1. Field of the Invention
The present invention relates generally to axial compressors for gas turbines and industrial applications, and in particular to an axial compressor having high-performance airfoils.
2. Description of the Related Art
NACA 65 series airfoils have heretofore been applied to subsonic airfoils located on the downstream side in an axial compressor. As described in “Aerodynamic Design of Axial-Flow Compressors”, National Aeronautics and Space Administration, 1965, (NACA, SP-36), the NACA 65 series airfoils are developed by an organized and comprehensive experimental research using a Wind Tunnel. In recent years, axial compressors have required higher loading combining a higher pressure ratio with cost reduction resulting from a reduction in the number of stages. A subsonic airfoil in the downstream stage of a high loaded compressor increases a secondary flow due to the growth of an endwall boundary layer. Therefore, corner stall occurs on a blade surface, so that a conventional airfoil may provably increase a secondary loss. The application of a high performance airfoil that can control the corner stall is an important technology to improve the performance of a high loaded compressor.
JP,A 8-135597 discloses a method of controlling a secondary flow in an axial compressor. This method involves adjusting the shapes of airfoil end portions liable to cause a secondary flow. Specifically, the method involves adjusting a curvature radius of an airfoil centerline at a position close to the leading edge and at a position close to the trailing edge, with the position of the leading edge of the airfoil remaining fixed, so as to reduce a static pressure gradient on a pressure surface and on a suction surface.
The traditional technology as described in JP,A 8-135597, for reducing the secondary flow loss occurring close to the endwall, adopts a mainstream method as below. A staggered angle and an airfoil shape close to the endwall are improved to reduce a loading on an endwall portion of the airfoil. Consequently, the secondary flow loss and corner stall are controlled. However, there is concern that a loss may be increased at a portion other than the endwall portion where the loading is increased. In addition, unsteady fluid vibrations such as buffeting or the like due to the turbulence or separation of a flow are likely to lower the reliability of the compressor.
Accordingly, it is an object of the present invention to provide a high performance airfoil of a compressor that achieves a reduction in loss and ensuring of reliability.
According to an aspect of the present invention, there is provided an axial compressor including a number of stator vanes attached to an inner surface of a casing defining an annular flow path; and a number of rotor blades attached to a rotating rotor defining the annular flow path. A flow path is defined between a pressure surface of a stator vane and a suction surface of a stator vane, the vanes being circumferentially adjacent to each other, or between a pressure surface of a rotor blade and a suction surface of a rotor blade, the blades being circumferentially adjacent to each other. The flow path is formed so that a throat portion at which a flow path width is minimized may be provided on the upstream side of 50% of an axial chord length. In addition, an axial flow path width distribution extending from the leading edges to trailing edges of the vanes or the blades defining the flow path therebetween may have an inflection point on the downstream side of the throat portion.
The present invention can provide a high performance airfoil of a compressor that achieves a reduction in loss and ensuring of reliability.
An axial compressor 1 includes a rotating rotor 2 to which a plurality of rotor blades 4 are attached and a casing 3 to which a plurality of stator vanes 5 are attached. An annular flow path is defined by the rotor 2 and the casing 3. The rotor blades 4 and the stator vanes 5 are alternately arranged in an axial direction. A single row of the rotor blades 4 and a single row of the stator vanes 5 constitute a stage. The rotor 2 is driven by a drive source (not shown) such as a motor or a turbine installed to have the same axis of rotation 6. An inlet flow 10 passes through the rotor blades 4 and the stator vanes 5 while being reduced in speed, and becomes a high temperature and pressure outlet flow 11.
An axial compressor is one in which rotor blades apply kinetic energy to an inlet flow and stator vanes change the direction of the flow for deceleration, thus, converting the kinetic energy into pressure energy for pressure rise. A boundary layer grows on an endwall of an annular flow path in such a flow field as described above. This increases a secondary flow loss on subsonic airfoils located on the downstream side in the axial compressor. Additionally, a highly loaded axial compressor that intends to increase a pressure ratio of the compressor and to reduce a cost due to a reduction in the number of stages enlarges corner stall on a blade surface. The corner stall is a key factor of the secondary flow loss. Thus, it has been a technical problem to create an airfoil shape that can control the corner stall.
Embodiments of the present invention can make uniform a static pressure gradient from a pressure surface to a suction surface with respect to a direction perpendicular to a flow, in a flow path between two adjacent blades or vanes. This can control a cross flow from the pressure surface to the suction surface between the rotor blades or between the stator vanes. Because of controlling the cross flow, corner stall occurring on the suction surface side can be reduced. Since the corner stall which is a key factor of the secondary flow loss can be controlled, a loss at a row of blades or vanes can be reduced, which leads to an improvement in the efficiency of the overall axial compressor.
Controlling the corner stall on the row of blades or vanes can improve an outlet flow angle. This can improve inlet flow angles of a row of stator vanes or rotor blades located on the downstream side of the row of the blades or vanes embodying the present invention. In addition, a reduction in the loss and higher performance at the stage composed of the rotor blades and the stator vanes can be achieved. Further, unsteady fluid vibrations such as buffeting or the like due to separation on a blade or vane surface can be avoided. Thus, the reliability of the axial compressor can be ensured.
An A-A section of the stator vane 5 is hereafter described by presenting a plurality of embodiments. However, the present invention is not limited to the stator vane but can similarly be applied to the rotor blade.
A vane shape of the axial compressor according to a first embodiment is shown in
The vane shape in
A vane shape of the axial compressor according to a second embodiment of the present invention is shown in
However, also the vane shape shown in the present embodiment has the same flow path width distribution, shown in
Incidentally, the general vane structure has a pressure surface and a suction surface which are smoothly joined together. To be exact, therefore, the curvature distribution exhibits an abrupt variation at a surface position close to the leading edge 23 and to the trailing edge 24. However, no reference is particularly made to such a joint portion in the figure.
The first and second embodiments describe the case where the curvature distribution of one of the pressure surface and the suction surface is varied to satisfy the flow path width distribution 42 in the axial direction of the vane shown in
A description is next given of how the adoption of the vane structure described in the embodiments acts on a flow field. Specifically, the vane structure is such that the throat portion at which the flow path width is minimized is provided on the upstream side of 50% of the axial chord length, and the axial flow path width distribution extending from the leading edges to the corresponding trailing edge of the vanes defining the flow path therebetween has an inflection point on the downstream side of the throat portion. Incidentally, such a vane is called the vane embodying the invention in some cases for simplification.
The axial distance shown in
Reducing the axial distance 65 of the equal-pressure line as described above can substantially bring the equal-pressure line 61 and the pressure gradient 62 of the static pressure between the vanes shown in
Further, the vane embodying the invention is configured so that the passage width distribution has the inflection point on the downstream side of the throat portion of the axial chord length. The throat portion is one in which the flow path width between the vanes is minimized to maximize the acceleration of the flow. In addition, the flow is decelerated on the downstream side of the throat portion so that static pressure is recovered (increased). Therefore, in the region where the flow is decelerated and the static pressure is increased, a turbulent boundary layer on the vane surface is developed so that the flow is likely to separate therefrom. Therefore, equalizing the static pressure gradient 62 between the vanes in that region is effective for lowering the secondary flow loss and for reducing the corner stall.
A plurality of cross-sections of the vanes described above are arranged in the vane-height direction and stacked one on another with their positions of the center of gravity aligned with each other. Thus, the three-dimensional vane can be designed. For example, the respective shapes of a 0%-section 71 on the casing side, a 50%-section of an average diameter and a 100%-section 72 on the rotor side are designed in the stator vane 5 shown in
A description is given of an effect of the vane designed as described above on a three-dimensional flow field.
The vane embodying the invention configured as described above can reduce the secondary flow loss and achieve the higher efficiency of the axle compressor. Since the vane embodying the invention can control the corner stall, the outlet flow angle can be brought closer to the design value compared with the traditional vane. Therefore, matching with respect to the rotor blades or stator vanes located on the downstream side can be improved. Thus, even multistage vanes or blades can be made to have high performance. Further, unsteady fluid vibrations such as buffeting or the like due to the turbulence or the like of a flow on the vane surface can be avoided and the reliability of the vane can be improved.
A general method of enhancing the performance of the traditional vane to reduce a secondary flow loss includes the following means. For example, a stagger angle of the endwall portion of the stator vanes is increased to reduce a loading on the endwall portion, thereby controlling corner stall. To arrange stator vanes on a casing, since a shroud portion is installed on the endwall, it is necessary to provide a fillet on the endwall portion of the stator vane and fully mount the endwall portion on the shroud portion. If the staggered angle of the endwall portion is increased as described above, the vane shape may probably protrude from the shroud portion or the fillet portion may probably partially be excluded. However, the vane embodying the present invention has almost the same staggered angle of the endwall portion as that of the traditional vane. Therefore, the shroud portion can be shared and the reliability of the vane can be ensured.
A description is next given of a profile creation method of the vane embodying the present invention. To create a two-dimensional cross-section profile of the vane, a peak Mach number on a suction surface and a shape factor of the suction surface are generally evaluated and the vane profile is created so as to minimize the peak Mach number and the shape factor. Incidentally, the shape factor is represented by a ratio of displacement thickness to momentum thickness on a surface boundary layer and serves as an index for indication of separation on the boundary layer. It is known that flow generally separates on the turbulent boundary layer at a shape factor of 1.8 to 2.4 or more.
The axial distance of the equal-pressure line which is an index allowing for the three-dimensional flow field is added to create the two-dimensional cross-section profile of the vane embodying the invention (
The embodiments of the present invention describe the stator vane of the subsonic stage located on the downstream side portion in the axial compressor and its function and effect. However, the present invention can applied to the design of a transonic airfoil located on the upstream side in the compressor and of a high subsonic airfoil located at an intermediate stage by changing the weighting factors in expression (1). It is clear that the same function and effect can be provided by applying the present invention to not only the stator vane but the rotor blade.
It is possible to design an arbitrary airfoil shape from the upstream side to the downstream side in the compressor by incorporating the indexes shown in expression (1) into a design system. This has also an effect of cutting design time. It is possible to design the airfoil shape uniquely without depending on a designer for higher performance of the airfoil.
The present invention can be applied to axial compressors for industrial applications as well as for gas turbines.
Number | Date | Country | Kind |
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2010-231085 | Oct 2010 | JP | national |
This application is a continuation of U.S. application Ser. No. 13/272,635, filed Oct. 13, 2011, which claims priority from Japanese Application No. 2010-231085, filed Oct. 14, 2010, the disclosures of which are expressly incorporated by reference herein.
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Entry |
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Seymour Lieblein, “Experimental Flow in Two-Dimensional Cascades,” Aerodynamic Design of Axial-Flow Compressors, National Aeronautics and Space Administration, 1965, pp. 183-226. |
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Number | Date | Country | |
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20160245300 A1 | Aug 2016 | US |
Number | Date | Country | |
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Parent | 13272635 | Oct 2011 | US |
Child | 15053355 | US |