1、A comprehensive study on restoring properties in expired/aged ABS

This study explores advanced techniques for restoring aged ABS, including physical methods like reprocessing and thermal treatments, chemical restoration using solvents and additives, and mechanical enhancement through fibre or filler reinforcement.

2、ABS改性技术研究进展

With the ever increase of the downstream industry on the requirements of material performance, the ABS of high-performance, high functional modification get great development. The paper summarizes the development of ABS modified research at home and abroad, and introduces the research and development of new ftmctional ABS. FEWER

3、Advances in Research on ABS Resin

In this paper, the manufacturing techniques and preparation methods of ABS resin at home and abroad were summarized, and it points out that the continuous bulk polymerization method has advantages and will compete and coexist with the emulsion polymerization method for a long time.

4、Novel study on improvement of plastics properties by blending of waste

Many research attempts have been made to short out them. This investigation focuses on utilizing such micro plastic to produce cost effective ABS plasticproducts including toys manufacturing.

Advance in bulk polymerization technology of ABS resin

This paper reviewed the main technologies for producing bulk polymerized acrylonitrile -butadienestyrene copolymer (ABS) developed at home and abroad, and analyzed the respective features and maturity of each technology.

Summary of ABS Resin Modification

It is necessary to study the recycling of ABS because of environmental, economic and energy reasons. In this study, an ABS resin was processed using a torque rheometer at different temperatures and for different numbers of cycles. Pyrolysis gas chromatography mass spectrometry (Py-GC/MS) was ...

Effects of Reprocessing on Acrylonitrile–Butadiene–Styrene and

It is necessary to study the recycling of ABS because of environmental, economic and energy reasons. In this study, an ABS resin was processed using a torque rheometer at different temperatures and for different numbers of cycles.

ABS树脂生产工艺路线探讨

本文概述了目前国内外ABS树脂生产技术状况,介绍了国外主要ABS生产厂家的生产技术及工艺特点、生产ABS常用的间歇式乳液聚合法尤其是连续本体聚合法,简述了国内ABS基本生产技术,并对今后ABS生产发展动向作了初步预测。

Preparation and characterization of high‐impact ABS resin with

This research serves to improve and balance the mechanical properties and antistatic properties of ABS resins, overcome the inherent defects, and provide a comprehensive method to broaden the application scope of ABS, which has a vital role in various industrial applications.

Study on the Recycling of ABS Resins: Simulation of

Process ability, morphology, optical, and mechanical properties of acrylonitrilebutadiene- styrene (ABS) polymers were studied by simulation of its reprocessing and service life. A series of ABS samples were prepared by melt-mixing of SAN and g-ABS.

ABS Resin: An Overview ABS resin, short for acrylonitrile-butadiene-styrene copolymer, is a thermoplastic polymer widely used in engineering applications due to its excellent comprehensive properties. With advancements in technology and increasing environmental standards, modifying ABS resin has become a critical focus in materials science research. This paper explores international research progress in ABS resin modification, aiming to provide references and insights for domestic studies in related fields.

1. Purposes and Significance of ABS Resin Modification Although ABS resin exhibits superior mechanical properties, processability, and cost-effectiveness, its heat resistance, impact resistance, and chemical stability remain areas for improvement. Modifying ABS to enhance its overall performance is a key topic in modern materials science. Such modifications can expand its application range and improve usability, thereby meeting diverse industrial demands.

2. Key Research Directions in International ABS Modification

1. Reinforcement Modification International researchers commonly incorporate fillers such as glass fibers, carbon fibers, talc, and mica into ABS to improve its mechanical properties, heat resistance, and flame retardancy. These fillers effectively reduce brittleness, enhance impact resistance, and stabilize thermal performance.

2. Blending Modification Blending ABS with other plastics (e.g., PP, PE, PC) or rubbers (e.g., natural rubber, synthetic rubber) is a major approach to creating composite materials. Such blends significantly improve comprehensive properties, offering enhanced elasticity, wear resistance, and versatility.

3. Grafting Modification Grafting involves chemically bonding monomers onto ABS molecular chains to form graft copolymers. This method boosts heat resistance, chemical resistance, and weatherability. For instance, international studies have achieved a glass transition temperature increase of approximately 50°C through grafting.

4. Nano-Modification Nanotechnology introduces new possibilities for ABS modification. Incorporating nanoparticles (e.g., carbon nanotubes, graphene) into ABS creates reinforced networks that enhance mechanical strength, thermal stability, and electrical/thermal conductivity.

3. Trends and Challenges in International Modification Research

1. Green and Environmentally Friendly Modifications Growing global environmental awareness drives research toward low-VOC emissions and recyclable modification methods to minimize ecological impact.

2. Multifunctional Integration Future modifications will prioritize multifunctional materials, such as ABS variants combining high strength, heat resistance, and toughness, to meet complex application needs.

3. High-Performance and Smart Modifications Advancements in technology demand higher material performance. Researchers are exploring smart materials (e.g., self-healing, adaptive properties) to enable ABS use in extreme environments.

The modification of ABS resin is an interdisciplinary and continuously innovative process. International breakthroughs in modification technologies offer valuable experience and technical support for domestic research. With ongoing advancements in materials science, ABS and its modified derivatives are poised to contribute significantly to broader applications and socio-economic development.