AIRFLOW CONTROL FOR AIR TURBINE STARTER
An example arrangement for cooling a gas turbine engine includes an air turbine starter having a turbine section for rotationally driving a compressor through rotation of a shaft. An starter air valve is configured to control a flow of pressurized air that flows downstream towards turbine blades of the air turbine starter. An airflow adjustment device (AAD) is configured to adjust the flow when a manual override feature of the starter air valve is engaged based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor. A governor is configured to control a degree to which the AAD adjusts the flow. The governor is mechanically linked to the shaft through one or more gears and configured to adjust the AAD such that a rotational speed of said one the shafts does not exceed a predefined threshold during a particular operating mode.
This application is a continuation of U.S. application Ser. No. 15/875,920 which was filed on Jan. 19, 2018, and is incorporated herein by reference in its entirety.
BACKGROUNDThis application relates to an air turbine starter, and more particularly to airflow control for an air turbine starter.
Gas turbine engines are known and typically include a fan delivering air into a bypass duct for propulsion. The fan also delivers air into a compressor where air is compressed and delivered into a combustor. The air is mixed with fuel and ignited. Products of this combustion pass downstream over turbine rotors driving them to rotate. The turbine rotors, in turn, rotate compressor rotors and the fan rotor.
An air turbine starter is typically included with a gas turbine engine for starting the gas turbine engine. The air turbine starter receives pressurized air from an auxiliary power unit when it is desired to start a gas turbine engine. The air turbine starter is connected to drive a compressor section of the gas turbine engine. When the air turbine starter receives the pressurized air, its turbine is driven to rotate, to in turn start rotation of the compressor section in the gas turbine engine through “motoring.”
Some gas turbine engines exhibit a so-called “bowed rotor” condition whereby certain components exhibit different thermal expansion from engine use, causing a shaft of a gas turbine engine, such as the “Ni” shaft that interconnects a fan, low pressure compressor, and low pressure turbine of the gas turbine engine, or “N2” shaft that interconnects a high pressure compressor and high compressor turbine, to become bowed.
Starting up and idling an engine exhibiting a bowed rotor condition without sufficiently cooling the engine is undesirable, because rotor blades may not be properly centered and may excessively rub into a housing. This poses challenges for aircraft with short turnarounds between flights, because a gas turbine engine may take several hours of standstill cooling to fully resolve a bowed rotor condition.
Low speed motoring of a gas turbine engine exhibiting a bowed rotor condition at sub-idling rotational speeds is a method to shorten the time needed for cooling.
SUMMARYOne example embodiment of an arrangement for cooling a gas turbine engine includes an air turbine starter, a starter air valve, and an airflow adjustment device. The air turbine starter includes a turbine section for rotationally driving a compressor of a gas turbine engine through rotation of a shaft that connects the turbine section to the compressor. The starter air valve is configured to control a flow of pressurized air along a flow path from a source to turbine blades of the turbine section. The starter air valve includes a manual override feature that allows manual opening of the starter air valve. The airflow adjustment device is configured to adjust the flow of pressurized air along the flow path when the manual override feature is engaged based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor.
One other example embodiment of arrangement for cooling a gas turbine engine includes an air turbine starter, an airflow adjustment device, and a governor. The air turbine starter includes a turbine section and an inlet duct in fluid communication with the turbine section. The turbine section is configured for driving a compressor of a gas turbine engine through rotation of a shaft that interconnects the turbine section and the compressor. The airflow adjustment device is configured to adjust a flow of pressurized air from a source to turbine blades of the turbine section. The governor is mechanically linked to the shaft through one or more gears and is configured to operate the airflow adjustment device to adjust the flow based on a rotational speed of one of the shaft and an additional shaft driven by the compressor, such that the rotational speed of said one of the shafts does not exceed a selected threshold during a particular operating mode.
One example embodiment of a method of motoring a gas turbine engine includes delivering a flow of pressurized air along a flow path to a turbine section of an air turbine starter. The flow path passes through a starter air valve, and the pressurized air causes the air turbine starter to rotate a compressor of a gas turbine engine through rotation of a shaft that interconnects the turbine section and the compressor. The method includes manually opening the air starter valve if needed. When the starter air valve is manually opened, a degree to which an airflow adjustment device adjusts the flow of pressurized air is controlled based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor.
One example embodiment of an arrangement for cooling a gas turbine engine includes an air turbine starter having a turbine section for rotationally driving a compressor of a gas turbine engine through rotation of a shaft that connects the turbine section to the compressor. A starter air valve is configured to control a flow of pressurized air along a flow path that flows downstream towards turbine blades of the turbine section, the starter air valve having a manual override feature that allows manual opening of the starter air valve. An airflow adjustment device is configured to adjust the flow of pressurized air along the flow path when the manual override feature is engaged based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor. A governor is configured to control a degree to which the airflow adjustment device adjusts the flow, the governor mechanically linked to the shaft through one or more gears and configured to adjust the airflow adjustment device such that a rotational speed of said one of the shafts does not exceed a predefined threshold during a particular operating mode.
One example embodiment of a method of cooling a gas turbine engine includes delivering a flow of pressurized air along a flow path to turbine blades of a turbine section of an air turbine starter, the flow path passing through a starter air valve, the pressurized air causing the air turbine starter to rotate a compressor of a gas turbine engine through rotation of a shaft that interconnects the turbine section and the compressor. The method includes controlling a degree to which an airflow adjustment device adjusts the flow of pressurized air to the turbine section when the starter air valve is manually opened based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor. The controlling includes utilizing a governor mechanically linked to the shaft through one or more gears and configured to adjust the airflow adjustment device such that a rotational speed of said one of the shafts does not exceed a predefined threshold during a particular operating mode.
The embodiments, examples, and alternatives of the preceding paragraphs, the claims, or the following description and drawings, including any of their various aspects or respective individual features, may be taken independently or in any combination. Features described in connection with one embodiment are applicable to all embodiments, unless such features are incompatible.
The cool-down motoring draws air into the gas turbine engine 20, which expedites cooling of the gas turbine engine 20 and mitigation of the bowed rotor condition The cool-down motoring is performed such that rotors of the compressor section 24 (e.g., a low pressure compressor of the compressor section 24) rotate at sub-idling rotational speeds without achieving a full start condition.
A starter air valve 104 controls a flow of pressurized air from a source 102 along an flow path 100 to the air turbine starter 110 for cool-down motoring and engine startup. In the example of
The starter air valve 104 may exhibit a fault condition, such as failing to open. To address this, the starter air valve 104 includes a manual override feature 116 that includes a tool interface 118 for engaging the override feature and actuating the starter air valve 104 open. The tool interface 118 may be engaged by a technician on the ground, for example. Once opened, the starter air valve 104 on its own may provide too much airflow to the air turbine starter 110, potentially driving the compressor section 24 at a rotational speed that is too fast for cool-down motoring.
An airflow adjustment device 106 is in series with the starter air valve 104 in the flow path 100, and is configured to limit the flow of pressurized air along the flow path 100 when the starter air valve 104 is manually overridden to an open position. Optionally, the airflow adjustment device 106 can also be utilized in conjunction with the starter air valve 104 when the starter air valve 104 is functioning properly. The airflow adjustment device 106 can include a valve, a resizable inlet duct of the air turbine starter 110, or adjustable vanes of the air turbine starter 110, for example.
A controller 120 controls the degree to which the airflow adjustment device 106 adjusts the flow in the flow path 100 to provide an amount of airflow to the air turbine starter 110 that will motor the gas turbine engine 20 at a sub-idle speed until a bowed rotor condition of the gas turbine engine 20 has diminished sufficiently, without achieving a full start condition.
The controller 120 controls the airflow adjustment device 106 based on a rotational speed of the shaft 114 that interconnects the air turbine starter 110 to the compressor section 24 (e.g., or alternatively shaft 70 or 82 as shown in
In one example, the controller 120 is configured with a mapping of rotational speeds of one of the shafts 70, 82, 114 to rotational speeds of the inner shaft and outer shaft so that the rotational speed of the measured shaft can conveniently be used as a benchmark to ensure that a rotational speed of the inner and/or outer shaft does not exceed a desired rotational speed for cool-down motoring.
In one example, the controller 120 is configured to perform cool-down motoring at a given rotational speed for a particular one of the shafts for a predefined time period. This time may be based on an engine type of the gas turbine engine 20 and/or a duration of a previous flight that the gas turbine engine 20 was just utilized for.
In one example, the controller 120 includes an electromechanical interface device, such as a pulse width modulated solenoid, a servomotor, or a torque motor, that controls the airflow adjustment device 106 based on input from a speed sensor 122 (see, e.g.,
In another example, the controller 120 includes a mechanical governor device that is mechanically linked to one of the shafts discussed above and includes flyweights configured to move outward when a centrifugal force is applied through an increased a speed of rotation. Also, other governors may be useful in the arrangement 10.
Although the airflow adjustment device 106 is depicted downstream of the starter air valve 104 in the flow path 100, it is understood that the airflow adjustment device 106 could instead be upstream of the starter air valve 104 in the flow path 100, or could be incorporated into the air turbine starter 110.
The compressed air flows past the vanes 72, drives the turbine wheel 65, and is then exhausted through an outlet 81. The turbine wheel 65 is driven by the pressurized airflow such that the turbine rotor shaft 70 mechanically drives a starter output shaft 82 though a gear system 84, such as a planetary gear system. In the example of
The turbine rotor shaft 70 and starter output shaft 82 are collinear with a central longitudinal axis D of the air turbine starter 110. The turbine blades 66 extend radially outward from the central longitudinal axis D and rotate about the central longitudinal axis D.
In this disclosure, like reference numerals from 100 to 972 designate like elements where appropriate, and reference numerals with the addition of one-hundred or multiples thereof designate modified elements that are understood to incorporate the same features and benefits of the corresponding elements.
The active bleed valve 206 is normally in a closed position, but can be opened by controller 220 to release pressurized air from the flow path 100.
The controller 220 could include a pulse width modulated solenoid, a servomotor, or a torque motor that controls the active bleed valve 206, for example.
After a bowed rotor condition of the gas turbine engine 20 is mitigated, the controller 220 is configured to cause the active bleed valve 206 to fully close for starting the gas turbine engine 20.
After a bowed rotor condition of the gas turbine engine 20 is mitigated, the controller 320 is configured to cause the shutter valve 306 to fully open for starting the gas turbine engine 20, and then optionally to fully close once the gas turbine engine 20 is started.
In the example of
In one example, the butterfly valve 406 is normally in a fully open position, and is selectively adjusted to a more closed position by an actuator 466 that is coupled to the butterfly valve 406 through a mechanical link 468 based on a rotational speed of the turbine rotor shaft 70. The actuator 466 is driven to rotate butterfly valve 406 through increased pressure in pneumatic lines 434, 436. Alternatively, the lines 434, 436 can be other types of pressure-based lines, such as hydraulic or fueldraulic lines.
The governor 420 is fluidly connected to the actuator 432 through the pneumatic lines 434, 436 and is configured to adjust a pressure in the lines based on a rotational speed of the shaft 70. In one example, the mechanical governor 420 includes flyweights configured to move outward when a centrifugal force applied by rotation of the shaft 70 increases due to an increased rotational speed of the shaft 70. Outward movement of the flyweights causes a pressure in the lines 434, 436 to increase, driving actuator 466 to rotate the butterfly valve 406 and close the butterfly valve 406 (e.g., by the governor 420 acting as a fluid motor that increases pressure in the pneumatic lines 434, 436).
After a bowed rotor condition of the gas turbine engine 20 is mitigated, a digital control 440 utilizes a governor shut off feature 438 to cause the butterfly valve 406 to fully open (e.g., by disengaging the governor 420 from the shaft 70 or dumping pneumatic pressure in lines 434, 436) for starting the gas turbine engine 20, and then optionally fully closes the butterfly valve 406 once the gas turbine engine 20 is started (e.g., by increasing pressure in the lines 434, 436).
In another example, the gears 430 could couple the mechanical governor 420 to the starter output shaft 82 instead of to the turbine rotor shaft 70.
Although
In one example, the openings 544 of the discs 542A-B are fully aligned by default and are biased to that fully aligned position. Referring again to
In one example, the mechanical governor 520 includes flyweights configured to move outward when a centrifugal force applied by rotation of the shaft 70 increases due to an increased rotational speed of the shaft 70. Outward movement of the flyweights causes extension of the shaft 548 along the central longitudinal axis D and/or rotation of the shaft 548 about the central longitudinal axis D, thereby increasing a misalignment between the openings 544 in the discs 542A-B and limiting airflow to the turbine blades 66 of the air turbine starter 510.
After a bowed rotor condition of the gas turbine engine 20 is mitigated, a governor shut off feature 538 is configured to disengage the governor 520 from the shaft 70 and/or shaft 548 as part of an electromechanical clutch, causing the air shutter 506 to return to a default, fully open position for starting the gas turbine engine 20.
After a bowed rotor condition of the gas turbine engine 20 is mitigated, the digital control 440 is configured to cause the actuator 654 rotate the disc 542B to a fully open position for starting the gas turbine engine 20, and then optionally to a fully closed position once the gas turbine engine 20 is started. The governor shut off feature 538 is controlled by the digital control 440.
In the examples discussed above, disc 542A is stationary and disc 542B rotates. In another example, disc 542B is stationary and disc 542A rotates. In another example, both of the discs 542A-B rotate.
This movement is performed by a mechanical governor 720 that corotates with the turbine rotor shaft 70, and is mechanically linked to the inner wall 778 through a shaft 752. In one example, the governor 720 includes flyweights configured to move outward when a centrifugal force applied by rotation of the shaft 70 increases due to an increased rotational speed of the shaft 70. Outward movement of the flyweights causes extension of the shaft 752 and inner wall 778 along the central longitudinal axis D, which reduces a volume of the inlet duct 76.
After a bowed rotor condition of the gas turbine engine 20 is mitigated, a governor shut off feature 738 is configured to disengage the governor 720 from the shaft 70 and/or shaft 548 as part of an electromechanical clutch, causing the inner wall 778 to return to a default, fully open position (e.g., position P1) for starting the gas turbine engine 20.
In this example, the controller 120 is a governor 920 that is mechanically linked to the turbine rotor shaft 70 through a plurality of gears 930A-B and a shaft 932. The governor 920, gears 930, and shaft 932 are configured to adjust the sync-ring 980 to implement a vane angle such that a rotational speed of the turbine rotor shaft 70 does not exceed a predefined threshold during a particular operating mode (e.g., during cool-down motoring of the gas turbine engine 20).
The governor 920 is fluidly connected to vane actuator 966 through pneumatic line 934 and is configured to adjust a pressure in the pneumatic line 934 based on a rotational speed of the shaft 70. In one example, the governor 920 includes flyweights configured to move outward when a centrifugal force applied by rotation of the shaft 70 increases due to an increased rotational speed of the shaft 70. Outward movement of the flyweights causes a pressure in the line 934 to increase, driving vane actuator 966 to adjust the sync-ring 980 by applying pressure to the vane actuator 966, which moves mechanical link 968 to rotate the sync-ring 980 about axis D. Alternatively, the line 934 can be a hydraulic or fueldraulic line.
As shown in
In the example of
Although example embodiments have been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. For that reason, the following claims should be studied to determine the scope and content of this disclosure.
Claims
1. An arrangement for cooling a gas turbine engine comprising:
- an air turbine starter comprising a turbine section for rotationally driving a compressor of a gas turbine engine through rotation of a shaft that connects the turbine section to the compressor;
- a starter air valve configured to control a flow of pressurized air along a flow path that flows downstream towards turbine blades of the turbine section, the starter air valve having a manual override feature that allows manual opening of the starter air valve;
- an airflow adjustment device configured to adjust the flow of pressurized air along the flow path when the manual override feature is engaged based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor; and
- a governor configured to control a degree to which the airflow adjustment device adjusts the flow, the governor mechanically linked to the shaft through one or more gears and configured to adjust the airflow adjustment device such that a rotational speed of said one of the shafts does not exceed a predefined threshold during a particular operating mode.
2. The arrangement of claim 1, wherein the governor is configured as a fluid motor that controls a degree to which the airflow adjustment device adjusts the flow by adjusting a pressure in a pressure-based control line that connects the governor to an actuator for the airflow adjustment device.
3. The arrangement of claim 1, comprising a governor shutoff device configured to disable the governor by disengaging the governor from the shaft or adjusting a pressure in a pressure-based control line that connects the governor to an actuator for the airflow adjustment device.
4. The arrangement of claim 1, wherein:
- the airflow adjustment device includes an additional valve; and
- the governor is configured restrict the flow of pressurized air by adjusting a position of the additional valve.
5. The arrangement of claim 4, wherein the additional valve includes an active bleed valve configured to selectively release pressurized air from the flow path.
6. The arrangement of claim 4, wherein the additional valve includes a shutter valve having a central aperture and configured to adjust the flow of pressurized air to the turbine blades by altering a flow area defined by the central aperture.
7. The arrangement of claim 4, wherein the additional valve includes a butterfly valve.
8. The arrangement of claim 1, wherein:
- the airflow adjustment device includes an air shutter situated in the flow path between the source of pressurized air and the turbine section, the air shutter including two discs; and
- the governor is configured to control a degree to which the airflow adjustment device adjusts the flow by controlling a degree to which airflow holes in the two discs are misaligned.
9. The arrangement of claim 1, wherein:
- the turbine section includes a plurality of turbine blades that extend radially outward from a central longitudinal axis;
- the air turbine starter includes an inlet duct that fluidly connects the plurality of turbine blades to the source of pressurized air; and
- the airflow adjustment device includes an inner wall of the inlet duct that is movable along the central longitudinal axis to adjust a volume of the inlet duct.
10. The arrangement of claim 1, wherein the airflow adjustment device includes a sync-ring, and rotation of the sync-ring about a central longitudinal axis of the air turbine starter adjusts vane angles of a plurality of variable vanes of the air turbine starter that are upstream of the turbine blades.
11. A method of cooling a gas turbine engine, comprising:
- delivering a flow of pressurized air along a flow path to turbine blades of a turbine section of an air turbine starter, the flow path passing through a starter air valve, the pressurized air causing the air turbine starter to rotate a compressor of a gas turbine engine through rotation of a shaft that interconnects the turbine section and the compressor; and
- controlling a degree to which an airflow adjustment device adjusts the flow of pressurized air to the turbine section when the starter air valve is manually opened based on a rotational speed of one of the shaft and an additional shaft that is driven by the compressor, said controlling includes utilizing a governor mechanically linked to the shaft through one or more gears and configured to adjust the airflow adjustment device such that a rotational speed of said one of the shafts does not exceed a predefined threshold during a particular operating mode.
12. The method of claim 11, wherein said controlling includes the governor adjusting a pressure in one or more pressure-based control lines that connect the governor to an actuator for the airflow adjustment device to control a degree to which the airflow adjustment device adjusts the flow.
13. The method of claim 11, comprising:
- disabling the governor by utilizing a governor shutoff device to disengage the governor from the shaft or adjust a pressure in a pressure-based control line that connects the governor to an actuator for the airflow adjustment device.
14. The method of claim 11, wherein:
- said airflow adjustment device includes an additional valve; and
- said controlling a degree to which the airflow adjustment device restricts the flow of pressurized air includes adjusting a position of the additional valve.
15. The method of claim 14, wherein the additional valve includes an active bleed valve.
16. The method of claim 14, wherein the additional valve includes a shutter valve having a central aperture and configured to adjust the flow of pressurized air to the turbine blades by altering a flow area defined by the central aperture.
17. The method of claim 14, wherein the additional valve includes a butterfly valve.
18. The method of claim 11, wherein:
- the airflow adjustment device includes an air shutter situated in the flow path between the source of pressurized air and the turbine section, the air shutter including two discs; and
- said controlling a degree to which the airflow adjustment device restricts the flow of pressurized air includes the control device selectively restricting the flow of pressurized air through misalignment of airflow holes in the two discs.
19. The method of claim 11, wherein:
- the airflow adjustment device includes a movable inner wall of an inlet duct of the air turbine starter that is in fluid communication with the turbine section; and
- said controlling a degree to which the airflow adjustment device reduces the flow of pressurized air includes adjusting a volume of the inlet duct by moving the inner wall along a central longitudinal axis of the air turbine starter.
20. The method of claim 11, wherein:
- the airflow adjustment device includes a sync-ring; and
- said controlling a degree to which the airflow adjustment device restricts the flow of pressurized air includes rotating the sync-ring about a central longitudinal axis of the air turbine starter to adjust vane angles of a plurality of variable vanes of the air turbine starter that are upstream of the turbine blades.
Type: Application
Filed: Mar 19, 2020
Publication Date: Jul 9, 2020
Inventors: Myles R. Kelly (Willimantic, CT), James S. Elder (South Windsor, CT)
Application Number: 16/823,457