AT511839A4 - DEVICE FOR CONTROLLING THE CLOSURE OF DOUBLE SLEEPING DOORS WHICH ARE EQUIPPED WITH SLIDING SHUTTERS - Google Patents

Abstract

The invention relates to a device for controlling the closing sequence of double-leaf swing doors, which are equipped with slide rail closers, wherein for blocking the closing movement of the active leaf (1) with the inactive leaf open movement of the sliding leaf belonging to the moving leaf (3) by means of a pair of wedge pieces ( 6, 7) is blocked, which are held guided on the sliding block (3) of the active leaf (1) and jammed by rotation of a rotary rod. The inclined surface (9) on which the wedge pieces (6, 7) abut each other, lies to the axis of rotation of the rotary rod (5) at an acute angle, with increasing distance from the axis of rotation of the rotary rod (5), the distance to the pivot axis (1.1) of the active leaf (1) increases. The width of the gap, between the rotating rod and the wall (2.1, 12.1) in which the wedge pieces (6, 7) are arranged, at that longitudinal region of the slide rail (2, 12) has a local minimum at which movement of the sliding block (3) of the Slow down the inactive leaf.

Description

description

The invention relates to a device for controlling the closing sequence of two-leaf swing doors, which are equipped with sliding rail closers, wherein one door is a unterschlagender, so-called passive leaf and the second wing is a sweeping, so-called scroll.

The device according to the invention is particularly advantageous for such doors, which have to meet a security claim, in particular for fire doors with so-called panic and escape function, advantageously applicable.

Due to folds which constitute a projection of one door leaf in front of another door leaf, it is necessary for the proper closing of a double-leaf door to close the wings in the correct order. This is the case when, from the open state, the passive leaf is first brought into the closed position and only then is the active leaf. To ensure that this takes place safely even in case of fire in fire doors, the wings are not only provided with a drive which automatically moves the door in the closed position, but also with a device for controlling the closing sequence which should cause the two leaves automatically in the closed in the right order.

If, when the inactive leaf is open, the active leaf also open, for example driven by a spring, executes a closing movement leading the inactive leaf, then this closing movement is stopped by the action of the device for controlling the closing sequence at a certain opening angle until the inactive leaf is in its closing movement enough ahead of the active leaf that the correct closing sequence is guaranteed.

In sliding rail door closers, a swivel arm protrudes from a door leaf to a sliding block, which is mounted longitudinally movably in a sliding rail arranged on the upper frame part DW of the door frame. With the door closed, that end of the swivel arm which is fastened to the door leaf lies closer to the pivot axis of the door leaf than that end of the swivel arm which is connected to the sliding block. During the majority of the closing pivoting movement of the door leaf, the sliding block slides in the slide rail away from the axis of rotation of the door leaf.

It is customary to use the movement of the sliding blocks of the individual door leaves for controlling the closing sequence and to keep or release this movement appropriately. When the inactive leaf is open, the movement of the sliding leaf of the active leaf is blocked when the active leaf is closed by a barrier. When the inactive leaf is closed, the lock is released. In most cases, it is envisaged for the release of the lock that a connected to the sliding block of the passive leaf part acts on the barrier of the active leaf.

In DE i96 05 586 A1 it is proposed to use module components for the realization of the principle described in the previous paragraph, wherein a triggering module influenced by the sliding block of the inactive leaf acts by means of a transmission module on the blocking module for the sliding block of the active leaf. Due to the modular design, adaptation to different door geometries should be particularly easy. In an otherwise unspecified embodiment, the transmission module should be formed by a mechanical link such as a rotary rod.

DE 101 22 817 B4 shows a device for controlling the closing sequence of two-leaf swing doors, which are equipped with slide rail closers, wherein a running along the slide rail, rotatable about its longitudinal axis rod as a transmission element between the inactive leaf and moving leaf

Page 2 DW 20 ······ ········································································. Rotary movement of the rotary rod is driven by a radially projecting from the rod pin which projects into the pivoting range of the Schwenkarnis between the inactive leaf and the sliding block of the passive leaf, directly by pivotal movement of the swing arm of the passive leaf. Movement of the sliding block of the active leaf is blocked or released by a radially projecting from the rotary rod cam acts as a locking member which is moved upon rotation of the rotary rod in the path of a part connected to the sliding block of the active leaf or thereof. In addition to many advantages is disadvantageous in the design that the rotary rod must be made very strong and telescopically by spring action to realize an overload protection can.

DE 40 12 358 CI shows a further device for controlling the closing sequence of two-leaf swing doors by means of Gleitschienenschließern. A in the slide on this along, rotatable about its longitudinal axis rod with a square cross-sectional area is included in the respective longitudinal region of the sliding block of the passive leaf and the sliding block of the active leaf. In the longitudinal region of the inactive leaf, the rotary rod is twisted around its longitudinal axis so that its partial lateral surfaces each have the shape of a very steep screw thread flank. The sliding block of the passive leaf comprises the thread formed in the manner of a spindle nut. When moving the sliding block of the passive leaf in the rail longitudinal direction, the rotary rod is thus rotated slightly. By this twisting wedge pieces, which are arranged on the sliding block of the active leaf, moved radially away from the corner regions of the square cross-sectional area of the rotary rod from the rotational axis of the rotary rod and clamped between the rotary rod and slide rail. This movement of the sliding leaf belonging to the active leaf along the slide away from the axis of rotation of the active leaf, blocked and thus closing movement of the active leaf stopped. A disadvantage of this design is that the device can only work in those pivoting ranges of the door leaf, in which the movement of the

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Sliders of the wings takes place during the closing movement of the wings away from the axis of rotation of the wings. In many door leaves, this movement takes place during the last part of the closing movement of the door leaf but on the axis of rotation of the door leaf. In particular, when the slide rail is disposed on the pivot axis of the door opposite side of the door frame, so that the active leaf must be brought with the open wing open in a disturbingly wide open standby position and held in this. If the wedge pieces causing the said blocking were to be placed in opposite orientation so as to block movement of the sliding block of the active leaf onto the axis of rotation of the active leaf, they would not only block closing movement of the active leaf, as required, but also with the fixed leaf open its wide opening movement.

The object of the invention is based on the device according to DE 40 12 358 CI for controlling the

Closing sequence of double-winged swing doors to improve so that it can also be used to block closing movement of the active leaf in such a range of motion of the active leaf during which moves the sliding block of the active leaf to the axis of rotation of the active leaf.

To solve the problem, it is assumed that a construction which has the following features in common with that according to DE 40 12 358 CI: - Gleitschienentürschließer be used. - To block the closing movement of the active leaf when the passive leaf is open, movement of the sliding leaf belonging to the active leaf is blocked. A rotary rod is arranged in the slide belonging to both wings, aligned parallel to this and around one

Page 4 DW 20 ···· »··············································································································································································································· - The rotary rod passes through a recess in the sliding block of the active leaf. - The width of the gap between the lateral surface of the rotary rod and a wall of the slide rail is variable by rotation of the rotary rod about said axis of rotation. - A pair of wedge pieces is arranged on the sliding block of the active leaf in the gap between the lateral surface of the rotary rod and the wall of the slide rail held out. - In dependence on the rotation of the rotary rod about its axis parallel to the slide rail axis of rotation, the wedge pieces are clamped in said gap or are loosely therein.

Measures by which the desired improvement can be achieved are proposed according to the invention: The oblique surface on which the wedge pieces rest against each other is aligned so that the distance to the axis of rotation of the rotary rod increases with increasing distance to the pivot axis of the active leaf. - In that longitudinal region of the slide, which sweeps over the sliding block of the active leaf during maximum pivotal movement of the active leaf, the minimum gap width between the wall of the slide rail and the lateral surface of the rotary rod, which occurs upon rotation of the rotary rod about its axis of rotation, depending on the coordinate in the longitudinal direction of the slide rail. - The said minimum gap width has at such longitudinal portions of the slide on a local minimum, at which for the closing sequence control movement of the sliding block of the active leaf is decelerated.

Due to the said orientation of the inclined surface on which the

Wedge pieces of the pair of wedge pieces abut each other is

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Movement of the sliding block of the active leaf blockable, which is aligned in the slide rail on the pivot axis of the active leaf. Thus, the active leaf can be braked even at advantageously small opening angles.

By said longitudinal dependence of the minimum gap width between the lateral surface of the rotary rod and the lateral surface of the slide rail, it is possible to keep the active leaf despite said alignment of the inclined surface in the opening angle range, which is above the opening angle of the waiting position, free to pivot even if the inactive leaf is open ,

The invention is illustrated including further advantageous features with reference to drawings:

Fig. 1: shows with reference to a diagram and a geometry sketch qualitatively the movement of the slide rail end of a belonging to a moving leaf pivot arm in dependence on the opening angle of the active leaf. The drawing is equally valid for swing doors according to the prior art and swing doors equipped according to the invention.

FIG. 2 shows a first device according to the invention in FIG

Sectional view with normal direction of view of the slide rail on that cutout on the slide rail on which the slide belonging to the sliding block is located.

Fig. 3: shows a sectional view of a part of a second inven tion proper device in sectional view with respect to the slide normal viewing direction.

The upper part of Fig. 1 is a partial sectional view from above of a pivoting active leaf 1, from the upper end face of a pivot arm 4.1 of a door closer 4 to a sliding block 3 in a slide rail 2 projects, which is aligned horizontally, parallel to the plane of the closed gangway , Out

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For visibility reasons, only the position of the slide 2 in Fig. 1 indicated by dashed lines.

The lower part of Fig. 1 is a diagram showing the displacement s of the sliding block 3 relative to its position with the active leaf 1 closed as a function of the opening angle of a moving leaf 1. Positive displacement means increased distance of the sliding block to the axis of rotation 1.1 of the active leaf.

When the extension of the swing arm 4.1 sweeps over the axis of rotation 1.1 of the active leaf, the sliding block 3 has its maximum distance from the axis of rotation of the active leaf. In the example shown, the sliding block 3 is pushed during the closing movement of the active leaf 1 only so long away from the axis of rotation 1.1 of the active leaf, as long as the opening angle of the active leaf is more than about 15 °; at a smaller opening angle, it is displaced towards the axis of rotation 1.1. 2, it is possible to place the waiting position of the closing movement of the active leaf only in those lower opening angle range, in which during the closing movement of the active leaf of the associated sliding on the pivot axis of the active leaf 1.1. 1 too moved.

According to the device according to the invention of FIG. 2, in the slide rail 2-which typically has an approximately C-shaped cross-sectional area-the sliding block 3 is held longitudinally displaceable, to which the swivel arm 4.1 belonging to the closer 4 of the inactive leaf 1 (FIG , The sliding block 3 is pierced by a running in the rail longitudinal direction through hole through which the rotary rod 5 passes. The rotary rod 5 extends in the groove enclosed by the slide 2 groove parallel to this. Opposite the slide rail 2, it is only about an axis parallel to its longitudinal axis (in the example shown, its axis of symmetry) rotatable, and not otherwise rotatable or displaceable.

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The sliding block 3 has a recess through which a space is formed, which is limited in the longitudinal direction of the slide 2 by walls of the sliding block 3 and in a direction normal thereto on the one hand by the rotary rod 5 and on the other hand by a wall 2.1 of the slide 2. In this recess is a pair of wedge pieces 6, 7 inserted such that only one wedge piece 6 can rest on the rotary rod 5 and only the other wedge piece 7 on the side wall 2.1 of the slide rail 2. The rotating rod-side wedge piece 6 has at its the rotary rod 5 facing Side on a parallel to the longitudinal direction of the slide rail surface. The second wedge piece 7 has on its side facing the side wall 2.1 a parallel to this side wall 2.1 surface. The two wedge pieces 6, 7 adjoin one another on an inclined surface 9, which is aligned so that the distance to the axis of rotation of the rotary rod increases with increasing distance to the pivot axis 1.1 of the active leaf. In the illustration according to FIG. 2, therefore, the pivot axis 1.1 of the active leaf (not shown) is to be assumed at some distance to the left of the sliding block 3.

The rotary rod 5 has at least one longitudinal region 5.2, in which its lateral surface is eccentrically shaped with respect to its axis of rotation, that is, the outline of its cross-sectional area deviates from that of a circular line running symmetrically about the axis of rotation. That is, for this longitudinal region 5.2, the distance between the lateral surface of the rotary rod 5 and the side wall 2.1 in the recess in which the pair of wedge pieces 6, 7 is located, changes when the rotary rod 5 is rotated about its axis of rotation. The eccentricity, so the difference between minimum and maximum distance between the lateral surface of the rotary rod 5 and the side wall 2.1 during rotation of the rotary rod about its axis of rotation 5 is such that at a minimum distance, the wedge pieces 6, 7 together the gap between the rotary rod 5 and side wall 2.1 bridge and that they can not bridge this gap at maximum distance.

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The rotary rod 5 also has longitudinal portions 5.1 which, regardless of the angle of rotation of the rotary rod, always have such a large distance from the side wall 2.1 that this distance can not be bridged by the wedge pieces 6, 7. The longitudinal regions 5.1 of the rotary rod 5 preferably predominate over the longitudinal regions 5.2.

The wedge pieces 6, 7 are entrained in sliding rail longitudinal direction with the sliding block 3 during movement of the sliding block 3 of the active leaf. Mobility of the sliding block 3 in the longitudinal direction of the slide rail can not be blocked by the rotating rod 5, regardless of its rotational position, as long as the sliding block 3 moves along longitudinal regions 5.1 of the rotary rod.

When the sliding block 3 moves along longitudinal portions 5.2 of the rotary rod 5, its mobility in the longitudinal direction of the slide rail depends on the rotational position of the rotary rod. When the axis of rotation 5 is in a position at which the distance between its longitudinal region 5.2 to the side wall 2.1 is maximum, movement of the sliding block 3 is not hindered.

If the rotary rod 5 is in a position in which the distance between its longitudinal region 5.2 to the side wall 2.1 is minimal, movement of the sliding block 3 is already hindered because the wedge piece 7 is pressed against the wall 2.1 of the slide rail 2 and braked by friction becomes. This braking effect is different for the two possible directions of movement of the sliding block 3.

Upon movement of the sliding block 3 of the active leaf on the axis of rotation of the active leaf to (according to FIG. 2, ie to the left) acts on the wedge piece 7 of the wall 2.1 from a frictional force by which this wedge piece on the inclined surface 9, to which the wedge pieces. 6 , 7 abut each other, away from the rotary rod 5 and increased to the wall 2.1 is pushed, so thus the friction is further increased. In the case of a very flat embodiment of the oblique surface 9, that is to say if it has a very acute angle to the longitudinal direction of the sliding surface 9.

Page 9 DW 20 • · ······································································································································································································ It is better to make the inclined surface 9 so steep that this complete blockage can not occur. In order to ensure that nevertheless sufficiently high minimum braking force is achieved in order to be able to stop the moving leaf during its closing movements driven by the door closer until the inactive leaf is closed, the compression spring 8 clamped between sliding block 3 and wedge piece 7 presses on the wedge piece 7 from the same direction. from which the frictional force through the wall 2.1 acts on the wedge piece 7. The optimum inclination of the inclined surface 9 and the optimum bias of the spring 8 to reliably avoid complete blocking on the one hand, on the other hand reliably provide sufficiently high braking force depends mainly on the coefficients of friction on the inclined surface 9 and the contact surface of the wedge piece 7 with the wall 2.1 from , In the context of expert action, optimal values can be found easily by combining calculations and tests. By - with proper interpretation of the inclination of the inclined surface 9 and the bias of the spring 8 - movement of the sliding block 3 on the axis of rotation of the active leaf is not completely blocked, but is braked only with a certain force, an overload protection is realized. This overload protection prevents damage to occur when attempting to close the active leaf out of its waiting position without first closing the passive leaf.

Upon movement of the sliding block 3 of the active leaf away from the axis of rotation of the active leaf (as shown in FIG. 2 thus to the right) acts on the wedge piece 7 of the wall 2.1 from a frictional force by which this wedge piece on the inclined surface 9, to which the wedge pieces. 6 , 7 abut each other, is pushed away from the wall 2.1, so thus the friction is reduced and mobility remains possible in any case. The sliding block 3 of the active leaf is thus independent of the rotational position of the rotary rod. 5

Page 10 DW 20 ··· * · * · · I · * I I · * · «·· I« «·« ·· m «* always displaceable away from the axis of rotation of the active leaf. When the sliding block 3 moves over the longitudinal region 5.2 of the rotary rod 5 and the rotary rod is in that rotational position in which the gap width between its lateral surface and the wall 2.1 is minimal, the movement of the sliding block 3 while a low friction is opposed because the sliding block 3 according to the compression spring 8 is pressed against the wall 2.1.

The rotational position of the rotary rod 5 is intended - as known from the documents mentioned at the beginning of the prior art - influenced by the inactive leaf.

According to a first known principle, the rotary rod 5 in that longitudinal region which is run over by the sliding block of the passive leaf have a very steep thread and the sliding block of the passive leaf is designed as a spindle nut and accordingly has the matching steep complementary nut thread, so that it moves along in its movement the slide the rotary rod 5 rotates.

According to a second known principle, a lever can protrude radially from the rotary rod 5, which protrudes into the pivoting range of the pivoting arm of the inactive leaf and thus is likewise pivoted upon movement of this pivoting arm.

Due to the invention described alignment of the inclination of the inclined surface 9 is achieved in addition to the advantage already mentioned as a further advantage that the pivot arm 4.1 of the active leaf 1 is not burdened in the waiting position to pressure, but on train. Thus, much slimmer designs are possible than they would be possible in construction according to the prior art and it is possible to lay the waiting position of the active leaf very close to those opening angle of the inactive leaf, in which the sliding direction of the sliding block 3 at the same pivoting direction of the Active wing reverses. In the area of this reversal point, the door closer 4 of the active leaf 1 exercises

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Blockade of the sliding movement of the sliding block 3 on the swing arm 4.1 an extremely large normal force. By in the construction according to the invention, this normal force is a tensile force and not as in the construction according to the prior art, a compressive force, it is much better manageable.

If the inactive leaf is open (beyond a certain minimum angle), block the movement of the active leaf in a waiting position. Other movement of the active wing, for example, further open, should already be possible. To achieve this, according to the embodiment shown in FIG. 2, the rotary rod 5 is subdivided into longitudinal zones 5.1 and 5.2, the longitudinal zones 5.1 being so slender that movement of the sliding block 3 of the active wing can never be stopped.

This design is robust and well functional, but has the disadvantage that the position of the longitudinal region 5.2, which represents a local narrowing of the gap between the rotary rod 5 and wall 2.1 of the slide rail 2, is dependent on the geometric relationships of the pivoting door to be controlled. For different geometries of swing doors are thus different turning rods provide.

A local narrowing of the gap between the rotary rod and a wall of the slide rail - as required for the Schließfolgesteuerung - can also be achieved by locally thickening the relevant wall of the slide rail. An advantageous embodiment of this is illustrated in FIG. A wall 12.1 of the slide rail 12 is provided with a grid of apertures 12.2, to which a applicator member 13 is plugged with the bridges 12.2 complementary projections. The application part 13 then represents a local thickening of the wall 12.1, through which in a limited longitudinal region of the slide rail 12, the distance between the wall 12.1 and the rotary rod is reduced. The rotary rod can now be used in the entire longitudinal area,

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·································································································································································································, which is covered by the sliding block of the active leaf, have the same eccentric cross-sectional shape throughout The held on sliding block pair of wedge pieces can bridge the gap between the rotating rod and wall 12.1 only in that longitudinal region in which the application member 13, the thickness of the wall 12.1 reinforced and thus reduces the gap width. In this embodiment, it is particularly advantageous that the position of the local constriction of the said gap on the slide rail 12 is adjustable by the applicator portion 13 is plugged at the appropriate location of the grid in the wall 12.1. So that there can be no tilting between a wedge piece and the application part, the intended contact surfaces between the two parts should have bevelled edges.

In an advantageous embodiment, the gap between the rotary rod 5 and wall 2.1 or 12.1 of the slide rail is narrowed not only in that longitudinal region at which the sliding block of the active leaf for the closing sequence control is to be kept in a waiting position, but also in that longitudinal region at which the sliding block of the active wing comes when the active leaf is completely closed. This can be achieved in a very economical manner, a gentle braking of the active leaf at the end of its closing movement.

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Claims (6)

A device for controlling the closing sequence of double-leaf swing doors, which are equipped with slide rail closers, wherein one door leaf is a knock-down, so-called still-wing is and the second wing an overturning, so-called active leaf, - being blocked for the blocking of the closing movement of the active leaf (1) with the fixed leaf movement of belonging to the active leaf sliding block (3), - wherein a rotary rod (5) in the sliding rail (2, 12) belonging to both wings is arranged parallel to it and can be rotated about an axis of rotation aligned parallel to the slide by pivoting the inactive leaf, wherein the rotary bar {5) is formed by a recess in the sliding block (3) of the Gangway (1) runs, - wherein the width of the gap between the lateral surface of the rotary rod (5) and a wall (2 .1, 12.1) of the slide rail is variable by rotation of the rotary rod about said axis of rotation, - wherein a pair of wedge pieces (6, 7) on sliding block (3) of the active leaf in the gap between the wall (2.1, 12.1) and the lateral surface of In which the wedge pieces (6, 7) are clamped or lie loosely in relation to the rotation of the rotary rod (5) about their axis of rotation parallel to the slide rail, characterized in that the surface on which the wedge pieces (6, 7) abut each other is formed as an inclined surface (9), which to the side DW DW 20 • # I · · · φ · Φ · · «Φ * Φ * ♦ *» · * • Axis of the rotary rod (5) occupies an acute angle, whereby the distance to the axis of the active leaf (1) increases with increasing distance to the axis of rotation of the rotary rod (5), - That in that longitudinal region of the slide rail (2 , 12), which the sliding block (3) of the active leaf (1) covers during a maximum possible pivotal movement of the active leaf, the minimum gap width between the wall (2.1, 12.1) and the lateral surface of the rotary rod (5), which upon rotation of the rotary rod ( 5) on its axis of rotation occurs depending on the coordinate in the longitudinal direction of the slide rail (2, 12), - and that said minimum gap width at such longitudinal portions of the slide rail (2, 12) has a local minimum, to which movement of Sliding block (3) of the active leaf (1) for controlling the closing sequence of the door leaf is braked. 2. Apparatus according to claim 1, characterized in that on a wedge piece (6, 7) of the sliding block (3) from a prestressed spring (8) exerts a parallel to the slide rail force aligned, which is oriented so that in the absence other forces, the wedge piece (7) facing away from the rotary rod (5) along the inclined surface (9) of the rotary rod (5) moves away. 3. Apparatus according to claim 1 or claim 2, characterized in that the rotary rod (5) in that length range, which is covered by the sliding block (3) of the inactive leaf (1) during a pivoting movement of the inactive leaf, two longitudinal regions (5.1, 5.2) , wherein the maximum radial distance of a cross-sectional surface area of the rotary rod (5) from the axis of rotation of the rotary rod (5) in the longitudinal area (5.2) is greater than this maximum radial distance in the longitudinal area (5.1) and wherein the outline of the cross-sectional area in the side 15 DW 20 • · · The longitudinal area (5.2) deviates from a circular line with the axis of rotation of the rotary bar (5) as an axis. 4. Apparatus according to claim 1 or claim 2, characterized in that the wall (12.1) in that longitudinal region of the slide rail (12) which is covered by the sliding block (3) of the passive leaf (1) during a pivoting movement of the inactive leaf, a local survey has, which protrudes from the other wall portion (12.1) in the direction of the rotary rod. 5. Apparatus according to claim 4, characterized in that the local elevation on the wall (12.1) by a separate application part (13) is formed, which on the wall (12.1) is fixed. 6. Device according to one of claims 1 to 5, characterized in that the gap between the rotary rod (5) and wall (2.1, 12.1) of the slide rail (2, 12) in addition to that longitudinal region on which the sliding block of the active leaf for the Keep closing sequence control in a waiting position is narrowed, even in that longitudinal region at which the sliding block of the active leaf reaches when the active leaf is completely closed. Page 16