DE20020229U1 - Device for storing a hinged lid, in particular a piano lid - Google Patents

Description

Z£I1£ER.&DICKEL PATENT ATTORNEYS EUROPEAN PATENT AND TRADEMARK ATTORNEYS

PO BOX 26 02 51 TELEPHONE: +49-89-22 18 06 HERRNSTRASSE 15

D-80059 MUNICH FAX: +49-89-22 26 27 D-80539 MUNICH

Johann Weinberger Sieding 4

A-4483 Hargelsberg

Device for supporting a hinged lid, in particular a piano lid

The invention relates to a device for supporting a hinged lid, in particular a piano lid, with a pot-like housing receiving a bearing pin, which forms a fluid-filled damping chamber for a rotary damper, the rotor of which is formed from the bearing pin and has a damping attachment dividing the damping chamber into two displacement sections.

In order to prevent, for example, the weight-related, undamped folding of a piano lid over the keyboard, the use of rotary dampers is known (EP 0 697 541 A1). These have a rotor that is rotatably inserted into a cylinder, leaving an annular gap free, which forms a damping attachment that protrudes radially into the annular space. This damping attachment divides the annular space, which is delimited by a radial partition of the cylinder and filled with a viscous fluid, into two displacement sections. Since the damping attachment carries a pivoting valve flap that rests against the cylinder wall in one direction of rotation of the rotor, but opens up a flow path between the cylinder wall and the damping attachment in the opposite direction of rotation of the rotor,

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In the direction of rotation of the rotor, effective damping of the rotary movement can be achieved for the blocking valve flap, which is only permitted to the extent that the viscous fluid is displaced past the valve flap from one displacement section of the annular space forming a damping chamber to the other. A disadvantage of this known rotary damper, however, is the comparatively high construction effort, in particular due to the valve flap mounted on the damping attachment of the rotor. In addition, such rotary dampers are used in addition to the rotary bearing for the hinged lid, which entails increased effort because the cylinder on the one hand and the rotor on the other have to be provided with support arms that are spring-loaded against each other, of which the support arm assigned to the lid carries a bearing roller in order to be able to lift the lid off its rotary bearing without dismantling the rotary damper.

In order to avoid such support arms, it is known (US 5 635 655 A) to design the pivot pin for the hinged cover as a rotor for the rotary damper, but the construction effort remains comparatively high because a damping attachment protruding radially into the annular damping chamber is provided with a valve that consists of a slider resting on the peripheral wall of the damping chamber, which opens a flow path between the two displacement sections in one direction of rotation of the rotor, but throttles the fluid flow between the displacement sections in the opposite direction of rotation. This high level of design effort is also to be accepted in other known rotary dampers, in which valve bodies are provided between the radial damping attachment of the rotor and the peripheral wall of the damping chamber, which throttle or release the flow path between the displacement sections depending on the direction of rotation, and which are adjusted relative to the damping attachment of the rotor either in the peripheral direction (JP 6193666 A, EP 0 529 313 A2) or in the radial direction (JP 10205567 A). If the flow paths controlled by valves are guided through the damping attachment of the rotor (US 5 064 033 A) or through a housing wall separating the two displacement sections of the annular damping chamber from each other (DE 37 18 858 A1), the design effort required by the valve arrangement remains high.

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which is further increased if the flow path between the displacement sections of the damping chamber is controlled by rolling elements that interact with cam tracks (JP 10292723 A).

The invention is therefore based on the object of designing a device for supporting a hinged lid, in particular a piano lid, of the type described at the outset in such a way that effective damping of the rotary movement of the hinged lid can be ensured with simple structural means, without having to use complex rotary dampers.

The invention solves the problem in that the damping chamber consists of a groove provided on the inside of the housing base, which runs along a circular arc coaxial with the housing, and in that the damping projection protruding axially against the groove base on the front side of the bearing pin forming the rotor engages with a clearance fit in the groove, which is covered by the bearing pin relative to the housing.

Due to these measures, a simple construction is achieved despite effective damping, because only the bearing pin forming the rotor has to be provided with a damping projection that protrudes axially against the groove base and engages with a clearance fit in the groove in the housing base that forms the damping chamber. Since this groove is covered by the adjacent front side of the bearing pin, when the bearing pin is rotated in the housing, viscous fluid between the bearing pin and the adjacent groove walls must be displaced from one displacement section of the damping chamber formed by the groove to the other, which, with an appropriate selection of the clearance fit dependent on the viscosity of the fluid, leads to very effective damping of the rotary movement of the bearing pin within the pot-like housing.

In order to achieve a good seal between the housing and the viscous fluid in the damping chamber, no front seal is required between the bearing journal and the housing base. Instead, a proven, structurally simple circumferential seal is sufficient, with the bearing journal being

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at least one sealing ring is used to seal the housing against the peripheral wall. However, it must be ensured that the throttling points caused by the clearance between the damping projection and the groove cannot be bypassed via a free space between the housing base and the front side of the bearing journal. For this purpose, the bearing journal can be spring-loaded in the axial direction against the housing base, which at the same time allows for advantageous tolerance compensation. This spring-loaded support of the rotating bearing journal can be achieved with simple structural means in particular if the bearing journal is axially supported on an elastomer housing cover which has a through-opening for a coupling projection of the bearing journal. With the help of this coupling projection of the bearing journal which protrudes over the pot-like housing, the respective hinged cover can be connected to the bearing journal in a simple manner in a rotationally fixed manner. The coupling projection can be designed in different ways. In the simplest case, the coupling attachment of the bearing journal has flattened portions arranged in pairs opposite each other.

In order to be able to introduce the viscous fluid into the damping chamber with little effort and without hindering the assembly of the rotary bearing, the housing base can have a closable filling opening for the damping chamber formed from the groove. This measure makes it possible to fill the viscous fluid after the rotary bearing has been assembled, which goes hand in hand with simple dosing of the filling quantity.

The subject matter of the invention is shown by way of example in the drawing. Fig. 1 shows a device according to the invention for storing a hinged lid in a

simplified axial section and
Fig. 2 this device in a section along the line H-II of Fig. 1.

The pivot bearing shown has a circular cylindrical, pot-like housing 1 with a mounting flange 2, which can be inserted, for example, into a cylindrical recess in the side walls that border the keyboard area of a piano. The hinged cover to be mounted is then placed on the

4t »· · * *♦♦·

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in the housing 1, the bearing pin 3 is mounted in a radial direction and for this purpose forms a coupling projection 5 provided with flattened portions 4 lying opposite one another in pairs and projecting axially beyond the fastening flange 2 of the housing 1.

In contrast to conventional pivot bearings of this type, a groove 7 is provided in the base 6 of the housing 1, which runs along a circular arc coaxial with the housing 1, as can be seen in Fig. 2. This groove 7 is covered by the front side 8 of the bearing pin 3 when the bearing pin 3 is pressed resiliently in the axial direction against the housing base 6. For this purpose, the pot-shaped housing 1 is closed with an elastomeric bearing cover 9, which forms a passage opening 10 for the coupling projection 5 of the bearing pin 3 and is held by a snap ring 11. An eccentric damping projection 12 is provided on the front side 8 of the bearing pin 3, which projects axially against the groove base and engages in the groove 7 with a clearance fit. Since the groove 7 is filled with a viscous fluid 13 and the damping projection 12 divides the groove 7 into two displacement sections 14 and 15, when the bearing pin 3 rotates in the housing 1, viscous fluid must be displaced via the damping projection 12 between the displacement sections 14 and 15. This fluid displacement takes place via the throttle gaps resulting between the damping projection 12 and the groove 7 due to the clearance fit, which leads to advantageous damping of the rotary movement of the bearing pin 3 within the housing 1.

In order to be able to easily fill the damping chamber formed by the groove 7 and divided into two displacement sections 14 and 15 by the damping projection 12 with the viscous liquid 13, the housing base 6 has a filling opening 17 which can be closed, for example, by a screw plug 16. The housing 1 is sealed against the viscous liquid 13 in a proven manner by two sealing rings 18 which are inserted into annular grooves in the bearing pin 3 and seal it against the peripheral wall 19 of the housing 1.

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It is probably not necessary to explain in more detail that the invention is not limited to the embodiment. For example, the damping projection 12 of the bearing pin 3 could have a transverse bore with an inserted check valve in order to limit the damping effect to one direction of rotation. However, this will generally not be necessary.

Claims (5)

1. Device for supporting a hinged lid, in particular a piano lid, with a pot-like housing which receives a bearing pin and forms a liquid-filled damping chamber for a rotary damper, the rotor of which is formed from the bearing pin and has a damping projection which divides the damping chamber into two displacement sections, characterized in that the damping chamber consists of a groove ( 7 ) provided on the inside of the housing base ( 6 ), which runs along a circular arc coaxial with the housing ( 1 ), and that the damping projection ( 12 ) which projects axially towards the groove base engages with a clearance fit in the groove ( 7 ) on the front side ( 8 ) of the bearing pin ( 3 ) forming the rotor, which groove is covered by the bearing pin ( 3 ) with respect to the housing ( 1 ). 2. Device according to claim 1, characterized in that the bearing pin ( 3 ) is sealed against the peripheral wall ( 19 ) of the housing ( 1 ) via at least one sealing ring ( 18 ). 3. Device according to claim 1 or 2, characterized in that the bearing pin ( 3 ) can be resiliently loaded in the axial direction against the housing base ( 6 ). 4. Device according to claim 3, characterized in that the bearing pin ( 3 ) is axially supported on an elastomeric housing cover ( 9 ) which has a passage opening ( 10 ) for a coupling projection ( 5 ) of the bearing pin ( 3 ). 5. Device according to one of claims 1 to 4, characterized in that the housing base ( 6 ) has a closable filling opening ( 17 ) for the damping chamber formed from the groove ( 7 ).