EP3438382B1 - Latch assembly of a lock - Google Patents

Description

The invention relates to a latch arrangement for a lock and a lock with the latch arrangement.

Latch arrangements are usually used in a lock and are used to hold the door leaf in the stop or in the striking plate. The trap arrangement presented here comprises two trap heads arranged in mirror images one above the other. This type of construction is also called "cross trap" and is for example in EP 2 706 174 A2 described. This type is used in particular for so-called "panic locks".

The two latch heads enable the door to be unlocked and locked in both transverse directions, i.e. door movement directions. If the falling shaft is blocked, the lock is positively locked in both transverse directions. If the falling shaft is not blocked, the lock is unlocked in both transverse directions.

Furthermore, the two latch heads can serve to relieve the pressure of locking elements in the transverse direction in that the two latch heads have a width which is greater than the width of the locking element. This ensures that the closing force of the door is absorbed by the latch heads by the striking plate coming into contact with the latch heads, while the locking element is freely movable relative to the striking plate and is thus relieved of pressure. Thus, the locking element can be withdrawn from the striking plate with minimal force by actuating the lock, and can only be retracted into the housing of the lock when the locking element is retracted the latch heads are unlocked so that they can be pushed back into the housing automatically, for example by manually moving the door away from the striking plate.

It is an object of the present invention to provide a latch arrangement with two latch heads that can be safely unlocked, even with a high preload on the door leaf and / or while avoiding signs of wear.

The problem is solved by the features of the independent claims. The dependent claims have advantageous refinements of the invention.

The invention is thus achieved by the following latch arrangement:
The latch arrangement is arranged in particular in the housing of a lock. The lock in turn is preferably mounted in a door leaf. The housing of the lock preferably includes the lock case. The lock faceplate, which is usually attached, in particular screwed, to the lock case and / or door leaf, is also part of the housing.

To describe the invention, three mutually perpendicular axes are defined: a vertical vertical axis, a transverse axis and a longitudinal axis. The transverse axis runs parallel to the two directions of door movement. The latch arrangement moves into and out of the housing along the longitudinal axis. A transverse direction is defined parallel to the transverse axis. A longitudinal direction is defined parallel to the longitudinal axis.

The trap assembly includes a dropper shaft. This is designed to be movably arranged in the housing of the lock along the longitudinal axis. In particular is the droppings arranged linearly movable along the longitudinal axis. However, it is also possible to design the falling shaft so that it executes a pivoting movement in the housing of the lock with a movement vector along the longitudinal axis.

The trap arrangement further comprises two trap heads. The first latch head is pivotally attached to the latch shaft. The first latch head can be pivoted or rotated about the first pivot axis with respect to the falling shaft.

The second latch head is also pivotally attached to the latch shaft. The second latch head can be pivoted or rotated about the second pivot axis relative to the falling shaft.

The two swivel axes are parallel to each other and parallel to the vertical axis. The two pivot axes are spaced apart. An axis distance between the two swivel axes is therefore greater than 0. This axis distance is defined in a plane perpendicular to the vertical axis, in particular parallel to the transverse axis.

Unless otherwise stated, the latch arrangement is always described in the basic position. In the basic position, the latch heads protrude from the lock housing and are not loaded in the transverse direction.

Each latch head of the latch arrangement preferably has an active surface. The two latch heads are preferably arranged so that the two active surfaces face outwards.

Each trap head of the trap arrangement preferably has a passive surface. When viewed on a plane perpendicular to the vertical axis, the active surface and the passive surface are wedge-shaped and thus at an acute angle to each other. When the door moves in In the transverse direction, an active surface (of the one latch head) and then a passive surface (of the other latch head) always come into contact with the striking plate.

Due to the load in the transverse direction on the respective active surface, the respective latch head pivots about its pivot axis relative to the latch shaft. In particular, the trap head is pivoted until its active surface is parallel to the passive surface of the other trap head. As a result, the active surface of the pivoted latch head and the passive surface of the non-pivoted latch head together form a wedge surface. The load in the transverse direction on this wedge surface leads to a force component along the longitudinal direction and thus to a displacement of the entire latch arrangement into the housing of the lock.

Complementary stop surfaces are preferably formed on the respective latch head and on the latch shaft, which abut one another when the latch head is pivoted until its active surface is parallel to the passive surface of the other latch head.

The respective latch head is preferably attached to the latch shaft via a pivot pin which extends from the latch shaft parallel to the vertical axis. A corresponding hole is formed in the trap head for receiving the pivot pin. However, the pivotable arrangement of the latch head on the latch shaft can also take place in another way, for example by means of a pin which is fixedly connected to the latch head and which is inserted in a hole in the latch shaft.

The center distance between the two pivot axes according to the invention allows design freedom in the design of the kinematics of the latch arrangement. In particular, it is possible to measure the respective pivot axis with the greatest possible distance to be arranged parallel to the transverse direction, to the active surface of the same trap head.

It is preferably provided that the first and second pivot axes are spaced apart transversely to the vertical axis, a straight line defined perpendicular to both pivot axes preferably running parallel to the transverse axis.

The center distance between the two pivot axes is preferably at least 2 mm, more preferably at least 3 mm, particularly preferably at least 4 mm.

Furthermore, the advantageous center distance can be determined depending on the width of the individual trap head. The width of the trap head is measured parallel to the transverse axis and at its widest point. The center distance is preferably at least 5%, more preferably at least 10%, particularly preferably at least 15% of this width. The two trap heads are preferably of the same width.

As already described, each trap head has an active surface facing outwards. The active surface preferably strikes the striking plate even before the passive surface of the other latch head touches the striking plate. The two active surfaces are preferably parallel to one another in the basic position of the latch arrangement. Furthermore, it is preferably provided that the respective active surface is perpendicular to the transverse direction in the basic position.

The two active surfaces are spaced apart from one another by a certain width, measured parallel to the transverse axis. In particular, this distance between the two active surfaces corresponds to the greatest width of the individual trap head. So the "width" is defined by: The distance of the two active areas and / or the greatest width of the individual trap head, each measured parallel to the transverse axis.

An "active surface distance" is defined on each trap head parallel to the transverse axis: an active surface distance is defined from the first pivot axis to the active surface of the first trap head; a further active surface distance is defined from the second swivel axis to the active surface of the second latch head.

It is preferably provided that the two active surface distances are each greater than half the width. The pivot axis of the respective trap head is therefore not in the middle of the trap head. Furthermore, the pivot axis of the respective trap head is thus spaced further than half the width from the associated active surface.

The two active surface distances are preferably of the same size, so that the same kinematics result for both latch heads.

It is preferably provided that the two latch heads are of identical design.

Each of the trap heads has a back. The back faces a tip of the trap heads. The trap heads protrude from the housing with the tip. In particular, the active surface and the passive surface of the trap head meet at the tip of the trap head.

It is preferably provided that the backs are each designed such that a width extension of the latch heads, measured parallel to the transverse axis, remains in the non-pivoted position when the latch heads are pivoted within the width dimension of the latch heads. The backs are particularly preferably rounded.

Each of the two latch heads preferably has a supporting edge. The supporting edge is parallel to the vertical axis and is from the respective one Swivel axis spaced. If the latch arrangement is installed in the housing of the lock, the supporting edge lies on an inside of the housing, in particular on the inside of the lock cuff.

Each trap head preferably has a contact surface. This contact surface is preferably perpendicular to the longitudinal direction. When installed, the contact surface is located inside the housing and points outwards. The supporting edge is preferably an edge of this contact surface.

When the latch arrangement is installed, the support edge forms a support axis due to its abutment on the housing. The respective trap head can be pivoted or rotated about this support axis relative to the housing. In the event of a load in the transverse direction on the active surface of the latch head, the latch head swivels about its pivot axis with respect to the latch shaft. At the same time, the trap head swivels about its support axis in relation to the housing. As a result, the pivoting movement of the latch head leads to a force component acting in the longitudinal direction on the latch shaft. This force component moves the latch assembly into the interior of the housing. Here the swivel axes move.

It is preferably provided that a first angle is formed between the active surface of the first latch head and a straight line which leads through the supporting edge of the first latch head and through the first pivot axis. A second angle is formed between the active surface of the second trap head and a straight line that leads through the supporting edge of the second trap head and through the second pivot axis.

The first angle particularly preferably corresponds to the second angle.

It is preferably provided that the first angle is greater than a third angle between the active surface of the first trap head and a straight line which leads through the supporting edge of the first trap head and through a center point on a line connecting the two pivot axes, and / or the second angle is greater than a fourth angle between the active surface of the second trap head and a straight line which leads through the supporting edge of the second trap head and through a center point on a line connecting the two pivot axes. The first, second, third and / or fourth angle can in particular be an acute angle. As a result, the forces acting on the latch arrangement can be influenced favorably and wear can thus be counteracted.

Two support distances are defined parallel to the transverse axis: a support distance is defined from the first pivot axis to the height of the support edge of the first latch head; a further support distance is defined from the second pivot axis to the height of the support edge of the second latch head. It is preferably provided that the support spacing of the respective trap head is equal to or shorter than the active surface spacing of the same trap head. In relation to the transverse axis, the supporting edge of the respective latch head preferably lies between the pivot axis and the active surface or at the same height as the active surface of the same latch head.

The support spacing is preferably at least 90%, particularly preferably at least 95%, of the active surface spacing of the same latch head.

Furthermore, the support spacing is preferably greater than half the width. The support spacing is preferably at least 102%, particularly preferably at least 105%, of half the width. The "width" is how already defined, the distance between the two active surfaces and / or the width of the individual trap head, each measured parallel to the transverse axis.

The center distance between the swivel axes according to the invention enables both a relatively large active surface distance (from the active surface to the swivel axis) and a relatively large support distance (from the support axis to the swivel axis). The large support spacing, when loaded in the transverse direction on the active surface, acts as a lever arm for the stroke or the linear movement of the drop shaft along the longitudinal axis and thus into the interior of the housing.

It is preferably provided that the first and the second pivot axis are offset from one another in such a way that a force with which the pivot axes can be moved back into a housing of the lock by pressure at least on the active surface of a latch head is less than a hypothetical force with which the pivot axes could be moved back into the housing of the lock by pressure at least on the active surface of a latch head if the pivot axes were arranged parallel to the vertical axis one above the other on a line connecting the pivot axes. The same pressure acts on the active surface. Wear can be effectively prevented by displacing the swivel axes.

It is preferably provided that the first and second pivot axes are offset from one another in such a way that a force with which the supporting edge is supported with respect to the rest of the lock, in particular the housing, particularly preferably the lock face plate, as soon as pressure is exerted on the active surface, is less than a hypothetical force with which the supporting edge would be supported with respect to the rest of the lock if the pivot axes parallel to the vertical axis one above the other on one connecting the pivot axes Line would be arranged. The hypothetical force arises with the same pressure on the active surface. This can prevent wear on the supporting edge.

It is preferably provided that the first and second pivot axes are offset from one another in such a way that a force which acts on a blocking device for locking the trap as soon as pressure is exerted on the active surface is less than a hypothetical force acting on the blocking device would act to block the trap if the swivel axes were arranged parallel to the vertical axis above one another on a line connecting the swivel axes. The hypothetical force arises with the same pressure on the active surface. Such an offset of the swivel axes can prevent wear on the blocking device and on the drop shaft and an easier opening under high preload can be achieved.

The invention further comprises a lock, in particular in the form of a panic lock. The lock according to the invention comprises the latch arrangement according to the invention, and the latch arrangement according to the invention is described in the description and in the claims.

The lock preferably comprises a housing. The housing includes in particular the lock case and the lock faceplate. The trap arrangement described is in particular located in the housing. The latch heads preferably protrude from the housing in the basic position.

The lock preferably comprises a spring which is supported on the housing and on the drop shaft. The spring pushes the drop shaft outwards along the longitudinal axis. Due to the force of the spring, the Drop shaft, as long as no other forces are acting on it, in its basic position and protrudes out of the housing.

The lock preferably comprises at least the blocking device for blocking the falling shaft in its basic position. The blocking device can be operated mechanically and / or electrically. In the blocked position, the large support distance has a favorable effect on the load on the drop shaft.

The latch arrangement is preferably arranged in the housing such that the two latch heads can each be pivoted about a support axis relative to the housing. The respective support axis is formed in particular by the support edges described above, which bear against the inside of the housing, in particular the lock cuff. However, it is also possible to design the support axes and thus the rotatability of the individual latch head with respect to the housing in another way.

Regardless of the structural design of the support axis, the two support distances are defined parallel to the transverse axis: the one support distance is defined from the first pivot axis to the support axis of the first latch head; the further support distance is defined from the second pivot axis to the support axis of the second latch head. The advantageous configurations of these support spacings have already been described with the aid of the latch arrangement.

1. (A) Schloss umfassend ein Gehäuse und eine im am Gehäuse angeordnete Fallenanordnung, wie sie hier beschrieben wurde.
2. (B) Schloss nach Punkt (A), umfassend eine am Gehäuse und am Fallenschaft abgestützte Feder, die den Fallenschaft zur Bewegung entlang der Längsachse nach außen beaufschlagt.
3. (C) Schloss nach einem der Punkte (A) oder (B), wobei die beiden Fallenköpfe jeweils um eine Stützachse gegenüber dem Gehäuse schwenkbar sind, wobei die jeweilige Stützachse zur Schwenkachse desselben Fallenkopfs parallel, jedoch in Richtung der Längsachse versetzt ist, wobei sich insbesondere die Schwenkachsen weiter entfernt von dem Fallenschaft als die Stützachsen befinden. Die Schwenkachsen befinden sich insbesondere in Längsrichtung weiter außen als die Stützachsen.
4. (D) Schloss nach Punkt (C), wobei parallel zur Querachse zwei Stützabstände definiert sind: einer von der ersten Schwenkachse zur Stützachse des ersten Fallenkopfs und einer von der zweiten Schwenkachse zur Stützachse des zweiten Fallenkopfs, wobei jeder Fallenkopf eine nach außen weisende Aktivfläche zum Anschlagen an ein Schließblech aufweist, wobei parallel zur Querachse zwei Aktivflächenabstände definiert sind: einer von der ersten Schwenkachse zur Aktivfläche des ersten Fallenkopfs und einer von der zweiten Schwenkachse zur Aktivfläche des zweiten Fallenkopfs, wobei der Stützabstand des jeweiligen Fallenkopfs gleich oder kürzer dem Aktivflächenabstand desselben Fallenkopfs ist.
5. (E) Schloss nach einem der Punkte (C) oder (D), wobei parallel zur Querachse zwei Stützabstände definiert sind: einer von der ersten Schwenkachse zur Höhe der Stützachse des ersten Fallenkopfs und einer von der zweiten Schwenkachse zur Höhe der Stützachse des zweiten Fallenkopfs, wobei jeder Fallenkopf eine nach außen weisende Aktivfläche zum Anschlagen an ein Schließblech aufweist, wobei die beiden Aktivflächen mit einer Breite, gemessen parallel zur Querachse, beabstandet sind, wobei die beiden Stützabstände jeweils größer sind als die halbe Breite.

The following features are provided in particular for the lock according to the invention:

1. (A) Lock comprising a housing and a latch arrangement arranged in the housing, as described here.
2. (B) Lock according to point (A), comprising a spring which is supported on the housing and on the drop shaft and acts on the drop shaft to move outwards along the longitudinal axis.
3. (C) Lock according to one of the items (A) or (B), the two latch heads each being pivotable about a support axis relative to the housing, the respective support axis being parallel to the pivot axis of the same latch head but offset in the direction of the longitudinal axis, whereby in particular the pivot axes are further away from the drop shaft than the support axes. The pivot axes are located further outside, in particular in the longitudinal direction, than the support axes.
4. (D) Lock according to point (C), two support distances being defined parallel to the transverse axis: one from the first pivot axis to the support axis of the first latch head and one from the second pivot axis to the support axis of the second latch head, each latch head having an outwardly facing active surface for Stop on a striking plate, two active surface distances being defined parallel to the transverse axis: one from the first pivot axis to the active surface of the first latch head and one from the second pivot axis to the active surface of the second latch head, the support distance of the respective latch head being equal to or shorter than the active surface distance of the same latch head is.
5. (E) Lock according to one of the items (C) or (D), two support distances being defined parallel to the transverse axis: one from the first pivot axis to the height of the support axis of the first latch head and one from the second pivot axis to the height of the support axis of the second latch head , wherein each latch head has an outward-facing active surface for striking a striking plate, the two active surfaces having a width, measured parallel to the transverse axis, are spaced, the two support distances are each greater than half the width.

Figur 1

eine schematische Ansicht eines erfindungsgemäßen Schlosses mit erfindungsgemäßer Fallenanordnung gemäß dem Ausführungsbeispiel,

Figur 2

eine Detailansicht der Fallenanordnung im Schloss nach Figur 1,

Figur 3

die Ansicht aus Figur 2, ohne Schlossstulp,

Figur 4

die Ansicht aus Figur 3, ohne den beiden Fallenköpfen,

Figur 5

den Fallenschaft der erfindungsgemäßen Fallenanordnung gemäß dem Ausführungsbeispiel, ohne den beiden Fallenköpfen,

Figur 6

den Fallenschaft der erfindungsgemäßen Fallenanordnung gemäß dem Ausführungsbeispiel, mit beiden Fallenköpfen, und

Figur 7

ein Detail aus Figur 6.

The invention will now be described in more detail using an exemplary embodiment. It shows:

Figure 1

2 shows a schematic view of a lock according to the invention with a latch arrangement according to the invention according to the exemplary embodiment,

Figure 2

a detailed view of the latch arrangement in the castle Figure 1 .

Figure 3

the view Figure 2 , without lock faceplate,

Figure 4

the view Figure 3 , without the two trap heads,

Figure 5

the dropping of the trap assembly according to the embodiment without the two trap heads,

Figure 6

the falling stem of the trap arrangement according to the embodiment, with both trap heads, and

Figure 7

a detail out Figure 6 ,

The figures show an embodiment of a lock 1 with a latch arrangement 5. In the figures, a vertical axis 40, a transverse axis 41 and a longitudinal axis 42 are drawn perpendicular to each other as a Cartesian coordinate system.

Figure 1 shows the lock 1 with its housing 2. The housing 2 comprises a lock case. A lock faceplate 3 is also part of this of the housing 2. The lock face plate 3 is firmly connected to the rest of the housing. The lock face plate 3 can be connected to the door leaf.

The latch arrangement 5 is located in the housing 2. In its basic position, the latch arrangement 5 protrudes from the housing 2 along the longitudinal direction 42.

For the sake of clarity, other components of the lock 1, such as a blocking device for blocking the latch arrangement 5, a follower nut or a locking cylinder, are not shown, but can be arranged in the housing 2 of the lock 1.

The latch arrangement 5 comprises a latch shaft 6, a first latch head 8 and a second latch head 9.

A spring support 4 is formed in the housing 2. A spring 7 is arranged between this spring support 4 and the drop shaft 6. The spring 7 presses the latch assembly 5 into the basic position shown.

The falling shaft 6 is guided in the housing 2 in a linearly movable manner along the longitudinal direction 42. For this purpose, a guide slot 10 is formed in the housing 2. In this guide slot 10 is a guide extension 24 ( Figure 6 ) of the drop shaft 6.

For a clear representation of the latch arrangement 5 is in Figure 3 the lock faceplate 3 is hidden. In Figure 4 the two trap heads 8, 9 are also hidden. Figure 5 only shows the dropper shaft 6. In Figure 6 the housing 2 of the lock 1 is hidden; only the latch arrangement 5, the spring support 4 and the spring 7 are shown. Figure 7 shows an enlarged detail Figure 6 ,

All figures are referred to below.

The drop shaft 6 comprises a first pivot pin 11 and a second pivot pin 12. The first pivot pin 11 extends upwards along the vertical axis 40. The second pivot pin 12 extends downward along the vertical axis 40.

Each of the two trap heads 8, 9 has a hole. The first pivot pin 11 is inserted in the hole of the first latch head 8. The second pivot pin 12 is inserted in the hole of the second latch head 9. As a result, the first latch head 8 can be pivoted about a first pivot axis 13 with respect to the falling shaft 6. The second latch head 9 is pivotable about a second pivot axis 14 with respect to the falling shaft 6. The two pivot axes 13, 14 are parallel to the vertical axis 40.

How in particular Figures 4 and 5 show, the two pivot axes 13, 14 are spaced apart from one another with an axis spacing 22. The center distance 22 is defined here parallel to the transverse axis 41.

Each of the two latch heads 8, 9 has an active surface 15 and an opposite passive surface 16. In particular Figure 6 shows that the active surface 15 is at an acute angle to the passive surface 16 of the same latch head 8, 9. The two active surfaces 15 point outward with respect to the transverse axis 41 and are parallel to one another. Furthermore, the two active surfaces 15 are perpendicular to the transverse axis 41. The passive surfaces 16 are in particular parallel to the vertical axis 40 and are inclined with respect to the transverse axis 41 and the longitudinal axis 42.

Like, for example Figures 2 and 3 show, stop surfaces 19 are formed on the latch heads 8, 9 and on the latch shaft 6. The stop surfaces 19 limit the pivoting of the respective latch head 8, 9 relative to the latch shaft 6.

In particular Figure 3 shows that each of the two latch heads 8, 9 has a contact surface 17. The contact surface 17 is perpendicular to the longitudinal axis 42. The contact surface 17 forms a support edge 18, the support edge 18 being the edge of the contact surface 17 which is parallel to the vertical axis 40 and is closest to the associated active surface 15.

In the basic position, the contact surface 17 and the supporting edge 18 rest on the inside of the lock cuff 3. The support edge 18 thus forms a support axis 23 about which the respective latch head 8, 9 can be pivoted or rotated relative to the housing 2. When the latch head 8, 9 is pivoted, the contact surface 17 lifts off from the inside of the housing, the supporting edge 18 remaining in contact on the inside and rolling on the inside. When the latch head 8, 9 is pivoted, the latch head is rotated about the pivot axis 13, 14, the pivot axes 13, 14 simultaneously being moved into the interior of the housing 2.

In particular Figures 6 and 7 show the following:
A width 25 that describes both the distance between the two active surfaces 15 and the greatest width of the individual latch head 8, 9; each defined parallel to the transverse axis 41.

The distances between the respective active surface 15 and the associated pivot axis 13, 14 of the same latch head 8, 9 are shown as active surface distances 26. Parallel to the respective active surface distance 26, the support distance 20 from the respective support axis 23 to the pivot axis 13, 14 of the same latch head 8, 9 is measured. The support distance is defined parallel to the transverse axis 41.

Due to the center distance 22 between the two pivot axes 13, 14, both the active surface distance 26 and the support distance 20 can be made relatively large.

A load in the transverse direction on the active surface 15 of a latch head 8, 9 acts with respect to the support axis 23 with a lever arm 21. The torque generated with the lever arm 21 about the support axis 23 leads to a corresponding force on the latch shaft 6 in the direction of the longitudinal axis 42, whereby the relatively large support distance 20 acts as a lever. As a result, the resulting force on the drop shaft 6 can be kept low. Wear on the support edge 18 can thus be prevented.

Figure 7 further shows on the basis of the second latch head 9 that a second angle α is formed between the active surface 15 of the second latch head 9 and a straight line which leads through the supporting edge 18 of the second latch head 9 and through the second pivot axis 14. Not shown is a corresponding first angle a, which is formed between the active surface 15 of the first latch head 8 and a straight line which leads through the supporting edge 18 of the first latch head 8 and through the first pivot axis 13. The size of the first angle α corresponds to the size of the second angle a.

Furthermore, in Figure 7 shown that the second angle α is greater than a fourth angle β between the active surface 15 of the second trap head 9 and a straight line through the support edge 18 of the second trap head 9 and through a center point 43 on a line connecting the two pivot axes 13, 14 leads. Analogously and not shown, the first angle α is greater than a third angle β between the active surface 15 of the first trap head 8 and a straight line which passes through the supporting edge 18 of the first trap head 8 and through a center 43 on one of the two pivot axes 13, 14 connecting line leads.

LIST OF REFERENCE NUMBERS

1

lock

2

casing

3

lock face

4

spring support

5

fall arrangement

6

latch shaft

7

feather

8th

first trap head

9

second trap head

10

guide slot

11

first pivot pin

12

second pivot pin

13

first pivot axis

14

second pivot axis

15

active surfaces

16

passive surfaces

17

contact surfaces

18

support edges

19

stop surfaces

20

support distance

21

lever arm

22

Wheelbase

23

support axes

24

Guide extension

25

width

26

Active area distance

40

vertical axis

41

transverse axis

42

longitudinal axis

43

Focus

α

first / second angle

β

third / fourth angle

Claims (15)

1. A latch-bolt assembly (5) for a lock (1), wherein are defined respectively vertical to each other a vertical axis (40), a transverse axis (41) and a longitudinal axis (41), comprising:

   • a latch-bolt shaft (6) for the displaceable arrangement in a housing (2) of the lock (1) along the longitudinal axis (42),

   • a first latch-bolt head (8), which is attached to the latch-bolt shaft (6) pivotably about a first pivot axis (13), wherein the first pivot axis (13) is parallel to the vertical axis (40), and

   • a second latch-bolt head (9), which is attached to the latch-bolt shaft (6) pivotably about a second pivot axis (14), wherein the second pivot axis (14) is parallel to the vertical axis (40), and

   characterized in that
   the first and the second pivot axes (13, 14) are spaced apart from each other.
2. The latch-bolt assembly according to claim 1, characterized in that the first and the second pivot axes (13, 14) are transversely spaced apart from the vertical axis, wherein preferably a straight line, which is defined vertically to both pivot axes (13, 14), extends parallel to the transverse axis (41).
3. The latch-bolt assembly according to claim 1 or 2, characterized in that an axis distance (22) between the two pivot axes (13, 14) amounts at least to 2 mm, preferably at least to 3 mm, particularly preferred at least to 4 mm.
4. The latch-bolt assembly according to any of the preceding claims,

   • wherein the individual latch-bolt head (8, 9) has a largest width (25), measured parallel to the transverse axis (41), and

   • wherein the axis distance (22) between the two pivot axes (13, 14) amounts at least to 5 %, preferably at least to 10 %, particularly preferred at least to 15 % of the width (25).
5. The latch-bolt assembly according to any of the preceding claims,

   • wherein each latch-bolt head (8, 9) includes an active surface (15) oriented to the outside for abutting against a strike plate,

   • wherein the two active surfaces (15) are spaced apart by a width (25), measured parallel to the transverse axis (41),

   • wherein two active surfaces distances (26) are defined parallel to the transverse axis (41): one being from the first pivot axis (13) to the active surface (15) of the first latch-bolt head (8) and one being from the second pivot axis (14) to the active surface (15) of the second latch-bolt head (9), and

   • wherein the two active surfaces distances (26) are respectively larger than half the width (25).
6. The latch-bolt assembly according to claim 5, wherein the two active surfaces distances (26) have the same size.
7. The latch-bolt assembly according to any of the preceding claims, characterized in that the two latch-bolt heads (8, 9) are formed identically.
8. The latch-bolt assembly according to any of the preceding claims,

   • wherein each latch-bolt head (8, 9) includes a back opposite a tip of the latch-bolt head (8, 9), and

   • wherein the backs are respectively formed such that a width extension of the latch-bolt heads (8, 9) measured parallel to the transverse axis (41), upon pivoting the latch-bolt heads (8, 9), remains within the width extension of the latch-bolt heads (8, 9) in the non-pivoted position.
9. The latch-bolt assembly according to any of the preceding claims, wherein each latch-bolt head (8, 9) includes a support edge (18) parallel to the vertical axis (40), wherein, upon resting against the housing (2), the respective support edge (18) is formed for forming a support axis (23), about which the latch-bolt head (8, 9) is rotatable in relation to the housing (2).
10. The latch-bolt assembly according to claim 9, characterized in that a first angle (α) is formed between the active surface (15) of the first latch-bolt head (8) and a straight line, which extends through the support edge (18) of the first latch-bolt head (8) and through the first pivot axis (13), and in that a second angle (α) is formed between the active surface (15) of the second latch-bolt head (9) and a straight line, which extends through the support edge (18) of the second latch-bolt head (9) and through the second pivot axis (14), wherein the first angle (α) corresponds to the second angle (α).
11. The latch-bolt assembly according to claim 10, characterized in that a first angle (α) is larger than a third angle (β) between the active surface (15) of the first latch-bolt head (8) and a straight line, which extends through the support edge (18) of the first latch-bolt head (8) and through a centre point (43) on a line connecting the two pivot axes (13, 14), and/or in that the second angle (α) is larger than a fourth angle (β) between the active surface (15) of the second latch-bolt head (9) and a straight line, which extends through the support edge (18) of the second latch-bolt head (9) and through a centre point (43) on a line connecting the two pivot axes (13, 14).
12. The latch-bolt assembly according to any of the claims 9 to 11,

    • wherein two support distances (20) are defined parallel to the transverse axis (41): one being from the first pivot axis (13) to the height of the support edge (18) of the first latch-bolt head (8) and one being from the second pivot axis (14) to the height of the support edge (18) of the second latch-bolt head (9),

    • wherein each latch-bolt head (8, 9) includes an active surface (15) oriented to the outside for abutting against a strike plate,

    • wherein two active surfaces distances (26) are defined parallel to the transverse axis (41): one being from the first pivot axis (13) to the active surface (15) of the first latch-bolt head (8) and one being from the second pivot axis (14) to the active surface (15) of the second latch-bolt head (9), and

    • wherein the support distance (20) of the respective latch-bolt head (8, 9) is equal to or shorter than the active surface distance (26) of the same latch-bolt head (8, 9).
13. The latch-bolt assembly according to any of the preceding claims, wherein each latch-bolt head (8, 9) includes an active surface (15) oriented to the outside for abutting against a strike plate, and wherein the first and the second pivot axes (13, 14) are offset to each other in such a manner that a force, with which the pivot axes (13, 14) are movable back into a housing (2) of the lock (1) by means of pressure at least on one active surface (15) of the latch-bolt head (8, 9), is lower than a hypothetical force, with which the pivot axes (13, 14) would be movable back into the housing (2) of the lock (1) by means of a pressure at least on one active surface (15) of the latch-bolt head (8, 9), if the pivot axes (13, 14) would be disposed parallel to the vertical axis (40) one above the other on a line connecting the pivot axes (13, 14).
14. The latch-bolt assembly according to any of the claims 9 to 13,

    • wherein two support distances (20) are defined parallel to the transverse axis (41): one being from the first pivot axis (13) to the height of the support edge (18) of the first latch-bolt head (8) and one being from the second pivot axis (14) to the height of the support edge (18) of the second latch-bolt head (9),

    • wherein each latch-bolt head (8, 9) includes an active surface (15) oriented to the outside for abutting against a strike plate,

    • wherein the two active surfaces (15) are spaced apart by a width (25), measured parallel to the transverse axis (41),

    • wherein the two support distances (20) are respectively larger than half the width (25).
15. A lock (1), comprising:

    • a housing (2), and

    • a latch-bolt assembly (5) disposed at the housing (2) according to any of the preceding claims.

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