1、Waterborne Epoxy/Acrylic Resins Stabilized through the Neutralization
In this work, a class of stable waterborne epoxy/acrylic resins with high performance is prepared through the simple blending of modified epoxy and acrylic copolymers.
2、Waterborne Epoxy/Acrylic Resins Stabilized through the Neutralization
In this study, we develop a strategy combining chemical and blending methods to prepare stable waterborne epoxy/acrylic resins. First, the bisphenol A-based epoxy is end-modified with ETA through the ring-opening reaction of the epoxide with the primary amine on ETA.
3、Preparation of acrylic resins modified with epoxy resins and their
The acrylic resin modified by bisphenol A epoxy resins (EP-MA-AR) shows significant enhancement over the acrylic resin without modification (AR) in adhesion between ink and polyethylene terephthalate (PET) film surface and as well water resistance performance.
4、Epoxy Additives and Polyamides
Ethylene and other amine are reacted with carboxylic acids to form very high molecular weight “non-reactive” polyamide resins that are further modified to provide varying degrees of “open time”, “green strength” and final adhesive strength to a wide variety of substrates.
Polymer Modification with Reactive Silicones
Both of these product types can easily be co-reacted with organic backbone based acrylate resins for modified properties. This UV cured acrylate system is the exception to the ultra-high elongation expected with silicone polymers. In these systems, typical elongations are under 25%.
Silicone Resins & Oligomers
These products have excellent compatibility with organic resins, so they can be used with organic resins as modifiers or as reactive diluents. They can also impart flexibility to coating which is curable due to the reaction with moisture under room temperature.
Silicone Modified Acrylic Resin
As one of the leading silicone modified acrylic resin manufacturers and suppliers in China, we warmly welcome you to buy cheap silicone modified acrylic resin made in China here from our factory.
Laromer® energy curable resins & reactive diluents
LAROMER LR 9023 An aromatic epoxy-modified acrylic resin. It can be used in energy curable resin formulation for coating applications, such as wood, wood products, paper, and plastic.
Acrylic Modified Organic Silicone Resin
The resin is made of silicone resin, acrylic resin and special silane intermediates by reaction. It is characterized by high hardness, good luster, good heat resistance, etc.
Amine modified special acrylate Factory
HU9453 is a reactive tertiary amine co-initiator. It can provide very fast surface cure to overcome the oxygen-inhibited problem when in combination with benzophenone type photoinitiator. It is suitable for paper varnish,screen and flexo printing, wood, plastic coatings and other fields.
In the vast realm of modern materials science, organic polymers are widely utilized across various fields due to their unique physical and chemical properties. Among these, acrylic resins—a crucial category of synthetic polymer materials—have attracted significant attention because of their excellent mechanical performance, chemical stability, and ease of processing. the presence of numerous polar groups in their molecular chains leads to poor water resistance, which limits their performance in specific applications. To overcome this limitation, organic amine-modified acrylic resins have emerged as an important research direction for enhancing the properties of traditional acrylic resins.
The research background of organic amine-modified acrylic resins originates from the growing demand for high-performance polymers. With advancements in technology, higher functional requirements for materials have arisen, particularly in aerospace, automotive manufacturing, electronics, and electrical industries, where stringent performance standards are imposed. Although conventional acrylic resins exhibit good overall properties, their subpar hydrolytic and chemical resistance performances struggle to meet the needs of high-end markets. By introducing organic amine compounds, it becomes possible to effectively improve the water resistance of acrylic resins, extending their lifespan and reliability under harsh environmental conditions.
The principle behind organic amine-modified acrylic resins lies in the ability of organic amine molecules to form hydrogen bonds or van der Waals interactions with polar groups on the acrylic resin chains. This reduces intermolecular forces, minimizes aggregation, and enhances the material's overall hydrophobicity. Additionally, the incorporation of organic amines through chemical bonding creates stable composites, further strengthening the materials' chemical corrosion resistance and mechanical properties.
In practical applications, organic amine-modified acrylic resins demonstrate superior performance. For instance, in coatings, these composites are widely used in marine paints and heavy-duty anticorrosion coatings due to their excellent water resistance and anticorrosion properties. In the electronics and electrical sectors, modified acrylic resins provide enhanced electrical insulation and aging resistance, meeting the specialized demands of electronic components. In aerospace, such materials withstand extreme environmental conditions—including high temperatures, pressures, and radiation levels—offering reliable protective layers for aircraft.
The preparation of organic amine-modified acrylic resins reflects a synergy of scientific exploration and technological innovation. First, suitable organic amines are selected as modifiers based on compatibility and modification efficacy. These amines are then introduced into the acrylic resin chains via copolymerization, grafting, or similar methods to form uniform composites. Finally, post-processing steps like thermal treatment or curing ensure stability and functionality.
Throughout research and application, continuous optimization of organic amine types and dosages aims to achieve optimal modification effects. In-depth analysis of microstructures and properties reveals modification mechanisms, providing theoretical guidance for further material design and application.
Studies on organic amine-modified acrylic resins not only advance materials science but also drive innovation and transformation in related industries. As technology matures and application fields expand, these high-performance composites will play increasingly vital roles in future development, contributing significantly to human progress.
