Stephen Michael Addison

Title: The Innovative Contributions of Stephen Michael Addison

Introduction

Stephen Michael Addison is a notable inventor based in Huntsville, Alabama. He has made significant contributions to the field of fluid dynamics through his innovative designs. With a total of 2 patents, Addison has focused on developing devices that enhance the efficiency of fluid flow systems.

Latest Patents

Addison's latest patents include the "Antivortex device and method of assembling thereof" and the "Antivortex device for multi-outlet liquid reservoir." The first patent describes an antivortex device designed to suppress the formation of a vortex created by fluid flowing through multiple outlet ports defined in a sump. This device features a plurality of center plates extending through a central axis of the sump, an extension plate aligned with one of the center plates, and a top plate coupled to the center plates. The second patent outlines a liquid reservoir with a sump that includes at least two outlet ports in fluid communication with a fluid conduit. The anti-vortex device in this patent consists of a first plate extending across the outlet ports and a second plate that is perpendicular to the first, effectively disrupting vortex formation.

Career Highlights

Stephen Michael Addison is currently employed at The Boeing Company, where he applies his expertise in fluid dynamics to various projects. His work at Boeing has allowed him to contribute to advancements in aerospace technology, particularly in systems that require efficient fluid management.

Collaborations

Throughout his career, Addison has collaborated with talented individuals such as Gary David Grayson and Alfredo Lopez. These collaborations have fostered an environment of innovation and creativity, leading to the development of groundbreaking technologies.

Conclusion

Stephen Michael Addison's contributions to fluid dynamics through his patents and work at The Boeing Company highlight his role as an influential inventor. His innovative designs continue to impact the efficiency of fluid flow systems in various applications.