COMBUSTOR FOR GAS TURBINE ENGINE

Abstract

In a combustor for a gas turbine engine, a radially outer end part of a dilution air introduction passage is radially slidably fitted into an inner periphery of an outer opening. A radially inner end part of the passage axially slidably abuts against an open edge of an inner opening. Therefore, even if outer and inner wall parts undergo relative movement in radial or axial direction due to difference in thermal expansion amount, it is possible to prevent occurrence of excessive stress and ensure airtightness for the outer and inner openings, stabilizing amount of dilution air introduced into a combustion chamber. Air does not leak into space between the outer and inner wall parts from the radially outer end part, therefore, air jet passing through an impingement cooling hole of the outer wall part collides with the inner wall part without disturbed, enhancing cooling effect of the inner wall part.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims priority under 35 U.S.C. § 119 to Japanese Patent Application No. 2019-41205 filed Mar. 7, 2019 the entire contents of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a combustor for a gas turbine engine, comprising an outer wall part having formed therein an impingement cooling hole, an inner wall part having formed therein an effusion cooling hole, and a tubular dilution air introduction passage providing a connection between an outer opening formed in the outer wall part and an inner opening formed in the inner wall part, the dilution air introduction passage introducing dilution air into a combustion chamber.

Description of the Related Art

U.S. Pat. No. 8,161,752 B2 has made known an arrangement in which an insert 174 (dilution air introduction passage) that connects a low temperature wall 156 (outer wall part) and a high temperature wall 154 (inner wall part) of a combustor 100 of a gas turbine engine and introduces dilution air to a combustion chamber 116 includes a cylindrical part 220 and a conical part 222 opening in a funnel shape from the cylindrical part 220, the cylindrical part 220 extends through an opening of the high temperature wall 154 and extends to the interior of the combustion chamber 116, and the conical part 222 opposes an opening 170 of the low temperature wall 156 via a gap 284.

In the conventional arrangement, there is a possibility that, since the gap 284 is present between the open end of the conical part 222 of the insert 174 and the opening of the low temperature wall 156, cooling air flowing between the low temperature wall 156 and the high temperature wall 154 will leak to the interior of the insert 174, the amount of dilution air supplied to the combustion chamber 116 will become unstable, the flow rate of cooling air 216 passing through an effusion cooling hole 214 of the high temperature wall 154 will decrease, and the cooling effect of the high temperature wall 154 will be degraded. There is also a possibility that, since the cylindrical part 220 of the insert 174 protrudes into the combustion chamber 116, the extremity of the cylindrical part 220 will be thermally damaged.

SUMMARY OF THE INVENTION

The present invention has been accomplished in light of the above circumstances, and it is an object thereof to stabilize the amount of dilution air introduced into a combustion chamber via a dilution air introduction passage while ensuring the cooling performance and durability of a combustor.

In order to achieve the object, according to a first aspect of the present invention, there is provided a combustor for a gas turbine engine, comprising an outer wall part having formed therein an impingement cooling hole, an inner wall part having formed therein an effusion cooling hole, and a tubular dilution air introduction passage providing a connection between an outer opening formed in the outer wall part and an inner opening formed in the inner wall part, the dilution air introduction passage introducing dilution air into a combustion chamber, wherein a radially outer end part of the dilution air introduction passage is radially slidably fitted into an inner periphery of the outer opening, and a radially inner end part of the dilution air introduction passage axially slidably abuts against an open edge of the inner opening.

In accordance with the first aspect, dilution air is introduced into the combustion chamber via the tubular dilution air introduction passage, which provides a connection between the outer opening formed in the outer wall part and the inner opening formed in the inner wall part, thus enabling the temperature distribution of the combustion chamber outlet to be appropriately maintained. With regard to the inner wall part, which faces the combustion chamber and therefore easily attains a high temperature, the outer face of the inner wall part is cooled due to air passing through the impingement cooling hole provided in the outer wall part colliding therewith, the inner face of the inner wall part is cooled by an air film formed by the air passing through the effusion cooling hole provided in the inner wall part, and it is thus protected from high temperature combustion gas.

Since the radially outer end part of the dilution air introduction passage is radially slidably fitted into the inner periphery of the outer opening, and the radially inner end part of the dilution air introduction passage axially slidably abuts against the open edge of the inner opening, even if the outer wall part and the inner wall part undergo relative movement in the radial direction or in the axial direction due to a difference in the amount of thermal expansion, not only is it possible to prevent an excessive stress from being generated, but it is also possible to ensure airtightness for both the outer opening and the inner opening of the dilution air introduction passage, thereby stabilizing the amount of dilution air introduced into the combustion chamber via the dilution air introduction passage and appropriately maintaining the temperature distribution at the combustor outlet. Moreover, since air is prevented from leaking into a space between the outer wall part and the inner wall part from the radially outer end part of the dilution air introduction passage, air passing through the impingement cooling hole of the outer wall part collides with the inner wall part without decreasing the flow rate, thus enhancing the cooling effect of the inner wall part.

According to a second aspect of the present invention, in addition to the first aspect, the inner opening protrudes from the inner wall part radially outward in a tubular shape.

In accordance with the second aspect, since the inner opening protrudes from the inner wall part radially outward in a tubular shape, the inner opening does not protrude into the combustion chamber from the inner wall part, thus preventing the inner opening from protruding into the combustion chamber and being thermally damaged.

According to a third aspect of the present invention, in addition to the second aspect, the radially inner end part of the dilution air introduction passage includes an annular flange portion, the annular flange portion axially slidably abutting against the open edge of the inner opening.

In accordance with the third aspect, since the radially inner end part of the dilution air introduction passage includes the annular flange portion, which axially slidably abuts against the open edge of the inner opening, even if the dilution air introduction passage, which moves in the axial direction integrally with the outer wall part, undergoes relative movement in the axial direction with respect to the inner wall part, airtightness can be ensured in a range in which the open edge of the inner opening does not become detached from the annular flange portion, and it is possible to reliably ensure airtightness for the radially inner end part of the dilution air introduction passage.

The above and other objects, characteristics and advantages of the present invention will be clear from detailed descriptions of the preferred embodiments which will be provided below while referring to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing the overall structure of a gas turbine engine. (first embodiment)

FIG. 2 is an enlarged view of part 2 in FIG. 1. (first embodiment)

FIG. 3 is an enlarged view of part 2 in FIG. 1. (second embodiment)

DESCRIPTION OF THE PREFERRED EMBODIMENTS

First Embodiment

A first embodiment of the present invention is explained below by reference to FIG. 1 and FIG. 2. In the present specification, the axial direction is defined as a direction in which a low pressure system shaft 15 and a high pressure system shaft 16 of a gas turbine engine extend, and the radial direction is defined as a direction orthogonal to the axial direction.

As shown in FIG. 1, a gas turbine engine for an airplane to which the present invention is applied includes an outer casing 11 and an inner casing 12, a front part and a rear part of a low pressure system shaft 15 being rotatably supported in the interior of the inner casing 12 via a front first bearing 13 and a rear first bearing 14 respectively. A tubular high pressure system shaft 16 is relatively rotatably fitted around the outer periphery of an axially intermediate part of the low pressure system shaft 15, a front part of the high pressure system shaft 16 is rotatably supported on the inner casing 12 via a front second bearing 17, and a rear part of the high pressure system shaft 16 is relatively rotatably supported on the low pressure system shaft 15 via a rear second bearing 18.

A front fan 19 having a blade tip facing an inner face of the outer casing 11 is fixed to the front end of the low pressure system shaft 15; part of the air sucked in by the front fan 19 passes through stator vanes 20 disposed between the outer casing 11 and the inner casing 12, part thereof then passes through an annular bypass duct 21 formed between the outer casing 11 and the inner casing 12 and is made to issue rearward, and the rest of the air is supplied to an axial low pressure compressor 22 and a centrifugal high pressure compressor 23 disposed in the interior of the inner casing 12.

The low pressure compressor 22 includes stator vanes 24 that are fixed in the interior of the inner casing 12 and a low pressure compressor wheel 25 that includes compressor blades on the outer periphery and is fixed to the low pressure system shaft 15. The high pressure compressor 23 includes stator vanes 26 that are fixed in the interior of the inner casing 12 and a high pressure compressor wheel 27 that includes compressor blades on the outer periphery and is fixed to the high pressure system shaft 16.

A reverse flow combustor 29 is disposed to the rear of a diffuser 28 that is connected to the outer periphery of the high pressure compressor wheel 27, and fuel is injected into the interior of the reverse flow combustor 29 from a fuel injection nozzle 30. The fuel and air are mixed in the interior of the reverse flow combustor 29 and undergo combustion, and the combustion gas thus generated is supplied to a high pressure turbine 31 and a low pressure turbine 32.

The high pressure turbine 31 includes nozzle guide vanes 33 fixed in the interior of the inner casing 12 and a high pressure turbine wheel 34 that includes turbine blades on the outer periphery and is fixed to the high pressure system shaft 16. The low pressure turbine 32 includes nozzle guide vanes 35 fixed in the interior of the inner casing 12 and a low pressure turbine wheel 36 that includes turbine blades on the outer periphery and is fixed to the low pressure system shaft 15.

Therefore, when the high pressure system shaft 16 is driven by means of a starter motor, which is not illustrated, air sucked in by the high pressure compressor wheel 27 is supplied to the reverse flow combustor 29, is mixed with fuel, and undergoes combustion, and the combustion gas thus generated drives the high pressure turbine wheel 34 and the low pressure turbine wheel 36. As a result, the low pressure system shaft 15 and the high pressure system shaft 16 rotate and the front fan 19, the low pressure compressor wheel 25, and the high pressure compressor wheel 27 compress air and supply it to the reverse flow combustor 29, and the gas turbine engine thus continues to run even when the starter motor is stopped.

While the gas turbine engine is running, part of the air sucked in by the front fan 19 passes through the bypass duct 21, is made to issue rearward, and generates the main thrust, particularly at a time of low speed flying. The rest of the air sucked in by the front fan 19 is supplied to the reverse flow combustor 29, is mixed with fuel, undergoes combustion, drives the low pressure system shaft 15 and the high pressure system shaft 16, is then made to issue rearward, and generates a thrust.

The reverse flow combustor 29 is formed from an outside liner portion 29a extending forward from a position at which the fuel injection nozzle 30 is provided, and an outside turn duct portion 29b that extends rearward while bending through 1800 from the front end of the outside liner portion 29a and is connected to the nozzle guide vanes 33. As is shown in FIG. 2 in an enlarged state, the outer shell of the reverse flow combustor 29 has a double layer structure formed from an inner wall part 42 facing a combustion chamber 41 and an outer wall part 43 covering the outer side of the inner wall part 42, the inner wall part 42 having a large number of effusion cooling holes 42a formed therein and the outer wall part 43 having a large number of impingement cooling holes 43a formed therein. The effusion cooling holes 42a of the inner wall part 42 are inclined together in the same direction so as to extend obliquely through the inner wall part 42, and the impingement cooling holes 43a extend through the outer wall part 43 so as to be orthogonal to the inner wall part 42 in their vicinity.

A plurality of dilution air introduction passages 44 are provided in the outside liner portion 29a of the reverse flow combustor 29, the dilution air introduction passage 44 extending through the inner wall part 42 and the outer wall part 43. The dilution air introduction passage 44 includes a cylindrical passage portion 44a and an annular flange portion 44b formed by bending a radially inner end of the passage portion 44a outward through right angles. A short cylindrical outer opening 43b bending inward in the radial direction is formed in the outer wall part 43, and the cylindrical passage portion 44a of the dilution air introduction passage 44 is radially slidably fitted into the outer opening 43b. A short cylindrical inner opening 42b bending outward in the radial direction is formed in the inner wall part 42, and the annular flange portion 44b of the dilution air introduction passage 44 abuts against the open edge of the inner opening 42b from the radially outer side.

While the gas turbine engine is running, the annular flange portion 44b of the dilution air introduction passage 44 abuts against the inner opening 42b of the inner wall part 42 due to a difference in air pressure, but in order to reliably make the annular flange portion 44b abut against the inner opening 42b when starting the gas turbine engine, it is possible to urge the dilution air introduction passage 44 toward the inner wall part 42 by means of a conical spring 45.

The operation of the embodiment of the present invention having the above arrangement is now explained.

High pressure air that has been compressed by the low pressure compressor 22 and the high pressure compressor 23 and supplied from the diffuser 28 to a space encircling the reverse flow combustor 29 is supplied from an outer peripheral part of the fuel injection nozzle 30 to the combustion chamber 41 of the reverse flow combustor 29, mixed with fuel injected from the fuel injection nozzle 30, and subjected to combustion. At the same time as this, high temperature combustion gas is diluted with air that has been introduced into the combustion chamber 41 through the plurality of dilution air introduction passages 44, thus appropriately maintaining the temperature distribution of combustion gas discharging from the reverse flow combustor 29.

Furthermore, the inner wall part 42 of the reverse flow combustor 29 facing the combustion chamber 41 attains a high temperature, but due to air passing through the impingement cooling hole 43a formed in the outer wall part 43 colliding with the inner wall part 42 at right angles the high temperature inner wall part 42 is thus cooled. Air that has passed through the impingement cooling hole 43a further passes through the effusion cooling hole 42a of the inner wall part 42 and forms an air film along an inner face of the inner wall part 42. The high temperature inner wall part 42 is cooled by the air film preventing combustion gas of the combustion chamber 41 from making direct contact with the inner face of the inner wall part 42.

While the gas turbine engine is running, since each member undergoes relative movement in the axial direction and the radial direction of the gas turbine engine due to a difference in the amount of thermal expansion, it is necessary to absorb the relative movement, thus preventing excessive stress from being generated in each member.

In particular, since a large difference in temperature is caused between the low temperature outer wall part 43 and the high temperature inner wall part 42 of the reverse flow combustor 29, the amount of relative movement in the axial direction and the radial direction between the inner wall part 42 and the outer wall part 43 becomes large in a section of the dilution air introduction passage 44, and there is a possibility that excessive stress will be generated and the amount of dilution air will become unstable.

However, in accordance with the present embodiment, even if the inner wall part 42 and the outer wall part 43 undergo relative movement in the radial direction, due to the cylindrical passage portion 44a of the dilution air introduction passage 44 sliding radially with respect to the outer opening 43b of the outer wall part 43, it is possible to absorb the relative movement in the radial direction between the inner wall part 42 and the outer wall part 43 while preventing air from leaking via the outer opening 43b.

Moreover, even if the inner wall part 42 and the outer wall part 43 undergo relative movement in the axial direction, due to the annular flange portion 44b of the dilution air introduction passage 44 sliding in the axial direction with respect to the inner opening 42b of the inner wall part 42, it is possible to absorb the relative movement in the axial direction between the inner wall part 42 and the outer wall part 43 while preventing air from flowing into the dilution air introduction passage 44.

In this way, since the air in the space sandwiched between the outer wall part 43 and the inner wall part 42 does not flow into the dilution air introduction passage 44, it becomes possible to stabilize the amount of dilution air that passes through the dilution air introduction passage 44 and is supplied to the combustion chamber 41, thus enabling the temperature distribution of combustion gas at the outlet of the reverse flow combustor 29 to be appropriately maintained. Moreover, since the air in the space sandwiched between the outer wall part 43 and the inner wall part 42 does not flow into the dilution air passage 44, the flow rate of air passing through the effusion cooling hole 42a of the inner wall part 42 will not decrease, thus enhancing the cooling effect of the inner wall part 42.

Furthermore, since the inner opening 42b of the inner wall part 42 does not protrude into the combustion chamber 41 but does protrude into the space sandwiched between the outer wall part 43 and the inner wall part 42, it is possible to prevent the inner opening 42b of the inner wall part 42 from being directly exposed to high temperature combustion gas flowing through the interior of the combustion chamber 41 and being thermally damaged.

Second Embodiment

A second embodiment of the present invention is now explained by reference to FIG. 3.

In the first embodiment the outer opening 43b of the outer wall part 43 protrudes radially inward toward the inner wall part 42, but in the second embodiment the outer opening 43b of the outer wall part 43 protrudes radially outward so as to be away from the inner wall part 42.

In accordance with the second embodiment, the same effects as those of the first embodiment can also be achieved.

Embodiments of the present invention are explained above, but the present invention may be modified in a variety of ways as long as the modifications do not depart from the gist of the present invention.

For example, a combustor to which the present invention is applied is not necessarily a reverse flow type.

Claims

1. A combustor for a gas turbine engine, comprising

an outer wall part having formed therein an impingement cooling hole,

an inner wall part having formed therein an effusion cooling hole, and

a tubular dilution air introduction passage providing a connection between an outer opening formed in the outer wall part and an inner opening formed in the inner wall part, the dilution air introduction passage introducing dilution air into a combustion chamber,

wherein a radially outer end part of the dilution air introduction passage is radially slidably fitted into an inner periphery of the outer opening, and

a radially inner end part of the dilution air introduction passage axially slidably abuts against an open edge of the inner opening.

2. The combustor for a gas turbine engine according to claim 1, wherein the inner opening protrudes from the inner wall part radially outward in a tubular shape.

3. The combustor for a gas turbine engine according to claim 2, wherein the radially inner end part of the dilution air introduction passage includes an annular flange portion, the annular flange portion axially slidably abutting against the open edge of the inner opening.