Title :
Thermal Analysis of High-Energy Railgun Tests
Author :
Motes, D. ; Keena, J. ; Womack, K. ; Stefani, F. ; Crawford, M.
Author_Institution :
Inst. for Adv. Technol., Univ. of Texas at Austin, Austin, TX, USA
Abstract :
This paper describes temperature measurements made on the high-energy medium-caliber launcher at the Institute for Advanced Technology. Simulations performed in Maxwell 3-D and E-Physics showed that Joule heating from current diffusing into the rails accounts for most of the temperature rise in the conductors. Temporal skin effects increase thermal dissipation significantly over what would be expected by the ohmic losses under fully diffused conditions. Based on this analysis, Joule heating is the overwhelmingly dominant source of heating in low-speed tests. As the velocity of the armature increases, Joule heating remains the dominant source of heat; however, additional mechanisms-which may include frictional heating, arcing energy, aluminum deposition, and temperature-dependent properties-are required to more satisfactorily explain the temperature profile obtained.
Keywords :
Maxwell equations; heating; railguns; thermal analysis; E-Physics; Joule heating; Maxwell 3D; aluminum deposition; arcing energy; conductors; current diffusing; frictional heating; high-energy medium-caliber launcher; high-energy railgun tests; ohmic losses; temperature measurements; temperature-dependent properties; temporal skin effects; thermal analysis; thermal dissipation; Conductors; Heating; Plasma temperature; Rails; Temperature; Temperature measurement; Transient analysis; Railguns;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2174375
