EP0411271B1 - Lock for driving rod with an accessory lock which is controlled by a central lock - Google Patents

Abstract

The invention relates to an espagnolette lock with an accessory lock (1) which is controlled by a central lock and which has a bolt (22) coming into hook-shaped engagement with the lock plate. In order, when the bolt is closed, effectively to absorb push-back forces exerted on this in the pre-closed position, a slotted control of the bolt (22) breaking the path of movement of the bolt (22) down into different portions is provided, in such a way that, during locking, a control pin of the bolt is first guided in a slot guided diagonally to the direction of movement of the espagnolette, to ensure that the hook engages behind the lock plate, and thereafter penetrates into a slot portion arranged parallel to the direction of movement of the espagnolette. <IMAGE>

Description

The invention relates to an espagnolette lock with an additional lock controlled by a central lock according to the preamble of claim 1.

Such espagnolette lock is known from DE-OS 27 32 471, the hook-shaped engagement being achieved in that the bolt of the additional lock pivots about a fixed pin of the lock case. To move the bolt head, which runs concentrically to the bolt pivot point, a drive rod extending from the central lock is used, the pin of which engages in a slot of the bolt of the additional lock extending transversely to the direction of displacement thereof. With this design, however, there is no blocking of the pre-locked bolt against turning back. Rather, corresponding push-back forces loading the bolt must be absorbed by the central lock.

The object of the invention is based on the object of designing a drive rod lock of the type in question from a manufacturing technology simple construction in such a way that, in addition to a favorable movement sequence of the bolt when closing, the pushing forces acting on it in the locked position are effectively absorbed.

This object is achieved by the invention specified in claims 1 and 21.

The subclaims represent advantageous developments of the inventive solution.

As a result of such an embodiment, a generic drive rod lock is created which, in addition to a structure which is advantageous in terms of locking technology, is distinguished by an increased security value. If the bolt is to be brought into its locking position, the drive rod is moved across the link control assigned to the bolt and the bolt is extended transversely to the faceplate longitudinal direction. During this bolt movement, the bolt passes through the associated entry opening of the striking plate. After the bolt head has entered the locking engagement opening of the striking plate, the movement of the bolt directed transversely to the extension displacement is associated with the fact that its locking head engages in hooking engagement with the locking engagement opening of the striking plate. This ensures that the hook engagement is achieved with certainty. If the bolt is in this composite engagement generated in this way, push-back forces acting on the bolt head are unable to move the bolt into the release position while increasing the locking security of the drive rod lock. The release position must be brought about by the will, namely by moving the drive rod, caused by the central lock. A variant according to the invention is characterized in that the bolt, when excluded by the link control, essentially moves on a linear path at an obtuse angle to the drive rod. This direction is opposite to the hook engagement. Superimposed with this linear movement there is still a pivoting of the bolt head opposite to the hook engagement. This means that when locking, the locking head first steps over the cuff and the locking head engages in the locking engagement opening. Only when this has been done is the locking bar pivoted by further drive rod displacement via the link control to achieve the hook behind the locking head on the striking plate. So that despite this control of the bolt and the required free space of the bolt head in the bolt passage opening of the bolt receives additional support, a base is provided on the front surface of the bolt which fills the bolt passage opening of the faceplate in the locked position. The base only engages in the bolt passage opening in the closing end phase. In a technically simple manner, the link control is formed by a slot / pin engagement. As long as the pin is in the slot section parallel to the drive rod displacement during the initial phase of the exclusion, there is no change in the position of the bolt. Only when the pin engages in the slot section directed at the cuff at an acute angle does the essentially linear exclusion of the bolt take place at an obtuse angle to the drive rod movement, combined with the small pivoting of the bolt head mentioned at the beginning. If the pin has passed through the slit section which is directed at an acute angle to the cuff, it can engage in a slit section which is also parallel to the drive rod movement, locking the locked position of the bolt. The push-back forces acting on the bolt are therefore effectively absorbed by this slot section. Before the peg sitting on the bolt has completely passed through the slit section directed towards the cuff, the pivoting movement of the bolt occurs. This results from a superposition of its displacement in the area to the slotted section at an acute angle and an abutment on a stop surface on the back of the cuff at a lever arm distance from the slot control point. The corresponding control of the bolt can be done by exclusive slot control. However, the structure of the link control is simplified if the bolt is spring-loaded in the exclusion direction. This ensures that the bolt moves on a correct path despite only a single slot slot during the locking displacement. Manufacturing and assembly advantages result from that the bolt lies in a pocket of a connecting rod connecting piece, the bottom of which has the slot sections. The bolt is therefore also located at a protected location on the guard lock.

However, according to a further embodiment of the invention, it is possible to achieve the hook engagement without swiveling the bolt. For this purpose, a bolt emanates from the bolt tail, which extends through both a link slot of the connecting rod connecting piece guided in the additional lock and also an angular housing-side guide slot thereafter. One angle leg of this guide slot runs at right angles to the cuff, ie in the direction of exclusion, and the other angle leg is directed parallel to the cuff. By shifting the connecting rod, the bolt is initially locked in a straight line through the slot slot. The pin runs through one angle leg. As soon as the pin comes into the angular apex of the angular guide slot, the transversely directed movement of the bolt takes place with the hook behind the handle. The locking of the bolt takes place in the reverse way, firstly lifting the hook behind the hook and secondly closing the bolt. One flank works when the latch is closed and the other flank of the link slot works when the latch is closed. Frictions during the closing process are reduced by a rolling element that can be rotated on the pin and which rolling element runs along the edge of the link slot. The slot slot can be designed so that it forms parallel opposite slot edge. However, there is a version that the slit in the direction of the gauntlet widens towards its upper end and that when the bolt is excluded, a load accumulator that charges and engages the rear is provided. The further the bolt is excluded, the more the energy accumulator is charged. As soon as the pin of the bolt is at the level of the angular apex of the guide slot, the energy accumulator can be discharged, the bolt being moved suddenly in the hook engagement direction. During this process, the pin sitting on the bolt also suddenly enters the angled leg of the angled guide slot, which runs parallel to the cuff. The speed at which the bolt moves in the transverse direction to the cuff is greater than that of the connecting rod connecting piece. As soon as the pin acts on the lower edge of the slot, the energy accumulator still supports the movement of the connecting rod connecting piece. The transverse displacement of the bolt is complete when its pin has completely passed through the angled leg running parallel to the cuff. The widening of the link slot then allows the drive rod connector to be moved even further, creating tolerance compensation if the closing process requires a further path of the drive rod connector. So that the bolt remains in its straight-line to the cuff position during the forward and backward closing, the energy accumulator designed as a compression spring is supported at one end on the connecting rod connecting piece and at the other end on a sliding block that comes against the bolt. The corresponding support surface of the sliding block runs at right angles to the cuff and thus always determines the position of the transom. This system is also maintained when the bolt moves into the hook engagement position. When the bolt is closed, the bolt is initially disengaged from the hook by the lower edge of the slot. The bolt and sliding block as well as the energy accumulator loading them move synchronously. When the bolt on the bolt side has reached the angular apex of the guide slot, the bolt is moved back through the lower edge of the slot edge. This relocation is supported by the partially loaded energy accumulator, which is then discharged during the closing relocation. So that the sliding block remains in its correct position, it carries a guide pin which extends through a transverse wall of the connecting rod connecting piece. This fulfills an additional function in that it also holds the compression spring.

When the bolt is extended in a straight line and the transverse movement of the bolt follows, a free space is created at the bolt passage opening. So that the bolt cannot be shifted back under the influence of constraining forces exerted transversely to its direction of exclusion while removing the hook behind the hook to the frame-side striking plate, the remaining free space is filled by a locking lug in the bolt's closed position. They are only controlled when the door is closed correctly. Constraining forces occurring on the bolt are therefore unable to bring the locking lug into the release position via the bolt. The espagnolette lock is therefore given an increased security value. When the bolt is closed, it in turn fills the entire bolt passage opening, so that when the door is open, the locking lug itself is not visible. The latter is part of a spring-loaded pawl and, when the closed position is reached, occurs together with the spring-loaded pivoting of the pawl into the form-filling position in the free space of the bolt passage opening. In the closed position, the play between the bolt-side pin and the link slot of the connecting rod connecting piece is so great that before reaching the corresponding edge of the slot edge of the bolt, its narrow edge acts on the locking nose of the pawl. Moving the bolt and the corresponding components back can only be done by forward written actuation of the drive rod. For this purpose, the pawl is mounted on the connecting rod connector and spring-loaded in the direction of its locking engagement. The angled end of the pawl forms on its narrow side facing the bolt passage opening edge an actuating flank which takes effect when the connecting rod connecting piece moves back. In the first phase of the closing movement, the pawl consequently pivots out of engagement with the free space of the bolt passage opening. This pivoting is possible because there is the corresponding game between the bolt-side pin and the link slot. The peg / slot mounting of the pawl allows a sudden entry of the locking lug into the free space in the closing end phase. While the bolt is being closed, the locking lug still encompasses a projection lying in its path of movement, which forms the connecting lug of the housing to the faceplate. In order to enable trouble-free driving around the projection, the top surface of the locking lug is also designed as a control flank. Their orientation is such that in the open position it is at an acute angle to the inside faceplate and thus allows the projection to overflow, starting from the open position. In order that the bolt does not leave its correct orientation during the shifting of the lock, a guide slide is carried along by the bolt in its transverse movement. This is in the slot / pin connection with the bolt, the slot of which runs in the direction of the extension displacement of the bolt. The guide slide itself is T-shaped in such a way that the ends of the T-legs lie in the fork pieces of the connecting rod connecting piece. These allow the guide slide to move in the drive rod movement direction. The guide slide, on the other hand, is carried via the slot in the T-bar, in which the bolt on the bolt side is non-rotatably guided. This configuration makes it possible to dispense with a spring-loaded slider.

In a further additional lock according to the invention, the bolt is designed as a pivot bolt which can be pivoted about a pivot axis and which can engage in hook-like engagement with the striking plate. The bolt couples with a control pin in a control slot of a link that can be driven by the drive rod. Due to the diagonal arrangement of the control slot, an arc-shaped locking movement is driven by the linear drive rod movement. Due to the control slot section which runs parallel to the drive rod movement and which adjoins the diagonal control slot at the end, the excluded bolt is blocked against being pushed in when the drive rod is completely displaced. In this configuration, too, the bolt can only be shifted into the additional lock housing by means of a deliberate shifting of the connecting rod. According to a preferred embodiment, the diagonally running slot section has a slot section angled at an obtuse angle to the drive rod movement, the slot section running parallel to the drive rod movement adjoining the angled slot section. The length of this angled slot section, which runs at an obtuse angle to the drive rod movement, is dimensioned such that when the pin passes over when the bolt is moved forwardly into the angled slot section, the tightening slope formed on one side on the bolt head of the bolt fully projects from the faceplate. This embodiment is particularly advantageous in terms of use, since there is therefore a link control of the bolt that can be broken down into different sections, during the first phase of exclusion, in which the control pin is guided in the acute-angled slot section, it is initially only displaced by a small angle. This has the consequence that a relatively large torque can be transmitted with its tightening slope in the striking plate during the immersion of the bolt. On the other hand, only a small torque can be transmitted during the second pre-closing phase, in which the locking pin is guided in the obtuse-angled slot section, but this is advantageously associated with a large angular displacement with the same relative linear rod displacement. In this phase, in which the tightening slope has emerged completely from the cuff, no great torque is required, since in this phase there is no longer any tightening movement, but only the pivot bolt is pivoted completely into the counter-locking part. A further advantageous development is provided by a guide slot running parallel to the drive rod movement in the link, which is penetrated by a pivot pin which forms the pivot axis and is mounted in the lock housing and the length of which corresponds to the drive rod stroke. This makes it possible to adjust the area of the entire lock width in order to achieve optimal guidance. It is further provided, in addition to the guide slot on the side facing away from the faceplate, to extend the end of the control slot by a slot section running parallel to the drive rod movement, in order to lock the locked position of the bolt. A minimum length of the bolt tail is achieved in that the control pin lying in the control slot can be displaced from a position adjacent to the rear wall of the housing, assigned to the locked bolt position, beyond the imaginary extension of the guide slot, to a position adjacent to the faceplate, assigned to the excluded bolt position. A secure guidance of the backdrop in the lock housing is parallel to Driving rod movement extending, embossed in the housing cover guide rib achieved to grip the guide claws of the link for guiding the link on the housing base.

• Fig. 1 eine Ansicht eines von einem nicht dargestellten Zentralschloß gesteuerten Zusatzschlosses, betreffend die erste Ausführungsform,
• Fig. 2 die klappfigürliche Ansicht der Fig. 1,
• Fig. 3 eine Ansicht des Zusatzschlosses bei abgenommener Schloßdecke, die zurückgeschlossene Stellung des Riegels betreffend,
• Fig. 4 eine der Fig. 3 entsprechende Darstellung, jedoch während der ersten Schließphase, wobei sich der schloßrückseitige Schlitzabschnitt relativ zum Zapfen des Riegels verlagert hat,
• Fig. 5 die Folgedarstellung, wobei der Riegel sich auf einer stumpfwinklig zur Treibstangenbewegung gerichteten Bahn verlagert hat unter gleichzeitiger, dem Hakeneingriff entgegengesetzter Schwenkung,
• Fig. 6 die sich durch weitere Treibstangenverlagerung anschließende Stellung, wobei der Riegelkopf in Hakeneingriffsstellung geschwenkt ist und sich der Zapfen des Riegels im Übergangsbereich zwischen dem spitzwinklig verlaufenden Schlitzabschnitt und dem sich daran anfügenden Schlitzabschnitt befindet,
• Fig. 7 die gegen Rückdrücken gesicherte Schlie- ßendstellung,
• Fig. 8 den Schnitt nach der Linie VIII-VIII in Fig. 7,
• Fig. 9 eine Ansicht des Zusatzschlosses gemäß der zweiten Ausführungsform bei angenommener Schloßdecke und zurückverlagertem Riegel,
• Fig. 10 eine der Fig. 9 entsprechende Darstellung, und zwar während des Ausfahrens des Riegels,
• Fig. 11 die vorgeschlossene, die Hakenhintergriffsstellung einnehmende Position des Riegels,
• Fig. 12 eine entsprechende Darstellung, und zwar während der Rückschließverlagerung des Riegels,
• Fig. 13 den Schnitt nach der Linie XIII-XIII in Fig. 9,
• Fig. 14 eine Ansicht des Zusatzschlosses gemäß der dritten Ausführungsform,
• Fig. 15 die klappfigürliche Ansicht der Fig. 14,
• Fig. 16 eine Ansicht dieses Zusatzschlosses bei abgenommener Schloßdecke und in Öffnungsstellung befindlichem Riegel,
• Fig. 17 den Schnitt nach der Linie XVII-XVII in Fig. 16,
• Fig. 18 eine der Fig. 16 entsprechende Darstellung, betreffend eine Vorschließ-Zwischenstellung, die bspw. dadurch erreicht ist, daß das das Zusatzschloß steuernde Mittelschloß eine Schließdrehung von 360° erfahren hat,
• Fig. 19 in perspektivischer Einzeldarstellung die die Sperrnase ausbildende Klinke,
• Fig. 20 eine weitere Zwischenstellung des Zusatzschlosses beim Vorschließen des Riegels, und zwar nach ca. eineinhalb Schließdrehungen am Mittelschloß,
• Fig. 21 das Zusatzschloß in derVorschließstellung des Riegels, welche zwei Schließumdrehungen des Mittelschlosses entspricht,
• Fig. 22 eine Zwischenstellung beim Rückschließen des Riegels in der Position, in welcher die Sperrnase der Klinke den Freiraum verlassen hat,
• Fig. 23 den Schnitt nach der Linie XXIII-XXIII in Fig. 22,
• Fig. 24 eine Ansicht gemäß Fig. 1 einer weiteren Ausführungsform,
• Fig. 25 eine klappfigürliche Ansicht der Fig. 24,
• Fig. 26 eine Ansicht des Zustazschlosses bei abgenommener Schloßdecke, die zurückgeschlossene Stellung des Riegels betreffend,
• Fig. 27 eine der Fig. 26 entsprechende Darstellung, jetzt jedoch während der ersten Schließphase, beim Übergang des Schließzapfens von einem parallel zur Treibstangenbewegung verlaufenden Schlitzabschnitt in einen spitzwinklig diagonal verlaufenden Schlitzabschnitt,
• Fig. 28 die Folgedarstellung, beim Übertritt des Schließzapfens vom spitzwinkligen diagonalen Schlitzabschnitt zum stumpfwinkligen diagonalen Schlitzabschnitt, wobei die Anzugsschräge des Riegelkopfes vollständig der Stulpe vorsteht,
• Fig. 29 eine Folgedarstellung, beim Übertritt des Steuerzapfens in den parallel zur Treibstangenbewegung verlaufenden Schlitzabschnitt,
• Fig. 30 die gegen Rückdrücken gesicherte, vollständig ausgeschlossene Stellung des Riegels,
• Fig. 31 den Schnitt gemäß der Linie XXXI-XXXI in Fig. 28 und
• Fig. 32 eine perspektivische Darstellung des Schwenkriegels.

Three exemplary embodiments of the invention are explained below with reference to the drawings. It shows

• 1 is a view of an additional lock controlled by a central lock, not shown, relating to the first embodiment,
• FIG. 2 shows the foldable view of FIG. 1,
• 3 is a view of the additional lock with the lock cover removed, regarding the closed position of the bolt,
• 4 shows a representation corresponding to FIG. 3, but during the first closing phase, the slot section on the rear side of the lock having shifted relative to the pin of the bolt,
• 5 shows the follow-up view, with the bolt having been displaced on a path directed at an obtuse angle to the drive rod movement with simultaneous pivoting opposite to the hook engagement,
• 6 the position adjoining by further drive rod displacement, the locking head being pivoted into the hook engagement position and the pin of the locking bar located in the transition region between the acute-angled slot section and the slot section attached thereto,
• 7 shows the closing end position secured against back pressure,
• 8 shows the section along the line VIII-VIII in FIG. 7,
• 9 is a view of the additional lock according to the second embodiment with the lock cover assumed and the bolt moved back,
• 10 is a representation corresponding to FIG. 9, namely while the bolt is being extended,
• 11 shows the pre-closed position of the bolt which assumes the hook engagement position,
• 12 is a corresponding representation, namely during the closing shifting of the bolt,
• 13 shows the section along the line XIII-XIII in FIG. 9,
• 14 is a view of the additional lock according to the third embodiment,
• 15 is the foldable view of FIG. 14,
• 16 is a view of this additional lock with the lock cover removed and the bolt in the open position,
• 17 shows the section along the line XVII-XVII in FIG. 16,
• 18 shows a representation corresponding to FIG. 16, relating to a pre-closing intermediate position, which is achieved, for example, by the central lock controlling the additional lock having undergone a closing rotation of 360 °,
• 19 is a perspective individual representation of the pawl forming the locking nose,
• 20 shows a further intermediate position of the additional lock when the bolt is being closed, namely after approximately one and a half closing rotations on the central lock,
• 21 the additional lock in the pre-locking position of the bolt, which corresponds to two closing turns of the center lock,
• 22 shows an intermediate position when the bolt is closed in the position in which the locking lug of the pawl has left the free space,
• 23 shows the section along the line XXIII-XXIII in FIG. 22,
• 24 shows a view according to FIG. 1 of a further embodiment,
• 25 is a flip-flop view of FIG. 24,
• 26 is a view of the additional lock with the lock cover removed, relating to the closed position of the bolt,
• 27 shows a representation corresponding to FIG. 26, but now during the first closing phase, when the locking pin transitions from a slot section running parallel to the drive rod movement into a slot section running diagonally at an acute angle,
• 28 shows the follow-up view, when the locking pin passes from the acute-angled diagonal slot section to the obtuse-angled diagonal slot section, the tightening bevel of the locking head projecting completely from the cuff,
• 29 shows a follow-up view, when the control pin passes into the slot section running parallel to the drive rod movement,
• 30 the completely locked position of the bolt secured against back pressure,
• Fig. 31 shows the section along the line XXXI-XXXI in Fig. 28 and
• Fig. 32 is a perspective view of the pivot bolt.

The espagnolette lock shown in FIGS. 1-8, relating to the first embodiment, has an additional lock 1 controlled by a commercially available central lock (not illustrated). The cuff 2 of the same is formed by an extension of the faceplate of the central lock. A driving rod 3 controlled by the central lock runs behind the cuff 2. The angled end 4 of the latter protrudes into the housing 5 of the additional lock 1.

In particular, the housing 5 has a lock base 6 fastened to the cuff 2 and at right angles thereto. From this, lock case side walls 7, 8, 9 are angled, on which a lock cover 10 is supported. This is from Befe retaining screws 11 held which engage in stud bolts 12 fastened to the lock base 6. In the housing 5 in the direction of the drive rod 3 displaceable connecting rod connector 13 is guided. This forms a niche 14 at the lower end for inserting the bent end 4 of the drive rod 3. In the middle, the connecting rod connecting piece 13 is provided with a recess 15 forming a pocket. The recess floor 16 slides on the inner surface of the castle floor 6 and is equipped with a slot slot 17. Specifically, this is composed of a slot section 18 adjacent to the rear wall of the lock and running parallel to the drive rod movement, a slot section 19 directed at an acute angle in the direction of the cuff 2, and a slot section 20 which adjoins this and also extends parallel to the drive rod movement. The slot section 19 connecting the two outer slot sections 18, 20 running parallel to one another runs at an angle of approximately 45 °.

The slotted slot 17 acts together with a pin 21 of a bolt 22 guided in the housing 5. This bolt has a bolt head 23 which, when the bolt 22 is completely closed, closes with the front surface of the cuff 2 and which projects into a bolt passage opening 24 thereof. The bolt head 23 is provided with a bevel 25 on the side facing the viewer. A bolt tail 26 connects to the bolt head 23. Between this and the bolt head 23, a cutout 27 extends on the underside of the bolt, so that the bolt head 23 protrudes like a hook. The above-mentioned pin 21 is located near the rear flank of the bolt tail 26 in the upper third of the same. The pin 21 is so long that it protrudes beyond the slot slot 17 and still engages in a guide slot 28 of the lock base 6 directed at right angles to the drive rod displacement.

On the flank facing the bolt head 23 and formed by the cutout 27, the bolt tail 26 is equipped with a stop surface 29 obtained by beveling.

Furthermore, the latch 22 is spring-loaded in the direction of exclusion. For this purpose, a torsion spring 30 is attached to the lower stud 12 of the lock housing 5. Its shorter leg 31 is supported on the rear wall of the lock housing, while the other, longer leg 32 acts on the bolt tail 26 below the pin 21 and thus the bolt 22 in the 3 pivoted position.

• Das Vorschließen des Riegels 22 verlangt eine Verlagerung der Treibstange 3 in Abwärtsrichtung mittels des nicht veranschaulichten Treibstangenschlosses. Einhergehend verschiebt sich das Treibstangen-Anschlußstück 13 in Abwärtsrichtung. Während des beginnenden Bewegungsablaufs durchwandert der riegelseitige Zapfen 21 den Schlitzabschnitt 18 des Kulissenschlitzes 17. Solange sich derZapfen 21 in dem Schlitzabschnitt 18 befindet, verändert der Riegel 22 seine Lage nicht, vergl. insbesondere Fig. 3 und 4. In Fig. 4 ist veranschaulicht, daß die obere Flanke 23' des Riegelkopfes 23 zur Stulpe 2 einen spitzen Winkel alpha einschließt. Während der weiteren Treibstangenverlagerung kommt der spitzwinklig verlaufende Schlitzabschnitt 19 zur Wirkung. Durch diesen erfährt der Riegel 22 zunächst eine Auswärtsbewegung aus einer stumpfwinklig zur Treibstange 3 liegenden, im wesentlichen linearen Bahn mit leichter Schwenkung entgegensetzt zum Hakeneingriff. Dies führt dazu, daß der Winkel alpha' zwischen oberer Flanke 23' des Riegelkopfes 23 und Stulpe 2 kleiner wird als der Winkel alpha. Im Zuge dieser weitgehend linearen Verlagerung des Riegels beaufschlagt die Anschlagfläche 29 des Riegelschwanzes 26 die Stulprückseite, vergl. Fig. 5. Dann befindet sich der Zapfen 21 immer noch im spitzwinklig verlaufenden Schlitzabschnitt 19. In Anlagestellung wird der Riegelschwanz 26 zur Stulpe 2 durch die Feder 30 gehalten. Wird die Treibstangenverlagerung fortgesetzt, so bewirkt die verbleibende Länge des spitzwinklig verlaufenden Schlitzabschnitts 19 eine Schwenkung des Riegels 22 in die Stellung gemäß Fig. 6. Diese Schwenkung erfolgt in Richtung eines Hakeneingriffs zu einem nicht veranschaulichten Schließblech. Bei der weiteren Treibstangenverlagerung bewegt sich dann der der Stulpe 2 benachbarte, parallel zu dieser verlaufende Schlitzabschnitt 20 relativ zum Zapfen 21 in die Stellung gemäß Fig. 7. Dadurch ist der Riegel 22 gegen Rückschwenken bzw. Rückdrücken gesichert. Entsprechende Kräfte werden demgemäß nicht in das veranschaulichte Zentralschloß geleitet bzw. müssen nicht von diesem aufgenommen werden. Während dervorschließverlagerung ist der Zapfen 21 in den anderen Endbereich des Führungsschlitzes 28 des Schloßbodens 6 getreten.

The following mode of action occurs:

• The locking of the latch 22 requires a displacement of the drive rod 3 in the downward direction by means of the drive rod lock, not shown. Accompanying this, the connecting rod connecting piece 13 moves in the downward direction. During the beginning movement sequence, the bolt-side pin 21 travels through the slot section 18 of the link slot 17. As long as the pin 21 is in the slot section 18, the latch 22 does not change its position, see in particular FIGS. 3 and 4. In FIG. that the upper flank 23 'of the bolt head 23 to the cuff 2 includes an acute angle alpha. During the further displacement of the drive rod, the slot section 19 running at an acute angle comes into effect. As a result of this, the latch 22 initially experiences an outward movement from an essentially linear path lying at an obtuse angle to the drive rod 3, with a slight pivoting opposite to the hook engagement. This leads to the angle alpha 'between the upper flank 23' of the locking head 23 and the cuff 2 being smaller than the angle alpha. In the course of this largely linear displacement of the bolt, the abutment surface 29 of the bolt tail 26 acts on the back of the faceplate, see FIG. 5. Then the pin 21 is still in the acute-angled slot section 19. In the position of engagement, the bolt tail 26 becomes the faceplate 2 by the spring 30 held. If the drive rod displacement is continued, the remaining length of the slot section 19 running at an acute angle causes the bolt 22 to pivot into the position according to FIG. 6. This pivoting takes place in the direction of a hook engagement with a striking plate (not shown). When the drive rod is displaced further, the slot section 20 adjacent to the cuff 2 and running parallel to it then moves relative to the pin 21 into the position according to FIG. 7. As a result, the latch 22 is secured against pivoting back or pushing back. Corresponding forces are accordingly not conducted into the illustrated central lock or need not be absorbed by it. During the pre-closing shift, the pin 21 has entered the other end region of the guide slot 28 of the lock base 6.

Furthermore, it must also be stated that after pivoting of the bolt 22 into the hook engagement position, a base 33 of the bolt tail 26 adjoining the bolt head 22 has filled in the bolt passage opening 24 of the cuff 2. Thus the latch 22 receives additional support in the upward direction.

The opening of the bolt 22 takes place by the upward movement of the drive rod 3. First, the bolt 22 pivots in the release position. Then it is pulled inwards by the link control in the starting position according to FIG. 3.

The additional lock according to the second embodiment, which is illustrated in FIGS. 9-13, bears the reference number 34. Its housing 35 is on the central lock, not shown leading cuff 36 set. The structure of the housing 35 corresponds to that of the first embodiment. In the interior of the housing 35, a connecting rod connecting piece 37 is guided parallel to the longitudinal direction of the cuff 36. The connecting rod connecting piece is displaced by a connecting rod 38.

In the central area, the connecting rod connecting piece 37 is provided with a pocket 39. In the recess bottom 40 formed by this pocket 39 there is a slotted slot 41 which increases in the direction of the cuff 36 and widens towards its upper end 42. The recess bottom 40 lies directly on the lock bottom 43 of the housing 35. A bolt 44, which is composed of a bolt head 45 and a bolt tail 46, slides on the inside of the recess bottom 40. A cutout 47 extends between the latter and the locking head 45 to form a locking head 45 projecting like a hook.

A pin 48 is embedded in the bolt tail 46. This passes through the slotted slot 41 and then an angular guide slot 49 of the lock base 43. The guide slot 49 has the angled leg 49 'which extends at right angles to the cuff 36 and which is formed via an angled apex 49 "adjacent to the cuff 36 into the shorter one parallel to the cuff 36 Angle leg 49 merges, the diameter of the pin 48 being adapted to the width of the guide slot 49. However, the link slot 41 has a larger width than the guide slot 49. At the level of the link slot 41, the pin 48 carries a rolling element 50. The outside diameter corresponds to the diameter of the Link slot 41 at its lower end 42 '. The transitions in the widened upper end 42' are also provided with radii corresponding to the diameter of the rolling body 50. These radii connect the upper and lower edge of the slot edge 51, 52 with a slot edge directed parallel to the cuff edge 53. The widened upper end 42 of the link slot lies, seen in the longitudinal direction of the lock, at the same height as the angle leg 49 of the guide slot 49.

13 shows in particular that the locking head 45 is wedge-shaped with the formation of bevels 54 and 54 'which run at an acute angle to one another and which cooperate with an engagement opening of the striking plate (not illustrated).

Another component of the additional lock is a block-like sliding block 55. This has a runner 57 which strikes the upper locking edge 56, the latter running parallel to the locking edge 56 and being directed at right angles to the cuff 36. The sliding block is guided in the direction of the drive rod displacement. For this purpose, the side of the slide opposite the runner 57 projects past a guide pin ₅₈ , which penetrates through a bore 59 in a transverse wall 60 of the connecting rod connecting piece 37. The guide pin 58 is the carrier of an energy accumulator K, which in turn is designed as a compression spring 61. This is supported on the one hand on the inside of the transverse wall 60 and on the other hand on the bottom of a blind hole 62 of the sliding block 55.

• Das Vorschließen des Riegels 44 verlangt eine abwärts gerichtete Bewegung der Treibstange 38. Hierdurch wird das Treibstangen-Anschlußstück 37 mitgenommen. Dessen obere Schlitzrandkante 51 drückt gegen den auf dem Zapfen 48 drehbaren Rollkörper 50 verbunden damit, daß der Riegel 44 mit dem Zapfen vorverlagert wird, also ausfährt. Während dieser Bewegung wird die Kraftspeicher-Druckfeder 61 geladen, da der Gleitstein 55 sich mit seiner Kufe 57 an der Oberkante 46 des Riegels 44 abstützt, vgl. Fig. 10. Sobald der riegelseitige Zapfen 48 den Winkelscheitel 49" des Führungsschlitzes 49 erreicht hat, entlädt sich die Kraftspeicher-Druckfeder 61 und verlagert über den Gleitstein 55 den vollständig ausgefahrenen Riegel 44 in Querrichtung, also in Hakenhintergriff zum Schließblech. Die Geschwindigkeit, mit welcher sich dabei der Riegel verlagert, ist größer als diejenige des Treibstangen-Anschlußstücks 37 in Abwärtsrichtung. Durch die Kraftspeicher-Druckfeder 61 ist gewährleistet, daß, falls der Riegel 44 noch nicht vollständig ausgefahren sein sollte, dieser vollständig vorgeschoben wird. Die Erzielung des Hakenhintergriffs ist daher stets gewährleistet. Sobald der Zapfen 48 die untere Schlitzrandkante 52 erreicht, bewegen sich Treibstangen-Anschlußstück 37 und Riegel 44 synchron miteinander. Die vollständige Hakenhintergriffsstellung liegt vor, wenn der Zapfen das untere Ende des Winkelschenkels 49"' erreicht hat. Dann erlaubt der zum oberen Ende hin verbreiterte Kulissenschlitz 41 noch eine gewisse Weiterverlagerung des Treibstangen-Anschlußstücks 37. Im Normalfall liegt jedoch die Stellung des vorgeschlossenen und gesicherten Riegels gemäß Fig. 11 vor. Dann werden etwaige auf den Riegel 44 einwirkende Rückdrückkräfte von dem Winkelschenkel 49 des winkelförmigen Führungsschlitzes 49 aufgefangen und demgemäß in das Schloßgehäuse 35 geleitet.

The operation of the additional lock according to the second embodiment is as follows:

• The closing of the bolt 44 requires a downward movement of the drive rod 38. As a result, the drive rod connector 37 is taken along. Its upper edge of the slot edge 51 presses against the roller 50 rotatable on the pin 48, so that the bolt 44 is advanced with the pin, that is to say extends. During this movement, the energy storage compression spring 61 is loaded, since the sliding block 55 is supported with its runner 57 on the upper edge 46 of the bolt 44, cf. Fig. 10. As soon as the bolt-side pin 48 has reached the angular apex 49 "of the guide slot 49, the energy storage compression spring 61 unloads and displaces the fully extended bolt 44 in the transverse direction, that is to say in hook engagement with the striking plate. The speed with which the bolt moves in the process is larger than that of the connecting rod connecting piece 37 in the downward direction. The energy storage compression spring 61 ensures that, if the bolt 44 has not yet been fully extended, it is fully advanced As soon as the pin 48 reaches the lower edge of the slot edge 52, the connecting rod connecting piece 37 and the bolt 44 move synchronously with one another. The complete hook engagement position is reached when the pin has reached the lower end of the angle leg 49 "'. Then the slotted slot 41 widened towards the upper end still allows a certain displacement of the connecting rod connecting piece 37. In normal cases, however, the position of the pre-closed and secured bolt according to FIG. 11 is present. Any possible push-back forces acting on the bolt 44 are then absorbed by the angle leg 49 of the angular guide slot 49 and accordingly conducted into the lock housing 35.

The closing requires an oppositely directed displacement of the drive rod 38, that is to say in the upward direction. The bolt 44 is taken along via the lower, rising edge 52 of the slot. Since it moves synchronously with the connecting rod connecting piece 37, the energy accumulator K does not exert any force to be overcome. This can only become effective when the pin 48 of the bolt 44 reaches the angle apex 49 "and from there is moved with the bolt in the direction of the angle leg 49 '. The energy accumulator then acts in conjunction with the slit edge 52 as a supporting component when closing the bolt using the still inherent stored force of the energy accumulator. An intermediate phase during closing is illustrated in FIG. 12, the pin 48 having just entered the angle leg 49 ′ of the angular guide slot 49.

In the third embodiment illustrated in FIGS. 14 to 23, the additional lock 63 has a housing 64. This is fastened to the cuff 65 leading to the central lock (not shown) of the drive rod lock. For this purpose, connecting tabs 67, which form projections, are bent on both sides of the bolt passage opening 66 from the lock base 68. Each connecting strap 67 is penetrated by a rivet 69 which is guided through the cuff 65 in order in this way to connect the lock housing to the cuff to form a fixed structural unit. The lock set-up is covered by a lock cover 70 into which the angled ends of the connecting straps 67 are inserted.

In the interior of the housing 64, a connecting rod connecting piece 71 is guided parallel to the longitudinal direction of the cuff 65. On this engages a drive rod 72 leading to the center lock, not shown. A closing operation of the same is accordingly transferred to the connecting rod connecting piece. The central lock is preferably constructed in such a way that two closing rotations correspond to a complete displacement of the connecting rod connecting piece 71.

The drive rod connector 71 lying flat on the lock base 68 has in the central region a slotted slot 73 which rises in the direction of the cuff 65, the two opposite ends of which merge into niches 74, 75 which run parallel to the direction of displacement of the drive rod connector. At the height of the slotted slot 73, there is a bolt 76 on the connecting rod connecting piece 71, which bolt is composed of a bolt head 76 'and a bolt tail 76 ". The bolt head 76' forms a hook projection 76 projecting transversely beyond the bolt tail 76". At the same level, the bolt head 76 'has a cross section which corresponds to that of the bolt passage opening 66.

The bolt tail 76 "carries on its side facing the connecting rod connecting piece 71 a projecting guide pin 77 which is slightly smaller in diameter than the width of the slot slot 73. The length of the guide pin 77 corresponds approximately to the thickness of the connecting rod connecting piece 71st The guide pin 77 is followed by a cross-sectionally offset pin section 77 ', which is immersed in an angular guide slot 78 of the lock base 68. The diameter of the pin section 77' corresponds approximately to the width of this angular guide slot 78. The latter is composed of an angled leg running at right angles to the cuff 65 78 'and an angle leg 78 "running parallel to the cuff 65, which is shorter than the other angle leg. The angle apex 78 connecting the two angle limbs is rounded.

The side of the bolt tail 76 "opposite the guide pin 77 'is also provided with a pin 79 projecting therefrom, which is rectangular in shape in such a way that its greatest length lies in the direction of the bar exclusion. This pin 79 fits in shape in the direction of the extension displacement of the bar 76 extending slot 80 of a guide slide 81. In plan, the guide slide 81 has a T-shape and accordingly forms a T-web 82 and the two T-legs 83 projecting therefrom. The aforementioned slot 80 is located in the T-web 82 The T-legs 83, on the other hand, are guided by fork pieces 84 of the connecting rod connecting piece 71 which are angled in the direction of the lock cover 70.

Another component of the lock mechanism is a pawl 85. At its upper end it forms a short slot 86, into which a pin 87 on the connecting rod connection side is immersed. In the open position, the pin 87 extends at the lower end of the slot 86 of the pawl 85, see FIG. 16. The end of the pawl 85 opposite the bearing point is angled in the direction of the cuff 65 and forms a locking lug 88. The pawl 85 is of one arranged on a stud 89 of the connecting rod connecting piece 71 arranged torsion spring 90 so that the locking lug 88 is forced into contact with the inner surface of the cuff 65. The angled end or the locking lug 88 forms a modulation flank 91 on its or its narrow side facing the bolt passage opening edge 66 '. The top surface 92 of the locking lug 88 extends at an acute angle to this, which top surface is also designed as a modulation flank. In the open position according to FIG. 16, the head surface control flank 92 extends at an acute angle to the inner faceplate and above the corresponding projection 67.

The operation of the espagnolette lock is as follows: If the middle lock, not shown, is actuated by means of a key, this leads via the drive rod 72 to entrainment of the espagnolette connector 71 in the downward direction. Due to the bolt-side guide pin 77 lying in the niche 74, the connecting rod connecting piece 71 is displaced in the initial phase without pre-closing the bolt 76. The pre-closing starts only when the upper edge of the slot 73 'of the slot slot 73 acts on the guide pin 77. After a closing rotation of the Key at 360 ° on the central lock is the position shown in FIG. 18 on the additional lock 63. Along with the previously described sequence of movements, the pawl 85 has been carried over the pin 87 of the connecting rod connecting piece. The locking nose control flank 92 passes over the projection 67 and inevitably leads to a pivoting of the pawl 85 against spring loading. In the course of the further locking operation, the position of the additional lock 63 according to FIG. 20 is reached after about one and a half key turns of the central lock. Then the locking lug 88 of the pawl 85 completely bypasses the projection 67 and also the rivet 69. Furthermore, the guide pin 77 is immersed in the upper recess 75 of the slot slot 73. Along with the locking of the bolt 76, the pin portion 77 'has passed through the apex 78 between the two angle legs 78', 78 "of the guide slot 78 at the level of the shorter angle leg 78" running parallel to the cuff 65, forcing a certain downward displacement of the bolt 76, which, however, has already been immersed in a counter-striking plate (not shown) during its rectilinear locking. During the further closing process, the hook engagement behind the striking plate is then achieved. After executing two closing rotations on the central lock, the position according to FIG. 21 is present. In the final phase of the transverse displacement of the bolt 76, the pawl 85 could pivot spring-loaded in the direction of the cuff 65, the locking lug 88 being immersed in the remaining free space F of the bolt passage opening 66. In this position, the guide pin 77 is located in the upper recess 75 of the link slot 73, while the pin section 77 'starting from the guide pin 77 lies at the lower end of the angle leg 78 "of the guide slot 78. During the closing process, the guide slide 81, which is shown in FIG Pin / slot connection to the bolt 76 is, shifted relative to the connecting rod connector 71.

Coercive forces occurring in the longitudinal direction of the bolt are absorbed on the one hand by the joint engagement between the striking plate and the bolt head. On the other hand, the pin portion 77 'is supported on the vertically extending angle leg 78 "or its wall. On the other hand, if constraining forces are applied to the latch 76 in the longitudinal direction of the drive rod 72, the upper longitudinal bar edge 93 abuts the locking lug 88, which in turn abuts In any case, the play between the guide pin 77 of the bolt and the lower edge of the slot edge 73 "is greater than the distance between the longitudinal edge of the bolt 93 and the locking lug 88, so that the lower edge of the slot edge 73" cannot come into effect the locked position is maintained.

Opening the additional lock requires the key actuation of the central lock, the key of which is to be turned in the opposite direction, associated with an upward displacement of the drive rod 72 and the connecting rod connector 71. In the initial phase of the upward movement of the connecting rod connector 71, the pawl 85 is immediately over taken the pin 87, which is now at the upper end of the slot 86 of the pawl 85. The control flank 91 interacts with the facing bolt passage opening edge 66 'and inevitably leads to a pivoting of the pawl 85 against spring loading. The niche 75 allows the displacement of the connecting rod connecting piece 71 without directly taking the bolt 76 in the upward direction, that is to say in the transverse direction to its excluding direction, so that the actuation of the pawl 85 can take place without problems. With the further closing actuation, the bolt is then dragged in the upward direction by the upward driving rod 72 and connecting rod connecting piece 71 via the lower edge of the slot edge 73 "and then retracted, the pin portion 77 'of the guide pin 77 passing through the angular slot 78. During this shift, the circumference passes Locking lug 88 protrusion 67. As a result, the actuation flank 91 on protrusion 67 becomes effective by pivoting pawl 85 against spring loading. As soon as pawl 85 has bypassed protrusion 67, torsion spring 90, which pawl 85 pivots toward cuff 65, can reset such that the pin 87 is then again in the lower region of the slot 86 in accordance with the basic position of the additional lock in FIG. 16.

Another additional lock according to the invention is shown in FIGS. 24-32, the bolt now being designed as a pivot bolt 122 which is pivotably mounted with a bearing pin 123 in the lock base 139 and the lock cover 134. On the lock floor, a link 131 is guided which has a guide slot 130 which runs parallel to the drive rod displacement direction and which is penetrated by the pivot pin 132 of the pivot bolt and whose length corresponds to the drive rod stroke.

In order to control the pivot bolt 122, the link 131 has a control slot 117, in which a control pin 121 of the bolt 122 engages. The control slot 117 has a diagonally extending region 119 and at the end in each case an adjoining slot section 118 and 120 running parallel to the drive rod displacement direction. The diagonal section of the control slot is divided into an obtuse-angled slot section 119 'and an acute-angled slot section 119 ".

The swivel bolt 122 consists of a bolt head 123 and a bolt tail 126, wherein the bolt 123 is mounted around the journal 132 in the bolt tail region. The control pin 121 is located in the transition area between the bolt tail and bolt head. The hook-shaped swivel bolt 122 has a bevel 125 on the head side. The pull-in chamfer is one-sided, and it has the task of pulling the door or the like to be locked against the counter-lock part during the locking of the bolt and its engagement in the striking plate of the counter-locking part, the locking part coming onto the pull-in chamfer 125.

To securely guide the link 131 on the lock base 139, the link has guide claws 138, 137 at each end, which surround guide ribs 135, 136 stamped into the lock cover.

• In der in Fig. 26 dargestellten Stellung befindet sich der Schwenkriegel 122 in der vollständig zurückgeschlossenen Position. Der Schließzapfen 121 befindet sich jetzt in dem parallel zur Treibstangenbewegung verlaufenden Schlitzabschnitt 118. Bei beginnender Treibstangenverlagerung, verbunden mit einer Abwärtsverlagerung der Kulisse 131 tritt der Steuerzapfen 122 aus dem parallel zur Treibstangenbewegung verlaufenden Schlitzabschnitt 118 heraus und tritt gemäß Fig. 27 in den diagonal verlaufenden Schlitzabschnitt 119" ein, der sich dem parallel verlaufenden Abschnitt 118 anschließt.

The functionality of the swing bolt is as follows:

• In the position shown in Fig. 26, the pivot bolt 122 is in the fully closed position. The locking pin 121 is now located in the slot section 118 running parallel to the drive rod movement. When the drive rod displacement begins, combined with a downward displacement of the link 131, the control pin 122 emerges from the slot section 118 running parallel to the drive rod movement and, as shown in FIG. 27, enters the diagonal slot section 119 ", which connects to the parallel section 118.

A subsequent displacement of the link 131 initially causes the latch 122 to move relatively slowly.

Fig. 28 shows the additional lock in one position, wherein the swivel bolt has been displaced so far that the bevel 125 has completely come out of the cuff. The boundary 140 between the chamfered area of the bolt head 125 and the non-chamfered area of the bolt head is flush with the faceplate in this position. In this position, the control pin 121 is in the transition into the obtuse-angled slot section 119 ', which is angled toward the drive rod with respect to the slot section 119 ". A further displacement of the link now causes a relatively large pivoting movement of the bolt relative to a comparatively small lifting movement of the link.

In the position shown in FIG. 29, the locking pin emerges from the obtuse-angled slot section 119 ′ and into the slot section 120 running parallel to the drive rod displacement direction.

30 shows the additional lock with the swivel bolt 122 fully closed. The locking pin 121 is supported in this position in the slot section 120 running parallel to the drive rod movement direction. In this position, the swivel bolt is secured against being pushed back, since the slot wall of the slot 120 is loaded when the swivel bolt is loaded from the outside only a normal force is exerted on this diaphragm wall.

The additional lock is controlled by a central lock, which has a lockable bolt. This bolt has two pre-closing positions, a first pre-closed position corresponding to the closing position of the additional lock shown in FIG. 28, so that the swivel bolt 122 only protrudes from the cuff 102 to such an extent that the boundary 140 between the beveled area and the non-beveled area of the Bolt head aligned with the faceplate. Only when the bolt is locked twice does the pivot bolt assume its completely excluded position shown in FIG. 30.

Claims (26)

1. Moving bar lock with an additional lock (1, 34, 63), controlled by a central lock, which has a locking bar (22, 44, 76) which engages the locking plate in hook-like manner, characterised by a sliding block control of the locking bar (22,44,76) which splits the movement path of the locking bar (22, 44, 76) into different sections in such a way that during lockout the locking bar initially moves out and then, for achieving a hook-like engagement on the locking plate, makes a movement transverse to the moving out displacement.

2. Moving bar lock, especially according to claim 1, characterised in that during lockout the locking bar (22) initially becomes displaced through light pivoting of the locking bar head (23) opposite to the hook-like engagement on an essentially linear path situated at an obtuse angle to the moving bar (3) and then pivots on the locking plate for achieving the hook-like engagement.

3. Moving bar lock, especially according to one or more of the preceding claims , characterised by a pedestal (33) for filling the locking bar through opening (24) of the weather rail (2) on the front surface of the locking bar (22).

4. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the sliding block control is formed by a slot/journal engagement (17, 21) and the slot (17), connected to a slot section (18) situated parallel to the moving bar displacement, has a slot section (19) directed at a vertical angle to the weather rail (2).

5. Moving bar lock, especially according to one or more of the preceding claims, characterised by a slot section (20) situated parallel to the moving bar for blocking the locked-out position of the locking bar (22).

6. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the pivot movement of the locking bar (22) from a stop surface (29) on the reverse side of the weather rail is achieved by a superpositioning of the locking bar displacement in the area situated at a vertical angle to the slot section (19) and the abutment against a stop surface (29) situated at a lever arm distance from the slot control point.

7. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the locking bar (22) is spring-loaded in the lockout direction.

8. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the locking bar (22) engages a pocket (15) of a moving bar connecting piece (13) whose base (16) contains the slot sections (18, 19, 20).

9. Moving bar lock, especially according to one or more of the preceding claims, characterised in t hat a journal (48, 77) on the locking bar side penetrates a sliding block slot (41,73) of a moving bar connecting piece (37, 71) guided in the additional lock and, also connected thereto on the housing side, an angular guide slot (49, 78) one of whose arms (49', 78') is situated at right angles to the weather rail 36, 65) and whose other arm (49"'. 78") runs parallel to the weather rail (36, 65).

10. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the journal (48) penetrates a roller body (50) which engages in the sliding block slot (41).

11. Moving bar lock, especially according to one or more of the claims, characterised in that the sliding block slot (41 ) inclined towards the weather rail (36) becomes wider towards its upper end (42) and that an energy store (K) is provided which charges up during the locking-out of the locking bar (44) and engages the locking bar in a hook-like manner.

12. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the energy store (K) formed by the pressure spring (61) is supported by the moving bar connecting piece (37) on the one hand and by the slide member (55) moving against the locking bar (44) on the other hand.

13. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the slide member (55) carries a guide pin (58) penetrating a transverse wall (60) of the moving bar connecting piece (37) and this supports the pressure spring (61).

14. Moving bar lock, especially according to one or more of the preceding claims, characterised by a blocking nose (88) which in the locking position of the locking bar (76) fills the free space (F) of the locking bar through opening (66).

15. Moving bar lock, especially according to claim 14, characterised in that the blocking nose (88) is formed by the bent end of a spring-loaded pawl (85).

16. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the pawl (85) is mounted on the moving bar connecting piece (71), is spring-loaded in the direction of its blocking engagement and that the bent end (blocking nose 88) at its narrow side facing the locking bar through opening edge (66') forms a control edge (91) which comes into effect when the moving bar connecting piece (71) returns.

17. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the mounting of the pawl (85) as journal/slot mounting (86, 87) is formed for free slot movement in the direction of the moving bar connecting piece (71) which forms the connecting tongue of the housing (64) to the weather rail (65), the blocking nose (88) by-passes a projection (67) situated in its path of movement.

18. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the head surface (92) of the blocking nose (88) is also forced as a control edge which in the opening position is at a vertical angle to the inside of the weather rail.

19. Moving bar lock, especially according to one or more of the preceding claims, characterised by the fact that as a result of a slot/journal connection (79, 80) being effected in the direction of the outward displacement from the locking bar (76) by the guiding slide (81) during its transverse movement.

20. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the guiding slide (81) is T-shaped and the ends of the T-shaped arms (83) engage in forked pieces (84) of the moving bar connecting piece (71) and the T-web (82) has the slot (80) in which the journal (79) on the side of he locking bar is non-rotatably guided.

21. Moving bar lock with an additional lock, controlled by a central lock, has a locking bar which by pivoting about a swivel axis engages in a hook-like manner to the lock plate, characterised by a sliding block (131), driven by a moving bar, which through a control slot (117) and a control journal (121) is coupled to the locking bar (122), in which for blocking the locked-out locking bar, the control slot section (119, 119', 119") running diagonally to the moving bar continues at the end in a slot section (120) running parallel to the direction of the moving bar.

22. Moving bar lock according to claim 21, characterised by a slot section (119") extending at a vertical angle to the direction of movement of the moving bar and at an obtuse angle from the slot section (119") is a slot section (119') of the diagonally extending slot section (119), in which connected to the obtuse angled slot section (119') is the slot section (120) extending parallel to the direction of movement of the moving bar and that the length of the slot section (119') at an obtuse angle is so dimensioned that when the control journal (121) enters the obtuse angled slot section (119') during the prelocking displacement of the locking bar (122), the pick-up diagonal (125) constructed on one side of the locking bar head (123) of the locking bar (122) projects completely from the weather rail (102).

23. Moving bar lock, especially according to one or more of the preceding claims, characterised by a guide slot (130), extending parallel to the moving bar in the sliding block (131), which is penetrated by a bearing pin (132) of the locking bar (122) mounted in the lock housing and forming the pivot axle, and the length of the locking bar corresponds to the stroke of the moving bar.

24. Moving bar lock, especially according to one or more of the preceding claims, characterised by a slot section (118) connected to the end of the control slot, for blocking the locked-in position of the locking bar (122), running parallel next to the guide slot (130) on the side of the guide slot (130) facing away from the weather rail (102).

25. Moving bar lock, especially according to one or more of the preceding claims, characterised in that the control journal (121) situated in the control slot (119) can be displaced from a locked-in position adjacent to the housing rear wall (133) (see Fig. 26) beyond the imagined extension of the guide slot (130) to a position adjacent to the locked-out position associated therewith.

26. Moving bar lock, especially according to one or more of the preceding claims, characterised by a guide rib (135, 136), embossed in the housing cover (134) running parallel with the moving bars, which grips the guide claws (137) of the sliding block (131) forguiding this along the housing floor (139).

Images