FR2935465A1 - Combustion chamber for gas turbine engine, has casing that is in support on upstream face of chamber bottom wall, where casing carries deflector support constituting stop arranged in manner to maintain deflector in contact with wall - Google Patents

Abstract

The chamber (1) has a chamber bottom wall (6) provided with an opening for a carburated air supply device (7) mounted on the wall. The supply device is formed of deflectors (9) made of Ceramic Matrix Composite material , where each deflector is in support on a downstream face of the wall and comprises another opening corresponding to the former opening of the wall. A metallic casing (8) is in support on an upstream face of the wall. The casing carries a deflector support (10) constituting a stop arranged in a manner to maintain contact of the deflector with the wall.

Description

1 Fixing a CMC baffle on a chamber bottom by clamping with a metal support

The present invention relates to the field of gas turbine engines and in particular that of the combustion chambers of such engines. The combustion chamber of a gas turbine engine receives compressed air from the upstream high pressure compressor and provides a combustion-heated gas in a fuel-fired combustion zone. The chamber thus comprises a bottom wall chamber, located upstream, on which are fixed the different fuel injection systems. Figure 1 shows a chamber of the prior art. The annular chamber 1 is housed inside a housing 2 of the engine downstream of the diffuser 3 of compressed air. It comprises an inner wall 4 and an outer wall 5 delimiting between them a combustion zone. In its upstream part the chamber comprises a transverse wall 6 of bottom chamber on which are provided openings each equipped with a system 7 for supplying carbureted air. Such a system is supplied with fuel from a liquid fuel injector and includes concentric annular grids to create swirling air streams promoting their mixing with the pulverized fuel web. Part of the air from the diffuser is diverted from the fuel inlet zone by a shroud and flows along and out of the outer wall as well as along and out of the inner wall. The part which passes inside the carburizing zone, crosses the wall 6 of chamber bottom, and the mixture is ignited by candles arranged on the outer annular wall. The primary combustion zone is therefore immediately downstream of the wall of the chamber bottom. A shield, in the form of sectored deflectors 9, lines the inside of the wall of the chamber bottom and serves to protect it from the intense radiation produced in the primary combustion zone. In the prior art, air is introduced through orifices made in the wall of the chamber bottom behind the deflectors, which are made of metallic material, to ensure their cooling. This air flows along the rear face of the baffles and is then guided to form a film along the longitudinal outer walls of the chamber.

Insofar as the chamber bottom deflectors are not mechanically stressed, have no structural role and have a single thermal protection function, and in the search for optimization of the air flows, it would be desirable to be able to reduce the flow along the wall of the chamber bottom and affect a fraction to another function, including cooling of the inner or outer walls. In addition, engine performance is constantly improving and leads to higher and higher chamber temperatures. In order to comply with the specifications of the service life of the chamber, it would be necessary to intensify the cooling of the walls and the bottom chamber deflector. The solution of increasing the cooling flow rate would be, on the one hand, a disadvantage for the efficiency of the chamber and, on the other hand, would disturb the temperature profile at the inlet of the high pressure turbine.

To solve this problem it has been proposed to replace the known metal baffle with a deflector CMC (ceramic matrix composite). The high temperature behavior of this material is much better than that of the metal. This solution makes it possible to control the flow rate of the cooling air of the baffles and, at the same operating temperature of the chamber, to reduce it in order to affect part of it to another function or to accept higher operating temperatures for same cooling air flow. CMCs, ceramic matrix components, are known per se. They are formed of a ceramic fiber reinforcement and a ceramic matrix. The manufacture of a CMC comprises the production of a fiber preform intended to constitute the reinforcement of the structure, and the densification of the preform by the ceramic material of the matrix. CMCs have the advantage of maintaining their mechanical properties up to high temperatures in an oxidizing medium.

However, the mounting of a piece of this type in a metal structure presents difficulties because of the large difference in their coefficient of expansion with the surrounding parts. A CMC has a thermal expansion rate four times lower than the metal used for the chamber. In addition, this material can not be welded or soldered. The object of the present invention is to propose a simple and economical method of mounting deflectors made of CMC material on the bottom wall of a combustion chamber.

For this purpose, the subject of the invention is a gas turbine engine combustion chamber comprising at least one chamber bottom wall provided with openings for fuel air supply devices and sectorized protection mounted on said chamber bottom wall and formed by deflectors, each deflector bearing on the downstream face of said wall and comprising an opening corresponding to an opening of the chamber bottom, an annular cylindrical portion and a substantially planar radial portion, said chamber comprising in addition, a metal sleeve bearing on the upstream face of said bottom wall of a chamber characterized in that said sleeve carries a metal deflector support constituting downstream of said wall a stop in axial translation for said deflector, so as to maintaining the deflector substantially in contact with said chamber bottom wall. The baffle is thus mechanically held by a simple clamping between the chamber bottom and the deflector support, without the need for welding or soldering. These parts which have expansion coefficients different from that of the deflector CMC, can also expand without creating significant constraints in the baffle.

According to preferred embodiments: said deflector support is in the form of a part consisting of a cylindrical part whose external diameter X is smaller than the inside diameter of the opening of the deflector and of a radial collar whose diameter outside is greater than said inside diameter of the deflector opening.

4 - the sheath has a cylindrical portion whose inner diameter is substantially equal to the outer diameter X of the cylindrical portion of the deflector. - The cylindrical portion of the sleeve support is inserted into the cylindrical portion of the sleeve to be fixed by welding or brazing. - The deflector support is mounted without clearance against the deflector when the combustion chamber is cold. - The outer diameter of the cylindrical portion of the deflector support is such that it has a cold game with the deflector, and that game eliminates the operating temperatures of the combustion chamber. - The sleeve has holes regularly distributed on the circumference of its cylindrical portion. the deflector support is a circular part on which is formed a succession of ribs and grooves aligned along the axis of the opening of the chamber bottom, said grooves communicating with the bores of the sleeve so as to form a circulation channel; of air for cooling the metal of the baffle support. - The carburized air supply system comprises a divergent bowl which is extended by a transverse flange inserted between the radial portion of the sleeve and a ring fixed integrally to said radial portion of the sleeve. - The sleeve and the deflector support respectively have on their circumference a notch adapted to receive an alignment finger so as to angularly position the two parts relative to each other during assembly. - The alignment finger is held in place in its housing by the transverse flange of the supply system. the alignment finger is held in place in its housing by welding, the deflector is made of a CMC material. The invention will be better understood, and other objects, details, features and advantages thereof will become more clearly apparent from the following detailed explanatory description of an embodiment of the invention given by way of example. examples purely illustrative and non-limiting, with reference to the accompanying schematic drawings. In these drawings: FIG. 1 is a view in axial section of a combustion chamber of a gas turbine engine according to the prior art; FIG. 2 is an axial sectional view of a detail of the combustion chamber of a gas turbine engine, showing a chamber bottom mounted according to one embodiment of the invention; - Figure 3 is a perspective view of the various elements for mounting a chamber bottom according to one embodiment of the invention; - Figure 4 is an axial sectional view of a detail of a chamber bottom mounted according to one embodiment of the invention, showing the locking device in rotation of the various elements constituting the chamber bottom; and FIGS. 5 and 6 are views in axial section and in perspective of a detail of a chamber bottom mounted according to one embodiment of the invention, showing the circulation of the cooling air of the deflector support. . Referring to Figure 2, there is a section of a wall 6 of a chamber bottom provided with an opening for a system 7 for supplying carbureted air. Against this wall is placed on the side of the interior of the combustion chamber a deflector 9 for protecting the bottom of the chamber from the high temperatures generated by the combustion. This deflector is advantageously made of ceramic matrix composite (CMC) which can withstand these high temperatures without the need for air cooling. It can, alternatively, be made of any material resistant to high temperatures and having a low coefficient of expansion, comparable to that of the CMC. It is held in place against the wall 6 of the chamber bottom by a deflector support 10, made of metallic material. The deflector support 10 has, in section, an L shape with a cylindrical portion 10c whose outer diameter X is smaller than that of the opening of the baffle to be slidable, and a radial portion 10r, flange-shaped , extending towards the outside of the chamber and whose outer diameter is greater than that of said opening.

The deflector 9 is thus clamped between the wall 6 of the chamber base against which it is in abutment, and the collar 1Or of the support of

6 baffle 10 which serves as abutment in axial translation downstream of the chamber bottom, without the need to rigidly attach to the wall 6 of the chamber bottom. This configuration makes it possible to use a non-weldable or solderable material, such as CMCs, to make the deflector.

On the other side of the wall 6 of the chamber bottom, ie upstream of the chamber, is placed a sleeve 8 also having a cylindrical portion 8c and a substantially radial portion 8r. The cylindrical portion 8c has an inside diameter which is also smaller than that of the opening and which is substantially equal to the outside diameter of the cylindrical portion 10c of the deflector 10. The deflector support 10 is inserted into the cylindrical portion of the sleeve 8 during assembly and is fixed there, for example by welding. The sheath assembly 8, deflector 9 and deflector support 10 thus constitutes a block which traps the wall 6, while leaving free passage for the fuel air supply system 7 in the opening of the chamber bottom. It is important to constantly maintain the deflector 9 substantially in contact with said wall 6 of the chamber bottom. Because of the differences in expansion between the metal parts and the deflector, made in CMC, expansion gaps must be provided so that the metal parts can expand and the deflector does not undergo excessive stress. First, during assembly, when cold, the deflector 9 is positioned against the wall 6 of the chamber bottom, without axial play and immobilized by the introduction of the deflector support 10 and the sheath 8 and then by the welding of one over the other. During the temperature rise, engine in operation, the cylindrical portions of the sleeve 8c and the deflector support 1Oc extend axially and show a game along the wall 6, which could allow the deflector to move. However, the outer diameter X of the cylindrical portion 10c of the deflector support is, cold, less than the inner diameter of the deflector. It is chosen such that, after expansion, this outer diameter of the deflector support becomes equal to or even slightly greater than that of the inner diameter of the deflector. In this way, it is obtained, hot, an immobilization of the deflector 9 by the clamping generated by the radial expansion of the cylindrical portion 10c of the deflector support.

7 The deflector is thus held cold by the collar 1Or and hot by the cylindrical portion 1 Oc of the deflector support. Still with reference to FIG. 2, there is shown a fuel air supply system 7 comprising among other things a block 7a intended to receive the fuel injector and to admit the air so that it mixes with the fuel. This block is extended by a diverging bowl 7b to ensure proper diffusion of the carbureted air in the combustion chamber 1. The bowl 7b is extended by a transverse flange 7c which extends to the upstream face of the radial portion 8r of the sheath 8, on which it is based. The supply system 7 is held in place by a ring 11 which is welded or brazed on the radial portion 8r of the sleeve, so as to trap the transverse flange 7c between it and said radial portion 8r and to fix the supply system 7 on the bottom wall of chamber 6.

As can be seen in Figures 2 to 6, the flange 10r covers a portion of the baffle and is therefore exposed to the temperature conditions of the combustion chamber. This element being, unlike the deflector, made of metal material requires to be cooled to support the conditions imposed on it. The invention therefore provides a cooling circuit which passes through the sleeve 8, as shown in Figures 5 and 6. For this the sleeve 8 is traversed by holes 13 regularly distributed on the circumference of its cylindrical portion 8c. Opposite the deflector support 10 is a circular piece on which is formed a succession of ribs 14 and grooves 15 aligned along the axis of the opening of the chamber bottom. These grooves are intended to define air flow channels for cooling the metal of the deflector support 10. The number and the spacing of the grooves 15 correspond to the holes 13 made in the sheath 8 and communicate with them to form the air circulation channels. To ensure proper alignment of the holes 13 and grooves 15 a device for aligning the two parts is provided. In the configuration illustrated in Figure 3 this device is constituted by an orientation finger 12 which is adapted to be inserted into notches 16 and 17 respectively in the sleeve 8 and the sleeve support 10. Similar notches are also performed in the deflector 9 and the chamber bottom 6 to allow the passage to the orientation finger 12. During assembly the operator takes care to align all these notches to be able to slide the orientation finger 12. This finger is held in place after the installation of the fuel gas supply system 7, by welding on the sheath 8. The cooling of the collar 1Or is performed, as seen in Figures 5 and 6, as follows : The air at the outlet of the compressed air diffuser 3 is deflected towards the sheath 8 and passes through the holes 13 to reach the grooves 15 of the deflector support 10. It circulates along these grooves and passes between the def reader 9 and the deflector support 10, thereby cooling said support. It is obvious that the air flow that is taken from the main circuit is much lower than that taken from the prior art to cool the baffle, the mass of material to be cooled is here very significantly lower. Those skilled in the art will be able to adjust the section of the groove to adjust the flow rate that circulates there to the value strictly necessary for the desired cooling. Referring to Figure 3, the mounting of a deflector according to one embodiment of the invention is carried out as follows: The sleeve 8 is first brazed to the chamber bottom 6 by aligning the notches made on both pieces. Then the deflector 9 is centered on the deflector support 10 by aligning the notches 17 and 18. This subassembly is then centered on the sleeve, placed against the chamber bottom 6 and oriented by the orientation finger 12. Welding beads are made between the sheath 8 and the deflector support 10 to maintain the subassembly on the chamber bottom 6. A carburized air supply system 7 is deposited in the opening of the bottom of the chamber. 8. A ring 11 is then placed against the sleeve 8 so as to trap the transverse flange 7c, and then welded to the radial portion 8r of the sleeve so as to maintain the supply system 7 in place. Although the invention has been described in connection with a particular embodiment, it is obvious that it is not limited thereto and that it comprises all the technical equivalents of the means described and their combinations if they are within the scope of the invention.

Claims (14)

REVENDICATIONS1. Gas turbine engine combustion chamber comprising at least one chamber bottom wall (6) provided with openings for carburized air supply devices (7) and sectorized protection mounted on said chamber bottom wall and formed by deflectors (9), each deflector (9) bearing on the downstream face of said wall (6) and comprising an opening corresponding to an opening of the chamber bottom, a cylindrical portion (9c) annular and a portion substantially planar radial (9r), said chamber further comprising a metal sheath (8) bearing on the upstream face of said chamber bottom wall (6) characterized in that said sheath carries a deflector support (10) metal constituting downstream of said wall (6) a stop in axial translation for said deflector, so as to maintain the deflector (9) substantially in contact with said wall (6) of the chamber bottom. 2. Combustion chamber according to the preceding claim wherein said baffle support (10) has the shape of a part consisting of a cylindrical portion (10c) whose outer diameter X is smaller than the inner diameter of the opening of the baffle and a radial flange (10r) whose outer diameter is greater than said inner diameter of the deflector opening. 3. Combustion chamber according to claim 2 wherein the sleeve (8) has a cylindrical portion (8c) whose inner diameter is substantially equal to the outer diameter X of the cylindrical portion (10c) of the baffle (10). 4. Combustion chamber according to claim 3 wherein the cylindrical portion (10c) of the sleeve support (10) is inserted into the cylindrical portion (8c) of the sleeve (8) to be fixed by welding or brazing. 5. Combustion chamber according to one of claims 1 to 4 wherein the baffle support (10) is mounted without clearance against the baffle (9) when the combustion chamber is cold. 6. Combustion chamber according to one of claims 2 to 4, wherein the outer diameter of the cylindrical portion (10c) of the deflector support (10) is such that it has a cold play with the deflector (9). ), and that this game is eliminated at the operating temperatures of the combustion chamber. 7. Combustion chamber according to one of claims 1 to 6 wherein the sleeve (8) has holes (13) regularly distributed on the circumference of its cylindrical portion (8c). 8. Combustion chamber according to claim 7 wherein the deflector support is a circular piece on which is formed a succession of ribs (14) and grooves (15) aligned along the axis of the opening of the chamber bottom, said grooves (15) communicating with the bores (13) so as to form an air flow channel for cooling the metal of the deflector support (10). 9. Combustion chamber according to one of claims 1 to 8 wherein the supply system (7) of carbureted air comprises a diverging bowl (7b) which is extended by a transverse flange (7c) inserted between the radial portion (7c) ( 8r) of the sheath (8) and a ring (11) fastened integrally to said radial portion (8r) of the sheath. 10. Combustion chamber according to one of claims 1 to 8 wherein the sleeve (8) and the deflector support (10) respectively have on their circumference a notch (16, 17) adapted to receive an alignment finger ( 12) so as to angularly position the two parts relative to each other during assembly. Combustion chamber according to claims 9 and 10 wherein the alignment finger (12) is held in place in its housing by the transverse flange (7c) of the supply system (7). 12. Combustion chamber according to all of claims 9 and 10 wherein the alignment finger (12) is held in place in its housing by welding. 13. Combustion chamber according to one of claims 1 to 12 wherein the baffle (10) is made of a material having a high temperature resistance and a coefficient of expansion, comparable to those of the CMC. 14. A gas turbine engine equipped with a combustion chamber according to one of the preceding claims.