An adapter to permit borescope access inside a gas turbine engine including a compressor stator having a plurality of compressor stator segments comprises a body portion defining a bore extending longitudinally therethrough from a first end to be disposed adjacent to outside surfaces of adjacent compressor stator segments to a second end to be disposed adjacent to inside surfaces of adjacent compressor stator segments. The bore permits a borescope to enter therethrough. The adapter further comprises an attachment portion for circumferentially coupling at least one compressor stator segment to an outer casing of the gas turbine engine.
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1. An adapter to permit borescope access inside a gas turbine engine having an outer casing and including a compressor stator having at least one compressor stator segment, the adapter comprising:
a body portion defining a bore extending longitudinally therethrough from a first end to be disposed adjacent to outside surfaces of the outer casing to a second end to be disposed adjacent to an inside surface of the at least one compressor stator segment, the bore permitting a borescope to enter therethrough, the body portion including an outer wall having a shaped feature configured to engage a correspondingly shaped feature on the at least one compressor stator segment; and
an attachment portion for circumferentially coupling the at least one compressor stator segment to the outer casing, the attachment portion including a flange extending from the outer wall and configured to be secured to the outer casing.
11. A gas turbine engine comprising:
a compressor section having an outer casing and including a compressor stator and rotor, the compressor stator including a plurality of compressor stator segments;
a combustion section communicating with and disposed downstream of the compressor section relative to a direction of airflow;
a gas turbine section communicating with and disposed downstream of the combustion section relative to a direction of airflow; and
an adapter circumferentially coupling at least one of the compressor stator segments to the outer casing, the adapter including a body portion defining a bore extending therethrough from at least an outside surface to an inside surface of an associated compressor stator segment, the bore permitting a borescope to enter therethrough, the body portion including an outer wall having a shaped feature configured to engage a correspondingly shaped feature on the at least one compressor stator segment, wherein the adapter further includes a flange for coupling the associated compressor stator segment to the outer casing.
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0. 12. A gas turbine engine as defined in
13. A gas turbine engine as defined in claim 12 11, wherein the flange includes a first portion extending outwardly from the body portion for coupling one of the at least one compressor stator segments to the outer casing, and includes a second portion extending outwardly from the body portion in a direction generally opposite to that of the first portion for coupling another of the at least one compressor stator segments to the outer casing.
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21. A gas turbine engine as defined in
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This invention was made with Government support under N00019-02-C-3003 awarded by the United States Navy. The Government has certain rights in this invention.
This invention relates generally to gas turbine engines, and more particularly to borescope inspection port devices for gas turbine engines.
Gas turbine engines are commonly equipped with pluggable holes in their outer casings to allow use of borescopes. These are fiber-optic devices that allow visual inspection of the interior of the engine without disassembling it, which is a major advantage to operators. However, the presence of the hole in the casing tends to locally disrupt the smooth flow of air through the engine along the casing walls. It can also be a path of leakage of high-pressure air into areas where it does not contribute to the engine's performance. This is true even though the ports are filled with a plug that is removed for borescope access, since the fit of the plug may not be—and normally is not—perfect.
Because the borescope access hole typically penetrates more than one component of a gas turbine engine, some allowance must be made for variations in the location of the hole in each of these components. This is usually accomplished by making the holes larger than they would otherwise need to be for borescope access. The increased size of the holes aggravates the airflow disruption and leakage problem.
One common design for a gas turbine engine compressor uses multiple segments of stator vanes inserted into the casing. Design features, such as anti-rotation lugs, fix the stator segments into the casing circumferentially, preventing them from spinning in place. Although this approach provides a number of advantages, it adds a part into the “stack” of engine parts through which the borescope access port must penetrate. The port's location is normally fixed by the locations and designs of the engine components on the outside of the casings, and of the aircraft or other location in which the engine is installed. The further away from the anti-rotation lugs the stator segments' borescope port is placed, the more variation there can be in the port's location relative to the external features, which usually are used to locate the removable plug itself.
Accordingly, it is an object of the present invention to provide a borescope port and gas turbine engine incorporating such port that overcomes the above-mentioned drawbacks and disadvantages.
In a first aspect of the present invention, an adapter, to permit borescope access inside a gas turbine engine having an outer casing including a Compressor stator having at least one compressor stator segment, comprises a body portion defining a bore extending longitudinally therethrough from a first end to be disposed adjacent to outside surfaces of the outer casing to a second end to be disposed adjacent to an inside surface of the at least one compressor stator segment. The bore permits a borescope to enter therethrough. The adapter further comprises an attachment portion for circumferentially coupling the at least one compressor stator segment to the outer casing.
In a second aspect of the present invention, a gas turbine engine comprises a compressor section having an outer casing and includes a compressor stator and rotor. The compressor stator includes a plurality of compressor stator segments. A combustion section communicates with and is disposed downstream of the compressor section relative to a direction of airflow. A gas turbine section communicates with and is disposed downstream of the combustion section relative to a direction of airflow. An adapter circumferentially couples at least one of the compressor stator segments to the outer casing. The adapter includes a body portion defining a bore extending therethrough from at least an outside surface to an inside surface of an associated compressor stator segment. The bore permits a borescope to enter therethrough.
With reference to
Preferably, a circumferential portion of an outer wall 56 of the body portion 42 is shaped for engaging a similarly shaped portion of at least one compressor stator segment 52 to prevent rotation of the compressor stator segment and the outer casing 51 relative to each other. As best shown in
Providing the adapter 40, for coupling the compressor stator segments 52 to the outer casing 51 in a circumferential direction, with a bore 44 for borescope access within a gas turbine engine eliminates variations in the location of a borescope port relative to the outer casing of the gas turbine engine. The adapter 40 in accordance with the present invention allows a smaller and less leak-prone design to be employed, and results in increased engine performance. The gas turbine engine and adapter in accordance with the present invention also reduces the number of machined components, thus resulting in a lighter and less costly engine.
As will be recognized by those of ordinary skill in the pertinent art, numerous modifications and substitutions can be made to the above-described embodiment of the present invention without departing from the scope of the invention. Accordingly, the preceding portion of this specification is to be taken in an illustrative, as opposed to a limiting sense.
Clouse, Brian Ellis, Dube, David P.
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