DE102010019847A1 - Attachment device for movably attaching monitor to aircraft passenger seat, has friction unit loading knuckle unit with force to fix support arm in usage condition and comprising adjustment element for changing force based on pivoting angle - Google Patents

Abstract

The device (10a) has a main knuckle unit (18a) for guiding a support arm (16a) along a pivoting area relative to a seat (14a). A friction unit loads the main knuckle unit with frictional force for fixing the support arm in a usage condition. The friction unit has an adjustment element for changing the frictional force based on a pivoting angle. The friction unit and the adjustment element are designed as a single-piece, and a locking unit locks the support arm and an energy storage unit in a form-fit manner, where the friction unit has a brake lining. An independent claim is also included for a method for movably attaching an object to a seat.

Description

State of the art

The invention relates to a seat mounting device according to the preamble of patent claim 1.

From the DE 197 25 347 A1 is already a seat mounting device, in particular a passenger seat mounting device, for movably attaching an object to a seat, with a support arm, with a main hinge unit, which is intended to guide the support arm along a pivoting range relative to the seat, and with a friction unit provided for this purpose is to apply for fixing the support arm in at least one use position, the main hinge unit with a frictional force known.

The invention is in particular the object of improving the ease of use of the seat mounting device.

This object is achieved by a seat mounting device according to claim 1. Further advantageous embodiments of the invention can be taken from the dependent claims.

Advantages of the invention

The invention relates to a seat mounting device, in particular a passenger seat mounting device, for movably attaching an object to a seat, with a support arm, with at least one main hinge unit, which is intended to guide the support arm along a pivoting range relative to the seat, and with at least one Friction unit, which is intended to apply for fixing the support arm in at least one use position, the main hinge unit with a frictional force.

It is proposed that the friction unit has at least one adjusting element, which is provided to change the at least one frictional force for fixing the support arm in dependence on a pivoting angle. As a result, the frictional force can be adapted to an operation of the seat mounting device. By adjusting the friction force, the operation of the seat mounting device can be facilitated, whereby a user comfort can be improved. An "object" should be understood in this context, in particular a monitor. The support arm is preferably designed as a Videotragarm. A "use position" is to be understood in particular a position of the support arm, in which a user uses the object. The use position is preferably one, in a partial pivoting range of the user adjustable, variable position of the support arm. Advantageously, the use position in the partial pivoting range is adjustable, in which the friction unit provides a frictional force. The adjusted by the user use position is held in particular by the frictional force. The adjusting element is preferably designed as a mechanical adjusting element.

It is further proposed that the adjusting element is provided to set a substantially frictionless part pivoting range. Thereby, the support arm can be moved with little effort, which is particularly comfortable a stowed position of the support arm can be adjusted. A "substantially friction-free partial pivoting range" is to be understood in particular as meaning a pivoting range of the support arm in which at least one friction element of the friction unit is operatively decoupled from the movement of the support arm. The brake element is preferably designed as a brake disc. A "stowage position" is to be understood in particular a position of the support arm, in which the seat attachment device is stored in an unused state. The seat attachment device is preferably arranged in the stowed position not disturbing for a user.

In an advantageous embodiment, the adjusting element has at least one surface contour, which is intended to mechanically convert a change of the swivel angle into an actuating force for the friction unit. As a result, the frictional force can be changed in a particularly simple manner. An "actuating force" is to be understood in particular a force which causes the frictional force of the friction unit. A "surface contour" should in particular be understood to mean a surface which deviates from a flat surface. The surface contour is preferably formed as a height profile. The surface contour may also be formed as a material texture changing along the surface or the like. Preferably results from the actuation force, the frictional force by means of which the main hinge unit is acted upon.

It is further proposed that the friction unit and the adjusting element are at least partially formed in one piece. Thereby, a particularly advantageous embodiment of the friction unit can be achieved, whereby an assembly of the friction unit and the adjusting element can be facilitated. In this context, "integral" should be understood in particular to mean that a friction surface of the at least one friction element of the friction unit has the surface contour of the adjustment element.

It is also proposed that the friction unit for forming the adjusting element at least a brake pad, the friction surface has the surface contour. As a result, the friction unit can provide a variable friction force in a particularly simple manner. In particular, a simple adjustment of the actuation force is possible.

In particular, it is advantageous if the seat mounting device has at least one energy storage unit which is provided to move the support arm automatically in an unlocked position. As a result, the support arm can be pulled out of a stowage position particularly easily. An "energy storage unit" is to be understood in particular as a unit which receives and / or stores a force applied by moving the support arm. The energy storage unit is advantageously designed as a mechanical energy storage unit. Preferably, the energy storage unit moves the support arm along the substantially frictionless Teilschwenkbereich.

Furthermore, it is advantageous if the seat mounting device has at least one power conversion unit which is provided to convert a linear force of the energy storage unit into a torque for the support arm. As a result, the support arm can be moved from the stowage position into the unlocked position in a particularly simple manner. The force conversion unit is preferably designed as a mechanical force conversion unit.

Particularly preferably, the seat mounting device has at least one latching unit, which is provided to lock the support arm and the energy storage unit simultaneously in a form-fitting manner. As a result, the support arm can be securely held in the stowed position. A latching unit preferably has at least one latching engagement element and a latching receiving element. A "latching engagement element" is to be understood in particular as an element which provides a holding force. The latching engagement element is preferably designed as a holding element. Advantageously, the latching engagement element is fixedly supported against a housing. A "locking receiving element" is to be understood in particular an element which is held by the holding force. The latch receiving element is preferably formed as a held element. Preferably, the latching engagement element and the latch receiving element engage each other, whereby the latching unit produces a positive connection. By "latch at the same time" is to be understood in particular that the support arm and the energy storage unit are latched together in at least one time by the latching unit. The latching unit preferably decouples the energy storage unit from the support arm. The latching unit preferably directly locks the energy storage unit, regardless of the latching of the support arm. By latching the energy storage unit advantageously no force of the energy storage unit acts on the support arm. The latching unit is preferably designed as a mechanical, self-latching latching unit.

In a further embodiment of the invention it is proposed that the seat mounting device has at least one release unit, which is provided to actuate the latch unit for jointly releasing the latching of the support arm and the latching of the energy storage unit. As a result, the titration of the support arm and the energy storage unit can be realized particularly advantageous. The trip unit is advantageously designed as a mechanical trip unit.

In particular, it is advantageous if the latching unit has at least two separate latching engagement elements and at least one coupling element, wherein the coupling element is provided to couple the release of the latching of the support arm and the energy storage unit in terms of motion technology. As a result, the joint release of the latching can be realized particularly easily. The coupling element is preferably designed as a mechanical coupling element. Preferably, the locking unit by means of the two separate locking engagement elements directly locks the energy storage unit and directly the support arm.

It is also advantageous if the coupling element is provided to solve the locking of the support arm and the energy storage unit temporally one after the other. Thereby, a force for releasing the locking can be reduced. Preferably, the coupling element first releases the latching of the support arm and then the latching of the energy storage unit.

In a further embodiment according to the invention, it is proposed that the latching unit has a common latching engagement element for the latching of the support arm and the energy storage unit. As a result, a space requirement of the seat mounting device can be reduced. A "common catch engagement element" is to be understood, in particular, as a catch engagement element which locks the support arm and the energy storage unit together. Preferably, the common latch engagement element locks the support arm via the power conversion unit. The latching unit preferably directly engages the energy storage unit and indirectly the support arm by means of the common latching engagement element.

It is also proposed that the seat mounting device comprises a mounting module, which at least partially comprises the energy storage unit, the trip unit, the power conversion unit and the locking unit. This can be a Assembly of the latch unit, the energy storage unit, the trip unit and the power conversion unit are facilitated to the seat mounting device. A "mounting module" is to be understood in particular a unit having a plurality of components, which can be mounted in a single assembly step.

drawings

Further advantages emerge from the following description of the drawing. In the drawings, two embodiments of the invention are shown. The description and claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

1 a seat schematically illustrated with an armrest and a seat attachment device connected to the armrest,

2 the seat mounting device in a use position with a mounting module,

3 the seat mounting device in a stowed position with the mounting module,

4 an exploded view of the seat mounting device,

5 a sectional view of the mounting module and a main hinge unit,

6 a schematically illustrated, alternatively formed seat mounting device in a stowed position and an armrest,

7 an exploded view of the alternatively formed seat attachment device and

8th a sectional view of a main hinge unit of the alternatively formed seat mounting device.

Description of the embodiment

The 1 to 5 show a seat 14a with a seat attachment device according to the invention 10a , The seat attachment device 10a is designed as a passenger seat mounting device. The seat attachment device 10a attaches a designed as a monitor object 12a movable on the seat 14a , The seat 14a includes an armrest 52a to which the seat attachment device 10a is connected. The seat 14a has sitting feet 54a on, by means of which the seat 14a on a floor 56a an aircraft is attached. The seat 14a is designed as a passenger seat. The armrest 52a is designed as an armrest console. The trained as a monitor object 12a is only in the 1 shown.

In a use position of the seat attachment device 10a (see. 1 and 2 ) the object can 12a from a user in the seat 14a sits, be used. In use position shows a screen level 58a of the item designed as a monitor 12a towards a backrest 60a of the seat 14a , The one on the seat 14a sedentary user thus has the designed as a monitor object 12a arranged in front of him. In a staging 62 the seat attachment device 10a (see. 3 . 4 and 5 ) the object can 12a by the user who is in the seat 14a sits, not used. In the staging 62 is the object designed as a monitor 12a in the area of the seat feet 54a below the armrest 52a of the seat 14a arranged.

The seat attachment device 10a includes a support arm 16a and a main hinge unit 18a , The main hinge unit 18a has a swivel joint. The hinge has a main axis of articulation formed as an axis of rotation 63a on (cf. 4 ). The main hinge unit 18a guides the arm 16a relative to the seat 14a along a pivoting range 20a , The swivel range 20a forms an angular range in which the support arm 16a is pivotable. By means of the main hinge unit 18a can the support arm 16a in a direction of movement 64a and a direction of movement 66a to be moved. By the movement of the support arm 16a in the direction of movement 64a will, starting from the stowage 62 , the use position set. By the movement of the support arm 16a in the direction of movement 66a is based on the use position, the stowage 62 set. The stowage 62 of the support arm 16a defines a pivoting angle of the support arm 16a from zero. A maximum use position 68a defines a maximum swing angle of the support arm 16a , In this embodiment, the maximum swing angle is 165 degrees. The swivel range 20a of the support arm 16a in this embodiment is thus 165 degrees.

The main hinge unit 18a has a warehouse 70a , a bearing housing 72a and a connection housing 74a on. The warehouse 70a is designed as a sliding bearing. The bearing housing 72a is formed in two parts. A first bearing housing part 76a is integral with the support arm 16a executed. A second bearing housing part 78a is separate to the support arm 16a educated. The bearing housing 72a surround the camp 70a , The connection housing 74a surrounds the bearing housing 72a , The bearing housing part 78a and the connection housing 74a are rotatably connected. The connection housing 74a indicates on one side, which is mounted with seat mounting device 10a the seat 14a facing, an opening 80a on. The side of the connection box 74a that the opening 80a has, forms a fastening device 82a out, by means of the support arm 16a at the seat 14a is attached. The connection housing 74a is firmly attached to the seat 14a connected. The side for fixing the connection housing 74a defines a mounting plane. The main joint axis 63a the main hinge unit 18a runs parallel offset to the mounting plane.

The support arm 16a is formed in three parts. The support arm 16a has a Tragarmstück 84a , an intermediate piece 86a and a device receptacle 88a on. In 2 shows the device receptacle 88a from the sheet level. The trained as a monitor object 12a is on the device receptacle 88a assembled. Next includes the support arm 16a two joints 90a . 92a , The first joint 90a is between the Tragarmstück 84a and the intermediate piece 86a arranged. The second joint 92a is between the intermediate piece 86a and the device receptacle 88a arranged.

The support arm piece 84a is integral with the first bearing housing part 76a educated. About the main hinge unit 18a is the Tragarmstück 84a movable with the fastening device 82a connected. The support arm piece 84a has a main extension direction, which in the use position in a viewing direction 94a in the seat 14a sitting user perpendicular to the main hinge axis 63a the main hinge unit 18a is aligned. The main extension direction is a direction of extension along a side wall of the support arm piece 84a along which the Tragarmstück 84a has a maximum extent. The direction of view 94a is oriented perpendicular to the mounting plane (see. 1 ).

The support arm piece 84a is about the first joint 90a movable with the intermediate piece 86a connected. The first joint 90a has a first hinge axis designed as a rotation axis. The first joint 90a is designed as a hinge. The first joint axis of the first joint 90a runs in the axial extension of Tragarmstücks 84a , The first joint axis of the first joint 90a is axially parallel to the main extension direction of Tragarmstücks 84a oriented. The first joint axis tensions with the main joint axis 63a a level up. In the direction of view 94a is the first hinge axis perpendicular to the main hinge axis 63a oriented. The first joint 90a leads the intermediate piece 86a relative to Tragarmstück 84a along an adjustment range.

The intermediate piece 86a is about the second joint 92a movable with the device receptacle 88a connected. The second joint 92a has a second axis of articulation designed as a rotation axis. The second joint 92a is designed as a hinge. The second hinge axis of the second joint 92a is axially parallel to a main extension direction of the device receptacle piece 88a oriented. The first hinge axis and the second hinge axis intersect perpendicularly at one point. The two joint axes span a plane. The second joint 92a leads the device receptacle 88a relative to the intermediate piece 86a along an adjustment range. The intermediate piece 86a couples the Tragarmstück 84a with the device receptacle piece 88a , The intermediate piece 86a is between the Tragarmstück 84a and the device receptacle 88a arranged.

For loading the main hinge unit 18a with a friction force for fixing the support arm 16a in the use position, the seat attachment device 10a a friction unit 22a on. To provide the frictional force, the friction unit 22a a brake pad 30a and a brake disc 96a on. The brake pad 30a and the brake disc 96a have a common axis of rotation coaxial with the main hinge axis 63a is arranged. The brake pad 30a has elevations on one side. The brake pad 30a is positively by the surveys rotationally fixed to the first bearing housing part 76a and thus with the support arm 16a connected. The brake disc 96a is positively locked against rotation with the connection housing 74a and thus with the fastening device 82a connected. The brake disc 96a is thus fixed to the seat 14a coupled. The brake pad 30a and the brake disc 96a lie in one to the main hinge axis 63a vertical plane to each other. By a movement of the support arm 16a along the swivel range 20a twist the brake disc 96a and the brake pad 30a up to today. A circular area with which the brake disc 96a and the brake pad 30a lie on each other, generates the frictional force that the arm 16a fixed in the use position.

To change the for fixing the support arm 16a provided frictional force as a function of the pivot angle, the friction unit 22a an adjustment 24a on. The adjustment element 24a has two surface contours 28a . 29a on which a change of the swivel angle mechanically into an operating force for the friction unit 22a implement. The adjustment element 24a lies with one of the surface contours 28a . 29a on a surface, resulting in moving the support arm 16a with respect to the adjusting element 24a twisted. Due to the surface contour lying on the surface 28a or the surface contour lying on the surface 29a the operating force changes along the movement of the support arm 16a ,

The adjustment element 24a is integral with the friction unit 22a educated. For the education of the setting element 24a has the friction unit 22a the brake pad 30a and the brake disc 96a on. The friction surfaces of the brake pad 30a and the brake disc 96a have the surface contours 28a . 29a on. In this embodiment, therefore, both surface contours lie 28a . 29a each other. The adjustment element 24a is by means of superimposed surface contours 28a . 29a the brake disc 96a and the brake pad 30a educated. The surface contours 28a . 29a are as two different height profiles of the brake pad 30a and the brake disc 96a educated. The surface contours 28a . 29a form a, in the circumferential direction of the superimposed circular surfaces, changing axial thickness of the brake pad 30a and the brake disc 96a out. The circumferential direction of the circular surfaces extends in the direction of the main hinge axis 63a vertical plane. The superimposed surface contours 28a . 29a forms the adjusting element 24a out. Due to the superimposed surface contours 28a . 29a an actuating force changes on the brake pad 30a and the brake disc 96a and thus the frictional force along the pivoting range 20a , Due to the changing thicknesses of the circular surfaces, changes during the movement of the support arm 16a along the swivel range 20a the frictional force of the friction unit 22a ,

The adjustment element 24a represents along the swivel range 20a a frictional Teilschwenkbereich 98a and a substantially frictionless Teilschwenkbereich 26a one. In the substantially frictionless Teilschwenkbereich 26a represents the adjustment element 24a a frictional force of the friction unit 22a from almost zero. The adjustment element 24a decoupled in the substantially frictionless Teilschwenkbereich 26a the brake disc 96a the friction unit 22a essentially from a movement of the support arm 16a ,

The frictional Teilschwenkbereich 98a extends during the movement of the support arm 16a in the direction of movement 66a from the maximum use position 68a of the support arm 16a up to an unlocked position 34a of the support arm 16a , During the movement of the support arm 16a in the direction of movement 66a is the frictional Teilschwenkbereich 98a as one to the maximum use position 68a subsequent upper Teilschwenkbereich formed. The substantially frictionless part swivel range 26a extends during the movement of the support arm 16a in the direction of movement 64a from the staging 62 of the support arm 16a up to the unlocked position 34a of the support arm 16a , During the movement of the support arm 16a in the direction of movement 64a is the substantially frictionless part swivel range 26a as one to the staging 62 subsequent lower Teilschwenkbereich trained.

In this embodiment, the unlocked position 34a of the support arm 16a defined by the tilt angle of 15 degrees. The frictional Teilschwenkbereich 98a is thus 150 degrees. The substantially frictionless part swivel range 26a is 15 degrees. Through the adjustment element 24a In a range of 15 degrees to 90 degrees, a linear increase in the frictional force takes place in the frictional partial pivoting range 98a , From the swivel angle of 90 degrees, the friction unit generates 22a a maximum frictional force, which gives them up to the maximum use position 68a constantly maintained. In a range of 90 to 165 degrees, the use position is in the frictional part pivoting range 98a adjustable.

The seat attachment device 10a further has a mounting module 50a on. The mounting module 50a partially includes a mechanical energy storage unit 32a , a power conversion unit 36a a catch unit 38a and a trip unit 40a (see. 5 ). The energy storage unit 32a , the power conversion unit 36a , the deterrent unit 38a and the trip unit 40a are in a mounting module housing 100a arranged. The mounting module housing 100a forms a common housing for the detent unit 38a , the energy storage unit 32a , the trip unit 40a and the power conversion unit 36a out. The mounting module housing 100a is about two screws with the fastening device 82a of the connection housing 74a attached. The mounting module 50a partially accesses the opening 80a of the connection housing 74a , The mounting module housing 100a is with mounted seat attachment device 10a in the armrest 52a arranged.

The mechanical energy storage unit 32a independently moves the support arm 16a in the unlocked position 34a , The energy storage unit 32a moves the arm 16a along the substantially frictionless Teilschwenkbereich 26a in the direction of movement 64a , The energy storage unit 32a has two power storage elements not shown in detail and a guide element 102 on. The energy storage elements store a force from the support arm 16a when moving in the direction of movement 66a is exercised. The power storage elements are between the guide element 102 and the mounting module housing 100a arranged. The energy storage elements are axially behind the guide element 102 arranged. The energy storage elements are each formed as a spiral spring. For guiding the guide element 102 indicates the energy storage unit 32a two guide rails 104a on. The guide element 102 can along the guide rails 104a to be moved. The energy storage unit 32a provides a linear force. The guide element 102 is designed as a guide carriage.

The power conversion unit 36a converts the linear force of the energy storage unit 32a in a torque for the support arm 16a around. The power conversion unit 36a couples the energy storage unit 32a and the support arm 16a in motion. The power conversion unit 36a includes a force conversion element 106a and an actuator 108a , The force conversion element 106a is with a screw 110a positively with the guide element 102 connected. The force conversion element 106a protrudes from the mounting module housing 100a out and engages with mounted mounting module 50a in the opening 80a one. The force conversion element 106a is as a cylinder with two recesses 112 . 114 educated. The first recess 112a has an inclined surface. One end of the force conversion element 106a with the first recess 112a partially engages in the guide element 102 , The end of the force conversion element 106a with the first recess 112a is about the screw 110a with the guide element 102 connected. Another end of the force conversion element 106a is in the staging 62 and the unlocking position 34a of the support arm 16a on the actuating element 108a , The actuator 108a is designed as a bolt. The actuator 108a is fixed to the support arm 16a connected. The actuator 108a engages offset to the main hinge axis 63a on the support arm 16a at. Will the actuator 108a through the energy storage unit 32a Applied to the linear force, it causes that on the support arm 16a acting torque.

The catch unit 38a locks the support arm 16a and the energy storage unit 32a at the same time form-fitting. The catch unit 38a locks the support arm 16a and the energy storage unit 32a in the staging 62 , The catch unit 38a includes two separate latch engagement elements 42a . 44a and two separate latch receiving elements 116a . 118a ,

The detent engagement element 42a and the latch receiving element 116a lock the arm directly 16a in the staging 62 , The detent engagement element 42a is with respect to the mounting module housing 100a rotatably arranged. The detent engagement element 42a has an axis of rotation. With mounted mounting module 50a is the axis of rotation of the latching engagement element 42a parallel to the mounting plane of the connection housing 74a arranged. The locking receiving element 116a is fixed to the support arm 16a connected. For interlocking connection engages the latching engagement element 42a in the locking receiving element 116a and holds the support arm 16a in the staging 62 firmly. The detent engagement element 42a protrudes from the mounting module housing 100a out and engages with mounted mounting module 50a through the opening 80a , The detent engagement element 42a is designed as a double latching hook. At the staging 62 grab the force conversion element 106a and the actuator 108a the power conversion unit 36a between the double locking hooks through. The locking receiving element 116a is designed as a latching hook receptacle. For secure gripping of the catch engagement element 42a in the locking receiving element 116a has the catch unit 38a a first power storage element 120a on. The first energy storage element 120a is designed as a spiral spring. The first energy storage element 120a exerts a force that the latch engagement element 42a against the latch receiving element 116a suppressed.

The detent engagement element 44a and the latch receiving element 118a lock directly the energy storage unit 32a in the staging 62 , The detent engagement element 44a is with respect to the mounting module housing 100a rotatably arranged. The detent engagement element 44a has an axis of rotation. With mounted mounting module 50a is the axis of rotation of the latching engagement element 44a parallel to the mounting plane of the connection housing 74a arranged. For interlocking connection engages the latching engagement element 44a in the locking receiving element 118a and keeps the linear force of the energy storage unit 32a firmly. The detent engagement element 44a is designed as a latching hook. The detent engagement element 44a has a vertical surface and an inclined surface. The locking receiving element 118a is designed as a latching hook receptacle. The second recess 114a the force conversion element 106a forms the catch hook receptacle 118a out. In the staging 62 lies the vertical surface of the latching engagement element 44a on a vertical surface of the second recess 114a and thus locks the energy storage unit 32a , In the unlocked position 34a of the support arm 16a grips the detent engagement element 44a with the vertical surface and the inclined surface partially in the first recess 112a ,

For secure gripping of the catch engagement element 44a in the locking receiving element 118a has the catch unit 38a a second force storage element 122a on. The second energy storage element 122a exerts a force that the latch engagement element 44a in the locking receiving element 118a suppressed. The second energy storage element 122a is designed as a leaf spring.

For motion-technical coupling of the release of the locking of the support arm 16a and the energy storage unit 32a from the staging 62 has the catch unit 38a a coupling element 46a on. The coupling element 46a couples the latching engagement element 42a and the latch engagement element 44a together. The coupling element 46a has a simple ending 124a and a double end 126a on. The coupling element 46a is formed tuning fork-shaped. The coupling element 46a points to the simple end 124a and at the double end 126a a recess on. The recess at the double end 126a is formed as a circular hole. The coupling element 46a is with the double end 126a by a connecting pin with the latching engagement element 44a connected.

To the locking of the support arm 16a and the latching of the energy storage unit 32a temporally successively to solve, the recess is at the simple end 124a designed as a slot. The coupling element 46a is with the simple end 124a by a connecting pin on the slot formed as a slot with the latching engagement element 42a connected. By formed as a slot recess has the connection of the coupling element 46a with the latching engagement element 42a Play on.

The trip unit 40a actuates the detent unit 38a to the latching of the support arm 16a and the latching of the energy storage unit 32a to solve together. The trip unit 40a releases the movement of the support arm 16a from the staging 62 in the unlocked position 34a out. The trip unit 40a includes one from the mounting module housing 100a outstanding trigger button 128a and a pull mechanism, which the user depresses by activating the release button 128a triggers. The pulling mechanism engages with a, from the mounting module housing 100a outstanding staff 130a in a recess of the latching engagement element 42a one. By pressing the release button 128a pull mechanism pulls the detent engagement element 42a from the latch receiving element 116a and then via the coupling element 46a the detent engagement element 44a from the latch receiving element 118a , By that in the simple end 124a of the coupling element 46a existing game becomes when pressing the trigger button 128a first the latch engagement element 42a and temporally offset the detent engagement element 44a pulled out of its catch. With seat attachment device mounted 10a with the mounting module 50a on the armrest 52a the trigger button sticks out 128a vertically from the armrest 52a out. Basically, the trigger button 128a but also be arranged horizontally.

In an operating sequence of the seat attachment device 10a in which the user the arm 16a , starting from the staging 62 , wants to set in a use position, the user presses the release button 128a the trip unit 40a , By pressing the release button 128a triggers the trip unit 40a together the locking of the energy storage unit 32a and the locking of the support arm 16a , This triggers the trip unit 40a first the locking of the support arm 16a and then the locking of the energy storage unit 32a , The energy storage unit 32a then sets the of the behind the guide element 102 arranged force storage elements stored linear force, whereby a translational movement of the guide element 102 results. The power conversion unit 36a converts the linear force or the translatory movement of the energy storage unit 32a in a torque or in a rotational movement of the support arm 16a um, by the force conversion element 106a against that with the support arm 16a firmly connected actuator 108a suppressed. The actuator 108a moves the arm 16a in the direction of movement 64a along the substantially frictionless Teilschwenkbereich 26a in the unlocked position 34a ,

In the absence of external force by the user holding the energy storage unit 32a the support arm 16a in the unlocked position 34a firmly. Starting from the unlocked position 34a represents the user by moving the support arm 16a in the direction of movement 64a along the frictional Teilschwenkbereich 98a the desired use position, wherein of the unlocked position 34a up to the pivot angle of 90 degrees, the adjustment 24a the friction force builds up or absorbs linearly. This is the power conversion element 106a no longer on the actuator 108a at. The friction unit 22a holds the set position of use by means of the frictional force. Through the joints 90a . 92a the user adjusts the use position of the object designed as a monitor 12a ,

In an operating sequence of the seat attachment device 10a in which the user the arm 16a , starting from the use position, in the stowage 62 to adjust, the user moves the support arm 16a in the direction of movement 66a along the frictional Teilschwenkbereich 98a in the unlocked position 34a , This builds the adjustment 24a the friction force from the pivot angle of 90 degrees to the unlocked position 34a linearly. The energy storage unit 32a holds in the absence of external force by the user the support arm 16a in the unlocked position 34a firmly. In the unlocked position 34a is the actuator 108a again at the power conversion element 106a at. Starting from the unlocked position 34a the user moves the support arm 16a in the direction of movement 66a along the substantially frictionless Teilschwenkbereich 26a in the staging 62 ,

When moving the support arm 16a in the direction of movement 66a along the substantially frictionless Teilschwenkbereich 26a the user merely overcomes the force behind the guide element 102 arranged force storage elements of the energy storage unit 32a , In the Movement of the support arm 16a in the direction of movement 66a along the substantially frictionless Teilschwenkbereich 26a saves the energy storage unit 32a the force applied by the user. The brake disc 96a the friction unit 22a is from the movement of the support arm 16a decoupled. By moving the support arm 16a in the direction of movement 66a along the substantially frictionless Teilschwenkbereich 26a converts the power conversion unit 36a the torque applied by the user in a linear force. This linear force stores the energy storage elements of the energy storage unit 32a , This linear force is the force that drives the arm 16a when pressing the release button 128a in the unlocked position 34a emotional. The stowage 62 is when snapping the latch unit 38a set.

The 6 . 7 and 8th show a second embodiment of a seat attachment device 10b , The seat attachment device 10b is designed as a passenger seat mounting device. The seat attachment device 10b attached to a non-illustrated, designed as a monitor object movable on a seat 14b , The seat 14b includes an armrest 52b into which the seat attachment device 10b is arranged. The armrest 52b is designed as an armrest console. The seat 14b has feet by means of which the seat 14b attached to a floor of an aircraft. The seat 14b is designed as a passenger seat.

In a staging 62b the seat attachment device 10b (see. 7 and 9 ) can be the subject of the user who is in the seat 14b sits, not used. In the staging 62b is designed as a monitor object within the armrest 52b arranged. The seat attachment device 10b is in the staging 62b entirely in the armrest 52b arranged. In a use position of the seat attachment device 10b (see section in dashed lines in 6 ) can be the subject of a user in the seat 14b sits, be used. In the use position, a screen plane of the object designed as a monitor points in the direction of a backrest 60b of the seat 14b , The one on the seat 14b seated user has thus arranged the monitor designed as an object in front of him. Only a support arm 16b the seat attachment device 10b protrudes from the armrest in the use position 52b ,

The seat attachment device 10b includes the support arm 16b and a main hinge unit 18b , The main hinge unit 18b has a swivel joint. The hinge has a main axis of articulation formed as an axis of rotation 63b on. The main hinge unit 18b guides the arm 16b relative to the seat 14b along a pivoting range 20b , The swivel range 20b forms an angular range in which the support arm 16b is pivotable. By means of the main hinge unit 18b can the support arm 16b in a direction of movement 64b and a direction of movement 66b to be moved. By the movement of the support arm 16b in the direction of movement 64b will, starting from the stowage 62b , a use position set. By the movement of the support arm 16b in the direction of movement 66b is based on the use position, the stowage 62b set. The stowage 62b of the support arm 16b defines a pivoting angle of the support arm 16b from zero. A maximum use position 68b defines a maximum swing angle of the support arm 16b , In this embodiment, the maximum swing angle is 103 degrees. The swivel range 20b of the support arm 16b in this embodiment is thus 103 degrees.

The main hinge unit 18b has a bearing housing 72b and a connection housing 74b on. The bearing housing 72b includes a warehouse. The connection housing 74b surrounds the bearing housing 72b , The connection housing 74b has a side that has a fastening device 82b formed. By means of the fastening device 82b is the arm 16b in the seat 14b attached. The connection housing 74b is fixed to the armrest 52b connected. The bearing housing 72b is regarding the connection housing 74b rotatably arranged. The side for fixing the connection housing 74b defines a mounting plane. The main joint axis 63b the main hinge unit 18b runs parallel offset to the mounting plane. The main hinge unit 18b is in every position of the seat attachment device 10b inside the armrest 52b arranged.

The support arm 16b is formed in three parts. The support arm 16b has a Tragarmstück 84b , an intermediate piece 86b and a device receptacle 88b on. The designed as a monitor object is on the device receptacle piece 88b assembled. Next includes the support arm 16b two joints 90b . 92b , The first joint 90b is between the Tragarmstück 84b and the intermediate piece 86b arranged. The second joint 92b is between the intermediate piece 86b and the device receptacle 88b arranged.

The support arm piece 84b is fixed to a part of the main hinge unit 18b connected. About the main hinge unit 18b is the Tragarmstück 84b movable with the fastening device 82b connected. The support arm piece 84b has a main extension direction, which in the use position in a viewing direction 94b in the seat 14b sitting user perpendicular to the main hinge axis 63b the main hinge unit 18b is aligned.

The support arm piece 84b is about the first joint 90b movable with the intermediate piece 86b connected. The first joint 90b has a first hinge axis designed as a rotation axis. The first joint 90b is designed as a hinge. The first joint axis of the first joint 90b runs in the axial extension of Tragarmstücks 84b , The first joint axis of the first joint 90b is axially parallel to the main extension direction of Tragarmstücks 84b oriented. The first joint axis tensions with the main joint axis 63b a level up. In the direction of view 94b is the first hinge axis perpendicular to the main hinge axis 63b oriented. The first joint 90b leads the intermediate piece 86b relative to Tragarmstück 84b along an adjustment range.

The intermediate piece 86b is about the second joint 92b movable with the device receptacle 88b connected. The second joint 92b has a second axis of articulation designed as a rotation axis. The second joint 92b is designed as a hinge. The second hinge axis of the second joint 92b is axially parallel to a main extension direction of the device receptacle piece 88b oriented. The first hinge axis and the second hinge axis intersect perpendicularly at one point. The two joint axes span a plane. The second joint 92b leads the device receptacle 88b relative to the intermediate piece 86b along an adjustment range. The intermediate piece 86b couples the Tragarmstück 84b with the device receptacle piece 88b , The intermediate piece 86b is between the Tragarmstück 84b and the device receptacle 88b arranged.

For loading the main hinge unit 18b with a friction force for fixing the support arm 16b in the use position, the seat attachment device 10b a friction unit 22b on. To provide the frictional force, the friction unit 22b a brake pad 30b and a brake disc 96b on. The brake pad 30b and the brake disc 96b have a common axis of rotation coaxial with the main hinge axis 63b is arranged. The brake pad 30b has elevations on one side. The brake pad 30b is by the surveys positively locked against rotation with the bearing housing 72b and thus with the support arm 16b connected. The brake disc 96b is positively locked against rotation with the connection housing 74b and thus with the fastening device 82b connected. The brake disc 96b is thus fixed to the seat 14b coupled. The brake pad 30b and the brake disc 96b lie in one to the main joint axis 63b vertical plane to each other. By a movement of the support arm 16b along the swivel range 20b twist the brake disc 96b and the brake pad 30b up to today. A circular area with which the brake disc 96b and the brake pad 30b lie on each other, generates the frictional force that the arm 16b fixed in the use position.

To change the for fixing the support arm 16b provided frictional force as a function of the pivot angle, the friction unit 22b an adjustment 24b on. The adjustment element 24b has two surface contours 28b . 29b on which a change of the swivel angle mechanically into an operating force for the friction unit 22b implement. The adjustment element 24b lies with one of the surface contours 28b . 29b on a surface, resulting in moving the support arm 16b with respect to the adjusting element 24b twisted. Due to the superimposed surface contours 28b . 29b on the surface, the actuating force differs along the movement of the support arm 16b ,

The adjustment element 24b is integral with the friction unit 22b educated. For the formation of the adjustment 24b has the friction unit 22b the brake pad 30b and the brake disc 96b on. The friction surfaces of the brake pad 30b and the brake disc 96b have the surface contours 28b . 29b on. In this embodiment, therefore, both surface contours lie 28b . 29b each other. The adjustment element 24b is by means of superimposed surface contours 28b . 29b the circular surfaces of the brake disc 96b and the brake pad 30b educated. The surface contours 28b . 29b are as two different height profiles of the brake pad 30b and the brake disc 96b educated. The surface contours 28b . 29b form a, in the circumferential direction of the superimposed circular surfaces, changing axial thickness of the brake pad 30b and the brake disc 96b out. The circumferential direction of the circular surfaces extends in the direction of the main hinge axis 63b vertical plane. The superimposed surface contours 28b . 29b form the adjustment element 24b out. Due to the superimposed surface contours 28b . 29b changes an operating force of the brake pad 30b and the brake disc 96b and thus the frictional force along the pivoting range 20b , Due to the changing thicknesses of the circular surfaces changes during the movement of the support arm 16b along the swivel range 20b the frictional force of the friction unit 22b ,

The adjustment element 24b represents along the swivel range 20b a frictional Teilschwenkbereich 98b and a substantially frictionless Teilschwenkbereich 26b one. In the substantially frictionless Teilschwenkbereich 26b represents the adjustment element 24b a frictional force of the friction unit 22b from almost zero. The adjustment element 24b decoupled in the substantially frictionless Teilschwenkbereich 26b the brake disc 96b the friction unit 22b essentially from a movement of the support arm 16b ,

The frictional Teilschwenkbereich 98b extends during the movement of the support arm 16b in the direction of movement 66b from the maximum use position 68b of the support arm 16b up to an unlocked position 34b of the support arm 16b , During the movement of the support arm 16b in the direction of movement 66b is the frictional Teilschwenkbereich 98b as one to the maximum use position 68b subsequent upper Teilschwenkbereich formed. The substantially frictionless part swivel range 26b extends during the movement of the support arm 16b in the direction of movement 64b from the staging 62b of the support arm 16b up to the unlocked position 34b of the support arm 16b , During the movement of the support arm 16b in the direction of movement 64b is the substantially frictionless part swivel range 26b as one to the staging 62b subsequent lower Teilschwenkbereich trained.

Through the adjustment element 24b continues in an area in the frictional Teilschwenkbereich 98b a linear increase in frictional force. From a swivel angle generates the friction unit 22b a maximum frictional force, which gives them up to the maximum use position 68b constantly maintained. From the swing angle in which the adjustment 24b the maximum frictional force provides, is the use position in the frictional Teilschwenkbereich 98b up to the maximum utilization position 68b adjustable.

For autonomous movement of the support arm 16b in the unlocked position 34b has the seat attachment device 10b a mechanical energy storage unit 32b on (cf. 8th ). The energy storage unit 32b moves the arm 16b along the substantially frictionless Teilschwenkbereich 26b in the direction of movement 64b , The energy storage unit 32b has a force storage element 132b and a guide element 102b on. The energy storage element 132b stores a force coming from the support arm 16b when moving in the direction of movement 66b is exercised. The energy storage element 132b is axially behind the guide element 102b arranged. The energy storage element 132b is between the connection housing 74b and the guide element 102b arranged. The energy storage element 132b is designed as a spiral spring. For guiding the guide element 102b indicates the energy storage unit 32b a guide rail 104b on. The guide element 102b can along the guide rail 104b to be moved. The energy storage unit 32b provides a linear force. The guide element 102b is designed as a guide carriage.

For converting the linear movement of the energy storage unit 32b in a torque for the support arm 16b has the seat attachment device 10b a power conversion unit 36b on. The power conversion unit 36b couples the energy storage unit 32b and the support arm 16b in motion. The power conversion unit 36b includes a force conversion element 106b and an actuator 108b , The power conversion unit 36b is designed as a rack drive. The force conversion element 106b is integral with the guide element 102b educated. The force conversion element 106b is as a toothing of the guide element 102b educated. The trained as a toothed force conversion element 106b has five teeth, wherein a tooth is formed as a half-tooth with shortened tooth head. The actuator 108b has a toothing. The toothing of the actuating element 108b is corresponding to the form of a toothed force conversion element 106b educated. The toothing of the actuating element 108b has four teeth. The toothing of the actuating element 108b engages in the force conversion element 106b and meshes with the force conversion element 106b , The actuator 108b is by means of two screws 134b firmly with the main hinge unit 18b connected.

To the arm 16b and the energy storage unit 32b at the same time positively locking, has the seat attachment device 10b a detent unit 38b on. The catch unit 38b locks the support arm 16b directly and the energy storage unit 32b indirectly in the staging 62b , For locking the support arm 16b and the energy storage unit 32b has the catch unit 38b a common latching element 48b and a common latch receiving element 136b on. The detent engagement element 48b and the latch receiving element 136b lock the support arm 16b and the energy storage unit 32b in the staging 62b , The common latching element 48b and the common latch receiving element 136b the detent unit 38b lock the support arm 16b indirectly via the power conversion unit 36b in the staging 62b ,

The detent engagement element 48b is regarding the connection housing 74b rotatably arranged. The detent engagement element 48b has an axis of rotation. The axis of rotation of the latching engagement element 48b is parallel to the mounting plane of the connection housing 74b arranged. The locking receiving element 136b is fixed to the guide element with a screw 102b connected. For positive connection the latch receiving element engages 136b into the latching engagement element 48b and holds the energy storage unit 32b and about the power conversion unit 36b the support arm 16b in the staging 62b firmly. For secure gripping of the locking receiving element 136b into the latching engagement element 48b has the catch unit 38b a force storage element 138b on. The energy storage element 138b is designed as a coil spring. The energy storage element 138b exerts a force that the latch engagement element 48b down against the latch receiving element 136b suppressed.

For actuating the detent unit 38b to put together the latching of the support arm 16b and the latching of the energy storage unit 32b to solve, has the seat attachment device 10b a trip unit 40b on. The trip unit 40b releases the movement of the support arm 16b in the unlocked position 34b out. To release the locking of the energy storage unit 32b and thus for releasing the locking of the support arm 16b in the staging 62b indicates the trip unit 40b a staff 130b on. The rod 130b lies with one end on the latch engagement element 48b , Another end of the staff 130b is due to a trigger button 128b , So the staff 130b safely on the trigger button 128b abuts, the trip unit 40b a force storage element 140b on. The energy storage element 140b is designed as a spiral spring. The energy storage element 140b is between a survey of the staff 130b and one, with the hinge of the main hinge unit 18b firmly connected support 142b arranged. The energy storage element 140b moves the staff 130b in a starting position in which the rod 130b on the trigger button 128b is applied and no force on the latch engagement element 48b exercises.

The trigger button 128b is in a recess in the Tragarmstück 84b arranged. The trigger button 128b is with respect to a housing of Tragarmstücks 84b rotatably disposed in the recess. The trigger button 128b has an axis of rotation. The axis of rotation is parallel to the main joint axis 63b arranged. To the trigger button 128b to move to an initial position after actuation, the trip unit 40b another power storage element 144b on. The energy storage element 144b is designed as a spiral spring. By pressing the release button 128b the staff pushes 130b on the latching engagement element 48b , which causes the latch engagement element 48b twisted and the positive connection is released.

The catch unit 38b , the energy storage unit 32b , the trip unit 40b and the power conversion unit 36b are in the connection housing 74b integrated. Save the trigger button 128b are the elements of the detent unit 38b , the energy storage unit 32b , the trigger unit 40b and the power conversion unit 36b not visible.

In an operating sequence of the seat attachment device 10b in which the user the arm 16b , starting from the staging 62b , wants to set in a use position, the user presses the release button 128b the trip unit 40b , By pressing the release button 128b triggers the trip unit 40b together the locking of the energy storage unit 32b and about the power conversion unit 36b the locking of the support arm 16b , The energy storage unit 32b then releases the stored linear force, causing a translational movement of the guide element 102b results. The power conversion unit 36b converts the linear force or the translatory movement of the energy storage unit 32b in a torque or in a rotational movement of the support arm 16b around. Due to the positive connection of the guide element 102b with the hinge of the main hinge unit 18b due to the power conversion unit 36b moves the energy storage unit 32b independently the support arm 16b in the direction of movement 64b along the substantially frictionless Teilschwenkbereich 26b in the unlocked position 34b ,

In the absence of external force by the user holding the energy storage unit 32b the support arm 16b in the unlocked position 34b firmly. Starting from the unlocked position 34b represents the user by moving the support arm 16b in the direction of movement 64b along the frictional Teilschwenkbereich 98b the desired use position, wherein of the unlocked position 34b up to the pivoting angle in which the adjustment unit 24b provides the maximum frictional force, the adjustment 24b the friction force builds up or absorbs linearly. The teeth of the actuator engages 108b no longer in the form of a toothed force conversion element 106b , The friction unit 22b holds the desired position of use by a frictional force. Through the joints 90b . 92b the user adjusts the use position of the object designed as a monitor.

In an operating sequence of the seat attachment device 10b in which the user the arm 16b , starting from the use position, in the stowage 62b to adjust, the user moves the support arm 16b in the direction of movement 66b along the frictional Teilschwenkbereich 98b in the unlocked position 34b , This builds the adjustment 24b the friction force from a swivel angle to the unlocked position 34b linearly. The energy storage unit 32b holds in the absence of external force by the user the support arm 16b in the unlocked position 34b firmly. In the unlocked position 34b engages the toothing of the actuating element 108b again partially in the form of a toothed force conversion element 106b , Starting from the unlocked position 34b the user moves the support arm 16b in the direction of movement 66b along the substantially frictionless Teilschwenkbereich 26b in the staging 62b ,

When moving the support arm 16b in the direction of movement 66b along the substantially frictionless Teilschwenkbereich 26b the user merely overcomes the force of the force storage element 132b , The brake disc 96b the friction unit 22b is from the movement of the support arm 16b decoupled. By moving the support arm 16b in the direction of movement 66b along the substantially frictionless Teilschwenkbereich 26b converts the power conversion unit 36b the torque applied by the user into a linear force. This linear force stores the force storage element 132b , This linear force is the force that drives the arm 16b when pressing the release button 128b in the unlocked position 34b emotional. The stowage 62b is when snapping the latch unit 38b set.

LIST OF REFERENCE NUMBERS

10

Seat hitch

12

object

14

Seat

16

Beam

18

Main joint unit

20

swivel range

22

Friction unit

24

adjustment

26

substantially frictionless part pivoting range

28

surface contour

29

surface contour

30

brake lining

32

Energy storage unit

34

unlocking

36

Power conversion unit

38

catch unit

40

trip unit

42

separate catch engagement element

44

separate catch engagement element

46

coupling element

48

common catch engagement element

50

mounting module

52

armrest

54

seat foot

56

ground

58

screen plane

60

backrest

62

stowed

63

Main articulation axis

64

movement direction

66

movement direction

68

maximum utilization position

70

camp

72

bearing housing

74

connection housing

76

first bearing housing part

78

second bearing housing part

80

opening

82

fastening device

84

Tragarmstück

86

connecting piece

88

Devices receiving piece

90

joint

92

joint

94

line of sight

96

brake disc

98

frictional partial pivoting range

100

Mounting module housing

102

guide element

104

guide rail

106

Power conversion element

108

actuator

110

screw

112

first recess

114

second recess

116

separate detent receiving element

118

separate detent receiving element

120

first power storage element

122

second force storage element

124

easy ending

126

double end

128

release button

130

Rod

132

Power storage element

134

screw

136

common catch receiving element

138

Power storage element

140

Power storage element

142

supporting

144

Power storage element

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19725347 A1 [0002]

Claims (15)

Seat attachment device, in particular passenger seat attachment device, for movably securing an object ( 12a ) on a seat ( 14a ; 14b ), with a support arm ( 16a ; 16b ), with at least one main hinge unit ( 18a ; 18b ), which is intended to support the arm ( 16a ; 16b ) along a swivel range ( 20a ; 20b ) relative to the seat ( 14a ; 14b ), and with at least one friction unit ( 22a ; 22b ), which is intended for fixing the support arm ( 16a ; 16b ) in at least one use position the main hinge unit ( 18a ; 18b ) to act on a frictional force, characterized in that the friction unit ( 22a ; 22b ) at least one adjusting element ( 24a ; 24b ), which is intended, the frictional force for fixing the support arm ( 16a ; 16b ) in response to a tilt angle. Seat mounting device according to claim 1, characterized in that the adjusting element ( 24a ; 24b ) is provided, a substantially frictionless Teilschwenkbereich ( 26a ; 26b ). Seat-mounted device according to claim 1 or 2, characterized in that the adjusting element ( 24a ; 24b ) at least one surface contour ( 28a . 29a ; 28b . 29b ), which is intended to mechanically change a change in the swivel angle into an operating force for the friction unit (FIG. 22a ; 22b ) implement. Seat attachment device according to one of the preceding claims, characterized in that the friction unit ( 22a ; 22b ) and the adjustment element ( 24a ; 24b ) are formed at least partially in one piece. Seat attachment device according to one of the preceding claims, characterized in that the friction unit ( 22a ; 22b ) for forming the adjusting element ( 24a ; 24b ) at least one brake pad ( 30a ; 30b ) whose friction surface is the surface contour ( 28a . 29a ; 28b . 29b ) having. Seat attachment device according to one of the preceding claims, characterized by at least one energy storage unit ( 32a ; 32b ), which is intended to support the arm ( 16a ; 16b ) automatically into an unlocking position ( 34a ; 34b ) to move. Seat attachment device according to one of the preceding claims, characterized by at least one force conversion unit ( 36a ; 36b ), which is intended to a linear force of the energy storage unit ( 32a ; 32b ) in a torque for the support arm ( 16a ; 16b ) to convert. Seat attachment device according to one of the preceding claims, characterized by at least one latch unit ( 38a ; 38b ), which is intended to support the arm ( 16a ; 16b ) and the energy storage unit ( 32a ; 32b ) at the same time positively lock. Seat attachment device according to one of the preceding claims, characterized by at least one triggering unit ( 40a ; 40b ), which is intended to jointly release the locking of the support arm ( 16a ; 16b ) and the latching of the energy storage unit ( 32a ; 32b ) the detent unit ( 38a ; 38b ). Seat attachment device according to claim 8 or 9, characterized in that the catch unit ( 38a ) at least two separate latch engagement elements ( 42a . 44a ) and at least one coupling element ( 46a ), wherein the coupling element ( 46a ) is provided, the release of the latching of the support arm ( 16a ) and the energy storage unit ( 32a ) to couple motion technology. Seat mounting device according to claim 10, characterized in that the coupling element ( 46a ) is provided, the latching of the support arm ( 16a ) and the energy storage unit ( 32a ) in chronological order. Seat attachment device according to claim 8 or 9, characterized in that the catch unit ( 38b ) a common latch engagement element ( 48b ) for the locking of the support arm ( 16b ) and the energy storage unit ( 32b ) having. Seat-mounted device according to one of claims 6 to 11, characterized by a mounting module ( 50a ) that the energy storage unit ( 32a ), the force conversion unit ( 36a ), the detent unit ( 38a ) and the trip unit ( 40a ) at least partially. Seat, in particular passenger seat, with a seat mounting device ( 10a ; 10b ) according to one of claims 1 to 13. Method for a seat mounting device, in particular a passenger seat mounting device, for movably fastening an object ( 12a ) on a seat ( 14a ; 14b ), with a support arm ( 16a ; 16b ), with at least one main hinge unit ( 18a ; 18b ) supporting the arm ( 16a ; 16b ) along a swivel range ( 20a ; 20b ) relative to the seat ( 14a ; 14b ), and with a friction unit ( 22a ; 22b ), the for fixing the support arm ( 16a ; 16b ) in at least one use position the main hinge unit ( 18a ; 18b ) subjected to a frictional force, characterized in that the friction unit ( 22a ; 22b ) at least one adjusting element ( 24a ; 24b ), the frictional force for fixing the support arm ( 16a ; 16b ) changed in response to a tilt angle.

Images