The present invention relates to a fuel spray nozzle for combustors of gas turbine engines.
Fuel injection systems deliver fuel to the combustion chamber of a gas turbine engine, where the fuel is mixed with air before combustion. One form of fuel injection system well-known in the art utilises fuel spray nozzles. These atomise the fuel to ensure its rapid evaporation and burning when mixed with air.
An airblast atomiser nozzle is a type of fuel spray nozzle in which fuel delivered to the combustion chamber by one or more fuel injectors is aerated by air swirlers to ensure rapid mixing of fuel and air, and to create a finely atomised fuel spray. The swirlers impart a swirling motion to the air passing therethrough, so as to create a high level of shear and hence acceleration of the low velocity fuel film.
Typically, an airblast atomiser nozzle has a number of coaxial air swirler passages. An annular fuel passage between a pair of air swirler passages feeds fuel onto a prefilming lip, whereby a sheet of fuel develops on the lip. The sheet breaks down into ligaments which are then broken up into droplets within the shear layers of the surrounding highly swirling air to form the fuel spray stream that enters the combustor.
Hot combustion gases can produce high metal temperatures in the nozzle, leading to degradation of the nozzle and a reduced service life. In particular, in nozzles having a coaxial arrangement of an inner pilot airblast fuel injector, an intermediate air swirler passage and an outer mains airblast fuel injector, high metal temperatures can be problem for a wall of the intermediate air swirler passage.
It is desirable to provide a fuel spray nozzle that is less susceptible to high metal temperatures.
The swirling air passing through the air swirler passages can help to protect the nozzle from contact with hot combustion gases, and can also convectively cool surfaces of the nozzle, extracting heat absorbed from flame radiation.
Accordingly, in a first aspect, the present invention provides a fuel spray nozzle for a gas turbine engine, the nozzle having a coaxial arrangement of an inner pilot airblast fuel injector and an outer mains airblast fuel injector, the nozzle further having an intermediate air swirler passage which is sandwiched between an outer air swirler passage of the pilot airblast fuel injector and an inner swirler air passage of the mains airblast fuel injector, wherein:
the nozzle further has an annular first splitter wall which separates the pilot outer air swirler passage from the intermediate air swirler passage, an outer surface profile of the first splitter wall defining a radially inner side of the intermediate air swirler passage; and
the nozzle further has an annular second splitter wall which separates the intermediate air swirler passage from the mains inner air swirler passage, an inner surface profile of the second splitter wall defining a radially outer side of the intermediate air swirler passage;
the outer surface profile of the first splitter wall and the inner surface profile of the second splitter wall having respective convergent sections (the convergence being relative to the overall axial direction of flow through the injector) which face each other to produce a convergent portion of the intermediate air swirler passage, and the inner surface profile of the second splitter wall further having a divergent section (similarly, the divergence being relative to the overall axial direction of flow through the injector) downstream of its convergent section.
Advantageously, the convergent section of the inner surface profile of the second splitter wall helps the air flow through the intermediate air swirler passage to form and maintain a cooling film on the convergent section of the outer surface profile of the first splitter wall. In this way, the metal temperature of the first splitter wall can be reduced, improving the service life of the nozzle.
In a second aspect, the present invention provides a combustor of a gas turbine engine having a plurality of fuel spray nozzles according to the first aspect.
In a third aspect, the present invention provides a gas turbine engine having the combustor of the second aspect.
Optional features of the invention will now be set out. These are applicable singly or in any combination with any aspect of the invention.
The pilot airblast fuel injector may typically have, in order from radially inner to outer, a coaxial arrangement of a pilot inner swirler air passage, a pilot fuel passage, and the pilot outer air swirler passage. The mains airblast fuel injector may typically have, in order from radially inner to outer, a coaxial arrangement of the mains inner swirler air passage, a mains fuel passage, and a mains outer air swirler passage. In either case, fuel exiting the respective fuel passage is atomised into a spray by surrounding swirling air exiting the air swirler passages.
The convergent section of the outer surface profile may extend downstream to a terminating annular lip of the first splitter wall.
The first splitter wall may be substantially frustoconical in shape over the length of the convergent section of its outer surface profile.
The divergent section of the inner surface profile may extend downstream to a terminating annular lip of the second splitter wall.
The second splitter wall may be substantially frustoconical in shape over the length of the divergent section of its inner surface profile.
The second splitter wall may have an inwardly directed annular nose which forms a transition between the convergent and divergent sections of the inner surface profile of the second splitter wall. The nose can act as a shroud, discouraging separation of the air flow leaving the convergent portion of the intermediate air swirler from the outer surface profile of the first splitter wall.
The intermediate air swirler passage typically contains a swirler that produces a swirl angle for the air flow through the intermediate air swirler passage. The swirler may produce a swirl angle for the air flow of more than 45° relative to the overall direction of flow through the passage. Preferably, the swirl angle may be more than 55° or 65°. By producing a relatively high swirl angle, swirling flow can be maintained around the successive convergent and divergent sections of the inner surface profile of the second splitter wall.
The second splitter wall may contain a row of circumferentially arranged internal bypass ducts which are arranged such that, in use, a portion of the air flow through the intermediate air swirler passage is diverted through the ducts to by-pass the convergent portion of the intermediate air swirler passage, the diverted air exiting the ducts to re-join the non-diverted air flow at the divergent section of the inner surface profile of the second splitter wall. In this way, if the non-diverted air flow is unable to form an adequate cooling film on the second splitter wall, e.g. over the most downstream end of the divergent section of its inner surface profile, the diverted air can be used to maintain cooling film coverage in such regions. In addition, air jets emerging from the ducts can provide impingement cooling of the second splitter wall.
The ducts may be angled at substantially the same angle as the swirl angle of the air flow through the intermediate air swirler passage. This assists the air flow to remain attached to the second splitter wall over the divergent section.
The second splitter wall may further contain an internal annular passage which is arranged such that an upstream end of the internal annular passage receives the diverted air flow exiting the ducts and a downstream end of the internal annular passage opens to the divergent section of the inner surface profile of the second splitter wall to re-join the diverted air flow with the non-diverted portion of the air flow. Such an internal passage allows the position at which the diverted air flow re-joins with the non-diverted air flow to be selected for best effect. For example, locating the downstream end of the internal annular passage close to the downstream end of the divergent section can help to reduce metal temperatures e.g. over exposed regions adjacent a terminating lip of the second splitter wall.
The first splitter wall may contain a row of circumferentially arranged effusion holes at the downstream end of the convergent portion of the intermediate air swirler passage. The holes can be angled at the swirl angle of the air flow through the intermediate air swirler passage. The holes can help to cool the first splitter wall, particularly in a region of the terminating lip of the wall.
Embodiments of the invention will now be described by way of example with reference to the accompanying drawings in which:
With reference to
During operation, air entering the intake 11 is accelerated by the fan 12 to produce two air flows: a first air flow A into the intermediate pressure compressor 13 and a second air flow B which passes through the bypass duct 22 to provide propulsive thrust. The intermediate pressure compressor 13 compresses the air flow A directed into it before delivering that air to the high pressure compressor 14 where further compression takes place.
The compressed air exhausted from the high-pressure compressor 14 is directed into the combustion equipment 15 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 16, 17, 18 before being exhausted through the nozzle 19 to provide additional propulsive thrust. The high, intermediate and low-pressure turbines respectively drive the high and intermediate pressure compressors 14, 13 and the fan 12 by suitable interconnecting shafts.
The swirling air passing through the passages 120, 124, 130, 134, 140 of the fuel spray nozzle 100 is high pressure and high velocity air derived from the high pressure compressor 14. Each swirler passage 120, 124, 130, 134, 140 has a respective swirler 220, 224, 230, 234, 240 which swirls the air flow through that passage.
The outer surface profile of the first splitter wall 142 has a straight section 150 parallel to the axis of the nozzle followed by a convergent section 152. The inner surface profile of the second splitter wall 144 has a straight section 160 parallel to the axis of the nozzle, followed by a convergent section 162 and then a divergent section 164. The two straight sections 150, 160 define a straight portion of the intermediate passage 140 which contains the swirler 240. The two convergent sections 152, 162 define a convergent portion of the intermediate passage. The first splitter wall is substantially frustoconical over the length of the convergent section 152, which extends downstream to a terminating lip 156 of the first splitter wall. The second splitter wall is substantially frustoconical over the length of the divergent section 164, which extends downstream to a terminating lip 166 of the second splitter wall. The second splitter wall has an inwardly directed annular nose 168 between the convergent 162 and divergent 164 sections.
Air flow through and from the intermediate passage 140 is indicated in
If the second splitter wall 144 did not have a convergent section 162 and the inwardly directed nose 168, the air flow through the intermediate passage 140 would tend to separate from the first splitter wall 142 as it turned radially outwardly along the frustoconical section of the of the second splitter wall. However, by adopting a convergent-divergent profile for the inner surface of the second splitter wall 144, an increased path length for the air flow through the intermediate passage 140 is produced. In particular, the air flow is forced in the convergent portion of the passage to follow the line of the frustoconical part of the first splitter wall 142. This helps to ensure that the air flow forms a cooling film over the first splitter wall, particularly towards its lip 156. In this way, the metal temperature of exposed parts of the first splitter wall can be reduced, improving the service life of the nozzle.
At the end of the convergent portion of the intermediate passage 140, the air flow then turns around the nose 168, the air forming a cooling film over the frustoconical part of the second splitter wall 144.
To maintain a swirling flow, despite the increased path length for the air flow through the intermediate passage 140, the swirler 240 can produce a relatively high swirl angle, e.g. of more than 45° or preferably of more than 55° or 65°.
In general it is desirable that the air flow from the pilot airblast fuel injector does not to mix with the air flow from the intermediate passage 140. To this end, the second splitter wall 144 can be shaped such that the air flow through the intermediate passage 140 turns around the nose 168 to leave a short portion of the first splitter wall 142 at the terminating lip 156 unwashed by the flow. To avoid overheating at this short portion, the first splitter wall can contain a row of angled effusion holes 176 adjacent its terminating lip which allow some of the air flow through the intermediate passage to effuse through and cool the wall.
The increased length of the flow path for the air flow through the intermediate passage 140 can reduce the effectiveness of the cooling film at the downstream end of the frustoconical part of the second splitter wall 144. To counteract this, in the variant the second splitter wall contains a row of circumferentially arranged internal bypass ducts 170 which run across the nose 168. The frustoconical part of the second splitter wall also contains an internal annular passage 172. The ducts 170, which can be angled at substantially the same angle as the swirl angle of the air flow through the intermediate passage, divert a portion of the air flow from the intermediate passage away from the convergent portion of the passage and direct it into a downstream end of the internal passage 172. From here, the diverted air, still swirling, coalesces into a continuous circumferential film which flows along the internal passage, to exit therefrom part way along the frustoconical part of the second splitter wall and re-join the non-diverted portion of the air flow. The re-joining air flow is thus well-positioned to improve the cooling film of the downstream end of the frustoconical part of the second splitter wall. In addition, the air jets emerging from the ducts can provide impingement cooling of the second splitter wall on the far surface of the internal passage.
While the invention has been described in conjunction with the exemplary embodiments described above, many equivalent modifications and variations will be apparent to those skilled in the art when given this disclosure. Accordingly, the exemplary embodiments of the invention set forth above are considered to be illustrative and not limiting. Various changes to the described embodiments may be made without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
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1321764.1 | Dec 2013 | GB | national |
This application is a continuation application of U.S. application Ser. No. 14/553,451, filed Nov. 25, 2014, the contents of which are incorporated herein by reference
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Number | Date | Country | |
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Parent | 14553451 | Nov 2014 | US |
Child | 15878518 | US |