NO319507B1 - Lasmekanisme - Google Patents

Abstract

A lock mechanism includes a lock bolt mechanism (6), for instance a key actuated mechanism, having a lock bolt (20a) and a latch bolt mechanism (4) including a latch bolt (9) and actuated by a follower lever (17). Movement of the lock bolt (20a) between its terminal positions is generated and stepped-up, or geared, through the medium of a connecting rod (24) and a transmission lever (22). The mechanism also includes a locking lever (32) and a coupling lever (27) and a dogging lever (31) by means of which the follower lever (17) of the latch mechanism (4) can be actuated to retract the latch bolt (9), for instance by turning a key. The lock mechanism is constructed in accordance with a module system for adaptation to different backsets and centre distances, cylinder/knob. The lock mechanism is adapted to suit differing backsets by using one or more connecting rods (24) having one or more alternative points (24a) of pivotal attachment to the transmission arm. The remainder of the lock bolt mechanism remains essentially unchanged when making such adjustments, possibly with the exception of the coupling lever (27). With regard to the latch bolt mechanism, a press rod (10) having a length commensurate with a relevant backset is exchangeably mounted in position while the remainder of the latch mechanism (4) remains essentially unchanged. Quick-release levers (39) of different lengths commensurate with different cylinder-knob centre-to-centre distances can be exchangeably mounted on a pivot shaft (38) in the region of the edge of the lock housing distal from the latch and lock bolts.

Description

The invention generally relates to a lock comprising a drop mechanism and a latch mechanism.

The drop mechanism in such locks is usually affected by a button or similar knob by means of a drop tube and a drop tube arm. The latch mechanism comprises a latch which is often acted upon by a cylinder lock from the outside of the door where the lock is mounted, and by means of a button or similar device from the inside of the door. The pulley mechanism can also be affected in other ways, e.g. using a cylinder lock on both sides of the door together with a quick release feature.

One or both locking mechanisms are often adapted to motor operation, in which case the bolt and latch or only one of them can be moved to their locked position and/or open position in response to a start signal to the motor. Motor-driven locking mechanisms are also known which can only be opened or closed by the motor.

Different countries have different standards regarding the number of times a key must be turned in a lock ft)T that the pulley mechanism, e.g. a real one, must have full effect. Swedish and other Nordic standards require the key to be turned only once, for which purpose driver devices in the cylinder lock and the button turner respectively affect the bolt or the catch by means of an exchange mechanism that reinforces the driver device's movement. It is thus necessary to ensure that, upon completion of a locking movement, the rail will be placed in a carefully defined position so that, e.g. after removing the key from the lock and then reinserting the key, the driver device in the cylinder lock is able to engage in the intended position, which will not be the case if the pulley mechanism has been able to take an intermediate position in the meantime. This problem is particularly relevant with motor-driven locks or locks that are equipped with a quick-release function.

The standards in other countries require the key to be turned twice to give the reel full extension. In this way it is possible to "half-lock", that is to remove the key after only one turn of the key, while "locking for the night" can be performed by turning the key two turns.

Other problems are that locks that are used for different purposes and i

different connections must necessarily have different so-called keyhole distances and different center distances between buttons

twists and the cylinder core. Different countries also have different standards for such depths and center distances, and it should be understood that the adaptation of a lock to satisfy different standard measurements often requires the rebuilding of vital parts of the lock, especially when it is also necessary to adapt the pulley mechanism so that the pulley will have full results in just one turn of the key.

The work in connection with adapting locks to satisfy different standards is complicated by the fact that other special requirements and wishes are often placed on lock constructions of the type in question here, e.g. that the locking structure must be off

such a type that after locking the reile-

the mechanism with the cylinder lock's key must also be able to lock the case by continuing to turn the key.

In some cases, locks intended for public premises and local entertainment establishments, such as cinemas, etc., must have some form of quick release mechanism. E.g. it is conceivable that a locking mechanism where the bolt is locked from the outside must be able to be opened in response to a single button or twist movement from the inside of the door, e.g. in an emergency. The quick-release function requires a different type of connection device between the drop mechanism and the pulley mechanism. The adaptation of locks to meet different standards for keyhole spacing and center distances in accordance with the above is associated with difficulties with regard to the construction of locking mechanisms where the aforementioned separate functions can be achieved.

An article entitled "Schlage Mortise Locks" on pages 23-27 of the May 1993 issue of "The National Locksmith" describes a number of characteristic features of a lock of the type in question, and also a number of tests performed on the lock. Among other things, mention is made of the possibility of changing the locking side of the locking unit without taking the lock apart. This change can be made by moving a screw from one side of the lock housing to the other.

The structure of the lock is relatively complicated and comprises a number of components. The article does not describe how this lock construction can be easily adapted to a changed or standard keyhole distance and center distance between knob turner and cylinder lock, and it should be understood that the compact design of the lock mechanism would require drastic remodeling of the mechanism as a whole by e.g. reduction of keyhole distance a.

DE-A1-34 00 618 (Karrenberg), DE-C2-30 37 018 (Fliether) and EP-Al-0 535 497 (C.I.S.A.) describe locking structures of the type to which the present invention relates, while the latter publication also describes a locking mechanism which includes a quick release feature. None of these publications, however, suggest a constructive procedure to change the keyhole spacing and/or center spacing for button-actuated cylinder locks.

Other examples of the state of the art appear in US-A 4,516,798 (Bergen), US-A 4,671,089 (Fleming, et al), DE-Al-3,540,848 (Schindler) and DE 2458628 (Sommer).

The present invention relates more specifically to a lock with a locking mechanism of the type specified in the introduction to claim 1.

A basic idea of the invention is to construct a locking mechanism of this type according to a modular concept, and more specifically a concept where the main part of the locking mechanism's components will remain unchanged during adaptation of the locking mechanism to different keyhole distances, while some of the locking parts must be easily replaced and adapted to facilitate keyhole spacing changes.

The inventive basic idea also includes the possibility of fulfilling one or more of the above-mentioned special requirements placed on a locking mechanism of this type, e.g. such requirements as that locking can be achieved with a single turn of the key and functional adjustments to adapt the lock to various special wishes or requirements, such as that the fall must be able to be influenced with the lock's key, and that the lock must be able to be released quickly using the button or the twister, etc.

One purpose of the invention is therefore, following a modular system, to construct a locking mechanism which can be easily adapted to different keyhole distances.

Another purpose is to provide a locking mechanism where an impact by a single turn of the key on the cylinder lock makes it possible to activate a drop function via the cylinder lock, and when it is desired or required a quick release function to retract the reel using the button or the twister.

A further purpose of the invention is to produce a locking mechanism of the above-mentioned type where, in a preferred embodiment, it is ensured that the rail will be placed in its open or retracted position when the cylinder lock's driver device approaches the recess on the connecting rod with which it is intended to cooperate for to bring the rail to its advanced, locked position.

These and other purposes are fulfilled with an inventive locking mechanism with the main features set out in the characterizing part of claim 1.

As the connecting rod transfers movement from the cylinder lock's driver

means of the transmission arm which directly affects the pulley and carries out the transmission of the movement of the carrier device, all that is necessary with regard to the locking mechanism to adjust the locking mechanism to different keyhole distances is to replace the inserted connecting rod with another suitable rod or to change the active length of the rod, which at small

changes to the keyhole spacing only require the transfer arm to be connected to another suitable pivot point on the connecting rod, the rod having a number, e.g. four such pivot points.

An important characteristic feature of the inventive locking mechanism is thus the provision of a connecting rod which is affected by the cylinder lock's driver device and which can be easily replaced and/or which provides alternative connection possibilities with cooperating elements and thus allows the exchangeable transmission of the driver member's movement.

In the case of large changes in the keyhole distance, it is usually necessary to replace the entire connecting rod, this connecting rod having in principle the same design as the replaced rod and also suitably having different alternative pivot points that can be used to satisfy different keyhole distance requirements.

Claim 2 states an advantageous embodiment of an inventive locking mechanism comprising an advantageous exchanged transfer function. The torque required to retract the latch and bolt when turning the key is very small compared to the torque required in known locking mechanisms, due to the parallelogram mechanism.

Claim 3 specifies an arrangement which will ensure that the lock is in a locked position even if the connecting rod were to be placed in an intermediate position when turning in one of the directions.

In the case of a locking mechanism constructed in accordance with the invention, it is preferred that the rest of the pulley mechanism, possibly with the exception of the connecting arm, remains essentially unchanged. A connecting arm of greater length may thus be necessary in the case of larger keyhole distances.

For the purpose of adapting the drop mechanism to satisfy different requirements for keyhole distance, it is preferred that a pressure rod with a length adapted to the relevant keyhole distance is arranged interchangeably between the drop tube and the drop tube arm with the rest of the locking mechanism essentially unchanged.

In the case of particularly large keyhole distances, the lock box can be provided with a separate control device, since the distance between the fall piston rod and the fall tube storage element, where the piston control is usually located, would otherwise be far too great.

In order to make it possible to adapt the lock to different center distances between the button turner in the drop mechanism and the cylinder core in the rail mechanism, the lock mechanism should preferably be constructed as specified in requirements 6 and 7.

Other preferred embodiments of the invention are indicated in the following claims.

The invention will now be described in more detail with reference to exemplary embodiments thereof with reference to the accompanying drawings.

Figure 1 is a perspective view of a lock box with a twist and a cylinder lock,

which accommodates a locking mechanism according to the invention.

Figure 2 shows the lock box in Figure 1 from above with the housing lid removed.

The lock box and associated locking mechanisms are designed for relatively small keyhole distances and frequently occurring center distances between the twist and the central axis of the cylinder core. The latch mechanism and the latch mechanism are both shown in their respective closed and locked positions.

Figure 3 is a drawing that corresponds to Figure 1, but where the rail is shown in its

retracted or unlocked position, as this condition is achieved with the aid of the cylinder lock key.

Figure 4 is a drawing that corresponds to the drawings in Figures 2 and 3, and shows

the state of the locking mechanism after continued turning of the key, in which state the latch has also moved to its retracted or unlocked position.

Figure 5 is a drawing that corresponds to the drawings in Figures 2-4, and shows the situation

where, from a starting position according to fig. 2, the twister in the breech mechanism has been actuated to move the breech to its retracted or unlocked position, while the quick release arm has simultaneously actuated the clutch arm in the breech mechanism to also move the breech to its unlocked position. Figure 6 is a drawing that corresponds to the drawing in Figure 5, and shows the situation when the twister in the drop mechanism has been released, so that the drop assumes an advanced or closed position. The resulting state in the locking mechanism corresponds to the state shown in Figure 2, where a corresponding state is achieved, however, by moving the bolt to its unlocked position from the initial position shown in Figure 1 by means of the key.

Figure 7 shows the locking mechanism according to the invention when it is used in a

lock box designed for much larger keyhole distances, where both locking mechanisms are in a state that corresponds to the initial state shown in Figure 1, that is, with the latch and bolt in the closed or locked position.

Figures 1-6 show a lock 1 according to the invention placed in a lock box 2 which includes a lock post 3, and which accommodates a turner or button turner-actuated drop mechanism 4

and a pulley mechanism 6 which is affected by a cylinder lock 5. The two locking mechanisms 4

and 6 are designed to interact with each other and are constructed in accordance with a so-called modular system to be able to easily adapt the lock to keyhole distances of different sizes and different center distances between the twister 8 in the drop mechanism and the center axis in the cylinder core 7. The design shown in figures 1 - 6

is intended to fit a relatively small keyhole distance and normally occurring, i.e. frequently occurring, center distances. The modular construction of the lock means that the majority of the components in the lock housing will have the same shape and dimensions for use with varying keyhole distances and center distances. Only a few of the components need to be replaced to adapt the lock to the relevant keyhole distances. As described in detail below, one and the same connecting rod can be used to adapt the lock to four different keyhole distances, while the connecting rod for deeper keyhole distances can

be replaced with a longer connecting rod of basically the same design, e.g. in accordance with the design shown in Figure 7.

The fall mechanism 4 which is placed in the box 2 comprises a storage element 12 for a fall tube 13 with a square shaft 13e which receives a twister 8. The fall tube 13 has a stop or shoulder 13a which grips one end of a pressure rod 10, the other end of which grips a fall tube arm 17 which is rotatably mounted on a pivot shaft 18. The upper end 17a of the drop tube arm engages between two shoulders lia, 1 lb which are mutually separated on a piston rod 11 which carries a drop 9 at one end. The other end of the piston rod 11 is received in a guide 12a arranged in the storage element 12 of the downpipe.

The torsionally affected downpipe 13 rotates or turns against the action of a spring 14 mounted in a spring holder 15.

The downpipe arm 17 is also affected by a spring 19 which lies against the pivot shaft 18 for the downpipe arm 17 and also against an arm part 17b. However, the spring can be positioned in a different way than what is shown, and can be in direct contact with the installation shoulder lia.

The drop tube 13 further has a contact shoulder 13b which acts on a so-called quick-release arm 39 which is rotatably mounted on a pivot shaft 38 at the end of the box 2 which is located away from the rail, and which has the function of making it possible to retract the rail mechanism by means of the twister 8 in a manner that will be described below.

The pulley mechanism 6 which is placed in the case 2 is affected by a cylinder lock 5. The mechanism 6 can alternatively be affected by other devices, respectively from the inside and outside of the door.

In the embodiment shown, the pulley mechanism comprises a pulley device 20 which is guided in a guide track or channel 20c to achieve rectilinear movement. The rail device comprises a rail 20a and two installation shoulders 20b.

The mechanism also comprises a connecting rod 24 for engagement with a driver member 7a belonging to the cylinder core 7, the function of the driver member being to move the connecting rod 24 between two end positions.

A transfer arm 22 which at one end can be turned about a pivot shaft 21 is rotatably connected to the connecting rod 24. The transfer arm 22 has a part 22a which engages between the two contact shoulders 20b on the rail device 20. The function of the transfer arm 22 is to transfer movement from the connecting rod 24 to real-

the device 20 in a way that gears up or exchanges the movements of the driving member 7a. This exchange or up-gearing of the drive member's movement makes it possible for the bolt 20a to be fully extended to a safe locking position with only one turn of the cylinder lock's key 5 (not shown).

As shown, the connecting rod 24 is provided at one end with four holes 24a. These holes can alternatively be used to adapt the lock to different keyhole distances, this being done by connecting a centrally located pivot pin 22c on the transfer arm 22 in a suitable hole. When the keyhole distance is greater than the keyhole distance for which the shown lock is adjusted, the left hole of the holes 24a can be used, while the right hole 24a is used in the event of a requirement for a smaller keyhole distance. When the keyhole distance is greater than the keyhole distance that can be achieved with the shown lock, it is necessary to replace the shown connecting rod 24 with a longer connecting rod 24' which includes an additional number of holes 24'a, in accordance with the embodiment in Figure 7.

The connecting rod 24 also cooperates with a locking arm 32 for the rail device 20,

as the arm 32 can be turned about a pin 43 arranged in a channel 20c in the rail arrangement 20. When the rail arrangement 20 is in its locked position, the function of the locking arm 32 is to prevent the rail from being pressed inwards. As the transfer arm 22 is rotated to

release the rail arrangement 20, the locking arm 32 is affected by the shoulder 22b provided on the inside of the arm 22, whereby the locking arm 32 is swung upwards about the pin 23 so that it is possible for the rail to be pulled in to its unlocked position.

The connecting rod 24 also cooperates with a coupling arm 27 which is rotatable

mounted at one end of a pivot shaft 26 and which carries a mounting shoulder 27a. The connecting arm 27 can be moved together with the connecting rod 24, so that the rod 24 and the arm 27 when the rail 20 moves to its locked position will move to a position where the contact shoulder 27a can be passed by the cylinder lock's driver member 7a.

When the rail device 20 is in its unlocked position, the coupling arm 27 is placed in

the position shown in figure 3, where the installation shoulder 27a is struck by the

the member while the driver member 7a continues to rotate past the position where the reel is fully retracted. After the driver member 7a and the contact shoulder 27a on the coupling arm have come into engagement with each other, the coupling arm 27 is rotated about the pivot shaft 26 while the coupling arm 27 and the driver member 7a continue to rotate, as shown in figure 4.

The locking mechanism also comprises a carrier arm 31 which forms a

transmission link through which the drop mechanism can be actuated by the locking mechanism to release the drop. The driver arm 31 is rotatable about a pivot shaft 30 and has at one end a projection 31 a which is affected by the coupling arm 27 when the arm rotates under the influence of the driver member 7a. Under the influence of the driving member, the driving arm 31 is rotated about its pivot pin 30, and a contact member 31b at the upper end of the driving arm is brought into engagement with the lower part 17c of the downpipe arm 17,

so that rotation of the driver arm 31 will draw in the fall 9 with the help of the fall pipe arm 17.

The pulley mechanism also comprises a control arm 34 which is rotatably mounted at one end on a pivot shaft 33, and which at its other end has a pivot pin 23 which is connected to the rear end of the connecting rod 24 opposite the transmission arm 22. The connecting rod 24 thus forms part of a parallelogram link mechanism comprising the four pivot points 21, 22c, 33, 23. The connecting rod 24 will thus be moved essentially in a straight line when it is affected by the driver member 7a, which engages in the recess 24 when the key is turned in the cylinder lock core 7.

The control arm 34 also has the important function of ensuring that the connecting rod will be placed in its end position when the driving member 7a is to engage in the recess 24b in the connecting rod 24, that is to say to prevent the connecting rod from assuming an intermediate position which will make such engagement impossible.

For this purpose, the control arm 34 comprises a recess 34a with which the driver member 7a engages in the event that the connecting rod is placed in an intermediate position during rotation of the driver member. When the driving member encounters a projection 34'a on the control arm 34, the arm is rotated about its pivot shaft 33 so that the pivot shaft 23 which connects the control arm 34 to the connecting rod 24 will. move to the right in the figures, and the connecting rod 24 will assume its end position where the locking mechanism is fully retracted to its unlocked position, and the driver member 7a is able to engage the recess 24b in the connecting rod 24, optionally to influence the mechanism to move to its locked state.

During withdrawal of the reel from the position shown in Figure 2, where the driver member 7a is rotated clockwise, the driver member is brought into engagement with the recess 24b on the connecting rod.

As explained above, when the locking mechanism is moved to its locked position, the coupling arm 27 and its abutment shoulder 27a are moved to the left in the figures, that is to say the driver member 7a passes and possibly engages the abutment shoulder 27a. The rope is pressed to its locking end position during this passage by the driver member 7a, that is to ensure the rope's locked condition. When the pulley mechanism is brought to its unlocked state, where the pulley 20a and the coupling arm 27 are in the position shown in Figure 3, continued rotational movement of the driver member 7a will cause the member to strike the landing shoulder 27a, thereby moving the case to its retracted or open position by means of the driver arm 31 and the downpipe arm 17, as shown in figure 4.

Figure 5 shows how the fall 9 and the reel 20a are both drawn in by the action of the twister in the fall mechanism. In this respect, the rail mechanism is affected by the quick-release arm 39 located at the edge of the part of the lock case which is located away from the rail, the quick-release arm 39 being affected by the contact shoulder 13b on the downpipe for rotation about the pivot shaft 38. The lower end 39b of the quick-release arm 39 will thus grip an abutment surface 24e on the connecting rod 24 and thus move the pulley 20a to its unlocked position.

The quick-release lever 39 can be omitted or removed when the quick-release function is not required.

It is seen that, by adapting the lock to different center distances between the twister and the cylinder lock, both the drop mechanism and the derailleur mechanism can remain essentially unchanged and that the only components that need to be adjusted are the driver arm 31 and the quick release arm 39. The basic idea of the invention as stated in the following claims includes also other designs where certain additional components, such as the downpipe arm 17, are alternatively or additionally replaced.

In the embodiment shown in Figure 7, the keyhole distance is much greater than the keyhole distance on the embodiments shown in the other figures. The fall mechanism 4 and the pulley mechanism 6 are mainly unchanged in the design of Figure 7, despite the larger keyhole distance.

With respect to the drop mechanism 4, only the push rod 10 has been replaced with a longer push rod, here indicated by 10'. In addition, the mechanism has been provided with a separate guide 41 for the piston rod 11 for the fall 9, since the piston rod 11 will not reach its usual guide comprising the recess 12a in the storage element 12.

As mentioned above with regard to the pulley mechanism, the connecting rod 24 in the previous embodiments has been replaced with a longer connecting rod 24', which includes a larger number of holes 24'a, for cooperation with the pivot pin 22c on the transfer arm 22. The connecting arm 27 in the earlier designs have also been replaced by a longer coupling arm 27', which is generally formed by providing an extension portion on the front end of a coupling arm of the same design as that used in the earlier embodiments according to figures 1-6.

As in the previous embodiments, if the bolt 20 in the embodiment of Figure 7 were to be placed in an intermediate position, during rotation it will influence the projection 34a on the control arm 34 to completely retract the reel 20 to its unlocked position. The lock can thereby be brought to its locked position in the normal way.

It thus appears that the lock can be adapted to satisfy requirements for significantly larger keyhole distances, while both the drop mechanism and the rail mechanism remain essentially unchanged. This has been made possible by constructing the lock in accordance with an adapted modular system.

The described and illustrated locks also provide the advantages mentioned at the outset, that is to say that the rail can be moved to its full extent in its locked position with only one turn of the key, and that the lock includes a control function that will ensure that the drive member can always be moved from an intermediate position to an unlocked position. The mechanisms also include advantageous transmission devices which produce low torque when actuated by the locking key, particularly when the latch 9 is moved to its open position by means of the driver arm 31, in accordance with Figure 4.

A locking mechanism according to the invention can therefore be easily adapted to motor operation, while the risk of a malfunction thereof is mainly eliminated.

When the lock is adapted for motor operation (not shown in the drawings), an electric motor is mounted in the lock box 2, e.g. in the space available at the top of the box. An output shaft for the motor can be provided with a hinge or similar device so that a part of the shaft will follow the rear edge of the lockbox when the lower end of the shaft is connected to the control arm 34 and turns the control arm, and thus the pulley mechanism 6, and, if applicable , the drop mechanism 4 between their respective end positions. The motor's output shaft will also include a release which ensures that the motor is disengaged under the influence of the pulley mechanism manually using the key.

When the motor-driven lock comprises a quick-release function, it is necessary that this release can be carried out extremely quickly at any time during motor operation. A quick-release arm 39 designed for a motor-driven lock will therefore comprise a free passage between its lower part 39b and the contact shoulder 24e on the connecting rod 24. During the free passage, a connection on a push and pull device is snapped apart. The arrangement re-arms or attempts to re-arm until the limit positions plus the time match the command to open or lock the lock.

In the case of a motor-driven lock, the control arm 34 cannot influence the drop mechanism 4 to retract the drop 9 to its open position. The pulley mechanism 6 in the motor-driven lock will therefore influence the drive member so that the latch 9 will be moved to its open position at the same time as the pulley 20a.

In the case of a motor-driven lock, it must also not be possible to start the motor when the driving member 7a has left its rest position, shown e.g. in figures 2, 5 and 6.

In the above mentioned and described embodiments of the invention, the reel mechanism is affected by a cylinder lock and/or a motor. However, it should be understood that the mechanism can be influenced in other ways, e.g. using a button turner or a turner from one side of the lock. In the case of locks which are provided with a quick-release function, i.e. locks which use a quick-release arm 39, current regulations prohibit influencing the lock by means of the button turner or the turner.

An important characteristic of the described and shown embodiments is that the coupling arm 27 arranged with the contact members 27a is driven by the control arm 34, or vice versa, and that the coupling arm 27 can be used at several keyhole distances. The mounting members 27a have been given the shape shown in the drawing to provide space and provide a large exchange effect (upshift) with a single turn of the key. It is also important that the locking arm 32 is able to fall down, despite the fact that the movement of the rail device 20 is slowed down when the rail is brought to the locked position. This provides effective forced control when moving the rail to its locked position. The arrangement also ensures that the driver member 7a will not be placed in the recess 24b in the connecting rod 24 when a quick release is performed at the same time as the lock is opened with a key from the outside, that is when the mechanism is influenced by a person on either side of the door where the lock is inserted.

A person skilled in the field will understand that other embodiments of the invention are possible within the scope of the inventive basic idea as stated in the accompanying claims.

Claims (10)

1. Locking mechanism comprising: a) a latch (9) which is actuated by a knob turner or twister by means of a spring-actuated latch tube (13), a pressure rod (10) and a latch tube arm (17), b) a pulley mechanism (6) which is affected by a cylinder lock (5) and an associated drive member (7a), and which comprises c) a rail device (20) which is controlled for rectilinear movement and comprises a rail (20a) and installation members (20b), d) a connecting rod ( 24) which comprises a recess (24b) for engagement with the driver member (7a) to move the connecting rod (24) between two end positions, e) a transfer arm (22) which is rotatably mounted on a pivot shaft (21) at one end and which is rotatably connected to the connecting rod (24) and which has a part (22a) that engages between the contact members (20b) of the rail arrangement (20) for transmission and exchange or gearing up of the movement of the connecting rod (24) to the rail arrangement (20), f) a locking arm (32) which cooperates with the rail device (20) and also with o the transfer arm (22), and which is rotatably mounted on a pivot pin (43), where, when the rail assembly is in the locked position, the locking arm (32) will prevent the device from being impressed, and when the transfer arm rotates to retract the rail assembly (20), pivots to a release position which allows the rail device to be retracted to its unlocked position, g) a coupling arm (27) which is provided with a contact member (27a) and which is rotatably mounted on a pivot shaft (26) at one end and is movable together with the connecting rod (24) so that, when the rail assembly (20) is moved to its locked position, the coupling arm will be moved to a position where the connecting member (27a) can be passed by a driver member (7a), which allows rotational movement of the cylinder lock (5), and ensures that the rail arrangement (20) is in its forward locking position and, when the rail arrangement (20) has been moved to its unlocked position, assumes a position where the installation member (27a) by continued rotation of the driver member in the right opening the lock will be grasped by the driver so that the coupling arm (27) is rotated around its pivot shaft (26) at one end of the arm, characterized in that h) the locking mechanism is constructed according to a modular system adapted to different keyhole distances, where, with the intention of making it possible to adjust the locking mechanism to different keyhole distances, the connecting rod (24) comprises one or more alternative points (24a) for pivoting attachment to the transfer arm ( 22), or the mechanism comprises several connecting rods (24, 24') of different lengths, each having one or more such alternative pivot attachment points (24a, 24'a), the connecting rod or rods being exchangeably attachable to the transfer arm (22). 2. Lock mechanism according to claim 1, characterized by a control arm (34) which is rotatable about a shaft (33) at one end and which at its other end carries a pivot pin (23) which is connected to the rear end of the connecting rod (24) opposite the transfer arm (22), so that the connecting rod (24) will form part of a parallelogram link mechanism with four pivot points (21, 22c, 33, 23). 3. Lock mechanism according to claim 2, characterized in that the control arm (34) comprises a projection (34a) which is positioned so that, when a key is turned to bring the locking mechanism to the locked position and the mechanism has not been fully retracted to the open position, the pulley mechanism (6) is affected by the driver member (7a) so that the control arm (34) will bring the pulley mechanism to a completely unlocked or retracted position where engagement between the driver member (7a) and the recess (24b) on the connecting rod (24) is ensured. 4. Lock mechanism according to one of claims 1-3, characterized in that the pulley mechanism (6) when adjusted to different keyhole distances remains mainly unchanged in other respects, possibly with the exception of the coupling arm (27). 5. Locking mechanism according to one of claims 1-4, characterized in that a pressure rod (10) with a length adapted to a suitable keyhole distance is replaceably mounted between the drop tube (13) and the drop tube arm (17), the rest of the drop mechanism (4) remaining essentially unchanged at different keyhole distances. 6. Lock mechanism according to one of claims 1-5, characterized by a replaceable carrier arm (31) which is rotatably mounted on a pivot shaft (30) and which has a length adapted to a suitable center distance to adapt the mechanism to different center distances between the turner or button turner for the drop mechanism and the core of the cylinder lock in the pulley mechanism (6). 7. Locking mechanism according to claim 6, comprising a quick-release arm (39) between the fall mechanism's fall pipe (13) and the connecting rod (24) in the pulley mechanism (6), characterized in that quick-release arms (39) of mutually different lengths can be interchangeably mounted on a pivot shaft (38) located in the area at the edge of the lockbox opposite the latch and rail. 8. Lock mechanism according to claim 6 or 7, characterized in that the rotatable carrier arm (31) carries an element at one end, e.g. a projection (31 a), which is affected by the coupling arm (27) when it is rotated under the influence of the driver member (7a), for turning the driver arm (31), the driver arm (31) at its other end carrying a contact member (31b) for engagement with the drop pipe (17) affecting the drop (9), so that turning the driver arm (31) will cause a retraction of the drop (9). 9. Lock mechanism according to one of claims 1 -8, comprising a motor drive and an electric motor located in the lock box (2), characterized in that a motor output shaft is connected to the control arm (34) via a release device for turning the control arm and thus the pulley mechanism (6), and possibly also the drop mechanism (4) between its/their end positions. 10. Lock mechanism according to claim 9, characterized in that the release device ensures disconnection of the motor when the pulley mechanism (6) is manually affected by a key.