaction and the formation of three dimensional cross linked structures takes place and bonding of wood particles in a hot press [1]. UF powder resins show high reactivity and good performance in the production and by their low price;however they lack in water resistance of the hardened resin [2]. Urea-formaldehyde (UF) resins are the most important type of adhesive resins for the production of wood based panels but process-ability and curing behavior of urea formaldehyde resin depended on various factors related to resin properties, types of wood and their properties, amount & type of catalyst, types and amount of polymers addition and environmental conditions [3]. This factor decides the process-ability of UF resin based composite during manufacturing of plywood, particle board and fiberboard. In this review paper, various factors affecting gel time and process-ability of UF resin based wood composite are reviewed.

A novel chain-extended urea containing hyperbranched polymer used as toughening modifier for epoxy resin

A new kind of reactive toughening accelerator for epoxy resin, amine-teminated hyperbranched polymer (H2O-NMe2) was synthesized and characterized by FT-IR spectroscopy. Dynamic mechanical analysis (DMA) was used to study the glass transition temperature (Tg), loss factor (tanδ) and activation energy (Ea) by using multiplexing frequency. The results show that the Ea at glassy relaxation process of modified system is about 70-80 kJ/mol higher than that of unmodified system, and the high modulus and good thermal properties are still maintained.

STUDIES ON IPE OF POLYACRYLAMIDE INVERSE EMULSION AND MODIFIDE UREA-FORMALDEHYDE RESIN

The selective water plugging agent was prepared by heating the blends of the polyacry-lamide inverse latex, modified urea formaldehyde resin, crosslinking agent and catalysts.The results show that using different types of polymers and additives or changing in theirproportion of the blends, the gelling viscosity, starting point of gelling and other propertiesof the IPN can be controlled.

Short Communication—A Novel Sample Preparation Method That Enables Ultrathin Sectioning of Urea-Formaldehyde Resin for Imaging by Transmission Electron Microscopy

Urea-formaldehyde (UF) resin is widely used as an adhesive for the manufacture of a range of wood and fiber based products. Although the microstructure of this resin has been examined at high resolution by field-emission scanning electron microscopy and atomic force microscopy, transmission electron microscopy (TEM) has thus far not been used, perhaps because of difficulties in ultrathin sectioning this resin in cured (polymerized) state. In the technical note presented here, a novel sample preparation method is described which enabled us to examine the microstructural morphology of UF resin by transmission electron microscopy in ultrathin sections, revealing the presence of spherical particles within the resin. Our initial attempt to ultrathin section the resin directly was not successful as it was too brittle to trim blocks for sectioning. Then, we developed a sample preparation technique that involved impregnation ofPinus radiatawood tissues with the UF resin, and then embedding of resin impregnated wood tissues with Spurr’s low viscosity embedding medium, which has been widely employed in plant and wood ultrastructure work. The TEM images illustrated and the information on the microstructural morphology of the UF resin presented are based on this novel sample preparation approach.

脲醛树脂包覆对片状羰基铁粉电磁吸波性能的影响

目的提高片状羰基铁粉(FCI)的吸波性能。方法采用原位聚合法制备脲醛树脂(UF)包覆片状羰基铁粉核壳复合粒子。通过透射电子显微镜(TEM)和X射线衍射仪(XRD)分别对试验前后样品的微观形貌和物相组分进行表征。采用矢量网络分析仪对处理前后片状羰基铁粉在0.5~18 GHz频率范围内的电磁参数进行测试,基于传输线理论对其反射损耗曲线进行拟合分析。结果微观形貌及X射线衍射谱结果表明,成功合成了脲醛树脂包覆片状羰基铁粉复合粒子(FCI@UF)。对测得的电磁参数进行分析,与原始片状羰基铁粉相比,包覆后铁粉介电常数和磁导率的实部、虚部均呈下降趋势,电磁波衰减能力减弱,与空气的阻抗匹配能力增强。反射损耗曲线图中,包覆后铁粉能有效吸收频带变宽(以反射损耗小于‒10 dB的带宽作为有效吸收频带),由3.15GHz变为4.38GHz,在13.84GHz时有最小反射损耗(‒20.64dB),最小反射损耗向高频移动,最小值降低率达41.38%。结论使用脲醛树脂对片状羰基铁粉进行包覆,制备了综合吸波性能更具优势的FCI@UF复合粒子,有效提高了片状羰基铁粉的吸波性能。

脲醛树脂前驱体碳微球形貌调控及电化学性能研究

为了探究原料配比对脲醛树脂形貌及碳微球电化学性能的影响,通过改变尿素、甲醛与甲酸的物质的量比,制备了三种不同微纳结构的脲醛树脂微球,再在氮气保护下800℃裂解,获得了相应的碳微球。采用上述脲醛树脂前驱体制备的花状碳纳米微球(NUFC-3)作为电极材料,在三电极体系中开展电化学性能研究。结果表明,在1 A/g的电流密度下,比电容(C_(s))为189 F/g;在20 A/g的电流密度下,C_(s)为145 F/g,其保留率为76.7%。该脲醛树脂为前驱体的碳微球具有制备方法简单、成本低廉及电化学性能优异等优点,有望在电化学储能领域获得应用。

异氰酸酯增强尿素-乙二醛树脂的结构与性能研究

为提升尿素-乙二醛树脂(UG)的耐水性能,本研究在UG树脂中添加高活性的异氰酸酯(MDI)共混制备了异氰酸酯/尿素-乙二醛(MDI-UG)木材胶黏剂。采用傅里叶变换红外光谱(FT-IR)、核磁共振波谱仪(NMR)和X射线光电子能谱(XPS)对其固化结构进行表征,通过差式扫描量热分析(DSC)、动态热机械分析(DMA)和扫描电镜(SEM)对其固化性能进行分析,以MDI-UG混合体系制备胶合板并测定其力学性能。结果表明UG树脂中含有的活泼氢基团与异氰酸酯反应形成新的氨基甲酸酯;与UG树脂相比,MDI-UG树脂的固化温度降低且热稳定性提高;采用扫描电镜下可观测到MDI-UG树脂的固化颗粒更加密集且交联支化程度明显提高;当MDI的添加量为3%且乙二醛与尿素的摩尔比为1.3:1时,所制得胶合板的热水湿状剪切强度达到0.72 MPa,表明MDI的引入显著改善了UG树脂的耐水性,而且充分发挥了UG树脂优异的环保性能和异氰酸酯的高强度特点。

低甲醛脲醛树脂基钢结构防火涂料的制备

本试验制备了一种低甲醛脲醛树脂基膨胀型钢结构防火涂料,探究了脲醛树脂加入量对防火涂料性能的影响,并分析其耐火机理。结果表明,在甲醛与尿素低摩尔比(0.8∶1)时,加入0.1%过氧化氢,制备低甲醛脲醛树脂,甲醛含量符合GB 18582-2020规定;加入脲醛树脂对膨胀型钢结构防火涂料的基本性能无影响,对涂层发泡性能和耐火性能影响显著,当脲醛树脂加入量在6%~10%时,涂层发泡厚度在3 cm以上,钢板背面温度在300℃以下,最低为271.9℃;脲醛树脂发生热解,分子链断裂产生大量阻燃气体,形成致密碳层,起到气源、碳源的作用。

钢琴桦木胶合板用的胶黏剂改性制备及性能

为提高钢琴桦木胶合板用胶黏剂的性能,以大豆粕或棉籽粕作为蛋白基,以尿素、制丝废水、水溶性PAE树脂作为改性材料,制备一种钢琴桦木胶合板用的黏胶材料,并对其性能进行测试。结果表明:与大豆粕作为蛋白基时相比,棉籽粕蛋白基黏胶材料的固含量、黏度得到改善,胶合强度较优;尿素可以使黏胶材料固含量、胶合强度提高,黏度减小,其中,尿素改性棉籽粕黏胶材料固含量为23.70%(质量分数),黏度为1 891 mPa·s,干胶合强度为1.308 MPa,湿胶合强度为0.525 MPa;当使用尿素和16%复合改性剂制备棉籽粕黏胶材料时,固含量为23.85%(质量分数),黏度为950 mPa·s,干、湿胶合强度分别为1.558、0.941 MPa,符合国标Ⅱ类胶合板标准,且热稳定性良好。综上,改性制备得到的胶黏剂可用于钢琴桦木胶合板,且具有一定的环保性。

尿素-乙二醛树脂改性大豆蛋白胶黏剂的制备及性能研究

以尿素-乙二醛(UG)树脂和大豆分离蛋白(SPI)为主要原料制备大豆蛋白胶(SUG),并对其固体含量、黏度、表面张力系数、接触角及胶合性能进行测试;利用XPS、FT-IR和^(13)C NMR对合成的SUG的结构进行表征;采用DSC及DMA对SUG的固化性能进行测定。研究结果表明:改性后大豆蛋白胶的固体含量、黏度、表面张力系数及接触角随着SPI添加量的增加而增大,其中黏度的变化最显著;合成大豆蛋白胶中主要含有C—C、C—O—C、C=O、C=N、C=O等官能团;结合^(13)C NMR及FT-IR分析结果,可以得出UG树脂与SPI二者之间产生了交联;当SPI用量为30 g,UG树脂用量为50 g时,制备的大豆蛋白基胶黏剂性能较佳且固化后储能模量较大,为4082 MPa,在160和180℃热压温度下制备的胶合板冷水24 h湿强度分别为1.23和1.48 MPa,热水3 h湿强度分别为1.05和1.22 MPa,远大于国家标准GB/T 9846—2015对II类胶合板的要求,且具备一定的耐沸水性能。

产红青霉菌对脲醛树脂的降解机制

[目的]每年有30多万吨脲醛用做树脂、粘合剂和绝缘材料,由于其降解持久性,此类物质废弃后对环境造成广泛的损害。本研究以产红青霉菌(Penicillium rubens 23229)为对象,研究其对脲醛树脂(UF)的降解过程和降解酶的性质。[方法]用X-射线衍射(XRD)和失重率评价P.rubens 23229及其酶的降解能力,通过液相-质谱联用(LC-MS)分析降解过程中间代谢产物,应用凝胶色谱柱对降解酶进行纯化。[结果]P.rubens 23229作用于UF,30 d后,材料失重率(降解率)为35%,结晶度由26.21%提升至29.44%,经计算得出,降解的35%包括UF结晶区7%,非结晶区28%;从菌种和脲醛共培养液中得到P.rubens 23229脲醛降解粗酶液,其最适作用温度为50℃,最适pH为4.0,LC-MS结果表明该粗酶液在降解过程中,首先将高分子UF主链降解,形成四甲基五脲、三甲基四脲等短链中间代谢物,然后进一步分解中间代谢产物为二氧化碳以及甲醛等终产物,降解作用位点包括脲醛主链中亚甲基与尿素间的C-N、酰胺键等。进一步对比了P.rubens 23229粗酶液与商业脲酶、蛋白酶对UF的降解能力,发现蛋白酶几乎无降解效果,脲酶有一定降解能力,但显著低于P.rubens 23229粗酶液。粗酶经纯化后降解效率提高28倍,凝胶渗透色谱(GPC)显示出分子量为6.89 kD和220.83 kD的2个峰,对应前面降解过程分析,说明降解过程包含主链降解酶和中间代谢物降解酶至少2种酶的复合体系共同发挥作用。[结论]P.rubens 23229脲醛降解酶由主链降解酶和中间代谢物降解酶共同组成,其中包含脲酶作用类似的酶,但降解主链的酶与已有蛋白酶作用方式不同,其具体的组成与性质有待于进一步研究。本研究对UF的生物降解具有一定的参考价值。

脲醛树脂包覆的环氧树脂微胶囊对树脂自修复性能的影响

将自制脲醛树脂包覆的环氧树脂微胶囊添加到环氧树脂基体中,制备了环氧树脂自修复复合材料。采用锥形双悬臂梁法分析了环氧树脂微胶囊的粒径、用量、制备方法对环氧树脂/环氧树脂微胶囊复合材料自修复效率的影响,观察了其自修复过程,揭示了自修复机理。结果表明:采用二步法制备的微胶囊,在微胶囊粒径为97~150μm,用量为15%(w)时,复合材料的自修复效率达到最大,为104.7%。

桐油微胶囊的制备及其自修复性能

采用吐温-20作为乳化剂成功合成以桐油为芯材、脲醛树脂为壁材的微胶囊;研究了乳化剂的含量、乳化转速和芯壁比对微胶囊表面形貌、粒径、壁厚和芯材含量的影响。最后,将微胶囊添加至环氧涂层进行红外、热稳定性、自愈性、电化学、附着力、耐水性测试,实验结果表明涂层表现出良好的自愈性能和耐水性;同时通过电化学分析发现,在添加质量分数10%微胶囊的环氧涂层的损伤区域,桐油在氧气的作用下聚合形成新的保护膜,表现出良好的物理阻隔性能。

脲醛树脂胶黏剂预压性能调控

脲醛树脂是我国人造板主要用胶,用于胶合板生产时,其施胶板坯的预压成型性能对胶合板加工过程至关重要,一定程度决定了板材生产效率。为保障人造板产品的环保性,低甲醛物质的量比环保型改性脲醛树脂被普遍采用,此类胶黏剂预压成型性不佳,需针对性探索预压性能高效提升技术。本研究提出通过在脲醛树脂分子结构中嵌入酚型物质实现胶黏剂预压性能调控的方法,探索酚型物质结构及添加量对脲醛树脂预压性能的贡献效果及贡献机制,并分析其对脲醛树脂性质及主要性能的影响。研究结果表明,酚型物质添加量小于1%即可有效改善脲醛树脂胶黏剂的预压性能,且胶黏剂预压性能随酚型物质中酚羟基含量增加而提升。1 h预压条件下,添加相同物质的量苯酚、邻苯二酚及邻苯三酚制备的改性脲醛树脂胶黏剂预压强度相对于UF(对照)分别提升44.74%,100.00%及113.16%。酚羟基与胶液组分间形成的氢键作用是脲醛树脂胶黏剂预压性能改善的主要原因。本研究为解决低甲醛物质的量比脲醛树脂预压成型性能差的问题提供了可行的科学基础及技术参考。

H-MMT对低物质的量比脲醛树脂胶粘剂性能的影响

将蒙脱土进行酸化处理,制备酸化蒙脱土(H-MMT)。随后在低物质的量比脲醛树脂合成体系中,加入制得的H-MMT,得到经H-MMT改性的脲醛树脂胶粘剂。通过控制加入H-MMT的投料比以及投放时间,探究其对脲醛树脂胶粘剂的黏度、固含率、游离甲醛含量以及胶接性能的影响。同时,对比分析了未改性脲醛树脂胶粘剂和H-MMT改性脲醛树脂胶粘剂的差异。研究结果表明:在脲醛树脂合成体系反应的第二阶段加入3%的H-MMT,改性脲醛树脂胶粘剂的性能最好,测得胶粘剂的游离甲醛含量为0.17%,固化时间为57.5 s,胶接强度为1.1 MPa;加入H-MMT的改性脲醛树脂胶粘剂中含有大量的醚键和羟甲基基团,可以提高胶粘剂的胶接性能;H-MMT改性的脲醛树脂胶粘剂中存在着未反应的残留尿素,进一步降低了体系的游离甲醛含量。

碳酸钙对三聚氰胺脲醛树脂胶黏剂性能的影响

三聚氰胺脲醛(MUF)树脂在我国的应用十分广泛。为了通过使用少量的改性剂对MUF树脂胶合强度和耐水性等方面起到较积极作用,利用200目(0.074mm)碳酸钙粉体作为MUF树脂的改性剂,采用普通脲醛树脂合成工艺制备改性MUF树脂,改性剂用量仅为树脂总质量的0.5%。测试各组树脂的理化性能,同时测试了使用树脂制备中密度纤维板的物理力学性能。结果表明:碳酸钙的加入显著提升了MUF树脂的黏度和固化时间;碳酸钙作为改性剂能显著提升MUF树脂制备纤维板的各项力学性能,其MOR提升超过15%,至39.23 MPa;改性MUF树脂制备板材的耐水性能也有所提升。

三聚氰胺-尿素-甲醛树脂浸渍改性对杉木压缩吸能特性的影响

采用质量分数为8%的三聚氰胺-尿素-甲醛(melamine-urea-formaldehyde resin,MUF)树脂溶液浸渍处理杉木(Cunninghamia lanceolata),通过准静态大变形压缩测试,考察杉木改性前后的压缩破坏模式、力学性能和压缩吸能特性等。结果表明:在改性材增重率为33.22%时,抗湿胀率达64.44%,尺寸稳定性得到改善;改性处理未影响杉木的压缩破坏形态,纵向主要为纤维屈曲和撕裂,径向主要为早晚材逐层压溃破坏,弦向主要呈火柴棍状破坏;改性材弹性模量和破坏强度提高,横纹平台应力显著增大,顺纹平台应力略有降低,致密化应变减小,纵向和横向之间的差异减小;改性材径向和弦向的单位体积吸能值分别增加了30%和17%,顺纹压缩吸能值及最大吸能效率则显著降低。低质量分数的MUF树脂浸渍处理可改善杉木的尺寸稳定性,缩小其纵向和横向之间的能量吸收差异。

化学堵水调剖剂DX-9研制及应用

在水平井开采中,边水或底水水窜问题严重,为穏油控水,提高采收率,介绍了一种可应用于水平井选择性堵水的化学堵水剂DX-9,研究该堵剂体系的性能以及影响因素。结果表明,选择性堵水剂DX-9具有固化时间可控、固化强度高且韧性强,最高突破压力梯度可达41.2 MPa/m,岩心封堵率可达99.23%,能够满足延长油田水平井选择性堵水应用。