1、High

SiO 2 -TiO 2 -EP-POSS/EP copes with a variety of complex construction environments. The synthesis of water-based anti-corrosion coatings for complex construction environments (e.g. rusty, wet, and oily metal surfaces) is still challenging.

2、改性环氧树脂防腐复合涂层的研究进展

Three strategies for enhancing the anticorrosive properties of epoxy resin are introduced in this paper, namely nanoparticle modification, micro/nano container modification, and bio-based...

3、Shanxi Modified Epoxy Anti

In this study, we developed an anti-wear and corrosion-resistant coating by filling corrosion inhibitor-loaded graphene oxide nanoribbons to enhance the synergetic protective performance of epoxy resins.

4、Facile construction of hydrophobically modified epoxy

The properties of the coatings were adjusted by the addition amount ratio of TiO 2 nanoparticles to epoxy resin. The performance tests of water wetting, abrasion resistance, and corrosion resistance of the coatings were carried out.

5、Insights into the Development of Corrosion Protection Coatings

Comparable blends of epoxy and polyamide, epoxy and polyester, and epoxy/poly (vinyl alcohol) and epoxy/polyurethane have superior adhesion, wear, barrier, and anticorrosion properties due to the fine dispersion of nanocarbon and inorganic nanoparticles.

Fluorine‐phosphate copolymerization waterborne acrylic resin coating

Abstract The modified waterborne acrylic resin was synthesized successfully by emulsion polymerization with octafluoropentyl methacrylate and phosphate functional monomer as monomers, showing an improved anti-corrosion performance of the resin coating.

Facile construction of hydrophobically modified epoxy coatings with

The modified coating prepared under optimal conditions displays excellent abrasion resistance, self-cleaning and anti-corrosion performances.

Modified Epoxy Anti

Given the excellent bonding performance, high mechanical properties, and good corrosion resistance of epoxy resin, in this study, water-based modified epoxy resin was used as the anti-corrosion material to improve the anti-corrosion performance of oil well cement.

Research progress of modified epoxy resin anticorrosive composite coatings

Three strategies for enhancing the anticorrosive properties of epoxy resin are introduced in this paper, namely nanoparticle modification, micro/nano container modification, and bio-based...

Preparation of graphene oxide modified epoxy resin coating

The anti-corrosion performance of graphene oxide/epoxy resin coating was analyzed by origination potential (OCP), water contact angle, corrosion morphology and gas permeation rate.

Modified Resin Anti-Corrosion Coating Construction

In modern industrial and marine engineering, there is a high demand for material durability and anti-corrosion performance. Traditional metal surface treatment methods, while providing good mechanical protection, often fail to meet long-term corrosion resistance requirements in harsh environments, such as marine or chemically corrosive conditions. the development and application of new anti-corrosion coating materials have become critical to extending equipment lifespan and ensuring safe operation.

Modified resin anti-corrosion coatings, as emerging materials, have gained attention due to their excellent corrosion resistance and mechanical properties. These coatings typically consist of modified resins combined with various additives, applied to metal surfaces using specialized processes to form a protective film.

I. Composition and Characteristics of Modified Resins

Modified resins are synthetic resins enhanced with functional additives that impart specific physical and chemical properties. Common types include epoxy, phenolic, and polyurethane resins. These materials often feature high molecular weights and thermal stability, enabling them to withstand demanding environmental and operational conditions.

II. Preparation Process for Anti-Corrosion Coatings

1. Surface Pretreatment: Cleanliness of the metal surface is fundamental to coating adhesion. Methods such as sandblasting, acid washing, alkali washing, or ultrasonic cleaning are used to remove oil, rust, and contaminants.

2. Primer Application: A primer layer improves adhesion and protection. The choice of primer (e.g., epoxy zinc-rich primer, polyurethane primer) depends on the substrate and desired coating properties.

3. Topcoat Application: The main anti-corrosion layer, formulated from modified resins, fillers, pigments, and curing agents, determines the coating’s performance.

4. Finish Coat Application: A finish coat enhances wear resistance and aesthetics. Compatibility with the substrate, color, and gloss are key considerations.

5. Curing and Drying: Curing involves complex chemical reactions under controlled temperature and humidity. Full drying ensures optimal adhesion and durability.

III. Applications of Modified Resin Anti-Corrosion Coatings

These coatings are widely used in marine engineering, petrochemicals, power equipment, and railway bridges. In these fields, traditional metal treatments often fall short in complex environments. Modified resin coatings provide effective protection, extend equipment lifespan, and reduce maintenance costs.

Advances in materials science have introduced innovations such as nanomaterials, antibacterial agents, and UV-resistant additives, enabling self-cleaning, antimicrobial, and weathering-resistant properties. Additionally, environmentally friendly formulations like low-VOC and solvent-free coatings align with growing eco-conscious demands.

Modified resin anti-corrosion coatings offer highly efficient protection for modern industry and marine engineering due to their superior corrosion resistance and mechanical strength. Ongoing technological innovations will likely lead to the development of even more advanced anti-corrosion coatings, further contributing to human progress.