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A Plasma Process to Apply Refractory Metal Coatings to Continuous Lengths of Copper Alloy Rails
Navy STTR FY2010.A
| Sol No.: |
Navy STTR FY2010.A |
| Topic No.: |
N10A-T025 |
| Topic Title: |
A Plasma Process to Apply Refractory Metal Coatings to Continuous Lengths of Copper Alloy Rails |
| Proposal No.: |
N10A-025-0248 |
| Firm: |
Materials & Electrochemical Research (MER) Corp.
7960 S. Kolb Rd.
Tucson, Arizona 85756-9237 |
| Contact: |
James Withers |
| Phone: |
(520) 574-1980 |
| Web Site: |
www.mercorp.com |
| Abstract: |
High strength copper alloys are preferred as the base rails for railguns due to their combination of strength and electrical and thermal conductivity, but suffer damage due to high current densities, arcing, gouging, and exposure to molten aluminum armatures. A refractory metal/alloy coating on the copper base alloy is an attractive approach for increasing rail life if the refractory metal coating remains adherent and withstands the thermal transients and other phenomena that usually limit shot life. A plasma process can apply the refractory metal/alloys from a molten state that provides a functionally graded interface resulting in adhesion at least equivalent to the base copper alloy strength. The plasma coating process can produce the refractory metal/alloy-copper base in continuous length, and with arbitrary cross-sections. In a team with the University of Texas (UT), the plasma refractory metal/alloy process will produce rail coupons for railgun testing at UT and demonstration that continuous lengths are producible. |
| Benefits: |
In addition to producing rails for railguns for all the military services, refractory metal coated copper base materials have applications to any electro-mechanical high heat, stress and current carrying requirement, high-speed maglev contacts, electrical generation facilities, high current switches, arc based electrodes and erosion resistant electrical contacts. |
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