DE102010007665A1 - Discharge nozzle for a jet engine - Google Patents

Abstract

The exhaust nozzle (2) has a centrally arranged sliding cone (13) to change the nozzle cross-section, where an extension tube is provided to guide the sliding cone. A drive device (15) is provided for axial adjustment of the sliding cone relative to the nozzle opening (3). The drive device is arranged for axial adjustment of sliding cone relative to the nozzle opening in the engine axis (4).

Description

The invention relates to a discharge nozzle for a jet engine with a centrally arranged sliding cone for changing the nozzle cross-section, with an extension tube for guiding the Gleitkonus and with a drive device for the axial adjustment of the Gleitkonus relative to the nozzle opening.

The change in the nozzle cross-section is advantageous for different flight conditions of an aircraft equipped with the jet engine, in order, for. B. to increase the thrust or reduce the engine noise. When the slide cone is retracted, the nozzle cross section has its maximum size and the gas velocity is low. When the slide cone is fully extended, the nozzle cross section has its minimum size and the gas velocity is maximum. Thus, by axial adjustment of the Gleitkonus for the purpose of enlarging the nozzle cross-section of the engine noise can be reduced. The nozzle cross-section is increased to reduce noise. If, however, the nozzle cross-section is reduced, the jet engine receives z. B. for the starting phase a greater thrust performance. The change of the nozzle cross-section can also be done to relieve the fan (flutter margin).

One from the textbook "The JET ENGINE" of Rolls-Royce Limited, Edition 1969, page 51, Figure 6-4 Known exhaust nozzle of this type comprises a provided with a directed into the inside of the thrust nozzle cylindrical collar drop-shaped Gleitkonus, which is axially reciprocally movable by means of the collar in the nozzle opening on a fixed tubular extension. The drive device for the axial adjustment of the Gleitkonus relative to the nozzle opening consists of a arranged in the tubular extension, the Gleitkonus actuated push rod, a substantially transverse to the axis of the engine and thus arranged transversely to the tubular extension lever arm, acts on the inner end of the push rod, and a drive acting on the outer end of the lever arm, arranged on the outside of the exhaust nozzle drive in the form of a cylinder piston unit. A housing for receiving the lever arm and the push rod extends on the inside of the exhaust nozzle transversely through the outlet cross section of the nozzle opening and is provided with the tubular extension on which the sliding cone slides with its cylindrical collar. The disadvantage here is the housing of the drive device serving housing, which is arranged in the hot exhaust gas flow and thus causes losses of thrust due to the resulting air friction and air turbulence. Furthermore, an increased material and space requirements are required, and it also results in an increased weight.

The invention is therefore based on the object structurally simplify the drive device for the Gleitkonus the exhaust nozzle and to avoid losses of thrust of the exhaust nozzle of a jet engine.

To solve this problem, the invention provides that the drive device is arranged for axial adjustment of the Gleitkonus relative to the nozzle opening in the engine axis. As a result, a disturbance of the gas flow within the exhaust nozzle is avoided and the drive device can be structurally simpler and lighter in weight.

In a further embodiment of the invention, it is provided that the extension tube is fixedly connected to the slide cone and axially displaceably mounted in the engine axis and that the drive device for the extension tube and the slide cone has a arranged in the extension tube drive. This embodiment allows a structurally particularly simple and lightweight design. The diameter of the extension tube corresponds to the largest diameter of the Gleitkonus.

In a further embodiment of the invention, a thrust nozzle with a centrally located in the engine exhaust cone is provided that the axially displaceable extension tube of the Gleitkonus is performed in the engine axis to the fixed engine exhaust cone in the engine. As a result, any disturbance of the exhaust flow in the exhaust nozzle is avoided because there are no losses of thrust due to air friction and Luftverwirbelungen. Also, a significant weight reduction can be achieved.

In a preferred embodiment of the invention it is provided that the drive device for the extension tube of the Gleitkonus a the extension tube surrounding and fixed in the exhaust cone outer working cylinder, concentrically and firmly mounted in this inner tube and at a distance from each other on the inner circumference of the extension tube fixedly arranged on the Having outer circumference of the concentric inner tube sliding working piston. As a result, the extension tube of the Gleitkonus between the outer cylinder and the concentric and firmly mounted inner tube is axially guided so sure that the extension tube and arranged at the end of the sliding cone are not excited to undue vibrations.

Furthermore, it is provided in this embodiment that the drive device arranged in the inner tube control piston assembly for axially extending and retracting the extension tube and having fixedly connected to this Gleitkonus for changing the cross section of the nozzle opening.

In this embodiment, it is provided that the control piston assembly a in a control cylinder movable, movable by an electric coil assembly against a spring assembly, two passages and two closing piston having control piston and connecting lines for supplying compressed air from the engine to one of two inlets in one between the working cylinder and the inner tube formed pressure chamber.

The invention is explained in more detail below with reference to a preferred embodiment of a discharge nozzle for a jet engine with a slide cone and with a displaceable extension tube.

It shows:

1 a partial longitudinal section through the drive nozzle of the jet engine with the Gleitkonus in the retracted position,

2 the partial longitudinal section after 1 with the sliding cone in the extended position,

3 the detail AE 1 with the exhaust pipe of the jet engine penetrating extension tube,

4 the detail AD off 1 with the outlet opening of the sliding cone,

5 the detail AB off 1 with the drive for the extension tube located in the retracted position,

6 the detail AC off 1 with the right end portion of the drive in the retracted position of the extension tube,

7 the detail BB off 2 with the drive for the extension tube located in the extended position,

8th the detail BC off 2 with the right end portion of the drive in the extended position of the extension tube.

In the 1 in a partial longitudinal section through the engine nacelle 1 a jet engine for an aircraft illustrated exhaust nozzle 2 includes a nozzle opening 3 with an outlet or nozzle cross section shown in dashed lines, one centric to the engine axis 4 arranged exhaust cone 5 and a mixer 8th in the radial circumferential nozzle channel 6 between the exhaust cone 5 and the outer wall 7 of the nozzle channel 6 for the shower mixture of the cold and warm exhaust gas flows 9 respectively. 10 that as nozzle flow 11 from the nozzle opening 3 escape. The direction of flight of the aircraft is with the arrow 12 designated.

Centric to the engine axis 4 is in the nozzle opening 3 one to the nozzle opening 3 pointed taper cone 13 arranged at the end of an extension tube 14 is attached and its tip with an outlet opening 17 for outgoing, used compressed air ( 4 ) is provided. The diameter D of the extension tube 14 corresponds to the largest diameter D of the sliding cone 13 , The axially displaceable extension tube 14 the sliding cone 13 is in the engine axis 4 to the fixed in the jet engine exhaust cone 5 guided and is by a drive device 15 operated, for the axial adjustment of the Gleitkonus 13 relative to the nozzle opening 3 in the engine axis 4 is arranged.

The extension tube 14 is with the sliding cone 13 firmly connected and in the engine axis 4 mounted axially displaceable. The drive device 15 for the extension tube 14 and the sliding cone 13 has one in the extension tube 14 and inside the exhaust cone 5 arranged drive 20 ( 5 ) on.

The 1 shows the sliding cone 13 in the retracted position, in which the cross section of the nozzle opening 3 reaches its maximum size and the exhaust gas velocity of the exiting nozzle flow 11 is low.

The 2 shows the sliding cone 13 in the fully extended position, in which the cross section of the nozzle opening 3 has its minimum size and the gas velocity of the exiting nozzle flow 11 becomes maximum. Through stepless axial adjustment of the sliding cone 13 by means of this permanently connected extension tube 14 may be the cross section of the nozzle opening 3 over the drive device 15 and the drive 20 be adjusted.

The 3 shows as a detail AE 1 the passage of the extension tube 14 through the free end 16 the central exhaust cone 5 , on the lateral surface 19 of the extension tube 14 sealingly rests.

The 4 shows as a detail AD 1 the passage of the in the drive device 15 in the interior 52 released compressed air according to arrow 18 from the exit opening 17 at the free end of the slide cone 13 ,

In the 5 and 6 as details AB or AC off 1 illustrated drive device 15 for the extension tube 14 the sliding cone 13 has an extension tube 14 closely embracing and in the exhaust cone 5 fixed outer working cylinder 21 , in this concentrically and firmly stored inner tube 22 and two spaced apart on the inner circumference 23 of the extension tube 14 firmly arranged, on the outer circumference 24 of the concentric inner tube 22 sliding power pistons 25 . 26 on. These are according to 5 in the retracted position of the extension tube 14 or the sliding cone 13 up to the in 5 Bottom left cylinder base 37 of the working cylinder 21 and according to 8th in the extended position of the extension tube 14 or the sliding cone 13 up to the cylinder bottom shown on the right 38 of the working cylinder 21 method. The two working pistons 25 . 26 are arranged at an axial distance X from each other and formed annular disk-shaped.

The working cylinder 21 and the associated inner tube 22 are concentric with each other and concentric with the engine axis 4 arranged and form between them a circular cylindrical piston chamber 46 made of, at both ends of the circular cylindrical cylinder bottoms 37 respectively. 38 having. Between the right hand piston crown 38 and the working cylinder 21 is according to 6 a slot 39 to the passage of the extension tube 14 educated.

For retracting and extending the sliding cone 13 from the nozzle opening 3 has the drive device 15 the drive 20 with one in the inner tube 22 arranged control piston assembly 27 on, by means of which the two working pistons 25 and 26 and with it the extension tube 14 with attached slide cone 13 for changing the cross section of the nozzle opening 3 be operated. The essentially from the control piston arrangement 27 existing drive 20 is in the inner tube 22 near the engine axis 4 arranged.

The spool assembly 27 has one in a control cylinder 28 sliding, from an electrical coil assembly 29 against a spring arrangement 30 movable control piston 31 on. This includes three passes 32 . 33 . 34 , which by radial circumferential cut-outs in the control piston 31 are formed, and two closing pistons 35 . 36 passing through the full, in the control cylinder 28 sliding cross-section of the control piston 31 are formed.

A pressure line 40 leads compressed air from the compressed air system of the jet engine according to the arrow 41 the spool assembly 27 of the drive 20 to. In accordance with 5 by means of the coil arrangement 29 against the force of the spring assembly 30 to the right moved spool 31 the compressed air is passing through the passage 32 through according to the arrows 42 . 43 . 44 through a to the pressure line 40 connected further pressure line 45 to the right arranged cylinder bottom 38 of the annular piston chamber 46 between the working cylinder 21 and the inner tube 22 fed. By means of the so from the outer, right cylinder bottom 38 according to the arrows 56 Pressing compressed air to the left are the two working pistons at a distance X 25 . 26 against the inner, left cylinder bottom 37 of the working cylinder 21 pressed so that the sliding cone 13 by means of the extension tube 14 is in its retracted position ( 1 ).

The 7 and 8th show the state of the drive device 15 together with drive 20 in accordance with 2 by means of the extension tube moved to the right 14 extended sliding cone 13 , After a reversal of the control piston 31 under the effect of the coil arrangement 29 and the spring assembly 30 locked the closing piston 35 the compressed air the way in the right piston bottom 38 of the piston chamber 46 leading pressure line 45 , At the same time the passage 33 opened for the compressed air, then according to the arrows 47 . 48 . 49 and another pressure line 53 to the cylinder bottom 37 at the left, inner end of the piston chamber 46 is fed to the working piston 25 . 26 to the right piston bottom 38 at the right, outer end of the piston chamber 46 to move, leaving the extension tube 14 move to the right and thus the sliding cone 13 from the nozzle opening 3 be moved out.

In both cases, it is provided that when moving the working piston 25 . 26 displaced air from the piston chamber 46 can escape. According to 5 this is done by displacing the air according to the dashed arrows 50 . 51 through the pressure line 53 and the second passage 33 of the control piston 31 in the interior 52 of the extension tube 14 , According to 7 this is done by displacing the air according to the dashed arrows 54 . 55 through the pressure line 45 and the third passage 34 of the control piston 31 also in the interior 52 of the extension tube 14 , From the interior 52 can air according to detail AD in 4 in the direction of the arrow 18 through the exit opening 17 at the free end 16 the sliding cone 13 escape.

LIST OF REFERENCE NUMBERS

1

Engine nacelle

2

exhaust nozzle

3

nozzle opening

4

Engine axis

5

exhaust cone

6

nozzle channel

7

Wall, outer

8th

mixer

9

Exhaust gas flow, cold

10

Exhaust gas flow, warm

11

nozzle flow

12

arrow

13

Gleitkonus

14

extension tube

15

driving device

16

free end

17

output port

18

arrow

19

lateral surface

20

drive

21

working cylinder

22

inner tube

23

inner circumference

24

outer periphery

25

working piston

26

working piston

27

Control piston assembly

28

control cylinder

29

coil assembly

30

spring assembly

31

spool

32

passage

33

passage

34

passage

35

closing piston

36

closing piston

37

cylinder base

38

cylinder base

39

slot

40

pressure line

41

arrow

42

arrow

43

arrow

44

arrow

45

pressure line

46

piston chamber

47

arrow

48

arrow

49

arrow

50

arrow

51

arrow

52

inner space

53

pressure line

54

arrow

55

arrow

56

arrow

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• "The JET ENGINE" of Rolls-Royce Limited, Edition 1969, page 51, Figure 6-4 [0003]

Claims (7)

Discharge nozzle for a jet engine with a centrally arranged sliding cone for changing the nozzle cross-section, with an extension tube for guiding the slide cone and with a drive device for axial displacement of the slide cone relative to the nozzle opening, characterized in that the drive device ( 15 ) for the axial adjustment of the sliding cone ( 13 ) relative to the nozzle opening ( 3 ) in the engine axis ( 4 ) is arranged. A thruster according to claim 1, characterized in that the extension tube ( 14 ) with the sliding cone ( 13 ) and in the engine axle ( 4 ) is mounted axially displaceable and that the drive device ( 15 ) for the extension tube ( 14 ) and for the sliding cone ( 13 ) in the extension tube ( 14 ) arranged drive ( 20 ) having. A thruster according to claim 2, characterized in that the diameter (D) of the extension tube ( 14 ) the largest diameter (D) of the sliding cone ( 13 ) corresponds. Discharge nozzle according to one of claims 2 or 3 with a centrally arranged in the jet engine exhaust cone ( 5 ), characterized in that the axially displaceable extension tube ( 14 ) of the sliding cone ( 13 ) in the engine axis ( 4 ) into the exhaust gas cone fixedly arranged in the jet engine ( 5 ) is guided. Discharge nozzle according to one of claims 1 to 4, characterized in that the drive device ( 15 ) for the extension tube ( 14 ) of the sliding cone ( 13 ) an extension tube ( 14 ) and in the exhaust cone ( 5 ) fixedly arranged outer working cylinder ( 21 ), in this concentrically and firmly stored inner tube ( 22 ) and at a distance from each other on the inner circumference ( 23 ) of the extension tube ( 14 ) fixedly arranged, on the outer circumference ( 24 ) of the concentric inner tube ( 2 ) sliding working pistons ( 25 . 26 ) having. The exhaust nozzle according to claim 5, characterized in that the drive device ( 15 ) one in the inner tube ( 22 ) arranged control piston assembly ( 27 ) for the axial extension and retraction of the extension tube ( 14 ) and of the fixedly connected thereto Gleitkonus ( 13 ) for changing the outlet cross-section of the nozzle opening ( 3 ) having. A discharge nozzle according to claim 6, characterized in that the control piston arrangement ( 27 ) one in a control cylinder ( 28 ) slidable from a coil assembly ( 29 ) against a spring arrangement ( 30 ) movable, passages ( 33 . 34 ) and closing piston ( 35 . 36 ) having control piston ( 31 ) and pressure lines ( 40 ; 45 . 53 ) for supplying compressed air from the jet engine to one of two inlets in one between the working cylinder ( 21 ) and the inner tube ( 22 ) formed piston space ( 46 ) having.

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