Gas turbine engine combustion chamber comprising CMC deflectors

A gas turbine engine combustion chamber including at least one deflector mounted on the chamber end wall and including an opening for a carburetted air supply device. The deflector includes an opening, corresponding to the chamber end wall opening, with an annular cylindrical part for attachment to the wall, the cylindrical part including a mechanical attachment mechanism collaborating with a complementary attachment mechanism on a metal sleeve secured to the wall and a cylindrical centering cup fixed by one end to the sleeve and housed inside the cylindrical part of the deflector.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the field of gas turbine engines and, in particular, to that of the combustion chambers of such engines.

2. Description of the Related Art

The combustion chamber of a gas turbine engine receives compressed air from an upstream high-pressure compressor and provides a gas that is heated by combustion in a combustion zone supplied with fuel. The chamber thus comprises a chamber end wall situated upstream and to which the various fuel injection systems are attached.FIG. 1shows a chamber of the prior art. The annular chamber1is housed inside an engine casing2downstream of the compressed air diffuser3. It comprises an interior wall4and an exterior wall5between them delimiting a combustion zone. In its upstream part, the chamber comprises a transverse chamber end wall6on which openings are formed, each opening being equipped with a carbureted-air supply system7. Such a system is supplied with fuel from a liquid-fuel injector and comprises concentric cascades of vanes to create streams of air that swirl, encouraging them to mix with the layer of atomized fuel.

Some of the air from the diffuser is diverted away from the fuel intake zone by the fairing8and flows along and around the outside of the exterior wall and along and around the outside of the interior wall.

The proportion which passes along inside the carburetion zone, crosses the chamber end wall6and the mixture is ignited by sparkplugs arranged on the exterior annular wall. The primary combustion zone is therefore situated immediately downstream of the chamber end wall. Deflectors9made of a metallic material line the inside of the chamber end wall and their function is to protect it from the intense radiation produced in the primary combustion zone. Air is introduced through orifices made in the chamber end wall behind the deflectors in order to cool them. This air flows along the rear face of the deflectors and is then guided so that it forms a film along the longitudinal exterior walls of the chamber.

Because the chamber end wall deflectors are not mechanically stressed, have no structural role and their only function is to afford thermal protection, and with a view to optimizing the air flows, it would be desirable to be able to reduce the stream along the chamber end wall and assign part of it to another function, notably that of cooling the interior or exterior walls.

Also, increasingly improved engine performance leads to increasingly high chamber temperatures being sustained. In order to conform to chamber life specifications, it would be necessary to intensify the cooling of the chamber walls and of the chamber end wall deflector. The solution involving increasing the cooling flow rate would be detrimental to chamber efficiency.

In order to solve this problem, the proposal is for the known metal deflector to be replaced with a CMC (ceramic matrix composite) deflector. The high-temperature capability of this material is far better than that of metal. This solution will make it possible to control the flow of deflector cooling air and, for the same chamber operating temperature, reduce it, so that a proportion of it can be reassigned to some other function or, alternatively, to allow higher operating temperatures to be tolerated for the same cooling air flow.

CMCs, ceramic matrix components, are known per se. They are formed of a carbon fiber or refractory reinforcement and of a ceramic matrix. The manufacture of a CMC involves producing a fibrous preform intended to constitute the reinforcement of the structure, and densifying the preform with the ceramic material of the matrix. CMCs have the advantage of maintaining their mechanical properties up to high temperatures in an oxidizing environment.

Fitting a component of this type in a metal structure does, however, present difficulties notable because of the substantial difference in their expansion coefficients. A CMC has a thermal expansion rate that is one quarter of that of the metal used for the chamber. Moreover, this material can be neither welded nor brazed.

BRIEF SUMMARY OF THE INVENTION

The applicant company has set itself the task of developing a way of fitting deflectors made of materials of the CMC type, on the end wall of a combustion chamber.

According to the invention, this objective is achieved using a combustion chamber that has the features listed in the main claim.

The sleeve is preferably fixed to the wall by brazing and the mechanical fastening means is of the jaw coupling type. Radial teeth on one of the two components, the cylindrical part of the deflector or the metal sleeve, engage with a groove in the other component.

The deflector is thus held in position without brazing. This solution makes it possible, at high temperatures, to hold the deflector in position against the sleeve. Specifically, as it expands, the cup will engage with the cylindrical part of the deflector.

Advantageously, the cup is fitted with clearance inside the cylindrical part of the deflector when the combustion chamber is cold, the clearance becoming smaller if not being eliminated at the combustion chamber operating temperatures. This clearance allows the components to be assembled and takes their difference in expansion into consideration.

More specifically, the cup comprises a radial flange by which it is fixed by welding to the metal sleeve.

The carbureted air supply system comprises a bowl fixed by a flange to the metal sleeve.

According to an alternative form of embodiment, the mechanical means of attachment of the deflector collaborates with a deflector support attached to the sleeve. This support forms an intermediate component which allows the zones where the metal components are brazed together to be separated from one another without the risk of damaging the CMC material of which the deflector is made.

As in the previous embodiment, the cylindrical part of the deflector is secured to a cup-forming cylindrical element housed with clearance, when cold, inside the annular flange of the deflector, said cup-forming element guiding the deflector when the temperature has increased.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 2shows a chamber end according to one embodiment of the invention. The end wall11of the chamber10is protected from the radiation of the combustion zone by a deflector12made of CMC. The shape of the deflector is approximately the same as that of the deflector9of the prior art with a generally flat part12apositioned parallel to the wall11and two parts12bwhich curve toward the exterior and interior walls. The deflector12is open in its central part with a cylindrical part12cof the same axis as the carbureted air supply system13.

Fixed in the opening in the chamber end wall11is a metal sleeve14. A brazed joint14aholds the sleeve14against the interior edge of the opening in wall11. The sleeve comprises a cylindrical part14band a radial part14c, the latter creating a space with a retaining cup15which is welded to its periphery. Transverse teeth14ddirected toward the axis of the opening in the wall11are created on the inside of the cylindrical part14bof the sleeve14. A centering cup16comprises a cylindrical part16aand a radial and transverse flange16b. The cup16is positioned inside the cylindrical part14bof the sleeve and fixed by a peripheral welded seam16cto the sleeve14. The cylindrical part16aof the cup is inside the cylindrical part12c.

The deflector12comprises a transverse groove12c1on the exterior face of the cylindrical part12c, forming a housing for the teeth14dof the sleeve. The groove is perforated to allow the teeth14dto pass axially at the time of fitting and then to allow locking by rotating the sleeve with respect to the cylindrical part12cof the deflector12. This method of mechanical attachment of the deflector to the sleeve is of the jaw coupling type. Other means of mechanical attachment are conceivable. As may be seen fromFIG. 2a, the cylindrical part16aof the cup is inside the cylindrical part12c, with a radial clearance at the time of fitting.

The air carburetion and injection device is depicted overall using the reference13. Given that the subject matter of the invention does not concern it, its details are not given. The divergent bowl13aof the device externally comprises a transverse flange13bhoused in the space formed between the radial face14cof the sleeve14and the retaining cup15.

This is how the assembly is constructed.

The sleeve14is brought,FIG. 3, against the chamber end wall11on the outside of the chamber. It is centered on the interior edge of the corresponding opening in the wall11.

The deflector12is positioned,FIG. 4, in the sleeve14from inside the chamber. The teeth14dare introduced axially through the perforations into the groove12c1. The sleeve14is turned to lock the teeth axially in relation to the annular flange12c. The sleeve14is therefore coupled to the deflector12by the collaboration between the teeth14dand the groove12c1.

The sleeve14is fixed,FIG. 5, by brazing it to the chamber end wall using the brazed seam14a,FIG. 2, and a rotation-preventing pin18is placed between the diameter of the sleeve and that of the deflector. The centering cup16is slid into the cylindrical part12cof the deflector, and the cup is attached by a spot or seam of welding16cbetween this cup and the sleeve14.

The fuel injection device13is then fitted and immobilized using the retaining cup15. This cup is welded to the sleeve.

This way of fitting the deflector allows the latter to be immobilized in the chamber end wall using a mechanical means of fastening. The welds are only between metal parts. The differential expansion of the deflectors with respect to the metallic environment are accounted for by the centering cup which, by expanding radially, immobilizes the deflector in position.

The clearances between the sleeve and the deflector on the one hand and between the deflector and the centering cup on the other need to be optimized according to the operating temperatures and the diameter of the components.

An alternative form of embodiment is now described with reference toFIG. 7.

Fitting is roughly the same as before; the sleeve and the cup have simply been modified.

The deflector12and the chamber end wall11remain unchanged. An intermediate sleeve24is fitted into the opening in wall11from the outside of the chamber; it is brazed at24aalong the edge of the opening. The deflector is introduced into the intermediate sleeve24from inside the chamber. An annular deflector support sleeve26comprises transverse teeth26dengaging with the exterior groove12c1of the annular flange of the deflector. The support sleeve26is slid axially from outside the chamber introducing the teeth26dinto the groove12c1via the perforations (not visible) of the groove. A rotation about the axis of the opening allows the support sleeve24to be coupled to the deflector. In order to maintain the mechanical connection between the support sleeve and the deflector, all that is required is for the support sleeve26to be welded, at26b, to the intermediate sleeve24at the periphery distant from the CMC deflector.

The support sleeve26comprises a cylindrical part26athat forms a radially interior cylindrical centering cup which fits inside the flange12c. When fitted cold, a clearance is left between the cylindrical part26aof the support sleeve and the flange12cof the deflector. Centering is achieved by the mechanical jaw-coupling means of attachment.

At the combustion chamber operating temperature, the deflector support sleeve, notably, expands more than the CMC deflector. The cylindrical part comes to press against the internal face of the flange12cfirmly and centers the deflector.

The fuel injection device13is fitted, as before, from the outside of the chamber, a transverse flange13bbeing immobilized between the rear face of the deflector support26and a retaining cup15brazed to the support.