WO2022029016A1

WO2022029016A1 - Storage compartment

Info

Publication number: WO2022029016A1
Application number: PCT/EP2021/071336
Authority: WO
Inventors: Christian Schumann; Thomas BAUMGÄRTL; Grzegorz CZERWIEC
Original assignee: Dr. Schneider Kunststoffwerke Gmbh
Priority date: 2020-08-04
Filing date: 2021-07-29
Publication date: 2022-02-10
Also published as: EP4271903A1; DE102020120557A1

Abstract

The invention relates to a storage compartment, in particular a storage compartment in a vehicle. This storage compartment has a container and a cover mounted on the container so as to be pivotable about an axis. A damping device which damps an opening movement of the cover is arranged on the axis, and comprises the following components: - a linear damper having a tappet, - a wedge which is mounted non-rotatably relative to the container, and - a rotary wedge which contacts the wedge and is rotatable together with the pivotable cover relative to the wedge.

Description

description

storage compartment

The invention relates to a storage compartment, in particular for a vehicle, for example a glove box for a car.

Storage compartments are usually provided in a vehicle, which in many cases are integrated into the dashboard of the respective vehicle. These storage compartments have a cover which folds down after a lock has been released, with this fold open taking place about a rotary axis.

It is already known to dampen this opening of the lid by means of a damping device. Without such a damping device, after the closure was released by gravity, the cover would fall down while rotating about the axis of rotation and would hang dangling or hit a paneling part of the vehicle or an occupant of the vehicle.

DE 10 2006 032 747 B4 already discloses a motor vehicle interior trim part which has a cover, a rotation angle sensor for detecting the open position of the cover and a control device. The control device has a non-volatile memory. The interior trim part also has a hysteresis brake for braking a movement of the cover, the control device being designed to set the braking torque of the hysteresis brake by adjusting the excitation current for the hysteresis brake at least as a function of an open position of the cover . Said memory contains a look-up table in which an excitation current for the hysteresis brake is defined for each angular range of the opening angle of the cover.

DE 103 41 969 A1 discloses a delay device for braking an opening movement of a flap Storage container known. This device has a brake wheel which is rotatably mounted in a housing filled with a braking medium in order to generate a braking torque. The brake wheel and the housing are coupled to the flap in such a way that the braking torque generated can be transmitted directly to the flap.

The object of the invention is to specify a storage compartment with a cover whose opening movement is damped by means of a space-saving, inexpensive damping system that is easy to assemble.

This problem is solved by a storage compartment with the features specified in claim 1 . Advantageous refinements and developments are specified in the dependent claims.

According to the present invention, a storage compartment for a vehicle is provided, which storage compartment has a container and a cover which is mounted on the container so that it can pivot about an axis, wherein a damping device which dampens an opening movement of the cover is arranged in the axis and has the following components:

- a linear damper with a plunger,

- a wedge, which is mounted against rotation relative to the container, and

- a rotating wedge which contacts the wedge and is rotatable together with the hinged cover relative to the wedge.

The components mentioned above, arranged on the axis, form a cost-effective and robust damping system that dampens the opening movement of the cover, which is space-saving and easy to assemble and shows robust behavior in practical operation.

The axis can be arranged essentially horizontally and also in the area of the lower edge of the container. The function of damping the opening movement of the damper is shown by the fact that the lid opens downwards using gravity . However, the functionality is also guaranteed under a non-horizontal axis if this does not exceed a certain angle from the horizontal, preferably 30°.

The lid can open downwards. However, depending on the course of the axis, an oblique pivoting movement of the cover may also be possible, which, however, essentially points downwards in the direction of gravitation.

The mutually facing end faces of the wedge and the rotary wedge can be designed at an angle. The damping properties of the damping device depend on the mutually facing end faces of the wedge and the rotary wedge. A small skew results in a small movement of the ram, while a large skew results in a large movement of the ram. The mutually facing end faces of the wedge and the rotary wedge can have a curved, e.g. have a concave, convex or S-shaped course. As a result, the course of force can be optimized during the opening movement on the damper, with e.g. initially a steep incline is provided in order to allow the cover a certain acceleration and towards the end of the opening movement the incline flattens out in order to achieve a higher braking force. Reversed or force curve-optimized curves are then to be selected or adapted to the requirements of the storage compartment.

The wedge and the rotary wedge are exposed to high frictional moments and can be designed as separate components and attached to the container or lid or molded onto the container and lid. The choice of material for the wedge and rotating wedge may differ from that of the container or the lid. Worn wedges can be replaced easily, quickly and inexpensively if they are designed as separate components. When the cover is closed, the sloping end faces of the wedge and the rotary wedge can run parallel to one another and can rest against one another.

The ram can have an end region protruding from the linear damper and can be displaced in the longitudinal direction of the axis, with a spring acting on the ram.

The spring can be designed as a compression spring. One end of the spring is supported in or on the linear damper, the other end of the spring acts on the plunger, the plunger being moved against the force of the spring when the cover is opened. The interior of the linear damper can also be filled with gas, a foam or a gel that is reversibly compressed when the lid is opened.

During the opening movement of the cover, the rotary wedge can be rotated about the axis together with the cover and can move the wedge in the longitudinal direction of the axis.

During the opening movement of the cover, the rotary wedge can be rotated about the axis together with the cover and can be displaced in the longitudinal direction of the axis via the wedge.

The closing movement of the lid can be undamped. The wedges can separate from each other during the closing movement. This can be prevented if, instead of wedges, threaded sections or spindle elements are used, which always engage in one another even during a closing movement.

Further advantageous properties of the invention result from the following exemplary explanation based on the figures.

It shows :

Figure 1 is a schematic representation of a first

Embodiment for a storage compartment closed lid and a longitudinal section to illustrate the damping system with the lid closed,

Figure 2 is a schematic representation of the first

Exemplary embodiment with the cover partially open and a longitudinal section to illustrate the damping system with the cover partially open,

Figure 3 is a schematic representation of the first

Embodiment with the lid open and a longitudinal section to illustrate the damping system with the lid open,

Figure 4 is a schematic representation of a second

Exemplary embodiment of a storage compartment with the lid closed and a longitudinal section to illustrate the damping system with the lid closed,

Figure 5 is a schematic representation of a third

Embodiment of a storage compartment with the lid closed and a longitudinal sectional view to illustrate the damping system with the lid closed and

FIG. 6 shows a detailed illustration of the second exemplary embodiment shown in FIG.

In its upper area, FIG. 1 shows a schematic illustration of a first exemplary embodiment of a storage compartment with the cover closed and in its lower area

Longitudinal section to illustrate the damping system with the cover closed. As can be seen from the upper representation of FIG. 1, the storage compartment 10 shown, which in the exemplary embodiment shown is a glove box of a car, has a container 20 which is closed by a cover 30 . In its closed state, this lid 30 is locked in or on the container 20 , which is not shown in FIG. Once unlocked, the lid pivots downwards, this pivoting occurring about an axis A located at the bottom of the container 20 and extending in the horizontal direction. A damping device D is arranged on this axis A, which dampens a resistance-free falling of the cover when the cover 30 is opened. This damping device D is explained in more detail with reference to the illustration at the bottom of FIG.

As can be seen from the illustration below in FIG. 1, the damping device D is positioned on the axis A and has the following components:

- a linear damper 40 which has a ram 41 which can be displaced in the longitudinal direction of the axis and which has an end region protruding from the linear damper 40 ,

- A spring 42 acting on the plunger 41, which is designed as a compression spring and one end of which is supported in the linear damper and the other end of which acts on the plunger 41,

- A wedge 43, which is mounted against rotation relative to the container 20, and

a rotary wedge 44 which contacts wedge 43 and is rotatable together with pivotable cover 30 relative to wedge 43 .

The linear damper 40 is inserted into a receptacle 21 of the container 20 . The longitudinal direction of the linear damper 40 corresponds to the longitudinal direction of the axis A. The ram 41 is in

Slidable longitudinally of the axis A, so that the as a piston trained right-side end portion of the plunger 41 is positioned more or less far in the interior of the linear damper 40. In the closed state of the cover 30, which is illustrated in the lower area of FIG.

In the exemplary embodiment shown, the spring 42 acting on the tappet 41 is a compression spring arranged within the linear damper 40 . Its right end area is supported in the linear damper 40 . The left-hand end area of the compression spring is supported on a right-hand end area of the tappet 41 designed as a piston. The ram 40 is guided in a guide 22 of the container 20 .

In the closed state of the cover 30 shown in FIG. 1, the spring 42 is in a slightly prestressed state, in which it uses the tappet 41 to drive the wedge 43, which has a sloping end face in its end region remote from the linear damper, with said prestressing force presses against an end face of the rotary wedge 44 which is also formed at an angle. The above-mentioned oblique end face of the wedge 43 runs parallel to the likewise oblique adjacent end face of the rotary wedge 44 , these two end faces bearing against one another.

The rotary wedge 44 is firmly connected to the cover 30 via a cover extension, so that it rotates about the axis A together with the cover 30 when the cover 30 is opened and closed. The rotary wedge 44 thus also rotates relative to the wedge 43 , which is connected to the container 20 in a non-rotatable manner. By rotating the rotary wedge 44 relative to the wedge 43, the non-rotatable wedge 43 is pushed away from the rotary wedge 44, d. H . shifted in the longitudinal direction of the axis A in the direction of the linear damper 40 . By moving the wedge 43 is also the

Plunger 41 in the longitudinal direction of the axis A in the direction of

Linear damper 40 moved. Furthermore, through the Moving the wedge 43 in the direction of the linear damper tensions the spring 42 more and more.

By moving the plunger 41 in the direction of the linear damper 40, the opening process of the cover 30 takes place in a damped manner.

As can also be seen from the illustration below in FIG. 1, the cover 30 is mounted on the container 20 using pins 31 and 32 . These pins can be embodied as separate components or, alternatively, also formed on the cover 30 or on the container 20 .

According to an alternative embodiment not shown in FIG. 1, the spring 42 is a compression spring which surrounds the plunger 41 , one end area of which is supported on the linear damper 40 and the other end area acts on the wedge 43 .

FIG. 2 shows at the top a schematic representation of the storage compartment shown in FIG. 1 with a partially opened cover and at the bottom a longitudinal sectional representation to illustrate the damping system with a partially opened cover.

The device shown in FIG. 2 differs from the device shown in FIG are shifted to the linear damper 40, so that the right-hand end area of the plunger 41 is shifted somewhat further into the inner area of the linear damper 40 than in the closed state of the cover 30 explained with reference to FIG.

In the partially open state of the cover 30 illustrated in FIG. 2, the spring 42 is at least slightly further compressed and is therefore in a more tensioned state than in the closed state of the cover 30. FIG. 3 shows a schematic representation of the storage compartment shown in FIG. 1 with the cover open at the top and a longitudinal section representation at the bottom to illustrate the damping system with the cover open.

The device shown in FIG. 3 differs from the device shown in FIG. 2 in that the rotary wedge 44 is rotated further relative to the wedge 43 than in FIG the plunger 41 is also shifted further in the direction of the linear damper 40, so that the right-hand end area of the plunger 41 is shifted even further into the inner area of the linear damper 40 than in the partially open state of the cover 30 explained in FIG.

In the open state of the cover 30 illustrated in FIG. 3, the spring 42 is compressed even more than in the partially open state of the cover 30 and is therefore in an even more tensioned state than in the partially open state of the cover 30.

When the cover 30 is then closed, the plunger 41 is pushed out of the linear damper 40 in the direction of the wedge 43 by a relaxation of the spring 42 . Furthermore, when the cover 30 is closed, the rotating wedge 44 is returned to its original rotating position shown in FIG.

The closing movement of the lid is undamped.

In its upper area, FIG. 4 shows a schematic illustration of a second exemplary embodiment of a storage compartment with the lid closed and in its lower area one Longitudinal section to illustrate the damping system with the cover closed.

As can be seen from the upper representation of FIG. 4, the storage compartment 10 shown, which in the exemplary embodiment shown is a glove box of a car, has a container 20 which is closed by a cover 30 . In its closed state, this cover 30 is locked in or on the container 20 , which is not shown in FIG. Once unlocked, the lid pivots downwards, this pivoting being about an axis A located at the bottom of the container 20 and extending in the horizontal direction. A damping device D is arranged on this axis A, which dampens a resistance-free falling of the cover when the cover 30 is opened. This damping device D is explained in more detail with reference to the illustration at the bottom of FIG.

As can be seen from the lower representation of FIG. 4, in this exemplary embodiment the damping device D is positioned on the axis A and has the following components:

- a linear damper 40, which has a plunger 41, which has an end region protruding from the linear damper 40,

- A spring 42 which is in contact with the plunger 41 and which is designed as a compression spring and one end of which is supported in the linear damper and the other end of which is in contact with the plunger,

The linear damper 40 is inserted in a guide 22 of the container 20 and within this guide in the longitudinal direction of the axis A movable . The longitudinal direction of the linear damper 40 corresponds to the longitudinal direction of the axis A. The left end area of the tappet 41 designed as a piston is arranged inside the linear damper 40 and supports an end area of the spring 42 . The right-hand end area of the plunger 41 is inserted into a receptacle 21 of the container 20 . The left-hand end area of the spring 42 is supported on the inside of the left-hand boundary wall of the linear damper 40 .

The outside of the left-side boundary wall of the linear damper 40 is in contact with the right-hand outside wall of the wedge 43 or is formed in one piece with it. The wedge 43 is arranged together with the linear damper 40 in a rotationally fixed manner with respect to the housing 20 but can be displaced in the longitudinal direction of the axis A. When the wedge 43 is displaced together with the linear damper 40, the spring 42 is compressed and thus tensioned. The positioning of the ram 41 , whose right-hand end region is mounted in the receptacle 21 of the container 20 , remains unchanged relative to the container 20 . Alternatively, the right-hand end area of the plunger 41 can also only bear against a molded rib as a counter bearing. The receptacle 21 only serves to secure the free end of the ram 41 against displacement or slipping and thus against the ram 41 tilting within the linear damper 40 . In addition, it is possible to provide the receptacle 21 or a rib for the stationary plunger 41 on the container 20 or the lid 30 .

The displacement of the linear damper 40 in the guide 22 of the container 20 changes the relative positioning of the stationary mounted ram 41 in the linear damper 40 .

In the closed state of the cover 30, which is illustrated in the lower area of Figure 4, the left-hand end area of the linear damper 40 is firmly connected to the wedge 43 or rests against it, with the spring 42 being in a slightly prestressed state in which the wedge 43, which in its end region remote from the linear damper has an oblique formed end face, presses against a likewise obliquely formed end face of the rotary wedge 44 . The said oblique end face of the wedge 43 runs parallel to the likewise oblique adjacent end face of the rotary wedge 44 , these two end faces lying against one another.

The rotary wedge 44 is firmly connected to the cover 30 so that it rotates together with the cover 30 about the axis A when the cover 30 is opened and closed. The rotary wedge 44 thus also rotates relative to the wedge 43 , which is connected to the container 20 in a non-rotatable manner. This twisting of the rotary wedge 44 relative to the wedge 43 pushes the non-rotatable wedge 43 away from the rotary wedge 44 in the longitudinal direction of the axis A. This displacement of the wedge 43 compresses the spring 42 arranged inside the linear damper and thus tensions it. This dampens the opening process of the lid.

As can also be seen from the illustration below in FIG. 4, the cover 30 is mounted on the container 20 using pins 31 and 32 . These pins can be embodied as separate components or, alternatively, also formed on the cover 30 or on the container 20 .

The closing movement of the lid is undamped.

In its upper area, FIG. 5 shows a schematic representation of a third embodiment of a storage compartment with the cover closed and in its lower area a longitudinal sectional view to illustrate the damping system with the cover closed.

As can be seen from the upper representation of FIG. 5, the storage compartment 10 shown, which in the exemplary embodiment shown is a glove box of a car, has a container 20 which is closed by a cover 30 . In its closed state, this lid 30 is locked in or on the container 20 , which is not shown in FIG. Once unlocked, the lid pivots downwards, this pivoting occurring about an axis A located at the bottom of the container 20 and extending in the horizontal direction. A damping device D is arranged on this axis A, which dampens a resistance-free falling of the cover when the cover 30 is opened. This damping device D is explained in more detail with reference to the illustration at the bottom of FIG.

As can be seen from the lower representation of FIG. 5, in this exemplary embodiment the damping device D is positioned on the axis A and has the following components:

- a linear damper 40 which has a ram 41 which can be displaced in the longitudinal direction of the axis A and which has an end region protruding from the linear damper 40 ,

- A spring 42 acting on the plunger 41, which is designed as a compression spring and one end of which is supported in the linear damper 40 and the other end of which acts on the plunger 41,

The linear damper 40 is connected to the pivotable cover 30, is inserted into a receptacle 33 of the cover and rotates about the axis A together with the cover when the cover is opened. The longitudinal direction of the linear damper 40 corresponds to the longitudinal direction of the axis A. The left end area of the tappet 41 designed as a piston is arranged inside the linear damper 40 and supports an end area of the spring 42 . The other end area of the spring 42 is supported on the inside of the left-hand boundary wall of the linear damper 40 . The plunger 41 is in a guide 34 of the cover 30 longitudinally displaceable. The right-hand end area of the ram 41 is firmly connected to the rotary wedge 44 . Consequently, when the cover 30 is opened, both the linear damper 40 and the plunger 41 as well as the rotary wedge 44 rotate. This twisting of the rotary wedge 44 relative to the wedge 43 connected securely to the container 20 results in a displacement of the rotary wedge 44 together with the plunger 41 in the longitudinal direction of the axis A, so that the spring 42 positioned in the linear damper 42 is compressed. This softens the opening action of the lid 30 .

As can also be seen from the illustration below in FIG. 5, the cover 30 is mounted on the container 20 using pins 31 and 32 . These pins can be embodied as separate components or, alternatively, also formed on the cover 30 or on the container 20 .

The closing movement of the lid is undamped.

In the exemplary embodiment explained with reference to FIG. 5, the wedge 43 is connected to the container 20 in a torsion-proof manner and, moreover, cannot be displaced in the longitudinal direction of the axis A. On the other hand, in this exemplary embodiment, the rotating wedge 44 can be rotated about the axis A together with the cover 30 and can also be displaced in the longitudinal direction of the axis A.

In contrast to this, in the exemplary embodiments explained with reference to FIGS. 1-4, the wedge 43 is likewise connected to the container 20 in a manner secured against rotation, but is displaceable in the longitudinal direction of the axis A. Furthermore, in the exemplary embodiments explained with reference to FIGS. 1-4, the rotary wedge 44 can be rotated together with the cover 30 about the axis A, but cannot be displaced in the longitudinal direction of the axis A.

FIG. 6 shows a detailed illustration of the second exemplary embodiment explained with reference to FIG. Also from this illustration it can be seen that the components belonging to the damping system, which include a linear damper 40 with a plunger 41, a wedge 43 and a rotary wedge 44, are positioned on axis A, which is the axis of rotation of the cover are . Furthermore, a part of the container 20 , the receptacle 21 of the container 20 , the guide 22 of the container 20 , a part of the cover 30 and the positioning of the pin 31 are illustrated in FIG. 6 .

Reference List

10 times

20 containers

21 recording

22 leadership

30 lids

31 pen

32 pin

33 recording

34 leadership

40 linear dampers

41 pestle

42 spring

43 first turning wedge

44 second rotary wedge A axis D damper system

Claims

patent claims

1. Storage compartment, which has a container (20) and one by one

Axis (A) pivotally mounted on the container (20) lid (30), characterized in that

- A damping device (D) that dampens an opening movement of the cover (30) is arranged in the axis (A), and has the following components:

- a linear damper (40) with a plunger (41),

- A wedge (43) which is mounted against rotation relative to the container (20), and

- A rotary wedge (44) which contacts the wedge (43) and can be rotated relative to the wedge (43) together with the pivotable cover.

2. Storage compartment according to Claim 1, characterized in that the axis (A) runs essentially horizontally and is arranged in the region of the lower edge of the container (20).

3. Storage compartment according to claim 2, characterized in that the cover (30) opens downwards.

4. Storage compartment according to one of the preceding claims, characterized in that mutually facing end faces of the wedge (43) and the rotary wedge (44) are formed obliquely.

5. Storage compartment according to claim 4, characterized in that the sloping end faces of the wedge (43) and the rotary wedge (44) run parallel to one another when the lid is closed and abut one another.

6. Storage compartment according to one of the preceding claims, characterized in that

- the plunger (41) has an end region protruding from the linear damper (40) and can be displaced in the longitudinal direction of the axis (A) and - A spring (42) acts on the tappet (41).

7. Storage compartment according to claim 6, characterized in that the spring (42) is designed as a compression spring, one end of the spring (42) is supported in or on the linear damper (40), the other end of the spring (42) on the plunger ( 41) acts and the plunger (41) is moved against the force of the spring (42) during the opening movement of the cover (30).

8. Storage compartment according to claim 7, characterized in that during the opening movement of the cover, the rotary wedge (44) rotates together with the cover (30) about the axis (A) and the wedge (43) in the longitudinal direction of the axis (A) moves.

9. Storage compartment according to Claim 7, characterized in that when the cover is opened, the rotary wedge (44) rotates together with the cover (30) about the axis (A) and via the wedge (43) in the longitudinal direction of the axis (A ) is moved.

10. Storage compartment according to one of the preceding claims, characterized in that the closing movement of the cover (30) is undamped.

11. Damping device (D), which has the following components:

- a linear damper (40) with a plunger (41),

- A wedge (43) which is mounted against rotation, and

- A rotary wedge (44) which contacts the wedge (43) and can be rotated relative to the wedge (43).

12. Damping device according to claim 11, wherein mutually facing end faces of the wedge (43) and the rotary wedge (44) are formed obliquely.

13. Damping device according to claim 12, wherein the oblique faces of the wedge (43) and the rotary wedge (44) extend parallel to one another and abut one another. 19

14. Damping device according to one of claims 11 to 13, in which the plunger (41) has an end region protruding from the linear damper (40) and is displaceable in the longitudinal direction of an axis (A) and in which a spring (42) on the plunger

(41) acts.

15. Damping device according to claim 14, wherein the spring

(42) is designed as a compression spring, one end of the spring (42) is supported in or on the linear damper (40), the other end of the spring

(42) acts on the plunger (41) and the plunger (41) can be moved against the force of the spring (42).

16. Damping device according to claim 15, in which the rotary wedge (44) rotates about the axis (A) the wedge

(43) shifts in the longitudinal direction of the axis (A).

17. Damping device according to claim 15, in which the rotary wedge (44) is displaceable in its rotation about the axis (A) via the wedge (43) in the longitudinal direction of the axis (A).