NO336790B1 - A locking device intended to be movably arranged relative to an engagement member, as well as a combination of the locking device and an engagement member. - Google Patents

Abstract

A locking device (1) intended to be movably arranged in relation to an engagement means (3), which locking device comprises a hook bolt (15) for engagement with the engagement means and a control element, which hook bolt presents an aperture (21) with an inner surface, and which control element comprises a follower (27) having an eccentric axis of rotation and a peripheral surface. The control element is arranged to transmit motion from an operating means to the hook bolt when the operating means is moved between a locking position and a release position, so that a relative tightening between the engagement means and the locking device is achieved when the operating means is moved to its locking position. In order to prevent breaking up of the locking device, the hook bolt is provided with a securing surface (17b), which is arranged to turn around the engagement means during locking.

Description

Locking device intended to be movably arranged in relation to an engaging element, as well as combination of the locking device and an engaging element

The present invention relates to a locking device which is intended to be arranged so that it can move in relation to an engagement element and which comprises a hook bolt for engagement with the engagement element and a control element, which hook bolt has a hole with an inner surface, and the control element comprises a follower device with an eccentric axis of rotation and a peripheral interface and is designed to transmit motion from an operating element to the detent bolt when the operating element is alternated between a locking position and an open position, the motion transmitted to the detent bolt producing a relative attraction between the latch and the engaging element when the detent bolt is in engagement with the engaging element and the operating element is brought towards the locking position, the latch bolt being pivoted around the follower device and the inner surface of the hole in the latch bolt which encloses and cooperates with the peripheral boundary surface of the follower device, so that rotation of the follower device carries the latch bolt one with him.

The invention also relates to a combination of a locking device and an engaging element.

The locking device and combination can especially be used in sliding doors where it is intended to produce an attractive effect between the sliding door and the door frame when it is closed and a dividing effect between the door and the door frame when it is opened, and where forced operation of the lock should be prevented.

US 2,599,511 describes a lock for a sliding door which is intended to slide in a door frame or door frame towards and away from an engaging element in the form of a closing pin, which is arranged in the door frame. The lock is intended for use in sliding doors on, for example, railway carriages. To ensure a good sealing effect with a sealing strip placed on the door frame or the door, the lock is designed to produce an attraction of the sliding door against the door frame in the carriage wall when it closes. The lock is also intended to have the effect of separating the door from the door frame when it is opened, to facilitate opening of the door if, for example, ice formation between the door frame and the door makes the door difficult to open. The described lock comprises a manually activated operating element, which is pivoted around a first pivot pin which extends across the direction of movement of the door and which is attached to a side plate of the lock. A hook bolt which runs essentially parallel to the direction of movement of the door is arranged on the side of the operating element, seen in the direction of movement of the door. On one side of the first pivot pin, seen in the longitudinal direction of the pivot pins, the hook bolt is pivoted around a second pivot pin which runs parallel to the first pivot pin and is attached to the operating element. One end of the detent bolt has a cam surface, which is designed to slide on and past the breech pin and has a recess, which is shaped to descend and engage the breech pin as the door moves toward its closed position. The lock is further provided with elements that hold the sear bolt in position so that its cam surface can slide onto the breech pin. The operating element and the two pivot pins are positioned so that the axis of rotation of the detent bolt moves around the axis of rotation of the operating element when the operating element is operated, an attracting movement is imparted to the detent bolt when the operating element is brought into the closed position and a separating movement when it is brought into the open position. The operating element and the hook bolt further have interacting elements by means of which the end of the hook bolt is lifted off from the operating element when this moves to the open position and is pressed down when the operating element moves to the closed position.

The construction described in US 2,599,511 is relatively complicated and is based on the principle that the operating element and the hook bolt are located side by side, that is to say in separate vertical planes that are parallel to the main plane of the door leaf. Such a location entails a number of disadvantages in terms of construction and strength. Firstly, this side-by-side arrangement means that the entire lock structure is subjected to bending stresses when the opening and tightening force is transmitted via the latch bolt. This applies in particular to the two pivot pins and to the areas in the operating element and the side plate to which the pivot pins are attached. The mentioned location further places a serious limitation on the thickness of the material that can be used in the catch bolt and the operating element for a given maximum width of the lock, at right angles to the main plane of the door. In addition, the location of the two pivot pins side by side means that the maximum diameter of the pins is relatively limited. This in turn places a restriction on the contact surfaces between the pivot pins and the hook bolt, the operating element and the side plate, which leads to high contact pressures with an increased risk of material breakage of these force-absorbing parts of the design construction.

DE 9212765U describes a lock having a hook bolt, which is arranged around an eccentrically carried follower device. The chin bolt is formed with an angled chin which engages with an engagement pin to achieve attraction and retention.

The lock shown in DE 9212765 has a serious disadvantage in that it is relatively easy to force open. By inserting an object between the door leaf and the door frame and then forcing the latch bolt upwards with the aid of the object, it is easily possible to release the engagement of the latch bolt with the engagement pin and thus force the lock open. This known lock has no devices to prevent such forced opening.

Further examples of the state of the art are shown in US 3851922.

The present invention relates to a lock which allows an attractive force to be applied between a sliding or swing door leaf and an adjacent door frame or an opposite door leaf when the lock operating element is moved between an opening position and a closing position. One purpose of the invention is to provide such a lock where breaking open the lock is made significantly more difficult.

Another object of the invention is to provide such a lock which also generates a separation force between the door leaf and the door frame or between the door leaves when the operating element moves from its closing position to its opening position.

One purpose of the invention is to provide such a lock which has a simple construction and which overcomes the aforementioned disadvantages in terms of design and strength inherent in previously known locks.

These purposes are achieved with a lock of the type described in the first part of this description and which is characterized in that the hook bolt has an engagement surface to produce the relative attraction and a separation surface to produce relative separation between the lock and the engagement element when the operating element is brought towards the opening position, and that the detent bolt has a locking surface, the detent bolt and the follower device are designed to allow the engaging surface and the detent surface to rotate about the engaging element when the operating element is moved between its opening position and its locking position, to counteract any forced opening of the locking device.

This provides a simple and reliable way of both attracting and separating the door leaf when the operating element is moved between its opening position and closing position. At the same time, the securing surface of the hook bolt together with the rotation of this and the engagement surface around the engagement element make forced opening of the lock considerably more difficult. When the engaging and securing surface has revolved around the engaging element, the hook bolt will enclose a larger portion of the periphery of the engaging element than the portion enclosed when the engaging surface first engages the engaging element. The securing surface will in particular mechanically prevent the hook bolt from being detached from the engaging element. This serves to prevent an object being inserted between the door leaf and the door frame or between door leaves that are used to force the hook bolt up and loosen from the engaging element.

Arranging the hook bolt around the follower device, so that the force is transferred via the peripheral interface of the follower device and the inner surface of the hole, means that it is also possible for the follower device and the hook bolt to be located in the same vertical plane parallel to the main plane of the door leaf. Both the follower device and the hook bolt can thus be manufactured with a material thickness equal to the inner width of the lock. The design construction means

furthermore, that only one axis, i.e. the axis of rotation of the follower device, must be supported in adjacent force-absorbing elements. This single axis is simply carried in the usual manner in both of the lock's side plates, with the result that no bending stresses occur in the structure when the force of attraction and separation is transferred from the operating element to the engaging element. The design construction also allows the follower device and the hole in the hook bolt to be manufactured with relatively large force-transmitting surfaces, which leads to lower contact pressure and thus to a reduced risk of damage or breakage of components, even if the transmitted attraction and separation forces are large forces.

Further advantages and characteristics of the lock in accordance with the invention are set out in the following independent claims and in the detailed description below.

The invention also relates to a combination of a lock and an engaging element which allows the lock according to the invention to be used in sliding doors, to which an oblique movement component is assigned during their closing movement.

An embodiment of the invention is described below with reference to the drawings, where: Fig. 1 is a perspective view of an embodiment of the invention and an engaging element, in which certain components have been omitted for greater clarity, Figs. 2a and 2b show different perspective views and 2c shows a plan view of a lock forming part of a combination with a lock,

Fig. 3 is a side view of the lock shown in Fig. 1, without the engaging element,

Fig. 4 is a side view on a larger scale of a follower device which forms part of the lock shown in fig. 1, Fig. 5 is a side view on a larger scale of a hook bolt which forms part of the lock shown in fig. 1, Fig. 6, 7 and 8 show side views of the lock when it assumes various closed and open positions, Fig. 9 is a side view of an enlarged detail of the embodiment of the lock and engagement element shown in fig. 1, Fig. 10 and 11 are plans of a combination of a lock and an engaging element in accordance with the invention. Fig. 1 shows a first embodiment of a locking device 1 in accordance with the invention. The figure also shows a closing piece 2 with an engaging element 3 in the form of a shackle which is attached to the closing piece 2. In the following description, it is assumed that the lock 1 is arranged in a door and the closing piece in a door frame or door frame. The lock is particularly suitable for use in sliding doors that are closed and opened by pushing the door in a horizontal or vertical direction, particularly parallel to the main plane of the door leaf. A sealing strip can be arranged on such doors, either on the door frame or on a short side of the door leaf that faces the door frame. In order for the strip to provide a good sealing effect, it should be pressed together between the door and the door frame when the door is closed. For this reason, the lock has been redesigned to produce an attractive force between the door and the door frame when the door is closed.

The lock 1 is primarily designed to be inserted into a door leaf 40 (see fig. 10). The lock comprises a lock housing 4 laterally bounded by two opposite cover plates or side plates 5, only one of which is shown in the figure. The side plate 5 shown in the figure has an internally threaded pin 6, which cooperates with screws to hold the two side plates together. When fitted, the lock housing 4 is attached to a lock plate 7 and inserted into the door leaf, so that the side plates 5 are essentially parallel to the main plane of the door leaf.

The end piece 2 (see Figs. 1 and 2a-2c) comprises a fastening plate 8 which is attached to the door housing by means of screws (not shown), which when adapted extend through screw holes 9 in the fastening plate 8. An engaging element in the form of a shackle 3 is attached to the back 8 of the attachment plate and extends through an opening 10 in the attachment plate 8 into the door opening. The shackle 3 (see fig. 2a) comprises two side legs 11a, 11b which at their end facing the door opening are connected to an engagement part 12. The engagement part 12 has a cam surface 13 which slopes downwards towards the door opening and ends towards the door opening at a vertical support surface 14.

Reference is again made to fig. 1 where the lock 1 comprises a hook bolt 15. The hook bolt 15 is shown more clearly on a larger scale in figure 5 and part of this on an even larger scale in figure 9. At its free end facing the breech piece 2, the hook bolt 15 has a cam surface 16 and a recess 17, which is open towards the bottom. The recess 17 has an engagement surface 17a which is arranged next to the cam surface 16 of the chin bolt and is finished at the bottom with a fastening surface 17b angled away from the cam surface 16 of the chin bolt. A separating surface 17c is arranged on the side of the recess 17 which is opposite to the engaging surface 17a. The engagement surface 17a and the separation plate 17c are connected by a bearing surface 17d. In the transition between the engaging surface 17a and the securing surface 17b is a restrained shoulder 17e. The end of the securing surface 17b which faces the engaging surface 17a will thereby be located somewhat outside the plane of the engaging surface 17a (to the right in the figure).

The hook bolt 15 further has an elongated section 18 which connects the end having the cam surface 16 and the recess 17 to an extended part 19. The elongated part 18 extends through an opening 7a in the front plate 7, which opening 7a has a lower support surface 7b (see Fig. 1 ). A torsion spring 20 is arranged around one of the pins 6 and with a leg 20a resting against another pin, so that the other leg 20b of the spring rests and presses the chin bolt down against the support surface 7b.

A through hole 21 is made in the extended section 19 of the hook bolt (see Fig. 5). The hole 21 has a largely circular cylindrical shape with an inner surface. From the largely circular-cylindrical shape, a shoulder 22 projects inwards towards the center of the hole 21. The shoulder 22 has two opposite shoulder side surfaces 22a, 22b in the circumferential direction of the hole and an inner shoulder surface 22c facing the center of the hole. An elongate through recess or recess 23 extends from a lower part of the inner surface of the hole 21 at some distance towards the elongate part 18 of the chin bolt. A compression spring 24 and a steel ball 25 are arranged in the recess 23 (see fig. 1), so that the spiral spring 24 rests against the bottom of the recess and presses the ball 25 against the hole 21.

In fig. 4, the follower device 27 is shown on a larger scale than the hook bolt 15 in fig. 5. The follower device 27 has a substantially circular cylindrical shape with a peripheral interface 28. Over the greater part of its circumference, the outside diameter of the follower device 27 is only slightly smaller than the diameter of the general circular cylindrical shape of the hole 21. In this way, the hook bolt 15 can swing around the follower device 27 while a large part of the peripheral interface 28 of the follower device and the inner surface of the hole 21 cooperate for the transmission of power. A stop recess 29 includes a circular segment covering approximately 90° and is bounded in the circumferential direction by two essentially radial stop surfaces 29a, 29b. A lock position recess 30 is also made a short radial distance inward from the stop recess 29. The lock position recess 30 is bounded in the circumferential direction by the stop surface 29a arranged in a clockwise direction and by a lock position stop surface 30a, which is arranged at a distance corresponding to the length in the circumferential direction of the inner shoulder surface 22c of the chin bolt. Two position-holding recesses 31a, 31b are further produced in the peripheral boundary surface of the follower device 27, outside the stop recess 29. These position-holding recesses 31a, 31b are essentially spherical with dimensions that correspond to part of the spherical surface of the steel ball 25.

The follower device 27 further has an eccentrically placed integrated pivot pin 32 which protrudes from both sides of the follower device. The pivot pins have a square through hole 33 in which a handle 34 (see fig. 6-8) or another operating element can be attached. The pivot pin is further pivotably carried in opposite openings in the two side plates 5.

The working principle of the lock will be described below with reference to fig. 6-9.

Fig. 7 shows the lock with a locking arm 36, which will be described below, in its locking position. This locking position is only assumed if locking arm 1 is actively brought there by operating a locking cylinder 38. When the sliding door is closed, the lock is first in the position shown in figure 6. the free end of the hook bolt 15 is in a position that protrudes from the lock housing 4. The torsion spring 20, the hook bolt 15 presses against the bearing surface 7b in the locking plate 7. The compression spring 24 presses the steel ball 25 into the position-holding recess 31a on the follower device 27. The follower device 27 and the hook bolt 15 are thereby releasably secured, which prevents their rotation in relation to each other and the handle 34 is thus held in its horizontal position. The door is now pushed against the door housing and the closing piece 2. This can be done either by applying a horizontally directed force against the handle 34 on the left in the figure or, for example, by manually, hydraulically or pneumatically applying a corresponding force against the door leaf or against a handle arranged on the door leaf. When the short side of the door approaches the door housing, the cam surface 16 of the hook bolt 15 slides onto the cam surface 13 of the engaging part 12 of the shackle 3, as shown in fig. 9. The hook bolt 15 and the follower device 27, which are still releasably held in relation to each other and the pivot pin 32 thus swing clockwise in bearings arranged in the side plates 5 for the pivot pins 32. During this movement, the handle 34 swings somewhat downwards in a clockwise direction. When the downward facing tip of the securing surface 17b in the recess 17 of the chin bolt

has passed the engagement part 12 of the shackle 3, the torsion spring 20 presses the free end of the hook bolt downwards so that the bearing surface 17d of the recess 17 is brought to rest against the top side of the engagement part 12. The hook bolt 15, the follower device 27, the pivot pin 33 and the handle 34 then pivot clockwise and resumes the position shown in fig. 6.

It is from this position that the attracting movement is initiated. By applying a counter-clockwise force to the handle 34, the pivot pin 33 and the follower device are made to rotate anti-clockwise. The free end of the hook bolt 15 is prevented from moving downwards as the bearing surface 17d rests against the engaging part 12 of the shackle 3. The spring force of the compression spring 24 is thereby overcome and the steel ball 25 is released from its fixed position in the position-holding recess 31a. The follower device 27 can then rotate freely in relation to the hook bolt 15. As the axis of rotation of the follower device 27 is arranged eccentrically and as the hook bolt 15 is arranged around the follower device 27, the center of the hole 21 in the hook bolt 15 and thus the axis of rotation of the hook bolt will move along a circular line around the axis of rotation to the follower device. A horizontal movement to the right in the figure is then assigned to the free end of the hook bolt 15, which cannot move downwards. The engaging surface 17a in the recess 17 of the hook bolt 15 engages with the engaging part 12 so that further horizontal movement to the right in the figure is prevented by the hook bolt. Continued clockwise rotation of the handle 34 now means that the extended part 19 of the hook bolt moves inwards/upwards in relation to the lock housing 4, so that the door in which the lock housing is fixed moves towards the closing piece 2. This attractive movement continues until the stop surface 29a of the follower device 27 comes into contact with the side shoulder surface 22a of the shoulder 23 in the hole 22 in the hook bolt (see fig. 7, 4, 5). As a result of the radially directed force acting between the peripheral interface of the follower and the inner surface of the hole, the shoulder 22 then assumes a locking position in which the inner shoulder surface 22c is located in the position-locking recess 30 in the follower. If a horizontal force is applied to the door in the opening direction, this prevents the door from opening, as the side shoulder plate 22b rests against the position-locking stop surface 30a in the position-locking recess 30.

As the extended part 19 of the hook bolt 15 also moves upwards during the attracting/locking movement, the free end of the hook bolt will rotate around the engaging part 12 so that the attachment surface 17b will to a certain extent enclose the underside of the engaging part 12. In this way, the hook bolt will be mechanically locked when engaging with the engaging element. If an object inserted between the door leaf and the door frame is used in an attempt to force the hook bolt 15 upwards, the fastening surface 17b will come into contact with the engagement element 3, this contact mechanically preventing further relative upward movement between the hook bolt 15 and the engagement element 3. Angle of the fastening surface 17b away from the free end of the hook bolt (to the right in the figure) ensures that the mechanical contact between the fastening surface 17b and the engagement element actually occurs if the hook bolt 15 is pressed upwards, even if a certain degree of slack exists between the engagement surface 17a and the engagement element 3 when the hook bolt 15 first pushed upwards. This securing effect is further enhanced by the fact that the end of the fastening surface 17b which faces the engaging surface 17a is displaced by a distance equal to the height of the retaining shoulder 17e from the plane of the engaging surface 17a. If the engagement element has a sharp edge facing the engagement surface 17a, this edge will come into mechanical locking contact with the retaining shoulder 17e if the hook bolt 15 is forced upwards. If the engagement element has a circular or otherwise curved cross-section, on the other hand, the retaining shoulder 17e will be able to pass a part of the engagement element, with the result that locking mechanical contact instead occurs between the inclined attachment surface 17b and the engagement element 3 .This represents a simple and effective means of countering an attempt to force open the latch by applying an upwardly directed force to the detent bolt near its free end.

When the lock has assumed this locking position, the handle 34 is in a vertical position as shown in figure 7. The handle 34 is held in this vertical position by the fact that the follower device 27 and the hook bolt 15 are releasably held, which prevents their rotation in relation to each other when the steel ball 25 is pressed into the second locking position recess 31b in the peripheral boundary surface of the follower device 27.

If the door, from the starting position shown in figure 6, is pulled with great force to the closed position, so that the sealing strip between the door and the door frame is pressed together by this closing force, it may happen that the lock passes through the sequences described above without any counter-clockwise attracting force that must be applied the handle.

Starting from the locking position illustrated in figure 7, it will now be described how the door is opened. The figure shows the locking arm 36 described below in its locked position. When opening the door, however, this locking arm must be in its release position, which is shown in fig. 8. To release the lock, a clockwise force is applied to the vertically aligned handle 34. The follower device 27 then rotates clockwise. However, the hook bolt 15 is still prevented from turning since the attachment surface 17b in the recess 17 is still engaged with the engaging part 12. The spring force of the compression spring 24 is thus overcome and the steel ball 25 is pushed out of the position-holding recess 31b, with the result that the follower device 27 and the hook bolt 15 are again able to rotate freely relative to each other. At the same time, the shoulder 22 is forced out of its locking position in the position-locking recess 30 and can then slide freely in the stop recess 29 in the follower device. The torsion spring 20 presses the hook bolt 15 down so that the bearing surface 17d in the recess 17 rests against the engaging part 12. As the follower device 27 continues to rotate clockwise, a horizontal movement is imparted to the free end of the hook bolt 15 outwards from the lock housing 4. The separating surface 17c in the recess 17 then engages the vertical support surface 14 of the engaging member 12, with the result that a separating force is imparted to the door causing it to move away from the closing piece 2. At the same time, the extended portion 19 of the latch bolt 15 moves downwards so that the free the end of the hook bolt 15 swings clockwise around the engagement part 12. The engagement of the attachment surface 17b around the engagement part 12 is thus released.

When the follower device has turned to the position shown in fig. 6, the hook bolt 15 takes a horizontal, protruding position. In this position, the steel ball 25 is again pressed into the position-holding recess 31a in the peripheral surface of the follower device 27. During continued rotation of the follower device 27 clockwise, the stop surface 29b of the follower device comes into contact with the side shoulder plate 22b of the shoulder 22 so that the chin bolt is obtained to rotate about the axis of rotation of the follower device 27. The force applied to the clockwise handle 34 overcomes the spring force of the torsion spring 20 with the result that the free end of the hook bolt is raised so that the lower tip of the attachment surface 17b escapes from the top of the engaging part 12 and the door can be pushed open . The lock has then assumed the position shown in figure 8 and when the force on the handle 34 clockwise is withdrawn, the lock returns to the position shown in fig. 6 in that the torsion spring 20 presses the hook bolt to carry the support surface 7b on the front plate 7. As the steel ball 25 is pressed into the position-holding recess 31a, the follower device and the handle follow to the positions shown in figure 6.

The lock according to the invention can be equipped with a locking arm 36, which is swung between a release position shown in fig. 6 and 8 and a locking position shown in fig. 7. In the locking position, one end of the locking arm 36 with a locking recess 37 grips the extended part 19 of the hook bolt 15 which thus prevents all movement of the hook bolt from its retracted locking position. Movements of the locking arm are controlled by a locking cylinder 38 which is operated by means of a key or a handle (not shown) in the usual manner.

The invention also relates to a combination of the lock described above and an engaging element. A preferred embodiment of the combination in accordance with the invention is described below with reference to fig. 10, 11, 2a, 2b and 2c. As the lock according to the invention has been described above, the following description of the combination will concentrate on the engaging element.

Fig. 10 and 11 show a sliding or sliding door 40 in which the sealing effect between the door 40 and the door frame 41 is not produced between the short side of the door leaf 42 and a side of the door frame facing the door opening. Instead, the sealing effect is achieved here between a surface 43 on the door leaf 40 which is parallel to the main plane of the door leaf and arranged near the short side of the door leaf facing the end piece and a corresponding parallel surface 44 on the door frame. A sealing strip 45 can be arranged between these two surfaces. In the example shown, the sealing strip is adapted to the door frame, but it can also be adapted to the door leaf.

In order to produce a good sealing effect on such sliding doors, upon their displacement towards the closed position, the door 40 must not only move parallel to the main plane of the door towards the door frame, but a movement component must also be allocated in a direction normal to the main plane of the door leaf. This can, for example, be brought about by arranging wedge-shaped guide elements 46 in the door frame 41 or in grooves outside the door frame, where the guide elements 46 guide the door during its displacement movement towards the closed position. These guide elements 46 force the door 40, when it approaches the closed position, to move obliquely towards the stopper in the door frame. A problem that arises when using the attracting and separating lock according to the invention, as described above, in such doors is that conventional engaging elements do not allow any oblique movement.

This problem is solved by the combination according to the invention. Fig. 2b shows how the shackle 3 is attached to the attachment plate 8. At their ends farthest from the engaging part 12, the two side legs 11 a and 11 b are joined to form a largely V-shaped piece 11c, which extends through the opening 10. A vertical continuous hole 47 is made in the V-shaped piece 11c. A pin 48 is arranged through the hole and attached to the side of the attachment plate 8 at a distance from the door opening. The internal diameter of the hole 47 is somewhat larger than the external diameter of the pin 48 so that the shackle 3 can swing around the pin 48. The shackle 3 is held in the vertical position by the underside of the V-shaped piece 11c which rests against the lower edge of the opening 10. Fig. 2c shows a plan view of the shackle 3, the fixing plate 10 and the pin 48. The figure shows that a vertical surface 12a in the engagement part 12, which is at a distance from the door opening, has a convex shape 12b which curves away from the door opening.

When the combination of the lock and the engaging element according to the invention is used in sliding doors where a movement component is supplied across the main plane of the door leaves at the end of their closing movement, the lock functions as described above. During the tightening phase, the engaging surface 17a of the hook bolt 15 contacts the vertical surface 12a of the engaging element 12. When the door 40 approaches its closed position and an oblique movement is assigned to it in the direction of the sealing strip 45, the shackle 3 will swing around the pin 48 while the convex shape 12b of the vertical surface 12a of the engaging part 12 causes the engaging surface 17a of the hook bolt to roll over the convex vertical surface. The door 40, the lock 1 and the hook bolt 15 are thus allowed to move laterally in relation to the closing piece 2 and the engagement part 12 without any lateral forces or bending stresses occurring on the hook bolt 15, the closing piece 2 or the engaging element 3.

An example of an embodiment of the locking device and the combination of a locking device and an engaging element in accordance with the invention has been described above. The invention naturally provides opportunities for variations within the scope of the following patent claims. For example, the lock can be placed in the door frame and the engagement element in the door. The lock according to the invention can also be used in swinging hinged doors instead of sliding doors. The door handle 34 described above can be replaced by other manually activated operating elements or such activated electrically, pneumatically or hydraulically, for example. The lock can also be designed with or without the locking mechanism comprising the locking arm 36 and the locking cylinder 38.

Claims (14)

1. Locking device (1) which is intended to be arranged so that it can move in relation to an engagement element (3) and which comprises a hook bolt (15) for engagement with the engagement element (3) and a control element, which hook bolt has a hole ( 21) with an inner surface, and the control element comprises a follower device (27) with an eccentric axis of rotation and a peripheral interface (28) and is designed to transmit movement from an operating element (34) to the detent bolt (15) when the operating element (34) is switched between a locking position and an open position, where the movement transmitted to the latch bolt (15) produces a relative attraction between the latch and the engaging element (3) when the latch bolt (15) is engaged with the engaging element (3) and the operating element (34) is brought towards it locking position, as the hook bolt (15) is pivoted around the follower device (27) and the inner surface of the hole (21) in the hook bolt (15) which encloses and cooperates with the peripheral boundary surface (28) of the follower device gene (27), so that rotation of the follower device (27) brings the hook bolt (15) with it, characterized in that the hook bolt (15) has an engagement surface (17a) to produce the relative attraction and a separation surface (17c) to produce relative separation between the lock and the engagement element (3) when the operating element (34) is brought towards the opening position, and that the hook bolt (15) has a securing surface (17b), the hook bolt (15) and the follower device (27) are designed to allow the engagement surface (17a) and the securing surface (17b) to rotate around the engaging element (3) when the operating element (34) is moved between its opening position and its locking position, to counteract any forced opening of the locking device (1). 2. Locking device as specified in claim 1, characterized in that the engagement surface (17a) and the separation surface (17c) are formed as two opposite sides of a recess (17), which is produced in the hook bolt (15) near the free end of this facing the engagement element (3). 3. Locking device as stated in claim 1 or 2, characterized in that the securing surface (17b) is shaped as an inclined extension of the engaging surface (17a). 4. Locking device as stated in one of claims 1 to 3, characterized in that a retaining shoulder (17e) is arranged between the engaging surface (17a) and the securing surface (17b). 5. Locking device as specified in one of claims 2 to 4, characterized in that the engagement surface (17a) and the separation surface (17c) are formed as two essentially parallel opposite sides of the recess and are connected by a bearing surface (17b). 6. Locking device as specified in one of claims 2 to 5, characterized in that the recess (17) is essentially U-shaped and the engagement surface (17a) is longer than the separation surface (17c). 7. Locking device as specified in one of claims 2 to 6, characterized in that the securing surface (17b) extends from the engagement surface (17a) towards the plane of the separation surface (17c). 8. Locking device as specified in one of claims 1 to 7, characterized in that the hook bolt (15) comprises a cam surface (16) which is designed to slide on the engagement element (3). 9. Locking device as set forth in one of claims 1 to 8, characterized in that the follower device (27) has a largely cylindrical part, the circumferential surface of which forms the peripheral boundary surface (28) of the follower device, each end of the boundary surface of the largely cylindrical part of the follower device and the hole (21) in the hook bolt (15) lies in essentially the same plane. 10. Locking device as specified in one of claims 1 to 3, characterized in that the stop surfaces (29a, 29b) are arranged on the peripheral surface of the follower device (27), where the stop surfaces cooperate with the side surfaces (22a, 22b) which are arranged on a shoulder (22) on the detent bolt (15), which shoulder projects inwardly into the hole (21) to transmit rotational motion from the follower device (27) to the detent bolt (15), and a recess (30) made radially inward in the circumferential surface of the follower device arranged between the stop surfaces (29a, 29b) to receive the shoulder (22) when the chin bolt (15) is in a retracted locking position. 11. Locking device as specified in one of claims 1 to 10, characterized in that the hole (21) in the hook bolt (15) is a through hole and that the follower device (27) has a through shaft (32) which is pivotably carried in a lock housing (4) which surrounds the hook bolt and the follower device, which through shaft (32) has devices (33) for connecting the operating element (34). 12. Locking device as specified in one of claims 1 to 11, characterized in that devices (23, 24, 25, 26, 31a, 31b) are designed to releasably prevent relative movement between the follower device and the hook bolt in two fixed positions. 13. Combination of a locking device as stated in one of claims 1 to 12 and an engagement element (3), characterized in that the engagement element (3) is pivotable around a vertical axis of rotation (48). 14. Combination as stated in claim 13, characterized in that the engagement element (3) comprises a convex surface (12b) which is designed to engage with an engagement surface (17b) in a recess (17) in the chin bolt (15).