1、Influence of hydrogenated petroleum resin on structure evolution and
Two polyethylene samples, one (PE-10) blended with 10% hydrogenated petroleum resin (HPR) and one (PE-0) blended without HPR, were used to investigate the structural evolution and deformation behavior during sequential biaxial stretch-ing and the properties of films after stretching.
2、Elucidating the chemical structures of petroleum resin using solid
In this research, both liquid- and solid-state 13 C NMR based on CP-TOSS/MAS method have been carried out to detect the chemical structural of petroleum resin.
3、(PDF) Hydrogenation Process for Producing Light Petroleum Resins as
The hydrogenation of petroleum resins (PRs) and the possibilities of using light hydrogenated PRs as components of hot-melt adhesives and pressure-sensitive adhesives have been surveyed.
4、Influence of hydrogenated petroleum resin on structure
Two polyethylene samples, one (PE-10) blended with 10% hydrogenated petroleum resin (HPR) and one (PE-0) blended without HPR, were used to investigate the structural evolution and deformation behavior during sequential biaxial stretching and the properties of films after stretching.
5、Petroleum Resin
Petroleum resin is term in common use for low molecular weight, about Mw 500–5,000, thermo-plastic hydrocarbon resins derived from cracked petroleum fractions.
Hydrogenated petroleum resin
Hydrogenated petroleum resin information, including chemical properties, structure, melting point, boiling point, density, formula, molecular weight, uses, prices, suppliers, SDS and more, available at Chemicalbook.
Hydrocarbon Resin
Resins have been classified in an almost arbitrary manner into hydrocarbons, petroleum resins, and phenolic resins. Hydrocarbon resins tend to have high glass transition temperatures so that at processing temperatures they melt, thereby allowing improvement in compound viscosity mold flow.
Influence of hydrogenated petroleum resin on structure evolution and
The influence of the hydrogenated petroleum resin P125 on the crystallization behavior, crystallization kinetics, and optical properties of polypropylene (PP) were investigated.
New advances in catalysts for C9 petroleum resin hydrogenation
C9 petroleum resin is a thermoplastic polymer produced by polymerization of C9 fraction obtaining from the steam cracking unit, and could be catalytic hydrogenated to remove the ethylenic C=C...
Petroleum resins, hydrogenated
Chemsrc provides Petroleum resins, hydrogenated (CAS#:71700-94-2) MSDS, density, melting point, boiling point, structure, formula, molecular weight etc. Articles of Petroleum resins, hydrogenated are included as well.
In today’s society, the petrochemical industry plays a critical role in global energy and economic development. as industrialization accelerates, issues such as environmental pollution, resource depletion, and energy crises have become increasingly prominent, prompting a reevaluation of traditional methods for producing and using petrochemical products. As an important chemical raw material, hydrogenated petroleum resin has attracted widespread attention due to its applications in industrial production and unique molecular structural characteristics. This article will delve into the molecular structure of hydrogenated petroleum resin, analyze its environmental impact, and explore future development trends.
Hydrogenated petroleum resin is a high-molecular-weight polymer formed by hydroprocessing long-chain hydrocarbons. This compound exhibits distinct physicochemical properties, enabling its widespread use in many industrial fields, including plastics, rubber, coatings, and adhesives. Its molecular structure primarily consists of saturated hydrocarbon groups linked by chemical bonds, forming a complex three-dimensional network.
The molecular structure of hydrogenated petroleum resin determines its unique performance. First, due to its highly saturated nature, it demonstrates excellent temperature resistance, chemical corrosion resistance, and mechanical strength. These properties allow it to maintain stability under harsh operating conditions, making it suitable for diverse industrial applications. Second, its high viscosity facilitates manufacturing processes. By controlling the conditions of the hydrogenation reaction, the molecular weight and molecular weight distribution of the resin can be precisely adjusted to meet the requirements of different products.
the production process of hydrogenated petroleum resin also raises environmental concerns. Large amounts of fossil fuels are consumed, resulting in significant greenhouse gas emissions and other pollutants. Additionally, recycling and reusing hydrogenated petroleum resin pose challenges. Its complex molecular structure makes effective recycling difficult, leading to resource waste and exacerbating environmental pollution.
To address these issues, scientists are exploring new synthesis methods and technological improvements. For example, substituting fossil fuels with biomass energy could reduce greenhouse gas emissions. Using biodegradable materials as raw materials may enhance recyclability and minimize environmental harm. Furthermore, developing novel catalysts and technologies could improve the recycling rate and reusability of hydrogenated petroleum resin, promoting sustainable resource utilization.
The future development of hydrogenated petroleum resin will prioritize environmental protection and sustainability. With growing environmental awareness and technological advancements, its production and applications are expected to expand. The development of new materials, such as incorporating nanotechnology and bio-based materials, could lead to next-generation hydrogenated petroleum resins with superior performance and better environmental adaptability.
hydrogenated petroleum resin, as a key chemical raw material, has garnered significant attention due to its industrial applications and molecular characteristics. Despite challenges in its production, ongoing technological innovations and improvements suggest a bright future. Future research will continue to explore its molecular properties and ways to better utilize and protect this valuable resource.
