WO2019091594A1 - Self-locking lock device with multipoint lock - Google Patents

Abstract

The invention relates to a self-locking lock device having a main latch element, which automatically moves into a locking position when the activation is on the closing plate side, wherein the main latch element comprises a drive element for a multipoint lock, which drives at least two additional latch elements of at least one additional latch device at a spatial distance from the main latch element, wherein the drive element is connected to a drive device for at least one additional latch element, characterized in that the drive device comprises a first drive part and a second drive part, wherein the drive element interacts with the first drive part for a first additional latch element and with the second drive part for a second additional latch element, and a movement of the first drive part and of the second drive part is synchronised with a movement of the main latch element.

Description

 SELF-LOCKING LOCKING DEVICE WITH

 MULTIPLE COMPRESSION DRIVE

The present invention relates to a self-locking device with ei _¬ NEM trigger element and a main locking element, which automatically moves when Schließblechseiti- ger activation of the trigger element in a closed position, the main locking element comprises a drive element for a Mehrfachverriegelungsan- drive, the at least one Additional bolt Sclmeßvoirichtung with at least one additional locking element at a distance from the main locking element drives, wherein the drive element cooperates with a drive device for at least one additional locking element.

The present invention also relates to an auxiliary latch device for such a self-locking latch.

From EP 2 956 605 AI such a self-locking locking device is known. The main locking element has a pin which engages in a guide slot of a locking rod. The guide slot extends obliquely to a direction of movement of the pin when the main locking element is moved to the closed position or in the open position. Due to the oblique arrangement of the guide slot, the locking rod is moved in a closing movement in one direction and in a Öffhungsbewegung in the other direction. In this way, a closing or opening operation is effected on the at least additional locking element, either directly or indirectly after deflection of the direction of movement of the locking rod. This known self-locking locking device has the disadvantage that the movement initiated in a closing operation or opening operation in one direction requires a great deal of force. This is not desirable in an automated process. The locking device should be smooth. In addition, the additional locking elements must be designed differently, since the locking bar moves in a closing operation or during an opening operation relative to these in each case in a different directions.

Other self-locking locks are well known in the art. These are constructed so that the closing device z. B. when a door closes, automatically locked when a trigger element is activated or actuated closing plate side. There are also multi-lock actuators known from the prior art, for. B. a door not only on the directly with the

Locking device in connection with the main locking element but also with at least one additional additional locking element at a vertical distance to the main locking element to lock. Such multiple-locking actuators are regularly actuated via a separate locking mechanism after the actual main lock has been locked. For this reason, then several lock cylinders are required, which may also require different keys required. The handling of such a known multiple locking in connection with such a known self-locking locking device is thus uncomfortable and expensive for the user. The object of the present invention is therefore to develop a self-locking Schließvor _¬ direction of the type mentioned in such a way that can be done much easier with this in a single automatic closing multiple locks.

The object is achieved in that the drive means comprises a first drive part and a second drive part, wherein the drive element cooperates with the first drive part for a first additional locking element and with the second drive part for a second additional locking element and a movement of the first drive part and of the second drive part is synchronized with a movement of the main locking element.

The present invention is based on the idea of deflecting in the mounted state of a closure device in approximately horizontal movement of a main locking element in two vertical movements, so as to independently control at least two additional additional locking elements, when the lock of the main locking element is automatically triggered ,

This is achieved quite advantageously in that two additional locking elements are driven by separate drive parts. The force is split during a closing movement and during an opening movement. In addition, the two additional locking elements can be designed identical.

Another advantage is that the first drive part and a first locking bar the second drive part having a second locking bar and at a BEWE _¬ supply of the main locking element in a locking direction, the first locking Stan _¬ ge in a different from the locking direction first direction and the second locking rod in one of the of the locking direction, and first direction under _¬ different second direction moves.

By the first and second deflection of the movement from a bolt direction in a different direction to the bolt direction and a direction different from the bolt and the first direction different from the main latch element lying identical additional locking elements can be controlled and moved.

Another advantage of the present invention is that the locking bar has a longitudinal axis and the guide device is aligned in a main plane obliquely to the longitudinal axis.

Due to the oblique arrangement of a guide device, it is possible to cause the extension piece connected to the main locking element not only to a horizontal movement but also to a vertical movement when the main locking element is moved in the operating state between a closed position and a Öfrhungsstellung.

A further advantage of the present invention is that the filling device has a slope, wherein the extension piece moves the slope on the way of the main Bar element from the closed position in the Öffhungsstellung overcomes.

This embodiment corresponds to the embodiment described in the following description and can be realized constructively low.

Alternatively, it may also be advantageous that the Fülmmgseinrichtung has a slope and the extension piece overcomes the slope on the way of the main locking element from the closed position to the Öffhungsstellung. This embodiment could be structurally favorable under certain circumstances, so that the expert is free to choose between the embodiments depending on the application.

A further advantage of the present invention is that the extension piece is arranged on a lower edge of the main locking element. The position of the extension and the slope determine the path of the respective additional locking element between the closed position and the Öffhungsstellung.

Another advantage of the present invention is that the other piece is located at an upper edge of the main latch member. In this case, also determine the extension and the slope of the Fülbrungseinrichtung the way between the closed position and the Öffhungsstellung the respective additional locking element.

Another advantage of the present invention is that the other piece is guided in parallel from its movement in the longitudinal slot at both. As a result, a fixed guide in both directions of the extension piece between a closed position and ensures an open position.

Likewise, it is advantageous that the extension piece is a roller having a rotation axis perpendicular to the main plane. By a roller, the friction in the Füh _¬ tion device is significantly reduced.

Another advantage of the present invention is that the locking bar is connected via a second actuator lug with a second additional locking element. This makes it possible to produce a multi-point lock at the top, for example, at the door, in the middle and at the bottom of a door.

Finally, it is also advantageous that a closing device is equipped with a multiple-locking drive according to the present invention.

An embodiment of the present invention will be described in more detail below with reference to the drawings. Show it:

1 shows a schematic view of a closing device with multiple locking drive according to the present invention in the closed position;

Fig. La is a schematic view of a first Ajatriebseinrichtung for

 Locking device of Fig.l;

Fig. Lb is a schematic view of a second Anlriebseinrichtung for ScMießvorrichtung from Fig.l;

FIG. 2 shows a schematic view of a multi-locking drive sliding device according to the present invention in the open position; FIG.

Fig. 2a is a schematic view of a first drive means for the

 Locking device of Figure 2;

2b is a schematic view of a second Anlriebseinrichtung for

 Locking device of Figure 2;

FIG. 3 shows a schematic view of the locking device with multiple locking drive from FIG. 1, with the auxiliary locking bolt open; FIG.

FIG. 4 shows a schematic view of the locking device with multiple locking drive from FIG. 2, with the auxiliary locking mechanism open; FIG.

In Fig. 1 is a schematic view from the side of an arrangement of a self-locking closure device 1 is shown with a multi-lock actuator 2, which is in a closed position. In Fig. 2 is a schematic view from the side of an arrangement of a self-locking closure device 1 is shown with a multi-lock actuator 2, which is in an Öffhungsstellung. The Schließvorrichrung 1 is arranged for example in a door and is bounded on one side by a faceplate 3, in which openings 7 are formed are, wherein a main lock member 5 in a locking direction by a RR Publ _¬ voltage through 7 in a closed position (Fig. 1) and back in a Öffhungsstellung (Fig. 2) can be moved. In Fig. 1 and Fig. 2, the path (the latch direction RR) of the main latch member 5 from the closed position to the opening position and vice versa are each represented by an arrow.

The closing device 1 has a cylinder lock 9, by means of which the closing device can be triggered manually in order, for example, to move the main locking element 5 out of the closed position into the open position or vice versa out of the open position into the closed position. Alternatively and not shown, the locking device 1 may also be provided with an electromagnetic door opener which automatically triggers a closing operation and / or an opening operation without the cylinder lock 9 having to be actuated.

By activation, the biased by a first compression spring 12 main locking element 5 is moved through its opening 7 in the closed position and blocked in this.

In many situations, it is desirable not to close a door, a window or any other component closing a wall opening with a single main locking element 5, but additionally at least one additional auxiliary locking device 11 having at least one additional locking element 11.1. 11.2 to use. The locking mechanisms for additional locking elements 11.1 and 11.2 can be configured as desired. A preferred and for the present invention favorable embodiment is shown in Figures 3 and 4. The respective To _¬ set-locking elements 11.1, 11.2 are connected via a actuator tab 13.1, 13.2 connected to a first lock rod 15.1 or second locking bar 15.2.

The first locking bar 15.1 has a first longitudinal axis LI and a main plane H, which coincides with the plane of the sheet of FIG. The second locking bar 15.2 has a second longitudinal axis L2 and a main plane H which coincides with the plane of the sheet of FIG. The first locking bar 15.1 has a first free end 15.3, in which engages the actuator tab 13.1 of a first Zusatzriegel- ScWießeinrichtung 11. The second locking bar 15.2 has a second free end 15.4, in which engages in the present embodiment, the second actuator tab 13.2 of a second auxiliary bolt locking device 11.

Locking rod and actuator tab do not mesh directly with each other but are coupled by a connecting rod element (can be up to 40cm long).

The respective actuator tabs can also be connected to more than one single additional locking element 11.1, 11.2. The first locking bar 15.1 and the second locking bar 15.2 are movable in Fig. 1 and in Fig. 2 upwards and downwards. In this case, the first locking bar 15.1 moves in a first direction ER and the second locking bar 15.2 moves in a second direction ZR, the two directions ER and ZR being opposite to one another in the present embodiment. In a built-in state, such a movement corresponds to a movement approximately in the vertical direction (upwards or downwards). Moved in the embodiment shown in the figures up or down). In the embodiment shown in the figures, the first locking bar 15.1 moves upwards (ER) during a closing operation and downwards (ZR) during an opening operation, while the first locking bar 15.2 moves synchronously downwards (ZR) during a closing operation and during an opening operation synchronously moved up (ER).

The main locking element 5 moves behind the main plane transversely to the first and second locking bar 15.1 and 15.2. In the installed state, the main locking element 5 performs an approximately horizontal locking movement in a locking direction RR, which means a movement to the left in the figures during a closing operation and a movement to the right in an opening operation. On the side facing the viewer of the main locking element 5, a drive element 17 is formed as a lug or pin.

In the present embodiment, the drive device comprises a first drive part 17.1 with the first locking bar 15.1 and a second drive part 17.2 with the second locking bar 17.2.

In Fig. La, the integrated in the closure device 1 in Fig. 1, the first drive part 17.1 is shown separately, ie in the closed position. In Fig. Lb, the integrated in the closing device 1 in Fig. 1, the second drive part 17.2 is shown separately, ie also in the closed position. In Fig. 2a, in the closing device 1 in Fig. 2 integrated, the first drive part 17.1 is shown separately, ie in the open position. In Fig. 2b is the integrated in the locking device 1 in Fig. 2, the second drive part 17.2 shown separately, ie also in the Öffoungsstellung.

The first drive part 17.1 comprises the first locking bar 15.1 with the main plane H and the second drive part 17.2 comprises the second locking bar 15.2 with the main plane H. The two drive parts are arranged in Fig. 1 and Fig. 2 perpendicular to the plane or main plane H in succession and can glide on each other during operation. In the illustrated embodiment, the two drive parts 17.1 and 17.2 are substantially identical in shape and rotated by a horizontal and arranged mutually displaced in a vertical, so that the two locking rods 15.1 and 15.2 can overlap in the installed state at least partially.

The drive element 17, connected to the latch 5, can also be designed as a roller with a rotation axis perpendicular to the main plane H. The drive element 17 engages in a first guide means 19.1 of the first locking bar 15.1 and in a second Fürirungseinrichfting 19.2 of the second locking bar 1 .2 a. In the present embodiment, the first and the second guide means 19.1 and 19.2 are each a recess and in particular in each case a longitudinal slot extending in the main plane H obliquely to the first and second longitudinal axis LI, L2. The angle between the first guide device 19.1 to the first longitudinal axis LI and the second For gseinrichtung 19.2 to the second longitudinal axis L2 need not be defined for the present invention, but is in the range of about 30 ° to about 50 °. The angle of the first guide device 19.1 with respect to the first longitudinal axis LI can also be different from the angle of the second guide means 19.2 with respect to the second longitudinal axis L2. In the embodiment illustrated in the figures exporting _¬ approximate shape of the angle is the same.

The alignment of the first and second Fühi gseinrichtung 19.1 Führungsein _¬ device 19.2 in relation to their longitudinal axes LI and L2, but is mirror-inverted. In the illustrated embodiment, the pitch of the first joining device is

19.1 for the drive element 17 during a closing movement (main locking element 5 to the left) positive and negative at an opening movement (main locking element 5 to the right). The slope of the second Fühnmgseinrichtung 19.2 is negative for the drive element 17, however, in a closing movement (main locking element 5 to the left) and positive at a Öff ungsbewegung (main locking element 5 to the right).

The formed as a longitudinal slot first Fü mmgseinrichtung 19.1 has two parallel first longitudinal edges and designed as a longitudinal slot second Fübjrungseinrichtung

19.2 has two parallel second longitudinal edges. The drive element 17 is guided in each case at the first longitudinal edges and the second longitudinal edges of the longitudinal slots 19.1 and 19.2. In other embodiments, the first Fugenmgseüirichtung 19.1 and the second guide means 19.2 may be designed differently and even very different. It is also possible that the first and second Fürirungseinrichtung 19.1 and 19.2 are uneven and include different angles to their longitudinal ^¬ axes.

In the illustrated embodiment, the first guide means 19.1 for the Drive element 17 on the way from the illustrated closed position into an opening _¬ tion position (arrow) a positive slope (the drive element is _¬ retracted, moves down), which overcomes the drive element 17 in this way and forms the second guide means 19.2 for the drive element 17th on the way from the illustrated closed position into a Öffhungsstellung (arrow) a negative slope (the drive member is retracted, moved upwards), which overcomes the drive member 17 in this way. On the way from the closed position into the Öffhungsstellung due to predetermined guide paths relative movement between the drive member 17 and each of the first Fungung device 19.1 and second guide means 19.2 instead. The overcoming of the positive and negative slope of the first and second Fü mmgseiririchtung 19.1, 19.2 is due to the horizontal movement (latch direction RR) of the main locking element 5, which forces each of the first locking bar 15.1, to dodge in the vertical direction downwards (arrow) and the second locking rod 15.2 forces to dodge in the vertical direction upwards (arrow direction). Dodge is made possible by the Führimgseinrichtung 19.1 or 19.2.

In Fig. La, the first drive part 17.1 is shown with the longitudinal axis LI in detail. In Fig. Lb, the second drive part 17.2 with the longitudinal axis L2 with respect to the first drive part 17.1 laterally moved to the left but in the position in which the two drive parts in Fig. 1 are superimposed and can slide along each other. The first locking bar 15. 1 has a first free end 15. 3, which is designed to produce a mechanical connection with a first auxiliary bolt closing device 11. The first free end 15.3 is much narrower in the main plane H. designed as the first locking bar 15.1. The first locking bar 15.1 has a widening by about twice. In this area, the first guide device 19.1 is formed as a longitudinal slot in the manner already described in the first locking bar 15.1. The Feühiimgseiiarichtung 19.1 is inclined with respect to the first longitudinal axis LI and extends in the illustrated Ausfiüirungsforrn from bottom left to top right. The second locking bar 15.2 has a second free end 15.4 which is designed to produce a mechanical connection with a second auxiliary bolt closing device 11. The second free end 15.4 is also much narrower in the main plane H than the second locking bar 15.2. The second locking bar 15.2 has a widening by about twice. In this area, the second guide device 19.2 is formed as a longitudinal slot in the manner already described in the second locking bar 15.2. The second Fülmmgseinrichtung 19.2 is arranged obliquely with respect to the second longitudinal axis L2 and extends in the illustrated embodiment from top left to bottom right.

In FIG. 2 a and FIG. 2 b, the first drive part 17. 1 and the second drive part 17. 2 are shown with respect to one another as in FIG. 1 a and FIG. 1 b, but shifted in the opening position, that is to say in the longitudinal direction, so that both drive parts to superimpose a larger piece.

In Fig. 3, the two auxiliary locking devices 11 are shown open. Since both auxiliary locking devices 11 are identical in construction and are arranged only mirror-inverted, only the upper auxiliary locking device 11 in FIG. 3 will be described in greater detail here described. The upper auxiliary bolt closing device 11 has a first auxiliary bolt closing element 11.1. This is located in Fig. 3, as well as the main locking element 5, in the closed position. The first auxiliary bolt closing element 11.1 is connected via an additional bolt drive element 14, which is connected to the auxiliary bolt closing element 11.1, and a first auxiliary bolt guide device 16.1 with an additional bolt drive part 25. The actuator tabs 13.1 and 15.3 do not engage directly with each other, but are coupled by a connecting rod member (can be up to 40cm long).

The additional bolt drive part 25 in turn has at a free end the actuator lug 13.1 for mechanical connection to the first free end 15.3 of the drive part 15.1. Also, the first auxiliary bar Fülirungseinrichtung 16.1 is a longitudinal slot, which is aligned according to the first Fühiimgseinrichtung 19.1. In the present embodiment, the angle to a vertical is also equal to the corresponding angle of the first guide device 19.1. But that does not have to be the case in other embodiments. The angle can be adapted to the distance of the additional bolt-closing element 11.1. In order for the whole to work, the auxiliary bar drive element 14 engages the top of the first auxiliary bar guiding device 16.1 and the bottom of a horizontal second auxiliary bar guiding device 16.2, which is formed in the housing bottom.

In this way, the auxiliary latch member 25 moves down, connected to 15.3 and driven by means of a connecting element with drive part 15.1 in the Öffhungsstellung shown in Fig. 4 The auxiliary bolt driving part 25 must move in a horizontal Öffhungsbewegung in the Öfmungsstellung shown in Fig. 4 down and shifts down together with the first drive part 15.1 down to the Öfmungsstellung is reached in Fig. 4. The auxiliary bar drive element 14 is then in Fig. 4 in the vicinity of the other upper end of the first auxiliary bar Fühi ^ gseinrichtung 16.1. In a horizontal closing movement from the Öfmungsstellung in Fig. 4 in the closed position in Fig. 3, the processes are reversed.

In other embodiments, the closing or opening movement need not necessarily be horizontal. The respective closing elements may have other (eg greater or less than 90 ° to the vertical) and also different directions of movement to each other. The principle always remains the same.

LIST OF REFERENCE NUMBERS

1 locking device

 2 interlock drive

 3 faceplate

 5 main locking element

 7 opening

 9 cylinder lock

 11 additional bolt locking device

 11.1 first additional locking element

 11.2 second additional locking element

 12 compression spring

 13.1 Actuator tab

 13.2 Actuator tab

 14 additional bolt drive element

 15.1 first locking bar

 15.2 second locking bar

 15.3 first free end

 15.4 second free end

 16.1 first auxiliary bar guide device

16.2 second auxiliary bar Fühimgseinrichtung 17 drive element / extension piece

 17.1 first drive part

17.2 second drive part 17.3 Rotary axis roller

 19.1 first sensing device

19.2 Second filling device 25 Additional bar driving part LI first longitudinal axis

 L2 second longitudinal axis

 H main level

 RR latch direction

 He first direction

 ZR second direction

Claims

claims A self-locking latch (1) having a main latch member (5) which automatically moves to a closed position upon rocker-side activation, the main latch member (5) comprising a drive member (17) for a multi-latch drive (2) at least two additional locking elements (11.1; 11.2) of at least one additional locking device (11) at a spatial distance to the main locking element (5) drives, wherein the drive element (17) with a drive means (17.1, 17.2) for at least one additional Bar element (11.1, 11.2) cooperates,  characterized,  in that the drive device comprises a first drive part (17.1) and a second drive part (17.2), the drive element (17) being connected to the first drive part (17.1) for a first additional latch element (11, 1) and to the second drive part (17.2). for a second additional locking element (11.2) cooperates and a movement of the first drive part (17.1) and the second drive part (17.2) is synchronized with a movement of the main locking element (5). 2. Self-locking closure device (1) according to claim 1,  characterized, in that the first drive part (17.1) has a first locking rod (15.1) and the second drive part (17.2) has a second locking rod (15.2) and, in the case of a movement of the main locking element (5) in a locking direction (RR), the first locking rod (15.1) in a direction different from the locking direction (RR) first direction (ER) and the second Vemegelungsstange (15.2) moves in a direction different from the locking direction (RR) second direction (ZR). 3. Self-locking closure device (1) according to claim 1 or 2,  characterized,  in that the first locking bar (15.1) comprises a first guiding device (19.1) and the second locking bar (15.2) comprises a second guiding device (19.2), the driving element (17) being arranged in the first guiding device (19.1) and in the second guiding device (19.2). intervenes. 4. Self-locking closure device according to claim 3,  characterized,  the first locking rod (15.1) has a first longitudinal axis (LI) and the first guide device (19.1) is aligned obliquely to the first longitudinal axis (LI). 5. Self-locking closure device according to claim 3 or 4,  characterized, that the second locking bar (15.2) has a second longitudinal axis (L2) has ^¬ and the second F & irangseinrichtung (19.2) diagonally to the second longitudinal axis (L2) is aligned. 6. Self-locking closure device according to one of claims 3 to 5, characterized  in that the first guide device (19.1) has a first incline and the second expander device (19.2) has a second incline, wherein the first incline is opposite to the second incline. 7. Self-locking closing device according to one of claims 3 to 6,  characterized,  the first carriage mechanism (19.1) and the second guide mechanism (19.2) are each designed as a longitudinal slot with two parallel longitudinal edges (19.3, 19.4). 8. Self-locking closure device according to one of claims 3 to 7,  characterized,  that the drive element (17) is guided in its movement in the longitudinal slot at both parallel longitudinal edges (19.3, 19.4). 9. Self-locking closure device according to one of claims 2 to 9,  characterized,  in that the drive element (17) comprises a roller which has an axis of rotation (17.3) perpendicular to the main plane (H). 10. Self-locking closure device according to one of claims 1 to 9, characterized that the Mehifachveniegelungsantrieb (2) via a first actuator lug (13.1) with the at least one additional locking element (11.1) is connected. 11. Self-locking closure device according to one of claims 1 to 11, characterized  in that the multiple-locking drive (2) is connected to the at least one additional locking element (11.2) via a second actuating drive lug (13.2). 12. Zusa1z-locking device (11) for a self-locking closure device according to one of claims 1 to 11,  characterized,  in that each additional locking element (11.1, 11.2) comprises an auxiliary locking drive element (14) which cooperates with an auxiliary locking device (16.1) of an auxiliary locking drive part (25) and a movement of the auxiliary locking drive part (25) with a Movement of the auxiliary bar drive element (14) synchronized. 13. Additional locking device (11) according to claim 12,  characterized,  in that the additional bolt guide device (16.1; 16.2) forms a slope for the additional bolt drive element (14) when the additional bolt drive part (25) moves. 14. Additional locking device (11) according to claim 12 or 13, characterized, in that the additional bolt-guiding device (16.1, 16.2) is designed as a longitudinal slot with two parallel longitudinal edges, and the additional-bar drive element (21) is guided on its movement in the longitudinal slot on both parallel longitudinal edges.