Company Filing History:
Years Active: 1997
Title: Philip James Morgan: Innovator in Flow Control Technology
Introduction
Philip James Morgan is a notable inventor based in Gales Ferry, Connecticut. He has made significant contributions to the field of flow control technology, particularly with his innovative designs that enhance the efficiency and functionality of flow control valves. His work is characterized by a deep understanding of thermal dynamics and material properties.
Latest Patents
Morgan holds a patent for a thermally responsive flow control valve. This invention features a valve body with a central flow passage that includes a poppet, which is releasably engageable with an annular valve seat. The poppet is designed with a head that interacts with the valve seat and contains a central bore filled with an expansion member made of silicone rubber or a similar material. This expansion member has a different coefficient of thermal expansion compared to the valve body, allowing for precise control of fluid flow based on temperature changes. The design includes a spring that pre-compresses the expansion member, balancing the forces created by thermal expansion. The valve is engineered to maintain a trickle flow at all times, ensuring that the expansion member remains at a temperature close to that of the fluid medium.
Career Highlights
Philip James Morgan is currently employed at The Lee Company, where he continues to develop innovative solutions in flow control technology. His expertise and inventive spirit have positioned him as a key player in the industry, contributing to advancements that improve operational efficiency in various applications.
Collaborations
Morgan collaborates with Leighton Lee, II, among others, to further enhance the development of flow control technologies. Their combined efforts have led to significant innovations that benefit the industry.
Conclusion
Philip James Morgan's contributions to flow control technology exemplify the impact of innovative thinking in engineering. His patent for a thermally responsive flow control valve showcases his ability to merge material science with practical applications, ultimately advancing the field.