This invention relates to turbine engines, and more particularly to turbine engine augmentors.
Afterburners or thrust augmentors are known in the industry. A number of configurations exist. In a typical configuration, exhaust gases from the turbine pass over an augmentor centerbody. Additional fuel is introduced proximate the centerbody and is combusted to provide additional thrust. In some configurations, the augmentor centerbody is integrated with the turbine centerbody. In other configurations, the augmentor centerbody is separated from the turbine centerbody with a duct surrounding an annular space between the two. U.S. Pat. Nos. 5,685,140 and 5,385,015 show exemplary integrated augmentors.
The centerbody may contain a burner serving as a combustion source. For introducing the additional fuel, a number of spray bars may be positioned within generally radially extending vanes. A pilot may be proximate an upstream end of the tailcone. Alternatively or additionally to the burner, a number of igniters may be positioned within associated ones of the vanes to ignite the additional fuel. Trailing portions of the vanes may serve as flameholder elements for distributing the flame across the flow path around the centerbody.
Separately, electro-graphitic carbon materials have been developed for a variety of uses. US Pre-grant Publication 20050084190A1 discloses a variable vane inner diameter (ID) bushing made from electro-graphitic carbon.
Accordingly, one aspect of the invention involves a turbine engine augmentor. A centerbody is positioned within a gas flowpath from upstream to downstream and has a downstream tailcone. A number of vanes are positioned in the flowpath outboard of the centerbody. An augmentor fueling system includes a number of spray bars having conduits extending through associated vanes. A number of fuel injector nozzles are distributed along each conduit. Each of the nozzles is positioned to discharge an associated fuel stream from one of the sides of the associated vane. A number of wear members is each mounted relative to an associated one of the nozzles for a range of motion relative thereto and moveably cooperate with the associated vane to accommodate operating deflection (e.g., differential thermal expansion or loading deformation) and/or tolerance of the spray bars and vanes.
In various implementations, the augmentor may be non-remote or remote. The augmentor fueling system may comprise a manifold within the centerbody feeding the spray bars. Each of the vanes may include a main body and a trailing edge box structure assembled to the main body. The wear members may each comprise an electrographitic carbon body. The wear members may each comprise a material softer than an adjacent material of the associated nozzle and an adjacent material of the associated vane body. The nozzles may include paired nozzles along opposite sides of each of the vanes or of every augmentor vane. The wear members may be removable from the associated nozzles nondestructively of such nozzles. The wear members may be secured to the nozzles by retainers interfitting with the wear members and nozzles. Each of the wear members may be moveable between an inward extreme and an outward extreme. At the inward extreme, the associated retainer may contact a boss of the associated spray bar. At the outward extreme, the associated retainer may contact an underside of a head of the associated nozzle. The boss and nozzle may be brazed or welded to each other. The retainer may be a bent wire. The wear members may be spring biased toward the outward extreme.
Another aspect of the invention involves electrographitic carbon wear blocks. Another aspect of the invention involves removable wear blocks secured to associated nozzles by retainer clips. The clips may have first and second legs received in first and second holes in the wear blocks. The first and second holes may intersect a nozzle-receiving aperture. The various aspects of the invention may be implemented in the manufacturing or remanufacturing of an engine or in the reengineering of an engine configuration from a baseline lacking such wear members (e.g., a baseline configuration wherein the wear members are metal and integrated to remaining portions of the spray bars).
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference numbers and designations in the various drawings indicate like elements.
The augmentor comprises a centerbody 30 generally symmetric around the axis 26 and formed as a portion of an engine hub. The exemplary centerbody has a main portion 32 and a tailcone 34 downstream thereof. Circumferentially arrayed vanes 36 have leading and trailing extremities 37 and 38 and extend generally radially between the centerbody 30 and a turbine exhaust case (TEC) 40. Each of the vanes may be an assembly of a leading main body portion 42 and a trailing edge box 44. The vanes have circumferentially opposite first and second sides 46 and 48 (
Each exemplary block 82 has an outboard face or side 100, an inboard face or side 102, first and second lateral faces or sides 104 and 106, and first and second longitudinal faces or sides 108 and 109 (e.g., proximal and distal relative to the length of the spray bar).
Any of a variety of assembly techniques may be used to assemble each spray bar. In the exemplary spray bar, the first conduit 66 is assembled from a longitudinal stacking of machined pieces, assembled with the blocks 69 and 72, and brazed. The second conduit 68 includes a tube assembled to a machined end piece to feed the most distal/outboard injectors (e.g., by brazing). This tube is inserted through the blocks 69 and into the block 72 and brazed thereto. The nozzles 80 may be brazed into their associated bosses 84. The springs 90 may be placed over the nozzles or preinstalled prior to nozzle installation. The blocks 82 are then installed so that their apertures 83 receive the nozzles 80. Further block movement compresses the associated spring 90. The retainers 88 are then inserted and the end portions 122 of the legs 116 bent over (e.g., manually by pliers or similar tool).
After a period of use, the wear blocks will become worn due to their engagements with the nozzles 80 and vane halves 150 and 152. Exemplary nozzles are formed of nickel-based superalloy. Exemplary vane corrugations 158 and 160 are formed of nickel-based superalloy. It has been determined that electrographitic carbon is an advantageous block material to engage and preferentially wear relative to such nozzles and structures. After wear, the spray bar may be remanufactured. Exemplary remanufacturing involves separating the two vane halves to expose the blocks. The retainers are removed (e.g., by straightening the end portion 122 or cutting them off and then extracting the remainder). The blocks may then be removed. The springs may similarly be removed if it is desired to replace the springs with new springs. New springs (if any) may then be installed followed by a new block and new retainer. The vane halves may then be reassembled over the spray bar.
One or more embodiments of the present invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. The inventive spray bars may be applied in a retrofit or redesign of an otherwise existing engine. In such cases, various properties of the spray bars would be influenced by the structure of the existing engine. While illustrated with respect to an exemplary center-fueled spray bar, non-remote augmentor situation, the principles may be applied to remote augmentors and to spray bars fueled from their outboard ends. Accordingly, other embodiments are within the scope of the following claims.
The invention was made with U.S. Government support under contract N00019-02-C-3003 awarded by the U.S. Navy. The U.S. Government has certain rights in the invention.
Number | Name | Date | Kind |
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2392682 | Marek | Jan 1946 | A |
3800530 | Nash | Apr 1974 | A |
3931707 | Vdoviak | Jan 1976 | A |
5001897 | Schultz | Mar 1991 | A |
5385015 | Clements et al. | Jan 1995 | A |
5685140 | Clements et al. | Nov 1997 | A |
6038852 | Celi | Mar 2000 | A |
20050084190 | Brooks et al. | Apr 2005 | A1 |
Number | Date | Country |
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0 750 164 | Dec 1996 | EP |
1 528 226 | May 2005 | EP |
1 444 679 | Aug 1976 | GB |
Number | Date | Country | |
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20070006590 A1 | Jan 2007 | US |