The application relates generally to gas turbines engines combustors and, more particularly, to fuel nozzles.
Gas turbine engine combustors employ a plurality of fuel nozzles to spray fuel into the combustion chamber of the gas turbine engine. The fuel nozzles atomize the fuel and mix it with the air to be combusted in the combustion chamber. The atomization of the fuel and air into finely dispersed particles occurs because the air and fuel are supplied to the nozzle under relatively high pressures. The fuel could be supplied with high pressure for pressure atomizer style or low pressure for air blast style nozzles providing a fine outputted mixture of the air and fuel may help to ensure a more efficient combustion of the mixture. Finer atomization provides better mixing and combustion results, and thus room for improvement exists.
There is accordingly provided a method for delivering fuel from a fuel nozzle of a combustor of a gas turbine engine, the method comprising: directing fuel from a fuel source through a flow splitter to provide at least two concentric fuel flows, filming the at least two concentric two fuel flows on concentrically arranged inwardly facing filming surfaces disposed downstream of the flow splitter, and atomizing the at least two concentric fuel flows into a core air flow.
There is also provided a method for delivering fuel from a fuel nozzle of a combustor of a gas turbine engine, the method comprising: directing a core air flow through a primary air passage of the fuel nozzle, the primary air passage extending centrally within the fuel nozzle and terminating at an exit located at a downstream end of the fuel nozzle; directing fuel from a fuel source through a flow splitter to provide at least two concentric fuel flows, the flow splitter disposed downstream of the exit of the primary air passage; filming the at least two concentric two fuel flows on concentrically arranged and radially inwardly facing filming surfaces disposed downstream of the flow splitter; and atomizing the at least two concentric fuel flows into the core air flow exiting the primary air passage.
Reference is now made to the accompanying figures in which:
Turning now to
The nozzle 100 includes generally a cylindrical body 102 defining an axial direction A and a radial direction R. The body 102 is at least partially hollow and defines centrally in its interior a primary air passageway 103 (a.k.a. core air), a secondary air passageway 104 and a first fuel passageway 106, all extending axially through the body 102 and communicating with a pressurized source of fuel (not shown). The first fuel passageway 106 is disposed concentrically between the primary air passageway 103 and the secondary air passageway 104. The secondary air passageway 104 and the first fuel passageway 106 may be annular. As will be described in more detail below, the fuel passageway includes a plurality of concentric fuel flows which are fed to a plurality of frustoconical fuel filming surfaces 107 and 109.
Although the nozzle of
The body 102 includes an upstream portion (not shown) connected to sources of pressurised fuel and air and a downstream portion 114 at which the air and fuel exit. The terms “upstream” and “downstream” refer to the direction along which fuel flows through the body 102. Therefore, the upstream end of the body 102 corresponds to the portion where fuel/air enters the body 102, and the downstream portion 114 corresponds to the portion of the body 102 where fuel/air exits.
The primary air passageway 103 is defined by outer wall 103b. The primary air passageway 103 carries pressurised air illustrated by arrow 116. The air 116 will be referred interchangeably herein to as “air”, “jet of air”, or “core flow of air”. In the illustrated embodiment, the primary air passageway 103 is straight and the outer wall 103b does not have surface treatment at the downstream portion 114. It is however contemplated that the primary air passageway 103 could have various shapes and that the outer wall 103b could have surface treatment to induce spinning of the air 116 carried therethrough. The outer wall 103b ends at exit end 115.
The secondary air passageway 104 is annular and defined by inner wall 104a and outer wall 104b (only a downstream portion being shown in the Figures). The secondary air passageway 104 carries pressurised air illustrated by arrow 118. The air 118 will be referred interchangeably herein to as “air”, or “film of air”. The secondary air passageway 104 is disposed radially outwardly from the primary air passageway 103. The secondary air passageway 104 converges (i.e. cross-sectional area may decrease along its length, from inlet to outlet) at the downstream portion 114.
The first fuel passageway 106 is defined by inner wall 106a and outer wall 106b. The first fuel passageway 106 carries pressurised fuel illustrated by arrow 119. The fuel 119 will be referred interchangeably herein to as “fuel”, or “fuel film”. The inner wall 106a ends with the exit end 115 of the primary air passageway 103, while the outer wall 106b extends downstream relative to the inner wall 106a. The outer wall 106b provides a first filming surface 107, which includes an axial first portion 120 and a converging second portion 122, and a second filming surface 109, which includes an axial third portion 124 and a converging fourth portion 126. The first and second filming surfaces 107, 109 are inwardly (an in this example radially) facing surfaces of nozzle projections 127, 129. The nozzle projections 127, 129 are downstream extending portions of the outer walls of the first fuel passageway 106 and an annular second fuel passageway 132 disposed around the first fuel passageway 106.
The inner wall 106a and outer wall 106b are evenly spaced throughout the first fuel passageway 106 in this example. In the illustrated embodiment, the exit end 115 of the primary air passageway 103 ends axially at about the third portion 124, but it is contemplated that the exit end 115 could end elsewhere relative to the outer wall 106b. The fourth portion 126 ends at exit end 128, downstream of the exit end 115 of the air passageway 103.
The secondary air passageway 104 and the first fuel passageway 106 are typically convergent in the downstream direction at the downstream portion 114. The outer wall 106b of the first fuel passageway 106 is converging at the downstream portion 114, thereby forcing the annular fuel film 119 expelled by the first fuel passageway 106 onto the jet of air 116 expelled from the primary air passageway 103. Similarly, the outer wall 104b of the secondary air passageway 104 are converging at the downstream portion 114, thereby forcing the annular film of air 118 expelled by the secondary air passageway 104 onto the annular fuel film 119. At the downstream portion 114, the annular fuel film 119 is sandwiched by the core flow of air 116 of the primary air passageway 103 and the annular film of air 118 of the secondary air passageway 104.
In this example, the outer wall 106b of the first fuel passageway 106 includes a flow splitter, in the shape of a plurality of bifurcating passages 130 (only one being shown in
The second fuel passageway 132 includes a closed end 134 slightly upstream of the bifurcating passage 130 and an open end 136 (i.e. exit end) downstream of the bifurcating passage 130. An outer wall of the second fluid passageway 132 includes the second filming surface 109. It is contemplated that the closed end 134 could be adjacent to the bifurcating passages 130. The second fuel passageway 132 in this example is not connected to a pressurized source of fuel except by the first fuel passageway 106 and is fed in fuel solely by the first fuel passageway 106. The plurality of bifurcating passages 130 are the sole inlet of the second fuel passageway 132 in this example. As a result, the fuel film 119 splits into two concentric annular fuel films 119a, 119b, each of reduced thickness relative to the fuel film 119. Having a fuel film of reduced thickness tends to improve transformation of the fuel film into droplet (i.e. atomisation). In the example shown in the figures, the fuel film 119b exits the fuel nozzle 100 at the exit end 128 and becomes in contact with the air 116. Similarly the fuel film 119a becomes in contact with the air 118 at the open end 136. Shearing between the fuel films 119a (resp. 119b) and the air 118 (resp. 116) exiting at different velocities, creates respective droplets of fuel 121a (resp. 121b) that will be ignited in the combustor 16.
In use, the air 116, 118 and the fuel films 119a, 119b may be given a spin or swirl or momentum to increase shearing between them, but also to enable the portion 119a of the fuel film 119 to travel through the bifurcating passages 130. This spin or swirl may be achieved by any suitable means (not shown). When spinning in the first fuel passageway 106, the fuel film 119 has a tangential velocity component (or momentum) and tends to accumulate on the outer wall 106b of the first fuel passageway 106. As a result, when the fuel 119 encounters the bifurcating passage 130 formed in the outer wall 106b, a portion separates from the fuel film 119 and flows through the bifurcating passage 130 to provide a plurality of concentric fuel film flows 119a, 119b. These concentric fuel film flows 119a and 119b spinningly converge inwardly, as a result of being directed by the converging portions of the fuel filming surfaces 107, 109 (i.e. converging second portion 122, converging fourth portion 126), and disperse into atomized droplets 121a, 121b, as the fuel flows come into contact with the air flows 116, 118 passing through the respective primary and secondary air passageways 103, 104. Providing a plurality of concentric filming surfaces 107, 109 may result in a smaller droplet size, and hence better atomization, as compared to the provision of a single filming flow.
In the example shown in the figures, the plurality of bifurcating passages 130 are inclined relative to the radial direction R to facilitate the flow of the fuel 119a. An angle between a downstream wall 130b of the bifurcating passages 130 and the axial direction is acute (i.e. the bifurcating passages 130 are inclined downstream). It is however contemplated that the plurality of bifurcating passages 130 could be inclined in any suitable fashion, including possibly not inclined at all. For example, the bifurcating passages 130 could be aligned with the radial direction.
In the example shown in the Figures, the fuel film 119a is spinning in a clockwise direction 140, and the fuel film 119b is spinning in the same (i.e. clockwise) direction 141. The air 116 is spinning in a counter clockwise direction 142, and the air 118 is also spinning in the same (i.e. counter clockwise) direction 143. It is contemplated that the air 116, 118 and fuel films 119a, 119b may be spinning in various combinations of directions relative to each other, with the fuel films 119a and 119b spinning in a same direction. The tangential momentum of the fuel films 119a, 119b is initiated downstream of the bifurcating passages 130. Having opposite direction between the fuel films 119a, 119b may decrease the momentum and the velocity and possibly preventing the thinning of the fuel film. One of the air 112 and 188 could spin in a same direction as the fuel films 119a, 119b. Some of the fuel and air may also not be spinning.
Turning now to
The nozzle 200 includes generally a cylindrical body 202 defining an axial direction A and a radial direction R. The body 202 defines centrally in its interior a primary air passageway 203 (a.k.a. core air), a secondary air passageway 204 and a first fuel passageway 206, all extending axially through the body 202 and communicating with a pressurized source of fuel (not shown). The first fuel passageway 206 is disposed concentrically between the primary air passageway 203 and the secondary air passageway 204. It is contemplated that the nozzle 200 could include more than one primary and secondary air passageways 203, 204 and that the primary and secondary air passageways 203, 204 could have a shape of any one of a conduit, channel and an opening. The size, shape, and number of the air passageways 203, 204 may vary depending on the flow requirements of the nozzle 200, among other factors. Similarly, although one annular first fuel passageway 206 is disclosed herein, it is contemplated that the nozzle 100 could include a plurality of fuel passageways 206, annular shaped or not. As will be described in more detail below, the fuel passageway includes a plurality of concentric fuel flows which are fed to a plurality of frustoconical fuel filming surfaces 207 and 209.
The body 202 includes an upstream end (not shown) connected to sources of pressurised fuel and air and a downstream end 214 at which the air and fuel exit. The terms “upstream” and “downstream” refer to the direction along which fuel flows through the body 202. Therefore, the upstream end of the body 202 corresponds to the portion where fuel/air enters the body 202, and the downstream end 214 corresponds to the portion of the body 202 where fuel/air exits.
The primary air passageway 203 is defined by outer wall 203b and carries pressurised air illustrated by arrow 216. The air 216 will be referred interchangeably herein to as “air”, “jet of air”, or “core flow of air”. The secondary air passageway 104 is defined by inner wall 204a and outer wall 204b and carries pressurised air illustrated by arrow 218. The air 218 will be referred interchangeably herein to as “air”, “film of air”, or “flow of air”.
The first fuel passageway 206 is defined by inner wall 206a and outer wall 206b, and carries pressurised fuel illustrated by arrow 219. The inner wall 206a ends with the exit end 215 of the primary air passageway 203, while the outer wall 206b extends downstream relative to the inner wall 206a. The outer wall 206b provides a filming surface 207 which includes an axial first portion 220, a converging second portion 222, and a second filing surface 209 which includes an axial third portion 224 and a converging fourth portion 226. The first and second filming surfaces 207, 209 are inwardly (an in this example radially) facing surfaces of nozzle projections 227, 229. The nozzle projections 227, 229 are downstream extending portions of the outer walls of the first fuel passageway 206 and an annular second fuel passageway 232 disposed around the first fuel passageway 206.
In this example, the inner wall 206a and outer wall 206b are evenly spaced throughout the first fuel passageway 206, except at the second portion 222, where the inner wall 206a and outer wall 206b form an annular chamber 223. The annular chamber 223 may allow the fuel to be fed from a single source. The size of the annular chamber 223 may vary from shown in the Figures. The fourth portion 226 ends at exit end 228, downstream of the exit end 215 of the air passageway 203.
The secondary air passageway 204 and the first fuel passageway 206 are typically convergent in the downstream direction at the downstream end 214. The outer wall 206b of the first fuel passageway 206 is converging at the downstream end 214, thereby forcing the annular film of fuel 219 expelled by the first fuel passageway 206 onto the jet of air 216 expelled from the primary air passageway 203. Similarly, the outer wall 204b of the secondary air passageway 204 is converging at the downstream end 214, thereby forcing the annular film of air 218 expelled by the secondary air passageway 204 onto the annular film of fuel 219. At the downstream end 214, the annular film of fuel 219 is sandwiched by the core flow of air 216 of the primary air passageway 103 and the annular flow of air 218 of the secondary air passageway 204.
In this example, the outer wall 206b of the first fuel passage 206 includes a flow splitter in the form of a plurality of bifurcating passages 230 (only one being shown in
The second fuel passageway 232 includes an end 234 connected to the bifurcating passage 230 and an open end 236 downstream of the bifurcating passage 230. An outer wall of the second fluid passageway 232 includes the filming surface 209. The second fuel passageway 232 is not connected to a source of fuel and is fed in fuel solely by the first fuel passageway 206. As a result, the fuel film 219 splits into two concentric annular fuel films 219a, 219b, each of reduced thickness relative to the fuel film 219. Having a fuel film of reduced thickness improves transformation of the fuel film into droplet (i.e. atomisation). In the example shown in the figures, the fuel film 219b exits the fuel nozzle 200 at the exit end 228 and becomes in contact with the air 216. Similarly the fuel film 219a becomes in contact with the air 218 at the open end 136. Shearing between the fuel films 219a (resp. 219b) and the air 218 (resp. 216) exiting at different velocities, creates respective droplets 221a (resp. 221b) of fuel that will be ignited in the combustor 16.
In use, the air 216, 218 and the fuel films 219a, 219b may be given a spin or swirl or momentum to increase shearing between them, but also to enable the portion 219a of the fuel film 219 to travel through the bifurcating passages 230. This spin or swirl may be achieved by any suitable means. The surface treatment may include a plurality of grooves, for example, helicoidally grooves or protrusions. When spinning in the first fuel passageway 206, the fuel film 219 has a tangential velocity component (or momentum) and tends to accumulate on the outer wall 206b of the fuel passageways 206. As a result, when the fuel 219 encounters the bifurcating passage 230 formed in the outer wall 206b, a portion naturally separates from the fuel film 219 and flows through the bifurcating passage 230 to provide a plurality of concentric flows. The concentric flows 219a, 219b spinningly converge inwardly, as a result of being directed by the converging portions of the filing surfaces 207, 209 (i.e. converging second portion 222 and converging fourth portion 224 of the nozzle projections 227, 229 respectively), and disperse into atomized droplets 221a, 221b, as the fuel flows come into contact with the air flows 216, 218, passing through the respective primary and secondary air passageways 203, 204. Providing a plurality of concentric filming surfaces 207, 209 may result in a smaller droplet size and hence better atomization, as compared to the provision of a single filming flow.
In the example shown in the figures, the plurality of bifurcating passages 230 are inclined relative to the radial direction R to facilitate the flow of the fuel 219a. An angle between a downstream wall 230b of the bifurcating passages 230 and the axial direction is acute (i.e. the bifurcating passages 230 are downstream inclined).
In the example shown in the Figures, the fuel film 219a is spinning in a clockwise direction 240, while the fuel film 219b is spinning in a counterclockwise direction 241. The air 216 is also spinning in a clockwise direction 242, while the air 218 is spinning in a counter clockwise direction 243. Having the fuel films 219a, 219b spinning in opposite directions from the air may enhance the shearing and atomisation of the fuel. It is contemplated that the air 216, 218 and fuel films 219a, 219b may be spinning in various combinations of directions relative from each other. Some of the fuel and air may also not be spinning.
The above flow splitter may allow producing exiting fuel films with a reduced thickness with minimal redesign of the fuel nozzle, avoiding the complications of staging and multiple fuel passages.
The above description is meant to be exemplary only, and one skilled in the art will recognize that changes may be made to the embodiments described without departing from the scope of the invention disclosed. For example, while a single bifurcation through the bifurcating passage 130/230 is shown in the figures, it is contemplated that more than one bifurcation would split the fuel films 119/219 into more (and possibly thinner) films. It is also contemplated that the fuel nozzle 100/200 could include another air passageway, such as disposed between the first fuel passageway 106/206 and the second fuel passageway 132/232 so as to shear in between the fuels films 119a, 119b/219a,219b. Similarly, the nozzle 100/200 could include a variety of bifurcating passages 130/230. Various shapes, number and disposition of the bifurcating passages 130/230 is contemplated. For example, the fuel nozzle 100/200 could have more than one circumferential array of bifurcating passages 130/230. The bifurcating passages 130/230 could be axially aligned or interspaced. The size and number and configuration of the bifurcating passages need not each be identical, and passages 130/230 for example may be provided to obtain the fuel film 119a/219a of a desired thickness. In another example, a desired thickness could be half of a thickness of the fuel film 119/219. In any case, the bifurcating passages 130/230 may not redirect all the fuel 119/219, but only a substantive portion 119a/219a to enable thinning of the fuel films 119a, 119b/219a, 219b relative to the fuel film 119/219. Other modifications which fall within the scope of the present invention will be apparent to those skilled in the art, in light of a review of this disclosure, and such modifications are intended to fall within the appended claims.
The present application is a divisional of U.S. patent application Ser. No. 14/494,872 filed on Sep. 24, 2014, the entire content of which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 14494872 | Sep 2014 | US |
Child | 15788092 | US |