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.

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.

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.

The effect of urea pretreatment on the formaldehyde emission and properties of straw particleboard

For manufacturing low-formaldehyde emission particleboard from wheat straw and urea-formaldehyde （UF） resins using urea treatment for indoor environments, we investigated the influence of urea treatment on the formaldehyde emission, physical and mechanical properties of the manufactured particleboard. Wheat straws were treated at three levels of urea concentration （5%, 10%, 15%） and 95℃ as holding temperature. Wheat straw particleboards were manufactured using hot press at 180℃ and 3 MPa with two types of UF adhesive （UF-45, UF-91）. Then the formaldehyde emission values, physical properties and mechanical properties were considered. The results show that the for- maldehyde emission value was decreased by increasing urea concentration. Furthermore, the results indicate that the specimens under urea treatment have better mechanical and physical properties compared with control specimens. Also specimens under urea treatment at 10% concentration and UF-91 type adhesive have the most optimum physical and mechanical strength.

胶合板用铝-磷-硼三系无机阻燃剂复合MUF胶黏剂的增强改性研究

以氢氧化铝、聚磷酸铵、硼酸锌为原料优选铝-磷-硼三系无机阻燃剂(Al-P-B)加入三聚氰胺改性脲醛树脂胶黏剂(MUF)中,并采用血粉(BP)进行增强改性,探讨其制备阻燃胶合板的可行性。研究结果表明,当MUF、Al-P-B、BP、小麦粉、氯化铵溶液(NH_(4)Cl)的质量份数比为100∶30∶2∶30∶0.5、单面涂胶量为250 g/m^(2)时,制得的阻燃胶合板的Ⅲ类胶合强度达1.31 MPa,燃烧性能等级达到GB/T 18101—2013《难燃胶合板》规定的B_(1)(C)级,甲醛释放量(干燥器法)为0.25 mg/L,符合Q/YFL 0030—2021《木质板材及其制品中甲醛释放限量》E_(0)级的要求。

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。

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。

UFC和大豆蛋白制备环保脲醛树脂

采用脲醛预缩液(UFC)制备甲醛和尿素物质的量之比为1.3∶1的脲醛树脂,并在"碱-酸-碱"制备工艺的3个阶段分别加入大豆蛋白(SPI)降解液进行改性。对改性后脲醛树脂的性能进行对比分析,并借助核磁共振(13C-NMR)和动态热机械性能(DMA)分析改性后脲醛树脂的结构特征及热机械性能。结果表明,与普通脲醛树脂相比,UFC制备脲醛树脂的胶合强度提高了16%,游离甲醛降低了33%;而采用UFC和SPI降解液制备脲醛树脂,树脂胶合强度变化不大,当SPI降解液加入量为10%时,其游离甲醛可降低50%。13C-NMR分析表明,在第3个阶段加入SPI降解液,可以降低脲醛树脂中的醚键含量并提高桥键含量,使树脂具有较高的交联度和较低的游离甲醛。DMA测试结果表明,在第3个阶段加入SPI降解液所制备的脲醛树脂具有较高的热机械性能和热稳定性。

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。

UF/石蜡储能微胶囊的制备与表征

以石蜡为囊芯,尿素-甲醛树脂为囊壁,运用原位聚合法合成相变储能微胶囊材料.采用光学显微镜观察微胶囊形成过程,扫描电子显微镜观察微胶囊的表面形貌和壁厚,用红外光谱仪表征微胶囊的化学成分,用差示扫描量热仪研究微胶束相变储能性能.研究表明,脲醛树脂可有效包覆石蜡,形成粒径分布均匀的相变储能微胶囊,该材料具有储能效果,可用于设计储能建筑材料.

纳米碳酸钙影响UF树脂性能的研究

实验对纳米CaCO3对UF树脂固化时间,游离甲醛含量及胶合强度的影响进行研究,结果表明:纳米CaCO3延长了树脂的固化时间,游离甲醛含量随加入量的增加而逐渐减少,纳米CaCO3对胶合板的胶合强度贡献不大。

UF微胶囊合成反应的动力学研究

以脲醛树脂(urea-formaldehyde,UF)为囊壁,双酚A型环氧树脂E-51为囊芯,采用原位聚合法合成UF环氧树脂微胶囊.根据化学反应动力学,得到脲醛树脂预聚体及微胶囊囊壁合成反应过程中的速率方程.测定不同温度下甲醛浓度随时间变化的曲线,确定不同温度下的速率常数k和反应级数;应用最小二乘法对实验k与温度T进行回归,计算出化学反应活化能E.研究反应温度、甲醛和尿素物质的量比对反应速率的影响,对脲醛树脂/环氧树脂微胶囊反应条件进行优化.

超支化聚合物改性UF的研究(I):聚酰胺-胺添加方式对UF性能的影响

以PAMAMs(聚酰胺-胺)超支化聚合物作为UF(脲醛树脂)的改性剂,考察了PAMAMs的添加方式对UF的黏度、固含量、固化时间、固化特性、游离甲醛含量、树脂结构及所制备板材力学强度的影响。研究结果表明:当PAMAMs在缩聚阶段加入时,改性UF的性能相对最好,其黏度下降了1.1 s、固含量增加了3.2%且固化时间缩短了39.1 s,但改性前后游离甲醛含量变化不大;该改性UF的固化速率提高、最大弹性模量增加和固化温度有所下降,并且其结构得到优化,即亚甲基桥键比例增加了86.98%、亚甲基醚键比例下降了29.82%和二羟甲基脲比例提高了1.98%;由该改性UF胶粘剂制备的刨花板,其内结合强度提高了44.9%。

三聚氰胺草酸盐与氯化铵作为UF固化剂的性能对比

以三聚氰胺草酸盐(MOX)和氯化铵分别作为脲醛树脂(UF)的固化剂,然后以相应的改性UF胶粘剂压制胶合板,并探讨了不同固化剂对UF的固化时间、胶合板的胶接强度和甲醛释放量等影响。结果表明:以MOX作为固化剂时,相应UF的固化速率相对较慢,由该改性UF胶粘剂压制而成的胶合板,其胶接强度相对较高,甲醛释放量略高于含氯化铵体系;含MOX固化剂的UF胶粘剂,其DSC曲线峰顶温度(86.22℃)和吸热量(51.14 J/mg)低于含氯化铵体系,并且含MOX体系的固化反应比较平稳。

单宁胶用PUF树脂的制备工艺与结构和交联性能关系的研究

提出了一种单宁胶用ＰＵＦ树脂的制备方法。用￣１３ＣＮＭＲ研究了制备条件对ＰＵＦ树脂组分、结构和交联性能的影响。压板试验表明ＰＵＦ树脂配制单宁胶时，只有折合甲醛值大于１０％（以栲胶固体计），压制的胶合板才能符合室外级板的强度要求。用ＤＳＣ研究了固化温度对该单宁胶固化程度的影响。

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%。

涂覆UF/纳米SiO_2的胶合板阻燃性能的研究

采用HC 2氧指数测定仪、HRR3热释放率测试系统,测定表面涂覆纳米SiO2改性脲醛树脂(UF/纳米SiO2)马尾松胶合板的阻燃性能 结果表明:随着纳米SiO2在脲醛树脂中加入量的增加,胶合板的氧指数显著增大,最高热释放率、2min总热释放量显著降低;纳米SiO2加入量超过脲醛树脂总量的3%以后,其氧指数、最高热释放率。

弱酸性条件起始合成MUF树脂工艺研究

为了开发一种新的在"弱酸—弱碱—弱酸—弱碱"条件下合成三聚氰胺-尿素-甲醛树脂(MUF)的工艺,对弱酸性条件下起始合成MUF工艺进行研究.探讨了在不同酸性阶段加入的三聚氰胺对脲醛树脂性能的影响,找出最佳的三聚氰胺改性脲醛树脂的合成工艺.在最佳工艺基础上,评价三聚氰胺用量对MUF树脂性能的影响以及对胶合板性能的影响,并对MUF树脂和普通脲醛树脂进行红外分析.结果证明:三聚氰胺在甲醛与尿素一次缩聚之后加入,对脲醛树脂改性效果最好,其胶合板湿剪切强度与甲醛释放量之间达到较好平衡,胶合板甲醛释放量为0.63mg/L,湿剪切强度为1.03MPa.红外谱图分析表明:三聚氰胺分子以亚甲基与脲醛树脂分子链相连并有可能嵌入脲醛树脂分子链中,形成一定数量的醚键,使三聚氰胺在脲醛树脂中真正起到骨架作用.