CN105658884A - Mortice lock assembly for use with cylinder cam in three zones - Google Patents

Abstract

This invention relates to a mortice lock assembly (4) for use with a first cylinder lock assembly (5) having a first cam (20) with a first arm (50) and an intermediate arm (51). The mortice lock assembly includes a sliding member (41) including abutment formation (46) which interacts with the first arm (50) and intermediate arm (51).

Description

For the mortice lock assembly used together with druum cam in three regions

Technical field

The present invention relates to the mortice lock assembly of a kind of mortice lock assembly and the combination of at least the first cylinder lock assembly and the mortice lock assembly combined with the first cylinder lock assembly and the second cylinder lock assembly. The mortice lock assembly of a kind of form includes the latch bolt (latchbolt) to extended position bias, also includes actuator, and this actuator is operable to from extended position, this latch bolt is moved to retracted position. It is expedient to the mortice lock assembly hereinafter with reference to this form describes the present invention, it is understood, however, that the present invention can also be applied to the mortice lock assembly with steady pin (deadbolt).

Background technology

Handle or turning knob generally will be needed to operate actuator for the mortice lock assembly of aforementioned type so that latch bolt retracts. Cylinder lock assembly can be set up to control the operation of actuator and/or latch bolt of directly retracting. When cylinder lock acts directly on latch bolt, still handle or knob are often set so that pulling door from closed position. Cylinder lock can be positioned so that and operates from the outside of door, and another cylinder lock or rotation latch (turnsnib) are positioned to operate from the inner side of door.

Mortice lock assembly is often the lock set selected by commercial location. This is likely due to caused by the more safety to commercial location requirement, and described more security ground provides by being loaded in the mortise cavity formed in door by lock set housing. Although mortice lock is generally mounted to door by skilled handworker (such as carpenter or locksmith), but it need nonetheless remain for spending the time of skilled handworker to assemble. Accordingly, it is intended that, the Design assistant of mortice lock assembly or at least consider the process of assembling mortice lock, so that installation time is minimum.

The design of existing mortice lock assembly makes to be difficult to be adjusted after having assembled lock. Load lock housing body mortise cavity generally hinders and be adjusted. The process being adjusted needs to remove mortice lock from mortise cavity such that it is able to be adjusted, and then mortice lock is assembled to this mortise cavity. Thus, it is adjusted expending time in and expensive after mortice lock is installed.

The process that mortice lock is assembled to safety door often includes pair of cylinders being locked from the inner side and outer side of door being filled to mortice lock housing. Each cylinder lock includes cam, and this cam needs and latch bolt direct interaction or the operation to control actuator that alternatively interacts with locking key (detent). Latch bolt is spring biased toward extended position, therefore can reliably guess the latch bolt position relative to cam when assembling cylinder lock. Cam is likely to be more difficult to prediction relative to the position of locking key. But, locking key can take active state NOR-function state.Confirming that locking key is positioned at for the tram interacted with cam is the responsibility that workman locked by dress. For most of mortice locks, this is usually non-applied state. If this position uncertain, mortice lock and cylinder lock can assemble, but cam possibility will not be positioned at the position interacted with locking key. Correcting this problem at least to need to remove cylinder lock from mortice lock, this increases assembly cost. Desirably, it is possible to the state adjusting locking key removes from mortice lock assembly without by cylinder lock.

The function required during being likely to from function required during construction stage to the inhabitation stage of function needed for mortice lock is different. During beginning, builder is likely to need mortice lock is arranged through function, thus various handworker can pass in and out building without using key. Along with the Item Value increase in whole building in building, builder may wish to be adjusted to the function of mortice lock one action escape lock (escapelatch). The function of mortice lock is adjusted to from the outside only by function that is key operated and that only operated by handle in inside by this. The inner side of door can be provided only on, when particularly the outside of door is likely to be subject to vandalism during construction stage when handle starts. And during the inhabitation stage, user may wish to lobby and arranges (vestibuleset). This setting arranges handle on both sides of the door, and wherein outer handle passes through key controller, and inside handle controls by rotating latch. Accordingly, it is desirable to mortice lock assembly and cylinder lock have adaptability.

Builder and business resident family more often suffer from a problem that the vandalism being the door utensil in portion outdoors is carried out than residential customer, particularly when building place and not going on patrol safely. When the operation of the handle using locking key to control to be destroyed, it is possible to what leave builder for is do not have any device to operate actuator. Accordingly, it is desirable to mortice lock assembly provides the selection of operation latch bolt to builder, particularly operate the selection of latch bolt from outer side of door.

Summary of the invention

According to an aspect of the present invention, provide a kind of mortice lock assembly, this mortice lock assembly for there is the first cylinder lock assembly of the first cam and there is the second cylinder lock assembly of the second cam or rotate together with latch use, described first cam has the first arm and intermediate arm, described second cam the second arm, described mortice lock assembly includes: housing; It is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes the sliding component of the state slided to adjust described locking device relative to described housing, this sliding component includes abutment structure, this abutment structure has the first area, second area and the zone line that are respectively used to interact with described first arm, described second arm and described intermediate arm, and described zone line is between described first area and described second area.

Preferably, described first area, described second area and described zone line include upper shoulder. It may further be preferable that described first area and described second area include the lower shoulder longitudinally-spaced with described first shoulder.

According to another aspect of the present invention, provide a kind of and at least the first cylinder lock assembly combination mortice lock assembly, described first cylinder lock assembly has the first cam, this first cam has the first arm and intermediate arm, the rotation of described first cam makes described first arm move in this first plane and makes described intermediate arm move in the mid-plane being parallel to described first plane, and described mortice lock assembly includes: housing; It is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes sliding component, this sliding component has the abutment structure interacted with described first cam, described abutment structure has the first area and zone line that interact respectively with described first arm and described intermediate arm, and described zone line positions adjacent to described first area.

When described mortice lock assembly include can relative to the latch of described housing movement between described extended position and retracted position, preferably, described first arm is formed at when described first cam rotates in one direction and interacts to be moved to described retracted position from described extended position by described latch with this latch, and described first cam is formed at when described first cam rotates in the opposite direction and interacts with described abutment structure.Preferably, described first arm and latch bolt are formed at when described cam rotates in the one direction and prevent described first arm from interacting with described abutment structure. It may further be preferable that described first arm is constructed such that only to make described locking device adjust described active state from described non-applied state with the interaction of described abutment structure. Interact it is even furthermore preferable that described intermediate arm is formed at when described cam rotates in said opposite direction with described abutment structure, thus only making described locking device adjust described non-applied state from described active state. Preferably, described abutment structure includes the first shoulder being arranged in described first area and described zone line, and described first shoulder has the upper surface closed by described first knee-joint and the lower surface engaged by described intermediate arm.

This molectron can also include the second cylinder lock assembly or the rotation latch with the second cam, described second cam has the second arm, the rotation of described second cam makes described second arm move in the second plane be parallel to described principal plane, described abutment structure has second area, this second area is adjacent to described zone line, for interacting with this second area. Preferably, described second area also includes first shoulder.

According to a further aspect in the invention, provide a kind of and the first cylinder lock assembly and the second cylinder lock assembly or rotation latch combination mortice lock assembly, described first cylinder lock assembly and described second cylinder lock assembly or rotation latch are all attached to this mortice lock assembly, described first cylinder lock assembly has the first cam, this first cam has the first arm and intermediate arm, described second cylinder lock assembly or rotation latch have the second cam, this second cam has the second arm, the rotation of described first cam makes described first arm move in this first plane and makes described intermediate arm move in the mid-plane being parallel to described first plane, the rotation of described second cam makes described second arm move in the second plane being parallel to described first plane, described mortice lock assembly includes: housing, it is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes sliding component, this sliding component has the abutment structure interacted with described first cam and described second cam, this abutment structure has the first area, zone line and the second area that interact respectively with described first arm, described intermediate arm and described second arm, and described zone line is between described first area and described second area.

The actuator that can be moved from described extended position to described retracted position by described latch is included relative to described housing latch of movement and being operable between extended position and retracted position at described mortice lock assembly, described locking device causes in the inoperable situation of described actuator when being in described active state, preferably, described first arm is formed at when described first cam rotates in one direction and also interacts so that described latch is moved to described retracted position from described extended position with described latch, and when described first cam rotates in the opposite direction, described first arm interacts with described abutment structure so that locking key is adjusted active state from non-applied state in described first area. preferably, when described first cam rotates in the one direction, described intermediate arm interacts with described abutment structure in described zone line. it may further be preferable that described abutment structure includes the first shoulder being arranged in described first area, described zone line and described second area and the second shoulder being only located in described first area and described second area. it is even furthermore preferable that described abutment structure has longitudinal direction, and described first shoulder and described second shoulder are spaced apart from each other on this longitudinal direction. it is even furthermore preferable that described first shoulder across described first area, described zone line and described second area be continuous print. it is even furthermore preferable that described second shoulder of described first area is spaced apart with described second shoulder of described second area.

Preferably, described first cam is configured to use described latch and prevents described first arm and described abutment structure from interacting so that described locking device is adjusted described non-applied state from described active state.Preferably, described first cam is configured to use described abutment structure to prevent described intermediate arm from interacting with described abutment structure so that described locking device is adjusted described active state from described non-applied state.

Preferably, described actuator includes interior hub and outer hub, described interior hub and described outer hub can rotate so that described latch moves relative to described housing, described locking device includes interior pawl and outer pawl, described interior pawl and described outer pawl interact with described interior hub and described outer hub respectively, thus prevent described interior hub and described outer hub from rotating when described locking device is under described active state. More preferably, described latch is the latch bolt including beveled head and body, wherein, latch bolt biasing device is for being biased towards described extended position by described latch, whereby when described latch is positioned at described extended position, described head stretches out from described housing, and when described latch is positioned at described retracted position, described head is generally within described housing.

Preferably, described second cam be only configured to and described abutment structure interact to adjust described locking device between described active state and described non-applied state. Further preferably, described second cam is configured to interact from described extended position described latch moved to described retracted position with described latch, and is configured for and only from described non-applied state, described locking device is adjusted described active state.

Can not admit that the document or material were known in Australia or comprised to the document or material information is regarded as a part for known general knowledge before the priority date of any claim using here the reference of the patent documentation provided as prior art or other materials being regarded as.

Accompanying drawing explanation

Embodiments of the present invention will be more fully described easily below with reference to appended diagram. Accompanying drawing and the illustration being merely an example of how to implement the present invention detailed further below. Concrete form and the layout of various feature as depicted should not be construed as a limitation of the present invention.

Fig. 1 is the lockset of the preferred implementation combining the mortice lock assembly according to present invention exploded partial perspective view before being arranged in door.

Fig. 2 is the axonometric chart of the mortice lock assembly of Fig. 1, and its cover plate is removed from lock housing body, and outer cylinder lock is fixed to this mortice lock assembly.

Fig. 3 is through the fragmentary perspective cross sectional view of the III of Fig. 2.

Fig. 4 is the detail perspective view of a part for the mortice lock assembly of Fig. 2, and its cam rotates, and locking key is positioned at non-applied state.

Fig. 5 is the front view of the mortice lock assembly of Fig. 2, and its cam rotates to engage latch bolt assembly in one direction.

Fig. 6 is the front view of the mortice lock assembly of Fig. 5, and its cam further rotates latch bolt assembly is moved to retracted position.

Fig. 7 is the front view of the mortice lock assembly of Fig. 2, and its cam rotates the sliding component with engagement keys in the opposite direction.

Fig. 8 is the front view of the mortice lock assembly of Fig. 7, and its flange further rotates to move sliding component thus locking key is adjusted active position.

Fig. 9 is the front view of the mortice lock assembly of Fig. 8, and its cam rotates the sliding component with engagement keys in the one direction, and this locking key simultaneously is located in active state.

Figure 10 is the front view of the mortice lock assembly of Fig. 9, and its cam further rotates to adjust the position of sliding component, thus locking key is adjusted non-applied state.

Detailed description of the invention

Illustrate the embodiment of lockset 1 referring now to Fig. 1, Fig. 1, on the whole, this lockset 1 includes external door utensil 2, inside door utensil 3, mortice lock assembly 4, outer cylinder lock set 5 and inner cylinder lock set 6. Describe the present invention with reference to term " interior " and " outward " easily hereinafter and be only used to easy explanation. These terms may alternatively be " first " and " second ", and is only the orientation in using. Mortice lock assembly 4 includes housing 7, and housing 7 is in use arranged in formation in the mortise cavity 8 of the lateral edges of door 9. Mortice lock housing 7 includes antetheca 10, and antetheca 10 is attached to the lateral edges of door 9 usually by screw fastener (not shown).

The inside door utensil 3 of diagram includes interior escutcheon 11, inner handle 12 and inner axis of heart 13. External door utensil 4 includes outer escutcheon 14, outdoor handle 15 and outer axle 16. Inner handle 12 and/or outdoor handle 15 may alternatively be turning knob etc., and the present invention is not intended to be limited to inner handle 12 as depicted or outdoor handle 15. Additionally, although fig 1 illustrate that inner cylinder lock set 6 and outer cylinder lock set 5, but inner cylinder lock set 6 could alternatively be interior rotation latch (turnsnib). Thus, in entire disclosure, internal or mentioning of the second cylinder lock assembly is intended to combine rotation this possibility of latch.

Cylinder lock assembly 5,6 shown in Fig. 1 all includes sleeve pipe 17 and lock core (barrel) 18 (only the lock core 18 of inner cylinder lock set is visible in FIG), and lock core 18 can rotate in sleeve pipe 17 by inserting suitable key (not shown). Key adjusts the position of pellet (not shown) in due form, so that they are directed at the sheer line (sheetline) (referring to Fig. 3) formed between lock core 18 and sleeve pipe 17. The model of action of the cylinder lock assembly 5,6 of this form should be familiar with for a person skilled in the art. It will be recognized that, it is illustrated that the form of cylinder lock assembly 5,6 can be to that indicated in the drawings form different, and the invention is not restricted to the pellet cylinder lock assembly 5,6 being described above and illustrating. Indeed, it is possible to pellet to be replaced with the bolt of disk, disk or other forms, and think those other forms cylinder lock assembly also within the scope of the invention. Additionally, also all aspects of non-invention are limited to mortice lock assembly and outer cylinder lock set and inner cylinder lock set combination. It may also be possible to apply the invention for following situation: inner cylinder lock set is replaced by rotation latch (not shown) etc. Rotate latch and can have the plug (not shown) being equivalent to sleeve pipe 17 and the rotating parts (not shown) being equivalent to lock core 18.

Illustrate the preferred implementation of the mortice lock assembly 4 in conjunction with the present invention referring now to Fig. 2, Fig. 2 and be referred to as the preferred form of the first cylinder lock assembly 5 in the claims. Nominally Fig. 2 illustrates the first cylinder lock assembly in the outside being positioned at mortice lock assembly 4, but, it can alternatively be locked on inner side. While figure 2 show that be referred to as the situation of standard gate back gauge mortice lock assembly 4, but it will be appreciated that it is can also be applied to hatch back gauge mortice lock assembly and long door back gauge mortice lock assembly. Although those skilled in the art will recognize that the implication of these words, but in summary, door back gauge refers to the distance between the antetheca 10 of housing 7 and the rear wall 21 of housing 7.

Fig. 2 illustrates the latch bolt assembly 22 with beveled head 23 and framework 23.Latch bolt assembly 22 is shown at extended position, and by this extended position, head 23 is stretched out by the antetheca 10 of housing 7. Compression spring 25 acts between latch bolt assembly 22 and the butting section 26 in position relative to housing 7, thus as shown in Figure 2 latch bolt assembly 22 being biased towards extended position.

Fig. 2 also show auxiliary bolt 27, and auxiliary bolt 27 has the wedge-shaped head 28 that the antetheca 10 through housing 7 extends. Auxiliary bolt 27 includes body 29, and body 29 is positioned at housing thus interacting with the locking mechanism 30 on the framework 24 being positioned at latch bolt assembly 22. Compression spring 31 acts between auxiliary bolt 27 and the butting section 32 formed in mortice lock housing 7, thus as shown in the figure auxiliary bolt 27 being biased towards extended position. While auxiliary bolt 27 retains and is positioned at extended position, locking mechanism 30 keeps being in non-applied state, and by this non-applied state, latch bolt assembly 22 freely moves to retracted position (referring to Fig. 6) from extended position. It is to be noted, however, that the position of the barrier structure 33 of locking mechanism 30 needs to misplace with retainer 34, thus allowing latch bolt assembly 22 to move to retracted position, for instance as shown in Figure 6. The present invention is not limited to the concrete structure of locking mechanism 30.

Mortice lock assembly according to a preferred aspect of the present invention includes actuator 35, and actuator 35 is operable to from extended position, latch bolt 22 is moved to retracted position. This actuator can take to realize any form of this function. The preferred form of the actuator shown in Fig. 2 takes interior hub 36 and the form of outer hub 37 (being substantially blocked). Interior hub 36 and the axle recess 38 each including a part for receiving the axle 13,16 associated respectively with inner handle 12 and outdoor handle 15 in outer hub 37. Each in interior hub 36 and outer hub 37 can rotate centered by its axis XX, in order to makes latch bolt assembly 22 move from the extended position shown in Fig. 2. Fig. 2 illustrate indirectly act in hub 36,37 each on interior hub 36 and outer hub 37 to be biased towards the compression spring 39 of the orientation shown in Fig. 2.

Mortice lock assembly 4 according to the present invention also includes locking device 40, and locking device 40 can adjust between active state and non-applied state, by this active state, causes actuator 35 not operate, and by this non-applied state, actuator 35 can operate. Locking key can take to realize any form of this function. The preferred form of locking device 40 as shown in Figure 2 combines the sliding component 41 at the square upward sliding being basically parallel to rear wall 21, and also includes the pawl 42,43 adjacent to hub 36,37. Sliding component 41 includes the upper end 43 interacted with the first cam 20 and the lower end 44 interacted with the interior pawl 42 being respectively acting on interior hub 36 and outer hub 37 and outer pawl 43. The specific design of shown pawl is not critical to, because sliding component 40 can also alternatively act directly on interior hub 36 and outer hub 37. Interior pawl 42 and outer pawl 43 are biased and take non-blocking orientation as shown in Figure 2 under the impact of compression spring 45. When the state of locking device 40 is adjusted to active state, the position causing pawl 42,43 is adjusted to such as shown in fig. 8 blocking position. When interior pawl 42 or outer pawl 43 are positioned at blocking position, prevent the rotation of corresponding interior hub 36 and outer hub 37.

Locking device 40 according to the present invention includes for the abutment structure 46 with the first cam 20 interaction.The preferred form of abutment structure 46 is it is shown in fig. 2, however, it should be noted that this abutment structure includes the interaction zone of three longitudinal extensions. In order to easily illustrate, it is possible to these three interaction zone to be designated first area 47, second area 48 and zone line 49. Fig. 2 illustrates the first cam 20 (associating with outer cylinder lock set 5) that can interact respectively with second area 48 and zone line 49. The first cam 20 shown in Fig. 2 includes the first arm 50 and the intermediate arm 51 that extend from the opposite sides of cam body 52. The mode that will interact with abutment structure with reference to diagram detailed description the first arm 50 after a while and intermediate arm 51. Interact with abutment structure 46 in the first region it is to be noted, however, that the first arm 50 is intended to when being attached to outer cylinder lock set 5 or the first cylinder lock assembly 5 or latch bolt assembly 22. And intermediate arm 51 only interacts with abutment structure 46 in zone line 49.

From Fig. 3 it will be appreciated that the first shoulder 53 that abutment structure 46 includes across first area 48, zone line 49 and second area 47 extend. Abutment structure also includes the second shoulder 54 being only located in second area 47 and first area 48. This between second shoulder 54 and the second shoulder 54 of first area 48 of second area 47, in zone line 49, leave gap 55.

It is able to recognize that from Fig. 3 and Fig. 4, the intermediate arm 51 of the first cam 20 includes sweep 56, thus when the first cam 20 rotates in one direction, intermediate arm 51 moves through the gap 55 between the second shoulder 54 of second area 47 and the second shoulder 54 of first area 48. From the position shown in Fig. 4, the first arm 50 causing the first cam 20 is engaged latch bolt assembly 22 to first cam 20 by further rotating on this direction, as shown in Figure 5.

From Fig. 5 it will also be recognized that when locking device 40 is in non-applied state as shown in Figure 5, the intermediate arm 51 of the first cam 20 rotates freely the first shoulder 53 through abutment structure 46. The first arm 50 causing the first cam 20 is interacted with latch bolt assembly 22 by the first cam 20 from further rotating of the position shown in Fig. 5, so that latch bolt assembly 22 moves to the retracted position shown in Fig. 6 from the extended position shown in Fig. 5. Such as, this allows use outer or latch bolt assembly 22 is moved to retracted position by the first cylinder lock assembly 5, to allow to open door, without the state of adjusting and locking mechanism 40. It should be noted that the first cam 20 can in the opposite direction to back rotation, to be returned to position as shown in Figure 2, again without the state of adjusting and locking mechanism 40.

Illustrate that the first cam 20 rotates from the position shown in Fig. 2 in the opposite direction to the such as position shown in Fig. 5 referring now to Fig. 7, Fig. 7 so that the first arm 50 engages the first shoulder 53 of locking device 40. First cam 20 further rotating in said opposite direction causes the sliding component 41 of locking device 40 to be forced downwardly so that pawl 42 pivots. Fig. 8 illustrates that further rotating of the first cam 20 causes locking device 40 to take active state, prevents hub 36 from rotating whereby. Equally, while being maintained under the active state shown in Fig. 8 by locking device 40, the first cam 20 can return to the position shown in Fig. 2.

Illustrate that referring now to Fig. 9, Fig. 9 the locking device 40 being in active state and the first cam 20 are rotated into so that intermediate arm 51 is engaged against the first shoulder 53 of structure 46.First cam 20 causes sliding component 41 to move to the cocked position shown in Figure 10 from further rotating of the position shown in Fig. 9. This causes that non-applied state taked by locking device 40 so that pawl 42 separates with hub 36. It will be recognized that while locking device 40 is maintained at non-applied state as shown in Figure 10, the first cam 20 can be rotated back to home position as shown in Figure 2.

Applicants have realized that, generally preferably, the first arm 50 and the second arm 51 is included from cylinder first cam 20 of outer cylinder lock set 5 operation, and preferably, the second cylinder lock assembly 6 operated from the inner side of mortice lock assembly 4 includes only having second cam (not being explicitly illustrated) of single arm. This single arm will only interact with inner region 47, and be configured between first shoulder 53 and the second shoulder 54, or alternatively be configured to the same with first arm 50 of the first round 20, to interact with latch bolt assembly 22 and abutment structure 46. Second cam will not include suitable intermediate arm, because this will hinder the operation of the intermediate arm 51 of the first cam 20. Additionally, when the second cylinder lock assembly 6 is replaced by rotation latch (not shown), the second arm will be attached to rotating parts or forms a part for rotating parts.

Various changes and/or increase can be incorporated in mortice lock assembly as described above, without departing from the spirit or scope of the present invention.

Can national applications beyond Australia or the Australia patent application in the future based on the present invention or the priority requiring the present invention. It should be understood that following provisional claims is only what be provided by way of example, it is not intended to limit the scope being likely to claim in applying for any this future. Feature can be increased to this provisional claims in future or omit feature from this provisional claims, to limit further or again to limit the present invention.

Claims (24)

1. a mortice lock assembly, this mortice lock assembly for there is the first cylinder lock assembly of the first cam and there is the second cylinder lock assembly of the second cam or rotate together with latch use, described first cam has the first arm and intermediate arm, described second cam has the second arm, and described mortice lock assembly includes:

Housing;

It is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes the sliding component of the state slided to adjust described locking device relative to described housing, this sliding component includes abutment structure, this abutment structure has the first area, second area and the zone line that are respectively used to interact with described first arm, described second arm and described intermediate arm, and described zone line is between described first area and described second area.

2. mortice lock assembly according to claim 1, wherein, described first area, described second area and described zone line include upper shoulder.

3. mortice lock assembly according to claim 2, wherein, described first area and described second area include lower shoulder.

4. the mortice lock assembly combined with at least the first cylinder lock assembly, described first cylinder lock assembly has the first cam, this first cam has the first arm and intermediate arm, the rotation of described first cam makes described first arm move in this first plane and makes described intermediate arm move in the mid-plane being parallel to described first plane, and described mortice lock assembly includes:

Housing;

It is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes sliding component, this sliding component has the abutment structure interacted with described first cam, described abutment structure has the first area and zone line that interact respectively with described first arm and described intermediate arm, and described zone line positions adjacent to described first area.

5. molectron according to claim 4, wherein, described mortice lock assembly includes can relative to described housing latch of movement between extended position and retracted position, described first arm is formed at when described first cam rotates in one direction and interacts to be moved to described retracted position from described extended position by described latch with this latch, and described first cam is formed at when described first cam rotates in the opposite direction and interacts with described abutment structure.

6. molectron according to claim 5, wherein, described first arm and latch bolt are formed at when described cam rotates in the one direction and prevent described first arm from interacting with described abutment structure.

7. the molectron according to claim 5 or 6, wherein, described first arm is constructed such that only to make described locking device adjust described active state from described non-applied state with the interaction of described abutment structure.

8. the molectron according to any one of claim 4 to 7, wherein, described intermediate arm is formed at when described cam rotates in said opposite direction and interacts with described abutment structure, thus only making described locking device adjust described non-applied state from described active state.

9. the molectron according to any one of claim 4 to 8, wherein, described abutment structure includes the first shoulder being arranged in described first area and described zone line, and described first shoulder has the upper surface closed by described first knee-joint and the lower surface engaged by described intermediate arm.

10. the molectron according to any one of claim 4 to 9, this molectron includes the second cylinder lock assembly or the rotation latch with the second cam, described second cam has the second arm, the rotation of described second cam makes described second arm move in the second plane being parallel to described first plane, described abutment structure has second area, this second area is adjacent to described zone line, for interacting with described second area.

11. molectron according to claim 10, wherein, described second area includes first shoulder.

12. one kind with the first cylinder lock assembly and the second cylinder lock assembly or the mortice lock assembly rotating latch combination, described first cylinder lock assembly and described second cylinder lock assembly or rotation latch are all attached to this mortice lock assembly, described first cylinder lock assembly has the first cam, this first cam has the first arm and intermediate arm, described second cylinder lock assembly or rotation latch have the second cam, this second cam has the second arm, the rotation of described first cam makes described first arm move in this first plane and makes described intermediate arm move in the mid-plane being parallel to described first plane, the rotation of described second cam makes described second arm move in the second plane being parallel to described first plane, described mortice lock assembly includes:

Housing;

It is positioned at the locking device of described housing, this locking device can be adjusted between active state and non-applied state, described locking device includes sliding component, this sliding component has the abutment structure interacted with described first cam and described second cam, this abutment structure has the first area, zone line and the second area that interact respectively with described first arm, described intermediate arm and described second arm, and described zone line is between described first area and described second area.

13. molectron according to claim 12, this molectron includes the actuator that can be moved from described extended position to described retracted position by described latch relative to described housing latch of movement and being operable between extended position and retracted position, described locking device causes described actuator not operate when being in described active state, described first arm is formed at when described first cam rotates in one direction and also interacts so that described latch is moved to described retracted position from described extended position with described latch, and when described first cam rotates in the opposite direction, described first arm interacts with described abutment structure so that locking key is adjusted active state from non-applied state in described first area.

14. molectron according to claim 13, wherein, when described first cam rotates in the one direction, described intermediate arm interacts with described abutment structure in described zone line.

15. the molectron according to any one of claim 12 to 14, wherein, described abutment structure includes the first shoulder being arranged in described first area, described zone line and described second area and the second shoulder being only located in described first area and described second area.

16. molectron according to claim 15, wherein, described abutment structure has longitudinal direction, and described first shoulder and described second shoulder are spaced apart from each other on this longitudinal direction.

17. the molectron according to claim 15 or 16, wherein, described first shoulder across described first area, described zone line and described second area be continuous print.

18. the molectron according to any one of claim 15 to 17, wherein, described second shoulder of described first area is spaced apart with described second shoulder of described second area.

19. the molectron according to any one of claim 12 to 19, wherein, described first cam is configured to prevent described first arm from interacting with described abutment structure so that described locking device is adjusted described non-applied state from described active state together with described latch.

20. molectron according to claim 19, wherein, described first cam is configured to prevent described intermediate arm from interacting with described abutment structure so that described locking device is adjusted described active state from described non-applied state together with described abutment structure.

21. the molectron according to any one of claim 13 to 20, wherein, described actuator includes interior hub and outer hub, described interior hub and described outer hub can rotate so that described latch moves relative to described housing, described locking device includes interior pawl and outer pawl, described interior pawl and described outer pawl interact with described interior hub and described outer hub respectively, thus prevent described interior hub and described outer hub from rotating when described locking device is under described active state.

22. the molectron according to any one of claim 13 to 21, wherein, described latch is the latch bolt including beveled head and body, wherein, latch bolt biasing device is for being biased towards described extended position by described latch, and whereby when described latch is positioned at described extended position, described head stretches out from described housing, and when described latch is positioned at described retracted position, described head is generally within described housing.

23. the molectron according to any one of claim 12 to 22, wherein, described second cam is only configured to and described abutment structure interacts to adjust described locking device between described active state and described non-applied state.

24. the molectron according to any one of claim 13 to 22, wherein, described second cam is configured to interact from described extended position described latch moved to described retracted position with described latch, and is configured for and only from described non-applied state, described locking device is adjusted described active state.