Company Filing History:
Years Active: 2022-2024
Title: Innovations of Jorge Manuel Jardim Da Silva
Introduction
Jorge Manuel Jardim Da Silva is a notable inventor based in São Paulo, Brazil. He has made significant contributions to the field of polymer science, particularly in the area of polyethylene architecture. With a total of 2 patents, his work has advanced the understanding and application of ethylene-based polymers.
Latest Patents
One of his latest patents is titled "Method of controlling polyethylene architecture." This innovative method involves polymerizing ethylene with optional monomers to form an ethylene-based polymer. It focuses on controlling the degree of long chain branching (LCB) in the polymer, which ranges from 0.1 to 10 per 1000 carbon atoms in the polymer backbone, as measured by CNMR. The degree of LCB is adjusted by adding branched vinyl ester during the polymerization process.
Another significant patent is "Extrusion coating resin from tubular reactor." This method includes polymerizing ethylene in a tubular reactor without the use of a chain transfer agent. The polymerization process is characterized by specific delivery pressures and peak temperatures, which allow for the control of the molecular weight of the resulting polyethylene.
Career Highlights
Jorge is currently employed at Braskem S.A., a leading company in the production of thermoplastic resins. His work at Braskem has allowed him to apply his innovative ideas in a practical setting, contributing to the company's advancements in polymer technology.
Collaborations
Throughout his career, Jorge has collaborated with notable colleagues such as Eduardo José Dotti and Omar Wandir Renck. These collaborations have fostered a productive environment for innovation and development in polymer science.
Conclusion
Jorge Manuel Jardim Da Silva's contributions to the field of polymer science through his patents and work at Braskem S.A. highlight his role as a significant inventor in the industry. His innovative methods for controlling polyethylene architecture and extrusion processes continue to influence the development of advanced materials.