The present invention relates to a rocket engine nozzle system, and more particularly to a nozzle system that comprises a group of individual nozzles.
Examples of rocket engine nozzle systems are already known that make use of sets of non-axially symmetrical nozzles that are of rectangular shape and that are fitted to a central core (also known as a “plug”).
A rocket engine with a central core and a linear set of individual nozzles of this type has been proposed in particular by the supplier Rocketdyne under the reference XRS-2000 for fitting to the reusable single-stage launcher in the context of the Lockeed-Martin X33 program, which program remains in the state of a project.
Rocket engines of that type present certain drawbacks in terms of mass or cooling difficulties.
Theoretical proposals have also been made to design a rocket engine nozzle system comprising a central core that is axially symmetrical in shape, essentially frustoconical, together with a set of axially symmetrical nozzles assembled around the central core.
Nevertheless, such axially symmetrical individual nozzles necessarily give rise to flow discontinuities in the gas on leaving the diverging portion of an individual nozzle in order to join the central core. Such discontinuities are not only harmful in terms of aerodynamic performance, but they also give rise to problems involving the thermal resistance of the central core, since the locations where the flows become attached to the central core are subjected to increased heat transfers as a result of the flows being deflected.
To remedy those drawbacks of the prior art, it is possible, as shown in
Such an arrangement enables certain drawbacks of axially symmetrical nozzles to be remedied, however it does not enable the space around the central core to be optimized, nor does it deal with the problem of flow discontinuity at the outlets from the nozzles, at their inner edges.
The invention seeks to remedy the above-mentioned drawbacks and in particular to enable the space allocated to the individual nozzles around the axially symmetrical central core to be optimized, while nevertheless ensuring high expansion ratios for the gas expelled by the individual nozzles and reducing thermal resistance problems for the central core.
In accordance with the invention, these objects are achieved by rocket engine nozzle system, comprising a set of individual nozzles distributed in a ring around a central core of axially symmetrical shape presenting a central axis, wherein each individual nozzle placed at the periphery of the central core comprises a circular section throat for receiving gas coming from a combustion chamber, and a diverging portion tangential to the central core, and wherein the diverging portion has an outlet section presenting first and second lateral sides that converge radially towards the central axis of the central core, an outer side that is curved with its convex side directed outwards, and an inner side situated in the vicinity of the central core.
Said inner side that is situated in the vicinity of the central core may be straight, but in an advantageous particular embodiment this inner side is curved with curvature close to that of the central core, and said inner side presents continuity of slope in the meridian plane with the central core, i.e. the inner side of the nozzle is tangential to the central core.
The radial lateral sides may be rectilinear, or in a variant embodiment, they may present a certain amount of curvature with a radius that is greater than that of the central core.
In a particular embodiment, the curved outer side of an outlet section of an individual nozzle presents curvature so as to constitute a portion of a circle that is concentric with the central core.
In another particular embodiment, the curved outer side of an outlet section of an individual nozzle presents curvature constituting a portion of an ellipse that presents radii that are smaller than the radius of the central core.
In the present invention, the individual nozzles present outlet sections that are generally trapezoidal in appearance, with each of the outlines thereof having a rectilinear or curvilinear shape specific thereto, depending on constraints of size, of the mechanical strength of the walls, and of optimizing flows.
Other characteristics and advantages of the invention appear from the following description of particular embodiments, given as examples and with reference to the accompanying drawings, in which:
Each individual nozzle 1 has a nozzle throat 12 of circular shape connected to a combustion chamber 11, and a diverging portion 13 terminating in an outlet section 14 that is generally trapezoidal in shape, where each of the sides 14a to 14d of this outlet section may be of some particular shape, whether rectilinear or curvilinear, depending on constraints of available space.
Using individual nozzles 1 that are not axially symmetrical makes it possible not only to optimize the space allocated to the nozzles around the central core 2 so as to reduce the discontinuities in combustion gas flow on leaving the nozzles 1 and joining the central core 2, but also to obtain gas expansion ratios in the nozzles 1 that are greater than can be obtained with axially symmetrical nozzles.
In the embodiment of
In
In the embodiment of
In general, each individual nozzle 1 presents a throat 12 of circular section and a diverging portion 13 of section that varies regularly so as to reach the desired shape at the outlet section 14 of the nozzle. This variation is computed on the basis of various propulsion performance criteria or of other constraints such as maintaining a cooling film, for example. It may also be observed that the trapezoidal shape of the outlet section 14 of the nozzles 1 provides advantages in terms of the mechanical strength of the walls as a result of the multiple curvatures that are formed in the diverging portion 13.
It should be observed that the face of a diverging portion 13 of a nozzle 1 that comes into contact with the central core 2 is preferably a warped surface with two curvatures. More particularly, a first curvature arc enables the edge of the diverging portion 13 of the nozzle 1 to be in contact with a line parallel to the central core 2, while a second curvature arc enables the nozzle to provide slope continuity in a meridian plane with the central core 2 at the end of the nozzle in the vicinity of its outlet section 14.
The nozzle 301 presents a diverging portion 313 with a warped surface having double curvature as mentioned above, and terminating in an inner side 314a that matches the shape of the central core.
The relationship between the warped surface having double curvature and the surface of the central core is firstly a condition that the warped surface of the nozzle be tangential to the surface of the central core along the parallel line of contact between them. This results in a nozzle outlet angle that varies along the side 314a within a range of values that is compatible with well-behaved aerodynamic flow.
The condition defining the relative position of each individual nozzle 1 and the truncated cone 2 is that the nozzles 1 and the truncated cone 2 must be tangential where they make contact.
In the embodiment of
The diverging portion 113 of a nozzle 101 presents a profile of elliptical section over the outer portion of the nozzle 101 up to the outlet section 114. It should be observed that optimizing a nozzle 101 may require the meridian profiles of the nozzle to be different in the plane extending radially relative to the central core 102 and in the plane orthogonal thereto.
The outlet section 114 may also be of a shape that retains the general appearance of a trapezoid, however the outer side 114b presents curvature that is highly marked, having a small radius of curvature, much smaller than the radius of curvature of the central core 102 or the radius of curvature of the circular arc of the outer sides 14b in the embodiment of
The lateral sides 114c and 114d of the outlet section 114 of the nozzles 101 are rectilinear and radial, whereas the inner side 114a of each nozzle closely matches the curvature of the central core 102 so as to avoid any gas flow discontinuity at the outlet from a nozzle, at its inner side 114a placed in the vicinity of the central core 102.
The inner side 14a, 114a of an outlet section 14, presents a size that is smaller than the chord defined from the curved outer side 14b, 114b.
Number | Date | Country | Kind |
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07 59619 | Dec 2007 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
3112612 | Berman et al. | Dec 1963 | A |
3188024 | Schneider | Jun 1965 | A |
3197959 | Keller | Aug 1965 | A |
3286469 | Atherton | Nov 1966 | A |
3314609 | Horgan et al. | Apr 1967 | A |
3486517 | Gaura | Dec 1969 | A |
3532297 | Maes | Oct 1970 | A |
3802190 | Kaufmann | Apr 1974 | A |
4017040 | Dillinger et al. | Apr 1977 | A |
4384690 | Brodersen | May 1983 | A |
4964340 | Daniels et al. | Oct 1990 | A |
6516605 | Meholic | Feb 2003 | B1 |
6761335 | Goodro et al. | Jul 2004 | B2 |
6845606 | Franchet et al. | Jan 2005 | B2 |
7281367 | Rohrbaugh et al. | Oct 2007 | B2 |
20070056261 | Lausten et al. | Mar 2007 | A1 |
Number | Date | Country | |
---|---|---|---|
20090145134 A1 | Jun 2009 | US |