US20170082289A1

US20170082289A1 - Combustor burner arrangement

Info

Publication number: US20170082289A1
Application number: US15/305,219
Authority: US
Inventors: Suresh Sadasivuni
Original assignee: Siemens AG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2014-05-02
Filing date: 2015-04-15
Publication date: 2017-03-23
Also published as: EP2940389A1; EP3137814A1; EP2940390A1; CN106415132B; EP3137814B1; RU2016142786A; RU2016142786A3; RU2642971C1; US10533748B2; CN106461219B; RU2672216C2; WO2015165735A1; EP3137815A1; CN106461219A; US20170045231A1; EP3137815B1; WO2015166017A1; CN106415132A

Abstract

A burner for a combustor having a burner axis, a fuel lance, an igniter and a main air flow passage(s). The passage is angled relative to the burner axis and creates a main vortex thereabout in a first rotational direction. The main vortex travels in a direction along the burner axis, away from the surface. The fuel lance is located downstream of the igniter with respect to the first rotational direction of the main vortex so that a part of a main air flow washes over the fuel lance and over the igniter. The fuel lance has a fuel lance axis, a liquid fuel tip having a fuel outlet and an array of air assist passages having outlets arranged thereabout. The air assist passages are angled relative to create an air assist vortex about the fuel lance axis in the same rotational direction to the first rotational direction.

Description

FIELD OF INVENTION

The present invention relates to combustion equipment of a gas turbine engine and in particular a burner arrangement of the combustion equipment.

BACKGROUND OF INVENTION

Gas turbines including dry low emission combustor systems can have difficulty lighting and performing over a full load range when using liquid fuels. Often this can be because of fuel placement and subsequent atomization of the fuel in mixing air flows particularly at low loads demanded from the engine. Ideally, the fuel droplets need to be very small and injected into an appropriate part of the airflow entering the combustor's pre-chamber via an annular array of main air flow swirlers in the vicinity of a burner arrangement to burn in the correct flame location. Also the fuel droplets should not contact any wall surface but at the same time the fuel droplets need to come close enough to the igniter so that the igniter can ignite the vaporised fuel on start up. If the fuel droplets contact a surface this can lead to carbon deposits building up or lacquers forming and which can alter airflow characteristics or even block air and/or fuel supply holes.
The liquid pilot injection lance can have additional air assistance to aid atomisation of the liquid fuel over a range of fuel flows. This air assistance can be a supplied via a number of air outlets completely surrounding a fuel orifice or filmer. These air assist outlets are angled to create a pilot fuel/air vortex that rotates in an opposite direction to the direction of rotation of a main fuel/air vortex. This liquid pilot injection lance is in a region prone to liquid fuel contact and as a result tends to incur carbon deposits. The residence time of the liquid fuel droplets is a crucial parameter for the fuel droplets to stay close to the surface of the wall of the burner. The longer the time the liquid fuel droplets reside close to the surface of the wall, the richer the fuel/air mixture and hence there is an increase in carbon deposition, nitrous-oxide (NOx) emissions and higher local heating of the surface near the pilot burner which in turn increases thermal gradients that lead to cracking in the surface.
These carbon deposits block the air assistance holes and subsequently prevent successful atomisation of the fuel. Poor atomisation of the pilot fuel also causes problems with ignition of the fuel at start-up. This is a common fault with gas turbine fuel injection systems and carbon build up is a common problem. Consequently, liquid pilot injection lances are regularly replaced and are considered a consumable part. This is undesirable because such replacement is expensive, causes the gas turbine to be off-line halting supply of electricity or power for example, and can be unscheduled.

SUMMARY OF INVENTION

One objective of the present invention is to prevent carbon deposits forming on components. Another objective is to prevent carbon deposits forming on a fuel lance of a combustor. Another object is to improve the reliability of igniting the fuel in a combustor. Another objective is to improve the entrainment of fuel droplets in an air flow. Another objective is to improve the atomisation of liquid fuel in a combustor. Another objective is to prevent liquid fuel contacting a surface within the combustor. Another objective is to reduce or prevent scheduled or unscheduled shut down of the engine for maintenance attributed to replacing or cleaning combustor components subject to carbon deposits and particularly the liquid fuel lance. Yet another objective is to reduce the residence time of the liquid fuel droplets close to the burner surface. A further objective is to reduce high local heating of the burner surface. Still further, an objective is to reduce emissions of the combustor.
These advantages and objectives are realised by the provision of a burner for a combustor of a gas turbine combustor, the burner comprises a body having a surface and an burner axis, a fuel lance, an igniter and a main air flow passage or passages, the main air flow passage or passages is angled relative to the burner axis and creates a main vortex about the burner axis in a first rotational direction, the main vortex travels in a direction along the burner axis and away from the surface, the fuel lance is located downstream of the igniter with respect to the first rotational direction of the main vortex so that a part of a main air flow washes over the fuel lance and then over the igniter, the fuel lance comprises a fuel lance axis, a liquid fuel tip having a fuel outlet and an array of air assist passages having outlets arranged about the fuel outlet, wherein the air assist passages are angled relative to the fuel lance axis to create an air assist vortex about the fuel lance axis in the same rotational direction to the first rotational direction.
The main air flow passage or passages may be tangentially angled relative to the burner axis.
The air assist passages may be radially angled relative to the fuel lance axis.
The air assist passages may be radially angled between and including 15° and 60° relative to the fuel lance axis.
The air assist passages may be radially angled approximately 30° relative to a tangent of the fuel lance axis.
The air assist passages may have a tangential angle between +/−45° relative to a tangent of the fuel lance axis.
The air assist passages may have a tangential angle approximately 0° relative to a tangent of the fuel lance axis.
The fuel lance and the igniter may be located at the same radial distance from the burner axis.
The fuel lance and the igniter may be located at different radial distances from the burner axis and preferably the igniter is radially inwardly of the fuel lance.
The fuel outlet of the fuel lance may be located at or near to the surface.
The igniter may be at least partly housed within the body and has an end face, the end face is located at or near to the surface.
The burner may comprise an annular array of swirl vanes arranged about the burner axis and which form the main air flow passages.
The main air flow passages may be angled in an anti-clockwise direction and the air assist passages are angled in an anti-clockwise direction relative to a view on to the surface.
The main air flow passages may be angled in a clockwise direction and the air assist passages are angled in a clockwise direction relative to a view on to the surface.
In one example, the fuel outlet is a fuel prefilmer and which may be divergent towards its end and can create a cone of fuel. In another example, the fuel outlet is an orifice and which can create a spray of fuel. In yet another example, the fuel outlet is a number of orifices and each orifice can create a spray of fuel.

BRIEF DESCRIPTION OF THE DRAWINGS

Further features, properties and advantages of the present invention will become clear from the following description of embodiments in conjunction with the accompanying drawings in which;

FIG. 1 shows part of a turbine engine in a sectional view in which the present invention is incorporated,

FIG. 2 shows a perspective schematic view of a section of a combustor unit of turbine engine and in detail a burner arrangement including a pilot burner surrounded by a main burner, the pilot burner having a liquid fuel lance and an igniter and is in accordance with present invention,

FIG. 3 shows a schematic perspective and cut-away view of part of the pilot burner and in detail the liquid fuel lance in accordance with present invention,

FIG. 4 is a view along a combustor axis and onto the surface of the burner as shown in FIG. 2 and where the pilot burner is generally surrounded by the main burner having an annular array of swirler vanes, the pilot burner having a liquid fuel lance in accordance with present invention,

FIG. 5 and FIG. 6 show sectional views of the main air flow along paths A-A and B-B respectively as shown in FIG. 4 and illustrates respective distributions of fuel droplets issuing from the liquid fuel lance,

FIG. 7 is a view on a tip of an embodiment of the present liquid fuel lance and generally along its axis showing an array of outlets arranged around a fuel outlet; the array of outlets directs a pilot air flow to impinge on, shearing and atomizing a liquid fuel film,

FIG. 8A is an isometric view of the liquid fuel lance schematically showing the relative radial angle μ of one of the air passages; the other air passages have been omitted for clarity,

FIG. 8B is a view on the exposed surface of the tip 72 of the liquid fuel lance as seen in FIG. 3,

FIG. 9 is a view on the surface of the burner and along the burner's central axis and indicates the orientation of the liquid fuel lance relative to the main air flow from the main burner and relative to the burner's central axis and in accordance with the present invention,

DETAILED DESCRIPTION OF INVENTION

FIG. 1 shows an example of a gas turbine engine 10 in a sectional view and generally arranged about a longitudinal axis 20. The gas turbine engine 10 comprises, in flow series, an inlet 12, a compressor section 14, a combustor section 16 and a turbine section 18 which are generally arranged in flow series and generally in the direction of the longitudinal or rotational axis 20. The gas turbine engine 10 further comprises a shaft 22 which is rotatable about the rotational axis 20 and which extends longitudinally through the gas turbine engine 10. The shaft 22 drivingly connects the turbine section 18 to the compressor section 12. The combustor section 16 comprises an annular array of combustor units 16 only one of which is shown.
In operation of the gas turbine engine 10, air 24, which is taken in through the air inlet 12 is compressed by the compressor section 14 and delivered to the combustion section or unit 16. The combustor unit 16 comprises a burner plenum 26, a pre-chamber 29, a combustion chamber 28 defined by a double walled can 27 and at least one burner 30 fixed to each combustion chamber 28. The pre-chamber 29, the combustion chamber 28 and the burner 30 are located inside the burner plenum 26. The compressed air 31 passing through the compressor 12 enters a diffuser 32 and is discharged from the diffuser 32 into the burner plenum 26 from where a portion of the air enters the burner 30 and is mixed with a gaseous and/or liquid fuel. The air/fuel mixture is then burned and the resulting combustion gas 34 or working gas from the combustion chamber is channeled via a transition duct 35 to the turbine section 18.
The turbine section 18 comprises a number of blade carrying rotor discs 36 attached to the shaft 22. In the present example, two discs 36 each carry an annular array of turbine blades 38. However, the number of blade carrying rotor discs could be different, i.e. only one disc or more than two rotor discs. In addition, guiding vanes 40, which are fixed to a stator 42 of the gas turbine engine 10, are disposed between the turbine blades 38. Between the exit of the combustion chamber 28 and the leading turbine blades 38 inlet guiding vanes 44 are provided.
The combustion gas 34 from the combustion chamber 28 enters the turbine section 18 and drives the turbine blades 38 which in turn rotates the shaft 22 to drive the compressor section 12. The guiding vanes 40, 44 serve to optimise the angle of the combustion or working gas on to the turbine blades 38. The compressor section 12 comprises an axial series of guide vane stages 46 and rotor blade stages 48.
The terms upstream and downstream refer to the flow direction of the airflow and/or working gas flow through the engine unless otherwise stated. The terms forward and rearward refer to the general flow of gas through the engine. The terms axial, radial and circumferential are made with reference to the rotational axis 20 of the engine unless otherwise stated.
FIG. 2 is a perspective view of a part of the combustor 16 showing the burner 30, the pre-chamber 29 and part of the combustion chamber 28. The combustion chamber 28 is formed with a tubular-like shape by the double walled can 27 (shown in FIG. 1) having and extending along a combustor axis 50. The combustor 16 extends along the combustor axial 50 and comprises the pre-chamber 29 and the main combustion chamber 28, wherein the latter extends in a circumferential direction 61 around the combustor axis 50 and generally downstream, with respect to the gas flow direction, of the pre-chamber volume 29.
The burner 30 comprises a pilot burner 52 and a main burner 54. The pilot burner 52 comprises a burner body 53, a liquid fuel lance 56 and an igniter 58. The main burner 54 comprises a swirler arrangement 55 having an annular array of swirler vanes 60 defining passages 62 therebetween. The annular array of swirler vanes 60 are arranged generally about a burner axis 50, which in this example is coincident with the combustor axis 50, and in conventional manner. The swirler arrangement 55 includes main fuel injection ports which are not shown, but are well known in the art. The main burner 54 defines part of the pre-chamber 29. The pilot burner 52 is located in an aperture 57 and generally radially inwardly, with respect to the burner/combustor axis 50, of the main burner 54. The pilot burner 52 has a surface 64 that defines part of an end wall of the pre-chamber 29. The end wall is further defined by the main burner 54.
The liquid fuel lance 56 is at least partly housed in a first hole 66 defined in the burner body 53 of the pilot burner 52. A pilot air flow passage 69 is formed between the liquid fuel lance 56 and the walls of the first hole 66. The liquid fuel lance 56 comprises an elongate fuel lance body 86 and a liquid fuel tip 72. The elongate fuel lance body 86 is generally cylindrical and defines a fuel flow passage 70. The liquid fuel tip 72 is mounted at one end of the elongate fuel lance body 86 and is located near to or at the surface 64. The liquid fuel lance 56 will be described in more detail with reference to FIG. 3. The igniter 58 is housed in a second passage 74 defined in the burner body 53 of the pilot burner 52. The end of the igniter 58 is located near to or at the surface 64. The igniter 58 is a well known device in the art and that requires no further description. In other combustors 16 it is possible that more than one liquid fuel lance and/or more than one igniter may be provided.
During operation of the gas turbine engine and more particularly at engine start-up, a starter-motor cranks the engine such that the compressor 14 and turbine 16 are rotated along with the shaft 22. The compressor 14 produces a flow of compressed air 34 which is delivered to one or more of the combustor units 16. A first or major portion of the compressed air 34 is a main air flow 34A which is forced through the passages 62 of the swirler arrangement 55 where the swirler vanes 60 impart a swirl to the compressed air 34 as shown by the arrows. A second or minor portion of the compressed air 31 is a pilot air flow 34B which is forced through the pilot air flow passage 69. The pilot air flow 34B can also be referred to as an air assistance flow. Liquid fuel 76 is forced through the fuel flow passage 70 and is mixed with the pilot air flow 34B and the main air flow 34A in order to atomise the liquid fuel. Atomisation of the liquid fuel into very small droplets increases surface area to enhance subsequent vaporisation.
The main air flow 34A generally swirls around the combustor axis 50. The swirler vanes 60 impart a tangential direction component to the main air flow 34A to cause the bulk main air flow 34 to have a circumferential direction of flow. This circumferential flow aspect is in addition to the general direction of the air and fuel mixture along the combustor axis 50 from or near the surface 64 towards the transition duct 35 (see FIG. 1). The fuel and air mixture passes through the pre-chamber 29 and into the combustion chamber 28. The main air flow 34A forces the pilot air flow 34B and entrained fuel near to the igniter 58, which then ignites the fuel/air mixture.
To start the engine, a starter motor rotates the shaft 22, compressor 14 and turbine 18 to a predetermined speed when the pilot fuel is supplied and ignited. Once ignited the combustor internal geometry and the air flow patterns cause a pilot flame to exist. As the engine becomes self-powering the starter-motor can be switched off. As engine demand or load is increased from start-up, fuel is supplied to the main fuel injection ports and mixed with the main air flow 34A. A main flame is created in the combustion chamber 28 and which is radially outwardly located relative to the pilot flame.
Reference is now made to FIG. 3, which shows a schematic perspective and cut-away view of part of the pilot burner 52 and in detail the liquid fuel lance 56. The liquid fuel lance 56 comprises the elongate fuel lance body 86 and the liquid fuel tip 72 which are elements that can be unitary or separate. The liquid fuel tip 72 is located and captured by a narrowing 78 at an end of the first hole 66 and forms a tight fit. At the end of the fuel flow passage 70, the liquid fuel tip 72 includes a swirl plate 80 which defines an array of fuel conduits 82 having inlets and outlets. The fuel conduits 82, only one of which is shown, are angled relative to a longitudinal or fuel lance axis 79 of the liquid fuel lance 56. Downstream of the swirl plate 80 is a fuel swirl chamber 84 and then a fuel outlet 86, which in this example is a fuel filmer. This fuel filmer 86 is divergent and produces a cone of liquid fuel. In other examples, the fuel outlet 86 can be an orifice that produces a spray of fuel or a number of orifices, each producing a spray of fuel.
The liquid fuel tip 72 forms an array of pilot air flow conduits 88 having inlets that communicate with the pilot air flow passage 69 and outlets 90 which surround the fuel filmer 86. In this exemplary embodiment, the pilot air flow conduits 88 are inclined or angled in both a circumferential sense and a radially inwardly relative to the longitudinal axis 79 of the liquid fuel lance 56. In other embodiments, the pilot air flow conduits 88 may be axially aligned, or angled in only one of the circumferential sense or radially inwardly relative to the longitudinal axis 79. In this exemplary embodiment there are 8 pilot air flow conduits 88; although in other embodiments there may be more or fewer conduits.
Pilot liquid fuel flowing in the fuel flow passage 70 enters the inlets of the fuel conduits 82 and exits the outlets imparting a swirl to the fuel in the fuel swirl chamber 84. The swirling fuel forms a thin film over the fuel filmer 86, which sheds the fuel in a relatively thin cone. Pilot air flow 34B impinges the cone of fuel and breaks the fuel into small droplets. The swirling vortex of air from the outlets 90 atomises the fuel along with the main air flow 34A.
The pilot air flow 34B is particularly useful at engine start-up and low power demands when the main air flow 34A has a relatively low mass flow compared to higher power demands and because of the lower mass flow is less able to atomise the liquid fuel. Advantageously, the pilot air flow 34B provides cooling to the pilot fuel lance and helps prevent fuel coking and carbon build up on the pilot fuel lance.
FIG. 4 is a view along the combustor axis 50 and on the surface 64 of the burner 30 where the pilot burner 52 is generally surrounded by the main burner 54. The liquid fuel lance 56 and the igniter 58 are shown mounted in the burner body 53 of the pilot burner 52. The swirler arrangement 55 of the main burner 54 surrounds the surface 64 and directs the main airflow 34B via the annular array of passages 62. The annular array of swirler vanes 60 and passages 62 are arranged to impart a tangential flow component to the main air flow 34A such that when the airflow portions from each passage 62 coalesce they form a vortex 34C generally about the burner axis 50. In this embodiment, the vortex 34C rotates generally anti-clockwise as seen in FIG. 4; this vortex 34C could also be said to be rotating in a clockwise direction as it travels in a direction from the surface 64 to the transition duct 35 through the pre-chamber 29 and then the combustor chamber 28.
In this exemplary embodiment, the vortex 34C is a single vortex, but in other examples the arrangements of pilot burner 52 and the main burner 54 can create a number of vortices rotating in either the same direction or different directions and at different rotational speeds.
The positions of the liquid fuel lance 56 and the igniter 58 are arranged so that the swirling or rotating main air flow 34A passes over or around the liquid fuel lance 56 and then on to the igniter 58. As the main airflow forms a vortex 34C about the axis 50, the liquid fuel lance 56 and the igniter 58 are positioned at approximately the same radial distance from the axis 50. Thus as the fuel lance 56 injects or sprays liquid fuel into the pre-chamber 29 the main airflow 34C entrains the fuel and transports it towards the igniter 58, where ignition can take place. However, it has been found that the fuel lance 56 and the igniter 58 can be located at different radial distances from the burner axis 50 and preferably the igniter 58 is radially inwardly of the fuel lance 56 because the co-rotating vortices draw the pilot vortex radially inward compared to counter-rotating vortices.
The vortex 34C has many different stream velocities within its mass flow. In this example, the portion of the vortex denoted by arrow 34Cs is travelling at a lower velocity than the portion of the vortex denoted by arrow 34Cf. Main air flow portion 34Cs is radially inwardly of main air flow portion 34Cf with respect to the axis 50. Main air flow portion 34Cs is at approximately the same radial position as the radially inner part of the pilot fuel lance 56 and the main air flow portion 34Cf is at approximately the same radial position as the radially outer part of the pilot fuel lance 56.
FIG. 5 and FIG. 6 show sectional views of the main air flow along paths A-A and B-B respectively as shown in FIG. 4 and the distribution of fuel droplets. In FIG. 4 the flow path B-B is radially outwardly of the fuel lance 56 and igniter 58 and the flow path A-A is approximately at the same radius as at least a part of the fuel lance 56 and igniter 58.
In FIG. 6 the fuel lance 56 and igniter 58 are shown in dashed lines for reference purposes. As shown, each portion of main air flow exiting each passage 62 flows for a short distance immediately across the surface 64, before leaving the surface 64 and travelling away from the surface 64 and along the axis 50 as another portion of the main air flow joins from a circumferentially adjacent passage 62. Thus as can be seen the any fuel droplets 92 entrained in this portion of the main air flow long flow path B-B are quickly lifted away from the surface 64 and therefore away from the igniter 58.
In FIG. 5 the main air flow 34A passes over the fuel lance 56 and on towards the igniter 58. The outlets 90, which surround the fuel filmer 86 of the fuel lance 56, direct the pilot air flow 34B to impinge on the cone of fuel exiting the fuel filmer 86 and break the fuel film into small droplets 92. The swirling vortex of pilot air, shown schematically as 94, from the outlets 90 atomises the fuel as it mixes with the main air flow 34A. The swirling vortex of pilot air 94 effectively forms a fluid buffer and causes to be formed on its leeward or downstream side a recirculation zone or a low-pressure zone 96. This recirculation zone or a low-pressure zone 96 draws the main air flow 34A towards the surface 64 between the fuel lance 56 and igniter 58. A portion of the fuel droplets 92 are also drawn towards the surface 64 and therefore close to the igniter 58 such that good ignition of the fuel/air mixture is possible.
Referring now to FIG. 7, which is a view on the tip 72 of the fuel lance 56 and generally along its axis 79, the array of outlets 90 direct the pilot air flow 34B with both tangential and radial components. These tangential and radial components will be explained in more detail below with reference to FIGS. 8A and 8B. When the portions of pilot air flow 34B from each outlet 90 merge they coalesce into the pilot vortex 94. The pilot vortex 94 rotates in a generally anti-clockwise direction as seen in FIG. 7; this vortex 94 could also be said to be rotating in a clockwise direction as it travels in a direction from the surface of the tip 72 towards the transition duct 35 through the pre-chamber 29 and then the combustor chamber 28. This is the same general direction of rotation as the main vortex. In this example, there are 8 outlets 90 arranged symmetrically about the axis 79 of the fuel lance and about the fuel filmer 86. This arrangement of outlets produces, at least initially, a symmetric pilot vortex 94. In other examples, the outlets 90 may be asymmetrically arranged about the fuel filmer 86 and one or each of the outlets 90 may be a different size.
In the case of the known fuel lance 56 and main swirler arrangement, where oppositely rotating vortices are present, in service it has been found that the outlets 90 become blocked by carbon deposits formed from liquid fuel landing on the surfaces of the fuel lance 56. In addition, carbon deposits can form on other surfaces of the burner arrangement. This blocking reduces the amount of pilot air flow 34B which in turn this reduces the effectiveness of the pilot air flow 34B shearing and breaking up the fuel film. As a consequence ignition of the fuel/air mixture becomes more difficult and unpredictable. Thus it has been found that the oppositely rotating main vortex and pilot vortex 94 causes particular air flow characteristics that lead to liquid fuel contacting the surface of the fuel lance and which then forms carbon deposits that block the outlets 90.
The counter-rotating pilot air flow 34B delivery and the counter-rotating pilot vortex 94 remain strong enough to effectively form the fluid buffer 94 and cause to be formed on its leeward or downstream side, the recirculation zone 96 or low-pressure zone 96. Thus the recirculation zone 96 or low-pressure zone 96 still draws the main air flow 34A towards the surface 64 between the fuel lance 56 and igniter 58. A portion of the fuel droplets 92 are also drawn towards the surface 64 and therefore close to the igniter 58 such that good ignition of the fuel/air mixture remains equally possible.
It has been found that arranging the fuel lance 56 and main swirler arrangement to have their respective vortices rotating in the same rotational direction, i.e. both clockwise or both anti-clockwise, carbon deposits are prevented or substantially prevented because fewer liquid droplets 92 contact the surfaces of the fuel lance 56 and burner.
FIG. 8A is an isometric view of the liquid fuel lance 56 schematically showing the relative radial angle μ of one of the air passages 88; the other air passages have been omitted for clarity. The air assist passages 88 have inlets 91 and a central axis 92. The air assist passages are typically drilled, but can be laser drilled or formed by an electron beam. It is possible that the tip of the fuel lance may be formed by layered deposition techniques, such as direct laser deposition, and so the shape of the air assist passage can be curved in any direction and in this case the angles referred to can relate to the issues air flow direction.
The air assist passages 88 are radially angled μ relative to the fuel lance axis 79. In this preferred embodiment the air assist passages 88 are radially angled μ approximately 45° relative to the fuel lance axis 79. However, at a minimum the angle μ is approximately 5° relative to the fuel lance axis 79. For best results the air assist passages 88 are radially angled μ between and including 30° and 60° relative to the fuel lance axis 79. It is even possible for the air assist passages 88 to be radially angled μ between and including 15° and 60° relative to the fuel lance axis 79 in certain examples of the invention.
FIG. 8B is a view on the exposed surface of the tip 72 of the liquid fuel lance as seen in FIG. 3 for example. Only one of the air assist passages 88 is shown for clarity. Here the central axis 92 of the air assist passages has a tangential angle δ of approximately 30° relative to a tangent 93 of the fuel lance axis 79. This tangential angle δ of approximately +30° is relative to a tangent 93, which is to say that the central axis 92 is angled ‘inwardly’. Here the outlet 90 is located radially inwardly of the inlet 91 relative to the axis 79. By angling the air passage inwardly a tighter vortex is generated and which can favourably atomise the fuel issuing from the fuel nozzle 86. In other embodiments the tangential angle δ can be between 25 and 45° relative to a tangent 93 and this can be dependent on the spray angle or liquid cone angle of the fuel issuing from the fuel outlet.
Alternatively, the tangential angle δ of approximately −45° is relative to a tangent 93, which is to say that the central axis 92 is angled ‘outwardly’. Here the outlet 90 is located radially inwardly of the inlet 91 relative to the axis 79. This can generates a weaker or less tight vortex to be formed and which can be more favourable where a high volume of air is used for the air assist or where a wide or flat cone of fuel is generated from the fuel orifice 86. In other examples, the air assist passages 88 can have a tangential angle δ approximately 0° relative to a tangent of the fuel lance axis 79.
Referring to FIG. 9 which is a view on the surface 64 of the burner 30 and along the axis 50 and from which a radial line 102 emanates and passes through the axis 78 of the fuel lance 56. The fuel lance 56 and igniter 58 are shown along with main airflow arrows 34A issuing from the main air flow passages 62. As described earlier, the portion of the vortex denoted by arrow 34Cf is travelling at a generally higher velocity than the portion of the vortex denoted by arrow 34Cs. The relatively slower flow is generally radially inward of the faster velocity air.
The fuel lance 56 as previously described is at least partly housed within the burner body 53 of the burner 30 and the outlets 90 and the fuel filmer 86 are located at or near to the surface 64. In this example, the outlets 90 and the fuel filmer 86 are located below the surface 64 in the burner body 53. The igniter 58 is also at least partly housed within the burner body 53 and has an end face 59, located just below the surface 64, but could be at or near to the surface 64.
The burner 30 further includes an array of gas injection ports 122 generally formed in a radially outward part of the burner 30 and under a circumferential lip 124 as shown in FIG. 2. These gas injection ports 122 can supply a pilot gas-fuel as is known in the art.
The terms clockwise and anticlockwise are with respect to the view on the surface 64 of the burner 30 as seen in FIG. 9.

Claims

What is claimed is:

1. A burner for a combustor of a gas turbine combustor, the burner comprises comprising:

a body having a surface and an burner axis, a fuel lance, an igniter and a main air flow passage or passages,

wherein the main air flow passage or passages is angled relative to the burner axis and creates a main vortex about the burner axis in a first rotational direction, the main vortex travels in a direction along the burner axis and away from the surface,

wherein the fuel lance is located downstream of the igniter with respect to the first rotational direction of the main vortex so that a part of a main air flow washes over the fuel lance and then over the igniter,

wherein the fuel lance comprises a fuel lance axis, a liquid fuel tip having a fuel outlet and an array of air assist passages having outlets arranged about the fuel outlet,

wherein the air assist passages are angled relative to the fuel lance axis to create an air assist vortex about the fuel lance axis in the same rotational direction to the first rotational direction.

2. A-The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the main air flow passage or passages is tangentially angled relative to the burner axis.

3. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the air assist passages are radially angled μ relative to the fuel lance axis.

4. The burner for a combustor of a gas turbine combustor as claimed in claim 3,

wherein the air assist passages are radially angled μ between and including 15° and 60° relative to the fuel lance axis.

5. The burner for a combustor of a gas turbine combustor as claimed in claim 3,

wherein the air assist passages are radially angled μ approximately 30° relative to a tangent of the fuel lance axis.

6. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the air assist passages have a tangential angle δ between +/−45° relative to a tangent of the fuel lance axis.

7. The burner for a combustor of a gas turbine combustor as claimed in claim k

wherein the air assist passages have a tangential angle δ approximately 0° relative to a tangent of the fuel lance axis.

8. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the fuel lance and the igniter are located at the same radial distance from the burner axis.

9. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the fuel lance and the igniter are located at different radial distances from the burner axis.

10. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the fuel outlet of the fuel lance is located at or near to the surface.

11. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the igniter is at least partly housed within the body and has an end face, the end face is located at or near to the surface.

12. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the burner comprises an annular array of swirl vanes arranged about the burner axis and which form the main air flow passages.

13. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the main air flow passages are angled in an anti-clockwise direction and the air assist passages are angled in an anti-clockwise direction relative to a view on to the surface.

14. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the main air flow passages are angled in a clockwise direction and the air assist passages are angled in a clockwise direction relative to a view on to the surface.

15. The burner for a combustor of a gas turbine combustor as claimed in claim 1,

wherein the fuel outlet is any one of a fuel prefilmer, an orifice or a number of orifices.

16. The burner for a combustor of a gas turbine combustor as claimed in claim 9,

wherein the igniter is radially inwardly of the fuel lance.