EP0413177A1 - Lock for driving rod - Google Patents

Abstract

The invention relates to an espagnolette lock having espagnolettes displaceable as a result of the rotation of the handle or the like and having a follower which is assigned to the handle and which, held in its basic middle position, can be pivoted out of this in opposite directions counter to springload, the lock case carrying a face plate which is continued, on the far side of the lock case, in freely projecting face-plate portions (1'), behind which are guided the espagnolettes (48) which control additional locking members, for example pivoting bolts, arranged in the region of the face-plate portions (1'), in such a way that these locking members can be introduced into counterlocking parts, located on the frame, both as a result of the rotation of the handle and as a result of the release of at least one force accumulator (55) loading the espagnolettes, the release of the force accumulator (55) being obtained by means of a release device (63) actuated by the frame or the like during the closing of the door, the release device (63) and/or the force accumulator (55) being arranged on the rear side of the free projecting face-plate portions (1'). To allow release also by means of a movement perpendicular to the face-plate plane in the direction of the striking plate (88), the invention proposes that the release device (63) be actuable in a direction perpendicular to the front side of the face plate. <IMAGE>

Description

The invention relates to an espagnolette lock according to the preamble of claim 1.

In the case of an espagnolette lock of the type in question, the trigger and the energy accumulator are each arranged on the back of the free protruding cuff rail sections outside the closure housing, so that the espagnolette lock can be produced in very small dimensions. It can be installed both with and without an energy accumulator. A door lock is to be carried out in the usual way without an energy accumulator and trigger. With the energy accumulator and the trigger, the locking elements already move into their locking position when the door is closed. The energy accumulator is charged during the opening movement by pressing the lever. The possibility of using this embodiment proves to be limited, however, since the trigger can only be actuated in the direction transverse to the faceplate. Unlike a swing door, where the faceplate swings in transversely to the striking plate during the closing process, z. B. in a sliding door, the faceplate moves vertically or approximately vertically against the striking plate.

The object of the invention is based on the task of designing an espagnolette lock of the type in question in a technically simple manner in such a way that triggering is also possible via a vertical movement to the faceplate plane in the direction of the striking plate.

This object is achieved in the invention specified in claim 1.

The subclaims represent advantageous developments of the inventive solution.

The espagnolette lock can be used for both sliding and swinging doors. The trigger is preferably arranged on the free faceplate section and has an extremely small installation depth. The design of the drive rod as a spreading spring and the formation of the locking edge by the faceplate enable the trigger to be created with very little effort. In addition to two bends on the drive rod, only two spacers and a pin provided with an annular groove are initially required. The trigger and the energy store can be located outside the lock housing, so that the drive rod lock can be created in small dimensions while realizing a small lock construction depth. B. proves advantageous when installed in tubular frame doors. Both the energy accumulator and the trigger can be provided at any point on the free, protruding faceplate sections. When using the espagnolette lock on a sliding door, the trigger can be equipped with an extremely flat head. Then the trigger does not form a disturbing protrusion in the closed position and the position of the trigger need not be taken into account when designing the striking plate. Favorable accommodation is also guaranteed with regard to the energy accumulator. The faceplate sections and / or the drive rods can form bends to form a chamber for receiving the energy store designed as a compression spring. If necessary, several such chambers can be provided, so that can always implement a predetermined force storage force. This embodiment also meets the purpose of coupling the drive rods via corner deflections and providing locking members on the horizontal drive rod sections. Sufficient force is always available which is sufficient to bring the corresponding locking members into their locked position. If this is not the case, for example, when the door is warped, the closing force can be increased by moving the handle against the normal actuation of the handle.

Closing the door causes a force on the trigger against the spring force of the U-shaped spreading spring, so that the trigger comes out of its locked position and releases the energy accumulator with the driving rods, which in turn brings the closing slider into the locked position. When using the espagnolette lock on a sliding door, the trigger is acted on vertically by the striking plate. The trigger head on a pivoting door is preferably designed as a truncated cone, in the shape of a trap. When the door is swung into the frame, the trigger is then acted upon either by the edge of the striking plate itself or by a run-on slope of the striking plate. When the drive rods are moved back by pushing the handle, the trigger can always return to the locked position due to the spreading spring that loads it. In this, the pin provided with an annular groove is supported on a locking edge, which is formed by two merging cutouts of different widths in the faceplate. In addition to a latching force, it is therefore also necessary to overcome the restoring force of the spreading spring in order to bring the energy accumulator into effect. In terms of function, it is favorable to design the drive rod, which acts as a spreading spring, in a U-shape and by means of two spacers on the To guide the faceplate. To achieve a favorable spring effect, the distance between the spacers on the faceplate is approximately 50 times the stroke of the trigger.

In addition, there are advantages with regard to the design of the espagnolette lock itself. The components holding the nut in its basic central position can be accommodated in a spatially advantageous manner. These can be assembled together with the nut as an external assembly unit in order to then install them in the lock housing combined with low manufacturing costs of the drive rod lock. This assembly unit also allows espagnolette locks to be manufactured with a small or extended backset. By means of the compression spring, the actuating arm, the slide and the auxiliary slide are held together to form a structural unit via the coupling pin such that the claw-shaped end of the actuating arm is clamped between the end face of the slide and the coupling pin. If the actuating arm is swiveled in one direction, the auxiliary slide is carried along against the force of the compression spring via the coupling pin. A displacement of the actuating arm in the other direction, on the other hand, leads to an immediate action on the slide by the claw-shaped end, together with a compression of the compression spring from the other side. This means that the actuating arm is either under tension or pressure. The claw-like grip under the coupling pin also leads to advantages in terms of assembly. The connection of the auxiliary slide, slide and actuating arm with a compression spring to one unit is favored by the mandrel emanating from the auxiliary slide, which engages both the compression spring and the slide in a space-saving manner and with its bow-shaped towards the end of the pin. Characterized in that the slide receives a portion of the compression spring, this is stabilized against buckling. It is then also protected within the corresponding structural unit. So that the coupling pin does not move with the one displacement of the actuating arm, it finds a stop at one end of the arcuately shaped slot of the lock housing. Then the claw-shaped end presses on the slide and moves it against the force of the compression spring. If the pivoting movement of the actuating arm takes place in the other direction, a slide displacement is blocked by the counter-stop edge opposite the stop edge of the slot. If the actuating arm is designed with two arms, one arm forms the claw-shaped end and the second arm forms the lever on which the chain link coupled with the nut engages. From the above it can be seen that the prefabricated assembly unit can largely be adapted to the structural conditions such that this assembly unit can be arranged in the lock housing at any angle. Furthermore, the adjustability of the mandrel length brings advantages in terms of assembly. Along with an adjustment of the mandrel length, the preload of the compression spring changes at the same time. The mandrel length can be adjusted, for example, by adjusting the thread. The end of the mandrel engaging the auxiliary slide is then provided with an external thread and the auxiliary slide with an internal thread. After assembling the coupling pin of the actuating arm, slide and lining up the compression spring, only the auxiliary slide need then be screwed on, which allows the compression spring to be set to the appropriate tension in a simple manner.

• Fig. 1 eine Ansicht des Treibstangenschlosses bei geöffneter Tür, aufgeladenem Kraftspeicher und in die Stulpschienen-Abschnitte eingefahrenen Schließgliedern,
• Fig. 2 die klappfigürliche Ansicht der Fig. 1,
• Fig. 3 eine Detaildarstellung des Treibstangenschlos­ses bei abgenommener Schloßdecke mit Blick auf das Schloßeingerichte in der der geöffneten Tür entsprechenden Stellung,
• Fig. 4 in herausvergrößerter Darstellung die die Nuß in ihrer Grund-Mittelstellung haltende Bauein­heit entsprechend der Offenstellung,
• Fig. 5 eine Seitenansicht der Stulpschienen-Abschnit­te im Bereich des Auslösers und des Kraftspei­chers entsprechend der geöffneten Tür, also bei aufgeladenem und gesichertem Kraftspeicher mit angedeutetem Schließblech,
• Fig. 6 eine klappfigürliche Ansicht hierzu,
• Fig. 7 eine Ansicht auf die Auslöseeinrichtung und den Kraftspeicher bei fortgelassenen Stulp­schienen-Abschnitten,
• Fig. 8 eine Ansicht des unteren Stulpschienen-Ab­schnittes im Bereich des als Schwenkriegel gestalteten Schließgliedes entsprechend der Freigabestellung desselben,
• Fig. 9 die klappfigürliche Ansicht hierzu,
• Fig. 10 eine der Fig. 3 entsprechende Darstellung, wobei die Tür in die Schließstellung gebracht worden ist bei verlagerten Treibstangen,
• Fig. 11 eine der Fig. 5 entsprechende Darstellung, jedoch bei entladenem Kraftspeicher,
• Fig. 12 die der Fig. 6 entsprechende Darstellung, jedoch bei verlagertem Auslöser,
• Fig. 13 eine der Fig. 7 entsprechende Darstellung, jedoch bei verlagertem Auslöser,
• Fig. 14 das Schließglied in seiner Verriegelungsstel­lung,
• Fig. 15 die zugehörige Seitenansicht,
• Fig. 16 das Treibstangenschloß im nußseitigen Bereich während des Zurückziehens der Falle und Aufla­dens des Kraftspeichers bei gleichzeitiger Aufwärtsverlagerung des Hilfsschiebers,
• Fig. 17 einen Ausschnitt des Treibstangenschlosses im Bereich der Nuß, welche entgegen Uhrzeigerrich­tung geschwenkt ist unter gleichzeitiger Verla­gerung der Treibstangen und der von diesen gesteuerten Schließglieder in die Verriege­lungsstellung,
• Fig. 18 den Schnitt nach der Linie XVIII-XVIII in Fig. 3,
• Fig. 19 den Schnitt nach der Linie XIX-XIX in Fig. 16,
• Fig. 20 den Schnitt nach der Linie XX-XX in Fig. 17,
• Fig. 21 eine mit einem Treibstangenschloß versehene Schiebetüre in Ansicht,
• Fig. 22 teils in Ansicht, teils im Längsschnitt das der Schiebetür zugeordnete Treibstangenschloß,
• Fig. 23 ein Querschnitt durch das Beschlagschild, wobei die Schnittlinie oberhalb des Schiebers verläuft,
• Fig. 24 in Grundrißdarstellung ein rahmenseitiges Schließblech,
• Fig. 25 teils in Ansicht, teils im Längsschlitz das Treibstangenschloß im Bereich des Schließwer­kes entsprechend der verriegelten Stellung der Treibstange,
• Fig. 26 eine Ansicht der Stulpschiene im Bereich eines Verriegelungszapfens,
• Fig. 27 teils in Ansicht, teils im Längsschlitz das Treibstangenschloß gemäß einer weiteren Ausfüh­rungsform,
• Fig. 28 eie Draufsicht auf den dem innenseitigen Beschlagschild zugeordneten Griff,
• Fig. 29 die dem Ausführungsbeispiels gemäß Fig. 27 zugeordnete Rasteinrichtung mit Kraftspeicher und
• Fig. 30 die klappfigürliche Darstellung der Fig. 29.

The invention is explained further below with reference to the accompanying drawing, which represents an exemplary embodiment. Here shows

• 1 is a view of the espagnolette lock when the door is open, the energy accumulator is loaded and the locking members are retracted into the faceplate sections.
• FIG. 2 shows the foldable view of FIG. 1,
• 3 is a detailed view of the espagnolette lock with the lock cover removed with a view of the lock mechanism in the position corresponding to the open door,
• 4 shows an enlarged representation of the structural unit holding the nut in its basic central position in accordance with the open position,
• 5 is a side view of the faceplate sections in the area of the trigger and the energy accumulator corresponding to the opened door, that is to say when the energy accumulator is loaded and secured with the striking plate indicated,
• 6 is a foldable view of this,
• 7 is a view of the release device and the energy accumulator with the faceplate sections omitted,
• Fig. 8 is a view of the lower faceplate section in the area of as a pivot bolt designed locking element according to the release position thereof,
• 9 is the foldable view of this,
• 10 shows a representation corresponding to FIG. 3, the door being brought into the closed position when the drive rods are displaced,
• 11 shows a representation corresponding to FIG. 5, but with the energy accumulator unloaded,
• 12 shows the representation corresponding to FIG. 6, but with the trigger shifted,
• 13 shows a representation corresponding to FIG. 7, but with the trigger shifted,
• 14 the closing member in its locking position,
• 15 the associated side view,
• 16 shows the espagnolette lock in the area on the nut side during the retraction of the latch and charging of the energy accumulator with simultaneous upward displacement of the auxiliary slide,
• 17 shows a section of the espagnolette lock in the area of the nut, which is pivoted counterclockwise with simultaneous displacement of the espagnolette and the locking members controlled by them into the locking position,
• 18 shows the section along the line XVIII-XVIII in Fig. 3,
• 19 shows the section along the line XIX-XIX in FIG. 16,
• 20 shows the section along the line XX-XX in Fig. 17,
• 21 is a view of a sliding door provided with an espagnolette lock,
• 22 partly in view, partly in longitudinal section, the connecting rod lock assigned to the sliding door,
• 23 shows a cross section through the fitting label, the cutting line running above the slide,
• 24 is a plan view of a striking plate on the frame side,
• 25 partly in view, partly in the longitudinal slot, the espagnolette lock in the area of the locking mechanism corresponding to the locked position of the espagnolette,
• 26 is a view of the faceplate in the area of a locking pin,
• 27 partly in view, partly in the longitudinal slot, the espagnolette lock according to a further embodiment,
• 28 is a plan view of the handle assigned to the inside fitting label,
• FIG. 29 shows the latching device with energy accumulator and assigned to the exemplary embodiment according to FIG. 27
• 30 shows the fold-out representation of FIG. 29.

The espagnolette lock has a faceplate 1 on which a lock base 2 is fixed in a rectangular arrangement. In a parallel arrangement to this extends a lock cover 4 tied by means of screws 3, which screws engage in stud bolts 5 on the lock bottom. The aforementioned faceplate 1 continues beyond the lock housing in freely projecting faceplate sections 1 '.

In the upper area of the lock housing, a nut 6 is mounted in the lock base 2 and lock cover 4 for receiving a handle 7 indicated by dash-dotted lines in FIG. 1. If it takes its horizontal position I, this corresponds to the basic middle position. The position indicated by line II is the one in which the nut 6 withdraws a trap 8. The latter is composed of a trap head 8 'and a trap tail 8'. The case head 8 'leads in the faceplate 1, while the case tail 8˝ is guided on the castle floor side. On the trap tail 8˝ attacks a leg spring 9, which loads the trap 8 in the outward direction. The application of the trap tail 8˝ is carried out by a nut arm 10 of the nut 6. In addition, the nut 6 is equipped with a starting from the nut arm 10 rotation limit stop 11, which cooperates with stop edges 12, 13 of an arcuate opening 14 of the lock cover 4, so that the Lever positions II and III experience a limit stop. The trigger positions II and III close between themselves An angle of about 90 ° so that the handle can be pivoted 45 ° in both directions from its horizontal position I.

Another arm 15 extends from the nut 6 in a right-angled arrangement to the latch actuating arm 10. There, a link plate 17 engages by means of an articulated pin 16, which in turn is coupled to the second arm 19 of an actuating arm 20 via an articulated axis 18. The latter is mounted below the nut 6 around a pivot pin 21 on the lock housing side. The first arm 22 opposite the second arm 19 forms a claw-shaped end 23 which engages under a coupling pin 25 guided into an arcuate slot 24 of the lock base 2 and lock cover 4. At the level of the claw-shaped end 23, the coupling pin 25 is surrounded by a bracket 26, which continues in a downward, approximately parallel to the faceplate 1 mandrel 27. At the end, the latter forms a threaded section 28. This engages in an internal thread of a peg-shaped centering projection 29 of an auxiliary slide 30. A guide projection 31 extending from this protrudes into an approximately vertically extending longitudinal slot 32 of the lock base 2. Opposite to the guide projection 31 there is a groove 33 on the auxiliary slide 30, into which a rib 34 of the lock cover 4 pressed in is immersed. This rib 34 extends parallel to the alignment of the longitudinal slot 32, as a result of which the auxiliary slide 30 receives an exact guidance.

The upper end of the longitudinal slot 32 forms a counter stop edge 35, which is opposite the stop edge 36 of the arcuate slot 24 at a distance. Against this stop edge 36, the coupling pin 25 is loaded by the auxiliary slide 30 in the downward direction the compression spring 37 is pulled, the latter surrounding the centering projection 29 and thus also receiving the mandrel 27.

The mandrel 27 passes through a slide 38. At its upper end, this forms a projection 39 which projects into the longitudinal slot 32. The lower end of the slider 38 facing the lock cover 4 is also provided with a groove 40 into which the rib 34 is immersed. The slider 38 receives only a portion of the compression spring 27 and has a support surface 41 at the level of the projection 39 for the facing end of the compression spring 37. As a result of this configuration, the claw-shaped end 23 of the actuating arm 22 becomes between the upper end face 42 of the slider 38 and the coupling pin 25 clamped so that the actuating arm 20, mandrel 27, auxiliary slide 30, compression spring 37 and slide 38 form a coherent structural unit which can be used as a whole in the lock. If necessary, this joint unit can also include the link plate 17 and the nut 6, so that a coherent, easy-to-assemble chain is obtained. This configuration allows the cohesive structural unit to be arranged in different orientations within the lock housing of an espagnolette lock. Only the guide slots are to be provided in the appropriate position.

Another component of the espagnolette lock is a bolt 43 which is arranged below the above-described structural unit and which is associated with a tumbler 44 which is sprung in the downward direction. The bolt 43 passes through a lower drive rod 45 of the drive rod lock. This drive rod 45 runs inside the faceplate 1 and the lower faceplate section 1 'and is at the level of the actuating arm 20 with a rack section 46 provided. Following this, the drive rod 45 is in positive connection with a drive rod connection piece 47 which can be displaced parallel to the faceplate 1 and from which an upper drive rod 48 extends.

A two-arm toothed segment 51, which is also rotatably mounted on the pivot pin 21, is used to displace the drive rods 45, 48. One arm forms a toothing 52 which is in engagement with the toothed strip section 46. Both arms of the toothed segment 51 are diametrically opposed Arch slots 53, 54 provided. The hinge axis 18 is immersed in the arch slot 53 between the link plate 17 and the second arm 19. When the espagnolette lock is in the open position, that is to say when the door is open, the hinge axis 18 extends at the upper end of the arch slot 53. The other arch slot 54, on the other hand, is penetrated by the coupling pin 25, which is located in this position at the lower end of the arch slot 54. Accordingly, an idle stroke between the actuating arm 20 and toothed segment 51 is created.

On the back of the lower faceplate section 1 'is designed as a compression spring energy store 55 is provided. The energy accumulator extends in a receiving chamber 56, which is formed by oppositely directed bends 57 and 58 of the lower faceplate section 1 'and the lower drive rod 45. To support the energy storage compression spring 55 is used on the one hand on the faceplate section 1 'riveted projection 59. On the other hand, an abutment 60 is attached to the drive rod 45 opposite to the projection 59. If the drive rod 45 moves in the upward direction, so the energy store 55 is charged via the abutment 60.

To secure the charged position of the energy accumulator 55 is used above the lock housing in the upper faceplate section 1 'arranged locking device 61. The latter has a trigger 63 which is formed with a locking edge 71. The trigger is a pin 65 firmly connected to the spreading spring 62 with an annular groove 66 and a wide head 64. The locking edge 71 is formed by the two recesses 69 and 70 of the face edge 1 '. The pin 65 is designed so that its diameter is smaller than the width of the recess 69 and larger than the slot 70 and that the diameter of the annular groove is smaller than the width of the slot 70. As illustrated in particular in FIG. 5, the drive rod 48 is designed as a spreading spring 62, wherein it is slidably mounted on the faceplate in the relaxed state of two spacers 67, 68, it having an upper bend 72 and a lower bend 73. In the locked position of the trigger 63, when the energy accumulator 55 is charged and the expanding spreading spring 62 is relaxed, the pin 65 is located in the recess 69 and is held in this position by the locking edge 71 and thus prevents the energy accumulator from being discharged. Movement of the drive rods 45, 48 in the downward direction is therefore not possible. The locking device consequently remains in the open position of the door in the position illustrated in FIG. 3.

Beyond the trigger 63 and energy storage 55 'additional closing members 76 are provided in the area of the faceplate sections 1'. In the exemplary embodiment, these are designed as swivel bolts. When ver When the espagnolette lock on a sliding door is used, these locking elements criss-cross behind the firing plate through special openings. The control of the swivel bar 76 is done both by the upper and by the lower drive rod 45, 48. For the sake of simplicity, only the control of the lower swivel bar 76 by the lower drive rod 45 is explained. The lower drive rod 45 carries a driver 77, which has a central recess 78. The latter is elongated in such a way that the narrow edges 79, 79 'to the faceplate section 1' diverge. In the upper area of the recess 78, a journal 80 is provided for the one-armed swivel bolt 76. The pivot bolt 76 is pivoted into the loading position of the energy store 55. His roof-shaped engagement end 81 then extends within an outlet opening 82 of the faceplate section 1 '. The transverse edges 83 and 84 of the outlet opening 82 form control surfaces for the pivot bolt 76, which has corresponding counter-control surfaces 85, 86. In the open position of the pivot bolt 76, the counter control surface 86 is supported on the narrow edge 79 '.

The operating principle of the espagnolette lock is as follows:

If a door equipped with the espagnolette lock according to the invention is in its open position, the espagnolette lock assumes the position according to FIGS. 3, 5 and 8. The energy store 55 is tensioned, but is prevented from being discharged by the latching device 61. The drive rods 45, 48 cannot shift and the swivel bolts 76 extend.

When the door is closed or the door is closed, the trigger 63 is released from the striking plate on the door frame side 88 or the run-up slope 89 and displaced against a certain locking force and the restoring force of the spreading spring 62. Here, the pin 65 loses its support on the locking edge 71, so that the energy store 55 can take effect and discharge connected with a downward displacement of the drive rods 45, 48, the annular groove 66 of the pin 65 engaging in the slot 70. The espagnolette lock then assumes the position shown in FIG. 10, while the latching device 61 and the energy accumulator 55 move into the position shown in FIG. 11. Along with a downward displacement of the drive rods 45, 48, the swivel bolts 76 are also displaced by the drivers 77. The counter-control surface 86 acts on the transverse edge 84 of the outlet opening 82 and thereby forces a swiveling displacement of the swivel member 76. It is therefore ensured after closing the door that both the latch 8 and the locking members 76 are in the engaged position with the striker plate 88 on the door frame or in the closing engagement openings have occurred there. This counteracts warping of the door. In this position it is then possible to pre-close the bolt 43 by means of a locking cylinder.

If one or both locking members 76 could not dip into their engagement openings when the door was closed, this also blocks the displacement of the drive rods 45, 48. However, there is then the possibility of supporting the energy accumulator in that the lever 7 is shifted counterclockwise into the position according to III with the entrainment of the connecting rods, with the exclusion of the swivel bolts, which with their roof-shaped engagement end into the associated engagement opening of the striking plate 88 occur. During this swivel movement, the Nut 6 with the parts coupled to it in the position shown in FIG. 17. Via the link plate 17 and actuating arm 20, the toothed segment 51 is immediately carried along, which displaces the drive rod 45 and, via the drive rod connector, the other drive rod 48 in the downward direction. This pivoting movement is limited by the stop edge 13 of the lock cover 4, against which the rotation limit stop 11 of the nut 6 abuts. By pivoting the actuating arm 20, its claw-shaped end 23 acts on the end face 42 of the slide 38, which moves in the downward direction against the force of the compression spring 37, see also FIG. 20. The coupling pin 25, on which the mandrel 27 and thus the auxiliary slide Support 30 remain in their position. If the pusher 7 is then released, the slide 38 returns spring-loaded to its starting position by pivoting the actuating arm 20 which, via the chain link 17, returns the nut 6 and thus the pusher 7 to the basic central position. Due to the arch slots 53, 54, the toothed segment 51 remains, so that the hinge axis 18 and the coupling pin 25 are then adjacent to the opposite ends of the arch slots 53, 54.

Opening the door, when the latch 43 has been closed, requires the same to be closed. Subsequently, the handle 7 is to be moved into the position II, the lock mechanism moving into the position according to FIGS. 16 and 19. The latch 8 is withdrawn by means of the nut 6. Furthermore, the link plate 17 pivots the actuating arm 20, as a result of which the auxiliary slide 30 moves in the upward direction against the force of the compression spring 37 via the mandrel 27. The slide 38 is in turn supported on the counter stop edge 35 of the longitudinal slot 32, see also FIG. 19. During this process The tooth segment 51 is also taken along. It remains in its end position. The arc slots 53, 54 then allow the actuating arm 20 and the nut 6 to pivot back into the starting position according to FIG. 3 under the action of the compression spring 37. The pivoting toothed segment 51 has displaced the drive rods 45, 48. The energy accumulator 55 is charged while the trigger 63 is lifted by the upward movement of the drive rod 48 over the locking edge 71 and engages in its locking position due to the spring loading by the spreading spring 62. With the displacement of the drive rods 45, 48, the locking members 76 were pivoted into their release position in the interaction of the transverse edge 83 and counter-control surface 85. The next closing process can then take place.

From the position shown in FIG. 3, the nut can be withdrawn at any time by moving the handle clockwise. In this process, the slide 38 is moved against the force of the compression spring 37 via the actuating arm 20. Due to the idle stroke, the toothed segment 51 is not taken along. The compression spring 37 then brings the aforementioned components back into their basic position. When the door is closed in this way, the latch 8 is not displaced by the striking plate on the frame. In this way, the door can be closed with low noise, the triggering and release of the energy accumulator 55 again taking place in the closing end phase and associated with an exit of the closing members 76.

The auxiliary slide 30 which can be screwed onto the threaded section 28 of the mandrel 27 also allows the mandrel length to be adjusted and thus a corresponding adjustment of the prestressing force of the compression spring 37.

21-30 show two further embodiments.

In both embodiments, the espagnolette lock is associated with a sliding door 101. This has a cross-sectional profile frame 102, which is filled by a glass pane 103.

The left, vertically running frame leg 104 carries a fitting plate 105 on the outside of the door and a fitting plate 106 on the inside of the door in flush opposite position. Both are almost identical in their construction. At the rear, each fitting plate is provided with a free space 107. Each fitting plate 105, 106 is a carrier of a U-shaped handle 108. The front ends of the U-legs 109 lie at the level of the longitudinal center line of the fitting plate 105, 106. The fixing screws 110, screwed in from the rear of the fitting plate serve to fix the handle 108. push through the corresponding openings in the fitting plate and engage in threaded holes in the U-leg 109. The screw heads of the fastening screws 110 then lie in the free space 107. The fixing of the handle 108 is such that the upper U-leg 109 is adjacent to the upper transverse edge of the fitting plate 105, 106.

Both fitting plates 105, 106 are connected by means of coupling screws 111, which start from the inside fitting plate and engage in threaded holes (not shown) of the outer fitting plate 105 in such a way that an opening by unscrewing the outer fitting plate cannot take place from outside without authorization.

Below the lower U-leg 109, a push-through opening 112 extends in the fitting plate 105, 106 for installing a locking cylinder 113. At the same time, the locking cylinder 113 extends through a locking mechanism 114. This is carried by a faceplate 116 lying in a frame groove 115 of the sliding door 101, behind which a drive rod 117 runs. The drive rod 117 extends through the locking mechanism 114 and is provided with a window, not shown, into which, in the locked position of the driving rod 117, a bolt 118 of the locking mechanism 114, which is not shown in detail, is immersed. The locking cylinder 113 is used to control the bolt 118 in such a way that the bolt 118 can only be displaced after a tumbler has been lifted.

An energy accumulator, as described above, is provided on the rear side of the lower faceplate section. The locking device also described above serves to secure the charged position of the energy accumulator.

Above the locking mechanism 114, the drive rod 117 carries a coupling lug 142 with a central, offset coupling lug 143. This has a rectangular cross section and engages non-rotatably in an opening 144 of an arm 145 that completely crosses the frame profile. The arm 145 is designed as a tab which is flat in the displacement plane of the drive rod 117 in such a way that it is enlarged in area in the area of the opening 144, from which stepped sections 146 start. Guided sliders 147 act on these in both fitting plates 105, 106. These are guided parallel to the drive rod displacement direction in the fitting plate and represent the handle for moving the drive rod 117.

Each slide 147 is guided in the area between the two legs 109 of the U-shaped handle 108. A slot guide is used for this. The corresponding slot 148 extends on the connecting line of the U-leg attachment points. From the rectangular shaped base plate 149 of the slide 147 lying on the outside of the shield, a stepped area 150 extends toward the shield, the width of which is adapted to that of the slot 148. However, its length is less than that of the slot 148 in order to be able to displace the slide 147 or handle. The area 150 in turn continues into a step-like shoulder 151. In this there is an insertion opening 152 for the respective free end section 146 of the arm 145. The extension 151 is encompassed by a frame 153 which rests on the bottom surface of the free space 107 and which is connected to the part of the slide on the outside of the shield by means of screws 154. To reduce the friction between fitting plate 105, 106 and base plate 149 and frame 153, slide plates 155 and 156 are provided.

Each slider 147 has a protruding actuating projection 157 lying in the plane of the U-legs 109. In order that this does not protrude into the surrounding space of the handle bar, the U-legs 109 are bent over to one longitudinal edge of the shield, cf. in particular Fig. 5.

The following mode of action results:

If the sliding door 101 equipped with the espagnolette lock according to the invention is in its closed position, the locking pins 139 engage positively in the correspondingly designed frame side towards striking plates 141. The locking position of the drive rod 117 is secured by the bolt 118 of the locking mechanism 114. The opening of the sliding door first requires an actuation of the locking cylinder in order to disengage the bolt 118. Thereafter, if the door outside is to be opened from the outside of the door, the slide 147 on the outside of the door is to be displaced in the upward direction. This is preferably done by the index finger engaging the actuating projection 157 while the thumb of the actuating hand is supported on the upper U-leg 109. Along with the upward displacement of the slide 147, the arm 145 is taken along, which in turn entrains the coupling plate 142 and thus the drive rod 117 in the outward direction. During this movement, the energy accumulator is charged and the trigger is lifted over the locking edge, where it engages. The locking pins also come into such a position with respect to the striking plate that the subsequent opening of the sliding door is made possible.

According to the second embodiment, shown in FIGS. 24 to 30, the same components have the same reference numbers. In this version too, the espagnolette lock is assigned to a sliding door 101. However, it would also be possible to design the connecting rod fitting so that it is suitable for a swing door.

From FIG. 24 it can be seen that the locking mechanism 114 has been inserted with its bolt 118 into a window 158 of the drive rod 117 and thus blocks the displacement of the drive rod 117.

As in the previous exemplary embodiment, a door plate 159 and 160 on the outside of the door and on the inside of the door are provided with a lock cylinder through insertion opening 112 in the lower area of the fitting plate. Each fitting plate 159, 160 has a slot 148 for guiding an area 150 stepped away from the base plate 149. The latter also continues into an extension 151, which is surrounded by a frame 153. Both frame 153 and base plate 149 are made of plastic, so that additional sliding plates can be dispensed with. The insertion opening 152 is connected to the end section 146 of the arm 145, which is connected in the same way to the drive rod 117 via a coupling bracket 142.

The slide 147 'is different from the first embodiment with a U-leg 109' penetrating and guided in this push-button shaft 161. Both U-legs 109 'of the U-shaped handle 108' arranged on the fitting plate 159, 160 have a guide opening 162 for the push-button stem 161.

Fig. 28 illustrates that the U-legs 109 'beyond the guide opening 162 to one longitudinal side edge 163 of the fitting plate 159, 160 are bent.

Furthermore, it is apparent in particular from FIGS. 27 and 28 that there is a distance x of the push-button shaft 161 perpendicular to the shield surface 161 to the base plate 149 of the slide 147 '. As further illustrated in FIG. 27, the pushbutton stem 161 projects beyond the free end of the base plate 149 of the slide 147 '.

In this version too, an energy accumulator 164 in the form of a compression spring is present below the locking mechanism 114. To support the energy storage compression spring 164 serves on the one hand a projection 165 riveted to the faceplate 116. On the other hand, an abutment 166 is fastened to the drive rod 117 opposite the projection 165. In contrast to the first version, the energy accumulator 164 is charged when the drive rod 117 travels in the downward direction.

To secure the charged position of the energy accumulator 164, a locking device 167 arranged above the locking mechanism 114 is used. The same has in the faceplate 116 two consecutive slot sections 168, 169 of different widths such that the upper slot section 168 has a smaller width here. As a result, a locking edge 170 is formed at the transition point between the two slot sections 168, 169. A pin with a truncated cone-shaped head K serves as the trigger member 171. It protrudes over the faceplate. The base diameter corresponds approximately to the width of the slot section 169. The head is followed by a pin section 172, the diameter of which is slightly smaller than the width of the slot section 168. This pin section 172 continues into a pin section 173 on the surface facing the faceplate the drive rod 117 abuts and its diameter corresponds to the width of the slot section 169. The drive rod 117 forms a spreading spring 174 with the area carrying the trigger member 171. Viewed in the longitudinal direction, there is a U-shape of this spreading spring 174. Two spacers 175 and 176 serve to guide the drive rod and the spreading spring 174 in the corresponding region thereof.

In the charged position of the energy accumulator 164, which corresponds to the open position of the sliding door, by The pin section 173 grips the slot section 169 and is supported on the locking edges 170, see FIG. 30. The energy accumulator 164 cannot accordingly relax. In this position there is an extended orientation of the spreading spring 174, see FIG. 29.

The unloaded position of the energy accumulator 164 is that which is present when the sliding door is closed. In this position, the spreading spring 174 is bent due to a previous application, and the pin section 173 is supported on both sides of the slot section 168 of the faceplate 116. Furthermore, the locking pin 139 engage in the narrower slot portion 177 'of the striking plate 177 in such a way that the collar 140 engages behind the striking plate 177 and accordingly ties the door to the frame. To block a displacement of the drive rod 117, the latch 118 can be locked into the position according to FIG. 25. The opening of the sliding door requires the bolt 118 to be closed. Then the pushbutton shaft 161 of the slide 147 guided in the fitting plate 159 ', if the opening is to take place from the outside of the door, is to be acted upon in the downward direction combined with entrainment of the arm 145 and the drive rod 117. During this movement, the locking pins 139 with their collar 140 enter the wider slot section 177˝ of the striking plate 177. At the same time, the energy accumulator 164 is charged by the downward displacement of the drive rod 117. At the same time, the trigger member 171 is taken along. As soon as the pin section 173 reaches the wider slot section 169, the spreading spring 174 can move back with the trigger member 171 being advanced, so that the pin section 173 is then supported on the locking edges 170. This is also the end secured position of the energy accumulator 164. It is then possible to open the sliding door.

If the sliding door is pushed closed when the energy accumulator 164 is charged, a frame-side stop acts on the head K of the release member 171 in the sliding end phase, so that the pin portion 173 moves away from the locking edges 170 while the spreading spring 174 is bent. The energy accumulator 164 can then take effect, which moves the drive rod 117 in the upward direction, along with the production of the rear grip between the locking pins 139 and the frame-side striking plates 177. Via the coupling plate 142 and arm 145, the sliders 147 are also carried, the push-button shafts 161 of which protrude above the U-leg 109 and accordingly indicate that the energy accumulator 164 is discharged.

All the new features mentioned in the description and shown in the drawings are essential to the invention, even if they are not expressly claimed in the claims.

ADDITIONAL SHEET

The disclosure content of the associated / enclosed priority documents is hereby included in full in the disclosure of the application.

Claims (13)

1. Espagnolette lock with by turning the handle or the like displaceable connecting rods and a handle assigned to the handle, which, held in its basic central position, can be pivoted out of this against spring loading in opposite directions, the lock case carrying a faceplate that extends beyond the lock case continues in freely protruding faceplate sections, behind which the drive rods are guided, the additional closing elements arranged in the area of the faceplate sections, for. B. swivel latches, control such that these locking members can be retracted into the frame-side counter-locking parts both by turning the handle and after releasing at least one force rod loading the drive rods, the release of the force accumulator being achieved by means of a trigger actuated when the door is closed by the frame or the like , wherein the trigger (63) and / or the energy store (55) on the back of the free projecting faceplate sections (1 ') are arranged, characterized in that the trigger can be actuated in the direction perpendicular to the faceplate front. 2. espagnolette lock, in particular according to claim 1, characterized in that the trigger against the force, the spring rod that spreads apart from the faceplate back, is movable from the holding position into the release position. 3. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the trigger as a pin (65) with a wide head (64), the diameter of which is smaller than the width of the Recess (69) and larger than the width of the slot (70) is designed with an annular groove, the groove diameter of which is smaller than the width of the slot (70). 4. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the trigger is held by a locking edge (71) in the holding position. 5. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the spreader rod acting as a spreading spring (62) contains bends (72, 73) and is slidably fastened by means of spacers on the faceplate, the distance of the spacers being about 50 -fold the stroke of the trigger. 6. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the head of the trigger is designed as a truncated cone. 7. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the striking plate has a run-up slope which is assigned to the trigger. 8. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the part of the drive rod acting as a spreading spring rests in the holding position on the faceplate. 9. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the faceplate sections (1 ') and / or the espagnolette (45, 48) form bends (57, 58) in which the energy accumulator 55 designed as a compression spring ). 10. Espagnolette lock, in particular according to one or more of the preceding claims, characterized by a coupling pin (25) braced by means of a compression spring (37) against the actuating arm (20) between the actuating arm and an auxiliary slide (30) crossing the slide (38), which coupling pin (25) clamps the claw-shaped end (23) of the actuating arm (20) against the end face (42) of the slide (38), the compression spring (37) sitting on a mandrel (27) of the auxiliary slide (30), which mandrel (27 ) runs through the interior of the slide (38) and engages over the pin (25) in a bow-shaped manner. 11. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the slide (38) receives a portion of the compression spring (37) and the coupling pin (25) in the direction of the slide (38) stop limited in a slot (24) of the lock housing is guided, the stop edge (36) of the slot (24) opposite a counter stop edge (35) which is assigned to the slide (38). 12. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the actuating arm (20) is designed with two arms and the second arm (19) via a chain link (17) with the nut (6) is coupled. 13. espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the compression spring (37) is adjustable by adjusting the length of the mandrel.

Images