1、Terpene resin

Terpene resin | C69H51N5 | CID 168010184 - structure, chemical names, physical and chemical properties, classification, patents, literature, biological activities, safety/hazards/toxicity information, supplier lists, and more.

2、β

β-萜烯树脂（Terpene resin），又称萜烯树脂，CAS号9003-74-1，分子式C10H18，分子量138.25，密度0.98g/cm³，闪点240°C。

3、Terpene resin

Terpene resin (CAS 9003-74-1) information, including chemical properties, structure, melting point, boiling point, density, formula, molecular weight, uses, prices, suppliers, SDS and more, available at Chemicalbook.

Terpene Resin Granules Formulation Proportion Table

Introduction to the Terpene Resin Granules Formulation In this formulation, terpene resin serves as the primary ingredient, typically accounting for 60%-70% of the total granule weight.

Preparation of High

β‐Pinene is able to be polymerized to obtain terpene resin. Terpene resin is a non‐toxic polymer that is chemically inert to most substances and has a wide range of industrial applica.

萜烯树脂_化工百科

制法：萜烯树脂主要通过聚合反应制备而成，其中一种常见的方法是将萜烯和适量的交联剂在一定温度条件下进行反应，形成三维网状结构的聚合物。 应妥善保管萜烯树脂，避免与明火和高温接触。

What is Terpene Resin

Terpene resins build themselves from basic C5 isoprene units, which link in head-to-tail fashion and wrap into larger chains. Most commercial samples fall into the C10H16 or C15H24 bracket before they link and polymerize, so not every batch carries a single molecular formula.

Terpene resin T

Terpene resin is a linear polymer obtained by using turpentine as raw material, polymerized under a catalyst, and undergoing processes such as hydrolysis, acidolysis, water washing, filtration and distillation.

萜烯树脂

The technical standards are formulated and revised by customers’ requirement and us, if there are any changes, the latest specification will be executed and confirmed in the contract.

Terpene resin

Chemsrc provides Terpene resin (CAS#:9003-74-1) MSDS, density, melting point, boiling point, structure, formula, molecular weight etc. Articles of Terpene resin are included as well.

Comprehensive Formula Guide for Terpene Resin Granules

I. Introduction Terpene resin is a high-molecular-weight material synthesized from terpene compounds, exhibiting excellent physical and chemical properties. In industrial production, terpene resin granules serve as critical additives across diverse applications. This article presents a comprehensive guide to terpene resin granule formulations, providing researchers and engineers in relevant fields with valuable references.

II. Basic Components of Terpene Resin Granules

1. Terpene Resin: Formed via polymerization of terpene compounds, it boasts superior heat resistance, chemical corrosion resistance, wear resistance, and insulating properties.
2. Plasticizers: Enhance flexibility and malleability. Common options include phthalic anhydride, sebacic anhydride, and maleic anhydride.
3. Stabilizers: Prevent degradation or oxidation during production, improving quality and stability. Examples: stearates, naphthenates, and organotin compounds.
4. Fillers: Reduce costs while increasing strength and hardness. Typical fillers: calcium carbonate, talcum powder, and mica powder.
5. Coupling Agents: Strengthen adhesion between terpene resin and fillers, enhancing mechanical performance and wear resistance. Common choices: titanate coupling agents and aluminum ester coupling agents.
6. Antioxidants: Inhibit oxidative reactions at high temperatures, prolonging product lifespan. Examples: phenolic antioxidants and amine antioxidants.
7. Solvents: Dissolve terpene resin and additives to improve production efficiency. Frequently used solvents: toluene, xylene, and ethyl acetate.
8. Dispersants: Improve dispersion of terpene resin for better mixing. Options include polyamides and polyvinyl alcohol.

III. Preparation Process of Terpene Resin Granules

1. Material Preparation: Weigh terpene resin, plasticizers, stabilizers, fillers, coupling agents, antioxidants, solvents, and dispersants according to the formulation.
2. Mixing: Combine all ingredients in a mixer until homogeneous.
3. Grinding: Process the mixed materials through a grinder to eliminate agglomeration and refine particle size distribution.
4. Filtration: Remove excess particles and impurities via filtration.
5. Drying: Dry the filtered materials in an oven until moisture content meets specifications.
6. Cooling: Cool the dried materials to prevent temperature-induced quality issues.
7. Granulation: Form the cooled materials into granules of specified shape and size.
8. Packaging: Package the finished terpene resin granules for storage and use.

IV. Applications of Terpene Resin Granules

1. Coatings: Leverages strong adhesion and weather resistance for anti-corrosion, wear-resistant coatings, etc.
2. Adhesives: Offers high bonding strength and flexibility, serving as a primary component in wood adhesives, plastic adhesives, and more.
3. Sealants: Exhibits oil resistance and aging resistance, suitable for rubber gaskets, sealing rings, and other sealing materials.
4. Composites: Combines with other materials to create specialized composites, such as carbon fiber-reinforced or metal-matrix composites.
5. Electronic Encapsulation Materials: Utilizes electrical insulation and thermal stability for chip encapsulation, circuit board protection layers, etc.

As a high-performance material, terpene resin granules hold vast application potential. Through in-depth research and optimization of formulations, their performance can be further enhanced, and costs reduced, thereby meeting diverse industry demands.