EP3822438A1 - Automatic lock - Google Patents

Abstract

The invention relates to a lock (50) with a main lock (51) having a latch (2) and with a bolt part (57), which bolt part (57) can be closed together with the latch (2) and controlled by a drive rod from a pre-locked locking position and when closing a door equipped with the lock (50) comprising a leaf and frame, controlled by a trigger (3), driven by an energy storage device (8), locks from a closed position, the trigger (3) engaging the drive rod (7, 53,54) is in a spring-loaded pivoting lever that holds the energy store (8) in its charged position and is pivotable in the faceplate plane, and upon contact with a frame-side contact surface releases a main lock slide (7) coupled to the connecting rod (53, 54) and with a feeler element (44) that scans the frame-side stop surface of the door. In addition to an automatic mode in which the sash is securely locked, a seal To enable locking, it is provided that a coupling device is effective between the main lock slide and a cylinder-driven gear (31), which couples to the drive rod when pre-locking via the cylinder and enables the drive rod to move in the locking direction, which further the bolt part (57) moved in the forward direction.

Description

The invention relates to a lock according to the preamble of claim 1.

Such a lock is out of the DE 10107744 B4 already known. The well-known lock has a latch and a bolt. Pivoting bolts are provided in secondary lock cases. The lock is equipped with a connecting rod which is used to control the secondary lock cases. A trigger also acts on this drive rod, which fixes the drive rod, on which an energy storage mechanism acts, in an open position until the sash dips into the frame and the trigger releases the drive rod and moves it into its locking position.

From the EP 2388420 A2 a lock with a delayed latch retraction has become known, with which a relief of the bolt causing the tight fit is to be achieved.

The disadvantage of the known configurations is that the locks do not provide a sufficient sealing function and there is a risk that, if the sealing pressure is too high, the automatic locking will be hindered by the sash not fully resting on the frame.

The object is therefore to provide a lock which, in addition to an automatic mode in which the sash is safely locked, enables a tight fit locking.

To solve this problem, the invention provides a coupling device for a lock according to the preamble, which is effective between the main lock slide and a cylinder-driven gear, which couples with the drive rod when pre-locking via the cylinder and enables a movement of the drive rod in the locking direction, which the bolt part moved further in the semicircle direction. This enables the bolt to penetrate further into a bolt engagement and this can be done independently of the automatic function from the movement of the main lock slide.

It has been proven that the locking part is a cylindrical bolt which is rotatably mounted and has axially extending tightening bevels. These bolts are easy and inexpensive to manufacture.

In order to achieve a tightening over the entire height of the sash, it is provided that the bolt is housed in a secondary lock case. The secondary lock case can be located at a smaller distance from the sash corners and correct a gap between the sash and frame caused by twisting the sash.

A simple embodiment of the coupling device provides that it consists of a coupling piece with a coupling piece toothing and a main lock slide toothing. Toothings can be easily produced, coupled and decoupled.

A simple control of the coupling device provides that the coupling piece is moved over a disk that is driven by the gearbox.

The required coupling movement can be achieved with structurally and spatially simple measures if the coupling piece is guided in the housing with a coupling piece guide pin.

Fig. 1a

ein Hauptschloss in Warteposition mit geöffnetem Flügel von der ersten Seite mit geöffneter Schlossdecke,

Fig. 1

b ein Hauptschloss nach Fig. 1a von der Rückseite, mit einem Durchbruch,

Fig. 2

eine Übersicht über eine Verriegelung mit einem Hauptschloss nach Fig. 1a und Nebenschlössern,

Fig. 3a

ein Nebenschloss in Warteposition mit geöffnetem Flügel von der ersten Seite mit teilweise geöffneter Schlossdecke,

Fig. 3b

ein Nebenschloss nach Fig. 3a von der Rückseite mit einem ausgebrochenem Boden,

Fig. 4a

ein Hauptschloss mit ausgelöstem Verschluss bei geschlossenem Flügel von der ersten Seite mit geöffneter Schlossdecke,

Fig. 4b

ein Hauptschloss nach Fig. 4a von der Rückseite betrachtet mit einem fensterartigen Ausbruch,

Fig. 5a

ein Nebenschloss in einer automatisch ausgelösten Verriegelungsstellung,

Fig. 5b

ein Nebenschloss nach Fig. 5a von der Rückseite mit fensterartigen Durchbrüchen,

Fig. 6a

ein Hauptschloss mit ausgelöstem Verschluss und Dichtschlussverriegelung bei geschlossenem Flügel von der ersten Seite mit geöffneter Schlossdecke,

Fig. 6b

ein Hauptschloss nach Fig. 6a von der Rückseite betrachtet mit einem fensterartigen Ausbruch,

Fig. 7a

ein Nebenschloss in einer automatisch ausgelösten Verriegelungsstellung und Dichtschlussverriegelung,

Fig. 7b

ein Nebenschloss nach Fig. 7a von der Rückseite mit fensterartigen Durchbrüchen,

Fig. 8a

ein Hauptschloss bei betätigtem Drücker von der ersten Seite mit geöffneter Schlossdecke,

Fig. 8b

ein Hauptschloss nach Fig. 8a von der Rückseite mit einem Durchbruch,

Fig. 9a

ein Hauptschloss bei Schlüsselbetätigung von der ersten Seite mit geöffneter Schlossdecke, und

Fig. 9b

ein Hauptschloss nach Fig. 9a von der Rückseite mit einem Durchbruch.

The drawings show further advantageous embodiments. It shows:

Fig. 1a

a main lock in waiting position with the sash open from the first side with the lock cover open,

Fig. 1

b a main lock after Fig. 1a from the back, with a breakthrough,

Fig. 2

an overview of a lock with a main lock Fig. 1a and side locks,

Fig. 3a

a secondary lock in waiting position with the sash open from the first side with the lock cover partially open,

Figure 3b

a secondary lock after Fig. 3a from the back with a broken floor,

Figure 4a

a main lock with released lock with the sash closed from the first side with the lock cover open,

Figure 4b

a main lock after Figure 4a viewed from the rear with a window-like breakout,

Figure 5a

a secondary lock in an automatically triggered locking position,

Figure 5b

a secondary lock after Figure 5a from the back with window-like openings,

Figure 6a

a main lock with released lock and tight-fitting locking with the sash closed from the first side with the lock cover open,

Figure 6b

a main lock after Figure 6a viewed from the rear with a window-like breakout,

Figure 7a

a secondary lock in an automatically triggered locking position and sealing lock,

Figure 7b

a secondary lock after Figure 7a from the back with window-like openings,

Figure 8a

a main lock with the handle pressed from the first side with the lock cover open,

Figure 8b

a main lock after Figure 8a from the back with a breakthrough,

Figure 9a

a main lock when the key is operated from the first side with the lock cover open, and

Figure 9b

a main lock after Figure 9a from the back with an opening.

The in Fig. 1 The main lock case shown is the faceplate with 1 and the latch with 2. A trigger 3 is provided on the trap 2, which is pivotably attached to the trap 2 and protrudes with an arm 4 in the direction of the trap tail 5. A main lock slide 7 is guided in the housing 6 parallel to the faceplate 1. This is acted upon by force by a compression spring 8. The compression spring 8 surrounds a spring guide 9 which is fixed as a bolt with a head in the housing 6. A main lock slide blocking surface 10, on which the arm 4 engages with a blocking edge 11, is attached to the main lock slide 7. The latch tail 5 of the latch 2 is assigned an additional change 12 on a buffer 13 and a latch leg spring 14. The additional change 12 lies in the pivoting range of a nut change arm 15 of the nut change 16. A second arm of the nut change 16 forms a nut change arm 17. The nut change arm 17 is hook-shaped and has a rotary bearing 18 for an alternating pressure piece 19. The alternating pressure piece 19 has an alternating pressure piece curve 20 into which a coupling piece pin 21 engages. The hook-shaped end of the nut changing arm 17 points upward in the drawing and forms the nut changing actuating surface 22 with a perpendicular to the drawing surface. A locking slide 23 lies with an upwardly angled stop 24 in the pivoting area of the nut changing actuation surface 22, so that when the nut changing 16 is rotated, the nut changing arm 17 strikes the locking slide 23. Furthermore, a leg spring 25 acts on the locking slide 23. The main lock slide 7 has a main lock slide control cam 26, which can be moved together with it, and a main lock slide toothing 27 ( Figure 1b ). An extension arm 28 is pivotably mounted at a pivot point 29 in the ceiling (not shown) of the main lock 51. The end of the extension arm 28 is assigned to the main lock bolt 30. On the side facing away from the faceplate 1 there is a gear 31, the gear wheel 32 of which has a cam 33 which protrudes from the plane of the drawing and can strike the free end of the alternating pressure piece 19.

From the Figure 1b it can be seen that the main slide 7 and its main lock slide toothing 27 lie opposite a coupling piece toothing 34 of the coupling piece 35. The coupling piece 35 has a J-shaped recess 36. The cam 37 of a disk 38 engages in the recess 36. The coupling piece guide pins 39 and 40 are also attached to the coupling piece 35. The coupling piece guide pin 40 engages in a bottom sheet metal guide curve 41a. The coupling piece guide pin 39 engages in a second bottom sheet metal guide curve 41b ( Figure 8b ) a. A flat spring 43 supports the coupling piece 35 against the disk 38. The bottom sheet metal guide curves 41a, 41b have a crutch-shaped course.

The design works together as follows:
The main lock slide 7 loaded by the compression spring 8 guided in the spring guide 9 is held in the upper position by the locking edge 11 of the trigger 3. The main lock bolt 30 is held in the retracted position by the leg spring 42 behind the faceplate 1. Due to the position of the gear 31 and the profile cylinder (not shown), the alternating pressure piece 19 is not acted upon by the cam 33 of the gear wheel 32. The coupling piece pin 21 also holds the alternating pressure piece 19 in position via the alternating pressure piece cam 20 so that it could be actuated by the gear wheel 32 with the cam 33. The coupling piece 35 is held in position by the disc 38 by means of the cam 37. The flat-shaped spring 43 mounted in the coupling piece 35 additionally presses the coupling piece 35 against the disk 38. In this position, the coupling piece 35 with the coupling piece toothing 34 is decoupled from the main lock slide toothing 27.

The Fig. 2 shows an overview of the lock 50. This consists of a main lock 51 and one or more secondary lock cases 52. The connection of the secondary lock cases 52 takes place via the faceplate 1 and the sliding rods 53, 54 guided thereon. The driving rods 53, 54 are with the main lock slide 7 and the connecting rod slide 56 of the secondary lock cases 52 are drivingly connected.

The Figs. 3a and 3b show a secondary lock case 52 in the open state of the door corresponding to FIG Figs. 1a and 1b of the main lock 51. A housing 55 is attached behind the faceplate 1. The drive rod 53 or 54 is drivingly connected to the drive rod slide 56, which is slidably guided in the housing 55. Transverse to this, the housing 55 guides a bolt 57 by means of two beads 58 and an elongated hole 59 in the base 60. A square end 61 of the bolt 57 causes a non-rotatable, displaceable mounting and has a pin 62 which engages in the elongated hole 59. The pin 62 engages in a control cam 63. The control cam 63 is a Z-shaped transverse slot, the end of which is a Bay 64 running parallel to its sliding section. In addition, the control cam 63 has a recess 65 which leads to a stair-step-shaped contour of a side wall of the control cam 63.

A hook bolt 66 is pivotably mounted below the bolt 57. An actuating mandrel 67, which can be displaced over the connecting rod slide 56, slides along the hook bolt rear side 84 and causes a pivoting movement of the hook bolt 66 about the axis of rotation 68. The actuating mandrel 67 is guided in a guide curve 69.

The main lock slide 7 driven in the main lock 51 is connected to the drive rod slide 56 by the drive rods 53, 54. The connecting rod slide 56 holds the bolt 57 held in the retracted position by the control cam 63 and the pin 62. The actuating mandrel 67 is held in a horizontal position by the main lock slide 7 and held in the vertical direction in the base 60 and cover by the guide curve 69. When actuated, this can drive past the axis of rotation 68 of the hook bolt 66 and pivot the hook bolt 66 out. Here the actuating mandrel 67 holds the hook bolt 66 in the retracted position.

As already described above, the trigger 3 is pivotably mounted in the latch 2 and the trigger actuating surface 44 acts against the action of a leg spring 45 when it comes into contact with a latch entry opening of a strike plate and releases the main lock slide blocking surface 10. If the door is closed, the latch 2 loaded by the latch leg spring 14 therefore moves into the main lock 51 when it hits the door frame. If the latch 2 is pushed out again with the door closed, it penetrates the latch entry opening. The trigger 3 is pressed in on the trigger actuation surface 44. As a result, the arm 4 is pivoted out of the main lock slide locking surface 10 and the main lock slide 7 loaded by the compression spring 8 moves downward until its stop 46 hits the coupling piece locking surface 47. The main lock 51 takes the in Figures 4a and 4b position shown.

The locking slide 23, which is spring-loaded by the leg spring 25, is in the locked position above the nut changing actuation surface 22, so that the main lock slide 7 could be operated by the nut changing arm 17. The locking slide 23 is rotatably mounted on the main lock slide 7 via the axis 48.

From the Figure 4b it can be seen that the main lock slide 7 and the coupling piece 35 remain out of engagement.

For the secondary lock case 52 this results in the following positions of the components and as in FIG Figures 5a and 5b shown: If the connecting rod slide 56 is moved a distance down in the main lock 51 after actuation of the trigger 3, the bolt 57 moves out a part of the distance in front of the faceplate 1 due to the pin 62, which engages the downwardly displaced control cam 63. The bolt 57 has tightening bevels which increase axially from the tip of the bolt 57 and which give the bolt 57 a wedge-shaped shape in the perpendicular direction. The pin 62 is now on the horizontal section of the recess 65. B. in the event of a break-in, the bolt 57 is pushed back, the connecting rod slide 56 would be pushed back via the pin 62 in the control cam 63 and thus unlocked all locking elements of the lock. The recess 65 is therefore made in the control cam 63 of the connecting rod slide 56. The pin 62 can only move in front of the vertical edge that runs parallel to the direction of displacement and cannot cause any displacement force on the connecting rod slide 56. Since the leg spring 70 always acts on the bolt 57 in the direction of the faceplate 1, the pin 62 always rests on the straight front longitudinal edge of the control cam 63. As a result, the pin 62 can always be operated without blocking anything. The hook bolt 66 is pivoted out in front of the faceplate 1 via the axis of rotation 68 by a downward movement of the actuating mandrel 67 guided in the guide curve 69. As a result of the movement of the hook bolt 66 and the pressure of the leg spring 71, the two back pressure safety devices 72 move with the pin 73 through the guide curve 69. The back pressure safety device 72 consists of a pivotable lever which engages with the pin 73 in the guide curve 69 and with the drive rod slide 56 is carried. When the hook bolt 66 is pivoted out, the back pressure safety device lies almost horizontally and engages behind the hook bolt 66 so that it is then in the locked position and is supported with the pin 73 on the end of the guide curve 69 of the secondary lock case 52.

A door equipped with the lock 50 is already locked in this position. The hook bolts 66 now engage in the corresponding bolt openings in the frame and prevent the sash from opening. However, the sash is not yet pressed against the frame. This tight seal must be activated manually. For this purpose, the previously automatically locked lock is tightly closed by turning the key on the profile cylinder (not shown). This is in the Figs. 6a and 6b and for the secondary lock cases in the Figures 7a and 7b shown. When the profile cylinder, not shown, is actuated, the gear 31 is actuated. Thus, the disk 38 with the cam 37 moves the coupling piece 35 with the coupling piece guide pins 39, 40 through the bottom sheet metal guide curves 41a, 41b ( Figure 8b ). The slightly arched course of the horizontal section of the curb-shaped floor sheet metal guide curves 41a, 41b ensures that the coupling piece 35 is easily lifted and set down, so that the coupling piece toothing 34 into the Main lock slide toothing 27 engages. The flat-shaped spring 43 compensates for the rotational movement of the disc 38 with the cam 37 and the vertical movement of the coupling piece 35 guided in the sheet metal guide cams 41a, 41b.

The coupling piece toothing 34 is pushed into the main lock slide toothing 27 by the movement of the disk 38 with the cam 37. At the same time, the coupling piece pin 21 pushes the alternating pressure piece 19 guided in the alternating pressure piece curve 20 and the locking slide 23, which is spring-loaded by the leg spring 25, in the direction of the faceplate 1. This has the effect that the gear wheel 32 can rotate freely with the cam 33 without actuating the alternating pressure piece 19. In addition, when the locking slide 23 is pivoted away from the nut change actuation surface 22, a further downward movement of the main lock slide 7 is possible and is supported by the disk 38 and the coupling piece 35. The downward movement of the main lock slide 7 actuates the extension arm 28, which is mounted in the housing 6 at the pivot 74, in the main lock slide control cam 26, so that the main lock bolt 30 extends. If the main lock bolt 30 is extended, the main lock slide 7 moves a bit lower and the locking tab 76 moves behind the bolt locking surface 77. The main lock bolt 30 is thus secured against being pushed back from the outside.

In the Figs. 7a and 7b the consequences for the secondary lock case 52 are illustrated. By actuating the gear in the main lock 51, the connecting rods 53 and 54 are moved further downwards. As a result, the connecting rod slide 56 is also moved downwards and the bolt 57 is pushed further in front of the faceplate 1 via the pin 62 and the control cam 63. If the beveled bolt 57 hits the frame part of the door, which is not shown, the door leaf is pulled into the door seal and the sealing connection is effected.

Based on Figs. 8a and 8b it can be seen that the lock 50 can also be opened via a lever handle. To do this, the sealing function on the main lock 51 must be deactivated by turning the key on the profile cylinder (not shown) ( Figs. 4a and 4b ). The main lock bolt 30 is locked back into the housing 6 of the main lock case 51 and the bolts 57 of the secondary lock cases 52 are correspondingly Figures 5a and 5b halfway in front of the faceplate 1. The locking slide 23 of the main lock 51 is in the locked position above the nut change actuation surface 22. The main lock slide 7 rests on the coupling piece locking surface 47.

The nut 78 can be moved in a rotary manner via a pusher (not shown). The socket 78 is concentric to the socket change 16 and has a square receptacle. The socket change 16 and the socket 78 can be rotated to a limited extent relative to one another, so that a Rotation of the nut change 16 does not entail any rotation of the nut 78. The socket 78 engages with radially projecting claws in the receptacles, which are enlarged for this purpose, of the socket change 16. In the exemplary embodiment, the four claws 79 engage in the socket actuation recesses 80. When the trigger is actuated, these four claws 79 of the socket 78 take the socket change 16 with them. As it rotates, the nut changing actuation surface 22 of the nut changing arm 17 abuts the locking slide 23 and pushes it upwards together with the main lock slide 7 connected to it.

At the same time, the nut changing arm 15 swivels and, after passing through a certain swiveling angle, encounters the additional swap 12. The trap leg spring 14 is tensioned. As a result, the nut changing arm 17 and its actuation of the main lock slide 7 precede the additional change and the latch 2 is only withdrawn into the lock when the connecting rods 53, 54 have pulled the hook bolts 66 back into the secondary lock case via the connecting rod slide 56. This is already in from the patent specification EP 2388420 A2 known, to the disclosure of which reference is made in this regard. The displacement of the main lock slide 7 also means that the main lock slide blocking surface 10 comes above the arm 4.

In the exemplary embodiment, two parallel main lock slide blocking surfaces 10 are provided so that the main lock slide 7 is held in position even when the handle is not fully actuated. In such a case, the main lock slide 7 would only execute a partial stroke of its way. When the trigger is released, the nut 78 is pushed back into the starting position by the compression spring 81 and a connecting piece 82. The main lock slide 7 lowers a little and is fixed on the locking edge 11 by the trigger 3 loaded with the leg spring 45.

The main lock 51 is thus in the waiting position again or the door is open.

Pressing the handle causes ( Figures 3a and 3b ) in the secondary lock cases 52: The connecting rod slide 56 is moved upwards by the connecting rods 53, 54 and pulls the bolt 57 back via the control cam 63 and the pin 62. At the same time, the actuating mandrel 67 is moved upward through the guide curve 69. The hook bolt 66 is pivoted in here. The back pressure safety device 72 is lifted out of the straight section of the control cam by the drive rod slide surface 82. Thus, when the hook bolt 66 is drawn in via the actuating pin 67, the pin 73 can slide through the lower part of the guide curve 69.

The bolt 57 loaded by the torsion spring 70 can be withdrawn completely via the control cam 63 and the pin 62. During the upward movement of the connecting rod slide 56, the pin 62 is in permanent contact with the continuous inclined surface of the control cam 63.

The lock 50 can also be opened by means of the key, for example from the outside. This change opening via the cylinder (not shown) initially causes the main lock bolt 30 in the main lock 51 to be closed, as already described above, and the bolts 57 of the secondary lock cases 52 to be pulled back until the pin 62 reaches the recess 65. As a result, the bolt 57 takes the in Figures 5a and 5b position shown.

The lock 50 is thus removed from the sealing function by turning the key on the profile cylinder.

The locking slide 23 is in the locking position above the nut change actuation surface 22. The main lock slide 7 rests on the coupling piece locking surface 47.

A further rotation of the bowl in the profile cylinder causes the gear 31 to drive the gear 32 with the cam 33. The cam 33 thereby moves upward in the drawing and actuates the alternating pressure piece 19 connected to the nut change 16. The alternating pressure piece 19 sets the rotatably mounted nut change 16 in rotation. As a result of this, the nut changing arm 17 moves upwards and strikes the stop 24 of the locking slide 23 with the nut changing actuating surface 22 and guides this together with the main lock slide 7 up to the locking position.

As already described above, the rotation of the nut change 16 causes the latch 2 to be withdrawn by means of the additional change 12, which is acted upon by the nut change arm 15.

When the key is released, the nut change 16 with the connected alternating pressure piece 19 falls back into the starting position. The main lock slide 7 is held by the main lock slide locking surface 10 and the arm 4.

The secondary lock cases 52 are unlocked when opening via the change or the cylinder in a manner analogous to opening via the socket 78.

The lock is now in the waiting position or the door is open.

List of reference symbols

1

Faceplate

2

Cases

3

trigger

4th

poor

5

Trap tail

6th

casing

7th

Main lock slide

8th

Compression spring

9

Lead management

10

Main lock slide blocking area

11

Barrier edge

12th

Additional bill

13th

buffer

14th

Trap leg spring

15th

Nut changing arm

16

Nut change

17th

Nut changing arm

18th

Pivot bearing

19th

Alternating pressure piece

20th

Alternating pressure piece curve

21

Coupling piece spigot

22nd

Nut change actuation surface

23

Gate valve

24

attack

25th

Leg spring

26th

Main lock slide control cam

27

Main lock slide toothing

28

Extension arm

29

pivot point

30th

Main lock bolt

31

transmission

32

gear

33

Cam

34

Coupling piece toothing

35

Coupling piece

36

Recess

37

Cam

38

disc

39

Coupling piece guide pin

40

Coupling piece guide pin

41a

Floor sheet metal guide curve

41b

Floor sheet metal guide curve

42

Leg spring

43

Flat spring

44

Trigger actuation surface

45

Leg spring

46

attack

47

Coupler blocking area

48

axis

50

Locking

51

Main castle

52

Secondary lock case

53

Connecting rod

54

Connecting rod

55

casing

56

Connecting rod valve

57

bolt

58

Bead

59

Long hole

60

ground

61

Square end

62

Cones

63

Control curve

64

bay

65

Recess

66

Hook bolt

67

Operating mandrel

68

Axis of rotation

69

Guide curve

70

Leg spring

71

Leg spring

72

Back pressure protection

73

Cones

74

pivot point

75

Bolt blocked area

76

Locking tab

77

Bolt blocked area

78

nut

79

claw

80

Nut actuation recess

81

Compression spring

82

Connector

83

Connecting rod slide surface

84

Hook bolt back

Claims (6)

Latch (50) with a main lock (51) having a latch (2) and with a bolt part (57), which bolt part (57) can be closed back together with the latch (2) and controlled by a drive rod from a pre-locked locking position and when closing one with the door equipped with the shutter (50) and comprising a door, controlled by a trigger (3), driven by an energy store (8), pre-locks from a closed position, the trigger (3) engaging the drive rod (7, 53, 54) is in a spring-loaded pivot lever that holds the energy store (8) in its charged position and can be pivoted in the faceplate plane, and when it comes into contact with a frame-side contact surface, it releases a main lock slide (7) coupled to the drive rod (53, 54) and with one the frame-side stop surface the door-scanning feeler element (44),
marked by
a coupling device which is effective between the main lock slide and a cylinder-driven gear (31) which, when pre-locking, couples with the drive rod via the cylinder and enables the drive rod to move in the locking direction, which moves the bolt part (57) further in the pre-locking direction. Lock according to claim 1,
characterized,
that the locking part is a cylindrical bolt (57) which is rotatably mounted and has axially extending tightening bevels. Lock according to claim 1 or 2,
characterized,
that the bolt (57) is housed in a secondary lock case. Lock according to claim 1,
characterized,
that the coupling device consists of a coupling piece (35) with a coupling piece toothing (34) and a main lock slide toothing (27). Lock according to claim 4,
characterized,
that the coupling piece (35) is moved over a disc (38) which is driven by the gear (31). Lock according to claim 4 or 5,
characterized,
that the coupling piece (35) with coupling piece guide pins (39, 40) is guided in the housing (6).

Images