Power plants – Combustion products used as motive fluid – Combustion products generator
Reexamination Certificate
1997-12-15
2001-01-23
Kim, Ted (Department: 3746)
Power plants
Combustion products used as motive fluid
Combustion products generator
C060S748000, C239S403000
Reexamination Certificate
active
06176087
ABSTRACT:
TECHNICAL FIELD
This invention relates to premixing fuel injectors for gas turbine engines, and to methods of premixing fuel and air prior to burning the fuel in a combustor. In particular the invention is a fuel injector and a method of mixing that promote clean combustion while safeguarding fuel injector and combustor durability.
BACKGROUND OF THE INVENTION
Combustion of fossil fuels produces a number of undesirable pollutants including nitrous oxides (NOx). Environmental degradation attributable to NOx has become a matter of increasing concern, and therefore there is intense interest in suppressing NOx formation in fuel burning devices.
One of the principal strategies for inhibiting NOx formation is to burn a fuel-air mixture that is both stoichiometrically lean and thoroughly blended. Lean stoichiometry and thorough blending keep the combustion flame temperature uniformly low—a prerequisite for inhibiting NOx formation. One type of fuel injector that produces a lean, thoroughly blended fuel-air mixture is a tangential entry injector. Examples of tangential entry fuel injectors for gas turbine engines are provided in U.S. Pat. Nos. 5,307,634, 5,402,633, 5,461,865 and 5,479,773, all of which are assigned to the assignee of the present application. These fuel injectors have a mixing chamber radially outwardly bounded by a pair of cylindrical-arc, offset scrolls. Adjacent ends of the scrolls define air admission slots for admitting air tangentially into the mixing chamber. A linear array of equidistantly spaced fuel injection passages extends along the length of each slot. A fuel injector centerbody extends aftwardly from the forward end of the injector to define the radially inner boundary of the mixing chamber. The centerbody may include provisions for introducing additional fuel, or a fuel-air mixture, into the mixing chamber. During engine operation, combustion air enters the mixing chamber tangentially through the air admission slots while equal quantities of fuel are injected into the air stream through each of the equidistantly spaced fuel injection passages. The fuel and air swirl around the centerbody and become intimately intermixed in the mixing chamber. The fuel-air mixture flows longitudinally aftwardly and is discharged into an engine combustor where the mixture is ignited and burned. The intimate premixing of the fuel and air in the mixing chamber inhibits NOx formation by ensuring a uniformly low combustion flame temperature.
Despite the many merits of the tangential entry injectors referred to above, they are not without shortcomings that may render them unsatisfactory for some applications. One shortcoming is that the fuel mixture in the mixing chamber can encourage the combustion flame to migrate into the mixing chamber where the flame can quickly damage the scrolls and centerbody. A second shortcoming is related to the flame's tendency to be spatially unstable even if it remains outside the mixing chamber. The spatial instability is manifested by fluctuations in the position of the flame and accompanying, low frequency acoustic (i.e. pressure) oscillations. Although the acoustic oscillations may not be auditorially objectionable, their repetitive character can stress the combustion chamber and reduce its useful life. The injectors referred to above are ineffective at stabilizing the combustion flame and therefore may contribute to poor combustor durability.
The problem of flame ingestion into the mixing chamber can be mitigated by a uniquely contoured centerbody as described in copending, commonly owned patent applications Ser. No. 08/771,408 and Ser. No. 08/771,409, both filed on Dec. 20, 1996. The disclosed centerbody is aerodynamically contoured so that the fuel-air mixture flows longitudinally at a velocity high enough to resist flame ingestion and promote disgorgement of any flame that is ingested. Unfortunately, these desirable characteristics of the contoured centerbody can be impaired by the low velocity of fluid in the boundary layer adhering to the centerbody. This is particularly true if the slowly moving boundary layer fluid includes fuel as well as air. Moreover it has been determined that the contoured centerbody affects the fluid flow field within the mixing chamber in a way that disturbs the uniformity of the fuel-air mixture discharged into the combustor. As a result, the potentially damaging spatial instability of the combustion flame is exacerbated and the injector's full potential for inhibiting NOx formation may be compromised.
What is needed is a premixing fuel injector that inhibits NOx formation, spatially stabilizes the combustion flame outside the injector, effectively resists flame ingestion, and reliably disgorges any flame that migrates into the interior of the injector.
SUMMARY OF THE INVENTION
It is, therefore, an object of the invention to provide a tangential entry premixing fuel injector, and a corresponding method of fuel-air mixing, that inhibits NOx formation, spatially stabilizes the combustion flame, resists flame ingestion and promotes reliable flame disgorgement.
It is a further object to provide an injector whose physical features operate in harmony so that advantages attributable to the features are not offset by accompanying disadvantages or compromised by any of the other features.
According to the invention a premixing fuel injector includes an array of fuel injection passages for injecting primary fuel nonuniformly along the length of a tangential air entry slot, and a flame disgorging, flame stabilizing centerbody that features a bluff tip aligned with the injector's discharge plane and that has discharge openings for discharging a combustible fluid into the combustor at the injector discharge plane. The combustible fluid may be a secondary fuel, preferably gaseous fuel, or may be a mixture of secondary fuel and secondary air.
In one embodiment of the fuel injector, the primary fuel passage array includes passages of at least two different classes, with each passage class being distinguished from the other passage classes by its capacity for injecting fuel. The passages are distributed along the length of the entry slot so that the distribution of passage classes is substantially periodic. In one detailed embodiment the passage classes are selected, and the passages are distributed so that primary fuel does not penetrate into the slowly moving boundary layer adhering to the centerbody.
The bluff centerbody tip, aligned with the discharge plane and having openings for discharging secondary fuel or fuel and air, anchors the combustion flame at the fuel injector discharge plane so that the combustion flame remains outside the injector where it is unlikely to damage the centerbody or scrolls. The anchoring capability of the bluff centerbody also spatially stabilizes the flame to suppress acoustic oscillations. The longitudinally nonuniform injection of primary fuel compensates for the tendency of the uniquely contoured, flame disgorging centerbody to disturb the uniformity of the fuel-air mixture discharged into the combustor. Accordingly, the selection and distribution of passage classes augments the acoustic suppression afforded by the bluff centerbody tip, helps to suppress NOx formation and, by preventing fuel penetration into the centerbody boundary layer, enhances the fuel injector's flame ingestion resistance and disgorgement capability.
One advantage attributable to the disclosed fuel injector and method of fuel-air mixing is improved fuel injector durability due to improved flame ingestion resistance and flame disgorgement capability. Another advantage is improved combustor durability due to suppressed acoustic oscillations.
The foregoing features and advantages and the operation of the invention will become more apparent in light of the following description of the best mode for carrying out the invention and the accompanying drawings.
REFERENCES:
patent: 4426841 (1984-01-01), Cornelius et al.
patent: 4587809 (1986-05-01), Ohmori et al.
patent: 4781030 (1988-11-01), Hellat et al.
p
Morford Stephen A.
Snyder Timothy S.
Sowa William A.
Van Dyke Kevin J.
Baran Kenneth C.
Kim Ted
United Technologies Corporation
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