The present disclosure concerns an aerofoil, particularly but not exclusively, an aerofoil for a gas turbine engine having a reduced broadband noise profile in use.
Noise from aircraft is an ongoing environmental concern. There are typically several sources of noise from an aircraft, including jet noise produced by shear interaction between the jet exhaust from gas turbine engines, and aerodynamic noise caused primarily by turbulent air created by the flow of air over aircraft surfaces.
As aircraft engine bypass ratios are increased, aircraft aerodynamic noise is becoming a relatively large contributor to overall aircraft noise. In particular, turbulence created on the leading and trailing edges of aerofoil surfaces is thought to produce a significant proportion of noise produced by an aircraft. Noise created by these mechanisms often has a wide range of frequencies (known as “broadband noise”), and is particularly difficult to eliminate.
Examples of aerofoils on aircraft include the wings and tail surfaces, as well as smaller components such as control surfaces and high lift devices such as flaps and slats. The gas turbine engines of the aircraft also typically include several aerofoils, including compressor and turbine rotors and stators, fan rotors and Outlet Guide Vanes (OGV). The gas turbine engine nacelle is also typically aerofoil shaped.
It has been proposed to provide wave-like projections on the leading edge of an aerofoil, as proposed for example in U.S. Pat. No. 6,431,498. It is thought that such projections reduce drag as well as reduce noise to some extent, as evidenced for example in US2013164488. Such projections have been proposed for both fixed and rotating aerofoils, as proposed for example in US2011058955. However, such projections do not eliminate noise completely, and it is therefore desirable to provide an aerofoil having improved noise attenuation properties.
The term “chord” will be understood to refer to the distance between the leading and trailing edge of an aerofoil, measured parallel to the normal airflow over the wing. The term “chordal” will be understood to refer to a direction parallel to the chord. The term “span” will be understood to refer to a direction generally normal to the chord, extending between a root and a tip of an aerofoil component.
According to a first aspect of the disclosure there is provided an aerofoil component defining an in use leading edge and a trailing edge, at least one of the leading edge and the trailing edge defining a waveform profile, wherein the waveform profile extends in a spanwise direction and comprises a superposition of a first wave and a second wave, the first and second waves having different wavelengths such that the waveform profile defines a plurality of first and second generally chordwise extending recesses spaced in a spanwise direction and having a different extent in the chordwise direction.
Advantageously, it has been found that the disclosed aerofoil provides reduce broadband noise when in use compared to prior arrangements.
One or more first recess may be separated from a further first recess in a spanwise direction by one or more second recess.
The first and second waves may have substantially the same amplitude. The waveform may comprise a sinusoidal wave.
The waveform profile may be of the form
where c(r) is representative of the chordwise extent c of the leading or trailing edge from the mean chord line C0 as a function of the span r, h1 and h2 are representative of the amplitude of the first and second waves respectively, and γ1 and γ2 are representative of the wavelength of the first and second waves. γ1 may have a different value to γ2. h1 and h2 may have the same value.
In a first example, γ1/c0 has a value of 1/30, and γ2/c0 has a value of 2/30. In a second example, γ1/c0 has a value of 2/30, and γ2/c0 has a value of 1/10. In a third example, γ1/c0 has a value of 1/30, and γ2/c0 has a value of 1/10. γ1/γ2 may be between ½ and 2.
h/c0 may have a value between 1/10 and ⅙. In a first example, h/c0 has a value 1/10. In a second example, h/c0 has a value of 4/30. In a third example, h/c0 has a value of ⅙.
The aerofoil may have a cross sectional profile which may vary across the span of the aerofoil in accordance with the formula:
Where y is representative of the thickness of the aerofoil at chordwise position x and spanwise position r, and f (x) defines an aerofoil cross sectional profile such as an NACA-65 series aerofoil, and wherein x=0 is defined as the trailing edge, and x=1 is defined as the leading edge.
The aerofoil component may comprise an aerofoil of a gas turbine engine, such as an outlet guide vane (OGV).
According to a second aspect of the present disclosure there is provided a gas turbine engine comprising an aerofoil component in accordance with the first aspect of the present disclosure.
According to a third aspect of the present disclosure there is provided an aircraft comprising an aerofoil component in accordance with the first aspect of the present disclosure.
According to a fourth aspect of the present disclosure there is provided a method of designing an aerofoil component, the method comprising the steps of: defining a first way and a second wave, the first wave having a different wavelength to the second wave;
superposing the first and second waves to define a superposed waveform; defining an aerofoil having a leading or trailing edge profile comprising the superposed waveform such that the leading or trailing edge defines a plurality of first and second generally chordwise extending recesses spaced in a spanwise direction and having a different extent in the chordwise direction.
The skilled person will appreciate that except where mutually exclusive, a feature described in relation to any one of the above aspects of the invention may be applied mutatis mutandis to any other aspect of the invention.
Embodiments of the invention will now be described by way of example only, with reference to the Figures, in which:
The gas turbine engine 10 works in the conventional manner so that air entering the intake 12 is accelerated by the fan 13 to produce two air flows: a first air flow into the intermediate pressure compressor 14 and a second air flow which passes through a bypass duct 22 to provide propulsive thrust. Air directed rearwardly by the fan 12 is directed to an Outlet Guide Vane (OGV) 32, which provides structural support for the engine 10, and removes swirl from the airflow. The intermediate pressure compressor 14 compresses the air flow directed into it before delivering that air to the high pressure compressor 15 where further compression takes place.
The compressed air exhausted from the high-pressure compressor 15 is directed into the combustion equipment 16 where it is mixed with fuel and the mixture combusted. The resultant hot combustion products then expand through, and thereby drive the high, intermediate and low-pressure turbines 17, 18, 19 before being exhausted through the nozzle 20 to provide additional propulsive thrust. The high 17, intermediate 18 and low 19 pressure turbines drive respectively the high pressure compressor 15, intermediate pressure compressor 14 and fan 13, each by suitable interconnecting shafts.
Each of the fan 12, compressors 14, 16 and turbines 20, 22, 24 comprise a plurality of aerofoil profiled rotating blades and stationary stators (such as the OGV 32), which is located downstream of the fan 12. Consequently, air travelling over the leading and trailing edges of these surfaces can contribute to aircraft noise. Since the core of the engine is shielded by the engine core casing, the majority of the noise emanates from the fan 12, OGV 32 and nacelle.
Part of the OGV 32 is shown in further detail in
The leading edge 38 of the aerofoil 32 has a serrated profile defined by a plurality of projections 44 separated by first and second recesses 46a, 46b. Each projection 44 extends in a generally forward, chordwise (i.e. in a direction parallel to airflow in use) direction, and each recesses extends in a generally rearward, chordwise direction such that the leading edge 38 defines a continuously inwardly and outwardly curving surface.
The plan profile (i.e. the projection of the leading edge 38 when viewed from either the suction or pressure surface) of the OGV 32 is defined by a waveform, as shown in
In general, the waveform can be described by the following equation:
Where c(r) is representative of the spanwise variation of chordwise extent c of the projection from the mean chord line C0, along the span r, h1 and h2 are representative of the amplitude of the 1st and 2nd waveforms respectively, and γ1 and γ2 are representative of the wavelength of the 1st and 2nd waveforms respectively. In other words, the chord length of the aerofoil at a spanwise position r is defined by formula 1.
In the embodiments shown in
respectively, are superimposed, resulting in the waveforms shown in the figures. In the specific samples tested, these wavelengths corresponded to wavelengths of γ1=5 mm and γ2=10 mm, of γ1=10 mm and γ2=15 mm and of γ1=15 mm and γ2=5 mm respectively. As will be understood, an important feature of the superimposed waveform is the ratio of the first and second (and if present, further) wavelengths, i.e.
For example, in the first embodiment shown in
is approximately 1.5. In the embodiment shown in
is 3. In experiments (as described in further detail below), a ratio of 2 has been found to be most effective.
Consequently, the waveform shown in
The waveform shown in
The waveform shown in
Where y represents the position along the chord line, and x represents the chordwise extent of the leading edge 38 from the mean chord line at position x.
As can be seen, the resultant leading edge profile shown in
This repeating pattern of projections and recesses/troughs produces a leading edge profile comprising repeating at least first and second chordwise extending recesses having different extents relative to the mean chord line, separated in a spanwise direction by at least first and second generally chordwise extending projections having different extents relative to the mean chord line. In the example shown in
The leading edge profile shown in
Consequently, the leading edge profile of
The leading edge profile shown in
Consequently, the leading edge profile of
The chordal cross sectional profile of the OGV 32 can be described in accordance with the following equation:
Where y is representative of the thickness of the aerofoil at chordwise position x and spanwise position r, and f(x) defines an aerofoil profile such as an NACA-65 series aerofoil, and wherein x=0 is defined as the trailing edge, and x=1 is defined as the leading edge.
This profile is illustrated in
In a first experimental series, flat plates representative of the leading edge profiles shown in
Without wishing to be restricted to theory, it is thought that the recesses/troughs located between each projection at downstream positions in the in use flow direction produce tone noise out of phase with noise produced by recesses/troughs upstream. Consequently, the noise cancels out, reducing overall noise. This is thought to be because the leading edge profile comprises similar troughs separated in a flow-wise direction htt. Since these troughs have similar geometry, they radiate similar tone noise, delayed in time by U/htt, where U is the flow velocity in the flow-wise direction. At a radiation frequency of ω=2πf, this time delay translates to a phase shift of ωU/htt. There therefore exists a particular (angular) frequency ω0, at which the radiation from adjacent troughs are 180° out of phase, i.e.,
ωU/htt=π,
and hence the frequency f0 of additional noise reduction is given by
f0=htt/2U
This destructive interference effect is an additional noise reduction mechanism that is not present for single frequency serrations, leading to additional reductions in radiated noise from the aerofoil leading edge, which are additional to the reductions in noise provided by a serrated leading edge.
In the case where there are more than two chordally spaced recesses (such as for the waveform shown in
Similarly, in
In
Further experimental results were obtained for airflow velocities of 80 m/s. Again, it was found that the double wavelength protrusions outperformed the noise attenuation properties of the single wavelength protrusions over a wide frequency range. It is expected that similar results would be obtained at still higher airflow velocities. From these results, it would appear that the frequency at which the maximum noise reduction relative to the baseline straight leading edge occurs is approximately proportional to the relatively airflow velocity at the leading edge. In the context of an OGV, this would be the mean jet flow velocity.
In each of the above described waveforms, the maximum amplitude of the first, second and (if present) further waveforms cj(r) that makeup the superpositioned waveform are the same. It has been found in experimentation that, by keeping the maximum amplitude of the waveforms cj(r) the same provides an enhanced noise reduction over a narrow frequency bandwidth. However, the disclosed leading edge serration waveform envisages superpositioned waveforms having different maximum amplitudes.
In a second experimental series, an aerofoil having a leading edge waveform with h/c0=0.167, γ1=0.067, γ1=0.133 and an aerofoil cross sectional profile corresponding to an NACA-65 series aerofoil was tested in a windtunnel under representative conditions with airflows at 20 m/s. An image of the leading edge of the test aerofoil a is shown in
As can be seen, the noise at frequencies between 400 Hz and 800 Hz is reduced relative to prior arrangements. Similar experiments were conducted for the same aerofoil at higher airflow velocities. In those tests, the frequency at which maximum noise attenuation was achieved increased approximately linearly with airflow velocity. Consequently, the results from the tests with flat plates are verified.
It has been found from further experiments that an important parameter for achieving maximum noise attenuation at a particular frequency f is the downstream distance between nadirs of first and second troughs, htt (see FIG. 10). In particular, a maximum noise attenuation frequency f can be calculated for a given distance htt at a given streamwise velocity U using the following equation:
Thus in the example shown in
It will be understood that the invention is not limited to the embodiments above-described and various modifications and improvements can be made without departing from the concepts described herein. For example, the invention could be employed in aerofoils of different parts of a gas turbine engine, different parts of an aircraft, or in non-aviation applications, such as wind turbines, marine propellers, industrial cooling fans, and other aerofoils in which noise is a consideration. The invention has been found to be effective for a wide range of aerofoil cross sectional profiles, and also for flat plate aerofoils.
Except where mutually exclusive, any of the features may be employed separately or in combination with any other features and the disclosure extends to and includes all combinations and sub-combinations of one or more features described herein.
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