EP2136022B1 - Drive unit for a swinging wing - Google Patents

Description

The invention relates to a drive arrangement for a pivoting wing according to the preamble of claim 1.

Such a drive arrangement for a relative to its fixed frame movable pivoting wing, which may be formed, for example, as a tilting window, as a French door, as a ventilation flap or the like., Is from the DE 201 20 604 U1 known. The integrated in the connection mechanism drive module for the swing wing comprises an elongated, cuboid drive housing, in which a by a geared motor extend and retracting drive chain is arranged. The drive housing is pivotally mounted on arranged at the ends of the housing bearing brackets on the frame profile of the pivoting wing, while the free end of the drive chain is articulated on the fixed frame. The predetermined by the bearing brackets pivot axis runs along a rear side of the drive housing, whereby the center of gravity of the drive housing has a significant distance from the pivot axis. The weight of the drive housing thus generates a moment about the pivot axis, which must be supported via the drive chain. Depending on the structural conditions, the drive housing can take a slightly tilted with respect to the horizontal plane end position with closed swing wing due to height clearance on the chain side. However, this can be undesirable because the impression of a less solid drive solution can be conveyed by tilting the drive housing from the horizontal plane and the associated game. In addition, it can possibly lead to increased wear of the drive mechanism by the tilting movement of the drive housing as a result of the game.

The DE 202 14 767 U1 discloses an ejection device for moving a wing of a window, a French window, a ventilation flap or the like with respect to a fixed frame with a drive means for driving a substantially only one-way deflectable chain, with arranged on the drive means and a free end of the chain brackets and at least one arranged in one of the holders bearing whose bearing axis is provided for parallel arrangement to a bearing axis of the wing on the frame, wherein the holder of the drive means for attachment to a side remote from the bearing axis of the wing side of the frame or the wing and at the free end of the Chain arranged bracket is provided for attachment to the opposite component, and wherein one of the holders has a stop for limiting the pivoting range of the free end of the chain or the drive means.

Furthermore, from the EP 0 994 231 A1 a chain thrust drive known with a motor, a chain and a housing with a chain outlet. The chain outlet has a movable outlet guide, which is preferably pivotable about the axis of rotation of a chain pinion. On the outlet guide acts an actuator, such as a spring, and moves them into the pivoting position. The pivoting can be limited by an adjustable stop element.

The invention has for its object to develop a drive arrangement for a swing wing according to the preamble of claim 1, the can convey the appearance of a solid construction of the drive assembly.

The object is solved by the features of claim 1.

The subclaims form advantageous embodiments of the invention.

In order to enable a more comfortable operation of the drive arrangement, the drive module can be automatically moved by means of an auxiliary drive into the end position eliminating the play. The auxiliary drive is provided by a spring arrangement, by the spring force of the drive module is constantly loaded in the direction of the stop means fixed end position. In this case, stop means, e.g. adjustable stops by means of adjusting screws, used in order to be able to make an exact adjustment of the intended end position of the drive module while compensating for tolerances.

In an elongated drive module, which is pivotally mounted at its ends in a conventional manner via bearing brackets, preferably one of two synchronously working loading springs can be integrated into each of the two bearing brackets. Particularly space-saving can be arranged in the bearing brackets to this constructive adjusted torsion springs. So they can enclose a support sleeve in the joint area of the associated bearing bracket under a compact arrangement. In this case, it is possible in a simple manner to use differently strong springs with adaptation to the dead weight of different heavy drive modules with varying drive solutions, by the spring force of which the end position of the drive module is reliably assumed.

In order that no additional stop means for limiting the Relativverschwenkung the drive module to the defined by the bearing brackets pivot axis are required, these can be advantageously formed by controlling circumferential contours of a screw-on and a moving with the drive module support plate of the bearing brackets. As a controlling peripheral contour, the mounting plate can be provided with a wedge-shaped stop lug which engages in a wedge-shaped, wedge-shaped recess of the support plate with a correspondingly larger wedge angle. It is understood that stop lug and fork stop must lie in a common plane of rotation for this purpose. Preferably, the end position of the stop lug in the fork stop, via which the spring force is supported, tuned to the constructive fixed end position of the drive module, that in the end position at least one peripheral side of the drive module is in an at least approximately horizontal plane.

In the following an embodiment in the drawing with reference to the figures will be explained in more detail.

Fig. 1

eine perspektivische Ansicht auf eine Antriebsanordnung bei geschlossenem Schwenkflügel;

Fig. 2

die perspektivische Ansicht auf die Antriebsanordnung bei teilweise geöffnetem Schwenkflügel;

Fig. 3

eine perspektivische Seitenansicht eines Konsolenbereichs der Antriebsanordnung;

Fig. 4

die Lagerkonsole gemäß Fig. 3 in separater Explosionsdarstellung;

Fig. 5

die zusammengebaute Lagerkonsole nach Fig. 4 in separater perspektivischer Darstellung;

Fig. 6

die Lagerkonsole von Fig. 5 in einer Seitenansicht von rechts.

Showing:

Fig. 1

a perspective view of a drive assembly with the swing wing closed;

Fig. 2

the perspective view of the drive assembly with partially opened pivoting wing;

Fig. 3

a side perspective view of a console portion of the drive assembly;

Fig. 4

the storage console according to Fig. 3 in a separate exploded view;

Fig. 5

the assembled warehouse console after Fig. 4 in a separate perspective view;

Fig. 6

the warehouse console of Fig. 5 in a side view from the right.

In the Figures 1 and 2 For example, there is shown a drive assembly 10 for pivoting a pivoting wing 20 of a window between its closed position and a fully open position, not shown. The rectangular frame of the pivoting wing 20 holds in the usual way a translucent glass and is mounted along the lower wing profile with a hinge band 21 about a horizontal axis on the lower frame profile of the window frame 22 pivotally. The upper frame profile of the pivoting wing 20 is pivotally connected in the central central region by a drive chain 11 with the opposite profile of the window frame 22.

For the articulation of the chain end serves a chain holder 12 which is fixed on the frame profile of the window frame 22. As a result of the articulation of an eyelet end of the last chain link on a horizontal axis of the chain holder 12, the drive chain 11 is pivotally mounted in the vertical direction. The drive chain 11 is composed in a known manner from an authoritative for their length of plurality of chain links, which are interconnected via pivotal joints formed by bolts. In the drive chain 11, the bolts are arranged close to each other at a constant distance parallel to each other near one of their narrow sides, while adjacent chain links are supported on the opposite narrow side when the drive chain 11 is stretched straight. This means that the drive chain 11 can be articulated from its straight stretched position exclusively to the bolt side. Therefore engages from the bolt having the narrow side of a matching sprocket 13 in the drive chain 11 a.

The chain sprocket 13 in turn is rotatably mounted in a drive housing 14, in which the drive chain 11 is guided through a central opening on the housing side opposite the window frame 22. The elongated, rectangular in cross-section and a total of approximately cuboid drive housing 14 is in turn attached at both ends via a respective bearing bracket 15 on the front side of the upper profile of the swing wing 20. Since the drive housing 14 is shown with removed housing cover, the installation of the inserted drive chain 11 can be within the drive housing 14 clearly recognize. The drive arrangement 10 can also be arranged in the reverse manner, wherein the drive housing 14 pivotally mounted in the bearing brackets 15 is arranged on the window frame 22 and a correspondingly adapted chain holder 12 on the pivot wing 20.

After the passage of the spanned at right angles between the window frame 22 and the drive housing 14 drive chain 11 in the drive housing 14, this initially wraps around them engaging in chain sprocket 13 and is bent over a guide means by about 90 degrees. After this turn, the drive chain 11 initially extends straight to the right end of the drive housing 14 before it is deflected by 180 degrees and thus in the opposite direction again extends to the sprocket 13 provided with the central region of the drive housing 14. This space-saving installation of the drive chain 11 is secured by a U-shaped deflection guide in conjunction with a corresponding guide channel, which is bounded by the drive housing 14 itself and the removed housing cover. By a rotary drive of the sprocket 13 in a clockwise direction over a not visible in the left half of the drive housing 14 arranged electric geared motor 16, the drive chain 11 thus be extended lengthwise to an end position of the drive housing 14, whereby the swing-wing 20 maximum in his completely open position is moved.

If the sprocket pinion 13 is rotated by switching the gear motor 16 counterclockwise, the drive chain 11 is retracted lengthwise back into the drive housing 14 and takes the U-shaped curved storage position in the drive housing 14 again, the swing-wing 20 on the in Fig. 2 shown intermediate position again to his in Fig. 1 shown closed position on the window frame 22 is used. In this closed position, the pivoting wing 20 is locked on the geared motor 16, since the mechanical gear of the geared motor, for example by an integrated worm gear, is self-locking. Additional locking means are thus not required for the pivoting wing 20.

When opening and closing the pivoting wing 20 via the drive chain 11, the upper frame profile of the pivoting wing 20 is moved on a circular path about the geometric axis of the hinge belt 21. The occurring height offset relative to the chain holder 12 must be compensated at the two mirror-symmetrical bearing brackets 15 via a rotation between the drive housing 14 and the swing wing 20 so that a tilt-free engagement of the sprocket 13 in between the chain holder 12 and the drive housing 14 straight drive chain 11 can be done. The adaptation of the instantaneous rotational position between the drive housing 14 and pivoting wing 20 takes place automatically via the reduction of the drive chain 11 with increasing distance from the chain holder 12, wherein the pivot wing 20 facing peripheral side of the drive housing 14 via the axis of rotation of the sprocket 13 at right angles to the straight chain direction between the window frame 22 and drive housing 14 is aligned.

In Fig. 3 is the geometric pivot axis 17 located around which the drive housing 14 is mounted by means of the bearing brackets 15 pivotable relative to the axially parallel frame profile of the swing leaf 20 over the required angular range. This pivot axis 17 extends close to the flat rear side of the drive housing 14 and thus at a considerable distance to the centerline corresponding center of gravity of the drive housing 14. By the weight of the drive housing 14 thus generates a moment through which the bearing brackets 15 in the clockwise direction about the pivot axis 17th are charged. However, this moment is supported by a spring drive, so that the drive housing 14 is held in its constructively fixed end position, in which the upper and the parallel lower peripheral side of the drive housing 14 are aligned horizontally and at right angles to the plane of the swing wing 20.

As in connection with the separate views of one of the two mirror-symmetrically constructed bearing brackets 15 in the FIGS. 4, 5 and 6 can be seen well, the parallel to the geometric pivot axis of the hinge belt 21 axis of rotation 17 is determined by the center of the bore of a bearing ring 15.1, the transversely to the plane of a rectangular mounting plate 15.2 protrudes from the bottom. The mounting plate 15.2 is screwed to two laterally adjacent slots 18 under surface contact with conventional fastening screws, not shown, on the front side of the upper frame profile of the pivoting wing 20. About the Schraubbefestigung the mounting plate 15.2 of the projecting transversely from this bearing ring 15.1 is securely attached, since the bearing ring 15.1 and the mounting plate 15.2 are made in one piece, for example, die-cast aluminum. Furthermore, a wedge-shaped stop lug 15.3 is formed on the visible end face of the screw-on 15.2, the projecting under cover to the bearing ring 15.1, but at a lateral distance to this, from the lower portion of the screw 15.2.

In the vertical plane of the stop plate 15.3, a support plate 15.4 of the bearing bracket 15 is pivotally mounted about the aligned to the central longitudinal axis of the bearing ring 15.1 axis of rotation 17. The plane of rotation of the support plate 15.4 extends at right angles to the plane of the opposite Anschraubplatte 15.2, and parallel to her covered in the lower corner end face of the drive housing 14. In the overlap area between the support plate 15.4 and drive housing 14, these are fixed, but easily detachable connected to each other, wherein a mehrgliedrige Connection between the two through a hole in the support plate 15.4 is secured by a fastening screw 19.

In the Anschraubplatte 15.2 facing end portion of the broad side of the support plate 15.4 is a hollow cylindrical support sleeve 15.5 transverse, whose bore is provided with a non-visible internal thread. In this internal thread, an axle pin 25 is screwed with a threaded shaft 25.1 in the assembled state, wherein the threaded shaft 25.1 protrudes from the end of a cylindrical pin shaft 25.2 with a larger diameter. The provided at the other end with a screw head bolt shank 25.2 penetrates a washer 26 and then the bore of a bearing bush 27, which in turn passes through the bore of the bearing ring 15.1. In this case, the bearing bush 27 on the support sleeve 15.5 facing the end of an integrally formed annular collar. When screwed axle 25, the bearing bush 27 is thus held in the bearing ring 15.1 against the annular end face of the support sleeve 15.5, whereby their storage position is secured within the bearing ring 15.1. The support sleeve 15.5 is enclosed by a circumferential play of the winding of a leg spring 28, which is arranged axially between the annular end face of the bearing ring 15.1 of the broad side of the support plate 15.4. In this case, a spring leg of the torsion-prestressed leg spring 28 are supported on the support plate 15.4 and the other spring leg on the mounting plate 15.2. The acting on the support plate 15.4 rotary drive force of the leg spring 28 is supported over the shorter leg of a wedge-shaped widening fork stop 15.6. This fork stop 15.6 is formed by two straight boundary surfaces of a triangular-shaped recess of the support plate 15.4, which is recessed from the screwing plate 15.2 facing corner region. If the support plate 15.4 pressed against the spring force of the leg spring 28 from the drive housing 14 down, so first the existing rotational play of the stop lug 15.3 between the legs of the fork stop 15.6 balanced before the other leg of the fork stop 15.6 abuts against its counter surface of the stop lug 15.3, which the support plate 15.4 is blocked against further pivoting. Thus, the required rotational play is ensured even in unfavorable tolerance, the square leg base of the fork stop 15.6 was widened by an approximately semicircular groove 15.7.

When the pivoting wing 20 is closed, the drive housing 14 is thus automatically moved into the fixed end position due to the auxiliary drive formed by the leg springs 28 arranged in the brackets 15. Since the rotational force of the torsion springs 28 remains effective in the end position defined by the fork stop 15.6 and associated stop lug 15.3, the drive housing 14 is held in its always the same, stable end position after its displacement.

List of reference characters

10

drive arrangement

11

drive chain

12

Kettenhalter

13

sprocket

14

drive housing

15

bearing bracket

15.1

bearing ring

15.2

screwing

15.3

stop lug

15.4

support plate

15.5

carrying sleeve

15.6

fork stop

15.7

fillet

16

gearmotor

17

swivel axis

18

Long hole

19

fixing screw

20

rotary vane

21

hinge

22

window frame

25

axle

25.1

threaded shaft

25.2

bolt shaft

26

washer

27

bearing bush

28

Leg spring

Claims (8)

1. Drive arrangement (10) for a swivel wing (20), having a connection mechanism which comprises a drive module with a drive housing (14) and a drive chain (11), which drive module can be articulated on the swivel wing (20) on the one hand and on an associated frame (22) on the other hand and the drive movement of which drive module allows the swivel wing (20) to be moved between its closed position and its open position, wherein the drive housing (14) is mounted about a pivot axis (17) extending at a distance from its centre of gravity, wherein, in the closed position of the swivel wing (20), the drive housing (14) can be displaced about the pivot axis (17) into a structurally defined end position with substantial suppression of the play in the pivoting direction,
   characterized in that an automatic displacement of the drive housing (14) into the end position is provided by means of an auxiliary drive of the drive arrangement (10), and in that the auxiliary drive is formed by a spring arrangement by means of whose spring force the drive housing (14) is driven into the end position which is defined by stop means of the drive arrangement (10), comprising a stop lug (15.3) which can be fastened to the frame (22) and a stop fork (15.6) which is connected to the drive housing (14).
2. Drive arrangement according to Claim 1,
   characterized in that the drive housing (14) is of elongate design and is mounted about the pivot axis (17) via two mounting brackets (15) arranged at its ends, wherein a spring of the spring arrangement is integrated into each of the mounting brackets (15).
3. Drive arrangement according to Claim 2,
   characterized in that the two springs integrated into the bearing brackets (15) are each designed as leg springs (28).
4. Drive arrangement according to Claim 3,
   characterized in that the mounting brackets (15) each have, as main parts, a screw-on plate (15.2) with a mounting ring (15.1) and a supporting plate (15.4) with a supporting sleeve (15.5) projecting therefrom coaxially to the mounting ring (15.1), which parts are connected to one another in an articulated manner, wherein, with the mounting bracket (15) assembled, the supporting sleeve (15.5) is enclosed by the spring winding of the assigned leg spring (28).
5. Drive arrangement according to Claim 4,
   characterized in that an axle bolt (25) is provided in each case for the articulated connection between the mounting ring (15.1) and supporting sleeve (15.5).
6. Drive arrangement according to Claim 5,
   characterized in that the axle bolt (25) is supported in the mounting ring (15.1) via a concentrically arranged mounting bush (27).
7. Drive arrangement according to Claim 4,
   characterized in that a control contour with stops (stop lug 15.3, stop fork 15.6) for limiting the relative pivoting between the drive housing (14) and screw-on plate (15.2) is present between the screw-on plate (15.2) and supporting plate (15.4).
8. Drive arrangement according to Claim 7,
   characterized in that the stops (stop lug 15.3, fork stop 15.6) of the control contour define an end position of the drive housing (14) in which at least one peripheral side of the drive housing (14) lies in an approximately horizontal plane.

Images