1、Synthesis and Properties of Epoxy Resin Modified with Novel Reactive

In view of the above, in this paper, we present a modification of commercially available epoxy resin with epoxy-functional liquid polybutadienes obtained via conventional epoxidation reaction as well as catalytic hydrosilylation.

2、Synthesis and Properties of Epoxy Resin Modified with

In this work, the influence of the new epoxy-containing liquid rubber-based modifiers on the thermal and mechanical properties of the cured epoxy resins was investigated.

3、Preparation, properties and compound modification mechanism of

To improve the pavement performance of emulsified asphalt (EA) and reveal the compound modification mechanism of waterborne epoxy resin and styrene butadiene rubber latex (WER/SBR) to EA, the EA samples with different WER/SBR dosages were first prepared.

4、Rubber modified epoxy resins

As far as the author is aware, although one of the first curing agents employed in epoxy resin technology, it is rarely used in commercial applications in general and rubber modified formulations in particular.

5、The Study on the Effect of Waterborne Epoxy Resin Content on the

High-performance polymer-modified mixtures are essential for rapid pavement maintenance. We added waterborne epoxy resin (WER) at different dosages to styrene–butadiene rubber (SBR) to create a composite-modified micro-surfacing mixture.

Mechanical properties of epoxy resin composites modified

To improve toughness, crack resistance, and other mechanical properties of cured epoxy resins (EP), styrene-butadiene rubbers (SBR) with epoxy groups named as ESBR were fabricated by emulsion polymerization and directly blending with EP in form of latex to make EP/rubber composites.

Influence of Modified Epoxy Dian Resin on Properties of Nitrile

Adhesion of the modified NBR to glass fibers increases due to its modification with the epoxy resins, however this time the ED-24 is more efficient than ED-24 AK reaching ca. 50% increase comparing to ca. 20% improvement, respectively.

Journal of Applied Polymer Science

Abstract Diglycidyl ether of bisphenol A (DGEBA)-based epoxy resin was modified using liquid carboxyl-terminated poly (butadiene-co-acrylonitrile) (CTBN) rubber.

(PDF) Synthesis and Properties of Epoxy Resin Modified with Novel

In this work, the influence of the new epoxy-containing liquid rubber-based modifiers on the thermal and mechanical properties of the cured epoxy resins was investigated.

Mechanical behavior of liquid nitrile rubber

Quasi-static and dynamic experiments were carried out to examine the influence of liquid nitrile rubber (LNBR) on the compressive behavior of epoxy resin.

Epoxy Resin Modified Butadiene Rubber: Application and Prospects of a High-Performance Composite Material

In modern industry and construction, the performance of materials directly impacts product quality, functionality, and service life. Epoxy resin and butadiene rubber (BR) are two commonly used polymer materials, each prized for their unique chemical structures and exceptional physical properties. single-component materials often struggle to meet increasingly stringent engineering demands. Consequently, research and application of epoxy resin-modified butadiene rubber—a high-performance composite material—have become critical. This article explores the concept of this composite, its applications across various fields, and future development trends.

I. Concept of Epoxy Resin Modified Butadiene Rubber

Epoxy resin is a thermosetting polymer characterized by repeating epoxy groups, offering excellent adhesion, mechanical strength, electrical insulation, and corrosion resistance. Butadiene rubber, synthesized from butadiene monomers, boasts remarkable elasticity, oil resistance, and wear resistance. By combining epoxy resin with butadiene rubber through composite modification, a novel high-performance material—epoxy resin modified butadiene rubber (ERMBR)—emerges. This composite retains the advantageous properties of butadiene rubber while leveraging the cross-linking effects of epoxy resin to significantly enhance mechanical strength, thermal stability, and chemical resistance.

II. Application Fields of ERMBR

1. Construction Industry: ERMBR holds vast potential in construction, such as manufacturing high-strength window frames, curtain walls, flooring, and stairs. These materials improve building durability and safety while delivering superior waterproofing, sound insulation, and thermal performance, thereby enhancing living environments.

2. Automotive Industry: In vehicle manufacturing, ERMBR is used for critical components like engine parts, braking systems, and suspension systems. Its high strength, wear resistance, and corrosion resistance meet rigorous automotive standards, boosting vehicle performance and reducing production costs.

3. Electronics and Electrical Equipment: ERMBR plays a key role in electronics, serving as circuit board protective layers, heat sinks, and electromagnetic shielding materials. Its electrical insulation properties help minimize electromagnetic interference, ensuring device reliability.

4. Aerospace: In aerospace, ERMBR is employed for aircraft structural components and engine parts, where high strength, rigidity, and fatigue resistance are essential. This composite enhances flight performance and safety.

III. Future Development Trends of ERMBR

As technology advances and market demands grow, ERMBR’s evolution will focus on:

1. High Performance: Pushing boundaries in mechanical properties, thermal stability, temperature resistance, and chemical resistance to meet aerospace, new energy, and other advanced field requirements.

2. Environmental Sustainability: Emphasizing eco-friendly production processes, low-emission techniques, and recyclable materials to reduce environmental impact.

3. Smart Functionality: Integrating sensors and intelligent controls to monitor and regulate material properties in real-time, aligning with smart manufacturing and automation trends.

4. Multifunctionalization: Expanding capabilities beyond traditional performance metrics to include self-healing, shape-memory, and temperature-sensing features, broadening application scope.

Epoxy resin modified butadiene rubber, as a high-performance composite, showcases immense potential across construction, automotive, electronics, aerospace, and more. With ongoing technological innovation and market growth, ERMBR will continue leveraging its unique advantages to drive progress and development in human society.