DE3019754C2 - - Google Patents

Description

The invention relates to a rectangular nozzle for jet engines, especially for military purposes, which as Konvergent-Di vergent nozzle is formed and in which by means of one several flaps existing flap system the thrust jet up at an angle of more than 90 ° from its original Direction can be deflected in which the flap system in with respect to the horizontal median plane of the nozzle is formed, and in which the valve system with one above and arranged below the central plane of the nozzle, and with a movement component parallel to the longitudinal axis of the nozzle Actuators movable main flap is provided.

Rectangular nozzles differ from those generally used for engines ken used in the military field with circular Cross-section in that it is a transition piece (Transitions piece) have that of the circular cross section behind the turbine or behind the afterburner in a rectangular or angular converts to rectangular cross-section. This right angle Cross-section is, provided it is a convergent-divergent- Nozzle acts, already reached before the narrowest cross section and maintained up to the exit level.

With a suitable design, rectangular nozzles have numerous advantages over nozzles with a circular cross section. So, especially when using two engines lying side by side, the resultant force resulting from the difference between thrust and stern resistance is greater than with circular nozzles. This is especially true in the transonic range (M = 0.9 to 1.2).

Furthermore, rectangular nozzles can generally be used with simpler ones Average than an adjustment of nozzles with a circular cross section Nozzle neck area, nozzle exit area and a thrust deflection or reverse thrust.

There are already numerous designs for rectangles in the literature known nozzles. For example, in AIAA paper 75-1318 from September 1975 treated a nozzle of the type mentioned at the beginning, the so-called ADEN nozzle (Augmented Deflector Exhaust Nozzel). It is a symmetrical thruster, in particular for use in high-performance combat aircraft with vertical launch capability is provided.

Wind tunnel examinations have shown, however, that a such nozzle changes due to pressure changes in the jet vertical thrust of up to 10%. This Schubän changes perpendicular to the actual direction of thrust can be caused by adjusting the throttle, must either by operating the tailplane or the Trimmed flaps over a suitable control device will.

From another publication, US-PS 40 52 007, is one Rectangular nozzle for jet engines known in which by means of a multi-valve valve system the thrust jet up to an angle of more than 90 ° with respect to its original direction is deflectable. The flap system is related to the center plane of the nozzle is symmetrical and consists of one each above and below the median plane of the nozzle arranged and with a movement component parallel to the nozzles longitudinally movable main flap, and a downstream Flap around a horizontal, perpendicular to the longitudinal axis of the nozzle lying axis is pivotally arranged.  

This also proves to be the case with certain flap positions corner nozzle as fluid mechanically disadvantageous because the main flap and the downstream flap above and below the nozzles middle plane are not connected. With such a clap Pen positions form on the rear edges of the main flaps turbulent flows, the pressure changes and changes in the Can generate vertical thrusts. In addition, the thrust jet can be distract from its original direction by more than 90 °, but this is only to generate a reverse thrust in which the main jet is divided into at least two partial streams.

The invention has for its object a rectangular nozzle type mentioned in such a way that on the one hand a possible Lich homogeneous nozzle flow is achieved, the change in Nozzle pressure prevented, or at least no influence on the Has direction of the thrust jet, and that on the other hand a continuous deflection of the thrust jet up to angles of more than 90 ° is attainable, and that the nozzle is as possible simple and therefore less prone to failure.

The invention solves this problem by providing that at the downstream trailing edges of the main flaps 1, 2 each about a horizontal axis perpendicular to the nozzle axis S, S ' pivotable end flap 3, 4 is articulated that the displacement of the main flaps 1, 2 with the hinged end flaps 3, 4 each follows along the longitudinal axis of the main flaps 1, 2 , and that additional baffles 5, 6 are arranged in the nozzle, behind which the main flaps 1, 2 are at least partially retractable.

In addition, the rectangular nozzle according to the invention has the front partly that it takes up little space when installed, since the individual flaps do not have the outer outline of the nozzle protrude and therefore no additional storage space, e.g. B. for a diverter flap is required. Furthermore, the invention Rectangular nozzle according to the advantage that due to the simple construction  way of the flap system the supply and distribution of the cooling air is significantly simplified. The rectangular nozzle after the Er The invention is particularly good for use in engines suitable with afterburner, where the adjustability of the Nozzle neck area between a minimum area when operating without Afterburning and a maximum area when operating with night combustion is required. Furthermore, the invention ensures rectangular nozzle, the independent adjustability the nozzle neck surface and the nozzle outlet surface. The boost Here, jet can be used both with and without post-processing combustion are continuously deflected downwards, with the Operation with afterburning a maximum deflection angle of about 100 ° can be achieved.

The rectangular nozzle according to the invention is thus outstanding for one Use in high-performance combat aircraft with vertical take-off suitable.

The subclaims relate to a particularly simple and ef ficated embodiment of the rectangular nozzle according to the invention, wherein this is designed as a convergent-divergent nozzle. In the before Preferred embodiment, the nozzle has a rear outflow angle of about 10 °, at which a trans particularly favorable ratio of thrust and stern resistance results. Furthermore, in this embodiment of the invention, it is in operation with afterburning inner surface to be cooled in the nozzle on a Mi reduced to a minimum since the main flaps are almost completely behind the additional baffles are retractable.

A particular advantage of this embodiment can be seen in the fact that the thrust jet deflection takes place in the vicinity of the narrowest cross section of the nozzle, at about M = 1, and not, as is often the case with other nozzles, further downstream in the area of the supersonic speed. As a result, the thrust losses when deflecting the thrust jet can be kept as low as possible.

In the following, the invention with reference to the drawing, he to be refined. It shows

Fig. 1 shows a longitudinal section through an example of the execution Rechteckdüse invention in a schematic representation (Klapenstellung without afterburning)

Fig. 2 is an illustration of the different cross-sections in Fig. 1,

FIGS. 3 to 6 more flap positions in the arrangement of FIG. 1.

In the figures, the same components have the same reference characters.

In the embodiment of the invention shown in the figures, it is a convergent-divergent rectangular nozzle, which is particularly suitable for installation in high-performance combat aircraft, which are also said to have vertical take-off capability. The nozzle is formed by the side walls 7 and the upper wall surface 8 and the lower wall surface 9 . It has an approximately circular cross section A on the entry side. This continues downstream, in a transition area, into an approximately rectangular cross section B or C. The width of the rectangular cross sections is chosen in the case of the embodiment shown here so that it corresponds approximately to the diameter D of the circular cross section on the inlet side.

On the top and bottom of the downstream nozzle part, a beam deflector consisting of several flaps is arranged symmetrically to the central plane of the nozzle. This consists in detail of the two main flaps 1 and 2 and the end flaps 3 and 4 articulated thereon via hinges.

The main flaps 1 and 2 are essentially flat, rectangular bodies which extend over the entire width of the nozzle. The upper main flap 1 is slightly longer than the lower main flap 2 . They are arranged in the nozzle, immediately below the upper or lower wall, in such a way that they are inclined at an angle of approximately 10 ° with respect to the jet direction and converge towards the outlet region of the nozzle. They are also so guided by scenes not shown here in the side walls 7 of the nozzle that they are slidable in the direction of their longitudinal axis, that is to say with a movement component parallel to the longitudinal axis of the nozzle. The actuating mechanism required for this is arranged outside the nozzle and is therefore also not shown in the figures.

Furthermore, parallel to the main flaps 1 and 2 guide plates 5 and 6 are arranged in the nozzle, which also have slightly different length and behind which the main flaps 1 and 2 are almost completely retractable.

The end flaps 3 and 4 also extend over the entire width of the rectangular nozzle and have a streamlined profile. Their largest cross-section, which lies in the region of the pivot axes S or S ' , is chosen so that the end flaps jump inwards relative to the main flaps by a distance d which corresponds to approximately half their diameter at this point. In their downstream from the pivot axes S and S ' located the end flaps 3 and 4 taper.

Due to this shape of the end flaps, the nozzle according to the invention at the height of the pivot axes S or S 'has its smallest cross-section in order to pass further downstream into a divergen part.

It should also be mentioned that the end flaps 3 and 4 facing Kan th of the main flaps 1 and 2 are shaped so that with each pivoting position of the end flaps 3 and 4 there is only the smallest possible space between the main and end flaps. The actuation mechanism for the end flaps 3 and 4 , like that for the main flaps 1 and 2, lies outside the actual nozzle and is therefore also not shown in the figures.

Finally, it should also be noted that in the figures, which are only intended to show a schematic representation, the rear side wall 7 is shown in its outer contours. The upper and lower walls 8, 9 of the nozzle only extend approximately to the position of the cross section B , while in the downstream region of the nozzle the upper and lower cover is formed by the flap system itself.

To be in Figs. 3 to 6, which on the basis of the operation to the invention OF INVENTION Rechteckdüse explained, different flap positions are shown, which at the same time different Be operating states of the nozzle, respectively.

Fig. 3 shows the flap position with the afterburner switched on. Ge compared to the representation in Fig. 1, the main flaps 1 and 2 are now fully retracted behind the baffles 5 and 6 , so that they are largely shielded from the engine jet and require minimal cooling. You can see from this presen- tation at the same time that when the main flaps are retracted the narrowest cross section of the flow is enlarged and thus the respective operating condition is adapted.

While in Figs. 1 and 3, the thrust jet nozzle unabge hinged leaves, FIGS. 4 to 6 show valve positions at which is done by pivoting the same direction end flaps 3 and 4, a deflection of the beam down. Here, Fig. 4 5 corresponds to the operation without afterburning and Fig. Afterburning operation.

Finally, FIG. 6 shows the case of a deflection of the thrust jet during post-combustion by more than 90 °. In this case, the geometric deflection angle is approximately 100 °. This position is realized in that the upper main flap 1 is fully extended, which is fully retracted under the main flap 2 , and in the end flaps 3 and 4 are folded down completely.

Is possible to Figs. 3, 5 and 6 make it also clear that the the flap positions shown in afterburning is in each the size of the smallest cross section is always the same, so that did plural continuous in every deflection of the shear beam and further it is possible to fly constantly with a slightly deflected thrust jet.

Also not shown in the figures is that against sensible pivoting of the end flaps ver the nozzle exit surface can be changed without changing the size of the narrowest cross-section is changed.

The rectangular nozzle according to the invention can additionally can be equipped with a separate thrust reverser.

Claims (10)

1. Rectangular nozzle, which is formed as a convergent-divergent nozzle and in which the thrust jet can be deflected up to an angle of more than 90 ° with respect to its original direction in which the valve system is related by means of a valve system consisting of several valves is formed symmetrically on the ho horizontal central plane of the nozzle, and in which the flap system is arranged with a valve located above and below the central plane of the nozzle, and is provided with a main component displaceable parallel to the longitudinal axis of the nozzle by means of adjusting devices, characterized in that the downstream trailing edges of the main flaps ( 1, 2 ) is articulated in each case about an end flap ( 3, 4 ) which can be pivoted about a horizontal axis perpendicular to the nozzle axis (S, S ') , such that the displacement of the main flaps ( 1, 2 ) with the articulated end flaps ( 3, 4 ) along the longitudinal axis of the main flaps ( 1, 2 ), and that in the D Additional guide plates ( 5, 6 ) are arranged behind which the main flaps ( 1, 2 ) can be at least partially retracted. 2. Rectangular nozzle according to claim 1, characterized shows that the outer outline of the main and end flap pen inside the nozzle. 3. Rectangular nozzle according to claims 1 and 2, characterized in that the main flaps ( 1, 2 ) are designed as flat bodies which are inclined at an angle ( α ) with respect to the central plane of the nozzle and are arranged in a downstream direction in a converging manner. 4. Rectangular nozzle according to claim 3, characterized in that the angle of inclination ( α ) of the main flaps ( 1, 2 ) relative to the central plane is approximately 10 °. 5. Rectangular nozzle according to claims 1 to 4, characterized in that the end flaps ( 3, 4 ) are streamlined in the longitudinal direction, their largest diameter in the region of the pivot axes (S, S ') and their downstream ends taper. 6. Rectangular nozzle according to claim 5, characterized in that the main flaps ( 1, 2 ) in their the Endklap pen ( 3, 4 ) facing area of the outer shape of the end flaps ( 3, 4 ) are adapted so far that the space between Main flap ( 1, 2 ) and end flap ( 3, 4 ) is as narrow as possible. 7. Rectangular nozzle according to claims 5 or 6, characterized in that the end flaps ( 3, 4 ) on the main flaps ( 1, 2 ) are held such that they are in the region of the pivot axes (S, S ') by a distance (d ) jump inwards opposite the main flaps ( 1, 2 ). 8. Rectangular nozzle according to claim 7, characterized in that the distance (d) corresponds approximately to half the diameter of the end flaps ( 3, 4 ) in the region of the pivot axes (S, S ') . 9. Rectangular nozzle according to claims 1 to 8, characterized in that in the side walls ( 7 ) of the nozzle scenes for guiding the main flaps ( 1, 2 ) are arranged in their displacement. 10. Rectangular nozzle according to claims 1 to 9, characterized in that the narrowest nozzle cross section is in the region of the pivot axes (S, S ') of the end flaps.