Abstract: The disclosure refers to an airplane's own mobility system. For supporting a passenger with reduced mobility on board an airplane and for simplifying as much as possible the use of a toilette, a mobility system for passengers with reduced mobility is provided. The mobility system includes an onboard toilette spatial unit having an entrance zone, an entrance door, and a toilette using zone with a toilette. Moreover, a movement device with a passenger carrying equipment is provided, which is moveable at least from the entrance zone to the toilette using zone and supported in the ceiling area. The passenger carrying equipment includes a seat device enabling a passenger a seat like position. For using the toilette, a passenger is movable back and forth with the movement device from the entrance zone to the toilette using zone.

Abstract: A 3D printing device includes a printing substrate, a movable printing head configured for additively producing from a modelling material a component on the printing substrate, and a flexible printing space cover which, proceeding from the printing head, spans the printing substrate such that a closed printing space is formed between the printing head and the printing substrate, wherein a printing nozzle of the printing head for applying the modelling material protrudes into the printing space. A support structure of the device includes flexible support rods which run from the printing head to the printing substrate and which hold the printing space cover above the printing substrate.

Abstract: A cargo hold component system for a cargo hold of an aircraft, the cargo hold component system including floor elements and fixing elements. The floor elements can at least partially be fixed releasably by the fixing elements to fixing sites provided on or in the hold floor, such that in a state fixed to the fixing sites, the floor elements support a loading of the hold with cargo containers, and that in a state in which a first group of the floor elements has been removed from the fixing sites by release of the fixing elements and a second group of the floor elements has been partially removed from the fixing sites by release of the fixing elements, the hold is sealed gas-tightly.

Abstract: An electrically heatable layer stack is disclosed. The electrically heatable layer stack includes at least two substrate layers, and at least one carbon nanotubes-, CNT-, layer, which is arranged between the substrate layers and which is configured to conduct an electric current. The substrate layers and the at least one CNT-layer are configured to produce heating of at least one of the substrate layers when an electric current is applied to the at least one CNT-layer. A vehicle assembly group, an aircraft, a method and a system for manufacturing an electrically heatable layer stack are also disclosed.

Abstract: A temperature regulating system for at least one galley compartment for an in-flight kitchen which is intended for installing in a transport apparatus or vehicle, especially in an aircraft, includes a controllable cooling and heating element, which is designed for selectively cooling or heating a specified section of the cooling and heating element, and a heat-insulating partitioning wall, which at least partially adjoins an encompassing side edge of the cooling and heating element and encloses the specified section of the cooling and heating element. The heat-insulating partitioning wall is designed for separating an interior space of the galley compartment from an interior of a section of a fluid duct which extends in the in-flight kitchen.

Abstract: A cabin monument arrangement for a passenger cabin of an aircraft, has at least two cabin monuments arranged next to each other, aligned substantially parallel and forming a gap. The gap includes a gap covering in the fastening region of the first lateral monument part and of the second lateral monument part in the region of the front edge portion of the respective cabin monument. In each case, a first contour-adapted rigid fastening strip is on the fastening region and a second contour-adapted, rigid fastening strip is on the second fastening region. A covering element is between the first and second fastening strips for covering the gap between the first monument part and the second monument part, the covering element formed from a flexible covering material of thin design. A corresponding covering of the gap between the cabin monuments can therefore be achieved with sufficient flexibility and material width.

Abstract: A wing (5) for an aircraft (1) and include a fixed wing (7), a high lift system (9) including a high lift surface (27) movably mounted to the fixed wing (7), and a high lift actuation system (29) for moving the high lift surface (27) relative to the fixed wing (7) between a retracted position and at least one deployed position, a foldable wing tip portion (11) mounted to the fixed wing (7) pivotally about an axis of rotation (35) between an extended position and a folded position, a tip actuation unit (13) for moving the foldable wing tip portion (11) between the extended position and the folded position.

Abstract: A panel structure for a vehicle, and especially for an aircraft or spacecraft, includes an area member, especially a skin member, that defines an areal expanse with a first surface and an opposite second surface and having a thickness between the first and second surfaces; and a plurality of elongate stiffener members which are attached to the area member and extend over at least one of the first and second surfaces; wherein at least one of the stiffener members is bifurcated at a bifurcation point into two or more branch stiffener members.

Abstract: A battery cell includes an anode, a cathode, and a separator between the anode and the cathode, wherein at least one of the anode or the cathode includes at least a carbon fiber ply comprising carbon fibers, the carbon fiber ply having a thickness of less than 90 micrometers. Also disclosed are a battery and an aircraft including such battery cell, and a method for manufacturing such battery cell.

Abstract: A fastening system has a fastening element and at least one fastening device having a flanged housing, a closure element, a hollow-sphere element and a spherical insert. The hollow-sphere element pivots about a first pivoting axis relative to the flanged housing, while the spherical insert pivots about a second pivoting axis in the hollow-sphere element. First engagement means in an opening of the spherical insert are of complementary design to second engagement means of the fastening element. The first and second engagement means are designed such that, in a first rotational position, the fastening element can be inserted freely into the opening and, in a second rotational position, the first and second engagement means engage in one another.

Abstract: A fastening system for securing a component includes a first securing element having an engagement end and external toothing, a second securing element having elastic clamp members arranged about a common axis and having internal toothing facing the axis, and a fixing member. The clamps members assume a radial position relative to the axis that is variable due to their elasticity. The clamps are designed such that the second securing element can be pushed onto the engagement end such that the teeth of the engagement end and the clamps snap into each other. The clamps move from a first radial position to an external second radial position to engage or disengage a snapped-in state when shifting the external toothing and the first internal toothing to each other.

Abstract: A fastening system for fastening fitments to a floor of a cabin of a vehicle has a receiving frame, a cantilever mounted on the receiving frame so as to be pivotable on a pivoting plane defined by the receiving frame, and having a mounting end and a fastening end, a first fastening element, and a multiplicity of second fastening elements. The first fastening element is arranged at the fastening end of the cantilever. The second fastening elements are positionable on the floor. The first fastening element is configured in a manner corresponding to the second fastening elements such that the first fastening element is mechanically connectable selectively to a second fastening element. A pivoting position of the cantilever is lockable relative to the receiving frame.

Abstract: A system for producing a component from a fibre composite material includes a moulding tool, a control unit and a plurality of mutually independent material application units, each of which includes a material store for providing fibres, a material delivery apparatus for delivering fibres from the material store and a drive device, and is configured, with the aid of the drive device, to follow a predetermined path on the moulding tool, while delivering fibres as required. The control unit controls the material application units by specifying a plurality of individual paths, so that they move autonomously along the paths. The control may, in particular, be carried out by optical projection onto the moulding tool.

Abstract: A method for manufacturing a multilayer fiber structure includes providing a receiving surface being formed by a first surface region of a contoured tool surface of a forming tool component and a support surface of a support component. Further, at least one fiber layer is formed on the receiving surface by laying down a plurality of fiber tapes onto the receiving surface. A roller device is positioned so as to press the at least one fiber layer against the tool surface and the support component and the roller device are synchronously moved along a curved transition region connects the first surface region to a second surface region of the tool surface. Thereby the at least one fiber layer is abutted against the transition region and the second surface region of the tool surface. Further, a tool system for manufacturing a multilayer fiber structure is disclosed.

Abstract: A leading-edge component for an aircraft includes at least a part of a flow body having a front skin and at least one rib, wherein the front skin includes 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 includes at least one kink separating the rib into a first section and at least one second section, and wherein main extension planes of the first section and the at least one second section enclose an angle of at least 10°.

Abstract: A leading edge structure (1) for a flow control system of an aircraft, including a double-walled leading edge panel (3) that surrounds a plenum (7), wherein the leading edge panel (3) includes an inner wall element (21) facing the plenum (7) and an outer wall element (23) in contact with the ambient flow (25), wherein between the inner and outer wall elements (21, 23) the leading edge panel (3) includes elongate stiffeners (27) spaced apart from one another, so that between each pair of adjacent stiffeners (27) a hollow chamber (29) is formed between the inner and outer wall elements (21, 23), wherein the outer wall element (23) includes micro pores (31) forming a fluid connection between the hollow chambers (29) and an ambient flow (25), and wherein the inner wall element (21) includes openings (33) forming a fluid connection between the hollow chambers (29) and the plenum (7).

Abstract: A wing for an aircraft, including a main wing, a slat, and a connection assembly movably connecting the slat to the main wing, the slat movable between a retracted and at least one extended position. The connection assembly includes an elongate slat track. A wing has a connection assembly without requiring the front spar being penetrated. The slat track has a first end mounted to the slat and a second end guided at the main wing for movement along a predetermined path extending in a direction from a front spar to a leading edge of the main wing and from a lower side to an upper side of the main wing. Between the first and second ends the slat track is mounted to the main wing allowing translation of the slat track and rotation of the slat track about a first axis of rotation parallel to the leading edge.

Abstract: A rail system for a vehicle includes a floor rail integratable into or onto the floor, first elongate movement rail elements, second elongate movement rail elements, holding devices to hold the movement rail elements on the floor rail, and gliders supportable on the movement rail elements in a gliding manner. The movement rail elements have a rail profile cross-section perpendicular to their main extension axis; the cross-section has an undercut that faces laterally outwards. The movement rail elements each have two opposed end faces, which can be brought into contact with end faces of other movement rail elements, such that at least one continuous movement rail with a constant rail profile cross-section is created. The gliders include a recess corresponding to the rail profile cross-section for gliding support.

Abstract: A wing for an aircraft including a slat, and a connection assembly for movably connecting the slat to the main wing. The connection assembly includes a first connection element movably mounted to the main wing and mounted to the slat, and a second connection element movably mounted to the main wing and mounted to the slat. The connection assembly includes a drive unit connected to the slat that includes a first and second drive station spaced apart in the wing span direction. The first drive station has a first input section, a first gear unit and a first output section connected to the slat. The second drive station has a second input section connected to the drive shaft, a second gear unit, and a second output section connected to the slat. The drive unit includes a sync shaft coupling the first output section to the second output section.

Abstract: A method to control folding of a wing tip section about a fixed base wing section by a control system that automatically determines whether: (i) a command signal is received to fold the wing tip section, (ii) a first condition indicating signal indicates that the aircraft is on the ground; (iii) the current speed of the aircraft is no greater than a preset maximum speed, and (iv) the aircraft is not at gate in an airport.