Company Filing History:
Years Active: 2006
Title: **Innovator Spotlight: Robb M Lee**
Introduction:
Robb M Lee is an influential inventor based in Albuquerque, NM, recognized for his contributions to the field of microelectromechanical systems. With a focus on creating innovative solutions for real-world applications, Lee has made significant strides in the area of acceleration sensing.
Latest Patents:
Robb M Lee holds a patent for a **Microelectromechanical acceleration-sensing apparatus**. This advanced acceleration-sensing device includes a moveable shuttle, or a suspended mass, paired with a latch mechanism designed to capture and secure the shuttle when it detects an acceleration event that exceeds a predefined threshold. The innovation behind this apparatus lies in its ability to provide a switch closure upon sensing the event, which remains latched thereafter. This technology can respond to a single-direction acceleration or two opposing components, and includes a two-stage sensing capability to detect sequential events. Notably, this invention holds potential applications in automotive airbag deployment systems, enhancing safety measures in vehicles.
Career Highlights:
Currently, Robb M Lee is affiliated with Sandia Corporation, where he continues to push the boundaries of technological innovation. His singular patent exemplifies his commitment to advancing engineering solutions and reflects his expertise in the mechanics of acceleration sensing.
Collaborations:
During his career, Robb has collaborated with talented colleagues, including Randy J Shul and Marc A Polosky. Together, these inventors contribute their diverse knowledge and skills, fostering a creative environment that encourages groundbreaking work.
Conclusion:
Robb M Lee's innovative approach to microelectromechanical systems has not only resulted in impactful inventions but also signifies the important role of collaboration in engineering advancements. As he continues to develop technologies that enhance safety and functionality, his contributions will undoubtedly shape the future of acceleration-sensing applications.