Corona igniter with hermetic combustion seal on insulator inner diameter

The invention claimed is: 1. A corona igniter, comprising: an insulator including an inner surface surrounding a bore and extending from an upper connection end to an insulator nose end; said inner surface of said insulator including an electrode seat between said upper connection end and said insulator nose end; said inner surface of said insulator presenting an inner diameter, said inner diameter decreasing along said electrode seat in a direction moving toward said insulator nose end; a center electrode disposed in said bore of said insulator; said center electrode including a head disposed on said electrode seat of said inner surface of said insulator; a metallic coating disposed on said inner surface of said insulator between said electrode seat and said upper connection end; said metallic coating not disposed on said inner surface of said insulator below said electrode seat; and a braze disposed along said inner surface of said insulator between said electrode seat and said upper connection end. 2. The corona igniter of claim 1 , wherein said braze is located between said head of said center electrode and said inner surface of said insulator. 3. The corona igniter of claim 1 , wherein a copper-based powder is disposed on said head of said center electrode, and said braze is located between said copper-based powder and said inner surface of said insulator. 4. The corona igniter of claim 1 , wherein said metallic coating includes a layer of molybdenum and manganese. 5. The corona igniter of claim 4 , wherein said metallic coating consists of molybdenum and manganese. 6. The corona igniter of claim 4 , wherein said metallic coating includes a nickel-based layer disposed on said layer of molybdenum and manganese. 7. The corona igniter of claim 1 , wherein said metallic coating includes nickel. 8. The corona igniter of claim 1 , wherein said metallic coating has a thickness of less than 0.1 mm. 9. The corona igniter of claim 1 , wherein said metallic coating and said braze provide a hermetic seal along said inner surface of said insulator between said electrode seat and said upper connection end. 10. The corona igniter of claim 1 , wherein said insulator includes an outer surface, an outer metal coating is disposed on said outer surface of said insulator, a nickel-based layer is applied to a shell, and a second braze is disposed between said outer metal coating on said insulator outer surface and said nickel-based coating applied to said shell. 11. The corona igniter of claim 10 , wherein said outer metal coating includes molybdenum and manganese, and/or said outer metal coating includes nickel. 12. The corona igniter of claim 10 , wherein said outer metal coating and said second braze provide a hermetic seal between said outer surface of said insulator and said shell. 13. The corona igniter of claim 1 , wherein said center electrode extends from said head to a firing end, said center electrode includes a firing tip at said firing end, and said firing tip has a plurality of branches each extending radially outwardly. 14. The corona igniter of claim 1 , wherein said center electrode is formed of an electrically conductive material; said electrically conductive material includes nickel; said center electrode has a length extending along a center axis from said head to a firing end; a majority of said length of said center electrode is surrounded by said insulator, said head of said center electrode is supported and maintained in an axial position by said electrode seat; said center electrode includes a firing tip at said firing end; said firing tip has a plurality of branches each extending radially outwardly from said center axis; said firing tip of said center electrode is disposed longitudinally past said insulator nose end of said insulator; an electrical terminal rests on said head of said center electrode; said insulator extends longitudinally along said center axis from said upper connection end to said insulator nose end; said insulator is formed of an insulating material; said insulating material includes ceramic; said inner surface of said insulator extends longitudinally along said center axis from said upper connection end to said insulator nose end and receives said center electrode and said terminal; said inner diameter of said insulator extends across and perpendicular to said center axis and decreases from a top to a base of said electrode seat; said insulator includes an outer surface presenting an outer diameter extending across and perpendicular to said center axis; said outer surface of said insulator extends longitudinally from said upper connection end to said insulator nose end; said insulator outer diameter decreases along a portion of said insulator moving toward said insulator nose end to present an insulator nose region; a shell formed of metal surrounds a portion of said outer surface of said insulator; said shell extends along said center axis from a shell upper end to a shell ower end; said shell upper end engages said insulator; said shell lower end is disposed adjacent said insulator nose region; at least a portion of said insulator nose region extends axially outwardly of said shell lower end; said metallic coating and said braze provide a hermetic seal along said inner surface of said insulator between said electrode seat and said upper connection end; said metallic coating includes a layer of molybdenum and manganese and a nickel-based layer applied to said layer of molybdenum and manganese; said metallic coating is not located from said base of said electrode seat to said insulator nose end; said metallic coating has a thickness of less than 0.1 mm; said braze is located between said head of said center electrode and said metallic coating on said inner surface of said insulator or said braze is located between a copper-based powder disposed along said center axis on said head of said center electrode and said metallic coating on said inner surface of said insulator; said braze is located along said head of said center electrode or said braze is located along said copper-based powder, and said braze is not located along other portions of said insulator inner surface; an outer metal coating is disposed on said outer surface of said insulator and contacts said shell; a braze is disposed between said outer metal coating on said insulator outer surface and said shell; said outer metal coating includes a layer of molybdenum and manganese and a nickel-based layer applied to said layer of molybdenum and manganese; and said outer metal coating and said braze provide a hermetic seal between said outer surface of said insulator and said shell.