Company Filing History:
Years Active: 2011-2016
Title: The Innovations of Rhad Veazey
Introduction
Rhad Veazey is a notable inventor based in Paradise, Texas, who has made significant contributions to the field of optical sensor technology. With a total of four patents to his name, Veazey's work focuses on enhancing the capabilities of current sensing in electrical systems. His innovative approach combines optical technology with magnetic fields to provide accurate measurements of electrical currents.
Latest Patents
One of Veazey's latest patents is an optical sensor assembly designed for installation on a current-carrying cable. This assembly is capable of sensing the current flowing through the cable and provides an electrical output that indicates the current level. The technology employs a magnetic concentrator placed near the cable, which creates a magnetic field that represents the current. An optical current sensor, situated within this magnetic field, exposes a beam of polarized light to the field. The polarized light beam is rotated by the Faraday effect in accordance with the current in the cable. The degree of rotation is then analyzed and converted into electrical signals that accurately portray the current. These electrical signals can be further processed and evaluated to provide insights into the quality of the current in the cable.
Career Highlights
Throughout his career, Rhad Veazey has worked with several companies, including Optisense Network, Inc. and Gridview Optical Solutions LLC. His experience in these organizations has allowed him to refine his skills and contribute to advancements in optical sensor technology.
Collaborations
Veazey has collaborated with notable individuals in his field, including Joseph Yossi Harlev and Leonard Johnson. These partnerships have fostered innovation and have been instrumental in the development of his patented technologies.
Conclusion
Rhad Veazey's contributions to optical sensor technology demonstrate his commitment to innovation and excellence. His patents reflect a deep understanding of the interplay between light and magnetic fields, paving the way for advancements in current sensing technology.