阅读说明：本技术 飞行器的机翼 (Wing of an aircraft ) 是由 伯恩哈德·施利普夫 弗洛里安·洛伦兹 斯蒂芬·本斯曼 达斯汀·沙皮 于 2018-04-26 设计创作，主要内容包括：本发明涉及一种飞行器(1,参见图1)的机翼(3,参见图1),所述机翼包括主机翼(5,参见图1)、缝翼(7,参见图1)、以及连接组件(9,参见图1),所述连接组件用于将所述缝翼(7,参见图1)可移动地连接至所述主机翼(5,参见图1),其中,所述连接组件(9,参见图1)包括长形缝翼轨道(17),其中,所述缝翼轨道(17)的前端部(21)安装至所述缝翼(7,参见图1),其中,所述缝翼轨道(17)的后端部(23)和所述中间部分(25)通过滚轮支承件(27)安装至所述主机翼(5,参见图1),所述滚轮支承件包括安装至所述主机翼(5,参见图1)的引导导轨(29)以及第一滚轮单元(31),所述第一滚轮单元安装至所述缝翼轨道(17)的后端部(23)、并且与所述引导导轨(29)相接合,并且其中,所述滚轮支承件(27)包括第二滚轮单元(33),所述第二滚轮单元安装至所述主机翼(5,参见图1)、并且与所述缝翼轨道(17)的中间部分(25)处的接合表面相接合。提供可能地简单、质量轻、以及成本有效的机翼设计的目的的实现在于：所述缝翼轨道(17)所具有的轮廓(37)包括上凸缘部分(39)、下凸缘部分(41)、以及连接所述上和下凸缘部分(39,41)的至少一个连接板部分(43),并且在于所述第二滚轮单元(33)布置在所述上和下凸缘部分(39,41)之间的凹部(45)中,并且与设于所述上凸缘部分(39)和/或所述下凸缘部分(41)的接合表面(35)相接合。(The invention relates to a wing (3, see fig. 1) of an aircraft (1, see fig. 1), comprising a main wing (5, see fig. 1), a slat (7, see fig. 1), and a connection assembly (9, see fig. 1) for movably connecting the slat (7, see fig. 1) to the main wing (5, see fig. 1), wherein the connection assembly (9, see fig. 1) comprises an elongated slat track (17), wherein a front end portion (21) of the slat track (17) is mounted to the slat (7, see fig. 1), wherein a rear end portion (23) and an intermediate portion (25) of the slat track (17) are mounted to the main wing (5, see fig. 1) by means of a roller bearing (27) comprising a guide rail (29) mounted to the main wing (5, see fig. 1) and a first roller unit (31), the first roller unit is mounted to a rear end portion (23) of the slat track (17) and engages with the guide track (29), and wherein the roller support (27) comprises a second roller unit (33) mounted to the main wing (5, see fig. 1) and engaging with an engagement surface at an intermediate portion (25) of the slat track (17). The object of providing a potentially simple, lightweight, and cost-effective wing design is achieved in that: the slat track (17) has a profile (37) comprising an upper flange portion (39), a lower flange portion (41), and at least one web portion (43) connecting the upper and lower flange portions (39, 41), and in that the second roller unit (33) is arranged in a recess (45) between the upper and lower flange portions (39, 41) and engages with an engagement surface (35) provided on the upper flange portion (39) and/or the lower flange portion (41).)

1. a wing (3) of an aircraft (1), the wing comprising:

a main wing (5),

a slat (7), and

a connection assembly (9) movably connecting the slat (7) to the main wing (5) such that the slat (7) is movable between a retracted position (11) and at least one extended position (13, 15),

Wherein the connection assembly (9) comprises an elongate slat track (17) extending along a track longitudinal axis (19) between a front end (21) and a rear end (23) and having an intermediate portion (25) between the front end (21) and the rear end (23),

wherein a front end portion (21) of the slat track (17) is mounted to the slat (7),

wherein a rear end portion (23) and an intermediate portion (25) of the slat track (17) are mounted to the main wing (5) by roller bearings (27) such that the slat track (17) is movable along the track longitudinal axis (19),

Wherein the roller support (27) comprises a guide rail (29) mounted to the main wing (5) and a first roller unit (31) mounted to a rear end (23) of the slat track (17) and engaged with the guide rail (29) and

Wherein the roller support (27) comprises a second roller unit (33) mounted to the main wing (5) and engaging an engagement surface (35) provided at an intermediate portion (25) of the slat track (17),

It is characterized in that the preparation method is characterized in that,

The slat track (17) has a profile (37) comprising an upper flange portion (39), a lower flange portion (41), and at least one web portion (43) connecting the upper flange portion (39) and the lower flange portion (41), and

The second roller unit (33) is arranged in a recess (45) between the upper flange portion (39) and the lower flange portion (41), and is engaged with an engagement surface (35) provided to the upper flange portion (39) and/or the lower flange portion (41).

2. A wing according to claim 1, wherein the slat track (17) has a profile (37) such that a first recess (45a) is formed between the upper and lower flange portions (39, 41) at a first side (47) of the web portion (43), and a second recess (45b) is formed between the upper and lower flange portions (39, 41) at a second side (49) of the web portion (43) opposite the first side (47).

3. Wing according to claim 2, wherein the second roller unit (33) comprises a first roller element (51) and a second roller element (53),

wherein the first roller element (51) is arranged in the first recess (45a) and the second roller element (53) is arranged in the second recess (45b), and

Wherein the first roller element (51) and the second roller element (53) are arranged coaxially and have the same radius.

4. a wing according to claim 3, wherein the web portion (43) of the slat track (17) includes a slot (73) extending from the first side (47) to the second side (49) of the web portion (43) and extending lengthwise along the track longitudinal axis (19),

Wherein the first roller element (51) and the second roller element (53) are mounted on a common shaft (75) for common rotation, and

Wherein the common shaft (75) travels from the first side (47) to the second side (49) of the web portion (43) through the slot (73).

5. An airfoil as claimed in claim 3 in which the first roller element (51) is mounted on a first shaft (55) and the second roller element (53) is mounted on a second shaft (57) spaced from the first shaft (55).

6. Wing according to any of claims 1 to 5, wherein the first roller unit (31) comprises a single third roller element (69).

7. wing according to one of claims 1 to 5, wherein the first roller unit (31) comprises a third roller element (69) and a fourth roller element (71),

Wherein the third roller element (69) and the fourth roller element (71) are arranged coaxially and have the same radius.

8. a wing according to any of claims 1 to 7, wherein the slat track (17) comprises first and second track portions (59, 61) formed spaced apart from one another,

Wherein each of the first and second track portions (59, 61) is integrally formed and extends along the track longitudinal axis (19) from the rear end (23) to the front end (21), and

Wherein the first rail part (59) and the second rail part (61) are mounted to and rest against each other along a contact plane (65) spanned by the rail longitudinal axis (19) and a wing thickness direction (67).

9. an airfoil as claimed in claim 8 when dependent on claim 6 in which the third roller element (69) is mounted to both the first track portion (59) and the second track portion (61).

10. an airfoil as claimed in claim 8 when dependent on claim 7 in which the third roller element (69) is mounted to the first track portion (59) and the fourth roller element (71) is mounted to the second track portion (61).

11. Wing according to any of claims 1 to 10, wherein a distance between an upper flange portion (39) and a lower flange portion (41) of the slat track (17) is greater than a diameter of the second roller unit (33) such that a gap (79) is provided between the second roller unit (33) and an engagement surface (35) at the upper flange portion (39), or between the second roller unit (33) and an engagement surface (35) at the lower flange portion (41),

Wherein the gap (79) is smaller at a threshold position (81a, 81b, 81c) along the slat track (17) at which the second roller unit (33) is located when the slat (7) is in the retracted position (11), and/or in a fully extended position (15), and/or in a defined partially extended position (13), and

wherein the gap (79) is larger in the area between the threshold positions (81a, 81b, 81 c).

12. a wing according to any of claims 1 to 11, wherein the roller support (27) comprises a third roller unit (83) mounted to the main wing (5) and engaging an upper surface (85) of the upper flange portion (39) of the slat track (17).

13. A wing according to any of claims 1 to 12, wherein the connection assembly (9) is a first connection assembly (91), wherein the wing (3) comprises a second connection assembly (93) connecting the slat (7) to the main wing (5) at a location spaced apart from the first connection assembly (91) in a spanwise direction (95), and wherein the second connection assembly (93) is formed identically to the first connection assembly (91).

14. An aircraft (1) comprising a wing (3) according to any of claims 1 to 13.

15. A connection assembly (9) for movably connecting a slat (7) to a main wing (5) of an aircraft (1), the connection assembly (9) comprising:

an elongated slat track (17) extending along a track longitudinal axis (19) between a front end portion (21) and a rear end portion (23) and having an intermediate portion (25) between the front end portion (21) and the rear end portion (23),

Wherein a front end portion (21) of the slat track (17) is configured to be mounted to the slat (7),

wherein a rear end portion (23) and an intermediate portion (25) of the slat track (17) are configured to be mounted to the main wing (5) by roller bearings (27) such that the slat track (17) is movable along the track longitudinal axis (19),

Wherein the roller support (27) comprises a guide rail (29) configured to be mounted to the main wing (5), and a first roller unit (31) mounted to a rear end (23) of the slat track (17) and configured to engage with the guide rail (29), and

Wherein the roller support (27) comprises a second roller unit (33) configured to be mounted to the main wing (5) and configured to engage with an engagement surface (35) provided at an intermediate portion (25) of the slat track (17),

it is characterized in that the preparation method is characterized in that,

The slat track (17) has a profile (37) comprising an upper flange portion (39), a lower flange portion (41), and at least one web portion (43) connecting the upper flange portion (39) and the lower flange portion (41), and

The second roller unit (33) is configured to be arranged in a recess (45) between the upper flange portion (39) and the lower flange portion (41), and to engage with an engagement surface (35) provided to the upper flange portion (39) and/or the lower flange portion (41).

Technical Field

The present invention relates to a wing of an aircraft, the wing comprising a main wing, a slat, and a connection assembly movably connecting the slat to the main wing such that the slat is movable between a retracted position and at least one extended position. Further aspects of the invention relate to an aircraft comprising such a wing, and to a connection assembly for use in such a wing.

background

The connection assembly includes an elongated slat track extending along a track longitudinal axis between a front end portion and a rear end portion and having an intermediate portion between the front end portion and the rear end portion. The forward end of the slat track is preferably fixedly mounted to the slat, for example by two spherical bearings arranged with an offset in the wing profile plane transverse to the spanwise direction. The rear end and intermediate portions of the slat track are movably mounted to the main wing by roller bearings so that the slat track is movable along the track longitudinal axis, i.e. along a predetermined path, preferably a circular path.

The roller support comprises a guide rail fixedly mounted to the main wing and a first roller unit mounted to the rear end of the slat track and engaged with the guide rail. Preferably, the guide rail is formed, for example, in a c-shape such that a surface thereof is opposite to a circumferential surface of the first roller unit, wherein a distance between an upper surface and a lower surface of the guide rail is greater than a diameter of the first roller unit so that the first roller unit can be engaged with only the upper surface or the lower surface of the guide rail at the same time. That is, the distance between the upper and lower surfaces of the guide rail is selected such that a gap is provided between the first roller unit and the upper or lower surface of the guide rail, so that the first roller unit cannot simultaneously engage with the upper and lower surfaces of the guide rail and thereby jam the first roller unit. Further preferably, the first roller unit has a first axis of rotation which extends parallel to the spanwise direction, the leading edge of the main wing, or the leading edge of the slat.

the roller support includes a second roller unit fixedly mounted to the main wing and engaging an engagement surface provided at a mid-portion of the slat track. Preferably, the second roller unit has a second axis of rotation which extends parallel to the spanwise direction, the leading edge of the main wing, or the leading edge of the slat.

wings of this kind are known in the art (for example from GB 404,149) in which the connection assembly comprises a second roller element formed from two roller elements which engage with the upper and lower surfaces of the slat track opposite to the slat track. However, there is a continuing need in the art to reduce the size, weight, and complexity of the connection assembly, and thus the entire wing.

disclosure of Invention

It is therefore an object of the present invention to provide a wing design which is potentially simple, lightweight, and cost effective.

This object is achieved in that: the slat track has a profile (i.e. a cross-section on the longitudinal axis) comprising an upper flange portion, a lower flange portion, and at least one web portion connecting the upper and lower flange portions. Such a profile may be, for example, a C-shaped profile, a double C-shaped profile, an I-shaped profile, an H-shaped profile, or a pi-shaped profile. The second roller unit is arranged in a recess between the upper and lower flange portions and engages with an engagement surface provided on the upper and/or lower flange portion, preferably in a sequential manner with the upper or lower flange portion or both flange portions. In this way, the second roller unit does not occupy space above and below the slat track, and the slat track may be retained by only a single roller element. This simplifies the connection assembly, saves space, and reduces weight, and thus increases the efficiency of the wing. Further, the connection assembly may be formed such that it is arranged completely in front of the front spar of the associated wing and does not penetrate into the front spar.

according to a preferred embodiment, the slat track has a profile (in particular an I-profile or a double C-profile) such that a first recess is formed between the upper and lower flange portions at a first side of the web portion and a second recess is formed between the upper and lower flange portions at a second side of the web portion opposite the first side. In this way, two roller elements can be received in two recesses.

In particular, it is preferred that the second roller unit comprises a first roller element and a second roller element. The first roller element is disposed in the first recess and the second roller element is disposed in the second recess. The first roller element and the second roller element are arranged coaxially, i.e. both rotate around the second axis of rotation, and have the same radius. Higher loads can be absorbed by the first and second roller elements and a symmetrical arrangement or an arrangement with two spaced-apart load paths is made possible.

Further, it is preferred that the web portion of the slat track includes a slot that extends from the first side to the second side of the web portion and extends elongate along the track longitudinal axis. Preferably, the slot extends along the rail longitudinal axis at least as long as the distance the slat moves between the retracted position and the fully extended position. The first roller element and the second roller element are mounted for common rotation on a common shaft. The common shaft travels from the first side to the second side of the web portion through the slot. Preferably, opposite ends of the common shaft are supported on the main wing. By using one common shaft to support the first and second roller elements, bending loads introduced into the main wing structure are minimized.

According to an alternative embodiment, the first roller element is mounted on a first shaft and the second roller element is mounted on a second shaft spaced apart from the first shaft. Preferably, the first and second shafts are independently supported on the main wing. By using separate shafts to support the first and second roller elements, no slot through the slat track is required.

according to a preferred embodiment, the first roller unit comprises a single third roller element mounted to the slat track, preferably by a yoke-shaped rear end portion of the slat track, which holds the third roller element from opposite sides. The use of only a single third roller element represents a very simple design.

In an alternative embodiment, the first roller unit comprises a third roller element and a fourth roller element. The third roller element and the fourth roller element are arranged coaxially, i.e. both rotate around the first axis of rotation, and have the same radius. Preferably, the third roller element is arranged at a first side of the web portion and the fourth roller element is arranged at a second side of the web portion. In this way, a spare roller element is provided.

according to a preferred embodiment, the slat track comprises first and second track portions formed spaced apart from one another. Each of the first and second track portions is integrally formed and extends along the track longitudinal axis from the rear end to the front end. The first and second rail parts are mounted to and rest against each other, e.g. by bolts, along a contact plane spanned by the rail longitudinal axis and the wing thickness direction (which plane may be a vertical symmetry plane), preferably along the entire longitudinal extension. By means of the first and second track portions, two separate load paths are introduced which may be designed as redundant load paths, so that when one load path fails, the other load path is still able to carry the ongoing air load applied via the slat.

in particular, it is preferred that the third roller element is mounted to both the first track portion and the second track portion. In this way, in case of failure of one of the first and second track portions, the third roller element will still be sufficiently supported by the other of the first and second track portions, such that the track portion will still be guided by the third roller element.

alternatively, it is preferred that the third roller element is mounted to the first track portion and the fourth roller element is mounted to the second track portion. In this way, in the event of failure of one of the first and second track portions, the other of the first and second track portions will still be guided by the associated one of the third and fourth rollers.

According to a preferred embodiment, the distance between the upper and lower flange portions of the slat track is greater than the diameter of the second roller unit, such that a gap is provided between the engagement surfaces at the second roller unit and the upper flange portion, or between the engagement surfaces at the second roller unit and the lower flange portion. In particular, the gap is small, preferably reduced to a minimum, at threshold positions along the slat track, which are positions at which the second roller unit is located when the slat is in a retracted position, and/or a fully extended position, and/or a defined partially extended position (e.g. take-off position). At the same time, the gap is larger in the region between the threshold positions. This threshold position with minimal clearance simplifies the control of the movement of the flaps between the retracted and extended positions.

according to another preferred embodiment, the roller support comprises a third roller unit mounted to the main wing and engaging an upper surface of the upper flange portion of the slat track. Preferably, the third roller unit comprises one common roller element engaging both the first track portion and the second track portion. Further preferably, the third roller element rotates about a third axis of rotation parallel to the spanwise direction. Further preferably, the third roller unit is arranged close to the leading edge of the main wing and may be arranged inside the main wing, partly outside the main wing, or completely outside the main wing with respect to the outer skin contour of the main wing. By means of such a third roller unit, additional support of the slat to the air load is obtained.

According to a further preferred embodiment, the connecting assembly is a first connecting assembly. The wing includes a second connection assembly that connects the slat to the main wing at a location spaced apart from the first connection assembly in the spanwise direction. The second connecting member is formed the same as the first connecting member, i.e., has the same features as the first connecting member. Alternatively, the second connecting assembly may also be formed differently from the first connecting assembly.

Another aspect of the invention relates to an aircraft comprising a wing according to any of the embodiments described above. The features and advantages mentioned in connection with the wing also apply to the aircraft.

Yet another aspect of the invention relates to a connection assembly for movably connecting a slat to a main wing of an aircraft, as described above with respect to the wing. The connection assembly includes an elongate slat track extending along a track longitudinal axis between a front end portion and a rear end portion and having an intermediate portion between the front end portion and the rear end portion. The forward end portion of the slat track is configured to be mounted to the slat. The rear end portion and the intermediate portion of the slat track are configured to be mounted to the main wing by roller bearings such that the slat track is movable along the track longitudinal axis. The roller support comprises a guide track configured to be mounted to the main wing, and a first roller unit is mounted to a rear end of the slat track and configured to engage the guide track. The roller support includes a second roller unit configured to be mounted to the main wing and to engage an engagement surface provided at an intermediate portion of the slat track. The slat track has a profile that includes an upper flange portion, a lower flange portion, and at least one web portion connecting the upper and lower flange portions. The second roller unit is configured to be disposed in a recess between the upper flange portion and the lower flange portion, and to be engaged with an engagement surface provided to the upper flange portion and/or the lower flange portion. The features and advantages mentioned in connection with the wing also apply to the connection assembly that can be used in such a wing.

In the following, preferred embodiments of the invention are explained in more detail with the aid of the drawings.