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Resistance of tantalum and columbium coatings to propellant gas erosion

: Schlett, V.; Stuke, H.; Weiss, H.; Grabatin, H.

Journal of vacuum science and technology A. Vacuum, surfaces and films 3 (1985), Nr.6, S.2545-2550
ISSN: 0734-2101
Fraunhofer IFAM ()
AES; Drahtexplosionsbeschichtung; erosion; Niob; PVD-Beschichtung; SIMS; Tantal

Alloy steel tubes of 70 mm length and 20 mm bore diameter were coated with tantalum of columbium by the wire explosion technique. This process uses the energy of an electric current pulse to melt or vaporize the coating material which is in the form of a wire in the center of the tube, and to deposit it on the bore surface. For testing, these tubes were mounted as outlet nozzles on a vented vessel and subjected to propellant gas pulses of 30 ms duration and 2500 K. The pressure buildup inside the vessel was 1000 bar. After each pulse the erosive wear of the test pieces was determined and after testing the reaction zone of the coatings was sputtered to a depth of 2 micrometers and analyzed by AES and SIMS during the process. Both coatingj materials showed excellent adhesion and their erodion resistance proved superior to the unprotected alloy steel. Tantalum, however, exhibited a much better performance than columbium. This was due to the different properties of the gas/metal reaction l ayers formed. In both cases the bore surface was covered with propellant gas residue of 1 micrometer thickness, that was built up and carried out with each pulse. Underneath, a layer consisting of Ta sub 2 O sub 5 or Nb sub 2 O sub 5 was formed. While Ta sub 2 O sub 5 was mechanically stable and therefore, built up to a considerable thickness providing good protection, the Nb sub 2 O sub 5 layer was formed and removed continuously with every round. This pattern exposed the unprotected Nb to the next pulse and caused a much faster wear rate.