The subject matter disclosed herein relates to a combustion system, and more particularly, a combustion system with a unique deflector.
Turbine engines, such as those used to power modern commercial aircraft, include a compressor for pressurizing a supply of air, a combustor for burning a hydrocarbon fuel in the presence of the pressurized air, and a turbine for extracting energy from the resultant combustion gases. In many aircraft engine applications, the compressor, combustor and turbine are disposed about a central engine axis with the compressor disposed axially upstream of the combustor and the turbine disposed axially downstream of the combustor.
It has become increasingly desirable to increase the efficiency and reduce the size of turbine engines. Such turbine engines typically include one or more shafts that include compressors, bypass fans, and turbines. Typically, air is forced into the engine and passed into a compressor. The compressed air is passed to a combustor, and at high temperature and pressure the combustion products are passed into a turbine. The turbine provides power to the shaft, which in turn provides the power to the compressor and fan or gearbox. Thrust is thereby produced from the air that passes from the fan, as well as from the thrust expended in the turbine combustion products. This system is typically packaged together with power production and thrust generation co-located.
Combustors for turbine engines typically have a wall with a plurality of air holes, such as cooling or dilution holes, for admitting compressed air into the combustor. In an annular combustor, outer and inner walls cooperate to define, and are separated by, an annular combustion chamber.
An annular combustor may further have a bulkhead, which may be segmented into panels in some combustor designs, at a forward end of the combustor and extending from the outer wall to the inner wall. At least one fuel nozzle extends through this bulkhead and into the combustion chamber to release the fuel. A swirler is generally positioned around each fuel injector to admit combustion air, create turbulence in the combustion air, and mix the combustion air and the fuel before the mixture is combusted.
One prior combustion system may comprise an outer cowl, an inner cowl, a combustor dome attached to the outer cowl and the inner cowl, an outer wall, an inner wall, and a combustor space defined by the outer wall, the inner wall and the combustion dome. The combustor dome has an outer dome ring, an inner dome ring, a plurality of nozzle components positioned between the inner dome ring and the outer dome ring, and the ring-like fuel manifold formed with the outer dome ring.
However, the combustion system of this prior design as above have many separate components which makes them expensive and complex to prepare and assemble them into the combustion system. Another shortcoming of this prior art is that the combustion system can only be assembled into the engine case from an aft position of the engine case, i.e., in an aft-mounted way.
Another prior art design is shown in
Such a prior art as shown in
Furthermore, in the prior design in
Therefore, when utilized in conjunction with aircraft, space and weight are at a premium and the engines must be as light and compact as possible. It would be desirable to reduce component size and complexity of an aero engine without sacrifice of system performance thereof.
Certain embodiments commensurate in scope with the originally claimed invention are summarized below. These embodiments are not intended to limit the scope of the claimed invention, but rather these embodiments are intended only to provide a brief summary of possible forms of the invention. Indeed, the invention may encompass a variety of forms that may be similar to or different from the embodiments set forth below.
In a first embodiment, a combustion system is provided to comprise: a cowl; a deflector configurated to include a ring body and a plurality of arms integrally extending outward from the ring body; an annular inner liner attached with the cowl; an annular outer liner attached with the cowl; wherein the deflector is positioned between the inner liner and the outer liner; the deflector, the inner liner and the outer liner define a combustion chamber therebetween; and wherein the deflector is attached to the cowl via the plurality of arms which are rigid enough to fix the deflector with the cowl while allowing for thermal expansion flexibility therebetween at the same time.
The deflector further comprises a plurality of swirlers integrated with the ring body on a same side of ring body with the plurality of arms. Each of the plurality of arms is L-shaped, and has an arm extension extending from the ring body and a mounting face angled from the arm extension, and wherein the mounting face defines an aperture for a fastener therethrough to fix the arm with the cowl. The deflector is positioned between an upstream end of the inner liner and an upstream end of the outer liner, and wherein edges of the ring body abut ends of the cowl, inner surface of the upstream end of the inner liner and inner surface of the upstream end of the outer liner.
The cowl is annular and has a dome-like cross section, and wherein the cowl is attached to and between the upstream end of the inner line and the upstream end of the outer liner. The cowl is fixed to a case of an engine through one or more mounting arm, and the one or more mounting arm extends forward in an upstream direction for enabling the combustion system to be assembled within the case in a forward mounting way.
A fuel nozzle enters through the cowl and an end of the fuel nozzle aligns with a corresponding swirler of the deflector such that corresponding fuel flow into the swirler and a space between the cowl and the deflector before into the combustion chamber. The combustion system further comprises a ferrule for attaining the end of the fuel nozzle with the corresponding swirler of the deflector.
In a second embodiment, a combustion system is provided to comprise: a cowl; a deflector configurated to include a ring body, a plurality of swirlers and a plurality of arms; an annular inner liner attached with the cowl; an annular outer liner attached with the cowl; wherein the plurality of swirlers and the plurality of arms are integrated on the ring body, the deflector is positioned between the inner liner and the outer liner thereby defining a combustion chamber thereamong, and wherein the deflector is attached to the cowl via the plurality of arms.
The plurality of swirlers are integrated with the ring body on a same side of ring body with the plurality of arms. Each of the plurality of arms is L-shaped, and has an arm extension extending from the ring body and a mounting face angled from the arm extension, and wherein the mounting face defines an aperture for a fastener therethrough to fix the arm with the cowl. The deflector is positioned between an upstream end of the inner liner and an upstream end of the outer liner, and wherein edges of the ring body abut end walls of the cowl, inner surface of the upstream end of the inner liner and inner surface of the upstream end of the outer liner.
The cowl is annular and has a dome-like cross section, and wherein the cowl is attached to and between the upstream end of the inner line and the upstream end of the outer liner. The cowl is fixed to a case of an engine through one or more mounting arm, and the one or more mounting arm extends forward in an upstream direction for enabling the combustion system to be assembled within the case in a forward mounting way.
A fuel nozzle enters through the cowl and an end of the fuel nozzle engages with a corresponding swirler of the deflector for delivering a fuel flow via the deflector into the combustion chamber.
In a third embodiment, an engine system is provided to comprise: a case; a fuel nozzle; and a combustor assembly (system). The combustor assembly (system) includes: an annular cowl; a deflector configurated to include a ring body and a plurality of arms integrally extending outward from the ring body; an annular inner liner attached with the cowl; and an annular outer liner attached with the cowl. The deflector is positioned between the inner liner and the outer liner; the deflector, the inner liner and the outer liner define a combustion chamber thereamong. The deflector is attached to the cowl via the plurality of arms which are rigid enough to fix the deflector with the cowl while allowing for thermal expansion flexibility therebetween at the same time.
The present subject matter provides a combustion system employing a one-piece deflector (dome) with integrally formed swirlers that covers the entire annulus of an annular combustor. The function is to protect related structural components from high combustion gas temperatures and hold the swirlers in place during assembly and operation. The deflector is attached to the cowl via a plurality of relatively weak arms so that it is free to expand as thermal loads driven into the device. The deflector typically has minimal mounting features and is printed as one piece with the swirlers. Additionally, the deflector may have holes printed into the surface that faces the combustor flame.
The assembly/fixing mechanism between the deflector and the cowl without additional dome (compared with the prior arts), which is a design simpler, lighter and cost-saving compared with the prior arts. And more importantly, the weakness of the arms allows for thermal expansion while the arms keep the combination of the whole structure stiff enough to withstand vibrational stresses.
Another advantageous technical effect of the present subject matter is that the ring body, the swirlers and the (weak) arms are integrated into the deflector as one single piece, which is simpler, lighter and cost-saving compared with the prior arts with separate ring, swirlers and deflectors.
Further, the present subject matter gives a forward mounting structure of the combustion system (combustor) with forwardly extending mounting arms fixed to the engine's case via fasteners, which makes the combustor/combustion system having a stronger capability against various vibrations.
These and other features, aspects, and advantages of the present subject matter will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
One or more specific embodiments of the present subject matter will be described below. In an effort to provide a concise description of these embodiments, all features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
In the following specification and the claims, reference will be made to a number of terms, which shall be defined to have the following meanings.
When introducing elements of various embodiments of the present subject matter, the articles “a,” “an,” “the,” and “the” are intended to mean that there are one or more of the elements. The terms “comprise/comprising,” “include/including,” and “have/having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
“Optional” or “optionally” means that the subsequently described event or circumstance may or may not occur, and that the description includes instances where the event occurs and instances where it does not.
Approximating language, as used herein throughout the specification and claims, may be applied to modify any quantitative representation that could permissibly vary without resulting in a change in the basic function to which it is related. Accordingly, a value modified by a term or terms, such as “about”, “approximately”, and “substantially”, are not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value. Here and throughout the specification and claims, range limitations may be combined and/or interchanged, and such ranges are identified and include all the sub-ranges contained therein unless context or language indicates otherwise.
The present subject matter can be applied to any annular combustor. A solution in accordance with the present subject matter provides advantages in the areas of part count, assembly, and durability. The solution combines the functionality of deflector/dome segments and positioning of the swirler. This means that there is no need for a combustor dome if structural loads are directed through liners, cowls or other components.
Now referring to
With reference to
A fuel nozzle 6 is fixed onto the case 20 (
A diffuser 4 is located at an upstream position relative to the combustor 75. Compressed air coming from a compressor flow through the diffuser 4 in a direction as indicated in arrow A into the chamber 22 between the case 20 and the inner structures 3. The compressed air may then flow into the combustor 75 for combustion.
With references to
As better shown in
The cowl 5 is annular and has a dome-like cross section. A plurality of apertures 55 are defined in an annular dome-like portion 56 of the cowl 5. The apertures are adapted to receive the injection end 65 of the fuel nozzle 6 therethrough and also allow some of the compressed air to pass through and go into the combustor 5. A plurality of mounting arms 51 extend outwardly and forwardly from the dome-like portion 56. Each mounting arm 51 has a mounting portion 53 at an end of the mounting arm 51 away from the dome-like portion 56. The mounting portion 53 may be a square plate like a platform, however, it can have any shape or configuration which enables it to fulfill its function. A hole 530 is defined in the mounting portion 53 for accommodating a fastener 54 (as in
As clearly shown in
It is well known that, in an engine, there would be various types of vibrations such as rotor/fan vibrations, aircraft/wing vibrations, vibrations caused by compressor blade passing frequencies, combustor acoustic vibrations, and engine system vibrations, etc. Because most of the weight of the combustor 75 focuses at an upstream end of the combustor 75, the forward mounting structure of the combustor 75 will definitely be more steady and firmer to resist possible strong vibrations as compared to the aft-mounted type of annular combustors in the prior arts discussed above.
Further refer to
Each swirler 84 extends upward from the surface 87 of the ring body 81 and defines a flare 85 therethrough in the center, with reference to
Particularly shown in
A mounting hole 834 is defined in the mounting face 832 for receiving a fastener 50 therethrough. The fastener 50 may be a bolt, nut, screw, or in other forms and is used to couple the arm 83 with the cowl 5. The fasteners/bolts 50 may go through corresponding mounting holes 834 of the arms 83 of the deflector 8 and then through corresponding holes (not labeled) in the dome-like portion 56 of the cowl 5 so as to fasten the deflector 8 with the cowl 5. In this way, the deflector 8 is attached to the cowl via the plurality of arms 83 which are rigid enough to fix the deflector 8 with the cowl 5 while allowing for thermal expansion flexibility therebetween at the same time.
An upstream end of the inner liner 70 and an upstream end of the outer liner 72 are coupled to opposite ends of the cowl 5 respectively via fasteners 52 respectively. Alternatively, the fasteners 52 may be any other suitable fastening means. The opposite ends of the cowl 5 extend respectively from opposite sides of the dome-like portion 56. The ring body 81 of the deflector 8 is traversely positioned between the upstream end of the inner liner 70 and the upstream end of the outer liner 72, while abuts against the opposite ends of the cowl 5 and inner walls of the inner and outer liners 70/72 in the meantime. In other words, the width of the surface 87 (the ring body 81) defines a distance between the upstream end of the inner liner 70 and the upstream end of the outer liner 72. By this way, the dome-like portion 56 of the cowl 5 and the ring body 81 of the deflector 8 enclose an annular chamber (not labeled). The swirlers 84 are located within the annular chamber between the dome-like portion 56 and the ring body 81.
Hence, the inner liner 70, the deflector 8 and the outer liner 72 commonly define the combustion chamber 9. There is a plurality of dilution holes 71 in the inner liner 70 and a plurality of dilution holes 73 in the outer liner which all are set for permitting air coming through from the chamber 22 between the case 20 and the combustor 75 into the combustion chamber 9.
Returning to
Optionally, about 20% of the compressed air, which enter the combustion chamber 9, flow through the apertures 55 of the cowl 5 and then through the swirlers 84 of the deflector 8 into the combustion chamber 9, while about 80% of the compressed air, which enter into the combustion chamber 9, flow through the dilution holes 71 of the inner liner 70 and the dilution holes 73 of the outer liner 72 into the combustion chamber 9.
Therefore, the combustion system 75 in accordance with the present subject matter is provided to comprise: a cowl 5; a deflector 8 configurated to include a ring body 81, a plurality of swirlers 84 integrated on the ring body 81 and a plurality of arms 83 integrally extending outward from the ring body 81; an annular inner liner 70 attached with the cowl 5; and an annular outer liner 72 attached with the cowl 5. The deflector 8 is positioned between the inner liner 70 and the outer liner 72; the deflector 8, the inner liner 70 and the outer liner 72 define a combustion chamber 9 thereamong. The deflector 8 is attached to the cowl 5 via the plurality of slim and weak arms 83, but the weak arms 83 are rigid enough to work together to fix the deflector 8 with the cowl 5 while allowing for thermal expansion flexibility therebetween at the same time.
The swirlers 84 and the plurality of arms 3 are integrated with the ring body 81 on a same side (surface 87) of the ring body 81. Each of the plurality of arms 83 is L-shaped, and has an arm extension 830 extending from the ring body 81 and a mounting face 832 angled from the arm extension 830. The mounting face 832 defines an aperture 834 for a fastener (e.g., bolt) 50 therethrough to fix the arm 83 with the cowl 5. The deflector 8 is positioned between an upstream end of the inner liner 70 and an upstream end of the outer liner 72. Edges of the ring body 81 of the deflector 8 abut opposite ends of the cowl 5 respectively, as well as inner surface of the upstream end of the inner liner 70 and inner surface of the upstream end of the outer liner 72.
The cowl 5 is annular and has a dome-like cross section, and the cowl 5 is attached to and between the upstream end of the inner line 70 and the upstream end of the outer liner 72. The cowl 5 is fixed to the case 20 of the engine 2 through one or more mounting arm 51. The mounting arm 51 extends forward in an upstream direction for enabling the combustion system 75 to be assembled within the case 20 in a forward mounting way.
A fuel nozzle 6 enters through the cowl 5 and an injection end 62 of the fuel nozzle 6 aligns with a corresponding swirler 84 of the deflector 8 such that corresponding fuel flow into the swirler 84 and an annular chamber between the cowl 5 and the deflector 8 before into the combustion chamber 9. The combustion system 75 further comprises a ferrule 62 for attaining the injection end 62 of the fuel nozzle 6 with the corresponding swirler 84 of the deflector 8.
In sum, the present subject matter provides a combustion system employing a one-piece deflector (dome) with integrally formed swirlers that covers the entire annulus of an annular combustor. The function is to protect related structural components from high combustion gas temperatures and hold the swirlers in place during assembly and operation. The deflector is attached to the cowl via a plurality of relatively weak arms so that it is free to expand as thermal loads driven into the device. The deflector typically has minimal mounting features and is printed as one piece with the swirlers. Additionally, the deflector may have holes printed into the surface that faces the combustor flame.
The assembly/fixing mechanism between the deflector and the cowl of the present subject matter can save an additional dome (compared with the prior arts as above), which is a design simpler, lighter and cost-saving. And more importantly, the weakness of the arms of the deflector can allow or accommodate for thermal expansion while the arms keep the combination of the whole structure stiff enough to withstand vibrational stresses.
Another advantageous technical effect of the present subject matter is that the ring body, the swirlers and the (weak) arms are integrated into the deflector as one single piece, which is simpler, lighter and cost-saving compared with the prior arts with separate ring, swirler or deflectors.
Furthermore, the present subject matter gives a forward mounting structure of the combustion system (combustor) with forwardly extending mounting arms fixed to the engine's case via bolts, which makes the combustor/combustion system having a stronger capability against various vibrations.
This written description uses examples to disclose the present subject matter, including the best mode, and also to enable any person skilled in the art to practice the present subject matter, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the present subject matter is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
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