1、C9石油树脂_百度百科

C9石油树脂是以裂解制乙烯装置的副产物C9馏分为主要原料，在催化剂存在下聚合，或将其与醛类、 芳烃、萜烯类化合物进行共聚合而制得的热塑性树脂。 它的分子质量一般小于 2 000，软化点小于 150 ℃，呈热塑性粘稠液体或固体。

2、C9 petroleum resins_化工百科

C9 petroleum resins - 简介 石油树脂是一种由石油中提取的天然或合成树脂。 它具有以下性质： 它在常温下通常是不溶于水的，但可溶于多种有机溶剂，并具有良好的粘附性。 化学性质：石油树脂是非极性物质，具有较好的耐化学性和耐氧化性。

3、C9 热聚石油树脂/C9 Thermal Hydrocarbon Resin

本产品用裂解C9原料,经热聚合生产制得,为黄色或淡黄色颗粒状固体,具有良好的热稳定性、相容性、耐水、耐酸碱。 900-C100 is made by cracked C9 through thermal polymerization. It is yellow or light yellow granular solid, with good heat stabi ty, solubility, water resistance and acid/alkaline ...

C9 petroleum resin

Chemsrc provides C9 petroleum resin (CAS#:68410-16-2) MSDS, density, melting point, boiling point, structure, formula, molecular weight etc. Articles of C9 petroleum resin are included as well.

Technical date sheet

C9 Petroleum resin is a kind of thermal plasticizing resin produced by C9 fraction, by-products of petroleum cracking, through pretreatment, polymerization and distillation; it is not a high polymer bat a low polymer with the molecular weight between 300-3000.

C9 resin

C9 resin information, including chemical properties, structure, melting point, boiling point, density, formula, molecular weight, uses, prices, suppliers, SDS and more, available at Chemicalbook.

Microsoft Word

C9 Hydrocarbon Resin T1211 (C9 Petroleum Resin T1211) is a low molecular weight thermoplastic aromatic resin produced from petroleum derived C9 fraction through thermal‐polymerization technique.

C9 Thermal Hydrocarbon Resin

C9 Thermal Hydrocarbon Resin specifications from Bohr Chemical - High-quality thermal polymerized resin for paint, rubber, adhesives, and printing ink industries. Technical specifications for PR and GML series grades with excellent heat stability and chemical resistance.

C9石油树脂H

C9热聚石油树脂是环型结构热塑性芳香族石油树脂，以裂解C9馏分为原料，通过加热聚合反应后，制得的黄色透明状固体。

C9石油樹脂:物化性質,結構性能,C9樹脂的原料,合成方法,熱

C9石油樹脂是以裂解制乙烯裝置的副產物C9餾分為主要原料，在催化劑存在下聚合，或將其與醛類、 芳烴、萜烯類化合物進行共聚合而製得的熱塑性樹脂。

On the vast stage of modern industry, materials science plays a pivotal role. Among various advanced materials, C9 resin stands out as a high-performance engineering plastic, renowned for its unique physical and chemical properties. Its widespread application across numerous fields underscores the critical importance of its melting temperature—a key indicator that not only determines the resin's performance but also directly impacts its effectiveness in practical use. This article aims to delve into the melting temperature of C9 resin, analyze its effects on performance, and provide practical recommendations to help engineers and researchers better understand and apply this essential parameter.

C9 resin is a high-performance engineering plastic distinguished by its excellent mechanical properties, wear resistance, and chemical stability. The melting temperature, defined as the point at which it transitions from a solid to a liquid state, is crucial for understanding the material's characteristics and selecting appropriate processing methods.

Firstly, the melting temperature of C9 resin is closely tied to its molecular structure. Variations in polymerization methods, additive types, and concentrations can lead to differences in melting points even within the same resin category. evaluating the melting temperature of C9 resin requires case-by-case analysis rather than generalized assumptions.

Secondly, the melting temperature directly influences the resin's performance. For instance, an excessively low melting temperature may cause issues such as mold sticking or material leakage during processing, compromising product quality and production efficiency. Conversely, an overly high melting temperature, while reducing viscosity, risks material degradation or burning, thereby affecting product integrity.

Additionally, environmental factors like temperature, pressure, and time exert significant influence on the melting temperature of C9 resin. In practice, maintaining stable performance necessitates precise control of melting temperature based on specific process requirements to achieve optimal results.

A comprehensive understanding of C9 resin's melting temperature also involves considering related factors, such as crystallinity, filler types and contents, and processing techniques. Adjusting these parameters can further optimize the resin's properties to meet diverse application demands.

In practical applications, selecting the appropriate C9 resin and melting temperature is vital. Engineers must align resin choices with product design and manufacturing processes while adapting melting temperatures to production and environmental conditions to ensure consistent and reliable quality.

Beyond these considerations, experimental methods, computational simulations, and data analysis can aid in determining and optimizing the melting temperature of C9 resin. These tools empower researchers and engineers to refine material performance and processing strategies.

the melting temperature of C9 resin is a complex yet critical parameter that governs both material behavior and production outcomes. By studying and applying this knowledge, we can leverage the unique properties of C9 resin to drive innovation and advancement in industrial technologies.