Company Filing History:
Years Active: 2015-2016
Title: Thomas Setz: Innovator in High-Power Semiconductor Technology
Introduction
Thomas Setz is a notable inventor based in Veltheim, Switzerland. He has made significant contributions to the field of high-power semiconductor technology, holding 2 patents that showcase his innovative approach to electrical engineering.
Latest Patents
One of his latest patents is a high-power semiconductor module. This module includes a high-power semiconductor device mounted on it, along with at least two electrical connections. A key feature of this module is a short-circuit device that generates a persistent electrically conducting path between the two electrical connections upon receiving a trigger signal. This is achieved by electrically destroying a semiconductor of the high-power semiconductor module.
Another significant patent by Setz is for a converter cell designed for cascaded converters, along with a control system and method for operating this converter cell. The cascaded electric power converter includes a converter cell with a cell capacitor and at least one phase leg that has multiple electric valves. The control system is designed to manage the switching of these electric valves, ensuring efficient operation of the converter cell.
Career Highlights
Throughout his career, Thomas Setz has worked with prominent companies in the industry, including ABB Research Ltd. and ABB Schweiz AG. His experience in these organizations has allowed him to refine his skills and contribute to groundbreaking projects in semiconductor technology.
Collaborations
Setz has collaborated with notable professionals in his field, including Staffan Norrga and Frans Dijkhuizen. These collaborations have further enriched his work and expanded the impact of his inventions.
Conclusion
Thomas Setz is a distinguished inventor whose work in high-power semiconductor technology has led to innovative solutions in electrical engineering. His patents reflect a commitment to advancing technology and improving efficiency in power conversion systems.