The present disclosure concerns a fuel spray nozzle for a gas turbine engine.
In a gas turbine engine, fuel is mixed with air prior to delivery into a combustion chamber where the mixture is ignited. Arrangements for mixing the fuel and air vary. In prefilming arrangements, fuel is formed in a film along a prefilmer surface adjacent to a nozzle. Pressurised, turbulent air streams are directed against the prefilmer surface and serve to shear fuel from the surface and mix the sheared fuel into the turbulent air streams. In vaporiser designs fuel is forced through a small orifice into a more cavernous air filled chamber. The sudden pressure drop and acceleration of the fuel flow upon entering the chamber disperses the fuel into a spray. High temperatures subsequently vaporise the fuel. Turbulent air flows in the chamber again encourage mixing.
Both methods have associated advantages and disadvantages. Prefilming fuel injectors have highly complex and intricate designs that are expensive to manufacture. Design iterations are slow, due to complexity of the manufacturing process. Whilst relatively simple in design and generally cheaper in manufacture, vaporiser fuel injectors provide inferior fuel preparation when compared to prefilming fuel injectors thereby resulting in inferior engine performance.
It is desirable to provide a fuel injector which is simple in construction but has improved performance over prior art vaporiser designs.
According to a first aspect of the invention there is provided a fuel spray nozzle comprising a fuel injector and an air swirler and having the configuration as described in Claim 1. The fuel injector component comprises a fuel passage having at least one inlet and at least one outlet, the outlet is configured for accelerating fuel exiting the fuel passage and ejecting a jet of fuel. The jet is directed in crossflow across a stream of relatively high velocity air exiting a swirl passage of a radially adjacent air swirler. The air swirler is arranged outboard of the fuel injector and comprises one or more passages that terminate in a single outlet chamber in which the fuel passage outlet(s) of the fuel injector sits.
Jet in crossflow′ is an airblast technique, in that the energy for atomisation is primarily provided by the airstream. It has some advantages over pre-filming injectors; the fuel is rapidly distributed over a range of radii, giving an opportunity for improved fuel/air mixing; and the mechanical design of the injector is simpler, permitting a reduction in manufacturing cost.
Desirably the fuel passage outlet and the air swirler outlet chamber are substantially axially coincident such that the jet is injected into the air stream after the air has been maximally accelerated and swirled in the swirler passages. This is assisted by walls of the swirler passages being radially convergent in a manner which directs the exiting air flow towards the fuel passage outlet to encourage mixing of the fuel and air in the outlet chamber and minimise filming of fuel on walls of the air swirler. The configuration ensures maximal atomisation of the fuel as it joins the relatively high velocity air stream.
The terms axial and radially herein are intended to refer to an axial centre-line passing through the air swirler and a radius around the axial centre-line.
Embodiments of the invention now described are configured in a jet in crossflow style of fuel spray nozzle.
In embodiments of the invention, the fuel outlet and the outlet chamber of the air swirler are positioned with respect to each other to maximise vaporisation of the fuel as it meets the air. The velocity and swirl imparted to the air in the swirler passages further assists in efficient mixing of the fuel and air on route to the combustion chamber. Optimal results can be achieved in part by optimising the angle of injection of the jet of fuel with respect to the direction at which the air exits a swirler passage and/or by the relative axial position of the fuel passage outlet relative to a terminus of the one or more swirler passages.
It will be appreciated that walls of the air swirler passages influence the predominant flow direction of an air stream exiting the swirler passages. The fuel passage outlet and walls of the swirler passages are directed towards each other so as to create a collision of the fuel and air streams which is within an optimum angle range (the vertex of the angle being downstream from the fuel outlet). The optimum angle is such that the fuel penetrates as far as possible across the radially adjacent swirl passage, without excessive impingement on the prefilming surface or any impingment on the outer wall of radially distal swirl passages.
For example, the optimum angle range is 30 to 150 degrees. More preferably, the range is 60 to 150 degrees, for example between about 90 and 130 degrees. The optimum arrangement may be influenced by factors such as the flow rate of the air and fuel at their outlets. The optimum angle range ensures that the mix of fuel with air in the air swirler outlet chamber is maximised and the amount of fuel crossing to a wall of the air swirler minimised.
Any fuel not picked up in the cross flow may collect on a prefilming surface which forms part of the air swirler or fuel injector. For example, the prefilmer surface is in the form of a cone of the fuel passage which extends and converges in a direction downstream from the fuel outlet. Alternatively the prefilmer may be a radially inwardly facing surface of the air swirler.
The fuel passage may have an annular configuration. The fuel passage may comprise a plurality of outlets symmetrically arranged around an annulus. Additional fuel circuits may be arranged inboard of the air swirler within the fuel injector to permit staging of the engine. Optionally the additional fuel circuits are annularly arranged.
The air swirler may be nominally concentrically arranged with respect to the fuel passage.
Optionally, a separate seal component is arranged between the air swirler and the fuel passage and is configured to allow radial and/or angular and/or axial movement between the air swirler and fuel passage. The seal may be configured to allow controlled leakage flow (for example specific metered flow) to pass through the passage between the fuel passage and air swirler.
In some embodiments, the fuel spray nozzle further comprises a non-swirling air jet. The air jet supply passage can pass axially through an annularly arranged fuel passage. In other embodiments the air passage may be annular and arranged outboard of the fuel passage. The air jet is advantageous in preventing a recirculating vortex from penetrating into the fuel spray nozzle thereby reducing carbon deposition on, and aerodynamic blocking of, the nozzle exit.
In some embodiments the fuel passage is protected from the ambient air by means of one or more cavities filled with stagnant air that acts as an insulating layer. These cavities can be configured to protect the fuel from heat flowing from the air in the air swirler, between the air swirler and fuel injector, or from any other air passage built into the fuel injector.
Upstream of the single outlet, the air swirler may comprise one or more air passages (which may optionally be convergent), extending annularly which include vanes configured to impart swirl on transmitted air. These passages may be configured to drive an axial flow or a radial flow, or a flow in any combination of these directions. Multiple convergent air passages may be aligned to have axial overlap, the outer radial wall of a first convergent passage forming a radially inner wall of an adjacent, upstream convergent passage. The vanes can be arranged to extend between the radially outer and radially inner walls of the converging passage, being exposed beyond the downstream edge of the most upstream radially outer wall.
At the upstream edge, the walls of the convergent air passages can be arched or undulated such that the length from the outlet chamber to the upstream edge is variable around the radial outer wall. The arches can be uniform. Where two or more convergent passages are provided with undulations, the radially outer walls of the passage may be arranged at different angular rotations relative to each other. The leading edges of the vanes connecting adjacent annular structures can be arched or inclined. Such a configuration is well suited to manufacture using additive layer manufacturing (ALM) techniques, for example direct laser deposition (DLD). The ability to use such manufacturing techniques provides greater flexibility in design of vane and passage shapes, allowing these shapes to be optimised to enhance aerothermal performance. By optimising vane and passage configurations to provide high intensity air turbulence and speed, the efficient atomisation of fuel into a fine spray with substantially uniform droplet size distribution can be achieved. The air swirler outlet and convergent air passages can be provided with a throat profile which is configured to control the cone angle of the exiting air. Achievable results can be comparable to or even exceed the atomisation provided by complex prefilmer arrangements.
EP2772688 discloses one embodiment of an air swirler suitable for use in embodiments of the fuel spray nozzle of the invention.
It will be appreciated that as well as shape, the number of vanes and passages can also be varied to suit requirements without departing from the scope of the claimed invention.
The described arrangement is relatively insensitive in terms of effective area with respect to axial, radial and angular movement between the fuel injector (which comprises the fuel passage and outlet) and the air swirler. Thus the fuel injector and air swirler can be mounted independently.
The separation of the fuel injector from the air swirler reduces the complexity and the cost of the manufacturing process compared to prior art prefilmer design.
The position of the fuel injector within the air swirler means that the air swirler can be combustor-mounted, reducing stress within both the combustion module casing and the fuel injector and thereby reduces the requisite size, aerodynamic drag, cost and weight of the fuel spray nozzle and combustion module casing compared to prior art arrangements.
The nozzle may further incorporate a thermal management system. A thermal management system might comprise a cooling circuit and/or a heat shield. In some embodiments an integral heat shield may extend radially outwardly from the outlet to provide an axially upstream facing heat shield surface.
Embodiments of the invention will now be described by way of example only, with reference to the Figures, in which:
With reference to
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. 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 shaft.
In
In
The swirler comprises annular channels 4 crossed by swirl vanes 3a. The channels 4 converge to a common outlet chamber 5.
Referring now to
Air swirler 33 comprises coaxially aligned air passages 34 having inlets 34a which converge towards a common outlet chamber 35. Swirler vanes 33a, 33b extend between walls of coaxially adjacent passages 34.
In
In
The second swirler 66 comprises a plurality of vanes 84 and a third member 86. The third member 86 is arranged coaxially around the second member 74. The vanes 84 of the second swirler 66 extend radially between the second and third members 74 and 86. The vanes 84 of the second swirler 66 have leading edges 88 and the third member 86 has an upstream end 90. The leading edges 88 of the vanes 84 of the second swirler 66 extend with radial and axial components from the upstream end 78 of the second member 74 to the upstream end 90 of the third member 86 and the radially outer ends 92 of the leading edges 88 of the vanes 84 of the second swirler 66 form arches 94 with the upstream end 90 of the third member 86. In particular the leading edges 88 of the vanes 84 extend with axial downstream components from the upstream end 78 of the second member 74 to the upstream end 90 of the third member 86.
The first member 72, the second member 74 and the third member 86 are generally annular members with a common axis Y. Thus, the upstream end of the first member 72 is upstream of the upstream end 78 of the second member 74 and the upstream end 78 of the second member 74 is upstream of the upstream end 90 of the third member 86.
The outer surface of the downstream end of the first member 72 tapers/converges towards the axis Y of the fuel injector head 60. The first member 72 The downstream end of the second member 74 tapers/converges towards the axis Y of the fuel injector head 60 and the inner surface of the downstream end of the third member 86 initially tapers/converges towards the axis Y of the fuel injector head 60 and then diverges away from the axis Y of the fuel injector head 60. An annular passage 104 is defined between the first member 72 and the second member 74 and an annular passage 106 is defined between the second member 74 and the third member 86. A central passage 108 is defined within the first member 74 in which a fuel passage can be received in accordance with the invention.
It is seen that the fuel injector head 60 is arranged such that the leading edges 76 and 88 of the vanes 70 and 84 respectively are arranged to extend with axial downstream components from the first member 72 to the upstream end 78 of the second member 74 and from the second member 74 to the upstream end 90 of the third member 86 respectively. In addition it is seen that the fuel injector head 60 is arranged such that the radially outer ends 80 and 92 of the leading edges 76 and 88 of the vanes 70 and 84 respectively form arches 82 and 94 with the upstream ends 78 and 90 of the second and third member 74 and 86 respectively. These features enable the fuel injector head 60 and in particular the first and second swirlers 64 and 66 of the fuel injector head 60 to be manufactured by direct laser deposition. These features enable the vanes 70 of the first swirler 64 to provide support between the first member 72 and the second member 74 and the vanes 84 of the second swirler 66 to provide support between the second member 74 and the third member 86 during the direct laser deposition process.
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.
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. 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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