1、Epoxy
The curing agents sold under the Baxxodur® trademark, such as polyether amines, aliphatic and cycloaliphatic amines, differ in molecular structure, basicity and number of functional groups.
2、环叙漆固化剂_百度百科
环叙漆固化剂curing agent for epoxy resin coatings供环氧漆用的、直接参加交联反应而结合在漆膜结构中的一类物质,可借以调节漆膜的性能、固化条件 (室温固化或加热固化)。
3、环氧树脂固化剂的常见类型及其固化机理
潜伏固化剂可与环氧树脂混合制成液态化合物,简化环氧树脂产品的应用,其应用范围从单一的包装胶粘剂向涂料、浸渍漆、灌封料、粉末涂料等多方面发展。
A critical review of dynamic bonds containing curing agents for epoxy
Particular emphasis is given to synthesis approaches and curing performances of intrinsically recyclable epoxy curing agents for the development of next-generation epoxy thermosets.
Epoxy Curing Agents
Clear and pigmented coatings based upon Amicure® IC curing agents exhibit very rapid hardness development, excellent low temperature cure, very good color and UV stability and excellent surface appearance.
Curing Agent: Types & Process of Curing Agents for Epoxy Resin
Explore the main types of curing agents & various crosslinking methods which help to improve the polymerization process to select the right curing agent for coating formulation.
Epikure Curing Agents
Epikure Curing agents by Hexion offer high performance and specialty curing solutions to a variety of epoxy resin formulations. Our extensive product line includes several high performance specialty curatives to meet difficult coatings requirements.
Epoxy Curing Agents: A Comprehensive Understanding of Their
Explore the basic knowledge of epoxy curing agents, including their classification, working principle, wide application in construction, electronics, automotive and other industries, as well as market trends and the latest developments of environmentally friendly products.
Epoxy Curing Agents
EPIKURE™ curing agents from Westlake Epoxy are used with our EPIKOTE TM epoxy resins and Heloxy TM reactive modifiers to meet a variety of application challenges.
The epoxy resin system: function and role of curing agents
Epoxy resins are frequently used in electrical devices, castings, packaging, adhesive, corrosion resistance, and dip coating. In the presence of curing agents, epoxy resins become rigid and infusible. Eco-friendliness and mechanical functionality have emerged as vulcanization properties.
In numerous fields of modern industry, materials science plays a pivotal role. Among them, epoxy resins, as a class of important high-performance materials, have their curing processes optimized, which decisively impacts the overall application outcomes. Epoxy curing agents, particularly hexamethyl ether, are critical components in the curing process of epoxy resins. They not only determine the mechanical properties of the materials but also influence their chemical resistance, heat resistance, and electrical properties. This paper aims to explore the significance of the hexamethyl ether curing agent and its role in practical applications.
The hexamethyl ether curing agent is a chemical substance used to promote the reaction of epoxy resins. By undergoing an addition reaction with the hydroxyl groups in the epoxy resin, it forms a stable three-dimensional network structure, thereby achieving the curing and hardening of the material. This curing process is the most critical step in epoxy resin applications, as it determines the final product's key properties, such as mechanical strength, wear resistance, and corrosion resistance.
Hexamethyl ether, as a commonly used epoxy curing agent, is favored for its good solubility and low volatility. In epoxy resin formulations, hexamethyl ether effectively promotes the polymerization reaction of the resin, accelerates the curing process, and simultaneously lowers the curing temperature, improving production efficiency. Additionally, hexamethyl ether exhibits excellent compatibility, allowing it to be mixed with various types of epoxy resins, thus broadening its application scope in specific fields.
the selection of epoxy curing agents is not static but must be optimized based on specific application scenarios and requirements. Different epoxy resin systems may require distinct curing agents to achieve optimal performance. For instance, in applications demanding high strength and hardness, hexamethyl ether may not be the best choice due to its relatively slower curing speed, potentially leading to subpar product performance. In such cases, other types of epoxy curing agents, such as aromatic or aliphatic acid anhydride curing agents, might be selected to achieve faster curing speeds and better performance.
Beyond choosing the appropriate epoxy curing agent, the formulation design of epoxy resins also significantly impacts their final properties. Factors such as the molecular weight of the epoxy resin, the type of functional groups, and the variety of additives directly affect the mechanical properties, thermal stability, and chemical resistance of the cured material. in practical applications, engineers must comprehensively consider various factors and adopt scientific formulation designs to achieve optimal performance.
The application prospects of the hexamethyl ether curing agent are vast. With advancements in technology and industrial development, the demand for high-performance materials continues to grow. Epoxy resins, as a critical composite material matrix, are expanding their application fields. From aerospace and automotive manufacturing to electronics, electrical equipment, and construction materials, all rely on the performance of epoxy resins and their curing agents. in-depth research into the properties and applications of the hexamethyl ether curing agent is of great significance for advancing materials science.
Looking ahead, research on epoxy curing agents will increasingly focus on environmental protection and sustainable development. As global awareness of environmental protection strengthens, reducing the use and emission of harmful substances has become an essential industry trend. Developing new eco-friendly epoxy curing agents, enhancing their biodegradability, or lowering the content of volatile organic compounds (VOCs) will be a key focus of future research. Meanwhile, exploring more curing agents with exceptional properties to meet the diverse needs of different fields and scenarios will also be a critical direction for scientific endeavors.
As a crucial component in the curing process of epoxy resins, the importance of the hexamethyl ether curing agent is unquestionable. By thoroughly understanding its properties and applications, combined with scientific formulation designs for epoxy resins, the comprehensive performance of materials can be effectively enhanced to meet modern society's demands for high-performance materials. Furthermore, prioritizing environmental sustainability and development will open broader prospects for the research, development, and application of epoxy curing agents.
