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A variable stator vane assembly and a bushing thereof. The bushing includes a metal bushing body and a wear-resistant coating. The assembly includes a rotatable trunnion and a first metal bushing. The trunnion is capable of being located in a through hole extending between outer and inner surfaces o

A variable stator vane assembly and a bushing thereof. The bushing includes a metal bushing body and a wear-resistant coating. The assembly includes a rotatable trunnion and a first metal bushing. The trunnion is capable of being located in a through hole extending between outer and inner surfaces of a compressor casing of a gas turbine engine. The first metal bushing is capable of being located in the through hole proximate the outer surface to surround a first portion of the trunnion when the trunnion is located in the through hole. The first metal bushing and the first portion have wear-resistant coatings which are in mutual contact, apart from any intervening lubricant, when the trunnion and the first metal bushing are located in the through hole and the trunnion is rotating with respect to the first metal bushing.

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The invention claimed is: 1. A variable stator vane assembly comprising: a) a rotatable variable-stator-vane trunnion consisting essentially of steel or titanium which is disposable in a through hole extending between outer and inner surfaces of a compressor casing of a gas turbine engine; and b) a

The invention claimed is: 1. A variable stator vane assembly comprising: a) a rotatable variable-stator-vane trunnion consisting essentially of steel or titanium which is disposable in a through hole extending between outer and inner surfaces of a compressor casing of a gas turbine engine; and b) a first metal bushing consisting essentially of steel or titanium which is disposable in the through hole proximate the outer surface to surround a first portion of the trunnion when the trunnion is disposed in the through hole, wherein the first metal bushing and the first portion have wear-resistant coatings consisting essentially of a ceramic disposed thereon which are in mutual contact, apart from any intervening lubricant, when the trunnion and the first metal bushing are disposed in the through hole and the trunnion is rotating with respect to the first metal bushing. 2. The variable stator vane assembly of claim 1, also including: c) a second metal bushing which is disposable in the through hole proximate the inner surface to surround a second portion of the trunnion when the trunnion is disposed in the through hole, wherein the second metal bushing and the second portion have wear-resistant coatings which are in mutual contact, apart from any intervening lubricant, when the trunnion and the second metal bushing are disposed in the through hole and the trunnion is rotating with respect to the second metal bushing; and d) a gas seal which is disposable in the through hole to surround a third portion of the trunnion when the trunnion is disposed in the through hole, wherein the third portion is disposed between the first and second portions, and wherein the gas seal is more flexible than either of the first and second metal bushings. 3. The variable stator vane assembly of claim 2, wherein at least one of the wear-resistant coatings of the first metal bushing and the first portion is lubricated to reduce friction from rotation of the trunnion with respect to the first metal bushing when the trunnion and the first metal bushing are disposed in the through hole, and wherein at least one of the wear-resistant coatings of the second metal bushing and the second portion is lubricated to reduce friction from rotation of the trunnion with respect to the second metal bushing when the trunnion and the second metal bushing are disposed in the through hole. 4. The variable stator vane assembly of claim 3, wherein the wear-resistant coatings of the first and second metal bushings and the first and second portions consist essentially of a ceramic. 5. The variable stator vane assembly of claim 4, wherein the wear-resistant coatings of the first and second metal bushings and the first and second portions are lubricated with graphite. 6. The variable stator vane assembly of claim 4, wherein the ceramic consists essentially of tungsten carbide, and wherein the gas seal is a polymeric gas seal. 7. The variable stator vane assembly of claim 2, also including a vane button which is attached to the trunnion and adapted to support a vane airfoil, which is disposed proximate the second portion, and which extends substantially perpendicularly away from the trunnion, wherein the second metal bushing and the vane button have wear-resistant layers which are in mutual contact, apart from any intervening lubricant, when the trunnion and the second metal bushing are disposed in the through hole and the trunnion is rotating with respect to the second metal bushing. 8. The variable stator vane assembly of claim 7, wherein the first and second metal bushings each include an outer circumferential surface which is coated with a wear-resistant material which contacts the compressor casing when the first and second metal bushings are disposed in the through hole. 9. The variable stator vane assembly of claim 2, wherein the first and second metal bushings are adapted to be press fitted into the through hole. 10. The variable stator vane assembly of claim 9, wherein the first and second metal bushings and the compressor casing have substantially equal coefficients of thermal expansion. 11. A variable-stator-vane-assembly bushing comprising a metal bushing body consisting essentially of steel or titanium which is disposable in a through hole extending between outer and inner surfaces of a compressor casing of a gas turbine engine to surround a wear-resistant coating consisting essentially of a ceramic disposed on a portion of a rotatable variable-stator-vane trunnion consisting essentially of steel or titanium which is disposed in the through hole, wherein the metal bushing body has a wear-resistant coating consisting essentially of a ceramic disposed thereon which is in contact, apart from any intervening lubricant, with the wear-resistant coating of the portion of the trunnion when the metal bushing body is disposed in the through hole and the trunnion is rotating with respect to the metal bushing body. 12. The variable-stator-vane-assembly bushing of claim 11, wherein the wear resistant coating of the metal bushing body is lubricated to reduce friction from rotation of the trunnion with respect to the metal bushing body when the metal bushing body is disposed in the through hole. 13. The variable-stator-vane-assembly bushing of claim 12, wherein the wear-resistant coating of the metal bushing body consists essentially of a ceramic. 14. The variable-stator-vane-assembly bushing of claim 13, wherein the metal bushing body is adapted to be press fitted into the through hole. 15. A variable stator vane assembly comprising: a) a rotatable variable-stator-vane trunnion consisting essentially of steel or titanium which is disposed in a through hole extending between outer and inner surfaces of a compressor casing of a gas turbine engine; and b) a first metal bushing consisting essentially of steel or titanium which is disposed in the through hole proximate the outer surface and which surrounds a first portion of the trunnion, wherein the first metal bushing and the first portion have wear-resistant coatings consisting essentially of a ceramic disposed thereon which are in mutual contact, apart from any intervening lubricant, when the trunnion is rotating with respect to the first metal bushing; c) a second metal bushing consisting essentially of steel or titanium which is disposed in the through hole proximate the inner surface and which surrounds a second portion of the trunnion, wherein the second metal bushing and the second portion have wear-resistant coatings consisting essentially of a ceramic disposed thereon which are in mutual contact, apart from any intervening lubricant, when the trunnion is rotating with respect to the second metal bushing; and d) a gas seal which is disposed in the through hole and which surrounds a third portion of the trunnion, wherein the third portion is disposed between the first and second portions, and wherein the gas seal is more flexible than either of the first and second metal bushings. 16. The variable stator vane assembly of claim 15, wherein at least one of the wear-resistant coatings of the first metal bushing and the first portion is lubricated to reduce friction from rotation of the trunnion with respect to the first metal bushing, and wherein at least one of the wear-resistant coatings of the second metal bushing and the second portion is lubricated to reduce friction from rotation of the trunnion with respect to the second metal bushing. 17. The variable stator vane assembly of claim 16, wherein the wear-resistant coatings of the first and second metal bushings and the first and second portions consist essentially of a ceramic. 18. The variable stator vane assembly of claim 17, also including a vane button which is attached to the trunnion and supports a vane airfoil, which is disposed proximate the second portion, and which extends substantially perpendicularly away from the trunnion, wherein the second metal bushing and the vane button have wear-resistant layers which are in mutual contact, apart from any intervening lubricant, when the trunnion is rotating with respect to the second metal bushing. 19. The variable stator vane assembly of claim 18, wherein the first and second metal bushings each include an outer circumferential surface which is coated with a wear-resistant material which contacts the compressor casing. 20. The variable stator vane assembly of claim 19, wherein the first and second metal bushings are press fitted into the through hole.