Supersonically Induced Mechanical Alloy Technology (SIMAT^(TM)) also known as gas-dynamic spraying is under development for corrosion protection and material repair for aluminum airframe structures. This technology enables material powder consolidation that is not possible using other spray technologies. Similar to cold spray but based on compact spray head with nozzle powder feed, SIMAT^(TM) is a low temperature process and does not create the high-temperature environment that affects both the substrate (especially thermally non-stable substrates) and the deposited coating. The emerging SIMAT^(TM) technology, now in development, has the potential for coating, repairing, and joining aluminum based materials.

The SIMAT^(TM) method adds new flexibility to powder material deposition producing thin to very thick deposits of various metals and metal-ceramic mixtures based on a cold spray particle kinetic approach inducing impact fusion. Solid particles in the size range of 10 to 100 microns are accelerated into a supersonic stream (ranging from 300 to 1200 m/s) using compressed air. These high velocity cold particles are projected on to a work piece. There is no heat discharge in the spray device itself, thus the powder material retains original characteristics. This spraying technique can generate a wide range of deposited layers with thickness ranging from tens of microns up to as much as centimeters. The process extends beyond the concept of "coatings" and includes the capability for in-situ material build-up and consolidation to a three-dimensional structures and joining of the components. The powder to be deposited and consolidation can be performed from a range of hybrid powders consisting of metals, alloys, ceramics and glasses. This paper shows examples of the process demonstrated on typical aircraft components for new or restored corrosion protection and repair damage for potential service life extension of the aircraft structure.