This invention relates to aircraft gas turbine engine stator vanes and, particularly, to non-uniform vane spacing.
Stator vanes are commonly used in aircraft gas turbine engine compressors and fans and in some turbine designs. Non-rotating or stationary stator vanes typically are placed downstream or upstream of rotor blades of the fans, compressors, and turbines. These vanes influence the tangential flow component entering or leaving the rotors, may increase the static pressure of the fluid and may set the flow angle to a level appropriate for the downstream rotor. Non-rotating stationary stator vanes may be variable stator vanes capable of having their angle varied or may be fixed and not able to vary their angle with respect to the incoming gas flow.
Airfoils in vanes have a series of excitation frequencies associated with them. More specifically, each airfoil produces a wake in an air stream that is felt as a pulse by a passing airfoil. The combination of the number of stator vane wakes (pulses) and the rotational speed of the compressor creates a stimulus that may coincide with a natural frequency of the rotor blades. It is highly desirable to keep the majority of the airfoil natural frequencies outside of the designed engine operating range.
Non-uniform vane spacing (NUVS) designs have been developed to reduce induced rotor blade vibrations. NUVS designs vary the vane spacing around the circumference of the engine casing to facilitate avoidance of rotor blade and stator vane natural frequencies or to reduce the amplitude of rotor blade resonant response at these frequencies. More specifically, within such designs the number of stator vanes is varied in one or more sectors of the stator vane assembly. Although the stator vane spacing may vary from one sector to the next, the stator vanes within each sector remain equally spaced relative to each other, and/or are designed with an equal pitch. The variation in vane spacing or pitch between stator vane sectors facilitates changing the frequency of the vane wakes to reduce the vibration response induced in adjacent rotor blades. Some conventional non-uniform vane spacing designs can cause compressor performance and operability issues. Some conventional non-uniform vane spacing designs can require a large number of vane sector configurations with associated manufacturing and inventory costs.
Thus, it is desirable to have non-uniform vane spacing compressor designs that avoid a large number of vane sector configurations and/or compressor performance and operability issues.
A gas turbine engine ring or circular row of non-uniformally spaced vanes includes first group and second groups including all the vanes in the ring or circular row, only one first group and only one second group of adjacent vanes, unequal first and second spacing between the adjacent vanes in the first and second groups respectively, and the first spacing greater than the second spacing.
The second group may include only three adjacent vanes and only two adjacent pairs of the vanes and the second spacing between each of the vanes in each of the two adjacent pairs. A nominal uniform spacing of the stator vanes may be used as a design parameter for designing the spacing of the non-uniformly spaced stator vanes and the second spacing may be about 25%-35% smaller than the nominal uniform spacing. The gas turbine engine ring or circular row may be sectored. The gas turbine engine ring or circular row may include about 9 to 14 sectors and about 8 to 16 vanes per sector.
The second group may include two or more adjacent vanes including one or more adjacent pairs of the vanes and the second spacing being between each of the one or more adjacent pairs of the vanes respectively.
A gas turbine engine assembly may include a gas turbine engine section including one or more rings or circular rows of fixed and/or variable non-uniformally spaced vanes, first group and second groups including all the vanes in each of the one or more rings or circular rows, only one first group and only one second group of adjacent vanes in each of the one or more rings or circular rows, unequal first and second spacing between the adjacent vanes in the first and second groups respectively, and the first spacing greater than the second spacing.
A method for designing non-uniform vane spacing for a ring or circular row of non-uniformally spaced gas turbine engine vanes includes determining a 360 degree nominal uniform spacing S pattern, spreading apart one interim pair of the nominal uniformally spaced apart vanes and moving the remaining vanes closer together wherein the remaining vanes are all evenly spaced at a first spacing creating one big gap or an interim large spacing between the interim pair, and inserting an additional vane in the one big gap or interim large spacing forming two adjacent equal narrow gaps or spaces having second spacings smaller than the first spacing.
Illustrated in
The high pressure compressor 18 is generally axisymmetrical about the longitudinal or axial centerline axis 12. A circular ring or row 13 of inlet variable stator vanes 16 which may have non-uniform vane spacing (NUVS) are disposed in the compressor 18 and used to optimize the direction at which gases flowing downstream D through the compressor 18 enter the first and second rows 47, 48 of rotatable blades 50. Though the exemplary embodiment of the stator vanes 15 with non-uniform vane spacing disclosed herein is for a high pressure compressor 18, similar stator vanes 15 with non-uniform vane spacing disclosed herein may be used in other compressor sections and in fan and turbine sections of a gas turbine engine as well. A compressor casing 61 radially outwardly supports stator vane assemblies 56 which include the stator vanes 15.
Referring to
In order to reduce induced rotor blade vibration amplitudes, at least one of the variable stator vane assemblies 56 or circular rows 11 of stator vanes 15 include non-uniform vane spacing indicated by unequal first and second spacing S1, S2 between the vanes 15 in first and second groups G1, G2 respectively of the vanes 15, as illustrated in
S1, S2 may be measured circumferentially along an arc C between an adjacent pair 17 of the vanes 15. The arc C extends between a pair of adjacent radii R having a common origin 19 on the axial centerline axis 12 and pass through the adjacent pair 17 of the vanes 15 respectively. S1, S2 may be measured linearly from the intersections I of the arc C and the adjacent pair 17 of adjacent radii R having the common origin 19 on the axial centerline axis 12.
The non-uniform vane spacing may also be angular and measured in degrees between the vanes 15. The non-uniform vane spacing may be indicated by unequal first and second angles A1, A2 as measured between the vanes 15 in the first and second groups G1, G2 respectively of the vanes 15 as illustrated in
The exemplary embodiment of the non-uniform vane spacing illustrated herein in the circular row 11 of non-uniformly spaced stator vanes 15 includes only a single first group G1 and only a single second group G2. One of the groups includes widely spaced stator vanes 15 and the other group includes narrowly spaced stator vanes 15. The embodiment of the circular row 11 of non-uniformly spaced stator vanes 15, illustrated in
In the design of such spacing, one method may start with a 360 degree equal or uniform spacing S pattern as illustrated in
The ring or circular row 11 of stator vanes 15 with non-uniform vane spacing may be sectored as illustrated by first and second sectors 36, 38 separated by splits 40 as illustrated in
While there have been described herein what are considered to be preferred and exemplary embodiments of the present invention, other modifications of the invention shall be apparent to those skilled in the art from the teachings herein and, it is therefore, desired to be secured in the appended claims all such modifications as fall within the true spirit and scope of the invention. Accordingly, what is desired to be secured by Letters Patent of the United States is the invention as defined and differentiated in the following claims.
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Entry |
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Office Action issued in connection with corresponding CA Application No. 2959676 dated Jan. 30, 2018. |
Machine translation of First Office Action and Search issued in connection with corresponding CN Application No. 2017101555231 dated Aug. 31, 2018. |
Number | Date | Country | |
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20170268537 A1 | Sep 2017 | US |