TECHNICAL FIELD The invention relates to a wing leading-edge component, a wing having a fixed wing body and a wing leading-edge component, as well as an aircraft.

BACKGROUND OF THE INVENTION Aerodynamic components of an aircraft are designed to meet several aerodynamic requirements of the respective aircraft, which lead to a certain shape exposed to an airflow. For optimizing the weight of the aircraft, usually hollow structures are used, which are stiffened by an interior structure. For example, a leading edge of a flow body used in a commercial aircraft may comprise a skin and ribs attached to an interior side of the skin.

Besides the aerodynamic and weight requirements, also bird strike is a sizing scenario for leading-edge regions of a flow body of an aircraft. For example, it is known to provide a reinforcing panel structure on the leading-edge region to withstand impact to a great extent. A rupture of an outer skin of a flow body in the leading-edge region due to an impact should be avoided. For example, EP 3 318 481 A1 shows a panel structure for an aircraft having an improved impact resistance. SUMMARY OF THE INVENTION

It is an object of the invention to provide an alternate leading-edge component, which has improved impact characteristics for avoiding or delaying ruptures of a skin panel that is stiffened by an interior structure.

The object is met by a leading-edge component for an aircraft having the features of independent claim 1. Advantageous embodiments and further improvements can be gathered from the subclaims and the following description.

A leading-edge component for an aircraft is shown, comprising at least a part of a flow body having a front skin and a rib, wherein front skin comprises a top section, a bottom section and a leading edge arranged therebetween, wherein the rib extends from the bottom section to the top section, wherein the rib comprises a flange that at least partially surrounds the rib, wherein the flange is attached to an inner side of the front skin, and wherein the at least one peripheral surface extends from the contact surface inwardly into the flow body and away from the inner side of the front skin or encloses a weakened connection region with the contact surface for bending inwardly into the flow body upon an impact onto the front skin on or adjacent to the at least one peripheral surface.

The leading-edge component can be any component that is capable of being arranged at a leading edge of an aircraft. For example, it may be a fixed leading-edge component as a part of a wing, of a horizontal tail plane or of a vertical tail plane. However, it may also be a movable component, such as a leading-edge slat or similar, which is designed to move relative to a fixed part of the aircraft.

In the context of the invention, the flow body may be considered an aerodynamic body that has a leading edge, which is exposable to an air flow and which is designed according to the invention. Hence, the leading-edge component may comprise a part of the flow body, such as a part of a fixed leading edge of a wing, or it comprises the whole flow body, such as a movable surface exposed to an airflow.

The front skin may be based on a surface-like component that comprises a significant curvature about a spanwise axis to form an aerodynamically advantageous leading- edge region. For example, the front skin is curved about significantly more than 45°, for example at least 90°. In the course of this curvature, a leading edge separates a bottom section and a top section. The leading edge is a line that may be close to a stagnation point in a certain flight state, such as the cruise flight.

A rib is a stiffening component, which is usually arranged parallel to a chordwise axis of the leading-edge component, which may be parallel to the x-axis, i.e. the longitudinal axis of the aircraft or perpendicular to the sweep angle of the flow body. Objects that hit the leading edge of an aircraft may cause a deformation of the material at the leading edge. By providing a rib with the design proposed according to the invention, the front skin is capable of providing a guided, large and harmonic deformation. Hence, ruptures in the front skin directly adjacent to flanges of the rib or ruptures through a series of connection holes for rivets between the front skin and the flanges can be avoided to a large extent or at least distinctly delayed.

The contact surface of the flange may be a section of a circumferential surface of the flange. The at least one peripheral surface directly follows on from the contact surface and extends away from it in a lateral direction. In doing so, it may also extend away from the inner side of the front skin per se or upon an impact onto the front skin. A transition between the contact surface and the at least one peripheral surface may comprise a distinct edge or kink or it may be rounded. The at least one peripheral surface may, however, also comprise a curvature in a lateral direction. However, it may also have a flat outer surface, such as a stripe shape, that runs along the respective lateral delimitation of the contact surface. The at least one peripheral surface extends from the contact surface in the form of a chamfered edge. By providing the at least one peripheral surface that slightly extends away from the inner side of the front skin, a sharp edge as a lateral delimitation of the flange is avoided. Hence, if a foreign object impacts onto the skin near the rib, the front skin can fold along the at least one peripheral surface, instead of experiencing a distinct shearing force at an edge of the flange, which may lead to a rupture along the flange.

However, the peripheral surface may simply follow on the contact surface in a lateral direction, while a weakened connection region is provided between the peripheral surface and the contact surface. The connection region may be designed in a way that the peripheral surface bends inwardly into the respective flow body upon an impact.

It should, however, be designed to only bend if a sufficiently strong impact with a predetermined energy occurs. Hence, the flange may be simpler to manufacture, but also avoids a sharp edge between the contact surface and the front skin to avoid or delay ruptures.

In a preferred embodiment, a transition between the at least one peripheral surface and the contact surface is rounded. Thus, a sharp edge or kink is prevented and the front skin is more harmonically deformed in this region. It is advantageous if the peripheral surface is angled or curved away from the inner side of the front skin. Thus, the front skin is able to deform in a guided manner from the contact surface to lay down onto the at least one peripheral surface, wherein the depth of an occurring bulge into the interior side continuously increases. Advantageously, the peripheral surface and the contact surface enclose local angles of at least 10° and particularly of at least 20° at least in a region. Thus, the at least one peripheral surface is limited in the lateral dimension and provides a sufficient guiding function for a deforming front skin. Preferably, the flange comprises two peripheral surfaces, which are substantially mirror-inverted relative to each other. Hence, either side of the respective flange provides the advantageous function of avoiding or at least delaying a rupture of the front skin according to the invention. However, the peripheral surface of one side may be designed slightly different to conform an increase of a chordwise extension of the respective rib due to a sweep angle of the leading edge of the flow body or a tapering.

Furthermore, the flange may comprise a substantially constant thickness and is bent or curved to form the contact surface and the at least one peripheral surface. Hence, the flange may provide a rather large surface, which includes the contact surface and the at least one peripheral surface, with a least possible weight. The at least one peripheral surface may be realized in a separate part to be joined to a contact surface containing part, or at least the flange may be provided as a single part.

In an advantageous embodiment, the peripheral surfaces are created by removing of material from the flange through a material removal process. Thus, a wide variety of different shapes of the flange can be achieved. The material removal process may include cutting, milling, laser ablation or other.

Still further, an underside of the flange opposite to the contact surface and the at least one peripheral surface may be flat. Hence, given the at least one peripheral surface that extends away from the inner side of the front skin, the thickness of the flange decreases in a lateral direction. The flange thus tends to deform only in laterally outer regions, if at all.

According to a preferred embodiment, the at least one peripheral surface is designed to reduce a shear stress of the front skin upon impact of a moving object onto the front skin. Thus, the flange may comprise rounded edges and a harmonic transition from the contact surface to a laterally outward direction. The overall design of at least the at least one peripheral surface may be conducted under focusing on the shear stress behavior.

As an option, the component is designed to be a fixed component rigidly attachable to a structure. Such a component may for example be a fixed leading edge of a wing, a fixed leading edge of a horizontal tail plane or a fixed leading edge of a vertical tail plane. However, many other types of components are conceivable.

However, the leading-edge component may also be designed to be a movable component having a substantially closed surface. It may comprise a back skin arranged rearward of the front skin. For example, the movable component may be a leading-edge flap of a wing and thus a part of a high lift system. The component may be realized in the form of a droop nose, a slat or any other conceivable element. The invention further relates to a wing for an aircraft, having a leading-edge component according to the above description.

In an advantageous embodiment, the wing further comprises a fixed leading edge, wherein the leading-edge component is movable between a retracted position directly forward the fixed leading-edge and at least one extended position at a further distance to the fixed leading edge. As explained above, the leading-edge component may be a leading-edge flap, which is movable relative to a fixed leading edge of the wing. It may be a droop nose or a leading edge slat, which is capable of providing a translational and rotational motion.

The invention still further relates to an aircraft having at least one wing according to the above description or at least one leading-edge component according to the above description. The aircraft may preferably be a commercial aircraft, a transport aircraft or a military aircraft. It may comprise at least one turbofan or turboprop engine, leading to significant cruise speed and thus to higher expected impact speeds of foreign objects.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics, advantages and potential applications of the present invention result from the following description of the exemplary embodiments illustrated in the figures. In this respect, all described and/or graphically illustrated characteristics also form the object of the invention individually and in arbitrary combination regardless of their composition in the individual claims or their references to other claims.

Furthermore, identical or similar objects are identified by the same reference symbols in the figures.

Fig. 1 shows a first exemplary embodiment of a leading-edge component for an aircraft in a sectional view.

Fig. 2 shows a second exemplary embodiment of a leading-edge component for an aircraft in a section view. Fig. 3 and 4 show a third exemplary embodiment of a leading-edge component with a foldable connection region.

Fig. 5 shows an aircraft having at least one such leading-edge component. DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

Fig. 1 shows a section of a leading-edge component 2 for an aircraft. Here, the leading-edge component 2 comprises at least a part of a flow body 4 having a front skin 6 and a rib 8. The front skin 6 comprises a top section 10, a bottom section 12 and a leading edge 14 arranged therebetween. As apparent, the front skin 6 has a significant curvature and is stiffened by the rib 8, which extends from the bottom section 12 to the top section 10 and towards the leading edge 14.

The rib 8 comprises a flange 16, that at least partially surrounds the rib 8. It is attached to an inner side 18 of the front skin 6 and comprises a contact surface 20, which is directly coupled with the front skin 6. The flange 16 may be connected to the front skin 6 by connection means 22, such as rivets or bolts. In this example, two peripheral surfaces 24 are directly adjacent to both lateral sides of the contact surface 20 or the rib 8, respectively. They extend away from the contact surface 20 in a lateral direction and also extend away from the inner side 18 of the front skin 6.

This design leads to a guided deformation of the front skin 6 upon an impact of a foreign object. In Fig. 1, a deformation 26 is shown, which occurs due to the impact. The front skin 6 is deformed to lay onto the peripheral surface 24 in the drawing plane on the right. Hence, there is no sharp edge between the front skin 6 and the flange 16 that causes high shearing stress, which may lead to a rupture of the front skin 6. Instead, the deformation 26 has a more harmonic shape and experiences a reduced shearing stress. A region from a transition 28 between the contact surface 20 and the peripheral surfaces 24 as well as the peripheral surfaces 24 lead to a relaxation of the front skin 6 and a guided deformation 26 into the interior side 30 of the flow body 4.

Consequently, the absorption of impact energy is improved and ruptures may largely be avoided or at least delayed.

In this example, the flange 16 comprises a substantially constant thickness d and the peripheral surfaces 24 therefore appear as kinked or bent ends of the flange 16.

In Fig. 2, a leading-edge component 31 having a flange 32 is shown, which also has a contact surface 20, two peripheral surfaces 24, two connection means 22, and a flat underside 34 opposite to the contact surface and the peripheral surfaces 24. The flange 32 may be manufactured through a material removing process, such as milling or cutting. Based on a slightly bulkier cross-sectional profile, the peripheral surfaces 24 are created through cutting away comers 36. However, the deformation behavior of the front skin 6 is substantially the same as with the flange 16 in Fig. 1.

Fig. 3 and 4 show a further exemplary embodiment in the form of a leading-edge component 37. Here, a flange 38 is provided, which comprises a contact surface 20, two connection means 22 and a peripheral surface 40, which encloses a weakened connection region 42 with the contact surface 20. Hence, upon impact of a foreign object onto the front skin 6, the peripheral surface 40 may deform, i.e. fold, relative to the contact surface 20. From a flush alignment of the paraffin so face 40 and the contact so face 20, a similar arrangement of the peripheral surface 40 and the contact surface 20 as shown in Fig. 1 can be achieved. The folding process already absorbs a part of the impact energy and also distinctly guides the deformation 26 into the interior side 30 of the flow body 4.

Fig. 5 shows an aircraft 44 having wings 46, a horizontal tail plane 48, a vertical tail plane 50 and engines 52. Each of these elements may comprise a leading-edge component 2, 31 or 37 according to the previous illustrations.

In addition, it should be pointed out that“comprising” does not exclude other elements or steps, and“a” or“an” does not exclude a plural number. Furthermore, it should be pointed out that characteristics or steps which have been described with reference to one of the above exemplary embodiments may also be used in combination with other characteristics or steps of other exemplary embodiments described above. Reference characters in the claims are not to be interpreted as limitations. REFERENCE NUMERALS

2 leading-edge component

4 flow body

6 front skin

8 rib

10 top section

12 bottom section

14 leading edge

16 flange

18 inner side

20 contact surface

22 connection means

24 peripheral surface 26 deformation

28 transition

30 interior side

31 leading-edge component

32 flange

34 underside

36 corner

37 leading-edge component

38 flange

40 peripheral surface 42 connection region

44 aircraft

46 wing

48 horizontal tail plane

50 vertical tail plane 52 engine d thickness of flange