초록 ▼

A fabrication technique is described for producing lighter weight and improved wear and erosion resistant gun barrels. The barrels are produced in an unconventional manner from the inside bore to the outside diameter of the barrel and combine a refractory metal, metal alloy, or ceramic composite inn

A fabrication technique is described for producing lighter weight and improved wear and erosion resistant gun barrels. The barrels are produced in an unconventional manner from the inside bore to the outside diameter of the barrel and combine a refractory metal, metal alloy, or ceramic composite inner liner with a metal matrix composite (MMC) or titanium or other suitable high strength, lightweight metal or metal alloy outer shell. A unique aspect of the invention is that there is a compositional gradation from the liner at the inside bore to the overwrap which extends to the outside diameter of the barrel. A process is also described to produce barrels with a refractory metal liner with improved wear and erosion resistance by depositing the refractory metal on the ID of a pre-fabricated barrel.

대표청구항 ▼

What is claimed is: 1. A high strength heat and wear resistant tube comprising an outer shell lined with a ceramic matrix composite material, wherein the ceramic matrix composite material consists of aligned carbon, graphite, or silicon carbide fibers; and wherein the matrix composite material is f

What is claimed is: 1. A high strength heat and wear resistant tube comprising an outer shell lined with a ceramic matrix composite material, wherein the ceramic matrix composite material consists of aligned carbon, graphite, or silicon carbide fibers; and wherein the matrix composite material is formed by building outward from a mandrel by fiber wrapping and infiltration/pyrolysis to form the matrix. 2. A high strength wear resistant tube as claimed in claim 1, wherein the liner comprises a refractory metal or metal alloy. 3. The high strength wear resistant tube as claimed in claim 2, wherein the liner is graded in composition from lower porosity at the bore to a higher porosity adjacent its outer diameter. 4. The high strength wear resistant tube as claimed in claim 2, wherein the liner comprises a refractory metal or metal alloy liner containing ceramic particulates. 5. A firearm barrel comprising a high strength wear resistant tube as claimed in claim 1. 6. A firearm barrel as claimed in claim 5, wherein the ceramic matrix composite material lining the outer shell inner surface is rifled. 7. The firearm barrel as claimed in claim 5, wherein the outer tube comprises a metal selected from the group consisting of steel, titanium and aluminum. 8. A firearm barrel comprising an outer tube having a wear and heat resistant liner, wherein the wear resistant liner consists of a formed in-situ material which is graded in composition from a lower porosity at the bore to a higher porosity at the outer diameter. 9. A firearm barrel as claimed in claim 8, wherein the liner comprises a ceramic matrix composite. 10. A firearm barrel as claimed in claim 8, wherein the liner comprises a refractory metal or metal alloy. 11. A firearm barrel as claimed in claim 8, wherein the liner has a bore with rifling formed in-situ. 12. A firearm barrel as claimed in claim 10, wherein the refractory metal or metal alloy is selected from the group consisting of Ta—Cr, Ta—Cr—Mo, Ta—W, Nb—Cr, Mo—Re, Mo—W—Re and Mo—Ta—W. 13. A firearm barrel as claimed in claim 10, wherein the refractory metal or metal alloy liner is formed in-situ by plasma transfer arc processing. 14. A firearm barrel as claimed in claim 8, wherein the outer tube comprises a metal selected from the group consisting of steel, titanium or aluminum. 15. A firearm barrel comprising an outer tube having a wear and heat resistant liner, wherein the wear resistant liner comprises a ceramic matrix composite having a bore with rifling formed in-situ and wherein the ceramic matrix composite material consists of aligned carbon, graphite, or silicon carbide fibers. 16. A high strength heat and wear resistant tube comprising an outer shell lined with a ceramic matrix composite material wherein the ceramic matrix composite material consists of aligned carbon, graphite, or silicon carbide fibers, a refractory metal, a refracting metal alloy or a refractory metal cermet, having a metal matrix composite overwrap. 17. A firearm barrel formed from the high strength heat and wear resistant tube as claimed in claim 16. 18. A firearm as claimed in claim 17, wherein the liner comprises refractory metal or metal alloy liner containing ceramic particulates. 19. A firearm barrel as claimed in claim 17, wherein the liner inner surface is rifled. 20. A firearm barrel comprising as claimed in claim 19, wherein the rifling is formed in-situ. 21. A firearm barrel as claimed in claim 17, wherein the refractory metal or metal alloy is selected from the group consisting of Ta—Cr, Ta—Cr—Mo, Ta—W, Nb—Cr, Mo—Re, Mo—W—Re and Mo—Ta—W. 22. A firearm barrel as claimed in claim 17, wherein the refractory metal or metal alloy liner is formed in-situ by plasma transfer arc processing. 23. A firearm barrel as claimed in claim 17, wherein the metal matrix composite overwrap comprises a metal selected from the group consisting of steel, titanium or aluminum. 24. A firearm barrel as claimed in claim 17, wherein the liner has a lower porosity adjacent its bore to a higher porosity adjacent its overwrap.