The invention relates to a movable hatrack for a passenger cabin of an aircraft for example. In particular, the invention relates to a movable hatrack with a lightweight construction. The invention also relates to the use of a hatrack of this type in an aircraft.
There are currently two different luggage compartment systems for aircraft cabins. There are non-movable luggage compartments (fixed bins) which take the form of a hatrack provided with a shutter facing the passengers. Alternatively, there are pivotable luggage compartments (movable bins) which take the form of a hatrack without a shutter which can be pivoted to face the passengers. All luggage compartments with a loading edge which can be moved in some way are known as “movable bins”. A fundamental aspect of a movable hatrack is that the open loading position differs from the closed position.
The component that is fixed to the fuselage in a movable hatrack is the housing which acts, inter alia, to receive the bin/storage container body itself. In this case, it is possible to dispense with a shutter because the hatrack becomes a closed box when it is pushed into the housing. The main advantage of movable hatracks is the changeable position thereof—in the closed state they offer a greater sense of space and the lowered, open position makes it possible to load and empty them comfortably.
The fuselage and the housing are connected by connecting rods which are fixed between aircraft-side and housing-side fittings. The housing and the hatrack are directly connected by rotary bearings or roller-guided rail systems, it being possible for the housing and the hatrack to be connected to form a pre-installed module.
An example of a movable bin which is pre-installed in a housing box as a hatrack module is disclosed in DE 10 2007 030331 A1 and WO 2009/003945 A1.
An aspect of the present invention provides a low-weight hatrack. Another aspect of the present invention provides a hatrack which does not pose any additional danger to passengers in the event of a crash.
In general, a hatrack according to an embodiment of the present invention comprises a hatrack body, a fixing brace and a bearing between the hatrack body and the fixing brace. The hatrack body may be formed as a box with one open side. The fixing brace may, for example, be fixed to a former of an aircraft structure. The fixing brace may have a correspondingly shaped fixing end for this purpose.
It should be noted that the fixing brace may take the form of a rod, trapezium or a planar shape. The fixing brace may also be a combination of a plurality of fixing braces forming a framework which is capable in particular of absorbing forces that arise.
The fixing brace further comprises a bearing end for receiving a bearing, the hatrack body being arranged on the bearing end of the fixing brace in such a way that the hatrack body is pivotable about at least one pivot axis.
Since hatracks in a passenger cabin of an aircraft are typically arranged transversely to the direction of flight, i.e. transversely to a longitudinal axis of the fuselage, the pivot axis of the hatrack body is substantially parallel to the longitudinal direction of the passenger cabin in the fuselage. The fixing brace will accordingly be arranged transversely to the longitudinal direction, between a bearing point of the hatrack body and preferably a former of the aircraft structure, and can therefore absorb in particular the forces acting transversely to the direction of flight.
The use of fixing braces makes it possible to dispense with a closed housing for receiving a hatrack body. This leads primarily to a reduction in weight.
According to an embodiment of the invention, the hatrack also comprises a sliding block which is arranged adjacent to the fixing end of the fixing brace. Said sliding block is fixed to the fixing brace in such a way that it is arranged at the front in the direction of flight, opposite the lateral wall of the hatrack, with the result that, if the hatrack body were forced forward in a crash, it would be supported against the sliding block arranged adjacent to or even on the former of the aircraft structure. In this way, it is possible to prevent the moments that arise on the fixing brace in a crash from destroying the fixing brace, and it is therefore possible to prevent the hatrack from being torn away from the aircraft structure. This in turn reduces the danger to passengers in the event of a crash.
The sliding block may be fixed to both the fixing brace and the hatrack body. The sliding block may also be formed so as to be integral with the fixing brace. According to a preferred embodiment, the sliding block is produced from a plastics material, for example polyamide, in such a way that the lateral wall of the hatrack body may be moved easily along the sliding block when the hatrack body is pivoted between an open and a closed position.
It is also possible to provide a gap between a sliding block and the hatrack body in such a way that the hatrack body can be moved on the fixing brace and past the sliding block without contact. In the event of a crash, a slight deformation of the fixing brace would ensure that the hatrack body contacts the sliding block and that therefore the forces acting in the direction of flight would in turn be channelled into the aircraft structure via the sliding block.
According to an embodiment of the invention, the hatrack body comprises a locking latch, it being possible to lock the hatrack body in a closed position using the locking latch. The primary purpose of a locking latch of this type is to prevent the hatrack body from being opened accidentally. The locking latch may either engage in a corresponding notch in the fixing brace if the locking latch is arranged laterally on the hatrack body, or may engage directly in a notch in the former of the aircraft structure if the locking latch is arranged on the rear or a lateral edge of the rear of the hatrack body.
In order to increase the level of comfort when actuating the hatrack body, i.e. when opening or closing the hatrack body, a damper may be provided and arranged between the fixing brace and the hatrack body. It should be noted that the damper may be a passive piston damper. Alternatively, the damper may also be an active member which on the one hand softens the speed of movement during opening and closing and on the other also provides active power assistance for the actuation of the hatrack body.
To further increase the level of safety in the event of a crash, the fixing brace of the hatrack may comprise an articulation point adjacent to the fixing end, the articulation point being formed in such a way that the fixing brace folds or is bent in the direction of flight when a force acts on said brace in the direction of flight. An articulation point of this type may be formed as a hinge over which no force can be transferred in the direction of flight. The articulation point of the fixing brace may, however, also be formed with a tapered cross-section, a kind of film hinge, in such a way that a predetermined bending point is formed when a force acting in the direction of flight arises.
In order to increase the rigidity of the hatrack body, a handle strip may be integrally formed on the front of the hatrack body. This can be achieved either by an extruded hollow profiled part or by connecting a handle-strip-shaped polyurethane foam profiled part with a honeycomb core arranged between two face sheets. The rigidity of the hatrack body is increased by the integrally formed handle strip on account of the geometry thereof, with the result that the wall thickness of the hatrack body can be reduced and therefore the weight can also be reduced.
These aspects described above may be implemented both in a hatrack comprising a hatrack body which is pivotable about a defined axis, and in a hatrack comprising a hatrack body which can be moved along a guide rail in both a translational and a rotational manner.
According to an embodiment of the invention, an aircraft comprises a hatrack with the features described above. The aircraft may further comprise a covering panel arranged above the hatrack in the passenger cabin of the aircraft. The covering panel may, at the lower edge thereof, comprise a portion which extends in the direction of the aircraft structure. This portion of the covering panel, which is not visible from the passenger cabin, may be shaped in such a way that the hatrack body, when in the closed state, forms a closed box together with said portion. By this means, it is possible to prevent objects in the hatrack body for example from catching behind the covering panel.
The aspects described above and further aspects, features and advantages of the invention may also be found in the example embodiments described below with reference to the appended drawings.
The main challenge in accommodating a movable hatrack is the limited installation space available for movement mechanisms, and the fact that the module weight is almost doubled due to the corresponding doubling of the sandwich surface. A housing is typically a closed drawer with a contour open towards the passengers, and a hatrack body is a smaller closed drawer with a contour open towards the passengers, located within the housing. This double-walled construction, including the required gap for movement and the movement mechanism, leads to a considerable loss of usable load volume in comparison with fixed hatracks (fixed bins) of the same size.
The same applies to the module weight, since the double-walled construction, including the required movement mechanisms, leads to a considerable increase in weight in comparison with movable bins of the same size using conventional movement mechanisms.
It is now proposed according to an embodiment of the invention that the double-walled construction of a movable hatrack (movable bin) be dispensed with and that the hatrack body be secured directly to the structure which, with an intelligent layout, means that a movable hatrack can be achieved with the same weight and loading volume as a fixed bin.
It is thereby advantageously possible for all the faces of a conventional hatrack module which are visible to the passenger to be retained. It is further possible for all the requirements placed on a conventional hatrack module with regard to rapid and simple assembly to be satisfied. The requirements of a conventional hatrack module with regard to loading characteristics and reliability are also satisfied. Furthermore, the provision of passenger supply functions also remains unimpaired.
It is thus possible for the loading volume of movable hatracks to be increased and the weight almost halved through the use of the “housing-free hatrack” according to an embodiment of the invention with identical external dimensions, without passengers and manufacturers having to contend with any evident drawbacks.
Furthermore, with regard to installation times, this “housing-free hatrack” may be installed using a quick-lock system, either through the use of rollers at the side of the structure which are inserted into axial quick-lock recesses on the hatrack body or through the use of rails. This further accelerates the time required for installation in the final cabin assembly process.
The hatracks described in this document dispense with the double-walled construction and are therefore fixed directly to the structure of the aircraft. Hatrack bodies which are pivotable about a fixed rotary bearing are installed for example with a quick-lock system, by means of rollers which are mounted on the structure and are clipped into internal axial quick-lock recesses.
To enable the hatrack body 100 to be inserted more easily, an insertion incline 130, i.e. a conical region extending towards the rear end of the hatrack body, may be provided. According to this embodiment, after the fixing brace 310 has been fixed in the horizontal direction and the fixing brace 320 has been fixed in the vertical direction to a former 400 of the aircraft structure, the hatrack body 100 may, via the insertion (assembly) incline 130 thereof, initially be pushed in the assembly direction M onto a roller at the bearing point 340 of the fixing braces 310 and 320 and then locked in place by being pushed further over the grippers 120 into the notch 110. In this way, an axially pivotable hatrack body may be fitted easily between a supply duct 420 and a covering panel (ceiling lining) 410.
In a manner comparable to the first embodiment, it is also possible in this case for the hatrack body 200 to be pushed in the assembly direction M via insertion inclines for example, initially onto the first roller at the bearing point 350, and then pushed further onto the further roller at the bearing point 340. The interaction between the two bearing points and the correspondingly arranged rollers, and the particular shape of the rails make it possible for the hatrack body to move in a complex manner, both translationally and rotationally.
This thus ensures rapid, simple assembly in a single step, with no time-intensive modification or readjustment required. A common feature of both principles is that the rollers which engage in the hatrack body at the bearing points take the form of fixed bearings at the front and loose bearings at the rear in the direction of flight.
As shown in
The fixed bearing is capable of absorbing loads which arise in the direction of flight, the loose bearing not being able to absorb loads of this type in the direction of flight but being able to compensate even for major structure-related and hatrack-related manufacturing tolerances. The bearing that actually functions as a guide is therefore located at the front in the direction of flight, with the rear loose bearing only acting as a guide transversely to the direction of flight. “Bending moments” arising about the bearing axis are compensated or neutralised, since the fixing brace framework is not subjected to bending forces on both sides because a hatrack body is received on the left- and right-hand sides at the same time.
Finally, a sliding block 370, which is arranged between the fixing brace 320 and the hatrack body, is also shown in
The locking latch which engages in the latch mechanism 380 may be actuated from a central handle via control cables. The locking latches may be acted upon on one side by a spring mechanism in such a way that they catch automatically when the hatrack body is closed and must be released to open the hatrack.
According to an alternative embodiment shown in
Alternatively, the locking mechanism 380 may be integrated directly into the structural former 400. An embodiment of this type is shown in
The embodiment shown in
According to this embodiment, the locking and latching forces acting on the locking latch 180 are not directed into the fixing framework, but are transferred directly into the structural former 400, which allows the construction to be made more lightweight through load path optimisation.
By enlarging the conventional construction thereof, the covering panel assumes the locking function performed by the housing in conventional hatracks, and is directly fixed to the structural former, which in turn decreases the weight of the ceiling assembly.
In the following, unacceptable bending loads which arise in the formers, such as crash loads in the direction of flight, will be described in particular. In
In this case, the intermediate framework deforms in the direction of flight until the face of the sliding block 370 in the proximity of the former comes into contact with the hatrack body 100 (
Alternatively, an articulation point 390, for example a rotary bearing, may be integrated into the intermediate framework. In this case, the moment introduced into the former is reduced to zero, but the bending forces in the intermediate framework increase (
A balance between the configurations shown in
As shown in
Alternatively, as shown in
While the invention has been illustrated and described in detail in the drawings and the above description, said illustrations and descriptions are merely intended to be illustrative or examples and are not restrictive, and therefore the invention is not limited by the disclosed embodiments. Other variations of the disclosed embodiments may be conceived and achieved by a person skilled in the art by modifying the claimed invention following a review of the drawings, disclosure and appended claims.
In the claims, the term “comprising” does not exclude other members or steps and the indefinite article “a” or “an” does not preclude a plurality.
The mere fact that particular features are specified in different dependent claims does not limit the subject-matter of the invention. Any desired combinations of said features may also be advantageously used. The reference numerals in the claims are not intended to limit the scope of the claims.
Number | Date | Country | Kind |
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10 2010 008 622.3 | Feb 2010 | DE | national |
The present application is a continuation of International Application No. PCT/EP2011/051055, published in German, which claims priority from U.S. Provisional Patent Application No. 61/306,225, filed on Feb. 19, 2010, and German Patent Application No. 10 2010 008 622.3, filed on Feb. 19, 2010, the disclosures of which are incorporated herein by reference.
Number | Date | Country | |
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61306225 | Feb 2010 | US |
Number | Date | Country | |
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Parent | PCT/EP2011/051055 | Jan 2011 | US |
Child | 13589516 | US |