1、Terpene derivative
The waterborne polyurethane prepared by this biobased silicone had excellent thermal insulation properties [22]. Transgenic soybean oil (TSBO) was combined with hydroxyl-terminated dimethyl silicone (HTMS) to prepare biobased silicone. This biobased silicone-modified polyurethane could be made into a coating with hydrophobic ability [36].
2、TERPENE RESINS IN PRESSURE SENSITIVE ADHESIVES
Over 17 years of experience in the pine chemistry-based industry with a focus on terpene resins and rosin resins for the adhesives market. Currently Senior Technology Leader, New Business Development at Arizona Chemical Company located in Savannah, GA. Started at Arizona Chemical as a product development chemist working in the area of terpene resins and continued primary technical focus in ...
3、The Chemistry of Tackifying Terpene Resins
Terpene Resins are low molecular weight hydrocar bon resins prepared by cationic polymerization of cer tain terpenes. They are used as tackifiers in pressure sensitive tapes, masking tapes, hot melt coatings and adhesives, laminating adhesives and rubber solution ad hesives. Terpene resins can be considered as solid sol vents for a rubber which function by solubilizing the smaller tack ...
4、Terpene Based Elastomers: Synthesis, Properties, and Applications
Dove et al. published their work recently with linalool-, nerol- and geraniol-based polyterpene resins [17]. The elastomer resins were produced using pentaerythritol tetrakis (3-mercaptopropionate) and an Irgacure 819 photo initiator, followed by postpolymerization treatments at various temperatures.
Terpene Resins
We offer high value-added terpene resins used as tackifiers for adhesives and modifiers for tread compounds for tires, rubber, and plastics. Suitable for pharmaceuticals, sealants, inks, paints, water-permeable asphalt pavement, etc.
TERPENE RESIN_化工百科
TERPENE RESIN - 简介 萜烯树脂是一种高分子化合物,具有以下特性: 物理性质:萜烯树脂通常为无色或淡黄色固体,具有良好的热稳定性和化学稳定性。 化学性质:萜烯树脂具有较好的溶解性,可以在一些有机溶剂中溶解,如丙酮、甲醇和二氯甲烷。
Silicone Modified Terpene Resin and It's Application
The terpene resin was subjected to hydrosilylation with trichlorosilane and dichloro-methylsilane to give a product with 42.6% silicone repeating units. It could be used to modify the surface of wollastonite and carbon black in the coatings for road marking and amino coatings.
Terpene Resins for Rubber
Terpene Resins are low molecular weight hydrocar bon resins prepared by cationic polymerization of cer tain terpenes. They are used as tackifiers in pressure sensitive tapes, masking tapes, hot melt coatings and adhesives, laminating adhesives and rubber solution ad hesives.
Silicone Resins and Intermediates Selection Guide
Silicone resins and resin intermediates have found utility in heat-resistant paint and industrial, marine and protective coatings (1950s); coil coatings (1970s); and, most recently, hybrid resin systems (1990s), creating interpenetrating silicone-organic resins with attributes of both chemistries for premium topcoat finishes.
Improving the Performance of Photoactive Terpene
Photocurable liquid formulations have been a key research focus for the preparation of mechanically robust and thermally stable networks. However, the development of renewable resins to replace petroleum-based commodities presents a great challenge in the field. From this perspective, we disclose the design of photoactive resins based on terpenes and itaconic acid, both potentially naturally ...
In the field of modern materials science, terpene resins and silicone resins stand out as two crucial synthetic polymers, each possessing unique chemical structures and physical properties that play pivotal roles in numerous industrial applications. This article aims to delve into the characteristics, uses, and significance of these resins in contemporary technological advancements.
Terpene Resins are high-molecular-weight materials synthesized through the polymerization of terpene compounds. Their molecular structures feature multiple carbon-carbon double bonds, endowing them with distinct physicochemical properties. Terpene resins exhibit excellent thermal stability, maintaining structural integrity and performance under high temperatures, which suits them for applications in harsh thermal environments. Additionally, their robust chemical resistance enables them to withstand corrosion from various chemicals, making them widely utilized in industries such as chemicals and petroleum.
Silicone Resins, primarily composed of siloxane molecules, boast a structure rich in silicon-oxygen tetrahedra. These resins are renowned for their superior heat resistance, electrical insulating properties, and mechanical strength—including high tensile strength and modulus—allowing them to perform reliably under extreme temperatures and pressures. Consequently, they find extensive use in aerospace, automotive manufacturing, and other high-performance sectors.
In practical applications, both resins demonstrate distinctive advantages. For instance, silicone resins are favored in electronic packaging due to their exceptional electrical insulation and thermal stability, while terpene resins are prized in coatings for their strong adhesion and flexibility.
challenges persist. The production of terpene resins is energy-intensive and involves complex processing, limiting their scalability. Silicone resins, while highly performant, entail higher manufacturing costs and may not fully replace traditional materials in certain contexts.
To address these hurdles, researchers are innovating. Efforts include optimizing production techniques to reduce terpene resin costs and leveraging silicone resins’ advantages to develop advanced composites tailored to specialized needs.
Looking ahead, terpene and silicone resins hold promise across diverse domains. In energy, they could enhance solar panel encapsulation; in healthcare, they might enable durable artificial joints and implants; and in environmental protection, they could aid in pollutant treatment.
terpene and silicone resins are indispensable in modern technology. Through sustained research and application development, these materials can overcome current limitations, drive further progress in materials science, and contribute significantly to societal advancement.
