About this Abstract |
Meeting |
MS&T21: Materials Science & Technology
|
Symposium
|
Advances in Dielectric Materials and Electronic Devices
|
Presentation Title |
Production of High Temperature 3D Printed Ceramics for Sensing Applications |
Author(s) |
Eleanore Rogenski, Victoria Adams, Eric MacDonald, Matthew Mullin, Ian Small, Pedro Cortes |
On-Site Speaker (Planned) |
Eleanore Rogenski |
Abstract Scope |
Ceramic materials possess many favorable properties such as heat resistivity, low dielectric profiles, and high resistance to corrosion, which makes them attractive materials in the aerospace, automotive, microelectronic, and biomedical industries. Nowadays, ceramics can be created through a variety of different additive manufacturing processes, allowing the production of customizable and intricate geometries for high temperature applications. The present work investigates the incorporation of high temperature metallic traces such as molybdenum and antimony tin oxide on 3D printed zirconia and alumina substrates to produce embedded thermocouple sensors. A variety of overmolding design concepts have been here studied in order to entrap the metallic conductive phases and yield mechanical robust structures. The present work represents the foundation of additional studies of high temperature embedded antennas as well as low temperature co-fired ceramics. |