FR3105994A1 - Variable outlet section nozzle for rocket motor and rocket motor comprising such a nozzle - Google Patents

Abstract

The invention relates to a rocket engine nozzle (1) with a variable outlet section, the nozzle comprising: a fixed part (2); and a movable part (3), movable between a retracted position, in which the movable part (3) surrounds the fixed part (2), and in which the fixed part (2) forms the inlet and the outlet of the nozzle ( 1), and a deployed position, in which the fixed part (2) forms the inlet of the nozzle and the movable part (3) forms the outlet of the nozzle (1); the movable part (3) being configured so that its outlet section increases when the movable part (3) moves from the retracted position to the deployed position, and so that, when the movable part (3) forms the outlet of the nozzle (1), the seal between the fixed part (2) and the moving part (3) at their junction makes it possible to prevent any leakage of the gases ejected during the operation of the nozzle. Figure for the abstract: Fig. 3

Description

Nozzle with variable outlet section for a rocket engine and rocket engine comprising such a nozzle

The invention relates to the field of rocket engines, and more particularly relates to a nozzle for a rocket engine intended to improve the efficiency of this engine.

The problem of rocket engine efficiency is a well-known problem in the aerospace world. Indeed, we note that for a fixed-speed rocket engine, the thrust produced varies significantly during a flight, in particular depending on the altitude at which the rocket operates. Indeed, for the thrust of a rocket engine to be maximum, the static pressure of the ejected gases must be identical to the ambient pressure prevailing around the rocket. However, during its use, the ambient pressure around the rocket varies according to the altitude at which it operates. In known manner, the static pressure of the ejected gases is determined by the section ratio between the neck of the nozzle and the outlet section. On a conventional rocket engine, this section ratio is fixed. Consequently, the static pressure of the ejected gases does not vary and therefore cannot be maintained equal to the ambient pressure throughout the flight. When the pressure of the ejected gases is higher than the ambient pressure, then the ejected gas flow must expand in order to adapt to the ambient pressure. The flow of ejected gas is then no longer parallel to the course of the rocket. The amount of movement produced is therefore reduced and generates a loss of efficiency of the motor. When the pressure of the ejected gases is lower than the ambient pressure, a suction phenomenon occurs, which slows down the rocket. This also generates a loss of engine efficiency. Moreover, when the pressure of the ejected gases is much lower than the ambient pressure, a phenomenon of separation of the ejected gases appears. This separation is often asymmetrical, causing thrust instabilities and side loads for the engine, which, in the most severe cases, can jeopardize the integrity of the engine.

A known solution for limiting the consequences of the problems set out above consists in adapting the nozzle to a given altitude, the ambient pressure of which corresponds to the average of the pressures encountered by the rocket engine during its use. In such a case, the pressure of the ejected gases is:

• lower than the ambient pressure during take-off and up to the adaptation altitude;
• equal to the ambient pressure at the adaptation altitude; And
• above ambient pressure at altitudes above the adaptation altitude.

The loss of efficiency generated in relation to the efficiency reached at the adaptation altitude can reach 20 to 30% at the time of take-off, then nearly 10% for altitudes above the adaptation altitude. The loss of efficiency during take-off is undoubtedly the most problematic, since it is during this phase that the mass of the rocket is greatest (due to the fact that its tanks contain the maximum amount of propellants), and, moreover, is subject to maximum drag due to the maximum air density.

In order to remedy the drawbacks mentioned above, solutions implementing a nozzle of variable section have been proposed, the modification of the section making it possible to have a nozzle that can be adapted during flight at different altitudes. Such solutions generally implement hinged flaps forming the end of the nozzle, and an actuation mechanism making it possible to modify the orientation of the flaps in order to tighten or widen the end of the nozzle. However, these solutions have the disadvantage of adding a large mass, and, above all, of modifying the profile of the nozzle too much. In general, no solution is known which is not penalizing in terms of cost and/or mass, and which makes it possible to modify the section of a nozzle continuously during use, so that the nozzle profile is kept very close to the ideal profile.

The object of the present invention is to remedy the drawbacks of the state of the art, and more particularly those set out above, by proposing a nozzle with variable section, the section of which can be modified during use while deviating as little as possible from the ideal profile.

To this end, the invention relates to a rocket engine nozzle with a variable outlet section, the nozzle comprising:

• a fixed part; And
• a movable part, movable between a retracted position, in which the movable part surrounds the fixed part, and in which the fixed part forms the inlet and the outlet of the nozzle, and a deployed position, in which the fixed part forms the inlet of the nozzle and the movable part forms the outlet of the nozzle;

the movable part being configured so that its outlet section increases when the movable part moves from the retracted position to the deployed position, and so that, when the movable part forms the outlet of the nozzle, the seal between the fixed part and the movable part at the level of their junction makes it possible to avoid any leakage of the gases ejected during the operation of the nozzle.

Thus, by implementing a nozzle comprising a fixed part and a mobile part whose section increases with its displacement from the retracted position to the deployed position, the invention makes it possible to vary the section of the nozzle, in a continuous manner, for adapt it to a wide range of altitudes. The invention makes it possible to adapt the nozzle over a wide range of altitudes while remaining as close as possible to the profile of the ideal profile of the nozzle, in particular from the point of view of the flow of fluids. The implementation of a nozzle according to the invention thus makes it possible to avoid the loss of 20 to 30% of thrust on takeoff that is observed on a conventional nozzle. The invention therefore makes it possible to significantly increase the payload, likewise reducing the cost, reduced to the mass, of sending the payload into orbit. The invention can also make it possible to limit the use of boosters, considered polluting and expensive.

In one embodiment, the movable part comprises a set of tiles, in which each tile is movable in translation relative to the fixed part of the nozzle, between a retracted position corresponding to the retracted position of the movable part, and a deployed position corresponding in the deployed position of the movable part, the set of tiles being configured so that, when the movable part forms the outlet of the nozzle, at least a section of the set of tiles forms a continuous envelope between the fixed part and the outlet of the nozzle, the tiles being contiguous two by two over the whole of this section, and so that an internal surface of the set of tiles has a section of circular shape at the level of an outlet section of the part fixed.

In one embodiment, the set of tiles is formed by alternating tiles of two types:

• tiles of a first type having an evolving cross-section, of increasing section in the direction of ejection of the gases;
• tiles of a second type, having an evolving cross-section, of decreasing section in the direction of ejection of the gases.

In one embodiment, the internal surface of each tile coincides with a portion of a cylinder of revolution with a diameter corresponding to the diameter of the internal surface of the set of tiles at the outlet section of the fixed part.

In one embodiment, the set of tiles includes an equal number of tiles of the first type and tiles of the second type.

In one embodiment, the set of tiles comprises a total number of tiles greater than or equal to 4, and for example between 6 and 24.

In one embodiment, the nozzle includes a system of rails to guide the set of tiles.

In one embodiment, the rail system comprises at least one rail of a first type to ensure the guidance of one or more tiles of the first type and at least one rail of a second type to ensure the guidance of one or more tiles of the second type.

In one embodiment, the rail system includes one rail per tile.

In one embodiment, the nozzle includes a drive system for moving the moving part.

In one embodiment, the drive system comprises at least one jack of a first type to drive one or more tiles of the first type, and at least one jack of a second type to drive one or more tiles of the second type.

In one embodiment, the drive system comprises one cylinder per tile.

In one embodiment, each tile comprises, on each side, a connecting device cooperating with a corresponding connecting device of the adjacent tile to form a sliding connection.

The invention also relates to an engine comprising at least one nozzle in accordance with that defined above.

The invention also relates to a rocket comprising at least one compliant engine as defined above.

The present invention will be better understood on reading the following detailed description, made with reference to the accompanying drawings, in which:

Figure 1 is a diagram representing the profile of a fixed part of a nozzle according to the invention.

Figure 2 is a side view of a nozzle according to the invention, a half-view showing the movable part of the nozzle in its retracted position, the other half-view showing the movable part in its deployed position.

Figure 2a is a half-sectional view of the fixed and mobile parts of the nozzle of Figure 2, the mobile part being in the retracted position.

FIG. 2b is a half-sectional view of the fixed and mobile parts of the nozzle of FIG. 2, the mobile part being in an intermediate position between the retracted and deployed positions.

FIG. 2c is a half-sectional view of the fixed and mobile parts of the nozzle of FIG. 2, the mobile part being in the deployed position.

Figure 2d is a sectional view of the fixed and movable parts of the nozzle in the configuration of Figure 2b, the section being seen in accordance with the section plane CC of Figure 2b.

Figure 2e is a detail view of Figure 2d.

Figure 3 is a side view of the nozzle of Figure 2, in its deployed position.

Figure 4 is a front view of a tile of the first type of the movable part.

Figure 5 is a side view of the tile of Figure 4.

Figure 6 is a bottom view of the tile of Figure 4.

Figure 7 is a perspective view of the tile of Figure 4.

Figure 8 is a front view of a tile of the second type of the movable part.

Figure 9 is a side view of the tile in Figure 8.

Figure 10 is a bottom view of the tile in Figure 8.

Figure 11 is a perspective view of the tile of Figure 8.

Figure 12 is a top view of the fixed part of the nozzle, in an eight-tile configuration.

FIG. 13 is a side view of the fixed part of the nozzle, in an eight-tile configuration, the profile of the mobile part in the retracted position being shown around the fixed part.

Figure 14 is a detail view of a tile of the movable part of the nozzle.

Figure 15 is a perspective view of the arrangement of two adjacent tiles.

Figure 16 is a view of a rocket equipped with a nozzle according to the invention.

The general architecture of a nozzle 1 according to the invention is described below, in relation to FIGS. 1 to 3.

In accordance with the invention, the nozzle 1 comprises a fixed part 2 and a mobile part 3. As can be seen in FIG. 2, which consists of two half-views of the nozzle 1, the mobile part 3 is mobile with respect to the part fixed 2 between a retracted position, or retracted position, visible in the lower half of Figure 2 (and in Figure 2a), and an extended position, or extended position, visible in the upper half of Figure 2 (and in the figure 2c). Between these two extreme positions, the movable part 3 can assume a plurality of intermediate positions, such as the position represented in FIG. 2b.

As shown in Figures 2 and 2a, the movable part 3 is located, in its retracted position, around the fixed part 2, and is positioned such that the free end of the movable part 3, which forms the section outlet 30 of the movable part, is located behind (relative to the direction of ejection of the gases materialized in FIG. 1 by the arrow F _G ) or at the same level as the free end of the fixed part 2. In this position, the outlet section 10 of the nozzle 1, which constitutes the gas ejection orifice (that is to say the outlet of the nozzle), is formed by the outlet section 20 of the fixed part 2 .

As shown in Figures 2 and 2c, the movable part 3 is located, in its deployed position, at least partially forward relative to the free end of the fixed part 2, and is positioned such that the output section 30 of the movable part 3 is located in the extension of the fixed part 2 and thus forms the outlet section 10 of the nozzle 1, and therefore the gas ejection orifice of the nozzle.

Whatever the position of the mobile part 3, the inlet section 12 of the nozzle 1 is formed by the inlet section 22 of the fixed part 2.

As shown in Figure 2b, the movable part 3 is located, in any intermediate position, between the retracted and deployed positions, partially advanced relative to the free end of the fixed part 2, and is positioned such that the outlet section 30 of the movable part 3 is located in the extension of the fixed part 2 and thus forms the outlet section 10 of the nozzle 1, and therefore the gas ejection orifice of the nozzle.

Whatever the position of the movable part 3, the latter is configured so that its section located at the level of the outlet section 20 of the fixed part 2 has a circular cross-sectional shape, of internal diameter equal to or greater than the external diameter. of the fixed part 2 at its exit section 20. Advantageously, the internal diameter of the mobile part 3 at the level of the exit section 20 of the fixed part 2 is equal to the external diameter of the latter, or has a value very close to this external diameter, making it possible to ensure a seal between these two elements sufficient to prevent any leakage of the gases ejected during the operation of the nozzle. Thus, as shown in Figure 2d, whatever the position of the movable part 3, the sealing between the fixed 2 and movable 3 parts is ensured by contact between these two elements. In the example of the figures, sealing is ensured by a tight fit between the fixed 2 and mobile 3 parts at their junction. Alternatively, a sealing element may be provided interposed between the fixed part and the movable part, at the level of their junction.

As shown in FIG. 1, the fixed part 2 has in the example the shape of a conventional nozzle, its internal surface being a surface of revolution of axis X. The fixed part 2 comprises, in the direction of the ejection of the gases : a convergent 24, a neck 26, and a divergent 28 whose free end forms the outlet section 20. The outlet section 20 of the fixed part 2 has a circular shape of radius A.

As shown in Figures 2 and 3, the movable part is in the example produced by means of an assembly of elements, or tiles 32, 34, movable in translation. In the example, the set of tiles 32, 34 is formed by alternating elements 32, 34 of two types:

• tiles of a first type 32; And
• tiles of a second type 34.

Each tile 32, 34 has an evolving section. The section of the tiles of the first type 32 is increasing in the direction of the ejection of the gases, while the section of the tiles of the second type 34 is decreasing in the direction of the ejection of the gases. Thus, as shown in Figure 2, the tiles are arranged so that the largest section of the tiles of the first type 32 is on the side of the outlet section 30 of the movable part 3, the largest section of the tiles of the second type 34 located on the opposite side. In the example of the figures, the shape of the tiles 32, 34 is such that the projection of the contour of their external surface on a diametral plane orthogonal to the median radial plane of each tile is of triangular shape. Thus, the tiles 32, 34 have the general shape of a triangle, these triangles being arranged in opposite directions two by two.

The mobile part 3 comprises an equal number of tiles of each type, and comprises in the example of figures 1 to 11 and 14 to 15 a total of twelve tiles, that is six tiles 32, 34 of each type. Figures 12 and 13 show a fixed part provided for a set of tiles comprising eight tiles in total. The total number of tiles of the set of tiles will be at least equal to 4, and in particular between 6 and 24. It is possible, for example, to provide a set of tiles comprising for example 6, 8, 10, or 12 tiles.

As visible in Figures 2 and 2a, the tiles of the first type 32 and the tiles of the second type 34 are configured to form, in the retracted position of the movable part 3, an assembly surrounding the fixed part 2, and whose internal surface has a shape that widens in the direction of gas ejection.

In the deployed position of the mobile part 3, visible in particular in FIGS. 3 and 2c, the tiles 32, 34 form an assembly having, at the outlet section 20 of the fixed part, a section of circular shape, the diameter is equal to or greater than the outer diameter of the fixed part 2 at the level of the outlet section 20, and provided to prevent any leakage of ejection gas between the two elements during operation of the nozzle.

The tiles 32, 34 of the set of tiles are arranged so that, when the movable part 3 is in a position in which it forms the nozzle outlet 1, at least one section 31 of the set of tiles, located between the section outlet 20 of the fixed part 2 and the outlet section 30 of the mobile part, has a continuous internal surface, of circular section at the level of the outlet section 20 of the fixed part 2.

The passage from the retracted position to the deployed position, or to any intermediate position, of the movable part 3 is obtained by sliding of the tiles 32, 34, by means of a system of rails 4. The system of rails 4 comprises in the example a plurality of rails 40, 42 including:

• rails of a first type 40, configured to cooperate with the tiles of the first type 32;
• rails of a second type 42, configured to cooperate with the tiles of the second type 34.

Preferably, the rail system 4 comprises as many rails of each type. In the example, the rail system 4 comprises one rail per tile 32, 34, and therefore comprises twelve rails in total, i.e. six rails of the first type 40 and six rails of the second type 42.

Each of the rails 40, 42 of the system of rails 4 is, in the example of the figures, of rectilinear shape, and oriented in a direction parallel to the direction tangent to the profile of the divergent 26 at the level of the outlet section 20 of the part fixed 2 (see figure 1, tangent line T).

In order to drive the mobile part from one position to another, the nozzle 1 comprises a system 5 for driving the mobile part 3 comprising in the example a plurality of cylinders 50, 52 including:

• jacks of a first type 50, configured to drive the tiles of the first type 32;
• cylinders of a second type 52, configured to drive the tiles of the second type 34.

Preferably, the drive system 5 of the mobile part 3 comprises as many cylinders 50, 52 of each type. In the example, the drive system 5 comprises one jack 50, 52 per tile 32, 34, and therefore comprises twelve jacks 50, 52 in total, i.e. six jacks of the first type 50 and six jacks of the second type 52 (some cylinders not being shown in Figure 3 for reasons of clarity).

An embodiment of the tiles 32, 34 that comprises the movable part 3 of the nozzle 1 is described below, in relation in particular to FIGS. 4 to 7 and FIGS. 8 to 11.

Figures 4 to 7 show different views of an embodiment of a tile of the first type 32.

Each tile of the first type 32 has a front end 320 and a rear end 322. The front end 320 of each tile of the first type 32 forms part of the output end of the mobile part 3 in its retracted position. As shown in Figure 6 which shows a cross section of a tile of the first type 32, the inner face 324 of each tile of the first type 32 coincides with a portion of cylinder of revolution of radius identical to that of the exit section of the fixed part (radius A). Each tile of the first type 32 has on its outer face 326 a cylinder attachment 328, located for example approximately halfway along the tile. The jack attachment 328 is used to fix the rod of the jack 50 provided to drive the tile in motion. Furthermore, each tile of the first type 32 comprises, on its internal face, a connecting device to the corresponding rail 40, such as a slider 330. A single slider 330 has been shown, but several sliders can be provided. The side edges of each tile of the first type 32 include a connection device to the adjacent tiles (which are therefore tiles of the second type 34), in the example in the form of a groove 332 shaped to cooperate with a shaped tenon complementary present on each tile of the second type 34, which is described in more detail below.

Figures 8 to 11 show different views of an embodiment of a tile of the second type 34.

Each tile of the second type 34 has a front end 340 and a rear end 342. The front end 340 of each tile of the second type 34 forms part of the output end of the mobile part 3 in its retracted position. As seen in Figure 10 which shows a cross section of a tile of the second type 34, the inner face 346 of each tile of the second type 34 coincides with a portion of cylinder of revolution, of identical radius to that of the section of exit from the fixed part (ray A). In addition, so that the different tiles can be contiguous when the movable part 3 is in the retracted position, each tile of the second type 34 has bevelled sides, oriented in a radial direction with respect to a circle with center C inscribed in the surface internal of the set of tiles at the rear end of the movable part 3 in the retracted position (that is to say the end opposite the outlet section 30 of the movable part 3). Each tile of the second type 34 has on its outer face 346 a cylinder attachment 348, located in the example close to the rear end 342. The cylinder attachment 348 makes it possible to fix the rod of the cylinder 52 provided to drive the moving tile. Furthermore, each tile of the second type 34 comprises, on its internal face 344, a connecting device to the corresponding rail 42, such as a slider 350. A single slider 350 has been shown per tile, but several sliders can be provided. The side edges of each tile of the second type 34 comprise a connection device to the adjacent tiles (which are therefore tiles of the first type 32), in the example in the form of a tenon 352 shaped to cooperate with one of the grooves 332 of complementary shape present on each tile of the first type 32. The grooves 332 and the tenons 352 have complementary shapes making it possible to form a sliding connection, as visible in FIG. 15 and in FIG. 2e. In the example, each groove 332 has in section comprising a widened part, of circular shape, and a narrowed part, and each tenon 352 has in section a complementary shape. Any shape allowing a sliding connection to be made, such as a dovetail shape, can alternatively be implemented.

The geometry and kinematics of the moving part 3 of the nozzle 1 are described below, in relation to FIGS. 1 to 3.

As mentioned above, the movement of the tiles 32, 34 forming the movable part 3 is carried out in a direction parallel to the tangent to the profile of the fixed part 2 at its exit section. The tangent lines at the points E and F have been shown in FIG. 1. The orientation of the tangents T corresponds to the orientation of the rails 40, 42 of the system of rails 4. The tangents T are secant at a point D, the triangle DEF being therefore isosceles. The configuration of the tiles 32, 34 of the mobile part implies that the course of all the tiles 32, 34 of the same type is identical. Furthermore, the travel of the tiles of the first type 32 between the retracted and deployed positions is less than that of the tiles of the second type 34. As shown in FIGS. 2, 2a, 2b, 2c and 3, the tiles of the second type 34 must cover a greater distance than the tiles of the first type 32 to pass from one extreme position to another, and vice versa. In the example of the figures, to pass from one extreme position to the other, the tiles of the second type 34 must travel a path twice as long as the tiles of the first type 32. This difference in travel implies a difference in length rails 40, 42 for guiding the tiles 32, 34. In the example, the length of the rails 42 guiding the tiles of the second type 34 is twice as long as that of the rails 40 guiding the tiles of the first type 32. Advantageously, the length of the rails of the second type 42 is at least equal to half the side of the triangle DEF, ie the length of the segments GE and HF. Advantageously again, the length of the rails of the first type 40 is at least equal to a quarter of the side of the triangle DEF, ie to half the length of the segments GE and HF. Such a configuration results in a difference between the radius A of the exit section 20 of the fixed part 2 and the radius B of the circle inscribed in the internal surface of the set of tiles 32, 34 at the level of the exit section 30 of the mobile part 3 (in the deployed position, cf. FIGS. 1 and 3) by 25%, which corresponds to an increase of around 56.25% in the area of the outlet section.

Figure 16 shows a rocket 100 comprising an engine (not visible) equipped with a nozzle 1 according to the invention. In the example, the drive system 5 of the mobile part is fixed to a fixed element of the engine or of the structure of the rocket 100.

The invention described above makes it possible to adapt the nozzle over a wide range of altitudes, in a continuous manner, while remaining as close as possible to the profile of the ideal profile of the nozzle, from the point of view of the flow of fluids in particular . In particular, the invention avoids the loss of 20 to 30% of thrust on takeoff that is observed on a conventional nozzle. The invention therefore makes it possible to significantly increase the payload, likewise reducing the cost, reduced to the mass, of sending the payload into orbit. The invention can also make it possible to limit the use of boosters, considered polluting and expensive.

Claims (15)

Nozzle (1) for a rocket engine with variable outlet section, the nozzle comprising:

• a fixed part (2); And
• a movable part (3), movable between a retracted position, in which the movable part (3) surrounds the fixed part (2), and in which the fixed part (2) forms the inlet and the outlet of the nozzle (1 ), and a deployed position, in which the fixed part (2) forms the inlet of the nozzle and the movable part (3) forms the outlet of the nozzle (1);

the movable part (3) being configured so that its exit section (30) increases when the movable part (3) moves from the retracted position to the extended position, and so that, when the movable part (3) forms the exit of the nozzle (1), the sealing between the fixed part (2) and the movable part (3) at the level of their junction makes it possible to prevent any leakage of the gases ejected during the operation of the nozzle. Nozzle according to the preceding claim, in which the movable part (3) comprises a set of tiles (32, 34) in which each tile (32, 34) is movable in translation relative to the fixed part of the nozzle (2), between a retracted position corresponding to the retracted position of the mobile part (3), and a deployed position corresponding to the deployed position of the mobile part (3), the set of tiles being configured so that, when the mobile part (3 ) forms the outlet of the nozzle (1), at least one section (31) of the set of tiles forms a continuous envelope between the fixed part (2) and the outlet of the nozzle (1), the tiles being contiguous two two over the whole of this section (31), and so that an internal surface of the set of tiles has a section of circular shape at the level of an outlet section of the fixed part (2). Nozzle (1) according to the preceding claim, in which the set of tiles (32, 34) is formed by alternating tiles of two types:

• tiles of a first type (32) having an evolving cross-section, of increasing section in the direction of gas ejection;
• tiles of a second type (34), having an evolving cross-section, of decreasing section in the direction of ejection of the gases.

Nozzle according to claim 2 or 3, in which the internal surface of each tile (32, 34) coincides with a portion of a cylinder of revolution of diameter corresponding to the diameter of the internal surface of the set of tiles at the level of the section of outlet (20) from the fixed part (2). Nozzle according to one of Claims 3 and 4, in which the set of tiles (32, 34) comprises an equal number of tiles of the first type (32) and tiles of the second type (34). Nozzle according to the preceding claim, in which the set of tiles comprises a total number of tiles greater than or equal to 4, and for example between 4 and 24. Nozzle according to one of Claims 2 to 6, comprising a system of rails (4) for guiding the set of tiles (32, 34). Nozzle according to the preceding claim, in combination with claim 3, in which the system of rails (4) comprises at least one rail of a first type (40) to ensure the guiding of one or more tiles of the first type (32 ) and at least one rail of a second type (42) for guiding one or more tiles of the second type (34). Nozzle according to one of Claims 7 and 8, in which the system of rails (4) comprises one rail (40, 42) per tile (32, 34). Nozzle according to one of the preceding claims, comprising a drive system (5) for moving the movable part (3). Nozzle according to the preceding claim, in combination with one of Claims 2 to 9, in which the drive system (5) comprises at least one cylinder of a first type (50) to drive one or several tiles of the first type (32) and at least one cylinder of a second type to drive one or more tiles of the second type (34). Nozzle according to the preceding claim, in which the drive system (5) comprises one cylinder (50, 52) per tile. Nozzle according to one of Claims 2 to 12, in which each tile (32, 34) comprises, on each side, a connecting device (332, 352) cooperating with a corresponding connecting device of the adjacent tile to form a connection slide. Engine comprising at least one nozzle according to one of the preceding claims. Rocket (100) comprising at least one motor according to the preceding claim.