DE69012427T2 - Reaction chamber and process for its manufacture. - Google Patents

Description

The invention relates to a chamber of a ramjet engine or a turbojet engine and in particular to a chamber of the type in which a fluid is introduced by transpiration across a heat-resistant porous wall.

The use of a porous material in a heat-resistant reaction tube of a turboprop engine is described in GB-A-2 089 434 and US-A-2,658,332. The tube is formed by an inner conduit of a low-density heat-resistant porous material and an external reinforcement, the presence of which is necessary due to the lack of mechanical strength of the porous heat-resistant material. The latter is formed from silica and alumina fibers, while the external reinforcement forms a network of circumferential and axial tubes and an outer casing of metal or a resin reinforced with carbon phases. The tubes can be traversed by a coolant or fuel and have perforated walls which allow the coolant or fuel to penetrate the internal insulating material.

The invention is based on the object of proposing a reactor chamber in which the effectiveness of the behaviour towards elevated temperatures, the mechanical strength and fuel injection can be ensured with the simplest possible structure.

According to the invention, the wall of the reactor chamber is made of a refractory composite material having a reinforcing structure compacted by a matrix and at least one injection zone formed by a part of the porous wall permeable to the fluid to be injected into the chamber, the permeability of the or each part of the wall forming an injection zone resulting from a lower compaction of the composite material compared to the remaining part of the wall which is impermeable to the fluid to be injected.

The heat-resistant composite material here is understood to be a composite with a ceramic or carbon matrix.

The or each part of the wall forming an injection zone is, for example, in the form of a ring, the surface of which opposite to that forming part of the internal surface of the chamber is in communication with a source of the fluid to be injected.

A heat-resistant composite material with a ceramic matrix (CMC) or a carbon matrix is particularly suitable for the manufacture of a reactor chamber in whose wall one or more zones for fluid injection by transpiration through a porous material are integrated.

In fact, such a material has thermostructural properties, that is, mechanical behavior and behavior towards elevated temperatures, which make it suitable for the manufacture of structural elements of the chamber In particular, external reinforcement around the wall made of a composite material as described in GB-A-2 089 434 is not necessary.

In addition, the porosity of a composite can be easily controlled by acting on the volume fraction of the main fibers of its reinforcing fiber structure and/or the degree of compaction by the base material of the matrix in order to obtain the permeability or impermeability to the fluid to be injected.

A material of type C/SiC (reinforcement of carbon fibers and matrix of silicon carbide) or of type SiC/SiC (reinforcement of fibers essentially of silicon carbide and matrix of silicon carbide) or of type C/C protected (reinforcement of carbon fibers, matrix of carbon and antioxidant protection) may be suitable.

The connection between the or each part of the wall forming an injection zone and the or each part of the wall forming the remainder of the chamber is advantageously achieved by assembling all the main parts of the wall in a state of incomplete compaction with respect to the desired degree of final compaction for each of the parts and by mixed compaction of the assembled wall parts. This mixed compaction is preferably achieved by chemical infiltration in the vapour phase.

A preferred embodiment is described below with reference to the accompanying drawing, the only figure of which is a schematic axial section of a stator reactor chamber.

In the example shown, the chamber 10 has a cylindrical shape with a circular cross-section and in the outlet direction of the air (arrow A) an upstream, sealed section, an injection ring 20 for injecting a flow of gaseous fuel and a sealed downstream section 14. The inner surfaces of the sections 12, 14 and the injection ring 20 form the inner, continuous, cylindrical wall of the chamber of a ramjet engine.

The outer surface of the ring 20 defines a fuel injection chamber 22 which is connected to a fuel source (not shown). The fuel is, for example, hydrogen which is injected in the gaseous state, the pressure prevailing in the injection chamber 22 being higher than that prevailing in the combustion chamber of the ramjet engine.

The ring 20 is a one-piece part made of a porous composite material with a ceramic or carbon matrix. The porosity of the base material of the ring 20 provides it with the permeability required to allow the injection of the gaseous fuel stream by transpiration across the injection ring. The amount of fuel injected into the combustion chamber is determined by the porosity of the injection ring, its length and the pressure difference between the outer and inner surfaces of the ring.

The base material of the ring 20 is a composite material consisting of a fibrous reinforcement partially compacted by a ceramic or carbon material. To produce the ring, an annular preform is manufactured which forms the fibrous reinforcement. The preform is made of carbon or ceramic fibers, e.g. from fibers in the made essentially of silicon carbide. The fibrous mold is produced, for example, by winding a fabric tape around a mandrel until the desired thickness is achieved. The fabric layers arranged one above the other can be connected to one another by needling or inserting threads.

The preform is densified in a gaseous or liquid manner. In the first case, densification is carried out by chemical infiltration in the vapor phase of a base material of the matrix, e.g. silicon carbide or carbon. In the second case, the preform is impregnated with an intermediate of the base material of the matrix, which is then obtained by thermal treatment.

The duration of the chemical infiltration in the vapor phase or the number of liquid thermolysis impregnation cycles are selected so that the desired final porosity is achieved taking into account the initial porosity of the preform. For example, an injection ring made of ceramic material C/SiC can be produced by making a preform from carbon fibers that has a fiber volume fraction of about 35% and compacting it by chemical infiltration in the vapor phase of silicon carbide until a residual porosity of about 40% is achieved.

In the case of a C/C type material, a special treatment is carried out to protect the material against oxidation. Various anti-oxidation protection treatments for C/C composites are known.

The sections 12, 14 of the ramjet engine chamber are also preferably made of a composite material with a ceramic or Carbon matrix. Advantageously, a material is chosen which has a reinforcement and a matrix of the same type as the injection ring 20. However, unlike the ring 20, the sections 12, 14 are impermeable, the impermeability being achieved by compaction exerted with sufficient pressure to fill the porosity of the fibrous reinforcement until the material becomes impermeable.

Advantageously, the connection between the sections 12, 14 of the wall of the chamber 10 and the injection ring 20 is achieved by mixed compaction. To this end, the sections 12, 14 and the ring 20 are manufactured separately, incompletely compacted to the desired final compaction level. The elements are then assembled abutting one another and placed in an infiltration furnace to obtain a final mixed compaction by chemical infiltration in the vapor phase. During the final mixed compaction, the continuity of the material of the matrix at the interfaces between the sections 12, 14 and the ring 20 ensures the connection between these elements. This final mixed compaction is continued until the desired degree of porosity for the injection ring 20 is achieved, the sections 12, 14 having been sufficiently pre-compacted to finally obtain the desired tightness.

From the above it follows that the use of protected CMC or C/C makes it possible to combine, within the same structure of the chamber wall, the behaviour at high temperatures or mechanical stresses and the fluid injection function in a specific zone of the chamber wall.

The number of injection zones can be greater than one if one or more additional Injection rings are provided to carry out a complementary fuel injection or the injection of an oxidizer for dilution downstream of the fuel injection. In addition, the injection zones can be given shapes other than ring shapes. In all cases, the parts of the wall forming the injection zones can be manufactured and assembled with the rest of the wall of the chamber as previously described with regard to the injection ring 20.

In the embodiment described with reference to the drawing, the injection of a gas fuel fluid into the interior of a stator reactor chamber is intended. The invention is also applicable in the case of the injection of a liquid fuel, whereby the porosity of protected CMC or C/C in the injection zone is adapted for this purpose. In addition, the scope of application of the invention is not limited to ramjet engine chambers operating with subsonic or supersonic combustion and also includes turbojet engine chambers.

Claims (5)

1. Reactor chamber in which a fluid is introduced by transpiration via a heat-resistant, porous injection zone forming part of the chamber, characterized in that the reactor chamber consists of a single wall made of a composite material with a ceramic matrix and has at least one injection zone formed by a porous part of the wall (20) permeable to the fluid to be injected into the chamber, the permeability of the or each part of the wall forming an injection zone resulting from a lower compaction of the composite material with ceramic matrix compared to the remaining part of the wall (12, 14) which is impermeable to the fluid to be injected. 2. Chamber according to claim 1, characterized in that the or each part of the wall forming an injection zone is, for example, in the form of a ring (20) whose surface opposite that forming part of the inner surface of the chamber is in communication with a source of the fluid to be injected. 3. Chamber according to claim 1 or 2, characterized in that the composite material with ceramic matrix is selected from a composite material of the C/SiC type and a composite material of the SiC/SiC type. 4. A method for producing a reactor chamber according to one of claims 1 to 3, characterized in that the or each part of the wall forming an injection zone and the or each part of the wall forming the remainder of the chamber are manufactured separately by incompletely compacting them to the desired degree of final compaction for each part of the main parts of the wall, assembling the main parts of the wall, and joining the assembled main parts of the wall together by mixed compaction until the desired degree of final compaction for each main part is achieved. 5. Process according to claim 4, characterized in that the mixed compaction is carried out by chemical infiltration in the vapor phase.