DE2063342C3 - Device for deflecting the jet of propellant gas from jet engines for aircraft - Google Patents

Description

The invention relates to a device for covering the propellant gas jet from jet engines for Aircraft with a curvature variable jet pipe, consisting of one behind the other in the pipe longitudinal direction arranged, mutually movable, cylindrical pipe sections.

Certain aircraft configurations require propellant gas jets from cruise engines for improvement the short take-off and short landing properties from their exit direction in the direction of the split flaps deflect at the wing trailing edge. This allows both a jet component that provides lift as well as an aerodynamic increase in lift in slow flight, d. H. at start and Landing, achieve.

For aircraft that have vertical flight characteristics with the help of lift jet engines, it is common to the jet of propellant gas emerging from the lift engines by a certain angular amount deflect the exit direction and thus generate braking stroke. For this purpose it is known to divert blades to be arranged in the area of the outlet nozzle, which are provided to be pivotable into the propellant gas jet.

In a known arrangement, a variable curvature is attached to the stationary jet pipe of a jet engine Pipe part connected. This ίο pipe part is made up of at a distance each other held cylindrical ring parts, which have parallel axes and corresponding bearings are provided pivotable against each other. Each of these ring parts consists of two concentric : 5 see rings, whereby in the space formed thereby engage rings provided with annular rings movably. The disadvantage of this version is that the flow is significantly disturbed by the annular depressions and thus high flow resistances be evoked. Furthermore, the sealing engagement of the ring members and shroud rings into each other the risk of jamming, especially with regard to a thermal load of the Pipe part through the hot propellant gas jets of a jet engine.

It is also still a curvature variable pipe part is known that a number of interengaging Has jacket rings or ring members. The ring links are also connected to one another via joints connected and pivoted against each other. Also in this known version are disregarded of a considerable number of interlocking components to form the curvature variable Pipe part, extending transversely to the direction of flow of the propellant gas jets, annular depressions between the individual links present.

The object of the invention is to provide a device for deflecting propellant gas jets from jet engines to create a constant guide in every position of the variable curvature pipe part of the jet of propellant gas emerging from the engine as well as perfect sealing of the jet guide is achieved and by means of which the flow resistances can be kept as low as possible.

The object is achieved according to the invention in that between each two adjacent cylindrical Pipe sections an outwardly extending lyre-like shape in the pipe longitudinal section Annular profile section arranged with an annular gap open to the inside of the pipe and on its radially inner one Ends each with one of the adjacent cylindrical pipe sections is firmly connected and that in each case attached on one side of the annular gap to the associated cylindrical pipe section, the annular gap in every position of the variable curvature jet pipe from the inside overlapping cylindrical Extension sections are provided. A device designed in this way for deflecting propellant gas jets is extremely simple in its structure. The training also allows the pipe part on all sides is movable and thus adjusts a jet outlet nozzle adjoining the tubular part in each outlet direction can be. In addition, a steady course of the beam guiding surface is achieved and a hindrance of the guided propellant gas jet through projections protruding into the flow or the jet guide surface interrupting depressions largely avoided.

In a further embodiment of the invention it is provided that in each case the one cylindrical pipe section has a cylindrical extension section has beyond the connection with the neighboring Lyra-shaped Ringprofilabschniu, which its Annular gap covered This is enough for a simple one Way the annular gaps, which are created by the lyra-like profiled sections, are covered in a streamlined manner are without the mobility of the curvature Pipe part is impaired.

In a further embodiment of the invention, it is also in a jet deflection device with a jet nozzle, with their outer spherical cap-shaped part in a recess on the fixed beam guide tube pivotally mounted it is provided that the curvature variable jet pipe in an annular Recess on the fixed jet guide or the jet outlet nozzle to form a transition jet guide surface is used This has the advantage that the outer contour of the fixed Beam guide tube and the jet outlet nozzle has a flow-favorable course. Simultaneously is through the into the recesses on the jet outlet nozzle or the fixed beam guide tube used, a variable-curvature tube part a flawless Guiding the jet of propellant gas to be deflected causes the outwardly extending lyra-like Profiles are thus created by the fixed beam guide tube in conjunction with the Jet outlet nozzle covered to the outside.

In the drawing, exemplary embodiments are in accordance with of the invention shown

F i g. 1 shows an overview of a jet engine arranged below the wing in a side view;

F i g. 2 shows an enlarged detail from FIG. 1 the swivel nozzle in normal position, cut lengthways shown;

F i g. 3 shows an enlarged detail from FIG. 1 the swivel nozzle in a swivel position, shown in longitudinal section;

F i g. 4 to 6 show an enlarged detail from FIG. 2 or 3 details of the swivel nozzle;

F i g. 7 shows a further embodiment of the Faltbzw. Corrugated pipe part in a longitudinal section, schematized shown.

In the drawing is the wing of an aircraft with arranged on both sides of the fuselage and attached to stems below the wing Turbine turbines shown.

In Fig. 1 is one of the turbofan engines with 2 and designated by 3 the aircraft wing. The turbofan engines 2 are below the wing in Area of the wing leading edge with the help of fastening stems 4 attached to the trailing edge of the Wing 3, double slotted flaps 6 and 7 are arranged, which are used to increase lift during take-off and landing can be used. With 10 the casing forming the engine nacelles is also referred to. Inside the front part of the fairing 10 is the air inlet opening ti, which the compressor blades 12 of the single-stage low-pressure compressor are arranged downstream. By means of the outer engine casing 14 and the inner engine casing 16, the bypass duct 17 is formed. The coaxial The air supply channel J9 lying to the sheath flow channel 17 conducts an air supply channel supplied by the low-pressure compressor Part of the air drawn in to the high-pressure compressor and the combustion chambers or to the turbine from which from the propellant gas jets of the jet outlet nozzle 20 are fed, the above listed here Engine elements are not shown.

As in particular the F i g. 2 and 3 show, the jet outlet nozzle 20 is separate from the fixed beam guide formed by the inner engine casing 16 is arranged. the Jet outlet nozzle 20 engages over part of its longitudinal extent in an annular recess 24 in the area of the free end of the inner engine shroud 16. The one engaging in the recess 24 Section of the jet outlet nozzle 20 has a spherical cap Circumferential surface 27, by means of which a pivoting movement of the nozzle 20 within the recess 24 of the beam guidance is enabled. In the nozzle 20 leading to the jet outlet opening 26 (FIG. 1) An annular recess 28 is incorporated into the beam guide surface 32. The jet outlet nozzle 20 has also fork parts 37, in the corresponding pivot bearing parts 35 on the inner engine casing 16 intervene. The fork parts 37 of the jet outlet nozzle 20 and the pivot bearing parts 35 of the stationary Sirahlrführung 16 are connected to one another in an articulated manner via pivot bearing bolts 38 which are coaxial to one another, so that the jet outlet nozzle 20 swivels around the plane parallel to the aircraft transverse axis able to perform lying axes. With the pivot pin 38 pivot levers 39 are connected, via a linkage 40 on both sides of the inner engine casing 16 to a not shown here Drive are connected. Inside the annular recess 24 of the inner engine shroud 16 or the annular recess 28 on the jet outlet nozzle 20 is a flexible or corrugated tube formed curvature variable jet pipe 45 used, which serves as a joint expansion compensation.

As shown in detail in FIGS. 4 to 6, there is the variable curvature jet pipe 45 at this version consists of individual profile elements 44, each consisting of a lyre-like in the pipe longitudinal section Assemble the ring profile section 46 and the cylindrical tube sections 48 and 49 adjoining it. The cylindrical tube section 48 of the profile elements 44 overlaps in each pivot position of the Jet outlet nozzle 20, the cylindrical pipe section 49 and the pipe section 48 of the adjacent profile element 44 and at the same time covers the ring profile section 46 formed by the lyre-like ring profile section and to the Beam deflection from the annular gap. Two needed each Profile elements 44 are with their cylindrical pipe sections 48 and 49 via a connection 50, which can be designed as spot welding, connected to each other. The cylindrical pipe sections 48 have on part of their longitudinal extent a shoulder 52, the offset cylindrical extension section is designated at 48 '. The cylindrical sections 48 'are thus on the same Diameter. The cylindrical sections 48, 48 'of the profile elements 44 thus form a transition beam guiding surface 33 between the jet guide surface 31 of the inner engine casing 16 and the Beam guiding surface 32 of the beam outlet nozzle 20 (FIGS. 2 and 3).

The mode of operation of the embodiment described according to FIG. 1 to 6 is as follows:

Should a deflection of the primary jet guided through the jet outlet nozzle 20 from the outlet direction

take place to the rear on the double slit flaps 6 and 7, the jet outlet nozzle 20 is moved about the pivot bearing pin 38 via the rod 40 and the pivot lever 39. The connection of the variable curvature jet pipe 45 on the one hand to the fixed jet guide 16 and on the other hand to the jet outlet nozzle 20 results in a corresponding curvature of the jet pipe 45, the length of the jet pipe 45 being shortened above the pivot bearing pin 38 and the elongation below the bolt 38 compared to the normal position due to the Lyra-like ring profile sections 46 is added. This results in a change in distance x ¹ or x " between each two ring profile elements compared to the normal distance of x. Because the cylindrical tube or extension section 48, 48 'of each profile element 44, the annular gap of the lyre-like ring profile section 46 and the cylindrical tube section 48 of the adjacent ring profile element 44 overlaps, a transition jet guide surface 33 is formed, through which the propellant gas jet is continuously released from the stationary jet guide 16 even in the pivoted position of the jet outlet nozzle 20

is guided to the jet nozzle 20. Adapting the cylindrical Sections 48, 48 'to the curvature of the profile elements 44 is thereby through the one-sided Connection of these sections 48, 48 'to the adjacent cylindrical section 49 of the ring profile elements 44 causes.

In Fig. 7 is another embodiment of one Curvature variable jet pipe 45 shown. In this version, the connection between the fixed beam guide 16 and the jet outlet nozzle 20 via a corrugated pipe consisting of one part made with lyra-like ring profile section 53 and cylindrical tube sections 54 and 54 '. With the section 54 'of each lyre-like ring profile section 53 is a cylindrical section via a connection 56 Extension section 55 firmly connected to each of the annular gap of the lyre-like ring profile section 53 and the subsequent cylindrical pipe section 54 in each pivot position of the jet outlet nozzle 20 overlaps. The cylindrical extension sections form the transition beam guiding surface 33 from the fixed jet guide 16 to the jet outlet nozzle 20.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. A device for deflecting the propellant gas jet from jet engines for aircraft with a curvature variable jet pipe, consisting of mutually movable cylindrical pipe sections arranged one behind the other in the longitudinal direction of the pipe, characterized in that between each two adjacent cylindrical pipe sections (48) an outwardly extending, in the pipe longitudinal section Lyra-like formed ring profile section (46, 53) with an annular gap open to the inside of the tube and is firmly connected at its radially inner ends to one of the adjacent zyür.deriform tube sections and that each on one side of the annular gap attached to the associated cylindrical tube section, the annular gap in cylindrical extension sections (48 ', 55) which overlap from the inside are provided for each position of the radiant tube (45), which can be changed in curvature. 2. Beam deflection device according to claim 1, characterized in that each of the one cylindrical Pipe section (48) a cylindrical extension section (48 ') over the connection (50) with the adjacent lyre-shaped ring profile section (46) also, the Annular gap covered. 3. Beam deflector according to claim 2, characterized in that the one cylindrical Pipe section (48) at the point of its connection (50) with the cylindrical extension section (48 ') has a shoulder (52) so that the cylindrical pipe sections and the cylindrical Extension sections each lie on a common diameter. 4. Beam deflector according to claim 1 to 3 with a jet nozzle, which with its outer spherical cap-shaped Part pivotally mounted in a recess on the stationary beam guide tube is, characterized in that the curvature variable jet pipe (45) in an annular Recess (24 or 28) on the fixed jet guide (16) or the jet outlet nozzle (20) is used to form a transition beam guide surface (33).