SE532158C2 - Lock with plunger - Google Patents

Description

53 30 ¶58 connected to, for example, the locking piston of the lock to allow the door to be opened with a simple push of an emergency opening pressure or a panic opening rod.

For example, in the case of evacuation doors, it may be desirable to be able to arrange a drop-down piston included in the lock when the door has been opened by means of the evacuation accessory. Such a function significantly increases personal safety in the event of a fire, for example. If a person who has moved out through an escape door discovers that the road outside the door is not passable, it can be vital for the person to be able to turn around and re-enter through the door from its outside. Such re-entry is possible if the piston is set up.

In prior art drop locks of the type comprising a displaceable drop piston, positioning of the drop piston can be effected manually by adjusting a button on the locking post, by using a special setting key which is inserted through the locking post or by adjusting the lock by means of a competent key which inserted into the lock cylinder. All of these previous ways of achieving set-up of the drop piston are relatively cumbersome and time consuming. They require, for example, that the door is open and that the plunger is pressed in with a finger or the like to enable the erection. Admittedly, such adjustable drop locks are also mounted at escape doors, but due to the cumbersome set-up maneuver, they are neither suitable nor intended to allow the fall piston to be set up in an emergency escape or in panic situations. These types of adjustable drop locks can, on the other hand, be useful in many other applications. However, even with other types of doors than evacuation doors, there may also be a need to make it easier and faster than previously possible to arrange the installation of one or more drop pistons included in the lock.

Brief Description of the Invention An object of the present invention is therefore to provide an improved fall lock. Another object is to provide such a lock which allows easy and quick installation of the drop piston. Another object is to provide such a lock where positioning of the drop piston is effected automatically when the lock is operated for opening with one of the accessories connected to the lock.

These and other objects are achieved with a drop lock of the type stated in the preamble of claim 1 and which has the features stated in the claim. Fall locks according to the invention are intended for doors, gates, window doors, windows and the like. The lock is especially suitable for use with interior escape doors. The drop lock comprises a drop piston which is adjustable between a restraining and a non-restraining condition, a first rower which is coupled to the drop piston and operable to change the drop piston to the non-restraining position by means of a first actuator, and a second rower which is connected to The plunger and operable to convert the plunger to the non-adherent condition by means of a second actuator According to the invention, the latch also includes a third rower, by means of which the second rower is connected to the plunger for converting the plunger from the adherent to the non-adherent condition. and a locking means configured to releasably, in engagement with the third rower, lock the third rower in a rotational position corresponding to the non-adherent condition of the plunger, to effect positioning of the plunger in the non-adherent condition. 10 15 20 25 30 532 fifi ß The fall lock according to the invention thus provides automatic aiming of the fall piston when the lock is operated with an accessory which is connected to the second rower. For example, if the fall lock is located at an emergency evacuation door and the other rower is connected to a panic evacuation accessory such as a panic opening bar, the drop piston will be set up automatically as soon as a person vacates the room using the panic evacuation accessory. If the person, when leaving the room, discovers that the escape route on the outside of the door is blocked, he or she can then reopen the door from the outside and look for another escape route. Thus, by equipping evacuation doors with a trap lock according to the invention, personal safety is significantly increased when using the evacuation door. Although the drop lock according to the invention is particularly suitable for use with escape doors, the invention of course also finds advantageous use also with other doors or the like where it is desirable to easily achieve automatic positioning of the drop piston when it is operated with it, one or more of the accessories are connected to the piston.

The first rower suitably comprises a release surface which, while rotating the first rower, in contact with the locking means brings the locking member out of engagement with the third rower. In this way, a simple reset of the plunger from the set-up to the existing condition is achieved.

The first rower can, for example, be connected to a locking cylinder, whereby the drop piston is reset by using an authorized key.

The first rower is suitably designed so as not to engage in locking engagement with the locking means when the first rower is operated to retract the drop piston. As a result, the drop piston is not set up when the lock is operated by means of the first rower. If, for example, the drop lock is arranged at an emergency evacuation door and the first rower is operated with a locking cylinder, no set-up of the drop piston takes place if a person with a competent key opens the door during normal passage which does not occur in an emergency.

The first and third rowers are suitably arranged axially in line with each other. This enables a compact and space-saving design of the drop lock.

The first rower, the second rower and the locking means are suitably arranged in an integrated module unit. Such a modular unit allows the automatic set-up function to be easily integrated in many different types of drop locks. The modular unit also makes it easier to subsequently achieve an automatic set-up function, even for locks that were not initially equipped with one.

The drop piston can be slidable between an extended position corresponding to the adhering state and a retracted position corresponding to the non-adherent state, the drop piston being biased in the direction of the projecting position.

The locking means then suitably comprises a number of locking steps, each of which, in engagement with the third rudder, releasably locks the third rudder in a respective rotational position which corresponds to a correspondingly retracted position of the drop piston. This ensures that the set-up piston is set up even if the door has been opened after only a partial retraction of the drop-down piston. If, for example, the door gap between the end plate and the locking post is relatively large, the door can be opened even if, for example, an emergency evacuation pressure connected to the drop piston is not pressed down to the fully depressed position. The drop set according to this embodiment ensures positioning of the drop piston also in this case. The locking means may alternatively comprise a single locking step and means for causing rotation of the third rudder to a position corresponding to a substantially fully retracted position of the drop piston, when the third rudder has been turned into engagement with the locking step in a rotating position which corresponds to a partially retracted position for the drop piston. Even with this embodiment, it is thus ensured that the positioning of the drop piston is ensured even if the door has been opened after, for example, an emergency evacuation pressure has only been partially depressed.

The drop lock may also or alternatively comprise a pivot axis about which the drop piston is rotatable between a first rotation position and a second rotation position, and a locking device which is arranged to releasably lock the drop piston in the first rotation position, the drop piston being in its adherent condition when is locked in the first turning position and wherein the third rower is connected to the locking device.

The drop lock may also comprise a fourth rower which is manoeuvrable by means of a third actuator. The fourth rower can then be connected to a second plunger. The fourth rower may also or alternatively be coupled to the second or third rower to provide positioning of the first plunger as it is operated by the third actuator. It is also possible for the fourth rower to be connected to the first rower to effect retraction without setting up the first piston.

The drop lock is suitably arranged at an emergency evacuation door, wherein an evacuation accessory, such as an emergency evacuation pressure or a panic evacuation pressure rod, is connected to the other rower. A locking cylinder is then suitably connected to the first rower.

Further objects and advantages of the invention will become apparent from the following detailed description of exemplary embodiments and from the claims. Brief description of the figures In the following, exemplary embodiments of the invention will be described with reference to the figures, of which: Fig. 1 is a perspective view according to a first embodiment of the invention with certain parts removed.

Fig. 2 is an exploded view in perspective and on an enlarged scale of a part included in the drop lock shown in Fig. 1.

Fig. 3 is a plan view on a reduced scale of the part shown in Fig. 2.

Figs. 4a-e are plan views corresponding to that of Fig. 3 and show the part in different position states.

Fig. 5 is a plan view on an enlarged scale corresponding to that of Fig. 3 and shows a second embodiment of the part shown in Fig. 3.

Fig. 6 is a perspective view of a drop lock according to another embodiment of the invention with certain parts removed.

Fig. 7 is a perspective view of some of the parts included in the drop lock shown in Fig. 6.

Detailed description of embodiments Fig. 1 shows an embodiment of the case according to the invention. The lock comprises a locking post 1, at which a lock housing 2 is arranged. In the figure, for increased clarity, only the lock housing bottom and parts of the side walls are shown. A first drop piston 3 extends through a recess in the locking post 1.

The drop piston 3 is connected at its rear end to a bange 4.

The drop piston 3 and the bang 4 are together axially displaceable between a position retracted in the lock housing and an extended position shown in the figure. The bang 4 is for this purpose guided in a U-shaped guide member 5 which is fixed to the locking post 1. The bang has a waist portion 6 with two radial surfaces 6a. A double-arm pivot rod 7 is arranged rotatably about a shaft 8 which is fixed in the bottom of the lock housing. One end of both arms of the swivel rod 7 is received between the radial surfaces 6a of the bang, on each side of the center axis of the bang. The other ends of both rotating rods 7 are connected to one end of a push rod 9.

The other end of the push rod 9 is connected to a first module unit 10, which will be described in more detail below. A torsion spring 17 is arranged around the axis of the pivot rod 7. A first end (not shown) of the torsion spring 17 bears support against the inside of the locking post 1. The other end of the torsion spring 17 (not shown) abuts against the radial surface 6a arranged closest to the drop piston 3. The torsion spring 17 is arranged to bias the bang 6 and the drop piston towards the extended position shown in Fig. 1. By axially displacing the push rod 9 in the direction of the locking post 1, the pivot rod 7 is rotated about the axis 8, counterclockwise in the figure. The ends of the pivot rod 7 arranged at the bang 6 then press, during abutment against the inner radial surface 6a of the bag 6, the bang 6 and the drop piston 3 in the direction of the retracted position. When a displacing force acting on the push rod 9 in the direction of the locking post 1 ceases, the torsion spring 17 causes the bang 6 and the drop piston 3 to be returned to the extended position shown in Fig. 1. In this case, the pivot rod 7 and the push rod 9 are also brought to their respective positions shown in Fig. 1. The fall lock further comprises an evacuation rudder 11, with a central through-going square hole to which an evacuation accessory, such as an emergency opening pressure or a panic opening rod, can be connected. The evacuation rudder is connected by means of a coupling rod 12 to the first module unit.

The embodiment of the drop lock shown in Fig. 1 also comprises a second drop piston 13 with a bang 13a. The second drop piston 13 with its bange 13a is connected to a second module unit 14 by means of a coupling device which corresponds to the above-described coupling between the drop piston 3 and the first module unit and which is not described in more detail here. The second module unit 14 comprises a rower 15 with a square hole to which an actuator, such as a pressure or the like, can be coupled for actuating the second piston 13.

With reference to Fig. 2, the first module unit 10 is described in the following. The module unit 10 comprises an upper 21 and a lower 22 housing part which together form a modular housing. The upper and lower housing parts each have a through opening Z1a, 22a which each opens into a cylindrical recess 23 arranged inside the module housing. The housing parts 21, 22 also have first laterally recessed recesses 21b, 22b which together form a channel 24 in which the other end of the push rod 9 (see Fig. 1) is axially displaceably received. The housing parts 21, 22 also have other laterally arranged recesses 21c, 22c which together form an opening 25, in which a locking member 30 is arranged.

The locking member 30 is slidably arranged in the opening 25, the displacement movement being rectilinearly controlled by means of the walls of the recesses 21c, 22c. A bent leaf spring 32 is fixed at one end to the module housing. The other end of the leaf spring 32 abuts against an abutment surface 33 of the locking member, for biasing the locking member 30 in the inward direction, against the cylindrical recess 23. The locking member 30 further comprises a number of locking steps 34 arranged on, in direction towards the cylindrical recess 23, projecting teeth 36. On the side of each tooth 36 opposite the locking steps, an inclined sliding surface 37 is arranged. An abutment surface 35 is also provided on the locking member, below the teeth 36, which abutment surface faces inwards towards the cylindrical recess 23.

A first rudder 40 is rotatably received in the cylindrical recess 23. The first rudder 40 has a central opening with radially inwardly projecting coupling means 41 for co-operation with corresponding coupling means on a first operating means (not shown). The first operating member can for instance consist of a locking cylinder which by means of a competent key can be turned from the outside of the door or the like at which the drop lock is arranged. It will be appreciated that the first actuator may also be any other accessory, such as a knob, a push, a motor driven or a solenoid driven accessory. The first rower can also be connected to actuators arranged on either or both sides of the door.

The first rower 40 comprises a radially outwardly projecting first actuator arm 42. The first actuator arm 42 is arranged so as to intersect the axial extension of the channel 24. When the first rudder 40 is rotated clockwise according to Fig. 2, the first actuator arm 42 comes into abutment against the end of the push rod 9 facing the module unit 10 (see also Fig. 1).

Continued rotation clockwise, the push rod 9 is pressed in the direction of the locking post 1, whereby the drop piston 3 is displaced towards its retracted position, as described above. Hereby it is thus possible to effect displacement of the drop piston 3 in the direction of its retracted position by, by means of a first actuator, turning the first rudder with a force which overcomes the biasing force of the torsion spring 17.

The first rudder 40 also comprises a release surface 43 which, during clockwise rotation, comes into contact with the corresponding abutment surface 35 of the locking member. Continued clockwise rotation presses the locking member 30, against the biasing force of the leaf spring 32, in a direction outwards from the cylindrical opening 23.

The evacuation rower 11 shown in Fig. 1 constitutes a second rower in the example illustrated here. This second rower 11 is connected by means of the second push rod 12 to a carrier 50 which is guided axially displaceably received in the module housing. The carrier 50 has at its one end coupling means 51 for coupling to the coupling rod 12.

At its other end, the carrier has a projecting pin 52.

The module unit 10 also comprises a third rudder 60 which is arranged in the cylindrical recess 23, axially aligned with the first rudder 40. The third rudder 60 has a central axial through recess 61 to thereby allow interconnection of a, on it to the the first rower 40 opposite the side of the third rower 60, arranged actuator (not shown). The third rudder 60 comprises a second radially projecting actuator arm 62 and a radially projecting locking arm 63 relative to this angle.

A spacer 70 is also provided in the cylindrical recess 23, axially aligned with the second 40 and third 60 rudders. The spacer 70 also has a central axial opening 71 through which it allows interconnection of an actuator with the first rower 40.

Fig. 3 shows a schematic view of the module unit 10. In Fig. 3 the spacer 70 is mounted with most of the first 40 and second 60 rudders obscured. The carrier 50 is connected to the module unit 10. As can be seen most clearly from Fig. 4a-e, where the spacer is removed, this connection is effected by the pin 52 of the carrier 50 being received in the radial recess 64 of the third rower and cooperating there with the one of the 64 side walls of the recess. When the carrier 50, by means of the second rower 11 and the coupling rod 12 (Fig. 1), is given an axial displacement in the direction of the arrow A, the pin 52 engages with the lower radial wall of the radial recess 64 in the outer mantle surface of the third rower 60. The third rower 60 is thereby imparted a rotational movement in a clockwise direction according to the figures. The second actuator arm 62 of the third rower then presses the push rod 9 schematically shown in Fig. 3 in the direction of the locking post 1. The push rod 9 then causes retraction of the drop piston 3, as described above. In this way the retraction of the drop piston 3 is thus effected by means of actuation of, for example, an evacuation accessory which is connected to the second rower 11.

With reference to Figs. 4a-e, it is described in the following how the set-up and release of the drop piston 3 is effected in the exemplary embodiment of the invention shown in the figures. In Figs. 4a-e, the push rod 9 has been removed for increased clarity. The first rower 40 is largely obscured by the third rower 60. However, the coupling means 41 of the first rower can be seen and in Fig. 4c its actuator arm 42 can also be seen. Fig. 4a shows an initial position for the first 40 and third 60 the rower and for the locking means 30 and the carrier 50. The figure shows the channel 24 in which one end of the push rod (not shown in Figs. 4a-e) is slidably received. When an actuator coupled to the second rower, such as an emergency evacuation accessory, is activated with a force which overcomes the biasing force of the torsion spring 17 (Fig. 1), the carrier 50 is imparted a downward displacement. The second actuator arm 62 of the third rower 60 is thus rotated to the position shown in Fig. 4b, whereby the drop piston 3 is pulled in from its fully extended position a corresponding distance as described above.

During this rotational movement of the third rudder 60, the locking arm 63 comes into contact with one after the other of the sliding surfaces 37 on the teeth 36 of the locking member. the actuating force on the actuator ceases in the position shown in Fig. 4b, the biasing force of the torsion spring 17 will strive to return the drop piston 3 to its extended position.

The force of the torsion spring 17 will also act on the push rod 9 which in turn in contact with the second actuator arm 62 strives to turn the third rower 60 in a counterclockwise direction towards the initial position. In this case, however, the tip of the locking arm 63 will be brought into engagement with the locking step 34 at which the locking arm is currently located. In this way, the continued rotation of the third rower in the counterclockwise direction is blocked, whereby also the push rod 9 as well as the drop piston are prevented from being returned to their respective initial positions. As a result, an arrangement of the drop piston 3 has been achieved in a partially retracted position.

Especially if the door gap between the frame and the door at which the lock is mounted is large, this arrangement in a partially retracted position brings a considerable advantage. With such doors, it is possible to open the door even if the piston has not been fully retracted. There is thus a risk that a person pressing the emergency evacuation device stops pressing as soon as the door is opened, whereby the plunger does not reach its fully retracted position. With the plurality of locking steps arranged on the locking member according to the embodiment shown in Figs.

If, instead, the actuating force continues to act on the actuator at the position shown in Fig. 4c, the third rower 60 is provided with a continued clockwise rotation, whereby further retraction of the drop piston is effected. Such rotation can, for example, continue to the position shown in Fig. 4c, which corresponds to a fully retracted position of the drop piston. In this position the locking arm 63 has passed the sliding surfaces of two further teeth 36. When the actuating force ceases, the force of the torsion spring 17 acts, as in the position shown in Fig. 4b, on the push rod 9 and the third rower, the locking arm 63 being engaged corresponding to the locking step on the locking member 30. This thus provides the positioning of the drop piston in a substantially fully retracted position.

Figs. 4c-e illustrate how the drop piston is disengaged from the set-up positions shown in Figs. 4b-c. Such disengagement is accomplished by operating the first rower 40. When its actuator, such as a locking cylinder, a force is applied which rotates the first rower clockwise according to the figures. The release surface 43 of the first rower 40 comes into contact with the abutment surface 35 of the locking member. Continued rotation of the first rudder 40 then presses the locking member 30, against the biasing force of the leaf spring 32, in the outward direction from the cylindrical recess 23. This releases the engagement between the locking arm 63 of the third rower and the locking step 34 of the locking member. the first rower has taken the fully rotated leg shown in Fig. 4d, the first actuator arm 42 of the first rower 40 is arranged substantially parallel to the second actuator arm 62 of the third rower 60. Both actuator arms 42, 63 are then in contact with the end of the first towing arm 9. When the actuating force on the first rudder 40 ceases, the force from the torsion spring 17 by means of the first push rod 9 presses the two actuator arms 42, 62 and thus their respective rudders 40, 60 during counterclockwise rotation back towards the initial position. As can be seen from Fig. 2, the release surface 43 of the first rower 40 is designed to ensure that the locking member 30 is kept in the extruded position until the locking arm 32 has passed all the locking steps 34.

With the embodiment described above, a simple reset of the drop piston to a non-set condition is thus effected, for example by means of a competent key which is inserted into a locking cylinder connected to the first rower. It should be noted that in the embodiment described above, the first rower is designed so that it does not engage the locking steps 34. In normal operation of the locking piston by means of an actuator connected to the first rower, no positioning of the piston takes place.

In the embodiment shown in Fig. 1, the rower 15 constitutes a fourth rower. In the example shown, this is coupled to the coupling rod 12 in such a way that a displacement movement of the coupling rod 12 is transmitted to a rotational movement of the fourth rower 15, but a rotational movement of the fourth rower 15 is not transmitted to a displacement movement of the coupling rod 12. For example, when a pressure connected to the fourth rower is pressed down, the second drop piston 13 will thus be retracted, on the other hand, the first drop piston 3 is not affected. If, on the other hand, the lock is operated with an accessory coupled to the second rower 11, both the first 3 and second 13 pistons are pulled in. In the illustrated example, the radial recess 64 of the third rower 60 is further formed so that the pin 52 of the carrier can move freely between the radial walls of the recess 64, which are arranged at a certain distance from each other. This allows the carrier 50 and thus the coupling rod 12 to be displaced even when the third rower 60 is in locked engagement with the locking member 30. This does not set up the second drop piston 13 when the locking arm 63 is in engagement with the locking step 34 of the locking member 30.

In the case of fire-rated evacuation doors, for example, for fire safety reasons, it is desirable that the second drop piston, even when the first drop piston is set up, causes the door to be locked in the closed position. In order to allow easy re-entry, in this case the fourth rower should be connected to accessories, such as the pressure on both sides of the door. It will be appreciated that, if desired, it is of course possible to design the drop lock so that the second drop piston 13 is also positioned when the first drop piston is set up. Furthermore, it is understood that through another interconnection between the fourth rower 15 and coupling rod 12 it is also possible to allow operation of the first plunger 3 by means of the fourth rower 15.

Fig. 5 shows an alternative embodiment of the module unit 10 '. This embodiment differs from the one described above mainly in that the locking member 30 'is formed with only one locking step 34'. This locking step 34 'is inclined and has a lower locking surface against which the locking arm 63 of the third rower 60 can slide. The locking member 30 'also has a knee 38' which merges at the top into the locking step 34 '. The leaf spring 32 'in this embodiment is suitably designed with a higher spring constant. The knee 38 'is arranged relative to the third rower so that, when the third rower has been rotated a certain distance corresponding to a certain retraction of the drop piston 3, the tip of the locking arm passes the knee 38' and comes into sliding abutment against the locking step 34 '. The strong leaf spring then presses the locking member 30 'in the inward direction, the sliding contact of the locking arm 63 with the inclined locking step 34' forcing the third rower to continue turning clockwise until the plunger is fully retracted. Thus, even in this embodiment, positioning of the plunger is ensured even if the second rower 11 has not been turned to a position corresponding to the fully retracted position of the plunger. In this embodiment, in contrast to the one described above, the drop piston will be automatically retracted to the fully retracted position, in which position it will also be set up. Release of the set-up position is achieved in this embodiment in the same way as described above, by means of the first rower.

Fig. 6 shows a drop lock according to another embodiment of the invention. As with the drop lock shown in Fig. 1, this drop lock comprises a first 120 and a second 13 'drop piston.

The lock also comprises a first module unit 10 'which in the example shown is identical to the module unit 10 in Fig. 1. The drop lock shown in Fig. 6 also comprises, like the lock according to Fig. 1, an escape rower 11' and a second module unit 14 'for operation of the second piston 13 '.

The drop lock shown in Fig. 6 differs from the lock according to Fig. 1 in that the first drop piston 120 is rotatable about an axis which is substantially parallel to the locking post 1 '. The drop piston 120 is part of a drop piston module 100 which is connected to the first module unit 10 'by means of a push rod 9'. Fig. 7 shows some of the parts included in the piston module in more detail. In Fig. 7, the plunger module is seen from a different direction than in Fig. 6. The plunger 120 is connected to a bange 130 and together with it axially displaceable relative to a base plate 110 of the plunger module. The plunger is further rotatable about an axis 121 relative to the bungee 130. The plunger module also includes a rake 140 with an actuating arm 141. The rudder 140 is connected by means of intermediate moving parts 160, 170, 180 to the rake 120. When the rudder is in the position shown in Fig. 7, the parts 160, 170 and 180 are locked at their positions shown in the figure.

Thus, the drop piston 120 is also prevented from rotating about the shaft 121. The drop piston 120 is then in an adjacent condition. The locking rudder 140 is biased by means of a torsion spring towards the locking position shown in Fig. 7, the falling piston normally assuming the adhering condition. When the drop piston is to be adjusted to its non-adherent condition, in order to allow the opening of the door at which the lock is arranged, the ratchet 140 is caused to turn clockwise in Fig. 7.

The parts 160, 170 and 180 thus become free to move, whereby the drop piston 120 can also rotate around its axis 121. If a force is applied to the door in the opening direction, the drop piston thus comes into contact with an end plate (not shown) in, for example, the door frame , to rotate about the axis 121.

The normally adjoining side of the drop piston is then tilted relative to the end plate, the end plate being acting on the drop piston with a force which causes the drop piston 120 and the bang 130 to be displaced axially to the right in Fig. 7.

The drop piston thus assumes its non-adherent position and allows the door to be opened if a force in the opening direction is applied to it. This type of rotatable drop piston is described in more detail in Swedish patent application no. 0800251-1 with the same applicant as for the present application. The content of the Swedish application no. 0800251-1 is hereby incorporated by reference into the present application.

To enable positioning of the rotatable drop piston 120, the operating arm 141 of the rudder 140 is connected via the push rod 9 'to the first module unit 10'. In the example shown, the push rod 9 'is identical to the push rod shown in Fig. 1. Operation and positioning of the drop piston 120 is effected by means of the evacuation rudder 11 'and the first and second rudders included in the first module unit 10' as well as the locking means, in a manner corresponding to the method described above.

Exemplary embodiments of the invention have been described above. It is to be understood that the invention is not limited to this exemplary description but that it may be varied freely within the scope of the appended claims. For example, the first and second rowers may be connected to any type of actuator, also including, for example, electrical ones. Furthermore, the number of rowers and actuators as well as the number of pistons can be varied. In addition to one or more drop pistons, the lock may also comprise one or more bars, also including espagnolette bars.

Claims (14)

10 15 20 25 30 532 153 20 Requirements A fall lock for doors, gates, window doors, windows and the like, comprising - a piston (3, 120) which is adjustable between an adherent and a non-adherent condition - a first rower (40) which is connected to the piston and manoeuvrable for adjusting the piston to the non-adherent position by means of a first actuator, and - a second rudder (ll, ll ') which is connected to the drop piston and manoeuvrable for converting the piston to the non-adherent state by means of a second actuator, characterized by - a third rower (60) by means of which the second rower is coupled to the drop piston for converting the drop piston from the adherent to the non-adherent state, and - a locking means (30, 30 ') designed to be releasable in engagement with the third rower lock the third rudder in a rotational position corresponding to the non-adherent condition of the piston, to position the piston in the non-adherent position state. A fall lock according to claim 1, wherein the first rower (40) comprises a release surface (43) which, while rotating the first rower, in contact with the locking member (30, 30 ') disengages the locking member from the third rower (60). ). A fall lock according to any one of claims 1-2, in which the first rower (40) is designed so as not to engage in locking engagement with the locking means (30, 30 ') when the first rower is operated to retract the drop piston. Fall lock according to one of Claims 1 to 3, in which the first (40) and third (60) rowers are arranged axially in line with one another. 10 15 20 25 532 158 21 A fall lock according to any one of claims 1-4, wherein the first rower (40), the third rower (60) and the locking means (30, 30 ') are arranged in an integrated module unit (10, 10'). A fall lock according to any one of claims 1-5, wherein the drop piston (3) is slidable between an extended position corresponding to the adhering condition and a retracted position corresponding to the non-adherent condition, the drop piston being biased in the direction of the projecting the situation. A fall lock according to claim 6, wherein the locking means (30) comprises a number of locking steps (34) each of which, in engagement with the third rower (60) releasably locks the third rower in a respective rotational position corresponding to a corresponding degree retracted position of the piston (3). A fall lock according to claim 1, wherein the locking means (30 ') comprises a locking step (34') and means (32 ') for effecting rotation of the third rower (60) to a position corresponding to a substantially full retracted position of the plunger (3), when the third rower has been turned into engagement with the locking step in a position of rotation corresponding to a partially retracted position of the plunger. A fall lock according to any one of claims 1-5, comprising a rotation shaft (121) about which the drop piston (120) is rotatable between a first rotation position and a second rotation position, and a locking device (140, 160, 170, 180) arranged to releasably locking the plunger in the first rotational position, the plunger being in its prior state when locked in the first rotational position and the third rower being coupled to the locking device. 10 15 532 158 22 A fall according to any one of claims 1-9, comprising a fourth rudder (15) operable by a third actuator. Fall trap according to claim 10, in which the fourth rower (15) is coupled to a second piston (13, 13 '). A fall according to claim 10 or 11, wherein the fourth (15) rower is coupled to the second (12) or the third rower (60) to provide positioning of the first plunger (3) when it is actuated by the third actuator. . A door comprising a drop lock according to any one of claims 1-12, and a space accessory connected to the second rower. A door according to claim 13, comprising a locking cylinder coupled to the first rower.