A gas turbine aircraft propulsion engine typically includes a fan section, a compressor section, a combustor section, and a turbine section. In general, during operation, air is compressed in the fan and compressor sections and is mixed with fuel and burned in the combustor section to generate hot combustion gases. The hot combustion gases flow through the turbine section, which extracts energy from the hot combustion gases to power the compressor section, the fan section, and other gas turbine engine loads. Efficiency of the gas turbine engine may decrease if a decrease of the pressure ratio of the compressor section occurs.
In one exemplary embodiment, a gas turbine engine includes a fan section. A splitter is downstream of the fan section and at least partially defines a secondary flow path on a radially outer side and an inner flow path on a radially inner side. A variable pitch rotor blade assembly is located at an inlet to the inner flow path and includes a plurality of variable pitch rotor blades.
In a further embodiment of any of the above, the plurality of variable pitch rotor blades rotate about a rotor blade axis that is transverse to an axis of rotation of the gas turbine engine.
In a further embodiment of any of the above, the rotor blade axis is perpendicular to an axis of rotation of the gas turbine engine.
In a further embodiment of any of the above, the fan section includes more than one fan blade row.
In a further embodiment of any of the above, the fan section includes at least one fan blade row with a stator row immediately downstream of at least one fan blade row and immediately upstream of the variable pitch rotor blade assembly. The stator row includes a plurality of non-rotatable vanes.
In a further embodiment of any of the above, the fan section includes at least one fan blade row with a stator row immediately downstream of at least one fan blade row and immediately upstream of the variable pitch rotor blade assembly. The stator row includes a plurality of rotatable vanes configured to rotate about an axis through a corresponding vane.
In a further embodiment of any of the above, the fan section includes a vane row immediately downstream of a fan blade row and immediately upstream of the inner flow path.
In a further embodiment of any of the above, an inlet guide vane is immediately downstream of an inlet to the fan section.
In a further embodiment of any of the above, the variable pitch rotor assembly is located downstream of the fan section.
In a further embodiment of any of the above, each of the plurality of variable pitch rotor blades include a spindle rotatably supported on at least one bearing.
In a further embodiment of any of the above, each of the spindles are attached to a separate lever arm that rotates the spindle in response to movement from a hydraulic actuator.
In a further embodiment of any of the above, the secondary flow path is a bypass flow path.
In another exemplary embodiment, a method of varying a bypass ratio of a gas turbine engine includes driving a fan section with a turbine section. The fan section directs air along a secondary flow path and an inner flow path. A pitch of a plurality of variable pitch rotor blades in a variable pitch rotor assembly in the core airflow path is varied in response to a change bypass ratio of the gas turbine engine.
In a further embodiment of any of the above, a high pressure ratio across the plurality of variable pitch rotor blades is maintained when operating at the gas turbine engine by varying the pitch of the plurality of variable pitch rotor blades.
In a further embodiment of any of the above, the variable pitch rotor assembly is located in a compressor section of the gas turbine engine.
En a further embodiment of any of the above, the pitch of the plurality of variable pitch rotor blades is increased in response to a decrease the bypass ratio of the gas turbine engine.
In a further embodiment of any of the above, the pitch of the plurality of variable pitch rotor blades is decreased in response to an increase in the bypass ratio of the gas turbine engine.
In a further embodiment of any of the above, the pitch of the plurality of variable pitch rotor blades is varied with an actuator.
In a further embodiment of any of the above, the fan section includes at least one fan blade row with a stator immediately downstream of at least one fan blade row and immediately upstream of the variable pitch rotor assembly. The stator includes a plurality of non-rotatable vanes.
In a further embodiment of any of the above, the fan section includes at least one fan blade row with a stator immediately downstream of at least one fan blade row and immediately upstream of the variable pitch rotor assembly. The stator includes a plurality of rotatable vanes that rotate about an axis through a corresponding vane.
The compressor section 14, the combustor section 16, and the turbine section 18 are generally referred to as the engine core. The fan section 12 and a low pressure turbine 22 of the turbine section 18 are coupled by a first shaft 24 to define a low spool. The compressor section 14 and a high pressure turbine 26 of the turbine section 18 are coupled by a second shaft 28 to define a high spool.
An outer engine case structure 30 and an inner engine structure 32 define a generally annular secondary flow path 34 around an inner flow path 36. It should be understood that various structure within the gas turbine engine 10 may define the outer engine case structure 30 and the inner engine structure 32 which essentially define an exoskeleton to support the core engine therein.
Air which enters the fan section 12 is divided between an inner flow through the inner flow path 36 and a secondary or bypass flow through the secondary flow path 34. The inner flow passes through the compressor section 14, the combustor section 16, the turbine section 18, and then through the nozzle section 20. The secondary flow may be utilized for a multiple of purposes to include, for example, cooling and pressurization. The secondary flow as defined herein is any flow different from the primary combustion gas exhaust core flow. The secondary flow passes through an annulus defined by the outer engine case structure 30 and the inner engine structure 32 then may be at least partially injected into the core flow adjacent the nozzle section 20.
The gas turbine engine 10 shown in Figure a operates on the Brayton thermodynamic cycle, the ideal thermodynamic efficiency of which depends only on the cycle pressure ratio as given by Equation 1:
As shown in Equation 1, the thermodynamic efficiency (ηth) of an engine, such as the gas turbine engine 10, operating on the Brayton cycle increases with increasing overall cycle pressure ratio ( ηoverall) at a given ratio of specific heats (γ=Cp/Cv).
The overall pressure ratio of the gas turbine engine 10 corresponds to the ratio of a burner inlet total pressure at the combustor section 16 to an engine inlet total pressure and is generally equal to the product of the pressure ratios of the fan section 12 and compressor section 14. The pressure ratio of any additional compression stage or stages which may be disposed in series with the fan section 12 and the compressor section 14 would likewise multiplicatively affect the overall engine pressure ratio of the gas turbine engine 10.
Although the real gas turbine cycle efficiency is also a function of component efficiencies and other factors, the overall engine pressure ratio represents a dominant factor in the thermodynamic efficiency of engine 10. Therefore, any factor which may decrease the overall pressure ratio of engine 10 would generally decrease the thermodynamic efficiency of the gas turbine engine 10.
As the air passes the fan stator 48, it reaches a splitter 52 where it is divided between bypass airflow B and inner airflow I. The bypass airflow B passes through the secondary flow path 34 located radially outward from the splitter 52 and is ejected out of an aft portion of the gas turbine engine 10. The inner airflow I passes through inner flow path 36 to variable blade pitch rotor 56 and stator 59 where its pressure is increased and then to compressor section 14 where it is further compressed before being heated in the combustor section 16 and expanded in the turbine section as discussed above (See
The inner flow path 36 includes a variable pitch rotor assembly 56 having a plurality of variable pitch blades 58 forming a row. A stator 59 is located immediately downstream of the variable pitch rotor assembly 56 and includes a plurality of vanes 61 forming a row. The variable pitch blades 58 of the variable pitch rotor assembly 56 are located immediately downstream of an inlet 57 to the inner flow path 36. The variable pitch blades 58 are rotatable about an axis of rotation R that is transverse or perpendicular to the engine axis A. As the variable pitch blades 58 rotate in unison about the axis of rotation R during operation, the corrected airflow rate through the inner flow path 36 and the secondary flow path 34 varies.
The variable pitch rotor assembly 56 may be located concentrically with and rotatable about engine centerline A and may be attached directly to the same shaft as fan blades 46 or may be driven through a gearbox off of the single fan 44 shaft or through a gearbox off of the high pressure spool of the engine or may be part of a separate engine spool independent of the fan and core spools.
During operation of the gas turbine engine 10, operating conditions may arise such that it is desirable to increase or decrease bypass airflow B in the secondary flow path 34 while simultaneously decreasing or increasing the flow in the inner flow path 36, respectively. When a lower bypass ratio for the gas turbine engine 10 is desired, for example at a fixed value of inlet airflow and rotor speed, which may be achieved in part by the closing of a variable nozzle at the exit of secondary flow path 34, an increase in airflow through the inner flow path 36 is required, corresponding to the decrease in bypass airflow through the secondary flow path 34. Concurrently with the increase in the air flow through the inner flow path 36, the variable pitch blades 58 are rotated to an increased pitch angle as required in order to maintain an optimum incidence angle on each of the variable pitch blades 58, thereby matching the flow capacity of the variable pitch rotor assembly 56 to the increase in airflow through the inner flow path 36 and maintaining the pressure ratio across the variable pitch rotor assembly 56.
Conversely, when an increase in the bypass ratio for the gas turbine engine 10 is desired, a reduction in airflow through the inner flow path 36 is required corresponding in magnitude to the increase in bypass airflow through the secondary flow path 34. Concurrently with the decrease in airflow through the inner flow path 36, the variable pitch blades 58 are rotated to a decreased pitch angle as required in order to maintain an optimum incidence angle on the variable pitch blades 58, thereby matching the flow capacity of the variable pitch rotor assembly 56 to the decrease in airflow through the inner flow path 36 and maintaining the pressure ratio across the variable pitch rotor assembly 56. Certain flight regimes require large changes in bypass ratio at high power.
The pressure ratio across the variable pitch rotor assembly 56 provides a significant contribution to the overall engine pressure ratio as described above and therefore by equation (1) to the overall cycle thermodynamic efficiency. For a constant-radius section through the variable pitch blade 58 from the leading edge to the trailing edge, it can be shown using Euler's turbine equation together with basic thermodynamic relationships that the pressure ratio across the rotor can be expressed as follows in Equation 2:
The conventional response to variations in rotor inlet flow coefficient φ1 and thus to variations in the rotor inlet flow is to vary the angle of the upstream fan stator 48, thereby varying the swirl at the leading edge of a fixed pitch rotor which may be located at the same location in the engine as variable pitch rotor 56 as shown schematically in
Conversely, an increase in the rotor φ1 (flow coefficient), corresponding to an increase in rotor inlet flow and therefore to an increase in Cx1 (air axial velocity), requires a decrease in the rotor inlet pre-whirl angle α1 with a corresponding decrease in circumferential velocity Cθ1 (circumferential velocity at the leading edge of the rotor blades, to zero in the illustrative example given in
The required increase in Cθ1 accompanying a decrease in rotor inlet flow at constant rotor blade speed U (corresponding to for example a high power engine operating condition) leads to a reduction in the change in absolute angular velocity across the rotor, i.e. to (Cθ2b-31 Cθ1b)<(Cθ2a−Cθ1a) as shown in the dashed and solid velocity triangle diagrams given in
Conventional engines utilize a variable pitch upstream stator with a fixed-pitch rotor in order to maintain an optimum rotor leading edge incidence in response to inlet flow variations as depicted schematically in
An advantage of the variable pitch rotor assembly 56 compared to a fixed blade pitch rotor is that the significant reduction in the rotor pressure ratio resulting from the increase in rotor pre-whirl which is required in response to a reduction in rotor inlet flow in order to maintain an optimum rotor leading edge incidence angle as described above and depicted schematically in
As shown in
As shown by Equation (2), the invariance of Cθ2 in response to variations in bypass ratio corresponds to an invariance in the rotor pressure ratio for the example depicted in
An additional advantage of the variable pitch rotor assembly 56 is that the variation of the angle of the absolute velocity vector C2 corresponding to a transition between operation at “low” and “high” bypass ratio is reduced as seen in
As shown in
The actuator 62 moves a slider 70 in either an axially forward direction A1 or an axially aft direction A2. The slider 70 is rotatably attached to a rotatable disk 72 through bearings 74. The slider 70 is fixed axially relative to the rotatable disk 72 with locks 76 abutting the bearings 74 and projections on both the slider 70 and the rotatable disk 72. A lever arm 78 is attached to a radially inner end of spindle 64 with a fastener and includes a slider projection 80 on a distal end of the lever arm 78. The slider projection 80 fits within a corresponding slot 82 in the rotatable disk 72. The slot 82 includes a directional component in an axial direction and in a tangential direction such that movement of the rotatable disk 72 in either the axially forward A1 or aft A2 direction causes the lever arm 78 to rotate the spindle 64 and the variable pitch blade 58 in the desired direction. Even though only a single rotatable blade mechanism 60 is shown in the illustrated example, a corresponding rotatable blade mechanism 60 associated with each of the variable pitch blades 58 circumferentially spaced around the engine axis A.
Air enters the fan section 112 through an inlet 140. Once the air enters the inlet 40, it passes over a plurality of inlet guide vanes 142 that are circumferentially spaced around the engine axis A Immediately downstream of the plurality of inlet guide vanes 142 is a forward fan row 144A having a plurality of fan blades 146A. The forward fan row 144A is separated from an aft fan row 144B having a plurality of fan blades 146B by a forward stator 148A having a plurality of vanes 150A forming a row. An aft stator 148B includes a plurality of vanes 150B and is located immediately downstream of the aft fan row 144B and immediately upstream of the splitter 52 and the variable pitch rotor assembly 56. In the illustrated example, the vanes 150B of the aft stator 148B are fixed from rotation and non-rotatable. In another example, each of the vanes 150B are rotatable about a separate axis transverse to the engine axis A.
As the air passes the fan stator 148B, it reaches the splitter 52 where it is divided between bypass airflow B through the secondary flow path 34 and inner airflow I through the inner flow path 36. The bypass airflow B travels through the secondary flow path 34 located radially outward from the splitter 52 and is ejected out of an aft portion of the gas turbine engine 10. The air entering the inner flow path 36 is further compressed in the variable blade pitch rotor 56 and compressor section 14 before being heated in the combustor section 16 and expanded in the turbine section 18 (See
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.