Thermosetting Epoxy(热固性环氧树脂)研究综述
Thermosetting Epoxy 热固性环氧树脂 - A highly conductive hard core is constructed by incorporating Ag flakes and silver nanoparticle-decorated multiwalled carbon nanotubes in thermosetting epoxy (EP). [1] In this study, a Sn–Bi composite solder paste with thermosetting epoxy (TSEP Sn–Bi) was prepared by mixing Sn–Bi solder powder, flux, and epoxy system. [2] Adhesive matrices comprising a blend of a thermosetting epoxy and a thermoplastic polymer are selected becauseit has shown potential to ensure good electrical and mechanical integrity whilst still allowing reworkablity for ACA interconnects. [3] This work provides an effective way to disperse carbon nanotubes with small amount of thermoplastic PS to simultaneously strengthen and toughen the thermosetting epoxy while introducing highly conductive function. [4]通过在热固性环氧树脂 (EP) 中加入银薄片和银纳米颗粒装饰的多壁碳纳米管来构建高导电性硬核。 [1] 在这项研究中,通过混合 Sn-Bi 焊料粉末、助焊剂和环氧树脂体系,制备了一种具有热固性环氧树脂的 Sn-Bi 复合焊膏 (TSEP Sn-Bi)。 [2] 选择包含热固性环氧树脂和热塑性聚合物混合物的粘合剂基质,因为它已显示出确保良好电气和机械完整性的潜力,同时仍允许 ACA 互连的可再加工性。 [3] 这项工作提供了一种有效的方法来分散碳纳米管与少量热塑性PS,同时增强和增韧热固性环氧树脂,同时引入高导电功能。 [4]
Different Thermosetting Epoxy
Two different thermosetting epoxy materials were studied to recoat bare FBG and presented a specific packaging method for thermosetting coatings. [1] In this investigation, we use ReaxFF reactive force field molecular dynamics simulations to evaluate the disintegration of several different thermosetting epoxy polymers subjected to hypervelocity AO impact. [2]研究了两种不同的热固性环氧树脂材料来重涂裸 FBG,并提出了一种特定的热固性涂层封装方法。 [1] 在这项研究中,我们使用 ReaxFF 反应力场分子动力学模拟来评估几种不同的热固性环氧聚合物在超高速 AO 冲击下的分解。 [2]
thermosetting epoxy resin 热固性环氧树脂
The specimens consist of a hollow sphere foam core sandwiched between two mild steel sheets, bonded with a thermosetting epoxy resin. [1] Undoubtedly, 4D printing technology opens up a new portal for the manufacturing of thermoset epoxy composites and complex structures, which make the shape memory thermosetting epoxy resins and their composites possess excellent properties and good engineering application prospects. [2] The fatigue strength characteristics of CF/TP strands were discussed through comparison to those of CF/TS strands with thermosetting epoxy resin as the matrix. [3] During the reaction, C-N bonds formed by the crosslinking agent and the three-dimensional network structure of the thermosetting epoxy resin were destroyed. [4] Non-metallic components (NMC) in waste printed circuit boards (WPCBs) are made of the thermosetting epoxy resin and glass fiber, which has been a research concern in the waste recycling area. [5] AMWCNTs are introduced in thermosetting epoxy resin and then carbon fibers are reinforced in the matrix. [6] % of thermosetting epoxy resins. [7] In brief, the proposed process is based on the viscosity–temperature characteristics of the thermosetting epoxy resin (E-20). [8] Thermosetting epoxy resins largely rely on petrochemical bisphenol-type monomers, which give high performance materials but are controversial due to their effects on human health. [9] Finally, the relation between the failure probability and creep failure times for CF/TP strands at various loads and temperature conditions was discussed by comparing the result of CF/TS strands with those for thermosetting epoxy resin as the matrix. [10] As a promising application, the BNS was introduced into a thermosetting epoxy resin. [11] This study aims to investigate rheological and extrusion behavior of thermosetting epoxy resins, which to find the universal property and printing parameters for extrusion-based rapid prototyping applications. [12]样品由夹在两块低碳钢板之间的空心球泡沫芯组成,并用热固性环氧树脂粘合。 [1] 无疑,4D打印技术为热固性环氧复合材料和复杂结构的制造开辟了新的门户,使形状记忆热固性环氧树脂及其复合材料具有优异的性能和良好的工程应用前景。 [2] 通过与以热固性环氧树脂为基体的CF/TS 钢绞线进行比较,讨论了CF/TP 钢绞线的疲劳强度特性。 [3] 在反应过程中,交联剂形成的C-N键和热固性环氧树脂的三维网络结构被破坏。 [4] 废旧印刷电路板(WPCB)中的非金属元件(NMC)由热固性环氧树脂和玻璃纤维制成,一直是废旧回收领域的研究热点。 [5] 将 AMWCNTs 引入热固性环氧树脂中,然后在基体中增强碳纤维。 [6] %的热固性环氧树脂。 [7] 简而言之,所提出的工艺是基于热固性环氧树脂 (E-20) 的粘度-温度特性。 [8] 热固性环氧树脂主要依赖于石化双酚类单体,这种单体可以提供高性能材料,但由于其对人体健康的影响而存在争议。 [9] 最后,通过比较CF/TS绞线与热固性环氧树脂为基体的结果,讨论了CF/TP绞线在不同载荷和温度条件下的失效概率与蠕变失效时间之间的关系。 [10] 作为一种有前途的应用,BNS 被引入到热固性环氧树脂中。 [11] 本研究旨在研究热固性环氧树脂的流变学和挤出行为,从而找到基于挤出的快速成型应用的通用性能和印刷参数。 [12]
thermosetting epoxy polymer 热固性环氧聚合物
The incorporation of inorganic nanoparticles with thermosetting epoxy polymer is an emerging field of research over the past few years. [1] The incorporated of inorganic nanoparticles with thermosetting epoxy polymer are an emerging field of research over past few years. [2] In this investigation, we use ReaxFF reactive force field molecular dynamics simulations to evaluate the disintegration of several different thermosetting epoxy polymers subjected to hypervelocity AO impact. [3] An anhydride-cured thermosetting epoxy polymer has been modified by the addition of different wt% of silica nanoparticles, core–shell rubber particles and hybrids with equal wt% of both. [4] Hygroscopic aging causes swelling, degradation of mechanical and interfacial properties in thermosetting epoxy polymers, which eventually lead to a fast fracture at the interface in nanocomposite. [5]无机纳米粒子与热固性环氧聚合物的结合是过去几年的新兴研究领域。 [1] 无机纳米粒子与热固性环氧聚合物的结合是过去几年的新兴研究领域。 [2] 在这项研究中,我们使用 ReaxFF 反应力场分子动力学模拟来评估几种不同的热固性环氧聚合物在超高速 AO 冲击下的分解。 [3] 通过添加不同 wt% 的二氧化硅纳米颗粒、核壳橡胶颗粒和两者重量百分比相等的混合物,对酸酐固化的热固性环氧聚合物进行了改性。 [4] 吸湿老化导致热固性环氧聚合物的膨胀、机械性能和界面性能退化,最终导致纳米复合材料的界面快速断裂。 [5]
thermosetting epoxy matrix
The result shows that all the properties found to be increased with nano basalt content in the thermosetting epoxy matrix. [1] It was incorporated into thermosetting epoxy matrix at various weight fractions (0. [2] Improving the fracture and post-cracking toughness of carbon fiber-reinforced composites based on thermosetting epoxy matrices are of significant interest in a wide range of applications. [3] A polymer-fibrous layer is used to make a prepreg based on glass fibres with a thermosetting epoxy matrix. [4]结果表明,发现所有性能都随着热固性环氧树脂基体中纳米玄武岩的含量而增加。 [1] 它以不同的重量分数 (0. [2] 提高基于热固性环氧树脂基体的碳纤维增强复合材料的断裂和开裂后韧性在广泛的应用中具有重要意义。 [3] 聚合物纤维层用于制造基于玻璃纤维和热固性环氧树脂基体的预浸料。 [4]