1、Terpene Phenolic Resin

This is a resin obtained by copolymerization of the renewable material terpene monomer and phenol. By altering the phenol modification degree for each grade, we offer grades that are compatible with low to high polarity materials.

2、Research progress on modification of phenolic resin

In recent years, more and more researchers have focused on the discussion of the properties of modified phenolic resins and gradually ignored the research on the synthesis processes that can affect the molecular structure and properties of phenolic resins.

3、Polyterpene Resins

Polyterpene Resin (also called Terpene Polymer or Terpene Resin) is produced using only the renewable material mixed Terpene or Terpene monomer. It is known as a tackifying resin, which is highly compatible with various polymer materials such as polyolefins, SIS, natural rubber or styrene elastomer.

4、Terpene Phenol Resin 803L

Phenolic resin 803L is an irregularly shaped, light yellow transparent solid made from rosin as the basic raw material, modified with phenol, and subjected to other stability treatments.

TERPENE & MODIFIED TERPENE POLYMERS

Our products include modified resins, terpene based. derivatives, flavour & fragrance ingredients, and other biobased chemicals.

TPR

TPR-560 is a high softening point modified terpene phenolic resin, which is characterized by high and low temperature resistance. TPR-560 has super cohesive force and excellent viscosity retention on adhesive, and is commonly used in pressure sensitive adhesive and hot melt adhesive.

Baolin Chemical

Terpene resins are yellow flake form, softening point at 110°C, used for adhesive, rubber, coating, ink, anti-rust oil of package, chewing gum etc. Terpene resin is also called terpene polymer, softening point at 80°C, it's also known as tickifying resin for various types of adhesive, rubber etc.

Terpene Resins

We are the exclusive manufacturer of hydrogenated terpene phenolic resins. Furthermore, we offer resins with low to high softening points, and some of these resins are manufactured exclusively by Yasuhara Chemical.

A Novel Approach to the Development of Natural Resin‐Based Biopolymer

In this study, it was aimed to synthesize and model the natural terpene-rosin phenolic resin (TRPR) by (a) reacting terpene and resin acids together in a single step without predistillation and (b) using an environmentally friendly and reusable ion-exchange catalyst (Amberlyst15).

A comprehensive review on modified phenolic resin

Current research on PR modification emphasizes both physical methods, including filler enhancement and fiber reinforcement, and chemical methods, such as copolymerization, grafting, and cross‐linking.

In the vast realm of modern materials science, phenolic resin, as a traditional thermosetting resin matrix, has been widely utilized due to its excellent mechanical properties and chemical stability. with the advancement of technology and increasing demands for new materials, the limitations of conventional phenolic resins have become increasingly apparent, such as insufficient heat resistance and uneven mechanical performance. To overcome these constraints, modified phenolic terpene resin has emerged, combining the structural advantages of traditional phenolic resins with the superior properties of novel polymeric materials, opening new avenues in the development of materials science.

The preparation process of modified phenolic terpene resin is complex and meticulous. Initially, terpene compounds are extracted from natural plants. These organic compounds, rich in hydrocarbon structures, possess unique molecular architectures that endow the modified phenolic resin with distinct physical and chemical characteristics. Subsequently, terpene compounds are mixed with phenolic resin, undergoing chemical reactions to form an interpenetrating network structure. The incorporation of terpene compounds not only enhances the resin's heat resistance and mechanical strength but also improves its chemical resistance.

Modified phenolic terpene resin boasts a broad application range, spanning aerospace, automotive manufacturing, electronics, and more. In aerospace, this resin is used to fabricate aircraft engine components and spacecraft exteriors, maintaining structural integrity and performance stability under extreme conditions. In the automotive industry, it is employed in high-performance braking systems and critical transmission components, enhancing vehicle safety and fuel efficiency. In electronics, the resin serves as an insulation layer and packaging material for circuit boards, ensuring the long-term stable operation of devices.

The advantages of modified phenolic terpene resin lie in its unique combination of properties. Compared to traditional phenolic resins, it demonstrates significant improvements in heat resistance, mechanical strength, corrosion resistance, and electrical insulation. the addition of terpene compounds imparts better processing performance and reduced mold shrinkage, facilitating more convenient and cost-effective manufacturing processes.

challenges persist in the application of modified phenolic terpene resin. Cost remains a primary constraint, as the extraction and purification of terpene compounds are intricate and expensive. Additionally, its production process is relatively complex, requiring advanced equipment, which elevates manufacturing costs. reducing the cost and enhancing the market competitiveness of modified phenolic terpene resin represent crucial directions for future research.

Looking ahead, the research and application prospects of modified phenolic terpene resin are promising. With advancements in nanotechnology and bioengineering, innovative material solutions are expected to emerge. For instance, the introduction of nano-fillers could further improve mechanical and thermal properties, while bio-based materials may reduce environmental impact. Furthermore, the application of intelligent manufacturing technologies could enable precise control over production processes, enhancing efficiency and product quality.

As a novel high-performance material, modified phenolic terpene resin holds immense potential across various fields. Through continuous technological innovation and optimization, it is poised to play an increasingly vital role in advancing materials science and addressing societal needs.