1、Advances in Waterborne Acrylic Resins: Synthesis Principle
In this paper, we introduce the method to synthesize waterborne acrylic resins, the composition of the resin, and basic properties of each monomer.
2、Strengthening waterborne acrylic resin modified with trimethylolpropane
In this study, waterborne acrylic resin modified by TMPTA as cross-linker was successfully prepared by solution polymerization with other acrylic monomers as comonomers and benzoyl peroxide as initiator.
3、Waterborne acrylic resin co
Both KH570 and KH571 contain a carbon‑carbon double bond and can be used as comonomers to modify waterborne acrylic resin. Because of the high activity of silanol groups of alkoxysilane, premature hydrolysis and crosslinking reactions must be avoided to obtain stable latexes.
Advances in water
By analyzing the effect of substances such as fluorine and silicon on the water-resistance of waterborne acrylic resin, it is pretty clear that the principle of its modification of...
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.
Advances in water
In addition, waterborne resins have high water resistance requirements for coating applications, so it is crucial to prepare waterborne resins with high hydrophobicity by chemical modification.
Stable waterborne epoxy resins: Impact of toughening agents on coating
The CEB waterborne epoxy resins (CEBs) were synthesized through blending CA-4 with BPA at controlled ratios, followed by reaction with liquid epoxy resin. The research examined how the chain length in each CA influenced the properties of the resins, films and coatings.
Advances in Waterborne Acrylic Resins: Synthesis Principle
In this paper, we introduce the method to synthesize waterborne acrylic resins, the composition of the resin, and basic properties of each monomer.
Advances in Waterborne Acrylic Resins: Synthesis Principle
In this paper, we introduce the method to synthesize waterborne acrylic resins, the composition of the resin, and basic properties of each monomer.
Strengthening waterborne acrylic resin modified with
Two-component waterborne acrylic resin with enhanced mechanical properties modified by trimethylolpropane triacrylate (TMPTA) and N- (2-aminoethyl)-3-aminopropyl trimethoxysilane (KH792) was successfully prepared by solution polymerization, and the resin composites were prepared by using conductive carbon nanotubes (CNTs).
In modern industry, advancements in material science are driving progress across various sectors at an unprecedented pace. Among these, waterborne resins—an essential class of polymer materials—have seen expanding applications in automotive, construction, furniture, and other fields. CAB modification technology, as an innovative approach to enhancing the performance of waterborne resins, is increasingly becoming a focal point in the industry. This article explores CAB modification technology and its applications in waterborne resins.
1. What Is CAB Modification? CAB modification involves treating waterborne resins with specific chemical modifiers. These modifiers include carboxylates (e.g., acrylates), amino compounds (e.g., polyamines), and alkaline earth metal oxides (e.g., magnesium hydroxide, aluminum hydroxide). They react with the hydroxyl groups in the resin to form a stable cross-linked network structure, significantly improving properties such as water resistance, heat resistance, and mechanical strength.
2. Advantages of CAB Modification
- Enhanced Water Resistance: CAB-modified waterborne resins exhibit excellent water resistance, maintaining their physical and chemical properties in humid environments. This is critical for applications like automotive and marine coatings.
- Improved Mechanical Strength: The modified resins show markedly higher mechanical strength, enabling better resistance to external pressure and impact, thereby extending product lifespan.
- Thermal Stability: CAB modification enhances thermal stability, preventing degradation at high temperatures and ensuring durable, stable coatings.
- Optimized Electrical Insulation: For applications requiring electrical insulation, CAB modification improves the resin’s performance, reducing risks of leakage and short circuits.
- Environmental Benefits: This technology reduces reliance on hazardous substances, lowers environmental impact during production, and aligns with sustainable development goals.
3. Application Areas of CAB-Modified Resins
- Automotive Coatings: Used for interior/exterior components (e.g., auto paint, roof coatings) to enhance corrosion resistance, scratch resistance, and wear resistance.
- Marine Coatings: Improves salt spray resistance, humidity/heat resistance, and corrosion protection, prolonging vessel lifespan.
- Construction Coatings: Suitable for exterior wall paints and waterproof coatings, offering better adhesion, weather resistance, and stain resistance.
- Furniture Manufacturing: Employed as wood coatings or adhesives to boost durability and aesthetics.
- Electronics Industry: Used in encapsulation materials for improved electrical properties and thermal stability, meeting stringent requirements for electronic devices.
4. Development Trends in CAB Modification Technology As technology and societal awareness evolve, CAB modification continues to advance. Future innovations are expected to introduce more efficient, eco-friendly modifiers and processes to meet growing demand. Additionally, green and sustainable CAB modification will become a key industry focus amid rising environmental concerns.
CAB modification has revolutionized waterborne resins, unlocking their potential across industries. Through ongoing technological innovation and expanded applications, CAB-modified resins are poised to deliver greater value and progress for society.
