Title :
Improving the resistivity variation in multi-layer heaters for use in dispenser cathodes
Author :
Spicer, John ; Hayes, David ; Antohe, Bogdan
Author_Institution :
Ceradyne Inc., 3M Co., Lexington, KY, USA
Abstract :
Dispenser cathodes must operate at specific temperature while a specific heater power is applied. To achieve the required temperature, a coiled wire heater is commonly used. These heaters are typically manufactured from Tungsten-Rhenium wire which is wound into a non-inductive coil. As the heater geometry is constrained by the material properties and electrical isolation needs of the wire, the coiled wire heater is often an inefficient use of available space and results in increased cost for the cathode assembly. The technology for a printed heater exists, but, so far, has been unable to meet the production resistivity requirements. This paper presents initial research using ink- jetted tungsten particles on a ceramic substrate as an alternate approach to the heater design.
Keywords :
bimetals; coils; induction heating; ink jet printing; rhenium alloys; substrates; thermionic cathodes; tungsten; tungsten alloys; WRe; cathode assembly; ceramic substrate; coiled wire heater; dispenser cathode; electrical isolation needs; heater geometry; heater power; ink-jetted tungsten particles; multilayer heater; noninductive coil; printed heater; production resistivity requirement; resistivity variation improvement; tungsten-rhenium wire; Cathodes; Ceramics; Space heating; Substrates; Tungsten; Wires; dispenser cathode; heater; temperature distribution;
Conference_Titel :
Vacuum Electronics Conference, IEEE International
Conference_Location :
Monterey, CA
DOI :
10.1109/IVEC.2014.6857542
