Bio-Based Hyperbranched Toughener From Tannic Acid and Its Enhanced Solvent-Free Epoxy Resin with High Performance

It is essential to design economic and efficient tougheners to prepare high-performance epoxy resin;however,this has remained a huge challenge.Herein,an eco-friendly,low-cost,and facile-fabricated bio-based hyperbranched toughener,carboxylic acid-functionalized tannic acid(CATA),was successfully prepared and applicated to the preparation of solvent-free epoxy resins.The mechanical performance,morphology,structural characterization,and thermal characterization of toughened epoxy resin system were studied.The toughened epoxy resin system with only 1.0wt%CATA reached the highest impact strength,111%higher than the neat epoxy resin system.Notably,the tensile strength and elongation at break of toughened epoxy resin systems increased moderately with increasing CATA loading.Nonphase-separated hybrids with significant toughening effect were obtained.Additionally,the thermal stabilities of toughened epoxy resin systems decreased with increasing CATA loading.This study provides an eco-friendly,cost-effective,and facile approach for the preparation of high-performance,solvent-free epoxy resins with potential for practical applications in sealing integrated circuits and electrical devices fields.

Research on thermal insulation materials properties under HTHP conditions for deep oil and gas reservoir rock ITP-Coring

Deep oil and gas reservoirs are under high-temperature conditions,but traditional coring methods do not consider temperature-preserved measures and ignore the influence of temperature on rock porosity and permeability,resulting in distorted resource assessments.The development of in situ temperaturepreserved coring(ITP-Coring)technology for deep reservoir rock is urgent,and thermal insulation materials are key.Therefore,hollow glass microsphere/epoxy resin thermal insulation materials(HGM/EP materials)were proposed as thermal insulation materials.The materials properties under coupled hightemperature and high-pressure(HTHP)conditions were tested.The results indicated that high pressures led to HGM destruction and that the materials water absorption significantly increased;additionally,increasing temperature accelerated the process.High temperatures directly caused the thermal conductivity of the materials to increase;additionally,the thermal conduction and convection of water caused by high pressures led to an exponential increase in the thermal conductivity.High temperatures weakened the matrix,and high pressures destroyed the HGM,which resulted in a decrease in the tensile mechanical properties of the materials.The materials entered the high elastic state at 150℃,and the mechanical properties were weakened more obviously,while the pressure led to a significant effect when the water absorption was above 10%.Meanwhile,the tensile strength/strain were 13.62 MPa/1.3%and 6.09 MPa/0.86%at 100℃ and 100 MPa,respectively,which meet the application requirements of the self-designed coring device.Finally,K46-f40 and K46-f50 HGM/EP materials were proven to be suitable for ITP-Coring under coupled conditions below 100℃ and 100 MPa.To further improve the materials properties,the interface layer and EP matrix should be optimized.The results can provide references for the optimization and engineering application of materials and thus technical support for deep oil and gas resource development.

Influence of spacer insulator material temperature characteristics on its electric properties

Spacer insulators are important insulating component of gas insulated switchgear(GIS). In order to analyze the influence of spacer insulator materials temperature characteristics on the electric performance, we tested the temperature distribution under work condition and the temperature characteristics of the material's relative permittivity. Then established a spacer insulator simulation model in finite element numerical simulation software to calculate its temperature and electric field. Using the temperature test results as a reference to verify the temperature calculation, and in order to analyze changes of the electric field along the surface of the spacer insulator, the temperature characteristics of relative permittivity have to be considered. Through the experimental research and simulation analysis, we found that the temperature characteristics of the spacer insulator materials have great impacts on the spacer insulator performance. When the temperature increases, the material relative permittivity also increases. In the low-temperature region of spacer insulator, the electric field intensity along the surface increases, so the electrical performance deteriorates. The conclusion of this paper can provide an important reference for further research about spacer insulator's working performance analysis.

特高压GIL绝缘子用微米氧化铝-氧化硅共混环氧复合材料的性能研究

特高压气体绝缘金属封闭输电线路(GIL)电压等级高、输送容量大,对绝缘子耐受电、热、力综合作用能力的要求更高。本研究通过分别掺杂微米级氧化铝、氧化硅和氧化铝-氧化硅共混填料的方式制备了环氧复合材料,对共混体系力学、热学和电气性能等进行测试分析。结果表明:随着氧化铝填料体积占比的提高,复合材料的综合力学性能提升,微米氧化铝/环氧复合材料综合力学性能最佳。掺杂两种填料有助于提升共混体系的导热和耐电弧性能,但会略微降低玻璃化转变温度和增大热膨胀系数,当氧化铝和氧化硅填料体积比为1∶1时,复合材料的耐电弧时间可达186.63 s,导热系数可达1.198 W/(m·K)。随着氧化硅填料体积占比提高,环氧复合材料的介电常数减小,电气强度升高,体积电阻率增大,介质损耗减小。微米氧化硅/环氧复合材料工频电气强度最高,可达36.63 kV/mm。

Development of epoxy resin with superior breakdown strength:A Review

Epoxy resin(EP)has been widely utilized in electrical equipment and electronic devices due to its fascinating electric,thermal,and mechanical properties.However,the complex insulation structures of modern power devices in high-voltage direct current systems pose several challenges for EP-based dielectrics.The most significant among these challenges is the need for EP to stably operate under greater electric fields,requiring superior breakdown strength.This paper summarizes the key factors influencing the breakdown strength of EP and reviews reported methods for enhancing this property.Recognizing the limitations of existing approaches,we propose that the emerging technology of molecule design offers a potentially optimal solution for developing EP with enhanced breakdown strength.Furthermore,we anticipate the future development direction of EP with satisfactory insulation properties.We believe that enhancing the breakdown theory of solid dielectrics,exploring new research and development methodologies,and creating environmentally friendly EP with high performance are primary focus areas.We hope that this paper will offer guidance and support for the future development of EP with superior breakdown strength,proving valuable in advancing EP-based dielectrics.

SiO_(2)气凝胶/环氧树脂/酚醛树脂复合材料性能研究

为拓宽SiO_(2)气凝胶(SA)的应用领域,以E-51环氧树脂(EP)、SA作为添加剂,采用常压干燥法,逐次与酚醛树脂(PF)、环氧树脂/酚醛树脂材料(EP/PF)混合,制备出SiO_(2)气凝胶/环氧树脂/酚醛树脂(SA/EP/PF)复合材料,通过傅立叶变换红外光谱、比表面积、孔径及力学性能测试,研究了SA、EP对PF隔热性能、力学性能的影响。结果表明:环氧树脂嫁接到酚醛树脂分子中,可改善酚醛树脂的力学性能,当环氧树脂添加量为20%时,最大拉伸强度提高了66%,最大弯曲强度提高了62.5%;当SiO_(2)气凝胶添加比例为1%时,SiO_(2)气凝胶/环氧树脂/酚醛树脂复合材料的导热系数最小,低至0.3185W/(m·K),隔热性能相比酚醛树脂提升16.14%,为SiO_(2)气凝胶推广应用提供了理论依据。

纳米填料改性环氧树脂建筑保温材料的制备及性能研究

环氧树脂基混凝土作为一种绿色环保的建筑材料,在道路修补和保温建筑中应用广泛。以环氧树脂E44为原料,二甲苯为稀释剂,纳米玻璃纤维为填料,制备了复合环氧树脂基混凝土,研究了不同纳米玻璃纤维长度对混凝土微观形貌、力学性能和保温性能的影响。结果表明,纳米玻璃纤维的掺杂发挥了“晶种”作用,促进了水化反应的进行,提高了环氧树脂基混凝土的密实度。纳米玻璃纤维长度的适当增加提高了混凝土与纤维的结合强度,当纳米玻璃纤维长度为8 mm时,混凝土的形貌最佳。随着纳米玻璃纤维长度的增加,混凝土的抗压强度和抗折强度先增大后降低。养护28 d,当纳米玻璃纤维长度为8 mm时,混凝土的抗压强度和抗折强度均达到最大值,分别为21.93和4.59 MPa。纳米玻璃纤维的掺杂改善了混凝土的孔结构,降低了导热系数,提高了保温性能,当纳米玻璃纤维长度为8 mm时,混凝土导热系数最低为0.147 W/(m·K),保温性能最佳。

疏水CY184/E-PDMS环氧树脂复合材料的制备及性能

环氧树脂虽然具有良好的耐漏电流和抗击穿等电气性能和力学性能,但由于其本身缺乏疏水性,因此在户外绝缘子领域难以大范围应用。为了解决环氧树脂疏水差的问题,采用γ-氨丙基三乙氧基硅烷(APTES)、六氢邻苯二甲酸双缩水甘油酯(CY184)对羟基封端的聚二甲基硅氧烷(HPDMS)进行改性,合成了含有环氧基团的疏水改性剂E-PDMS,并制备了CY184/E-PDMS复合材料。结果表明,接枝了环氧基团的E-PDMS与CY184相容性良好,当E-PDMS质量分数达到10%时,复合材料水接触角能稳定在105°,呈现疏水性;体积电阻率提升至1.36×10^(14)Ω·m,介电常数在1000 Hz下降低至3.55,玻璃化转变温度和拉伸强度分别提升至117℃和59.4 MPa。经过E-PDMS改性后,CY184环氧树脂的疏水性、绝缘性、力学性能、热稳定性等均有明显提升,拓宽了CY184环氧树脂在绝缘子领域的应用。

球形氮化硼/环氧复合材料的制备及绝缘性能研究

针对常规片状氮化硼比表面积大,与环氧树脂复合时会急剧增大树脂黏度的问题,本研究制备了球形氮化硼,并将其作为填料与环氧树脂复合制备了球形氮化硼/环氧复合材料。研究了球形氮化硼/环氧复合材料的制备工艺和固化特性,对比研究了片状/球形氮化硼填料的形貌和填充量对环氧树脂复合材料力学性能和电学性能的影响规律。结果表明:随着反应温度升高,环氧树脂的固化度呈现“S”型曲线变化,整个固化过程可大致分为“慢-快-慢”3个阶段。力学性能方面,加入少量氮化硼可以提高环氧树脂复合材料的力学性能;高填充量时,球形氮化硼/环氧复合材料比片状氮化硼/环氧复合材料具有更优异的力学性能。电气性能方面,环氧树脂复合材料的相对介电常数随填料含量的增加而增大,介质损耗因数均低于0.02;与片状氮化硼/环氧复合材料相比,球形氮化硼/环氧复合材料的“填料-树脂”界面减少,具有更低的相对介电常数和介质损耗因数;添加适量的氮化硼能够显著提高复合材料的体积电阻率和电气强度。

机械应力影响环氧树脂绝缘电树枝劣化研究进展

环氧树脂凭借其优异的电气绝缘、耐热与机械性能以及良好的可塑性,被广泛应用于支撑绝缘子、绝缘拉杆等电气设备绝缘部件。随着电气设备电压等级的提高,环氧树脂绝缘部件运行工况日趋严苛,机械应力带来的绝缘失效问题更为突出。根据国内外参考文献,文中综述了机械应力下环氧树脂电树枝劣化引发绝缘击穿现象的研究进展。根据环氧树脂承受应力的不同,介绍了拉伸、压缩应力下电树枝生长的形貌特征,总结了温度工况下机械应力对电树枝生长的影响规律。基于环氧树脂分子链的物理微观结构与电荷输运特性,从能量角度探讨了绝缘材料在机械应力下的电树枝劣化机理。阐述了电气设备环氧绝缘部件的电树枝研究的关键问题与解决思路,为开发高绝缘性能的环氧树脂绝缘材料提供了参考。

固化制度调控双酚A环氧树脂/酸酐体系绝缘性能的研究进展

酸酐固化双酚-A环氧树脂由于其优异的绝缘、热学以及机械性能,被广泛应用于电气设备的支撑、绝缘和密封等关键部件。然而极端运行环境与紧凑化设计趋势下,环氧树脂绝缘经常发生过热和击穿故障,严重威胁电气设备的安全稳定运行。以环氧树脂体系原料混合比、固化时间与温度组合为核心的固化制度是决定环氧树脂微观结构的关键因素,也直接影响其宏观性能。本文介绍了酸酐固化双酚-A环氧树脂固化动力学模型的演变过程,研究结果表明双酚-A环氧树脂/酸酐体系需考虑前后固化过程分阶段拟合其动力学参数。基于不同的混合比以及固化时间和温度组合,重点论述了固化制度对双酚-A环氧树脂/酸酐体系绝缘性能的影响规律,讨论了固化状态相关微观结构对绝缘性能的调控机制。相关研究结果有望为高端电工环氧树脂应用提供配方选型和工艺优化等方面的参考。

咪唑-银修饰BN填充环氧树脂导热绝缘复合材料

环氧树脂(EP)已经广泛应用于电气绝缘材料,但其导热系数较低,越来越难以适应现代高功率密度电气设备的散热需求。本文在氮化硼(BN)表面沉积醋酸银(AgAc)和2-乙基-4-甲基咪唑(2E4MI)络合物,制备咪唑-银修饰BN杂化材料(Ag(2E4MI)_(2)Ac@BN),用其填充EP制得Ag(2E4MI)_(2)Ac@BN/EP复合材料,随后研究其导热性能。结果表明:当填料体积分数为20%时,Ag(2E4MI)_(2)Ac@BN/EP复合材料的导热系数为1.72 W/(m·K),比BN/EP复合材料的导热系数(0.96 W/(m·K))提高了79.2%。Monte Carlo法模拟表明:在EP基体中,Ag(2E4MI)_(2)Ac@BN的接触热阻R_(c)=2.7×10^(6)K/W,低于BN的R_(c)(5.5×10^(6)K/W)。与BN/EP复合材料相比,Ag(2E4MI)_(2)Ac@BN/EP复合材料的拉伸强度及介质损耗因数(tanδ)增加,电气强度及体积电阻率降低,但仍保持较高电绝缘性能。

环境友好型环氧树脂材料研究进展

环氧树脂具有优异的力学性能、热稳定性、化学稳定性和电气绝缘性,已被广泛应用于绝缘材料领域。稳定的三维交联网络结构在赋予环氧树脂优异性能的同时,也给其再加工、降解和回收带来巨大的难题。现阶段,越来越多的研究开始关注于环境友好型环氧树脂材料,以期解决再加工、降解等问题。本文综述了基于动态共价键环氧树脂的几种典型设计思路与方法,重点介绍引入酯键、二硫键、硅氧键、亚胺键、D-A结构、缩醛键、主-客体作用以及多重动态键构造环境友好型环氧树脂绝缘材料,同时,介绍动态键在特定刺激下使环氧树脂交联网络拓扑结构发生可逆改变,实现重塑、再加工、自修复和降解等功能,最后总结并展望基于动态共价键绝缘材料的应用前景。

基于亚胺键的环保型环氧树脂的制备与再生

为改善环氧树脂电气设备粉碎、填埋等不环保的处理方式的现状,以生物基香草醛与环氧氯丙烷合成单环氧化物,并与二胺固化剂固化原位形成亚胺键结构,得到生物基环保环氧绝缘材料。该生物基环保环氧树脂在0.3 mol/50 mL盐酸混合溶剂(甲醇与水的体积比为6∶4,80℃)时降解速度最快,在40 min内能完全降解。由0.5 mm粉碎颗粒在140℃、5 MPa压力下再生的环氧树脂玻璃化转变温度为114.86℃,击穿电场强度为44.08 kV/mm,性能保持率达到95%,并且可以在在弱酸环境中完全降解。退役后的环氧树脂粉碎为细小颗粒后,在高温高压的环境下能再生且性能良好。

动车组车顶环氧树脂绝缘子合模缝对闪络路径的影响分析

动车组车顶环氧绝缘子在注射成型过程中,伞裙表面沿竖直方向会出现两条合模缝,凸起的棱边会畸变其附近的电场。本文对动车组车顶环氧绝缘子在湿润工况下合模缝对闪络路径的影响进行研究,通过喷淋闪络试验,比较合模缝处与伞裙其他部位的闪络概率,观察水滴在环氧树脂伞裙表面的运动特性,并通过仿真分析合模缝对水带形成、电场强度和电流密度分布的影响。结果表明:在合模缝处容易形成闪络通道,且在电场的作用下,合模缝附近的水带会拉伸甚至桥接相邻伞裙。高压端伞裙表面合模缝处水带的电流密度比伞裙其他部位的水滴电流密度高1倍以上;桥接伞裙的水带会畸变局部电场,缩小爬电距离和增加单位爬电距离承担的电压值。

交变载荷下绝缘拉杆用GFRP电树枝劣化特性

气体绝缘组合电器(gas insulated switchgear,GIS)现场调试或运行过程多次发生绝缘拉杆内部击穿问题,影响工程投运与设备可靠性,迫切需要探明故障机理。该文选取GIS断路器绝缘拉杆用玻璃纤维增强环氧树脂复合材料(glass fiber reinforced epoxy resin composite,GFRP)为研究对象,通过计算分、合闸下绝缘拉杆主应力分布特性,设置交变载荷下电树枝劣化实验条件,研究不同交变载荷对GFRP内电树枝生长特性影响规律。结果表明,相较于单一载荷,交变载荷条件下GFRP中电树枝生长速度加快,平均击穿时间降低,击穿概率增大。基于复合材料力学仿真发现交变载荷下GFRP内树脂-纤维界面处会出现较大的应力集中,局部应力损伤已达到失效的临界值。综上,交变载荷下绝缘拉杆纤维-树脂界面机械损伤与绝缘劣化交互演进是造成绝缘击穿的主要原因,也可作为试验考核与结构设计的改进依据。

环氧树脂材料在铁路电力设备中的绝缘应用

铁路电力设备通常需要使用绝缘性良好的材料来保证设备的安全性和可靠性。环氧树脂材料是一种具有优良绝缘性能的材料,在铁路电力设备中得到了广泛应用。本文综合分析了环氧树脂材料的性能优势以及铁路电力设备所用环氧树脂配方体系,结合具体案例分析环氧树脂材料在铁路电力设备中的绝缘应用。

促进剂对绝缘子用环氧复合材料性能的影响

通过监测环氧体系固化反应速率、反应放热量、玻璃化转变温度,系统研究了促进剂比例对环氧体系固化反应的影响,提出了快速固化树脂配方开发及评价方法,为高压开关绝缘子成型效率提升提供参考。

500 kV直线塔复合绝缘子断串原因分析

运用外观检查、解剖检查、染料渗透试验、红外测温试验,对一起500 kV某线路72号直线塔复合绝缘子断串故障原因进行分析。结果表明,故障相绝缘子护套存在自身缺陷、密封不严等问题,导致其芯棒与外界空气、雨水等接触,在强电场、酸液、潮湿空气等长期作用下芯棒受腐蚀,进而造成复合绝缘子中承力作用的玻璃纤维在电化反应下断裂,绝缘子在导线自重等综合作用下断串。

模拟环氧树脂绝缘内部自然气泡的局部放电特性研究

在环氧树脂绝缘材料气隙中发生的局部放电(PD)现象是导致绝缘性能下降的关键因素,其检测与诊断对评估材料的绝缘状态至关重要。现有研究多集中于制备人工缺陷样品并以此探究局部放电现象,但对缺陷模型的现实符合性及局部放电与气隙尺寸的具体关系尚缺乏深入探讨。因此,本研究提出了一种模拟绝缘材料内部气隙缺陷的实用方法,并通过三种类型的传感器对局部放电进行测量,分析了气隙尺寸对放电过程的影响。运用快速傅里叶变换(FFT)对放电信号频率进行分析,揭示了放电幅度和频率与气隙大小之间的显著相关性。该研究结果不仅为理解环氧树脂材料内部气隙对局部放电特性的影响提供了新的视角,而且为绝缘材料的缺陷诊断和寿命预测提供了重要的理论依据。