EP4098834A1 - Actuator for driving a movable furniture part - Google Patents

Abstract

Actuating drive (1) for driving a movably mounted furniture part (2), comprising at least one actuating arm (3) to be connected to the furniture part (2), the at least one actuating arm (3) being designed to be movable between a first and a second end position, a Damper (4) for damping both a movement (14) of the at least one adjusting arm (3) into the first end position and a movement (15) of the at least one adjusting arm (3) into the second end position, the damper (4) being damping executes a damping stroke, and a coupling mechanism (5, 6, 7, 8, 9, 10) for coupling the at least one adjusting arm (3) or an adjusting part (11) connected or connectable thereto to the damper (4), at least during the movements (14, 15) of the at least one actuating arm (3) into the two end positions, the coupling mechanism (5, 6, 7, 8, 9, 10) having an actuator (10) for executing the damping stroke of the damper (4), wherein the actuator (10) the damper (4) both at the Movement (14) of the at least one actuating arm (3) into the first end position and during the movement (15) of the at least one actuating arm (3) into the second end position to carry out the damping stroke.

Description

The invention relates to an actuator for driving a movably mounted furniture part, comprising at least one actuating arm to be connected to the furniture part, the at least one actuating arm being designed to be movable between a first and a second end position, a damper for damping both a movement of the at least one actuating arm in the first end position and a movement of the at least one actuating arm into the second end position, with the damper performing a damping stroke during damping, and a coupling mechanism for coupling the at least one actuating arm or an actuating part connected or connectable to it to the damper at least during the movements of the at least one actuating arm in the two end positions, the coupling mechanism having an actuator for executing the damping stroke of the damper. The invention further relates to a piece of furniture with a furniture body and at least one furniture part, preferably in the form of a flap, mounted so that it can move, preferably about a horizontal axis, and at least one actuator according to the invention arranged on the furniture body, the at least one actuating arm of the actuator being connected to the at least one furniture part connected is.

An actuator according to the preamble of claim 1 is from WO 2005/075778 A1 known. In this solution, a damper is provided which is mounted in a floating manner on the housing of the actuator and is acted upon by a complex lever mechanism to carry out the damping stroke. This embodiment requires a large amount of space. the Due to their complexity, the lever mechanism for loading the damper is also susceptible to wear and expensive.

The objective technical task of the present invention is therefore to specify an actuator according to the preamble of claim 1, which does not have the described disadvantages of the prior art and is characterized in particular by a compact design. Another object of the invention is to specify a piece of furniture with such an actuator.

These objects are achieved by the actuator according to the features of independent claim 1 and the furniture according to the features of claim 13.

It is therefore provided in the actuator according to the invention that the actuator acts on the damper both when the at least one actuating arm moves into the first end position and when the at least one actuating arm moves into the second end position to carry out the damping stroke. The fact that the damper is always acted upon to carry out the damping stroke, i.e. both during the movement of the at least one actuating arm into the first end position and during the movement of the at least one actuating arm into the second end position, is carried out by the same actuator, eliminating the need for one space-consuming force deflection mechanism.

The damping of the movement of the at least one actuating arm by the damper preferably takes place within the areas which are immediately in front of the two end positions.

According to a preferred embodiment of the invention, it is provided that the actuator has an end-position force accumulator for applying force to the at least one actuating arm both when the at least one actuating arm moves into the first end position and when the at least one actuating arm moves into the second end position. Due to the simultaneous provision of a damper and an end-position force accumulator, a damped, driven movement of the at least one actuating arm into the two end positions can take place, independently of any additional main driving force accumulator for applying force to the at least one actuating arm or for compensating for the weight of a movably mounted furniture part connected to the at least one actuating arm . In this case, the locking force of the furniture part is independent of the design of such a main drive force accumulator or the design of a transmission mechanism arranged between such a main drive force accumulator and the at least one actuating arm.

In combination with the end-position force accumulator described, it can advantageously be provided that the coupling mechanism has a force transmission element, preferably pivotably mounted, with the end-position force accumulator supporting the force transmission element both during the movement of the at least one actuating arm into the first end position and during the movement of the at least applied to an actuating arm in the second end position.

Such a power transmission element can also be used to
the end position force accumulator in the charged state can be releasably locked via the force transmission element and a pivoting lever which can be moved relative thereto and which can engage in the force transmission element in a non-positive and/or positive manner, or vice versa. In the releasably locked and loaded state, the end-position force accumulator is then in a waiting position for releasing the force stored in the end-position force accumulator for a movement of the at least one actuating arm into the first end position or into the second end position.

The charging of the end-position force accumulator takes place favorably both when the at least one actuating arm moves out of the first end position, ie also when the at least one actuating arm moves out of the second end position.

A particularly compact design of the actuator is possible if the damper and the end-position force accumulator are arranged essentially parallel to one another.

In a particularly simple manner, the at least one actuating arm or an actuating part connected or connectable to it can be coupled to the damper or the end-position force accumulator in the event that the at least one actuating arm makes a first pivoting movement when moving into the first end position and when moving into the second end position a second pivoting movement, which is opposite to the first pivoting movement, takes place in that the coupling mechanism includes a pivoting lever and a rectifying mechanism for converting the having both pivoting movements of the at least one actuating arm in a pivoting movement of the pivoting lever taking place in the same direction.

Specifically, this rectification mechanism can be solved, for example, in that the rectification mechanism has at least one first and one second control cam and at least one first and one second control element, with the two control elements being coupled for movement to the at least one actuating arm, the first control element being in the first end position of the at least one control arm is in engagement with the first cam, and the second control element is in engagement with the second control cam in the second end position of the at least one control arm, preferably with the two control cams being arranged on the pivoting lever, and/or the two control elements on the at least an actuating arm connected or connectable actuating part are arranged.

Further advantageous embodiments of the actuator are defined in dependent claims 6-12.

As already stated at the outset, protection is also sought for a piece of furniture with a furniture body and at least one furniture part that is mounted so that it can move, preferably about a horizontal axis, preferably in the form of a flap, and at least one actuator according to the invention arranged on the furniture body, with the at least one actuating arm of the actuator is connected to the at least one piece of furniture.

Further details and advantages of the present invention are explained in more detail below on the basis of the description of the figures with reference to the drawings.

Fig. 1

ein Möbel mit einem bewegbar gelagerten Möbelteil in Form einer Faltklappe und einem Stellantrieb in einer bevorzugten Ausführungsform,

Fig. 2a

eine vergrößerte perspektivische Ansicht des Stellantriebs mit teilgeöffnetem Gehäuse und ohne Stellarm,

Fig. 2b

eine Explosionsdarstellung des Stellantriebs gemäß Fig. 2a,

Fig. 3

eine Stellung des Stellantriebs, in welcher sich der Stellarm in einer Mittenstellung zwischen den beiden Endlagen befinden würde,

Fig. 4-6

eine Abfolge von Stellungen des Stellantriebs zur Illustration der Bewegung des wenigstens einen Stellarms in die erste Endlage aus einer Mittenstellung, und

Fig. 7-9

eine Abfolge von Stellungen des Stellantriebs zur Illustration der Bewegung des wenigstens einen Stellarms in die zweite Endlage aus einer Mittenstellung.

Show in it:

1

a piece of furniture with a movably mounted furniture part in the form of a folding flap and an actuator in a preferred embodiment,

Figure 2a

an enlarged perspective view of the actuator with a partially open housing and without an actuating arm,

Figure 2b

an exploded view of the actuator according to Figure 2a ,

3

a position of the actuator in which the actuator arm would be in a mid-position between the two end positions,

Figures 4-6

a sequence of positions of the actuator to illustrate the movement of the at least one actuator arm to the first end position from a middle position, and

Figures 7-9

a sequence of positions of the actuator to illustrate the movement of the at least one actuator arm in the second end position from a middle position.

figure 1 shows a side cross-sectional view of a piece of furniture 29 with a furniture body 30 and a furniture part 2, which is mounted so that it can move about a horizontal axis, in the form of a flap, more precisely a folding flap composed of two partial flaps 34 and 35, the furniture part 2 being connected via at least one hinge 32 to the Furniture body 30 is connected and the two partial flaps 34 and 35 are pivotally connected to one another via a central hinge 33 .

The piece of furniture 29 also comprises at least one actuator 1, which is arranged on a side wall 31 of the furniture body 30, with the actuator 1 having an actuating arm 3 which is connected to the furniture part 2, more precisely to the partial flap 35, via a coupling piece 36. The piece of furniture 29 preferably comprises two such actuators 1 which are arranged on opposite sides 31 of the furniture body 30 and are each connected to the furniture part 2 via an actuating arm 3 .

The movable furniture part 2 has an open position in which figure 1 is shown, and a closed position in which the movable furniture part 2 covers an interior of the furniture 29 at least partially to the outside. When the movable furniture part 2 is in its open position, the actuating arm 3 of the actuating drive 1 is in an end position, hereinafter referred to as the second end position. When the movable furniture part 2 is in its closed position, the actuating arm 3 is in a further end position, referred to below as the first end position.

Relating to figure 1 It should also be pointed out that the movable furniture part 2 shown in this figure, in the use position of the furniture 29 and during a movement from the closed position to the open position, a pivoting movement 15 (compare the sequence of Figures 7 to 9 ) runs upwards.

How from the Figures 2a and 2b shows, in a preferred embodiment, the actuator comprises a housing 18, only half of this housing being shown in the two figures in order to enable a view of the interior of the actuator. The actuator is mirror-symmetrically covered by a second half of the housing.

A mounting part 40 on which a linear damper 4 and an end-position force accumulator 12 is mounted is connected to the housing 18 so as to be rigid with respect to movement. Furthermore, the assembly part 40 forms a bearing point 47 for an actuating part 11 , the actuating part 11 being pivotably mounted relative to the assembly part 40 or the housing 18 . On the housing 18 or the mounting part 40, two ring gears 39 are also arranged, in which a gear wheel 41, which is arranged on the actuating part 11, engages. If the actuating part 11 moves too quickly relative to the housing 18, a braking element connected to the gear wheel 41 causes the movement of the actuating element 11 or the actuating arm 3 connected to it to be braked relative to the housing 18, so that a user is injured by moving the actuator too quickly Actuating arm 3 is avoided. The actuating arm 3 can be connected to the actuating element 11 via an adapter piece 38 .

The actuator 1 also has a coupling mechanism 5, 6, 9 and 10 for coupling the at least one actuating arm 3 or the actuating part 11 that can be connected to it to the linear damper 4 when the at least one actuating arm 3 moves into the two end positions, the coupling mechanism having a Actuator 10 for executing the damping stroke of the linear damper 4 has. The actuator 10 is on in the illustrated embodiment a pivoting lever 9 arranged. The pivot lever 9 can be pivoted about a pivot axis 45 relative to the housing 18 of the actuator 1 . The coupling mechanism also includes two control elements 5 and 6, which are in the form of bolts and whose mode of operation is explained in more detail below with reference to the following figures. Furthermore, the coupling mechanism comprises a pivot axis 46 (cf figure 3 ) relative to the housing 18 pivotable force transmission element 13, wherein the force transmission element 13 is acted upon on the one hand by the end position force accumulator 12. On the other hand, the force transmission element 13 contacts the pivoted lever 9 via a contact means 17 arranged on the pivoted lever 9.

The linear damper 4 comprises a damper housing 21 and a plunger 22 that can be pushed in relative to the damper housing 21, the plunger 22 being activated by the actuator 10 both during the movement of the at least one actuating arm 3 into the first end position, i.e. also during the movement of the at least one actuating arm 3 in the second end position can be depressed relative to the damping housing 21, as can be seen from the following figures.

Finally, the actuator 1 in the embodiment shown also includes a main drive force store 23 for applying force to the actuating arm 3 or the actuating part 11 that can be connected to it via a transmission mechanism 24, 25, 26, 27, 28 and 37. The transmission mechanism includes a first relative to the pivot axis 42 to the housing 18 pivotable intermediate lever 24, which is articulated to the main force accumulator 23 and has a control contour 37. On A first rolling element 26 of a second intermediate lever 25 rolls off this control contour 37 , which is designed to be pivotable about the pivot axis 43 in relation to the housing 18 . The second intermediate lever 25 also has a second rolling element 27 which runs on a control contour 28 which is formed on the actuating part 11 .

It should also be noted with regard to the end-position energy store 12 or the main energy store 23 that this preferably comprises at least one spring element, particularly preferably in the form of a compression spring.

figure 3 shows the actuator 1 in a central position, which corresponds approximately to an opening angle of 50°. In this, as well as in the following illustrations, a relevant section of the actuator 1 is shown enlarged. In the middle position according to figure 3 , from which the actuating arm, on the one hand, initiates a movement 14 into the first end position (compare the sequence of Figures 4 to 6 ) as well as a movement 15 into the second end position (compare the sequence of Figures 7 to 9 ) can execute, the end position force accumulator 12 is essentially fully charged and releasably locked in this state via the force transmission element 13 and the pivoting lever 9, which engages in a non-positive manner in the force transmission element 13. To produce the frictional connection, a contact means 17 designed as a projection is arranged on the pivoting lever 9 and engages in a corresponding locking recess 44 arranged on the force transmission element 13 .

The end-position force accumulator 12 comprises a sleeve 48, which is held by a compression spring 49, which is inserted on the one hand in the sleeve 48 engages and on the other hand on the mounting element 40 and the housing 18 is supported. Thus, the end-position energy accumulator 12 is mounted indirectly on the housing 18 at one end 19 . The opposite free end 50 contacts the force transmission element 13.

The linear damper 4 is arranged essentially parallel to the end-position force accumulator 12 and is also mounted at one end 20 indirectly via the mounting element 40 on the housing 18 . As stated, the linear damper 4 comprises a damper housing 21 and a plunger 22 which can be pressed in relative to the damper housing 21. The linear damper 4 also comprises a return spring 51 which moves the linear damper 4 into the position according to FIG figure 3 moved back. The linear damper 4 makes contact via the plunger 22 with the actuator 10 which is arranged on the pivoting lever 9 .

In summary, the end position force accumulator 12 in figure 3 lurking position shown substantially fully loaded and releasably locked. The linear damper 4 assumes a position in which the plunger 22 is essentially maximally extended and is ready for a damping stroke. In this waiting position, there is no coupling between the linear damper 4 and the actuating arm 3 or the actuating element 11 that can be connected to it.

If the actuating arm 3 now performs a movement 14 into the first end position, which corresponds to the closed position of the movably mounted furniture part 2, the following processes take place on the actuating drive 1 (compare Figures Figures 4 to 7 ):
The control part 11, which can be connected to the control arm 3, is pivoted until the control element 5, which is arranged on the control part 11 and is motion-coupled to the at least one control arm 3, contacts the first cam 7, which is arranged on the pivoting lever 9, for the first time. Due to the relative arrangement of the axes of rotation 47 of the actuating part 11 and 45 of the pivoted lever 9 and the relative arrangement of the control element 5 and the control cam 7, the pivoted lever 9 is moved in the direction of the first end position of the actuating arm in a subsequent further pivoting movement 14 of the actuating arm 3 in one of the pivoting movement 14 opposite pivoting movement 16 converted. Specifically, the control part 11 rotates clockwise and the pivoting lever 9 counterclockwise.

This rotational movement, which is forced by the engagement of the control element 5 in the control cam 7, moves the contact means 17 out of the detent recess 44 of the force transmission element 13. As a result, the compression spring 49 of the end-position force accumulator 12 can subsequently relax. The force released in the process is transmitted via the force transmission element 13 to the pivoting lever 9, which subsequently actively drives the actuating arm 3--again through the engagement of the control element 5 in the cam 7.

At the same time, the actuator 10 arranged on it is pivoted counterclockwise together with the pivoting lever 9 and is thus pressed against the plunger 22 of the linear damper 4 . The plunger 22 is thus pushed in relative to the damper housing 21, as a result of which the linear damper 4 has its damping effect unfolded. In other words, the actuator 10 executes the damping stroke of the linear damper 4.

In summary, the actuating arm 3 that can be connected to the actuating part 11 is moved into the first end position in an actively damped manner due to the special arrangement of the end-of-stroke energy store 12 and the linear damper 4 .

The sequence of Figures 7 to 9 shows the movement of the actuating arm 3 starting from the middle position according to FIG figure 3 into the second end position, which corresponds to the open position of the movable furniture part. During this movement 15, which takes place counterclockwise, the second control element 6 contacts the second control cam 8, as a result of which the at least one actuating arm 3 or the actuating part 11 that can be connected to it is coupled. Due to this engagement of the bolt-shaped control element 6 in the second control cam 8 and the relative arrangement of the axes of rotation 45 and 47 as well as the relative arrangement of the second control cam 8 relative to the second control element 6, the pivoting lever 9 subsequently also performs a pivoting movement 16 counterclockwise. The end-position force accumulator 12 and the linear damper 4 subsequently develop the same effects as when the at least one actuating arm 3 moves into the first end position.

If one compares the processes that take place on the actuator 1 when the actuating arm 3 moves into the first end position with the processes that take place when the at least one actuating arm 3 moves into the second end position, it can be seen that the two control elements 5 and 6 and the two cams 7 and 8 interacting therewith Act as a rectification mechanism, which converts the two pivoting movements 14 and 15 of the at least one actuating arm 3 into a pivoting movement 16 of the pivoting lever 9, each taking place in the same direction.

Claims (15)

Actuating drive (1) for driving a movably mounted furniture part (2), comprising at least one actuating arm (3) to be connected to the furniture part (2), the at least one actuating arm (3) being designed to be movable between a first and a second end position, a Damper (4) for damping both a movement (14) of the at least one adjusting arm (3) into the first end position and a movement (15) of the at least one adjusting arm (3) into the second end position, the damper (4) being damping executes a damping stroke, and a coupling mechanism (5, 6, 7, 8, 9, 10) for coupling the at least one adjusting arm (3) or an adjusting part (11) connected or connectable thereto to the damper (4), at least during the movements (14, 15) of the at least one actuating arm (3) into the two end positions, the coupling mechanism (5, 6, 7, 8, 9, 10) preferably having an actuator (10) for executing the damping stroke of the damper (4). wherein the actuator (10) is pivotable ldet is characterized in that the actuator (10) the damper (4) both during the movement (14) of the at least one adjusting arm (3) in the first end position and during the movement (15) of the at least one adjusting arm (3) into the second end position to carry out the cushioning stroke. Actuating drive (1) according to claim 1, wherein the actuating drive (1) has an end-position force accumulator (12) for applying force to the at least one actuating arm (3) both during a movement (14) of the at least one adjusting arm (3) into the first end position and during a movement (15) of the at least one adjusting arm (3) into the second end position. Actuator (1) according to claim 2, wherein the coupling mechanism (5, 6, 7, 8, 9, 10) has a preferably pivotably mounted force transmission element (13), wherein the end position force accumulator (12) supports the force transmission element (13) both in the Movement (14) of the at least one actuating arm (3) into the first end position and during the movement (15) of the at least one actuating arm (3) into the second end position, preferably with the end-position force accumulator (12) being in the charged state via the force transmission element ( 13) and a pivoting lever (9) which can be moved relative thereto and which can engage in the force transmission element (13) in a non-positive and/or positive manner or, conversely, can be locked in a detachable manner. Actuating drive (1) according to claim 2 or 3, wherein the end-position force accumulator (12) can be charged both when the at least one actuating arm (3) moves out of the first end position and when the at least one actuating arm (3) moves out of the second end position, and/or wherein the damper (4) and the end-position force accumulator (12) are arranged essentially parallel to one another. Actuating drive (1) according to any one of claims 1 to 4, wherein the at least one actuating arm (3) during the movement in the first end position executes a first pivoting movement (14) and during the movement into the second end position a second pivoting movement (15), which is opposite to the first pivoting movement (14), and the coupling mechanism (5, 6, 7, 8, 9, 10) a pivoting lever (9) and a straightening mechanism (5, 6, 7, 8) for converting the two pivoting movements (14, 15) of the at least one adjusting arm (3) into a pivoting movement (16) of the pivoting lever (9 ) having. Actuator (1) according to claim 5, wherein the rectifying mechanism (5, 6, 7, 8) has at least a first and a second control cam (7, 8) and at least a first and a second control element (5, 6), the two Control elements (5, 6) are coupled for movement to the at least one actuating arm (3), the first control element (5) is in engagement with the first cam (7) in the first end position of the at least one actuating arm (3), and the second control element ( 6) in the second end position of the at least one actuating arm (3) is in engagement with the second cam (8), preferably with the two cams (7, 8) being arranged on the pivoting lever (9), and/or the two control elements (5 , 6) are arranged on the actuating part (11) that is or can be connected to the at least one actuating arm (3), preferably with the two control cams (7, 8) running essentially in a straight line and/or being aligned essentially at right angles to one another, and/or the two Controls (5, 6) are bolt-shaped. Actuating drive (1) according to claim 5 or 6, wherein the actuator (10) is arranged on the pivoted lever (9) and/or a contact means (17) for contacting the force transmission element (13) according to claim 3 is arranged on the pivoted lever (9). Actuating drive (1) according to one of claims 1 to 7, wherein the actuating drive (1) comprises a housing (18) and the damper (4) and/or the end-position force accumulator (12) directly or indirectly at one end (19, 20). mounted, preferably fixed, on the housing (18). Actuating drive (1) according to one of Claims 1 to 8, the damper (4) being designed as a linear damper. Actuating drive (1) according to Claim 9, in which the linear damper (4) has a cylinder and a piston which can be moved relative thereto, the linear damper (4) being actuated by the actuator (10) both during the movement (14) of the at least one adjusting arm (3) in the first end position and during the movement (15) of the at least one actuating arm (3) into the second end position can be acted upon in such a way that essentially only the piston moves and the cylinder is immovable, or vice versa, and the piston or the Cylinder moves in both movements (14, 15) of the at least one actuating arm (3) in the same direction. Actuating drive (1) according to Claim 9 or 10, in which the linear damper (4) has a damper housing (21) and a plunger which can be pressed in relative to the damper housing (21). (22), the linear damper (4) by the actuator (10) both during the movement (14) of the at least one adjusting arm (3) into the first end position and during the movement (15) of the at least one adjusting arm (3) in the second end position can be acted upon in such a way that essentially only the plunger (22) moves and the damper housing (21) is immovable, or vice versa, and the plunger (22) or the damper housing (21) moves during both movements (14, 15) of the at least one actuating arm (3) are each moved in the same direction. Actuating drive (1) according to one of claims 1 to 11, wherein the actuating drive (1) has a main driving force accumulator (23) for applying force to the at least one actuating arm (3) or an actuating part (11) connected or connectable thereto, preferably via a transmission mechanism (24, 25, 26, 27, 28, 37). Furniture (29) with a furniture body (30) and at least one furniture part (2) mounted so that it can move, preferably about a horizontal axis, preferably in the form of a flap, and at least one actuator (1) according to one of the claims arranged on the furniture body (30). 1 to 12, wherein the at least one actuating arm (3) of the actuating drive (1) is connected to the at least one furniture part (2). Furniture (29) according to claim 13, wherein the at least one movable furniture part (2) is connected to the furniture body (30) via at least one hinge (32), wherein preferably the at least one movable furniture part (2) is designed in the form of a folding flap composed of a first and a second partial flap (34, 35), the first partial flap (34) is pivotably mounted on the furniture body (30), and the second partial flap ( 35) is pivotably connected to the first partial flap (34) via a central hinge (33), and the actuating arm (3) of the actuator (1) is connected to the second partial flap (35). Furniture (29) according to claim 13 or 14, wherein the at least one movable furniture part (2) has an open position and a closed position, and the closed position of the furniture part (2) with the first end position of the at least one actuating arm (3) and the open position of the furniture part (2) corresponds to the second end position of the at least one adjusting arm (3), preferably wherein the at least one movable furniture part (2) performs an upward pivoting movement (15) when the furniture item (29) is in the use position and when moving from the closed position into the open position executes

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