This application relates to a starter air valve for an air turbine starter.
Gas turbine engines are known, and typically include a compressor compressing air and delivering it into a combustor where it is mixed with fuel and ignited. Products of the combustion pass downstream over turbine rotors, driving them to rotate. The turbine rotor, in turn, drives a compressor rotor.
To start a gas turbine engine, it is known to initially have a drive input to rotate the compressor rotor and the turbine rotor such that combustion can begin. Typically, an air turbine starter drives a shaft to, in turn, drive the compressor rotor to rotate. The air turbine starter is supplied with air, typically from an auxiliary power unit.
A starter air valve assembly is positioned intermediate the auxiliary power unit and the air turbine starter. The valve assembly is provided with a control valve that controls the flow of pressurized air to an actuator for a valve member.
The control valve selectively routes air to a solenoid or torque motor, for controlling the passage of the air to the actuator for the valve member.
The control valve must be operable to selectively move the actuator to positions that are less than full open prior to startup. This allows the engine to initially rotate at lower speed operation to slowly warm the engine. Engine rotors may sometimes bow due to an uneven rate of cooling at the top and bottom of the rotor, and this initial slow rotation corrects the bowing.
A starter air valve for an air turbine starter system has a valve member and an actuator. A rotary spool valve connects to a source of pressurized air. The rotary spool valve has a rotatable valve body and an outer housing. There is also an actuator control for the actuator. The rotatable valve body and the valve housing selectively provide three modes of operation for the starter air valve. A first mode of operation connects pressurized air through the rotatable valve body to communicate with the actuator control, and to receive pressurized air back from the actuator control. The rotatable valve body then communicates the air to the actuator. In a second mode the rotatable valve body blocks communication between the actuator control and the actuator, and delivers air through a variable area port in a wall of the rotatable valve body to bypass the valve member. In a third mode the rotatable valve body blocks communication between the actuator and the actuator control, and connects pressurized air to the actuator without having passed to the actuator control.
A starter air system is also disclosed.
These and other features may be best understood from the following drawings and specification.
The gas turbine engine 22 includes a fan 24, a compressor section 26, a shaft 28 and a turbine 31, all of which are shown schematically. As known compressor section 26, shaft 28 and turbine 31 may all rotate together. An auxiliary power unit (APU) 30 provides air through a starter air valve 32. An actuation assembly 34 is shown for the starter air valve 32 to control the flow of air from an APU 30 downstream to an air turbine starter system 35. Air turbine starter system 35 includes a turbine 36 and a clutch 37. The air drives the turbine 36 to, in turn, drive gears within an accessory gearbox 38 and a drive a shaft 40, which drives the shaft 28 to turn gears in the gas turbine engine 22. This drive is shown schematically, and may be generally known.
The starter air valve 32 is shown in
In an embodiment, valve member 57 may be a butterfly disk. However, this disclosure extends to systems with other valve types.
As shown in
As also shown, there are a series of gradations 1-10 that can achieve positions for operation as shown in
A second mode is shown in
As shown in
In the prior art, in this position, air was still allowed to flow between lines 82 and 84. Thus, the air intended to bypass valve member 57 could flow back to actuator control 62.
As shown in
By delivering the airflow directly to the actuator 58 in this third mode, one should be able to achieve proper positioning of the valve member 57. However, if this does not cause the valve member to move, the actuator 58 itself, has failed.
A starter air valve for an air turbine starter system under this disclosure could be said to include a valve member and an actuator. A rotary spool valve is to be connected to a source of pressurized air. The rotary spool valve has a rotatable valve body and an outer housing. There is an actuator control for the actuator. The rotatable valve body and the valve housing selectively provide three modes of operation for the starter air valve, A first mode of operation connects pressurized air through the rotatable valve body to communicate with the actuator control, and to receive pressurized air back from the actuator control. The rotatable valve body then communicates the air to the actuator. In a second mode the rotatable valve body blocks communication between the actuator control and the actuator, and delivers air through a variable area port in a wall of the rotatable valve body to bypass the valve member. In a third mode the rotatable valve body block communication between the actuator and the actuator control, and connects pressurized air to the actuator without having passed to the actuator control.
Although an embodiment of this invention has 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 true scope and content of this disclosure.