The U. S. Army and Navy have experienced significant corrosion problems with magnesium alloys that are used to fabricate aircraft components. The most severe of these are associated with large and expensive transmission and gearbox housings for rotorcraft, which have to be removed prematurely because of corrosion. Many of the parts cannot be reclaimed because there is not an existing technology that can restore them adequately for service. The U.S. Army Research Laboratory has developed a Cold Spray process to reclaim magnesium components that shows significant improvement over existing methods and is in the process of qualification for use on rotorcraft. The cold spray repair has been shown to have superior performance in the tests conducted to date, is inexpensive, can be incorporated into production, and has been modified for field repair, making it a feasible alternative over competing technologies. Cold spray trials were performed using various aluminum powders at different deposition conditions with both helium and nitrogen carrier gas. Evaluations of the resultant cold spray aluminum coatings deposited on ZE-41A magnesium alloy substrates were conducted using microstructural analysis, hardness, bond strength and corrosion testing. The work presented here represents the first two years of a three-year effort, which will result in the establishment of a demonstration cold spray facility at the Naval Air Depot, where the overhaul and repair of Navy rotorcraft is accomplished.
[1]
Tobias Schmidt,et al.
The cold spray process and its potential for industrial applications
,
2005,
Thermal Spray 2005: Proceedings from the International Thermal Spray Conference.
[2]
Anatolii Papyrin,et al.
Cold Spray Technology
,
2006
.
[3]
Wang Hong-zhe,et al.
Cold Spray Technology
,
2009
.
[4]
R. Mccune,et al.
Characterization of copper layers produced by cold gas-dynamic spraying
,
2000
.
[5]
Joseph R. Davis.
Properties and selection : nonferrous alloys and special-purpose materials
,
1990
.
[6]
G. Thompson,et al.
A non-chromate conversion coating for magnesium alloys and magnesium-based metal matrix composites
,
1995
.
[7]
V. Champagne,et al.
Interface material mixing formed by the deposition of copper on aluminum by means of the cold spray process
,
2005
.
[8]
E. Lugscheider,et al.
A systematic approach to material eligibility for the cold-spray process
,
2003,
Thermal Spray 2003: Proceedings from the International Thermal Spray Conference.
[9]
P. Shipway,et al.
Cold gas dynamic spraying of aluminum: The role of substrate characteristics in deposit formation
,
2005
.