This application claims priority under 35 U.S.C. §119 to Swiss Patent Application No. 01388/10 filed in Switzerland on Aug. 27, 2010, the entire content of which is hereby incorporated by reference in its entirety.
The present disclosure relates to burner technology, such as a method for operating a burner arrangement and a burner arrangement for implementing the method.
Gas turbines with sequential combustion have been known in the prior art, in which the combustion gases from a first combustor, after performing work in a first turbine, are fed to a second combustor, where, with the aid of the combustion air which is contained in the combustion gases, a second combustion takes place, and the reheated gases are fed to a second turbine.
For this second combustion, SEV burners such as those described for example in “Field experience with the sequential combustion system of the GT24/GT26 gas turbine family”, ABB Review 5, 1998, p. 12-20, or in EP 2 169 314 A2 can be used.
In the case of conventional burners of gas turbines as disclosed in, U.S. Pat. No. 7,493,767 B2; an impingement cooling of transition pieces, to vary and influence the distribution of cooling air over the impingement cooling plate using holes in the plate equipped with “flow capturing elements” or “scoops” to provide locally higher mass flows of cooling air. Since in this case, owing to the lack of effusion cooling, the cooling air does not enter the mixing chamber directly through the burner wall but is guided along the burner wall on the outside, no consideration has to be taken for the interaction of the flow in the mixing chamber with cooling air which flows in through the burner wall.
In the case of an SEV burner, however, there is a close relationship between the distribution of the inflowing diffusion cooling air and the flow conditions in the mixing chamber or in the subsequent combustion chamber.
An exemplary method for operating a barrier arrangement is disclosed. The method comprising flowing a hot combustion gas, including combustion air, parallel to a burner wall through a mixing chamber, which is delimited by this burner wall, to a combustion chamber; mixing the hot combustion gas with an injected fuel in a mixing chamber; flowing cooling air from an outside of the burner wall through effusion holes in the burner wall into an interior of the mixing chamber, wherein the cooling air, on the outside of the burner wall, is deflected in its flow direction by means of deflection elements.
An exemplary burner arrangement is disclosed. The barrier arrangement comprising a mixing chamber which extends in a flow direction, wherein the mixing chamber is delimited on an outside surface by a burner wall, upstream has an inlet for a hot combustion gas which contains combustion air, and to which a combustion chamber is connected downstream, wherein the mixing chamber includes a fuel lance for injecting fuel, the fuel lance projecting into the mixing chamber, and wherein the burner wall is provided with effusion holes through which cooling air, which is introduced on the outside of the burner wall, can flow into the mixing chamber; and a plurality of deflection elements arranged on the outside of the burner wall to deflect the introduced cooling air towards said burner wall.
The disclosure shall subsequently be explained in more detail based on exemplary embodiments in conjunction with the drawing. In the drawing
Exemplary embodiments of the disclosure are directed to improving the method for operating a burner arrangement so that higher combustion temperatures can be achieved or highly reactive fuels can be used, and also to a burner arrangement for implementing the method.
In the exemplary embodiments cooling air is deflected in a directed manner on the outside of the burner wall in its flow direction by means of deflection elements which are in a distributed arrangement. As a result, the effusion cooling can be virtually “tailored” in order to intensify its effect in specified regions of the burner. The use of deflection elements enables a greatly improved adjustment of the direction of the injected effusion cooling air. As a result, the flow conditions inside the mixing chamber are optimized, which, when considering the stability of combustion of reactive fuels, benefits operational reliability.
The deflection elements allow a more intensely concentrated effusion cooling of the burner in their region. The deflection elements can be attached directly on the outer surface of the burner wall. They can have the form of a halved spherical half-shell and thereby resemble an orchestra shell. The height and width of the semicircle-like opening of the deflection elements can be varied as a function of the diameter and spacing of the effusion holes which are covered by it. The number and the positioning of the deflection elements depend upon the design of the burner. The orientation of the deflection elements (e.g., the alignment of their openings) can be selected so that the maximum cooling air flow is deflected into the effusion holes. The deflection elements can be produced and fastened either individually or produced together in the form of a correspondingly stamped and/or embossed plate. The deflection elements can be welded or cast on the burner wall. The number and diameter of the effusion holes can also be adapted to the positions of the deflection elements.
In an exemplary embodiment the cooling air on the outside of the burner wall has a velocity component which is parallel to the burner wall, and in that the cooling air is deflected towards the burner wall.
In another exemplary embodiment cooling air is deflected by means of one deflection element in each case into one of the effusion holes.
In yet another exemplary embodiment the cooling air is deflected by means of one deflection element in each case into a plurality of effusion holes.
In an exemplary embodiment the effusion holes are inclined by their axes to the burner wall, and in that the cooling air is deflected by means of the deflection elements such that upon entry into the effusion holes it flows essentially parallel to the axes of the effusion holes.
In another exemplary embodiment of a method of the present disclosure the effusion holes are inclined by their axes to the burner wall, and in that the cooling air is deflected by means of the deflection elements such that upon entry into the effusion holes the cooling air flows essentially perpendicularly to the burner wall.
In yet another exemplary embodiment of the method of the present disclosure a perforated plate with holes is arranged on the outside of the burner wall and at a distance from the burner wall, such that cooling air is introduced on the side of the perforated plate which faces away from the burner wall and by means of the deflection elements is deflected into the holes of the perforated plate and flows towards the burner wall.
In an exemplary embodiment of the method of the present disclosure spoon-like shells are used as deflection elements, which shield the associated effusion holes from one side and are open in the direction of the inflowing cooling air.
In another exemplary embodiment a burner arrangement includes a mixing chamber which extends in a flow direction. The mixing chamber is delimited on the outside by a burner wall and upstream has an inlet for a hot combustion gas which contains combustion air, and to which a combustion chamber is connected downstream, wherein a fuel lance for injecting a fuel projects into the mixing chamber and the burner wall is provided with effusion holes through which cooling air, which is introduced on the outside of the burner wall, can flow into the mixing chamber, wherein deflection elements are arranged on the outside of the burner wall and deflect the introduced cooling air towards said burner wall.
In another exemplary embodiment of the burner arrangement of the present disclosure the deflection elements are designed such that cooling air is deflected towards the burner wall.
In an exemplary embodiment of the burner arrangement of the present disclosure one deflection element can be associated in each case with one of the effusion holes.
In another exemplary embodiment of the burner arrangement of the present disclosure one deflection element is associated in each case with a plurality of effusion holes.
In yet another exemplary embodiment of the burner arrangement of the present disclosure the effusion holes are inclined by their axes to the burner wall, and the deflection elements are designed such that the cooling air, upon entry into the effusion holes, flows essentially parallel to the axes of the effusion holes.
In an exemplary embodiment of the burner arrangement of the present disclosure the effusion holes are inclined by their axes to the burner wall, and the deflection elements are designed such that the cooling air, upon entry into the effusion holes, flows essentially perpendicularly to the burner wall.
In another exemplary embodiment of the burner arrangement of the present disclosure a perforated plate with holes is arranged on the outside of the burner wall and at a distance from the burner wall, and the deflection elements are arranged on the side of the perforated plate which faces away from the burner wall such that cooling air is deflected by means of the deflection elements into the holes of the perforated plate and flows towards the burner wall.
In yet another exemplary embodiment of the burner arrangement of the present disclosure the deflection elements are designed as spoon-like shells which shield the associated effusion holes from one side and are open in the direction of the inflowing cooling air.
In yet another exemplary embodiment of the burner arrangement of the present disclosure the deflection elements are attached on the outer surface of the burner wall or of the perforated plate.
Exemplary embodiments of the present disclosure provide for “tailoring” or optimizing the effusion cooling of a known burner as shown in
Furthermore, the deflection elements 21, in regions in which the flow velocity of the cooling air on the outer side of the burner wall 15 and the static pressure, on account of the high flow velocity, are reduced, dam up the flow, and convert at least some of the dynamic pressure into static pressure. The deflection elements 21 therefore allow the feed pressure for the effusion cooling to be increased and to be adjusted.
The size of the deflection elements 21 in relation to the diameters of the effusion holes 16 can be varied.
As a result of selecting the size of the deflection elements 21 in relation to the diameters of the effusion holes 16, the function can be established as a deflecting element or as a damming element for recuperation of the dynamic pressure.
In principle, the effusion holes 16 can be oriented with their hole axes perpendicular to the plane of the burner wall 10. In most cases, however, as shown in
The described effusion cooling is not limited to the mixing chamber 12 but can also extend to the liner of the combustion chamber 13. In addition to the actual cooling, the effusion cooling in the liner can avoid self-ignition of the air-fuel mixture. In addition to the cooling, the effusion cooling in the mixing chamber 12 or premixer can avoid stagnation of the combustible gases on the burner wall 15 by forming a boundary layer.
The deflection elements 21, 22 can fulfill the following tasks:
The function of forming a vortex of the cooling air by means of the deflection elements 21, 22 can be augmented by the deflection elements 21, 22 being attached in a specific overall arrangement (e.g., staggering) in order to fluidically mutually influence the function. As a result, the convective cooling on the outside of the burner wall 15 is increased. Rows of deflection elements 21, 22 can therefore be arranged at right angles to the flow direction of the cooling air 20, for example, wherein the deflection elements 21, 22 of two consecutive rows can be arranged in each case in an offset manner to each other.
The deflection elements 21, 22 can locally intensify the effusion cooling of the burner. If, according to
Many regions of the effusion cooling are limited by the velocity of the cooling air being high and only in the presence of a low static pressure prevailing. Many regions of the effusion cooling must be intensified because the thermal load on the hot gas side (e.g., on account of a high heat transfer coefficient or a high flame temperature) is particularly high. The deflection elements have a combination of damming up and deflection, to capture cooling air which would otherwise flow past the effusion holes. In this manner, the cooling can be locally intensified without the risk of crack development being increased as a result of an increase of the number of effusion holes or increase of the diameter of the effusion holes.
The deflection elements altogether have the following characteristics:
Thus, it will be appreciated by those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The presently disclosed embodiments are therefore considered in all respects to be illustrative and not restricted. The scope of the invention is indicated by the appended claims rather than the foregoing description and all changes that come within the meaning and range and equivalence thereof are intended to be embraced therein.
Number | Date | Country | Kind |
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01388/10 | Aug 2010 | CH | national |