EP0454959A2 - Plug actuated sliding bar lock - Google Patents

Abstract

The drive rod lock is actuated by a lock cylinder (41), whose tongue (43) is enclosed by a gear ring (39) with a gap (42) for the passage of the cylinder. The ring meshes with two pinions on the outside, which drive sliders (28) coupled to the rods via redn. gear trains. When the bolt (35) is locked clear of the ring, a lever (W) actuated by the latter allows retraction of the catch (33) by a key. The lever operating arm (71) is spring-loaded towards the gear ring, and is controlled by an edge (76) on the rod slider.

Description

The invention relates to a locking cylinder-actuated espagnolette lock according to the preamble of claim 1.

In one embodiment to be considered - DE 35 20 862 A1 - the change lever arrangement is composed of two levers coupled together. The lower of these levers forms an elongated hole in which a coupling pin of the bolt is immersed. When the bolt is closed, the lower lever is controlled into the actuation area of the ring gear via this coupling connection. This then allows the switch to be actuated while retracting the latch. If the bolt is locked, it in turn takes the lower lever with it so that it leaves the actuation area of the ring gear. Such a change lever arrangement requires, as a result of the lever of the change lever arrangement carried by the bolt when the bolt is closed, a relatively large installation space. Corresponding espagnolette locks with a small backset can therefore not be created on this basis.

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 so that the change lever arrangement allows the smallest possible backset and that control of the change lever arrangement is not derived from the closing movement of the bolt.

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

The subclaims represent advantageous developments of the inventive solution.

As a result of such a design, an espagnolette lock of the type in question is specified, the change lever arrangement of which requires only a small accommodation space in the lock housing. The mortise lock can be set to different backset without changing the change lever arrangement. This includes even the smallest possible backset. This advantage is achieved in that the change lever arrangement is no longer coupled to the bolt itself. Rather, it is controlled by a control edge of the connecting rod connecting slide. There is a spring loading of the actuating arm against the direction of the sprocket actuation area. With a corresponding closing rotation in order to be able to retract the latch by means of the change lever arrangement, a shifting of the connecting rod connecting slide takes place via the gear transmission, so that the control edge moves the actuating arm into the actuating area of the ring gear, which in the event of further rotational displacement of the ring gear to one Withdrawing the trap leads. If the closing rotation takes place in a different direction in order to pre-close the bolt and to engage the drive rods or the bolt elements seated thereon, the actuating area of the toothed ring can pass through the pivoted actuating arm without any problems. The actuating arm is pivoted into the release position by the change lever spring. The change lever spring fulfills a double function in that it is also the latch spring. As a result, lock components can be saved. The design of the actuating arm as ensures that the actuating arm is carried along well when the key is alternately actuated hook pawl pointing in the circumferential direction of the ring gear. The latter engages articulatedly on a change lever intermediate member leading into the trap area and pivots behind a nose of the toothed ring in the actuating position, that is to say for the purpose of withdrawing the trap. The fact that the control edge of the connecting rod connecting slide engages in the area of the articulation point between the actuating arm and the intermediate member has a particularly space-saving effect. For the purpose of a space-saving construction, the change lever spring sits on the end area of the intermediate link. The pushing movement of the same upon changing operation leads to a retraction of the latch into the lock housing interior via a change lever deflection member. The change lever spring forming the latch spring is advantageously designed as a compression spring. Its end on the link side is in a non-positive connection with one arm of the deflecting member in such a way that the compression spring is tensioned when the nut is actuated and accordingly brings it back into its pre-closing position after the nut actuation has ended. In order to achieve this non-positive connection without additional components, it is formed by a spring wire passing through the compression spring, which continues via a fastening pin on the deflection member into a torsion spring section which loads the trap tail. In a technically simple manner, the spring wire is designed as a bend in the last thread of the compression spring. The end of the compression spring opposite the bend, on the other hand, is supported on a fixed abutment of the lock housing. The abutment is advantageously designed as a projection of a carrier plate of the gear transmission. Furthermore, the structure of the drive rod lock is simplified by equipping the deflecting member with a third arm on which the nut actuating slide engages. The latter is in one Provided free space of the support plate is loaded by a return spring and is in mesh with the nut. So that different distances between the axis of rotation of the cylinder core of the lock cylinder and the axis of rotation of the nut can be realized without changing the lock structure, the nut is arranged in an interchangeably used bearing housing. Depending on the distance, the tooth of the nut engages in one of several windows of the nut actuating slide. Different spacing dimensions therefore only require modified bearing housings, which allows the production of differently designed locks according to the modular system. The bearing housing is otherwise designed so that it forms a fitting plate screw passage hole arranged below the nut. The deflection member, which is also controlled by the nut actuating slide, projects with its arm engaging the latch between the fork prongs of the forked latch tail. The third arm of the deflecting member acted upon by the nut actuating slide is also forked. Through the fork opening formed in this way, the connecting rod connecting slide runs through to achieve a nesting of components connected with a saving of space. This is optimized by the fact that the connecting rod connecting slide can be inserted into the fork opening of the latch tail with an angle leg lying transversely to the cuff. The length of the lock housing of the espagnolette lock can be shortened in the longitudinal direction by the amount of retraction of this angle leg. In addition, the nesting can be further improved in that the latch travels back with its fork opening over the angular section of the connecting rod connecting slide running parallel to the cuff. So that the actuating arm does not pivot into the actuating area of the ring gear even when the case is moved back the actuating arm is held in a neutral basic position by a fixed spring. For example, after painting the door and with the latch shifted inward, it cannot happen that a locked bolt cannot be closed again. The one-sided clearance between the deflecting member and the intermediate member, which occurs when the latch is pushed back, then also contributes to a trouble-free closing function. It is thereby ensured that the change lever spring representing the latch spring can be stretched over the deflecting member while the intermediate member remains in its position.

Fig. 1

eine Ansicht des Treibstangenschlosses bei zurückgeschlossenem Riegel,

Fig. 2

eine klappfigürliche Darstellung der Fig. 1,

Fig. 3

eine Ansicht des Schloßgehäuses bei fortgelassener Schloßdecke, wobei sich der Zahnkranz in der Grundstellung befindet, die das Einsetzen eines Schließzylinders erlaubt,

Fig. 4

den Schnitt nach der Linie IV-IV in Fig. 3,

Fig. 5

in vergrößerter Darstellung den oberen Bereich des Treibtangenschlosses gemäß der Stellung, die sich bei rückgeschlossenem Riegel und abgezogenem Schlüssel ergibt, teils in Ansicht, teils im Längsschnitt,

Fig. 6

den Schnitt nach der Linie VI-VI in Fig. 5,

Fig. 7

eine Ansicht der Trägerplatte mit rückwärtigem Eckwinkel bei strichpunktiert angedeutetem Schloßboden,

Fig. 8

hierzu die klappfigürliche Darstellung,

Fig. 9

eine Ansicht des Treibstangenschlosses, von dem Schloßboden her gesehen, bei strichpunktiert angedeutetem Schloßgehäuse,

Fig. 10

eine Seitenansicht des der oberen Treibstange zugeordneten Treibstangen-Anschlußschiebers, welcher sich aus zwei Teilen zusammensetzt,

Fig. 11

in vergrößerter Darstellung das Treibstangenschloß im Bereich des Lagergehäuses für die Nuß, teilweise in Ansicht, teilweise im Schnitt,

Fig. 12

einen Längsschnitt durch das Lagergehäuse,

Fig. 13

ein abgewandelt gestaltetes Lagergehäuse, durch welches ein größeres Abstandsmaß zwischen Zylinderkernachse und Nußdrehachse bestimmt wird,

Fig. 14

teils in Ansicht, teils im Schnitt die Stulpe mit Lagerböckchen und Befestigungsvorsprüngen vor dem Verbinden mit dem Schloßboden und der Schloßdecke,

Fig. 15

die klappfigürliche Darstellung der Fig. 14,

Fig. 16

eine Draufsicht auf das Schließeingerichte bei Drückerbetätigung unter Zurückziehen der Falle, wobei nur die entsprechenden Funktionsteile des Treibstangenschlosses veranschaulicht sind,

Fig. 17

eine entsprechende Darstellung des Treibstangenschlosses bei Wechselbetätigung,

Fig. 18

eine der Fig. 9 entsprechende Darstellung, jedoch bei vollständig vorgeschlossenem Riegel, welche Vorschließstellung nach zwei Schließdrehungen des Schlüssels erzielt wird,

Fig. 19

eine der Figur 18 entsprechende Darstellung, die sich beim Zurückschließen des Riegels ergibt, und

Fig. 20

eine Rückansicht des Riegels, in Richtung des Riegelschwanzes gesehen.

An embodiment of the invention is explained below with reference to the drawings. It shows

Fig. 1

a view of the espagnolette lock with the bolt closed,

Fig. 2

2 shows a foldable illustration of FIG. 1,

Fig. 3

2 shows a view of the lock housing with the lock cover removed, the toothed ring being in the basic position, which allows the insertion of a locking cylinder,

Fig. 4

the section along the line IV-IV in Fig. 3,

Fig. 5

in an enlarged view the upper area of the drive rod lock according to the position that results when the bolt is closed and the key removed, partly in view, partly in longitudinal section,

Fig. 6

the section along the line VI-VI in Fig. 5,

Fig. 7

1 shows a view of the carrier plate with a rear corner angle with a lock base indicated by dash-dotted lines,

Fig. 8

the foldable representation,

Fig. 9

2 shows a view of the espagnolette lock, seen from the bottom of the lock, with the lock housing indicated by dash-dotted lines,

Fig. 10

a side view of the connecting rod connecting slide associated with the upper connecting rod, which is composed of two parts,

Fig. 11

in an enlarged view the espagnolette lock in the area of the bearing housing for the nut, partly in view, partly in section,

Fig. 12

a longitudinal section through the bearing housing,

Fig. 13

a modified bearing housing, which determines a larger distance between the cylinder core axis and the nut axis of rotation,

Fig. 14

partly in view, partly in section, the cuff with lugs and fastening projections before connecting to the lock base and cover,

Fig. 15

14 shows the foldable representation of FIG. 14,

Fig. 16

a plan view of the closing mechanism when the handle is actuated while the latch is withdrawn, only the corresponding functional parts of the espagnolette lock are illustrated,

Fig. 17

a corresponding representation of the espagnolette lock when changing,

Fig. 18

9 shows a representation corresponding to FIG. 9, but with the bolt fully closed, which pre-locking position is achieved after two locking rotations of the key,

Fig. 19

a representation corresponding to Figure 18, which results when closing the bolt, and

Fig. 20

a rear view of the bolt, seen in the direction of the bolt tail.

The espagnolette lock has a lock housing 2 connected to a cuff 1. The cuff 1 fastened to one narrow side of the lock housing 2 has a greater length than the lock housing 2 and extends over an upper and a lower drive rod 3 or, respectively, emerging from the lock housing 2. 4. The latter are provided with locking members 5 which cooperate with counter-closing parts, not shown, on the frame.

At the level of the narrow side walls 6, 7, bearing blocks 8 extend from the rear surface of the cuff 1 and continue to form a step in rearward-facing fastening projections 9. Seen in cross section, the fastening projections 9 projecting over the narrow side walls 6, 7 have a trapezoidal shape such that the base of the trapezoid extends to the interior of the lock housing turned towards. For the fastening projections 9, both the lock base 10 and the lock cover 11 running parallel thereto form insertion pockets 12 and 13 on the narrow side walls. The pocket 12 formed by the lock base 10 is obtuse-angled. One angular section 12 'lies against the facing side wall of the fastening projection 9, while the adjoining angular section 12''is supported flatly on the trapezoidal surface opposite the base. The angle section 12 ″ is equipped with a passage opening 14 which is aligned with a threaded bore 15 of the fastening projection 9. Otherwise, this threaded hole runs parallel to the cuff 1.

The other insertion pocket 13 in turn also has an angular shape. The angle leg 13 'starting directly from the castle ceiling 11 is supported on the facing oblique flank of the trapezoidal fastening projection 9. The adjoining angle leg 13' 'extends over the angle leg 12' 'and lies flat on it. There the angle leg 13 '' is equipped with a hole 16. By means of a bolt 17, which extends through the insertion pockets 12, 13 and enters the threaded bore 15 of the fastening projection 9 as a screw, the cuff 1, lock base 10 and lock cover 11 can be connected to form a structural unit.

The outer surface 18 of the bearing blocks 8 is convexly curved. Within this convex curvature also extend the outer surface of the fastening projections 9 and the insertion pockets 12, 13 formed by bends, cf. 5 and 6. This makes it possible to produce pockets on the doors that the outline shape of the lock housing at the height of the bearing blocks 8 are adapted.

Each bearing block 8 has a projection 19 with an oval cross section for fixing it on the cuff 1, which is inserted into a shape-adapted recess 20 of the cuff and riveted there, cf. 5 and 14 in particular.

At the side of the passage channels 21 for the drive rods 3, 4, the bearing blocks 8 form centering brackets 22 which are immersed in shape-matched edge recesses in the lock base 10 and lock cover 11. The aforementioned centering tabs 22 are flush with the outer surfaces of the lock base 10 and lock cover 11.

An additional fastening point between cuff 1 and lock base 10 is then also provided. Part of the same is a projection 24 fastened to the rear surface of the cuff 1, which extends in the area between the two bearing blocks 8. A threaded bore 25 is provided in the projection 24 for receiving a bolt 26, which is also designed as a screw. The latter runs parallel to the cuff 1, but is aligned at right angles to the other bolts 17, since it is screwed in through a hole 27 in the lock base 10. In this way, differently designed cuffs 1 with connecting rods 3, 4 can be connected to lock housings 2, which may also have different designs, with easy assembly.

In the exemplary embodiment, the lower drive rod 4 is forked in the region of the section crossing the bearing block 8. A longitudinal slot 29 is formed by the two fork tines 4 ', 4''. Each fork 4 '. 4 '' is provided with an angled end portion E, E ', which rest on the lock base 10 and immerse in form-fitting coupling recesses 31, 32 of a drive rod connecting slide 28 lying flat on the lock base 10. The aforementioned longitudinal slot 29 extends, moreover, at the level of a through hole 30 of the cuff 1 for a locking cylinder fastening screw 30 '.

A trap 33 is guided between the upper bearing block 8 and the projection 24. This has a head 33 'which extends through a latch opening 34 of the cuff 1 and is equipped with a latch slope, to which a latch tail 33' 'adjoins the housing.

Below the latch 33, a bolt 35 is guided in the lock housing. Its locking head 35 'passes through a cross-section-adapted passage opening 36 of the cuff 1.

Between the bolt head 35 'and the lock base 10 there remains such a distance which allows the drive rod connecting slide 28 to be passed through. In one end position of the same, the end section E 'can then pass under the bolt head 35' combined with a small space requirement between the lower narrow side wall 7 and the bolt 35.

The lock base 10 and the lock cover 11 hold a support plate 37 between them. This supports a toothed ring 39 in its lower region in a bore 38 facing the lock cover 11. The axis of rotation of the same is designated M1. The bore 38 is crossed by a locking cylinder insertion opening 40. The same is the outer contour of a profile locking cylinder 41 customized. The axis of rotation M2 of the cylinder core of the profile locking cylinder used is eccentric to the axis of rotation M1, below the same, cf. Fig. 3.

The aforementioned gear rim 39 has a radially directed gap 42 for engaging a lock bit 43 of the profile locking cylinder 41, shown in dash-dotted lines. Two output gearwheels 44, 45 mesh with the external teeth of the gear rim 39. Despite the locking cylinder through-gap 42, it is achieved that the ring gear 39 meshes with at least one driven gear 44 or 45. The rotation of the output gears 44, 45 is transmitted to an end gear 51 with the interposition of further reduction gears 46-50. The axle journals for the same are also part of the carrier plate 37. The carrier plate 37 thus contains all the pinion functional units.

The end wheel 51 meshes with the rack 52, which is parallel to the cuff 1 and is located at the free end of the connecting rod connecting slide 28. A further drive rod connecting slide 53 is guided in a parallel position opposite the rack 52. This forms a rack 54. The latter is assigned to the connecting rod connecting slide 53 in hook engagement 55 according to FIG. 10. In this way, the drive rod connecting slide 28, 53 are driven in opposite directions by the end gear 51 of the gear transmission. The aforementioned racks 52, 54 run on both sides of a section 37 ′ of the carrier plate 37 narrowed at the top.

The drive rod connecting slide 53 controls the interlocking with the interposition of a pivot lever 56 in such a way that first the connecting rod connecting slide 53 precedes the bolt exclusion and then the bolt 35 is taken along. As a result, only the locking members 5 can engage and bring about a tightening of the door, so that the locking bar 35 can then move freely into the striking plate recess facing it.

The bolt 35 has on its bolt tail 35 'a run-up slope 57 which extends obliquely to the direction of movement of the bolt 35. This is formed by a lateral elevation 35' '' of the bolt tail 35 '', which elevation 35 '' 'leads on the lock base 10. The elevation 35 '' 'is surmounted by a guide pin 58 which protrudes into a longitudinal slot 59 of the lock base 10 which extends in the direction of exclusion of the bolt 35. The run-up slope 57 is followed by a recess 60 for a control arm 61 of the pivot lever 56. The end of the control arm 61 is, as can be seen from the figures, shaped like a club.

The pivoted lever 56 which is mounted around a material-uniform pin 62 of the carrier plate 37 has on its side facing the connecting rod connecting slide 53 a toothed ring section 63, the teeth of which cooperate with a toothed strip 64 of the connecting rod connecting slide 53. The rack 64 is located on an extension 65 of the connecting rod slide 53 or the rack 54. This extension 65 extends with the bolt 35 closed in front of a locking edge 66 of the bolt tail 35 ″, cf. Fig. 9. The lower end edge 65 'of the extension 65 is also formed into an inclined flank which interacts with the ramp slope 57 in the manner described later.

The terminal tooth 63 'of the ring gear section is immersed in a recess 67 of the drive rod connecting slide 53 which is approximately extended in accordance with the advance of the connecting rod connecting slide 53. This is a take-away game. When the game is over, the extension 65 has also released the bolt shift.

It can be seen in particular from FIG. 18 that the width of the bolt tail 35 ″ corresponds approximately to that of the lateral elevation 35 ″ ″. The latter is slightly wider. In the closed position of the bolt, the bolt tail 35 ″ then overlaps the driven wheels 44, 45, which, however, are located on the opposite side of the carrier plate 37. The bolt tail 35 ″ extends in a cutout 68 of the carrier plate facing the lock base 10.

The pivot pin 70 of an actuating arm 71 of a change lever arrangement W is immersed in an arch slot 69 of the support plate 37 arranged below the bolt 35 concentrically with the axis of rotation M1. The actuating arm 71 is designed as a hook pawl pointing in the circumferential direction of the ring gear 39. For this purpose, the longer lever arm of the actuating arm 71 forms a hook 72 at the end, which is arranged in the same plane as a support ring shoulder 73 of the ring gear 39. In the basic position of the drive rod lock illustrated in FIG. 3, which basic position allows the installation of a profile locking cylinder, the hook 72 is supported on the support ring shoulder 73. The latter forms a counter hook 74 projecting into the path of movement of the hook 72. A rod-shaped intermediate member 75 of the change lever arrangement, which runs approximately parallel to the cuff 1, articulates on the shorter lever arm of the actuating arm 71 W on. The lower, angled, coupling pin-forming link end 75 'protrudes in the direction of the lock base 10 and extends in the path of movement of a control edge 76 of the drive rod connecting slide 28 which extends at right angles to the cuff 1. According to the basic position in FIGS Control edge 76 the end 75 'and thereby slightly pivots the actuating arm 71, which with its hook 72 comes against the support ring shoulder 73 of the ring gear 39. A leaf spring 77 clamped on the carrier plate 37 then acts on the end of the actuating arm 71 equipped with the hook 72. The same endeavors to keep the actuating arm 71 in a neutral basic position, in which the hook 72 lies outside the movement path of the counter hook 74 of the ring gear 39. Such a neutral basic position of the actuating arm 71 is shown, for example, in FIG. 16.

The upper end region 78 of the intermediate member 75 is plate-shaped and represents a plunger. An abutment 79 starting from the narrowed section 37 'of the carrier plate 37 and the opposite flank of the carrier plate section 37' serve to guide the end region 78. One end of the change lever spring 80 designed as a compression spring is supported on the abutment 79. The opposite end of the compression spring 80, on the other hand, is supported on laterally projecting shoulders 81 of the end region 78. The last thread turn located there continues via a bend 80 'into a spring wire 82 passing through the compression spring and loops above the abutment 79 with a fastening pin 83 one with three Poor equipped deflection member 84 of the change lever arrangement W. For the storage of the deflection member 84, one of the narrowed section 37 'is made of the same material outgoing pin 85. The fastening pin 83 is located on the free end of the first arm 86 of the deflection element 84. This forms a driving shoulder 87 above the end region 78, which lies in the path of movement of the end region 78 of the intermediate element 75. The spring wire 82 wrapping around the fastening pin 83 continues beyond the fastening pin 83 and forms a torsion spring section 82 'there loading the latch tail 33''. The change lever spring 80 fulfills the function of a latch spring due to its special design. Basically, the change lever spring 80 strives to displace the actuating arm 71 against the direction of the ring gear actuation area.

At a right angle to the first arm 86, a second arm 88 extends from the deflecting member 84, which projects between the fork tines of the forked latch tail 33 ″. Each tine of the forked latch tail 33 ″ each has a slot 89, 89 ′ which runs perpendicular to the direction of movement of the latch and which slots are offset from one another by the shifting movement. According to the exemplary embodiment shown, a pin 90 extends through the latch-side arm 88 of the deflection member 84 and establishes the driving connection to the latch 33.

In the retracted position of the latch 33, the pin 90 is aligned with a hole 91 in the lock cover 11. Then the pin 90 designed as a grub screw can be unscrewed and the latch 33 can be turned around its longitudinal axis, so that the screwed-in pin 90 with its projecting end in dips the slot 89 'of the other fork.

Crossing the slot 89, 89 ', a guide groove 92 is provided on each broad side of the latch tail 33' ', into which a guide projection 93 protrudes from the lock cover 11 and lock base 10.

The third arm 94 extends approximately diametrically opposite to the first arm 86 in order to engage a nut actuating slide 95. The latter is located in a space left by the carrier plate 37 within the lock housing 2 and is loaded by a return spring 96. Furthermore, the nut actuating slide 95 meshes with a nut 97 which is rotatably arranged in a two-part bearing housing 98 which is interchangeably inserted in the lock housing 2. Its length corresponds to a multiple of the nut diameter. The nut actuating slide 95 forms on the back a plurality of windows 99 for engagement of a tooth 97 ', the nut 97. In the exemplary embodiment, the tooth 97' engages in the lower two windows 99 arranged one above the other. The bearing housing 98 forms a fitting plate screw passage hole 100 arranged below the nut in the form of an elongated hole. This bearing housing 98 is designed with the nut 97 and the nut actuating slide 95 as a completely preassembled structural unit which can be inserted into a contour-matched recess A of the lock base and lock cover, in parallel extension to the narrowed support plate section 37 '. In the embodiment, this unit is set to a distance between the axis of rotation of the nut and that of the cylinder core to 72 mm.

13 shows a modified bearing housing 98 ', which can accommodate a nut 97 and the actuating slide 95 without modifying the same. Then the tooth 97 'of the nut engages in the upper window 99 of the Nut actuation slide 95 a. Below the nut bearing point, a fitting plate screw passage hole 100 'extends within the bearing housing 98'. The contour of the bearing housing 98 'can correspond to that of the bearing housing 98 described above, so that only the modified nut housing 98' has to be installed in order to change the distance between the locking cylinder and the nut. A spacing of 92 mm between the axis of rotation of the locking cylinder and the axis of rotation of the nut 97 is realized by means of the structural unit illustrated in FIG. 13. Further spacing dimensions would be possible by designing the bearing housing accordingly.

The basic positions of the nut are realized in a known manner by stops. Likewise, the rotary end positions of the nut stops are assigned, which are not dealt with in more detail.

The third arm 94 of the deflecting element 84 lying in the movement path of the nut actuating slide 95 is forked. The fork opening 33 '''is penetrated by the connecting rod connecting slide 53. The connecting rod connecting slide 53 continues into the area of the latch tail 33 ″ and merges into an angle leg 101 lying transversely to the cuff 1, which can be moved into the fork opening of the latch tail 33 ′. In the shifted-back position the latch travels with its fork opening over the angular section 102 of the connecting rod connecting slide 53 which runs parallel to the cuff 1 and which angular section 102 extends through the fork opening of the third arm 94. The angled leg 101 directed towards the cuff 1 has an arrow-shaped profile, cf. see in particular Fig. 4. The arrowhead is facing the trap 33, and the The latch head 33 'forms contour-like grooves 103 on both narrow sides. Seen in the direction of movement of the latch, the latch passage opening 34 of the cuff 1 corresponds to the outline shape of the latch head, which allows the latch 33 to be turned over by 180 °.

On the upper flank, the angled leg 101 forms a coupling projection 104 on its free front end, which protrudes into a recess 105 adapted to the cross section at the free end of the upper drive rod 3. A displacement of the connecting rod connecting slide 53 is therefore inevitably transferred to this connecting rod 3.

Since the angled leg 101 can step into the range of motion of the latch head 33 ', a smaller distance between the facing narrow side 6 and the latch 33 is sufficient, which permits a lower overall height of the lock housing. The fact that the end section E 'of the drive rod 4 can overlap the bolt 35 also contributes to this.

The upper rear edge of the lock edge of the lock housing 2 forms an approximately angular bulge 106. A contour-adapted corner angle 107 located between the lock base 10 and the lock cover 11 limits this bulge toward the rear narrow side of the lock housing. The end regions of the corner bracket 107 are provided with threaded bores 108, 109 which allow the connection to the lock cover 11 and the lock base 10. The bulge 106 framed by the corner bracket 107 forms a fitting shield screw through hole 110 with its rounded inner apex. One leg of the bulge 106 is oriented vertically and runs parallel to the cuff 1, while the other leg is at an acute angle is directed towards the cuff and extends in the upward direction.

The depth of the bulge 106 lying in the facing direction extends over the extension of the connecting line L of the nut 97 and the fitting screw passage hole 100, cf. Fig. 1.

If a door equipped with the illustrated espagnolette lock is provided with a long plate 111, shown in phantom in FIG. 1, this can be held by means of three screws 112, 113 and 114. The upper fastening screw 112 enters the bulge 106 and thus extends above the nut bearing point. The second fastening screw 113 passes through the fitting plate screw passage hole 100 of the bearing housing 98, while the third fastening screw 114 runs below the lock cylinder and the lock housing 2. This measure makes it possible, for example, to only loosen the central fastening screw 113 in order to then be able to remove the espagnolette lock. The long plates do not have to be dismantled for this, as is usually the case.

Another bulge 115 is provided in the area of the lower corner of the lock housing 2. This is formed by the rear contour of the carrier plate 37, which contour the castle ceiling 11 and the castle floor 10 are adapted in the corresponding area.

The bulge 115 extends to the rear of the lock cylinder 41. A depth of the bulge 115 is selected such that the bulge bottom 115 'of the lock cylinder longitudinal axis is closer than the distance between the lock cylinder longitudinal axis and this forend-adjacent forend screw passage hole 122. The backing plate 37 having this forms the bulge bottom with its rear narrow side wall, which runs obliquely towards the cuff 1. Finally, there is a third bulge 116 on the rear wall of the lock housing 2. The latter extends in the area rearward of the nut 97. The depth thereof pointing in the direction of the faceplate is at least so great that the bulge bottom 116 'is closer to the nut center than the distance between the nut center and the fitting screw passage hole adjacent to it, which is adjacent on the faceplate and which is held by the carrier plate 37 is designed as slot 120. The two aforementioned bulges 115, 116 allow the door to be assigned rosettes 117, 118 indicated by dash-dotted lines in FIG. 1 instead of the long plates in the area of the nut and the locking cylinder. One fastening screw 119 for the rosette 117 passes through the elongated hole 120 of the carrier plate 37, while the other fastening screw 121 penetrates the door in the region of the bulge 116. The elongated hole 120 and the bulge 116 also permit the use of differently shaped bearing housings 98 for the nut in order to be able to implement different spacing dimensions between the nut bearing point and the axis of rotation of the cylinder core.

A fastening screw 122 'which penetrates the through hole 122 of the carrier plate 37 and a fastening screw 123 which is arranged diametrically thereto and which runs in the region of the bulge 115 serve to hold the rosette 118 surrounding the locking cylinder.

Even if the rosettes 117, 118 are arranged, it is sufficient to fix the fastening screw opposite the bulge unscrew to remove the espagnolette lock.

The support plate 37 with the gear transmission and the change lever arrangement W and the bearing housing 98 represent structural units. If drive rod locks with different backset dimensions are to be created, these structural units need not be modified. Rather, it is sufficient to lengthen or shorten the castle floor and castle ceiling, while the rear area remains unchanged including the bulges. Corresponding reductions and extensions are then to be made for the bolt and the latch and the connecting rod connecting slide 28. Due to this slight change, however, a large range of differently designed locks can be manufactured combined with reduced production costs and reduced storage.

The following mode of action occurs:
3, the lock is in the basic position, which allows the locking cylinder 41 to be inserted. The key slot then does not align with the gap 42 of the ring gear 39. After installation of the locking cylinder 41 and removal of the key, the position of the ring gear 39 shown in FIG. 16 results. Along with the slight rotation of the ring gear 39, the reduction gear and the End wheel 51 of the connecting rod connecting slide 28 is shifted slightly in the downward direction, so that due to the spring loading the actuating arm 71 is pivoted counterclockwise in such a way that its hook 72 has come out of the path of movement of the counter hook 74 of the ring gear 39.

The latch can be withdrawn in the key withdrawal position when the bolt 35 is closed by actuating the lever handle. The nut 97 is pivoted into the position illustrated in FIG. 16 via the pusher (not illustrated). Their tooth 97 'shifts the nut actuating slide 95 in the downward direction. The third arm 94 of the deflecting element 84 lying in the movement path of the nut actuating slide is acted upon by pivoting the deflecting element 84 clockwise. The second arm 88 forming the latch arm pulls the latch 33 back via the pin / slot connection. During this pivoting of the deflection element 84, the change lever spring 80, which also serves as a latch spring, is tensioned. After the end of the pressurization, the nut 87 and the nut actuating slide 95 return to their stop-limited basic position. Furthermore, the change lever spring 80 guides the deflection member 84 into the starting position by relaxing.

The change lever operation is shown in Fig. 17. To do this, turn the ring gear 39 clockwise by pressing the key. At the same time, the end gear 51 is taken along via the gear transmission, which leads to an upward displacement of the connecting rod connecting slide 28, as a result of the tooth engagement. The control edge 76 of the connecting rod connecting slide 28 acts on the end 75 'of the intermediate member 75 accompanied by a pivoting of the actuating arm 71 in the clockwise direction, which pivoting is limited by the hook 72 resting on the support ring shoulder 73. By continuing to operate the key, the hook 72 and the counter-hook 74 come into contact with one another and entrainment of the actuating arm 71, the pivot pin 70 of which moves upward within the arch slot 69 of the carrier plate 37. This is accompanied by the pontic 75 carried in the upward direction. Its end portion 78, which forms a tappet, acts on the driving shoulder 87 of the first arm 86 of the deflection element 84. As a result, the deflection element 84 pivots and takes the latch 33 with it in the lock-in direction in the direction of the lock. During this process, the change lever spring 80 is charged. If the key is brought into the key withdrawal position after the door has been opened, the ring gear 39 rotates back by the appropriate amount. At the same time, the change lever spring 80 can relax, pivot the deflection element 84 counterclockwise and drive the latch 33 into its forward position.

The locking of the bolt 35 requires an opposite closing rotation. About the ring gear 39 and the reduction gear and its end wheel 51, the drive rod connecting slide 28, 53 are driven in opposite directions by meshing. The direction of movement of the connecting rod connecting slides 28, 53 is indicated in FIG. 9 by arrows. The drive rods 3, 4 with the locking members 5 attached to them are dragged along. As long as the extension 65 is in front of the locking edge 66 of the bolt tail, the bolt 35 cannot protrude. Accordingly, the pivot lever 56 does not change its position. This means that the connecting rod connecting slides advance with the connecting rods. After the niche 67 which allows the advance of the connecting rod connecting slides 28, 53 has passed, the terminal tooth 63 'of the ring gear section 63 is acted upon. Shortly before, the extension 65 has also released the locking edge 66 of the locking tail 35 ″. This is the case after turning a key. The locking of the bolt 35 therefore only begins when the door has been sufficiently tightened through the corresponding locking elements. Accordingly, the bolt can also dip into its associated striking plate recess without interference. During the further closing rotation, the pivoting lever 56 is then rotated via the tooth engagement while simultaneously taking the bolt into the pre-closing position illustrated in FIG. 18. After two locking rotations, the control arm 61 acts on a stop 124 of the carrier plate 37. In this pre-locking position, the key can be removed. Any push-back forces acting on the bolt are directed into the locking cylinder via the tooth engagement.

The locking of the bolt 35 takes place by means of an opposite closing rotation. Along with this, the drive rod connecting slides 28, 53 are driven in opposite directions in the opposite direction of the arrow via the end wheel 51 and the toothed rack engagement. After completing a closing rotation of approximately 540 °, the position shown in FIG. 19 occurs. Then the rack 64 comes out of engagement with the toothing of the pivot lever 56. Nevertheless, the bolt 35 is closed, since then the rearward displacement is taken over by the extension 65 by the lower, obliquely directed end edge 65 'acting on the run-up slope 57 of the bolt tail 35' 'and thereby forcing the backward displacement with simultaneous entrainment of the bolt 35. In the final phase of the return rotation, the extension 65 thereby again comes in front of the locking edge 66 of the bolt tail 35 ″.

The features of the invention disclosed in the above description, the drawing and the claims can be of importance both individually and in any combination for the implementation of the invention. All disclosed features are essential to the invention. In the disclosure of the application is hereby also included in full the content of the disclosure of the associated / attached priority documents (copy of the prior application).

Claims (20)

Locking cylinder actuable drive rod lock with a toothed ring (39) comprising the locking bit (43) of the locking cylinder (41), which has a locking cylinder push-through gap (42), and the outer circumference of which meshes with two output gearwheels (44, 45), the rotation of which, with the interposition of further reduction gearwheels, occurs Espagnolette connecting slide (28, 53) serves for displacing the espagnolette, and with a change lever arrangement (W) which is actuated by the ring gear (39) and can be actuated from the actuation area of the ring gear (39) when the bolt (35) is closed, for pulling back the latch (33 ) by means of the key, characterized in that the actuating arm (71) of the change lever arrangement (W) is spring-loaded against the direction of the sprocket actuating area and can be controlled in this area by a control edge (76) of the connecting rod connecting slide (28). Espagnolette lock, in particular according to claim 1, characterized in that the change lever spring (80) is also the latch spring. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the actuating arm (71) is designed as a hook pawl pointing in the circumferential direction of the toothed ring (39) which articulates and engages on a change lever intermediate member (75) leading into the latch area Operating position swivels behind a nose (counter tooth 74) of the ring gear (39). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the control edge (76) of the espagnolette connecting slide (28) engages in the region of the articulation point between the actuating arm (71) and the intermediate member (75). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the change lever spring (80) sits on the end region (78) of the intermediate member (75) and the interchangeable pushing movement of the intermediate member (75) via a change lever deflecting member (84) translated into the retraction movement of the trap (33). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the change lever spring (80) is designed as a compression spring and its end on the link side is non-positively connected to one arm (86) of the deflection member (84) such that it is actuated when the nut is actuated the trap (33) is tensioned. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the non-positive connection is formed by a spring wire (82) passing through the compression spring, which continues via a fastening pin (83) on the deflection member (84) into a catch tail (33 '') loading torsion spring section (82 '). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the spring wire (82) as a bend (80 ') of the last thread of the compression spring (change lever spring 80) is designed. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the end of the compression spring opposite the bend (80 ') is supported on a stationary abutment (79). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the abutment (79) is designed as a projection of a carrier plate (37) of the gear transmission. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the deflecting member (84) has a third arm (94) for engaging a nut actuating slide (95). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the nut actuating slide (95) is loaded in a free space of the carrier plate (37) by a return spring (96) and is in meshing engagement with the nut (97). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the nut (97) is arranged in a bearing housing (98) interchangeably inserted in the lock housing (2) and the nut actuating slide (95) has a plurality of windows (99) for one each Engagement of the tooth (97 ') has the nut (97). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the bearing housing (98, 98 ') forms the fitting plate screw passage hole (100 or 100') arranged below the nut (97). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the tail (33 '') of the latch (33) is forked and the arm (88) of the deflecting member (84) which engages on it projects between the fork tines. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the third arm (94) acted upon by the nut actuating slide (95) is forked and the espagnolette connecting slide (53) runs through the fork opening. Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the espagnolette connecting slide (53) can be moved into the fork opening of the latch tail (33 '') with an angle leg (101) lying transversely to the cuff (1). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the latch (33) moves in the rearwardly displaced position with its fork opening over the angular section (102) of the espagnolette connecting slide (53) running parallel to the cuff (1). Espagnolette lock, in particular according to one or more of the preceding claims, characterized in that the actuating arm (71) is of a fixed position Spring (77) is held in a neutral basic position. Espagnolette lock, in particular according to one or more of the preceding claims, characterized by a one-sided clearance between the deflection member (84) and the intermediate member (75) which occurs when the latch (33) is pushed back.

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