Company Filing History:
Years Active: 2004-2019
Title: Scott McClelland: Innovator in Gas Mixing and Semiconductor Technologies
Introduction
Scott McClelland is a notable inventor based in San Jose, California. He has made significant contributions to the fields of gas mixing and semiconductor processing. With a total of 2 patents, McClelland's work showcases his innovative approach to engineering challenges.
Latest Patents
One of McClelland's latest patents is a gas mixing apparatus. This apparatus includes a container with a closed top and bottom, designed to facilitate the mixing of multiple process gases. The design features a plurality of first inlets that allow gases to enter the container in a manner that promotes efficient mixing. Additionally, an outlet is positioned at the bottom of the container to enable the removal of the mixed gases.
Another significant invention is a magnetically coupled linear servo-drive mechanism. This mechanism is specifically designed for transporting semiconductor wafers within a processing system. It utilizes a set of magnets to drive a complementary set of magnets inside a carriage, ensuring precise linear motion while preventing angular rotation. This innovative design enhances the efficiency and reliability of semiconductor wafer handling.
Career Highlights
Throughout his career, Scott McClelland has worked with prominent companies in the technology sector. Notable among these are Novellus Systems Incorporated and Applied Materials, Inc. His experience in these organizations has contributed to his expertise in developing advanced technologies.
Collaborations
McClelland has collaborated with several talented individuals in his field, including Thomas M. Pratt and Craig Lyle Stevens. These collaborations have likely enriched his work and led to further innovations.
Conclusion
Scott McClelland's contributions to gas mixing and semiconductor technologies highlight his role as an influential inventor. His patents reflect a commitment to advancing engineering solutions in these critical areas.