1. Field
The present invention relates to turbine vanes and blades for a gas turbine stage and, more particularly, to third and fourth stage turbine vane and blade airfoil configurations.
2. Description of the Related Art
In a turbomachine, such as a gas turbine engine, air is pressurized in a compressor then mixed with fuel and burned in a combustor to generate hot combustion gases. The hot combustion gases are expanded within the turbine section where energy is extracted to power the compressor and to produce useful work, such as turning a generator to produce electricity. The hot combustion gas travels through a series of turbine stages. A turbine stage may include a row of stationary vanes followed by a row of rotating turbine blades, where the turbine blades extract energy from the hot combustion gas for powering the compressor, and may additionally provide an output power.
The overall work output from the turbine is distributed into all of the stages. The stationary vanes are provided to accelerate the flow and turn the flow to feed into the downstream rotating blades to generate torque to drive the upstream compressor. The flow turning in each rotating blade creates a reaction force on the blade to produce the torque. The work transformation from the gas flow to the rotor disk is directly related to the engine efficiency, and the distribution of the work split for each stage and the associated airfoil angles may be controlled by the vane and blade design for each stage and studied and selected for each unique engine design. Each row of airfoils has a unique set of inlet angles at the airfoil leading edge and a set of exit angles at the airfoil trailing edge. These angles are varied along the radial direction from the root to the tip.
In one aspect of the present invention, a turbine airfoil assembly for installation in a gas turbine engine having a longitudinal axis, the turbine airfoil assembly including an endwall for defining an inner boundary for an axially extending hot working gas path, and an airfoil extending radially outwardly from the endwall, the airfoil having an outer wall comprising a pressure sidewall and a suction sidewall joined together at chordally spaced apart leading and trailing edges of the airfoil, an airfoil mean line is defined extending chordally and located centrally between the pressure and suction sidewalls, airfoil inlet and exit angles are defined at the airfoil leading and trailing edges that are substantially in accordance with inlet angle values, α, and exit angle values, β, set forth in one of Tables 1, 2, 3, and 4, where the inlet and exit angle values are generally defined as angles between a line parallel to the longitudinal axis and the airfoil mean line lying in an X-Y place of an X, Y, Z Cartesian coordinate system in which Z is a dimension perpendicular to the X-Y plane and extends radially relative to the longitudinal axis, and wherein each of the inlet and exit angle values is defined with respect to a distance from the endwall corresponding to a Z value that is a distance of a total span of the airfoil from the endwall with the distances being joined smoothly with one another to form a complete airfoil shape.
In another aspect of the present invention, third and fourth stage vane and blade airfoil assemblies in a gas turbine engine having a longitudinal axis, each airfoil assembly including:
In another aspect of the present invention, a turbine airfoil assembly for installation in a gas turbine engine having a longitudinal axis, the turbine airfoil assembly including an endwall for defining an inner boundary for an axially extending hot working gas path, and an airfoil extending radially outwardly from the endwall, the airfoil having an outer wall comprising a pressure sidewall and a suction sidewall joined together at chordally spaced apart leading and trailing edges of the airfoil, an airfoil mean line is defined extending chordally and located centrally between the pressure and suction sidewalls, airfoil exit angles are defined at the airfoil trailing edge that are substantially in accordance with exit angle values, β, set forth in one of Tables 1, 2, 3, and 4, where the exit angle values are generally defined as angles between a line parallel to the longitudinal axis and the airfoil mean line lying in an X-Y plane of an X, Y, Z Cartesian coordinate system in which Z is a dimension perpendicular to the X-Y plane and extends radially relative to the longitudinal axis, wherein each the exit angle value is defined with respect to a distance from the endwall corresponding to a Z value that is a distance of a total span of the airfoil from the endwall with the distances being joined smoothly with one another to form a complete airfoil shape, and wherein each the airfoil exit angle is within about 1% of a respective value set forth in one of Tables 1, 2, 3, and 4.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following drawings, description and claims.
The invention is shown in more detail by help of figures. The figures show preferred configurations and do not limit the scope of the invention.
In the following detailed description of the preferred embodiment, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration, and not by way of limitation, a specific embodiment in which the invention may be practiced. It is understood that other embodiments may be utilized and that changes may be made without departing from the spirit and scope of the present invention.
Broadly, an embodiment of the present invention provides a turbine airfoil assembly for installation in a gas turbine engine. The airfoil assembly includes an endwall and an airfoil extending radially outwardly from the endwall. The airfoil includes pressure and suction sidewalls defining chordally spaced apart leading and trailing edges of the airfoil. An airfoil mean line is defined located centrally between the pressure and suction sidewalls. An angle between the mean line and a line parallel to the engine axis at the leading and trailing edges defines gas flow entry angles, α, and exit angles, β. Airfoil inlet and exit angles are substantially in accordance with inlet angle values, α, and exit angle values, β, set forth in one of Tables 1, 2, 3, and 4.
Referring to
During operation of the gas turbine engine, a compressor (not shown) of the engine supplies compressed air to a combustor (not shown) where the air is mixed with a fuel, and the mixture is ignited creating combustion products comprising a hot working gas defining a working fluid. The working fluid travels through the stages of the turbine section 12 where it expands and causes the blades 16, 20, 24, 28 to rotate. The overall work output from the turbine section 12 is distributed into all of the stages, where the stationary vanes 14, 18, 22, 26 are provided for accelerating the gas flow and turn the gas flow to feed into the respective downstream blades 16, 20, 24, 28 to generate torque on a rotor 30 supporting the blades 16, 20, 24, 28, producing a rotational output about a longitudinal axis 32, of the engine, such as to drive the upstream compressor.
The flow turning occurring at each rotating blade 16, 20, 24, 28 creates a reaction force on the blade 16, 20, 24, 28 to produce the output torque. The work split between the stages may be controlled by the angular changes in flow direction effected by each of the vanes 14, 18, 22, 26 and respective blades 16, 20, 24, 28, which work split has an effect on the efficiency of the engine. In accordance with an aspect of the invention, a design for the third and fourth stage vanes 22, 26, and blades, 24, 28, is provided to optimize or improve the flow angle changes through the third and fourth stages. Specifically, the design of the third and fourth stage vanes 22, 26 and blades 24, 28, as described below, provide a radial variation in inlet and exit flow angles to produce optimized flow profiles into an exhaust diffuser 34 downstream from the turbine section 12. Optimized flow profiles through the third and fourth stages of the turbine section 12 may facilitate a reduction in the average Mach number for flows exiting the fourth stage vanes 26, with an associated improvement in engine efficiency, since flow loss tends to be proportional to the square of the Mach number.
Referring to
The cross section of
At the trailing edge 48, a blade metal angle of the surfaces of the pressure and suction sides 38, 40 adjacent to the trailing edge 48 is provided for directing flow exiting from the vane 22 and defines an airfoil trailing edge (TE) or exit angle, β. The airfoil exit angle, β, is defined as an angle between a line 32P parallel to the longitudinal axis 32 and an extension of the airfoil mean line, CV3, at the trailing edge 48, i.e., tangential to the line CV3 at the airfoil trailing edge 48.
The inlet angles, α, and exit angles, β, for the airfoil of the vane 22 are as described in Table 1 below. The Z coordinate locations are presented as lengths along the total span of the vane 22. The values for the inlet angles, α, and exit angles, β, are defined at selected Z locations spaced at increments along the span of the vane 22, where 800 mm (of total value) is located adjacent to the inner endwall 42 and 1215 mm (of total value) is located adjacent to the outer endwall 44. The inlet angles, α, and exit angles, β, are further graphically illustrated in
The inlet angle, α, is selected with reference to the flow direction coming from the second row blades 20, and the exit angle, β, may be selected to provide a predetermined direction of flow into the third stage blades 24.
The portions of the airfoil for the vane 22 described in Table 1 are provided with reference to a Cartesian coordinate system, as discussed above, that has orthogonally related X, Y and Z axes (
Referring to
The cross section of
At the trailing edge 68, a blade metal angle of the surfaces of the pressure and suction sides 58, 60 adjacent to the trailing edge 68 is provided for directing flow exiting from the blade 24 and defines an airfoil trailing edge (TE) or exit angle, β. The airfoil exit angle, β, is defined as an angle between a line 32P parallel to the longitudinal axis 32 and an extension of the airfoil mean line, CB3, at the trailing edge 68, i.e., tangential to the line CB3 at the airfoil trailing edge 68.
The inlet angles, α, and exit angles, β, for the airfoil of the blade 24 are as described in Table 2 below. The Z coordinate locations are presented as lengths along the total span of the blade 24. The values for the inlet angles, α, and exit angles, β, are defined at selected Z locations spaced at increments along the span of the blade 24, where 810 mm (of total value) is located adjacent to the inner endwall 62 and 1252 mm (of total value) is located adjacent to the blade tip 64. The inlet angles, α, and exit angles, β, are further graphically illustrated in
The portions of the airfoil for the blade 24 described in Table 2 are provided with reference to a Cartesian coordinate system, as discussed above, that has orthogonally related X, Y and Z axes (
Referring to
The cross section of
At the trailing edge 88, a blade metal angle of the surfaces of the pressure and suction sides 78, 80 adjacent to the trailing edge 88 is provided for directing flow exiting from the vane 26 and defines an airfoil trailing edge (TE) or exit angle, β. The airfoil exit angle, β, is defined as an angle between a line 32P parallel to the longitudinal axis 32 and an extension of the airfoil mean line, CV4, at the trailing edge 88, i.e., tangential to the line CV4 at the airfoil trailing edge 88.
The inlet angles, α, and exit angles, β, for the airfoil of the vane 26 are as described in Table 3 below. The Z coordinate locations are presented as lengths along the total span of the vane 26. The values for the inlet angles, α, and exit angles, β, are defined at selected Z locations spaced at increments along the span of the vane 26, where 780 mm (of total value) is located adjacent to the inner endwall 82 and 1400 mm (of total value) is located adjacent to the outer endwall 84. The inlet angles, α, and exit angles, β, are further graphically illustrated in
The portions of the airfoil for the vane 26 described in Table 6 are provided with reference to a Cartesian coordinate system, as discussed above, that has orthogonally related X, Y and Z axes (
Referring to
The cross section of
At the trailing edge 108, a blade metal angle of the surfaces of the pressure and suction sides 98, 100 adjacent to the trailing edge 108 is provided for directing flow exiting from the blade 28 and defines an airfoil trailing edge (TE) or exit angle, β. The airfoil exit angle, β, is defined as an angle between a line 32P parallel to the longitudinal axis 32 and an extension of the airfoil mean line, CB4, at the trailing edge 108, i.e., tangential to the line CB4 at the airfoil trailing edge 108.
The inlet angles, α, and exit angles, β, for the airfoil of the blade 28 are as described in Table 4 below. The Z coordinate locations are presented as lengths along the total span of the blade 28. The values for the inlet angles, α, and exit angles, β, are defined at selected Z locations spaced at increments along the span of the blade 28, where 760 mm (of total value) is located adjacent to the inner endwall 102 and 1439 9 mm (of total value) is located adjacent to the blade tip 104. The inlet angles, α, and exit angles, β, are further graphically illustrated in
The portions of the airfoil for the blade 28 described in Table 8 are provided with reference to a Cartesian coordinate system, as discussed above, that has orthogonally related X, Y and Z axes (
It is believed that the vane 22, blade 24, vane 26, and blade 28, constructed with the described average angle changes, provide an improved or optimized flow of working gases passing from the turbine section 12 to the diffuser 34, with improved Mach numbers for the flow passing through the third and fourth stages of the turbine. In particular, the design for the gas-path boundaries and airfoil angles of the third and fourth stages are configured provide a better balance between the Mach numbers for the third and fourth stages, which is believed to provide an improved performance through these stages, since losses are generally proportional to the square of the Mach number.
While specific embodiments have been described in detail, those with ordinary skill in the art will appreciate that various modifications and alternative to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention, which is to be given the full breadth of the appended claims, and any and all equivalents thereof.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/094,107, filed Dec. 19, 2014, entitled “Turbine Airfoil Unique Aero Configuration”, the entire disclosure of which is incorporated by reference herein in its entirety.
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