1、Synthesis and characterization of polyurethane acrylate with bio

The study explores the impact of the ratio of bio-oil to polyethylene glycol on the properties of polyurethane resin. As the amount of bio-oil added increases, the molecular weight of polyurethane acrylate decreases.

2、A review of recent development in preparation and modification of

To meet the required specifications of WPU, researchers have developed various modification techniques aimed at improving WPU performance. This paper provides an overview of the preparation principles and methods for WPU.

3、Acrylonitrile Butadiene Styrene/Thermoplastic Polyurethane Blends for

Currently, the most extensively exploited filament materials for FDM are thermoplastic materials such as polylactic acid (PLA), acrylonitrile butadiene styrene (ABS), and polycarbonate (PC). There still exist a few types of polymer blend filaments being utilized nowadays.

4、Advances in Toughening Modification Methods for Epoxy Resins: A

This work provides a comprehensive review of the recent advancements in the toughening modification methods for epoxy resins.

5、Development and Characterization of Polyurethane and Acrylonitrile

The objective of this study was to enhance the rigidity characteristics of polyurethane by melt blending acrylonitrile butadiene styrene into polyurethane using a compatibilizer.

Development and Characterization of Polyurethane and Acrylonitrile

The objective of this study was to enhance the rigidity characteristics of polyurethane by melt blending acrylonitrile butadiene styrene into polyurethane using a compatibilizer.

水性聚氨酯的改性研究进展

水性聚氨酯涂料 (WPU)是一种新型的聚氨酯 (PU)材料,与传统的溶剂型聚氨酯涂料相比,由于具有无毒、不燃和无污染等诸多优点,因此成为聚氨酯化学技术中发展最迅速最具有活...

Compatibilizing and toughening of the styrene and acrylonitrile

This study presents the synthesis of a core-shell impact modifier, a copolymer of polybutadiene grafted with styrene and acrylonitrile (PBL-g-SAN), using emulsion polymerization to enhance the mechanical properties of SAN resin.

水性聚氨酯的改性及应用研究进展

介绍了水性聚氨酯的各种改性方法:内交联改性、外交联改性、自交联改性,丙烯酸酯、环氧树脂、有机硅改性,互穿聚合物网络 (IPN)改性以及蒙脱土复合插层改性等,对各种改性方法进行了对比,并对水性聚氨酯的国内应用现状进行了概述。

Improved Acrylonitrile Butadiene Styrene Resin with Butadiene

In the present study, butadiene-functionalized graphitic nanoplatelet (BfGN) was made with solid graphite and 1,3-butadiene, without the need for additional reactants or reactions. It is expected that the butadiene-functional groups at the edges of the BfGN enhance compatibility with other materials.

In the vast field of modern materials science, synthetic resins, as a critical class of polymeric materials, serve as a cornerstone for technological advancement and societal development due to their unique physicochemical properties and broad application prospects. Among these, acrylonitrile (Acrylonitrile, AN) resin has attracted significant attention because of its excellent mechanical properties, electrical insulation, and chemical resistance. Polyurethane (Polyurethane, PUR), known for its exceptional elasticity and wear resistance, has seen increasingly sophisticated modification techniques, bringing transformative improvements to traditional resins. This paper explores the potential applications of combining Acrylonitrile Resin (AN) with Polyurethane Modifications (PUM) and how this integration enhances performance.

Overview of Acrylonitrile Resin (AN)

Acrylonitrile resin, abbreviated as AN resin, is a thermosetting plastic polymerized from acrylonitrile monomers. It boasts strong mechanical strength, heat resistance, electrical insulation, and chemical resistance, making it widely used in electronics, automotive, and construction industries. its curing process typically requires high temperatures and catalysts, which poses limitations in shaping and processing.

Overview of Polyurethane Modifications (PUM)

Polyurethane Modifications (PUM) refer to composite materials obtained by modifying polyurethane through methods such as introducing polyurethane prepolymers or blending. PUM exhibits superior mechanical properties, high resilience, and excellent oil and solvent resistance, leading to widespread applications in sports equipment, footwear, and protective materials.

Integration of Acrylonitrile Resin (AN) and Polyurethane Modifications (PUM)

Combining AN resin with PUM leverages complementary advantages to create novel materials with exceptional comprehensive performance. This synergy retains AN’s mechanical strength and electrical insulation while enhancing flexibility, wear resistance, and service life through PUM’s elasticity and durability.

1. Enhanced Mechanical Performance: Adjusting the PUM ratio improves AN’s impact resistance and wear resistance, making it suitable for wear-prone components or high-impact applications.
2. Improved Heat and Chemical Resistance: PUM addition significantly boosts AN’s thermal stability and chemical resistance, maintaining performance in extreme conditions—e.g., stable electrical insulation and oil resistance at elevated temperatures.
3. Optimized Processing: Incorporating PUM simplifies AN’s processing by lowering curing temperatures, reducing energy consumption, and improving manufacturability.
4. Functional Innovations: The hybrid material enables specialized functions, such as self-healing properties or shape-memory effects in smart composites.

Practical Applications

In automotive manufacturing, AN resin is commonly used for lightweight yet strong body structures. To further reduce vehicle weight and improve fuel efficiency, researchers developed an AN-PUM composite. This material combines AN’s high strength with PUM’s toughness and wear resistance, allowing thinner yet durable panels. Additionally, the composite demonstrates long-term durability and environmental sustainability, aligning with green manufacturing trends.

The integration of Acrylonitrile Resin (AN) and Polyurethane Modifications (PUM) expands AN’s applicability and introduces new performance enhancements. This synergistic combination enables the development of high-performance materials tailored to diverse modern needs. With ongoing advancements in materials science, such hybrids are poised to drive innovation and breakthroughs in future applications.