The present invention relates to an arrangement for passing a line in a load-free manner through a pressure frame of a fuselage of an aircraft or spacecraft, a fuselage for an aircraft or spacecraft having an arrangement of this type and an aircraft or spacecraft having an arrangement of this type or having a fuselage of this type.

Although applicable to any aircraft or spacecraft, the present invention will be described in greater detail by way of example with reference to an aircraft.

During the flight phase of the aircraft, an internal pressure is usually applied to the passenger cabin thereof, which internal pressure is above the external atmospheric pressure. For this purpose, the passenger cabin must be constructed in a pressure-tight manner. This is achieved in particular by means of a pressure frame arranged in the tail region of the aircraft. The pressure frame separates, for example, the pressurised passenger cabin from an unpressurised or lightly pressurised fuselage portion.

EP 0 847 916 B1 accordingly discloses a pressure frame in the shape of a dome, in particular at the tail-end termination of the pressurised region of an aircraft fuselage, an annular frame being provided to receive annular forces in particular, the annular frame being formed by the edge of the dome, in such a way that the edge having a transition region having the internal radius of curvature is turned up at an acute angle in the direction of the fuselage tail in such a way that it fits tightly against the inside of the fuselage structure in a peripheral contact strip having a predetermined width.

DE 39 23 871 C2 also discloses a pressure frame made of fibre composite material for an aircraft having a pressure fuselage, the pressure frame comprising a dome shape which transitions at the edge into a shape corresponding to the aircraft. In the edge region the pressure frame is reinforced by the integration of further fibre layers, and rigid fibre material can preferably be used here.

In an aircraft having a pressure frame, it is necessary to pass lines, in particular fuel lines, from the pressurised region of the fuselage into the pressure-free region and vice versa, and in this case maintain the prevailing pressure difference between the fuselage regions. For example, a fuel line must be passed from a central wing box of the aircraft to an auxiliary energy unit, such as an auxiliary gas turbine, which is normally arranged in the tail region of the aircraft, or to tail-end trimming tanks of the aircraft. To do this, it is necessary to pass the fuel line through the pressure frame arranged at the tail end. It is operatively known to the applicant to pass the fuel line through the pressure frame by means of a suitable arrangement for passing the fuel line through. The pressure frame comprises an opening for this purpose, in which a sleeve is arranged which is sealed against the opening by means of an O-ring. The fuel line is passed through the sleeve and is sealed against the sleeve by means of a further O-ring. An axial displacement of the line and a rotation of the line relative to the pressure frame are therefore possible. It has however proved disadvantageous that, owing to the lack of mechanical decoupling of the line from the pressure frame in the case of deformations of the pressure frame or the surrounding fuselage structure, an unacceptably high mechanical loading of the fuel tine is reached, as a result of which, for example, leakages in a line system of the aircraft can occur. This is obviously to be avoided.

It is therefore an object of the present invention to provide an improved arrangement for passing a line in a load-free manner through a pressure frame of a fuselage of an aircraft or spacecraft, which arrangement eliminates the above-mentioned disadvantages.

This object is achieved according to the invention by an arrangement having the features of claim 1 , a fuselage having the features of claim 14 and/or an aircraft or spacecraft having the features of claim 15.

An arrangement is accordingly provided for passing a line in a toad-free manner through a pressure frame of a fuselage of an aircraft or spacecraft, comprising: an opening penetrating the pressure frame, through which opening the line is passed, the line being mechanically decoupled from the pressure frame; and a flexible sealing device arranged outside the opening, at least in portions, which device is simultaneously operatively connected to the line and the pressure frame for pressure-tight separation of a first side from a second side of the pressure frame.

A fuselage for an aircraft or spacecraft having an arrangement of this type and an aircraft or spacecraft having an arrangement of this type or having a fuselage of this type are also provided. The idea on which the present invention is based consists in providing an arrangement which allows the line to be passed through the pressure frame in such a way that the line is mechanically decoupled from the pressure frame. It is hereby possible to reliably prevent mechanical loading of the line, even in the case of severe deformation and/or deformation of varying severity of the fuselage structure and/or of the pressure frame owing to flight loads and/or loads resulting from the pressurisation of the pressure frame. The occurrence of leakages in a line system of an aircraft or spacecraft can thus be prevented by an arrangement of this type, as a result of which the reliability of an aircraft of this type is increased.

Advantageous configurations and improvements of the arrangement specified in claim 1 are found in the sub-claims.

According to a preferred embodiment, the sealing device is formed in one piece. This ensures a particularly simple, economical and easy-to-assemble construction of the arrangement.

According to a preferred embodiment, a predetermined air gap is arranged between an edge of the opening and the line in order to achieve free movability of the line in the opening. Axial and radial movability of the line in the opening is hereby advantageously ensured, as a result of which the line is mechanically decoupled from the pressure frame at all times.

According to a further preferred embodiment, the sealing device is constructed as a bellows. The sealing device can thus be deformed particularly easily and without transmitting forces to the line.

According to a further preferred embodiment, the sealing device is arranged on the first side of the pressure frame. There is preferably a higher pressure on the first side of the pressure frame than on the second side of the pressure frame. There is thus an overpressure on the outside of the sealing device at all times, as a result of which an excessive expansion of the sealing device and possible damage thereto as a result is reliably prevented.

According to a further preferred embodiment, the sealing device has approximately a truncated cone shape having a first end-face flange portion and a second end-face flange portion, the sealing device in particular tapering, starting from the second end-face flange portion, towards the first end-face flange portion. A cross-sectional difference from the opening towards the line can hereby advantageously be bridged without the use of additional construction elements.

According to a further preferred embodiment, the line comprises a first coupling device assigned to the first, in particular pressurised, side of the pressure frame, and a second coupling device assigned to the second, in particular unpressurised, side of the pressure frame. A modular construction of a line system of the aircraft or spacecraft is hereby advantageously ensured, as a result of which individual components of the line system can be conveniently replaced.

According to a further preferred embodiment, the first coupling device is fixed to a first structural element of the fuselage, which structural element is assigned to the first side of the pressure frame, and a second coupling device is fixed to the second structural element assigned to the second side of the pressure frame. A reliable positioning of the line relative to the pressure frame is hereby ensured. The line thus moves together with the load-bearing structural elements of the fuselage.

According to a further preferred embodiment, the sealing device is fixed to the first coupling device of the line, as a result of which the assembly effort required to assemble the sealing device is reduced.

According to a further preferred embodiment, the arrangement comprises a flange which surrounds the opening, extends out from the pressure frame and is in particular tubular. A simple and convenient assembly of the sealing device is hereby ensured, the device being operatively connected only to the projecting flange for assembly on the pressure frame.

According to a further preferred embodiment, the flange extends out from the pressure frame on the first side thereof, as a result of which the flange is advantageously only minimally deformed in the case of a bending deformation of the pressure frame.

According to a further preferred embodiment, the sealing device is fixed to an end portion of the flange. A simple assembly of the sealing device by sliding the sealing device onto the end portion is hereby ensured. According to a further preferred embodiment, the line is formed as a fuel line, as a result of which the arrangement advantageously ensures a leakage-free fuel supply of an aircraft or spacecraft having an arrangement of this type.

The invention is described in further detail in the following by way of embodiments with reference to the appended schematic figures of the drawings.

In the figures:

Fig. 1 is a sectional view of a preferred embodiment of an arrangement for passing a line in a load-free manner through a pressure frame of a fuselage of an aircraft or spacecraft;

Fig. 2 is a perspective view of the arrangement according to Fig. 1; and

Fig. 3 is a further perspective view of the arrangement according to Fig. 1.

In the figures, like reference numerals denote like or functionally equivalent components, unless stated otherwise.

Fig. 1 to 3, which are referred to simultaneously in the following, illustrate a preferred embodiment of an arrangement 1 for passing a line 2 in a load-free manner through a pressure frame 3 of a fuselage 4, in particular a fuselage airframe 4, of an aircraft or spacecraft 5. The fuselage 4 is preferably formed using a fibre-reinforced plastics material, in particular using a carbon-fibre-reinforced plastics material. The fuselage 4 can comprise a metal material. This material can be flexibly deformed by mechanical loads which act on the fuselage 4 during operation of the aircraft or spacecraft 5. A longitudinal direction of the fuselage 4 is denoted by x, a transverse direction by y and a vertical direction by z.

The line 2 is preferably formed as a fuel line 2 of the aircraft or spacecraft 5. The line 2 can also be formed as an electrical or mechanical supply line 2. The line 2 is in particular formed as a double-walled line 2 having an inner wall 6 and an outer wail 7 which concentrically surrounds the inner wall 6. The inner wall 6 preferably has a tubular cross-section through which fuel is conveyed. An intermediate space 8, in particular an intermediate space 8 filled with air, is provided between the inner wall 6 and the outer wall 7. The intermediate space 8 can be filled with a gas other than air, for example with an inert gas. The intermediate space 8 can also be drainable. The walls 6, 7 can be formed using a fibre-reinforced plastics material and/or a metal material. The line 2 preferably comprises a first end-face coupling device 9 and a second end-face coupling device 10. The line 2 is operatively connected to a line system 31 of the aircraft or spacecraft 5 in a detachable manner by means of the coupling devices 9, 10. The coupling devices 9, 10 are for example formed as detachable quick couplings 9, 10.

The pressure frame 3, also referred to as a pressure dome 3 or pressure bulkhead 3, preferably divides an interior 32 of the fuselage 4 in the x-direction into at least a first fuselage portion 11 and a second fuselage portion 12. The first fuselage portion 1 1 is for example formed as a passenger cabin 11 of the aircraft or spacecraft 5. The second fuselage portion 12 can be an unpressurised region 12 of the aircraft or spacecraft 5. A first side 13 of the pressure frame 3 preferably faces towards the first fuselage portion 11 and a second side 14 of the pressure frame 3 preferably faces towards the second fuselage portion 12. The pressure frame 3 is preferably curved convexly towards the second side 14. When viewed from the second fuselage portion 12, the pressure frame 3 is in particular curved convexly into said fuselage portion. The pressure frame 3 preferably has an approximately watch-glass shape. Air pressure, in particular artificially produced air pressure, is preferably applied to the first fuselage portion 1 1 and the first side 13 of the pressure dome. The second fuselage portion 12 and the second side 14 of the pressure frame 3 are preferably unpressurised, that is to say an artificially produced overpressure preferably does not prevail in the second fuselage portion 12. The second fuselage portion 12 is for example under atmospheric pressure. An air-pressure difference preferably prevails between the first side 13 and the second side 14 of the pressure frame 3. The pressure frame 3 is preferably peripherally operatively connected to the fuselage 4 or to load-bearing structures of the fuselage 4. For this purpose, the pressure frame 3 can comprise a peripheral annular frame which is connected to the fuselage 4. The pressure frame 3 can be formed integrally with the fuselage 4, in particular with a fuselage skin. For example, the pressure frame 3 is formed using a fibre-reinforced plastics material, in particular a carbon- fibre-reinforced plastics material. The pressure frame 3 can comprise a metal material, such as an aluminium material. The pressure frame 3 absorbs loads resulting from the pressurisation of the first fuselage portion 11 and flight loads occurring during operation of the aircraft or spacecraft 5. The pressure frame 3 can hereby be flexibly deformed. The pressure frame 3 further comprises an opening 15 penetrating therethrough and comprising an edge 16, in particular a peripheral edge. The opening 5 is preferably circular. Alternatively, the opening 15 can for example be rectangular or elliptical. The opening 15 connects the fuselage portions 1 1 , 12 to one another. The line 2 is passed through the opening 15. The line 2 is preferably mechanically decoupled from the pressure frame 3 in this case. In particular, the line 2 is passed through the opening 15 without contact therewith. In order to achieve free movability of the line 2 in the opening 15, a predetermined air gap 17 is arranged between the line 2 and the edge 16 of the opening 15. The line 2 can move in the opening 15, preferably in the x-, y- and/or x-direction. The air gap 17 preferably completely surrounds the line 2 and ensures at all times that the line 2 is mechanically decoupled from the pressure frame 3. A thickness d of the air gap 17, which is preferably measured starting from the outer wall 7 to the edge 16, is formed in such a way that the line 2 does not contact the edge 16 even in the case of severe deformations and/or deformations of varying severity of the fuselage 4 and/or the pressure bulkhead 3, as a result of which mechanical decoupling of the line 2 from the pressure frame 3 is ensured at all times.

The line 2 is preferably fixed to a structural element 18 of the fuselage 4 using the first coupling device 9, which is in particular assigned to the first side 13 of the pressure frame 3. A fixing element 34 which operatively connects the structural element 18 and the coupling device 9 can be provided for this purpose. The structural element 18 is for example a crossbar 8 of the fuselage 4. The second coupling device 10 of the line 2, which is preferably assigned to the second side 14 of the pressure frame 3, is preferably fixed to a further structural element 19. The further structural element 19 is for example a so-called A- bracket 19 of the fuselage 4. An A-bracket is a bracket connected to load-bearing elements of the fuselage 4. The line 2 is thus mounted on the two structural elements 18, 19 and passed through the pressure frame 3 by means of the opening 15. The line 2 is thus preferably decoupled from movements and/or deformations of the pressure frame 3. The line 2 can be mounted on the structural elements 18, 19 or on one of the structural elements 18, 19 in the form of a movable mounting, that is to say, for example, so as to be displaceable in the x-direction.

The arrangement 1 preferably comprises a sealing device 20, which is in particular flexible, is arranged outside the opening 15 at least in portions and is preferably simultaneously operatively connected to the line 2 and to the pressure frame 3 for the pressure-tight separation of the first side 13 from the second side 14 of the pressure frame 3. The sealing device 20 preferably separates the fuselage portions 11 , 12 from one another in a pressure- tight manner. The sealing device 20 is in particular formed in one piece. The sealing device 20 is preferably formed using a rubber-elastic material, such as a rubber material and/or silicone material. The sealing device 20 can be fibre-reinforced and/or formed as fibrous tissue. For example, the sealing device 20 is formed as a bellows 20. The sealing device 20 is preferably arranged on the first side 13, that is to say on the pressurised side 13, of the pressure frame 3. The sealing device 20 preferably projects into the first fuselage portion 11. In particular, the sealing device 20 allows the line to move in the opening 15 in an x-, y-, and/or z-direction. In the case of a displacement of the line 2 in the x-direction relative to the pressure frame 3, the sealing device 20 can be displaced in the opening 15, at least in part. This allows the greatest possible axial displaceability of the line 2 in the x-direction relative to the pressure frame 3. The preferably flexible configuration of the sealing device 2 also ensures movability of the line 2 relative to the edge 16 of the opening 15 in the y- and z- directtons at ail times.

The sealing device 20 preferably has approximately a truncated cone shape comprising a first end-face flange portion 21 and a second end-face flange portion 22. The sealing device 20 preferably tapers starting from the second end-face flange portion 22 towards the first end-face flange portion 21. The sealing device 20 is preferably fixed to the first coupling device 9 of the line 2. In particular, the first end-face flange portion 21 of the sealing device 20 is fixed to the first coupling device 9 and/or the first structural element 8 by means of two clamps 23, 24, arranged with axial spacing from one another. The flange portion 21 preferably surrounds the line 2 and/or the coupling device 9 in such a way that a pressure- tight operative connection is produced therebetween. The second end-face flange portion 22 of the sealing device 20 is preferably operatively connected to the pressure frame 3.

The arrangement 1 comprises in particular a preferably tubular flange 25 which surrounds the opening 15 and extends out from the pressure frame 3. The flange 25 extends for example from the first side 13 of the pressure frame 3 towards the first fuselage portion 11 and has in particular a leading edge which is oriented approximately parallel to the z- direction. The flange 25 is preferably formed as an A-bracket 25. The flange 25 in particular comprises a contact portion 26 which preferably rests on the surface of the pressure frame 3 in a planar manner. The contact portion 26 can rest on the first side 13 of the pressure frame 3. The contact portion 26 is preferably connected to the pressure frame 3, for example by means of a rivet connection which comprises a large number of rivets 33. The contact portion 26 can alternatively or additionally be screwed, glued or connected in any way to the pressure frame 3. A seal can be provided between the contact portion 26 and the pressure frame 3. Alternatively, the contact portion 26 can be formed integrally with the pressure frame 3. A centre axis 27 of the flange 25 extends preferably approximately parallel to the x- direction. The sealing device 20 is preferably fixed to an end portion 28 of the flange 20. The second end-face flange portion 22 of the sealing device 20 is preferably mounted on the end portion 28 of the flange 25 by means of two clamps 29, 30. The flange portion 22 of the sealing device 20 can be glued to the end portion 28. The end portion 28 can have a peripheral protrusion on the outside, which protrusion is operatively engaged with the flange portion 22 in order to fix this flange portion in the x-direction. The flange portion 22 preferably surrounds the end portion 28 of the flange 25 in such a way that a pressure-tight connection is produced therebetween.

By means of the arrangement 1 it is possible to pass the line 2, which is fixed to corresponding structural elements 18, 19 of the fuselage 4 by means of the coupling devices 9, 10, in a load-free manner through the opening 15 of the pressure frame. In this case, the line 2 is mechanically decoupled from the pressure frame 3 at all times, as a result of which no unwanted loads are transferred to the line 2. Mechanical loading of the coupling devices 9, 10 is thus prevented, as a result of which the danger of a leak occurring in the line system 31 of the aircraft or spacecraft is avoided or at least reduced.

The materials, numerical data and dimensions given are to be understood as examples and merely serve to illustrate the embodiments and developments of the present invention.

It is obviously also possible to use the invention in other fields, in particular in vehicle construction or shipbuilding.

List of reference numerals

1 arrangement

2 line

3 pressure frame

4 fuselage

5 aircraft or spacecraft

6 inner wall

7 outer wall

8 intermediate space

9 coupling device

10 coupling device

11 fuselage portion

12 fuselage portion

13 side

14 side

15 opening

16 edge

17 air gap

18 structural element

19 structural element

20 sealing device

21 flange portion

22 flange portion

23 clamp

24 clamp

25 flange

26 contact portion

27 centre axis

28 end portion

29 clamp

30 clamp

31 line system

32 interior

33 rivet fixing element thickness