RU2643125C2 - Door lock - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: door lock comprises a housing, as well as a feeding mechanism associated with a door handle, and a chamfered spring-loaded bolt made with the possibility to lock doors disposed in said housing. The chamfered spring-loaded bolt comprises a rod part made like a rod and a head disposed at the front end of the rod part and having chamfered surface. The rod part of the bolt is interfaced with a return spring, which ensures the possibility for the bolt head to project from a hole made in the housing sidewall. The feeding mechanism is made with the possibility to move the rod part of the bolt and thus to retract its head into the housing. The bolt is reversibly fixed in the housing by a locking mechanism of reversible type, so that the orientation direction of the chamfered surface of the bolt head is selected in accordance with the direction of closing the door. According to the proposed solution, the rod part and the feeding mechanism are combined using a reversible locking mechanism that can fix and release the rod part of the bolt. Thus, the possibility to quickly change the orientation direction of the bolt is ensured. The present invention can be used in a lock, the spring-loaded bolt of which has chamfered surface.

EFFECT: increasing the reliability.

12 cl, 15 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to a door lock, and more particularly to a door lock, in which, if necessary, the orientation of the beveled spring-loaded crossbar can be changed.

BACKGROUND

A traditional lock for a room door comprises a housing in which a tapered spring-loaded crossbar is placed, wherein one surface of the side wall at the upper end of the crossbar is tapered, and the tapered spring-loaded crossbar itself is mounted in the housing with a possibility of sliding movement. A beveled spring-loaded bolt is used to interact with the door frame. When closing the door, the beveled surface at the upper end of the crossbar moves along the door frame and is pressed into the lock case by the action of this box. When closing the door in the working position, the bolt latches and moves into the corresponding hole made in the door frame, so that the door is locked. When the door is opened, the door handle or the handwheel of the lock is turned to move the bolt into the lock case, and thus the door is unlocked. Thus, the orientation direction of the tapered surface of said crossbar is selected in accordance with the direction of opening / closing the door. If the orientation direction of the beveled surface of the crossbar when installing the lock in the door is incorrect, there is a need to change the orientation of this surface to the opposite.

The traditional way to change the crossbar orientation is to disassemble the door lock housing to change the direction of the crossbar orientation. Obviously, this method is very complex and fraught with the danger of improper assembly. In particular, if the door lock case has an all-welded or forged design, there is practically no possibility of changing the direction of the bolt orientation, and therefore it is necessary to replace the entire door assembly if a new “correct” door lock is not delivered. To address the above drawback, a solution is directed according to which the crossbar can be quickly replaced. Thus, in patent application No. 200610067331.2, a lock is described comprising a box-shaped housing, a bolt arranged to move in an opening in the lock housing, and a device mechanically connecting said lock with at least one drive. The specified lock contains: the first main body, located partially outside the specified box-shaped body and made with the possibility of locking in the left or right direction, and the second main body located in the box-shaped body and mechanically connected to the specified at least one drive, the first main body connected to the second main body using a reversing mounting mechanism. The first main body is inserted into the hole in accordance with the selected locking direction and connected to the second main body. The specified reversing mounting mechanism is a “lock” connection made with the possibility of elastic deformation, moreover, the two side parts of the second main body are respectively provided with holding teeth. The retaining teeth interact with the holding base, the shape of which corresponds to the shape of the indicated first main body of the reversible type, said mounting mechanism comprising a device for disconnecting the “lock” connection between the holding teeth and the corresponding holding base. The principle of the design described above is that the rod part of the spring-loaded crossbar is made with the possibility of separation into two parts due to the presence of a “lock” connection between the holding teeth and the corresponding holding base. Taking into account the need for elastic deformation between the retaining teeth and the holding base, the materials of which these holding teeth or the holding base are made must be of high strength and elasticity, and at the same time, they must have some rigidity, such as spring steel or high-quality plastic, otherwise, they can be easily destroyed. However, spring steel has a high cost and is also excessively difficult to manufacture. A material such as plastic is not suitable for use in all climatic conditions, in particular in regions with low temperatures, its rapid destruction is possible. In addition, the detachable design of the spring-loaded crossbar increases the cost of the product and the cost of maintenance.

SUMMARY OF THE INVENTION

The objective of the present invention is to provide the possibility, if necessary, to change the direction of orientation of the crossbar without dividing it into two parts, as well as in the manufacture of said crossbar and its assembly using material suitable for traditional locks. Thus, according to the present invention, there is provided a door lock comprising a housing, as well as a feeding mechanism associated with a door handle, and a tapered spring-loaded deadbolt configured to lock the doors located in the housing. The specified crossbar contains a rod part, made like a rod, and a head located on the front end of the rod part and having a beveled surface. The core of said crossbar is coupled to a return spring, which enables the crossbar head to protrude from an opening made in the side wall of the housing, the feed mechanism being configured to move the core of said crossbar and thus divert its head to the housing. The proposed lock is characterized in that said crossbar is reversibly fixed in the housing by a locking mechanism of a reversible type, so that the orientation direction of the beveled surface of the crossbar head can be selected in accordance with the direction of closing the door.

The reversing-type locking mechanism is configured to fix the rod of the bolt in the housing when the bolt is inserted into the housing and to release the rod of the bolt to remove the bolt from the housing.

According to the technical solution described above, the pivot of the bolt is not only connected to the feed mechanism, but can also be fixed and released using the specified locking mechanism of the reversible type to change the direction of orientation of the bolt in accordance with the need.

The specified locking mechanism of the reverse type contains:

(1) A pair of shoulders, which are formed on two opposite sides of the rod part of the crossbar and whose outer side is facing the head of this crossbar, and a locking lever configured to engage from any of the external sides of the specified shoulder or to disengage from any of the external sides of the specified shoulder, so that when the locking lever interacts with the outside of the shoulder, the removal of the specified bolt from the housing is prevented, and in the absence of interaction of the locking lever with the external On the shoulder side, it is possible to extract said bolt from the housing.

The shoulder is a protrusion located at an angle relative to the axial direction of the pivot portion of the crossbar, so that its outer side faces the indicated beveled surface. The angle of inclination between the shoulder and the axis of the pivot portion of the crossbar is selected so as to allow the locking lever to lock or release said crossbar and is preferably mainly oriented in the vertical direction. Thus, if the locking lever is engaged with the outer side of the shoulder, the bolt shaft is fixed and cannot be removed from the housing, and when the locking lever is not engaged with the outer side of the shoulder, the bolt rod is released and can be removed from the housing.

Secondly, two shoulders (pair) are respectively formed on two opposite sides of the rod part of the crossbar. Thus, when changing the orientation direction of the beveled surface of the head of said crossbar, the outer side of at least one shoulder of these two shoulders interacts with the locking lever to form a transmission link. The position of the two shoulders, i.e. above the shaft part and under the shaft part or in the left and right parts of said shaft part mainly depends on the position of the locking lever. The two opposite sides are located on the positive axis and the negative axis, which extend in the same coordinate axis X, and the angle between them is 180 °, as a result of which their interchangeability is ensured.

According to the technical solution described above, the design that ensures the interaction of the locking lever with the shoulder formed on the rod part of the crossbar to form a reversible type locking mechanism for fixing the specified crossbar is simple and traditional materials used in the manufacture of the crossbar and its assembly can be used. manufacturing locks such as galvanized steel sheet or plastic. Even if the crossbar and the locking lever are made of plastic, they do not experience elastic deformation, therefore there is no problem of their destruction at low temperature.

(2) The locking mechanism comprises a mounting axis mounted to be movable in the axial direction, the locking lever being rigidly attached to the mounting axis and moving with it in the axial direction. The installation axis passes between two opposite sides of the housing and is installed with a gap that allows movement in the axial direction; moreover, this gap is greater than the distance between the two positions of the locking lever, in one of which this lever interacts with the outer side of the shoulder, and in the other this lever does not interact with the outer side of the shoulder. A return spring is installed between the mounting axis and either of the two opposite sides of the housing.

According to the aforementioned technical solution, the mounting axis is made with the possibility of displacement by a certain distance in the axial direction, causing a corresponding movement of the locking lever. The specific position of the return spring mainly depends on the relative position of the locking lever and the specified rod portion of the bolt. When released, the return spring brings the mounting axis closer to the inner side surface of the opposite side wall and forces the locking lever to interact with the shoulder. When the installation axis is pressed, the return spring is compressed and the installation axis moves away from the inner side surface of the opposite side wall, which causes the locking lever to disengage from the shoulder. The installation axis can be pressed with a special tool, and an access hole can be made in the housing in the area corresponding to the upper end of the installation axis, and a tool with a thin tip can be used to press the installation axis, which, when inserted into the specified hole moves the axis.

An additional technical solution is that the installation axis is also mounted to rotate around its axis; wherein said feed mechanism comprises a driving lever, the rotation of which, when the door handle is rotated, causes the locking lever to rotate, which in turn, by means of a shoulder, retracts said bolt into the housing.

An additional technical solution is that the locking mechanism also includes a positioning cam lever, which is rigidly attached to the mounting axis or the locking lever. During its rotation, the driving lever rotates the positioning cam lever, which in turn causes the locking lever to rotate.

An additional technical solution also consists in the fact that the mounting axis is also rotatably mounted about its axis, said locking mechanism also comprises a positioning cam lever, which is rigidly attached to the mounting axis or locking lever, and said feeding mechanism comprises a driving lever that is connected to positioning cam lever. When the door handle is turned clockwise, the drive lever is actuated and rotates or moves horizontally to rotate the specified positioning cam lever, which in turn rotates the locking lever, and the locking lever withdraws the specified bolt into the housing by means of a shoulder.

According to the proposed technical solution, the main purpose of the specified cam lever is to connect to the specified feed mechanism, in particular with the drive lever and the locking lever, as a result of which a constructive relationship between the locking lever and the door handle is ensured. Secondly, the specified driving lever can be actuated by a door handle (in general, the right hand is used more often, and thus a turn in the clockwise direction is selected), as a result of which it rotates or moves in the horizontal direction.

Of course, the specified driving lever can also be directly connected with the rod part of the specified crossbar.

In general, the door lock is equipped with an internal manual lock. The specified latch is mainly designed to block the door handle from the inside (from the room) when the door is locked, and thus prevents the door from being opened by turning the door handle by other people outside the room. Therefore, the specified latch can directly rigidly fix the drive arm and thus prevent it from turning or allow it to slip idly when the door handle is turned or force is exerted on it from the outside of the door.

An additional technical solution also consists in the fact that between the driving lever and the rod part of the crossbar there is an auxiliary lock, additionally fixing the specified crossbar.

An additional technical solution also consists in the fact that the installation axis comprises an external installation axis and an internal installation axis located inside the external installation axis, wherein the internal installation axis is connected to the end of the external installation axis, and there is a chamber between said external and internal axes for accommodating said spring return. The length of the internal mounting axis is greater than the length of the external mounting axis. The diameter of the mounting holes made in the housing in accordance with the location of the axis is slightly larger than the outer diameter of the specified internal mounting axis. The return spring is located between the mounting axis and part of the wall around these holes.

An additional technical solution also consists in the fact that the mounting axis contains a pin rigidly attached to the side wall of the housing and a movable cap worn on this pin, and there is an axial clearance between the pin and the movable cap in which the return spring is located.

An additional technical solution also consists in the fact that the lock according to the present invention further comprises an access hole made in the housing and corresponding to the specified mounting axis, and by means of a tool tip inserted into the indicated hole, the installation axis can be moved in the axial direction in order to subsequently withdraw the locking lever engages with the outer side of the shoulder with the termination of interaction with it.

An additional technical solution also consists in the fact that a guide mechanism for said crossbar is also located in the housing, comprising a chamber for receiving a return spring having an inlet for receiving an end of the rod portion of said crossbar. When installing the end of the rod of the bolt in the specified hole, the return spring acts on this end.

An additional technical solution also consists in the fact that a limiting protrusion is additionally formed on the rod part of the said crossbar, and there is also a limiter on the housing that interacts with the specified limiting protrusion, and the interaction of the limiter and the specified limiting protrusion limits the maximum distance over which the specified bolt enters the housing through the indicated hole in it.

An additional technical solution also consists in the fact that the end of the rod part of said crossbar has a beveled surface extending towards the end of the rod part.

Since the present invention has the above features and advantages, it can be applied to a lock whose spring-loaded deadbolt has a tapered surface.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 schematically shows an internal top view of the lock according to the present invention, where the front side wall 1d and the beveled spring-loaded bolt 3, shown on the back of the guide mechanism 7, are removed.

Figure 2 shows the left side view of the crossbar shown in figure 1.

Figure 3 schematically shows a perspective view of the crossbar 3 of the castle according to the present invention.

Figure 4 schematically shows a perspective view of the crossbar 3 of the lock according to the present invention, shown in figure 3, rotated 180 °.

5 is a schematic sectional view of a mounting axis 5 of a lock according to the present invention.

6 is a schematic perspective view of a mounting axis 5 according to one embodiment.

6 a is a schematic sectional view of a mounting axis 5 according to yet another embodiment.

7 schematically shows a perspective view of the guide mechanism 7 of the lock according to the present invention.

FIG. 8 schematically shows a section through a guide mechanism 7 comprising a chamber 71, an inlet 72, and a guide plate 73.

FIG. 9 is a schematic perspective view of a lock drive lever 8 according to the present invention.

Figure 10 schematically shows a top view of the lock with the removed side cover before inserting the bolt 3 into the housing 1.

Figure 11 schematically shows a top view of the lock with a guide mechanism 7 mounted in the housing, after the bolt 3 is inserted into the housing 1.

On Fig shows a sectional side view along the line aa shown in Fig.11.

13 is a schematic sectional view of yet another embodiment of a mounting axis 5 according to the present invention.

On Fig schematically shows a view of another embodiment of the lock without a side cover according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Detailed embodiments of the present invention are described below with reference to the accompanying drawings.

Embodiment 1 mainly relates to a technical solution, according to which the locking lever 52 not only moves in the axial direction, but also rotates around its axis to reverse fix the beveled spring-loaded crossbar 3.

As shown in figures 1 and 2, the door lock contains a housing 1. The housing 1 has a lower, left, right, front and rear walls that form a cavity for accommodating the elements of the lock. The side wall 1a shown in FIG. 1 has an opening 10; 1 and 2 show the front and rear side walls (1d, 1c) of the housing 1. The lock contains a feed mechanism associated with a door handle, a beveled spring-loaded bolt 3, which locks the door with a locking lever 52, which fixes the bolt 3 and the installation axis 5 in the housing 1. The crossbar 3 is arranged to slide by sliding from the opening 10 for locking the door, but when it is retracted into the housing 1, the door can be opened. Secondly, the lock case contains a decorative plate 9, which is firmly connected to the side wall 1a by means of screws. A hole is also made in the decorative plate 9 through which the head 31 of the said bolt 3 can pass. When the lock case is installed in the door, the decorative plate 9 closes the lock case.

As shown in FIG. 1, said feed mechanism comprises a door handle pivot assembly 2 located between the front and rear side walls (1d, 1c) of the housing 1, with a square hole 21 made in the center of the pivot unit 2 connected to the door handle, and on the outside of said pivot assembly, a return spring 26, a pivot arm 23, and a first pivot pin 22 and a second pivot pin 24 restricting the position of the pivot arm 23 are located. The first pivot pin 22 limits the normal position e after the return of the pivot arm 23 to its original position, and the second limiting pin 24 limits the angular position of the pivot arm 23 at its maximum rotation clockwise. Since most people use the right hand, the direction of rotation of the door handle is set clockwise. When the door handle is turned clockwise, the knob 2 of the door knob forces said pivot arm 23 to rotate coaxially, and the limit pin 24 restricts the travel of the pivot arm 23 as a whole to an angle of about 90 °. When the door handle is released, the return spring 26 drives the pivot assembly 2 to return the pivot arm 23.

As shown in FIG. 1, the return spring 6 interacts with the tail portion 326 of the crossbar 3. The return spring 6 can cause the head 31 of the crossbar 3 to move in the direction from the housing 1, when said crossbar 3 is retracted into the housing 1 after pressing it.

As shown in FIG. 1, said feed mechanism also comprises a drive lever 8, arranged to move left and right horizontally under the control of the rotary lever 23. The drive lever 8 by means of a bolt 3 is interfaced with an internal manual lock 4. If the manual lock 4 is rotated counterclockwise arrows and fix, it interacts with the driving lever 8 and prevents it from moving to the right. Thus, even if a force is applied to the door handle acting in the internal or external direction, said door handle cannot be rotated or will rotate idle depending on its design. Manual lock 4 is mainly used to fix the door handle on the inside of the door.

Figures 3-4 show schematically the structure of the crossbar 3. The crossbar 3 comprises a rod portion 32 having a rod-like shape, and a head 31 located at the front end of the rod portion 32 and having a beveled surface. When closing the door, the head 31 of the crossbar 3 slides along the door frame with its beveled surface 310 and is pressed into the housing 1 by the action of the indicated door frame. When the head 31 of the crossbar 3 moves out of the housing under the action of its spring and enters the bolt socket made in the door frame, the door turns out to be locked. When the door is opened from its inner side, the internal manual lock 4 is released in a clockwise direction, and the bolt 3 is completely retracted into the lock body to open the door by turning the door handle.

As shown in FIGS. 3-4, the rod portion 32 of the crossbar 3 has an approximately symmetrical shape.

The rod portion 32 is symmetrical about its left and right portions and is provided with a first protrusion (323a, 323b) and a second protrusion (324a, 324b). The first protrusion 323a and the second protrusion 324a are located on one side at a certain distance from each other, and the first protrusion 323b and the second protrusion 324b are located on the other side at a certain distance from each other.

The upper and lower sides of the rod portion 32 contain approximately the same recesses (321a, 321b) and flat areas (322a, 322b), respectively, half surrounding the recesses (321a, 321b), the open parts (320a, 320b) of the recesses (321a, 321b) located on the upper and lower sides of the rod portion 32, facing in opposite directions. Thus, after insertion of the rod portion 32 with lateral orientation in one direction or in the opposite direction into the housing 1, the open portion 320a of said recess 321a or the open portion 320b of said recess 321b facing the locking lever 52 interacts with the locking lever 52. In FIG. 1 shows that the locking lever 52 is located to the left of the rod portion 32, with the recess under the bolt 3 always facing the left, and thus the locking lever 52 easily fits into the recess under the rod portion 32.

The transition part between the recess (321a, 321b) and the flat region (322a, 322b) forms a shoulder (34a, 34b), the outer side (33a, 33b) of which is facing the head 31 of the crossbar 3. Thus, due to the fact that the recess (321a , 321b) forms a shoulder (34a, 34b), the structure of the rod portion 32 is reinforced by the indicated flat region (322a, 322b). The outer side (33a, 33b) of the shoulder is approximately equally distributed over the upper and lower sides of the shaft portion 32 so that interchangeability of the upper and lower sides of the shaft portion 32 is ensured.

The outer size of the head 31 of the bolt 3 is larger than the outer size of the rod portion 32, and the intermediate part between the head 31 of the bolt 3 and the rod portion 32 is bounded by a circle and protrudes at least in the upper and lower lateral directions in the form of a protrusion 311. The protrusion 311 interacts with the limiter (not shown in the drawings) located in the housing 1 and limiting the maximum distance by which the bolt 3 can be deepened into the housing 1 when it moves in the hole 10 of the housing 1. The specified limiter may be a protrusion a lobes made by punching and pressing in the front and rear side walls (1d, 1c) of the housing.

The upper and lower sides of the tail portion 326 of the rod portion 32 are symmetrically provided with a bevel 325 beveled towards the end of the rod portion 32. The bevel 325 facilitates the insertion of the bolt 3 into the housing 1. The tail portion 326 of the rod portion 32 has a flat shape.

Due to the design described above, if it is necessary to change the direction of the bevel of the crossbar 3, only the direction of the surface 310 of the head 31 of the crossbar 3 is reversed, since the core portion 32 has a symmetrical structure, and thus the order of its connection with other components of the lock remains unchanged.

5 and 6 show another construction of the mounting axis 5. As shown in FIGS. 5 and 6, the axis 5 comprises an outer mounting axis 54 and an inner mounting axis 53 located in the outer mounting axis 54. On the outer mounting axis 54 are arranged radially passing the locking lever 52 and the cam lever 51,1 rigidly attached to the locking lever 52. The inner mounting axis 53 is connected to one end of the outer mounting axis 54, and between these axes there is a cavity for accommodating the return spring 55. The length of the inner axis 53 is greater than the length of the outer axis 54. The rear side wall 1c interacting with the mounting axis 5 has an opening 56, the diameter of which is larger than the diameter of the internal mounting axis 53, which is inserted into the hole 56 for rotation and axial movement. The return spring 55 is located between the specified installation axis 5 and the peripheral part of the specified hole 56. Thus, the installation axis 5 is able to move both in the axial direction and around its axis.

As shown in FIG. 5, the mounting axis 5 extends between the front wall 1d and the rear wall 1c of the housing 1 and is mounted with an axial clearance equal to the difference between the length of the outer axis 54 and the distance from the front wall 1d to the rear wall 1c. In addition, the front wall 1d has an access hole 11 located near the upper end of the mounting axis 5. The tip of the tool 13 inserted into the hole 11 moves the mounting axis 5 in the axial direction, which in turn moves the locking lever 52 and the cam lever in the axial direction 51. When the tool 13 is released, the return spring 55 returns the installation axis 5 to its original position and presses it against the inner side of the front wall 1d. Alternatively, to achieve the same result, as shown in Fig. 6a, the mounting axis 5 may be T-shaped, with the locking lever 52 and the cam lever 51 located directly on the vertical column 53a of the axis 5, the return spring 55a is located between the upper end 54a of the specified axis 5 and the front wall 1d and interacts with the specified axis 5, and the vertical column 53a is inserted into the hole 56 with the possibility of rotation around its axis and movement in the axial direction. Thus, the axis 5 with force is inserted into the hole 11 for access with the possibility of movement in the axial direction and radial movement under the action of the specified cam lever 51.

Further, the mounting axis 5 may also have the structure shown in Fig.13. But in this case, it is necessary to move the cap 54b, which allows rotation around an axis on the specified rod part.

Alternatively, the technical solution shown in FIGS. 5 and 6 can be changed so that the internal mounting axis 53 can only move in the hole 56 in the axial direction and cannot rotate about its axis. Thus, such an improved solution can be applied in the second embodiment.

Alternatively, the technical solution shown in figa can be changed so that the vertical axis 53a could move in the hole 56 only in the axial direction and could not rotate around its axis. Thus, such an improved solution can be applied in the second embodiment.

7 and 8 schematically show the design of the guide mechanism 7. The guide mechanism 7 with a fit inserted by its mounting protrusion 74 into the hole 12 made by punching and pressing in the rear wall 1c, and thus the specified guide mechanism is mounted and fixed in the housing 1 coaxially with the crossbar 3, being clamped above and below between the front wall 1d and the rear wall 1c.

The guide mechanism 7 has a chamber 71, an inlet 72 and a guide plate 73. The chamber 71 has a conical shape to accommodate a return spring 6, which also has a conical shape. When the bolt 3 is inserted into the housing 1, the end of the bolt 326 enters the inlet 72 along the guide plate 73 and interacts with the return spring 6. Thus, the shape of the inlet 72 is associated with the shape of the end of the 326 bolt.

Fig. 9 schematically shows the construction of the drive lever 8. The drive lever 8 comprises a drive head 81, a drive shaft 82 connected to an internal hand latch 4, a transition wall 83 connecting the drive head 81 to the drive shaft 82, a fixing recess 84 made in lead shank 82, ledge 87, coupled and interacting with the cam lever 51, the locking recess 85, blocking the interaction of the bolt 3 with the protrusion (323a, 323b), and the connecting recess 86 made in the leading head 81 and interacting with the rotary lever m 23. It should be noted that the locking recess 84 generally cooperates with an internal manual clamp 4 for fixing the driving lever 8.

Figure 10 schematically shows a lock assembly before inserting the bolt 3 into the housing 1. Before completing the door lock or shipping it from the factory, the bolt 3 can be structurally separated from the housing 1 (or the lock housing) or can be inserted into the housing 1. After completing the lock case, if it turns out that the direction of the beveled surface 310 of the crossbar 3 is not chosen correctly, the indicated direction can be changed by re-inserting the crossbar correctly into the housing 1 after pressing the mounting axis 5 and removed I bolt 3.

In Fig.11 schematically shows a view of the Assembly after installing the guide mechanism 7 and the bolt 3 in the castle body, as shown in Fig.1. It should be noted that the insertion direction of the crossbar 3 not only coincides with that shown in Fig. 10, but also coincides with that shown in Fig. 4. The guide mechanism 7 is seated in a hole 12 made in the rear wall 1c with the protrusion 74 in the specified hole, and is thus rigidly attached to the housing 1 and is aligned with the bolt 3. In addition, the locking lever 52 extends into the recess 321a located in the lower side region of the shaft portion 32 and interacts with the outside 33a of the shoulder 34a. The driving lever 8 extends along the lower side of the rod portion 32 of the bolt 3 and is located under the side of the locking lever 52, the transition wall 83 being located away from the axial movement of the rod portion 32, i.e. during insertion or removal, the core portion 32 is substantially not in contact with the transition wall 83.

The rod portion 32 is symmetrical with respect to its left and right portions, provided with first protrusions (323a, 323b) located on the transition wall 83 and mating with the recess 85 in the drive arm 8. The end 326 of the bolt 3 extends into the inlet 72 in the guide plate 73 and interacts with the return spring 6. The first protrusion 323a or the first protrusion 323b interact with the recess 85 to form an auxiliary lock securing the bolt 3. It is also possible that the gap space between the first protrusion 323a and the second the second protrusion 324a interacts with the wall of the recess 85 to form an auxiliary retainer fixing the bolt 3.

The proposed door lock operates as follows.

If the internal manual lock 4 is open, i.e. turned clockwise, and the door handle is turned clockwise, the pivot assembly 2 of the door handle pivots the pivot arm 23 about its axis, and the second limiting pin 24 restricts the maximum pivot movement of the pivot arm 23 clockwise. When the door handle is released, the return spring 26 drives the pivot assembly 2 of the door handle and returns the pivot arm 23 to its original position, the first limiting pin 22 restricting the return stroke of the pivot arm 23.

When the pivot arm 23 rotates clockwise, a connecting recess 86 formed on the drive head 81 and cooperating with the pivot arm 23 moves the drive arm 8 horizontally to the right. At the same time, the drive lever 8, by means of a step 87 formed on it, rotates the mounting axis 5 clockwise, while the locking lever 52, which is rigidly attached to the mounting axis 5, also rotates clockwise synchronously and thus interacts with the outside 33 of the shoulder and forces the bolt 3 to move towards the housing 1.

When the door handle is released, the rotary lever 23 returns to its original position and moves the drive lever 8 horizontally to the left, and thus the locking lever 52 and the cam lever 51 located on the mounting axis 5 are also synchronously rotated in a counterclockwise direction and return to their original position. The bolt 3 extends from the housing 1 under the action of the return spring 6 and acts on the locking lever 52, returning it to its original position. The first protrusion 323a formed on the rod portion 32 (or in the turned position of the bolt the first protrusion 323b) enters the recess 85 in the drive arm 8, and thus additionally fixes the bolt 3, preventing it from exiting. Then the cam lever 51 or the driving lever 8 limits the locking lever 52, preventing it from returning, and hold it in its original position.

When removing the crossbar 3, the above operation is repeated with the door handle turning in a clockwise direction. The locking lever 52 interacts with the outer side 33 and moves the bolt 3 towards the housing 1. The protrusion 323a on the rod portion 32 also disengages from the recess 85 on the driving lever 8; at this time, the tool 13, inserted into the hole 11, presses the installation axis 5 to move it axially downward, and the axial clearance between the installation axis 5 and the locking lever 52 located on it exceeds the travel distance by two positions of the locking lever, in one of which the locking lever 52 interacts with the outer side 33a of the shoulder 34a, and in another, the locking lever 52 does not interact with the outer side 33a of the shoulder 34a. When the locking lever 52 disengages from the outer side 33a of the shoulder 34a (but the cam lever 51 cannot disengage with the shoulder 87 on the driving lever 8), the return spring 6, in the compressed state, actuates the bolt 3 and pushes it out housing 1, and the bolt 3 can also be removed manually.

When the crossbar 3 is inserted, its end 326, which has a flat shape, acts as a guide, and thus the insertion of the crossbar does not encounter obstacles. In addition, the upper and lower sides of the end 326 of the rod portion 32 of the bolt are symmetrically provided with a bevel 325, which also serves as a guide. Therefore, during the entire process of inserting the crossbar 3, its rod portion 32 freely passes over the locking lever 52.

Thus, the reverse interaction of the locking lever 52 with the outer side (33a, 33b) of the shaft portion 32 can be realized by its rotation around the axis and displacement in the axial direction, as a result of which not only reversible quick insertion of the crossbar 3 is achieved, but also its interaction with door handle. Then, the first protrusion 323a or the first protrusion 323b interact with the recess 85 for further auxiliary fixation of the bolt 3 during operation.

According to one of the embodiments described above, a cam lever 51 located on the mounting axis 5, said first protrusion (323a, 323b) and said second protrusion (324a, 324b), as well as a recess 85 on the driving lever 8, are absent, and the first lever 81a of the second the driving lever 8a according to the second embodiment is directly connected to the locking lever 52, or in the case of using the cam lever 51, the first lever 81 of the second driving lever 8a according to the second embodiment is directly connected to the cam lever 51. Thus m, when the second driving lever 8a is rotated, the locking lever 52 is directly or indirectly actuated, rotates, and thus causes the bolt 3 to move towards the housing 1. When the door handle is released, the second driving lever 8a returns to its original position and frees up the path for the rod to move part 32 of the bolt 3, which actuates the locking lever 52 to return it to its original position. Since the movement of the locking lever 52 is prevented by the transition wall 83 of the driving lever 8 or a similar stop located on the housing 1, this lever can remain in its original position. When the tool 13 presses on the mounting axis 5, the locking lever 52 disengages from the outer side 33a of the shaft portion 32, and thus the bolt 3 can be removed from the lock.

Option 2 implementation mainly relates to the technical solution, consisting in the fact that the locking lever 52 can only move in the axial direction for two-way blocking of the crossbar 3.

In contrast to the embodiment 1, the installation axis 5 does not have a cam lever 51 and is provided with only the locking lever 52. Therefore, in this embodiment, there is no interaction between the installation axis 5 and the drive lever 8. The design of the installation axis 5 is shown in Fig. 12. The mounting axis 5 includes a pin 53b firmly connected to the rear wall 1c, a movable cap 54b worn on the pin 53b, and a return spring 55b located between the pin 53b and the movable cap 54b. The movable cap 54b is movable only in the axial direction along the pin 53b and cannot rotate around its axis. In addition, the drive lever 8 does not have a recess 85, and thus there is no interaction between the first protrusion (323a, 323b) and the drive lever 8.

Another difference from embodiment 1 is that, as shown in FIG. 13, said feed mechanism also comprises a second drive lever 8a, which can be rotatably disposed in said housing 1 and whose central shaft is equipped with a spring 83a, which can return the second driving lever 8a to its original position. The pivot arm 23 of said feed mechanism is combined with the first arm 81a of the second driving arm 8a and the end arm 82a of the second driving arm 8a and interacts with a protrusion (324a, 324b) formed on the shaft portion 32.

As shown in FIG. 13, when the door handle is rotated clockwise, the rotary lever 23 rotates clockwise, the second drive lever 8a is also actuated and rotated counterclockwise, the end lever 82a of the second drive lever 8a moves the bolt 3 in the direction of the specified the housing 1 by means of the protrusion 324a, and the locking lever 52 is disengaged from the shoulder 34a. When the door handle is released, the end lever 82a of the second driving lever 8a stops fixing the crossbar 3, as a result of which the said crossbar 3 is again pulled out of the housing 1, the locking lever 52 again interacts with the outer side 33a of the shoulder 34a and thus prevents the crossbar from leaving the housing. At this moment, by pressing the mounting axis 5 to move it axially from the outer side 33a, the crossbar 3 can be pulled out of the lock or pulled back, and thus the orientation of the bevel of the crossbar 3 can be changed. Thus, the combination of the locking lever 52 installed with the possibility of movement in the axial direction, and the outer side (33a, 33b) of the rod portion 32 provides a reversible design that allows you to quickly insert the bolt 3.

Claims (14)

1. A door lock comprising a housing, as well as a feed mechanism associated with the door handle, and a tapered spring-loaded bolt, configured to lock the doors located in the housing; moreover, the specified crossbar contains a rod part made in the form of a rod, and a head located on the front end of the rod part and having a beveled surface; wherein the core part of said crossbar is coupled to a return spring, which makes it possible for the crossbar head to protrude from an opening made in the side wall of the housing, and the feeding mechanism is configured to move the core part of said crossbar and thereby withdraw its head into the housing; characterized in that the housing also has a guiding mechanism for said crossbar, comprising a chamber for receiving a return spring having an inlet for receiving an end of the rod portion of said crossbar, the return spring acting on this end when it is installed in said hole said crossbar is reversibly fixed in the housing by a reversing-type fixing mechanism, so that the orientation direction of the beveled surface of the head of said crossbar can be selected in accordance with the direction of closing the door. 2. A door lock according to claim 1, characterized in that said fixing mechanism comprises a pair of shoulders which are formed on two opposite sides of the pivotal part of said crossbar and whose outer sides are facing the head of this crossbar, and a locking lever configured to engage from any of the external sides of the specified shoulder or disengaging from any of the external sides of the specified shoulder, so that when the locking lever interacts with the external side of the shoulder, removing the specified rig la of the body is prevented, in the absence of interaction of the locking lever with the outer side of the shoulder is provided the possibility of extracting said pins from the housing. 3. A door lock according to claim 2, characterized in that said fixing mechanism comprises a mounting axis mounted for axial movement, the locking lever being rigidly attached to the mounting axis and moving along with it in the axial direction; and the installation axis itself passes between two opposite sides of the housing and is installed with a gap that allows movement in the axial direction; moreover, this gap is greater than the distance between the two positions of the locking lever, in one of which this lever interacts with the outer side of the shoulder, and in the other there is no interaction of this lever with the outer side of the shoulder, and a return spring is installed between the installation axis and either of the two opposite sides of the housing. 4. A door lock according to claim 3, characterized in that the mounting axis is also mounted to rotate about its axis; wherein said feed mechanism comprises a driving lever, the rotation of which, when the door handle is rotated, causes the locking lever to rotate, which in turn, by means of a shoulder, retracts said bolt into the housing. 5. The door lock according to claim 4, characterized in that the said locking mechanism also comprises a positioning cam lever, which is rigidly attached to the mounting axis or locking lever; moreover, the specified driving lever during its rotation rotates the specified positioning cam lever, which in turn causes the rotation of the locking lever. 6. A door lock according to claim 3, characterized in that the mounting axis is also rotatable around its axis, said locking mechanism also comprising a positioning cam lever that is rigidly attached to the mounting axis or locking lever; said feed mechanism comprises a drive lever that is coupled to said positioning cam lever; when the door handle is rotated, said driving lever is actuated and moved horizontally to rotate said positioning cam lever, which in turn rotates the locking lever, and the locking lever, by means of the shoulder, retracts said bolt into the housing. 7. The door lock according to claim 3, characterized in that between the drive arm and the rod part of said crossbar there is an auxiliary lock, additionally fixing said crossbar. 8. Door lock according to any one of paragraphs. 3-7, characterized in that the installation axis contains an external installation axis and an internal installation axis located inside the external installation axis, wherein the internal installation axis is connected to the end of the external installation axis, there is a chamber between said external and internal axes for accommodating said return spring, the length of the internal installation axis is greater than the length of the external installation axis; the diameter of the mounting holes made in the wall of the housing in accordance with the location of the axis is slightly larger than the outer diameter of the internal mounting axis, and between the mounting axis and part of the wall around the holes there is a return spring. 9. Door lock according to any one of paragraphs. 3-7, characterized in that the mounting axis contains a pin rigidly attached to the side wall of the housing, and a movable cap worn on this pin, and between the pin and the movable cap there is an axial clearance in which the return spring is located. 10. Door lock according to any one of paragraphs. 3-7, characterized in that it further comprises an access hole made in the housing and corresponding to the installation axis, and by means of a tool tip inserted into the specified hole, the installation axis can be moved in the axial direction in order to then disengage the locking lever with the outside of the shoulder with the cessation of interaction with it. 11. Door lock according to any one of paragraphs. 1-7, characterized in that the limiting protrusion is additionally formed on the rod portion of the said crossbar, and the housing also has a limiter interacting with the specified limiting protrusion, and the interaction of these limiter and the limiting protrusion limits the maximum distance over which the specified bolt enters the housing through indicated hole in it. 12. Door lock according to any one of paragraphs. 1-7, characterized in that the end of the rod part of the specified crossbar has a beveled surface, beveled in the direction of the end of the rod part.

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