BACKGROUND

[0001] Aircraft gas turbine case cooling systems help the efficiency of gas turbine engines by lowering fuel consumption thereof. The systems distribute relatively cool air from an engine compressor to the casing surface of turbine cases causing the casing surface to shrink. Clearance between the case inner diameter and turbine blade tips shrinks to minimize the amount of air that escapes around the blade tip thereby increasing fuel savings to optimize the system.

[0002] Generally, during a cruise condition, compressor air is ducted to manifolds that surround the turbine cases. The manifolds direct the cooler air on a case surface causing case diameter to shrink, closing blade tip-to-case clearances.

[0003] However, at take off or during climbing, the cooling air is shut off causing the cases to grow in diameter. Clearances between the blade tips and the casing are increased and the system is not optimized but blade-to-case interactions are minimized.

SUMMARY

[0004] According to an exemplary embodiment, a low bypass turbofan gas turbine engine, such as in a fighter jet application, has a high pressure turbine having a blade and an engine casing disposed about the blade. A shield is disposed around the casing adjacent to the blade to create an area between the shield and the casing. A gate selectively controls entry of cooling air into the area and may be closed if the engine is maneuvering and may be open if cruising.

[0005] According to a further exemplary embodiment, a cooling system is disposed in a low-bypass turbofan gas turbine engine, the engine having a high pressure turbine having a blade and an engine casing disposed about the blade. The cooling system has a shield disposed around the casing adjacent to the blade to create an area between the shield and the casing. A gate may selectively controls entry of fan air into the area if disposed about the casing such that the gate is adapted to be closed if the engine is maneuvering and may be open if the engine is cruising. PA-11444U;67097-1307

[0006] According to a further exemplary embodiment, a method of cooling a low- bypass turbofan engine includes the steps of providing a shield around a casing adjacent a high pressure turbine blade in the engine, gating fan air to an area between the shield and the casing to shrink the casing around the blades if the engine is in a cruise mode.

[0007] These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] Figure 1 shows a schematic drawing in which a jet engine utilizes a clearance control system that is off.

[0009] Figure 2 is an embodiment of the schematic embodiment of the jet system of Figure 1 in which the air flow is vented through the duct.

[0010] Figure 3 shows an exploded view of the air cooling system of Figure 1.

[0011] Figure 3 A shows an expanded view taken along the lines 3 A in Figure 3.

[0012] Figure 3B shows a back view of Figure 3A.

[0013] Figure 4 shows a perspective view of the system disclosed herein in cruise condition.

[0014] Figure 5 shows the system disclosed herein in take-off or maneuver condition.

[0015] Figure 6 shows the system disclosed herein in steady-state condition.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0016] Referring to Figure 1, a jet engine 15 used with aircraft that have performance as a priority, e.g., a military fighter aircraft 10 that is used for quick acceleration and deceleration, is schematically shown. . Such engines 15 frequently employ high speed maneuvers, in which the engine may be throttled upwardly and downwardly quickly and often.

[0017] Historical active clearance control systems ("ACS" and not shown) do not work with these engines and aircraft 10. The cooling provided by an ACS cannot keep up with the rapid heat changes in the engine caused by maneuvering. For instance, a pilot (not shown) may need rapid acceleration in one instance that causes the case 20, and clearance, to PA-11444U;67097-1307 expand rapidly. Air directed to the case by an ACS to minimize that clearance may not be delivered in time to cool the case during that maneuver. But cooling caused by the ACS may occur too rapidly as the throttle is pulled back to decelerate the aircraft (and the temperature of the engine) so that blade tip-to-case interference may occur. Such situations are clearly undesirable. Moreover, ACS may be heavy and may limit the aircraft' s ability to maneuver. As a result, engines in this type of aircraft 10 do not have ACS and particularly in the high pressure turbine section 25 of the engine 15 where such tip-to-case in clearance is critical and in which tip-to-case interference is undesirable.

[0018] Referring to Figures 1 and 2, a portion 17 of an engine 15 is shown. The engine casing 20 encloses high pressure turbine blades 30, low pressure turbine blades 35 and a plurality of stationary struts 40. A ducting system 45 directs cooling air (indicated by arrows 50) on a continual basis to the case 20 outside the low pressure turbine blades 35 via boss 55. This cooling air is typically directed from a compressor (not shown) through the ducting system 45 in an area between the case 20 and a nacelle 60.

[0019] Referring now to Figures 1 and 2, exemplary clearance control system 65 ("CCS") for the high pressure turbine blades 30, or other areas of the engine 15, is shown. The CCS 65 includes a heat shield 70, an actuation valve 75, and a finger seal 80, or other means of conventionally constraining the heat shield to a cylindrical case, such as a band clamp (not shown). Figure 1 shows the actuation valve 75 closed thereby causing a flow of cooling air 85 not to pass between the heat shield 70 and the case 20 thereby allowing the case to expand and minimize a probability of tip-to-case interference. Such a condition is used if said aircraft 10 is maneuvering. Figure 2 shows the actuation valve 75 open thereby causing a flow of cooling air 85 from an engine fan (not shown) to pass between the heat shield 70 and the case 20 thereby causing the case 20 to shrink and improve fuel consumption. Such a condition is used if said aircraft 10 is cruising or in steady state as will be discussed herein.

[0020] Referring now also to Figures 3, 3 A, and 3B, the heat shield 70 is a piece of annular sheet metal that is contoured radially from its inlet end 90 to its outlet end 95 a distance from the casing to allow a proper amount of air 85 into a space 100 between the heat shield 70 about the case 20 adjacent to the high pressure turbine blades 30. PA-11444U;67097-1307

[0021] The inlet end 90 has a vertically-oriented face 105 (though other orientations are contemplated herein) that has a plurality of openings 110 that are roughly rectangular having curved sides 115 as the heat shield 70 is designed to enclose the case 20. On that face 105, the heat shield 70 has one or more slots 120 for cooperating with an annular strap 125 as will be discussed herein. The strap 125 and the face 105 and its openings 110 form the valve (or gate) 75.

[0022] The face 105 on its back portion 130 (see Figure 3B) thereof has annular L-shaped flanges 135 that form races 140 for holding the flat annular strap 125 against the back portion 130. The strap 125 has a plurality of spaced slots 145 that ape the shape of the openings 110 are designed to be in register, partially in register and out of register with the openings 110 in the face 105 to meter air 85 in the space 100.

[0023] The heat shield 70 has a bottom flange 145 which is designed to be in register with the casing 20. A finger seal 150 (see Figures 1 and 2) is attached to the bottom flange 145 by conventional means and is disposed against the case 20 and against the flange 145 to prevent the air 85 from entering the area 100 closed by the heat shield if not desired. The finger seal 150, is one embodiment and it should be apparent to those skilled in the art that the forward heat shield can be attached by other means, including a band clamp (not shown).

[0024] Referring to Figure 3A, the face 105 of the heat shield may have an electro mechanical device 155 that engages a boss 160 in the slot 120 to move the strap radially or about an axis 165 of the engine 15. This electromechanical device 155, such as a solenoid or the like) is attached to a controller 170, as will be discussed herein, via a rod 175 attaching to the tab 175 attached to the strap 125. The strap is placed within the races 140 within the back 130 of face 105 and is controlled by the electromechanical device 155 to move the strap 125 slots 145 into an out of registry with the openings 110 in the face 105 of the heat shield 70. One may also recognize that the strap may be rotated by a remote linkage (not shown) or the like.

[0025] The heat shield has several openings 180 therein to allow the boss 55 that extends from the duct system 50 to pass therethrough to provide a cooling air to the low pressure turbine blades 35 of the engine 15. PA-11444U;67097-1307

[0026] Referring now to Figure 4 and Figures 1-3, the operation of the heat shield is described. If the air craft is maneuvering, the strap 125 is rotated in its races 140 so that the slots 145 in the strap 125 do not align with the openings 110 in the face 105. Air 85 cannot enter the space 100 and the case 20 is not cooled. Clearance between the blade 30 and the case 20 is allowed to grow thereby minimizing a possibility of tip-to-case interference.

[0027] Referring now to Figure 5 and Figures 1-3, the operation of the heat shield 70 is described. If the aircraft 10 is in a steady state, e.g., where it is neither cruising nor maneuvering but cooling is somewhat effecting and maneuvering is possible, the strap 125 is rotated in its races 140 so that the slots 145 in the strap 125 align partially with the openings 110 in the face 105. Some air 85 enters the space 100 and the case 20 is cooled a degree. Clearance between the blade 30 and the case 20 is being controlled to a degree thereby starting to minimize fuel consumption.

[0028] Referring now to Figure 6 and Figures 1-3, the operation of the heat shield is described. If the air craft is cruising, e.g., where maneuvering is not anticipated, the strap 125 is rotated in its races 140 so that the slots 145 in the strap 125 align with the openings 110 in the face 105. Air 85 enters the space 100 and the case 20 is cooled to minimize tip clearance and to minimize fuel consumption.

[0029] This simple, light-weight CCS may provide a fuel efficiency benefit, in the range of 0.5% - 1.0% TSFC (thrust specific fuel consumption).

[0030] Although a combination of features is shown in the illustrated examples, not all of them need to be combined to realize the benefits of various embodiments of this disclosure. In other words, a system designed according to an embodiment of this disclosure will not necessarily include all of the features shown in any one of the Figures or all of the portions schematically shown in the Figures. Moreover, selected features of one example embodiment may be combined with selected features of other example embodiments.

[0031] The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed examples may become apparent to those skilled in the art that do not necessarily depart from the essence of this disclosure. The scope of legal protection given to this disclosure can only be determined by studying the following claims.