RU2328583C2 - Locking device (variants) and driving mechanism of locking elements pair (variants) - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: on mechanism frame additional link and pair of side links are installed which are pin-joined with additional link and locking elements of device. Additional link creates rotational pair with cross slide that in joint with profiling of locking elements provides guaranteed leaf application to the aperture construction and efforts aligning on locking elements in wide range of exploitation efforts.

EFFECT: decrease of rubbing pairs deterioration; significant decrease in leaf and door-case production accuracy and decrease of their cost.

16 cl, 16 dwg

Description

FIELD OF THE INVENTION

The present invention relates to locking devices, in particular to locking devices for backlash-free locking of the sash relative to the reciprocal structure, as well as to the drive mechanisms of a pair of locking elements.

State of the art

Known locking device for fixing the sash relative to the reciprocal structure (RF patent No. 2194838). The known device closest to the invention by its technical nature contains a pair of opposed locking elements installed in the sash with the possibility of movement relative to the mating parts of the opening structure closed by the sash, and a drive mechanism of the locking elements located in the sash and containing a housing on which it is movable installed a pair of side links associated with locking elements.

The disadvantage of this locking device is that it does not provide locking with the sash pressed against the opening structure, i.e., the valve is backlashless. This is due to the fact that in the known device, the transmission of movement to the locking elements is carried out by means of a gear transmission, including a gear wheel in contact with each other and two gear racks placed on both sides relative to the gear wheel. In this transmission, the gear connected with the handle forms a rigid connection between the gear racks, which prevents the locking elements from being made in such a way that when they interact with the mating parts of the opening structure (holes in the door frame elements), the shutter is guaranteed to be pressed against this structure. In addition, the presence of a gear mechanism complicates and increases the cost of its construction.

There is a simpler solution to the mechanism for actuating the locking elements, excluding gearing from it. This solution is implemented in the well-known mechanism for fixing the leaf of a double-leaf door relative to the door frame (a lock manufactured by "MOTTURA" company, model 96.097, is available for general viewing on the Internet at: http://www.solocks.lv/data/prices / mottura .pdf (p. 7)).

This mechanism (figure 4), which is the closest to the proposed mechanism in technical essence, comprises a housing, a slider mounted for movement in the housing, a pair of side links mounted on different sides of the slide with the ability to move in response to moving the slide and having means connection with locking elements.

However, this mechanism does not provide the possibility of backlash-free locking of the sash relative to the door frame. For both technical solutions discussed above, with certain deviations from the given geometric characteristics of the sash and / or opening structure resulting from distortions, misalignment or exceeding the tolerances during manufacturing or assembly, a situation is possible in which one of the locking elements rests on the opening structure , loses the possibility of further movement, thereby excluding the movement of the second locking element. This is due to the fact that its side links made in the form of levers pivotally mounted on the housing are interconnected by means of a slider (central link) in such a way that the premature entry of one of the two locking elements into tight contact with the opening structure does not allow the other locking element to take its working position. As a result, it is not possible to achieve reliable fixation of the entire sash. In this situation, it is necessary to exert a closing force much higher than normal, which makes it possible to bring both locking elements into working position.

Another disadvantage of the known mechanism is that it is designed to work exclusively in two fixed positions: the locking elements are either fully extended or completely removed. This mechanism also does not have protection against force unauthorized unlocking by axial action on the locking elements in the "open" direction.

US Pat. No. 3,744,829 discloses a differential rack-and-pinion mechanism, proposed to solve a similar problem - balancing the forces on the locking elements when locking the sash in a locking device with several locking elements located on one sash at a distance from each other and moving simultaneously. However, the locking device disclosed in this patent is structurally of a different type: in it, all the locking elements move together in one direction, and the differential mechanism itself is quite complex, heavy and contains many moving parts, which reduces its reliability.

Disclosure of invention

To overcome the above disadvantages of technical solutions known from the above-described prior art, a drive mechanism for a pair of locking elements comprising a housing and a slider mounted with the possibility of movement in the housing is proposed.

The difference between the proposed mechanism and its closest analogue is that it contains a means of differential (changing depending on the conditions) multidirectional movement of the locking elements in response to the movement of the slide, having parts spaced on different sides from the axis of movement of the slide.

This difference eliminates the rigid kinematic connection between the side links of the mechanism, which allows the locking elements to be introduced into interaction with mating elements (the mating parts of the opening structure (door frame, etc.) in which the sash is installed), by means of a common drive, but to a large extent independently of each other (with different sizes of movement of the locking elements depending on the conditions). This, in turn, allows the use of such a mechanism in a locking device with guaranteed backlash-free locking of the sash relative to the design of the opening in a wide range of operating conditions with a given distribution of fixing forces on the locking elements.

This technical result is achieved by simple technical means, in particular by including only one additional articulated link in the mechanism, which actually turns the mechanism into a differential one.

Also proposed is a locking device for fixing the leaf relative to the structure of the opening closed by it, in which the proposed mechanism is used. The locking device comprises a pair of locking elements mounted on the leaf with the ability to move and interface with parts of the opening structure, and a drive mechanism for the pair of locking elements containing a housing mounted on the leaf. The difference between the proposed locking device and its closest analogue (RF patent No. 2194838) is that the aforementioned mechanism comprises a slider mounted to be movable in the housing, and means of differential multidirectional movement of the locking elements in response to the movement of the slide having parts spaced apart sides from the axis of movement of the slider, and the locking elements are profiled and installed with the possibility of creating efforts to press the sash against the structure of the opening during the interaction of the lock boiling elements mating with them parts of the opening structure.

First of all, the proposed locking device and mechanism provide a backlash-free fixation of the sash relative to the opening structure by means of locking elements, which create the force of pressing the sash against the structure due to the interaction of the locking elements with the parts of the opening structure mating with them, which is not provided in both analogues. In addition, the proposed locking device achieves an increased level of reliability of the sash design and ease of use of the sash, increased service life of the locking device due to reduced wear in the friction units, which, in turn, is achieved by equalizing the forces transmitted to the locking elements when the sash is pressed against the structure the opening. If necessary, the invention allows, instead of balancing the forces transmitted to the locking elements, to achieve their desired distribution.

The proposed locking device and the drive mechanism of the locking elements used in it also can significantly reduce the requirements for the accuracy of the manufacture of the sash, the design of the opening and their elements.

A sash is understood to mean any rotary or sliding sash installed in the structure of an opening to be closed and, in particular, designed to open or close access to a fenced area, inside a room or, for example, a safe or a refrigerator. Accordingly, an opening means, in particular, openings in buildings, vehicles, fences or the like. devices.

The locking elements can be made in the form of rod-shaped crossbars with a pointed end, for example with a conical or wedge-shaped working surface of the crossbars. In this case, the mating mating part of the opening structure is made in the form of an opening in the structure, the axis of which is offset relative to the bolt axis in the direction of movement of the sash with the possibility of introducing a pointed end into said hole with elastic contact with the part of the opening and pressing the sash against the opening structure. In this embodiment, the conversion of efforts in the interaction of the crossbars with the design of the opening is provided by the profiling of the crossbars, as well as the location of the movable and fixed elements of the pair (crossbars and counter holes) with an offset relative to each other. However, the aforementioned technical result can be achieved by using many other schemes. For example, profiled can be part of the structure of the opening, interacting with the locking element and made, for example, in the form of a protrusion, and not holes. It is also not mandatory to use sliding bolts or pins. The locking element can be rotatable and interact with the response design of the opening as a cam.

The locking device may further comprise an elastic element located between the mating surfaces of the sash and the reciprocal structure of the opening and providing said elastic contact. An elastic element, preferably made of elastomer, may be secured to a leaf or to an opening structure.

In the simplest embodiment of the invention, an additional link that acts as a means of differential multidirectional movement of the locking elements can form a rotational pair directly with the slider. In this case, the slider or the housing must be equipped with a stopper for fixing the slider in the working position, that is, to prevent spontaneous release of the locking elements from the working position or malicious withdrawal from this position. From a practical point of view, this option is not very convenient: the gear ratio in such a mechanism may be insufficient, so that too much effort may be required to overcome the resistance from the locking elements.

A more practical option is that the additional link forms a rotary pair with a slider, which, in turn, forms a screw pair with a drive link, in which the mechanism contains an element with an external thread mounted rotatably in the housing, while the slider is provided with an internal thread and mounted on an element with an external thread with the possibility of reciprocating movement in response to its rotation. An element with an external thread is preferably made in the form of a screw, supported on the housing by at least one end with fixing relative to the housing in the direction of the center line of the screw.

Firstly, a screw pair facilitates locking, since several turns of the screw correspond to the working stroke of the locking elements. Secondly, a screw pair in a similar design is self-braking, which eliminates the need for additional stoppers. Using the screw as the driving link of the mechanism further enhances the usability of the locking device.

An additional link can be made in the form of a rocker arm, at the ends of which there are axles, while the side links are pivotally mounted on the housing and have grooves in which the axes can rotate the side links in response to the movement of the rocker arm, and the means of connection with the locking elements are made in the form of holes at the ends of the side links.

Another embodiment of the proposed mechanism is possible, in which the additional link is made in the form of three levers pivotally connected together at one of its ends, the second end of one (middle) of the levers pivotally connected to the slider, and the second ends of the other two levers pivotally connected to the side links with the ability to rotate the side links in response to the movement of the levers.

In the next embodiment of the proposed mechanism, the additional link is a cable transmission made in the form of two cables mounted on the side links and placed on both sides of the slider with the ability to move relative to it, while the side links are pivotally mounted on the housing between the cable attachment points, and Means of connection with the locking elements are made in the form of holes at the ends of the side links.

In yet another embodiment, as the indicated means of differential multidirectional movement of the locking elements, the mechanism comprises a plate having elongated connection grooves with locking elements located at an angle to each other on said spaced apart parts, the plate being pivotally connected to the slider.

As mentioned above, in one embodiment of the proposed mechanism, said screw can be installed resting on its body resting on its two ends and play the role of a guide slider along which it moves. In another embodiment, the mechanism may further comprise at least one slide guide, and the screw is mounted resting one end on the housing.

In all embodiments of the invention, suitable means of connecting the side link to the locking member may be used. In particular, the side links can be pivotally connected to the locking elements by means of holes or grooves at the ends of the side links into which an axis or protrusion is inserted at the end of the locking element, or, conversely, the side link can be provided with an axis inserted into the opening in the locking element. The connection of the side links of the mechanism with the locking elements can be realized by installing articulated rods between them. At the same time, the lateral links of the mechanism can be connected to the locking elements directly or by means of mechanical gears of another type.

Brief Description of the Drawings

A detailed description of the invention is accompanied by the following drawings, schematically illustrating the essence of the invention by the example of its implementation in the design of the door unit.

Figure 1 schematically shows a General view of the door block with a locking device for fixing relative to the door frame of one of the leaves of a double or half door, which is usually always in the closed position (rarely used).

In Fig.2 and 3 shows a local section of the locking device in the area marked in Fig.1 remote element I, with the unlocked (Fig.2) and fixed (Fig.3) sash, respectively.

Figure 4 presents the image of the mechanism - the closest analogue of the invention.

Figure 5 presents a view in isometric projection of the proposed mechanism in a preferred embodiment.

Figure 6 presents a plan view of the proposed mechanism in a preferred embodiment.

In Fig.7 shows a section aa, indicated in Fig.6.

On Fig presents a view in plan of the proposed mechanism with the unlocked sash with the allocation of invisible elements dotted.

Figure 9 presents a view in plan of the proposed mechanism with a fixed sash.

Figure 10 presents a view in plan of the proposed mechanism in another embodiment.

11-13, the following alternative embodiment of the mechanism.

On Fig-16 presents another alternative embodiment of the mechanism.

The implementation of the invention

Figure 1 schematically shows a General view of the door block with a locking device for backlash-free locking of the leaf 1, which is one of the leaves of a double-leaf door, relative to the design of the opening in the form of a door frame 2. In Fig. 1, the door block is shown from the inside, while the main leaf is conditionally not shown and sash 1 is locked. The locking device contains a pair of opposed locking elements, made in the form of crossbars 3 and designed to fix and press the sash 1 to the door frame 2 (hereinafter, locking elements in the general case are understood to mean both the crossbars themselves and the rods extending from them).

To drive the bolts 3 when locking and unlocking, the leaf 1 has a drive mechanism 4 connected to the bolts 3 (hereinafter, for brevity, the mechanism). As shown in FIGS. 2 and 3, the crossbar 3 is movably mounted in the sleeve 5, rigidly fixed in the leaf 1. The crossbar 3, thus installed and connected to the mechanism 4, can be moved into the hole 6 made in the profile of the door frame 2, and out of him. To create a force to press the sash 1 to the door frame 2, the crossbar 3 and the hole 6 are located relative to each other so that the axis of the hole 6 in the profile of the door frame 2 is slightly offset from the axis of the crossbar 3 in the direction of movement of the sash 1 when it is pressed against the door frame 2 As can be seen in FIGS. 2 and 3, the distance between the axis of the crossbar 3 and the axis of the hole 6 before starting the interaction of the crossbar 3 with the edge of the hole 6 decreases in the final phase of this interaction. The crossbar 3 is profiled so that, when interacting with the edge of the hole 6, the sash 1 is pressed against the door frame 2. For this, the crossbar 3 shown in FIGS. 2 and 3 has a conical working surface. In the process of sliding the conical working surface of the crossbar 3 along the edge of the hole 6, the force applied to the crossbar 3 is converted into the force of pressing the sash 1 against the door frame 2.

To ensure elastic contact of the mating surfaces of the sash 1 and the door frame 2 around the perimeter of the sash 1 is installed an elastic element 7, preferably made of elastomer. When the shutter 1 is locked, the elastic element 7 presses the working surface of the bolt to the edge of the hole, providing a power closure of the bolt-hole pair, and seals the gap between the shutter and the door frame.

For a more visual illustration of the essence of the present invention, Fig. 4 shows an image of the closest analogue of the invention - a mechanism for fixing a leaf of a double-leaf door. The known mechanism comprises a housing 8, a slider 9, mounted for translational movement relative to the housing 8, and a pair of side links 10 mounted to rotate on the housing 8 on opposite sides of the slider 9. The housing 8, the slider 9 and the side links 10 constitute a kinematic chain of the mechanism moreover, the slider 9, which performs the function of a leading link in this mechanism, and the lateral links 10, which are driven, are interconnected by means of an axis 11 protruding from the slider 9 and passing into the through grooves made in the lateral links 1 0. With linear movement of the slider 9 in the housing, the side links 10 synchronously rotate relative to the housing.

Figure 5-9 presents a preferred embodiment of the proposed drive mechanism of the locking elements (position 4 in figure 1). In this embodiment, the slider is included in the kinematic chain of the mechanism as a link forming a helical pair with the leading link of the mechanism. The leading link in the mechanism, that is, the link to which the forces are applied to drive the mechanism, is a screw 12, the end of which is provided with a slot 13 for a screwdriver. The function of the driven links that transmit the movement to the crossbars 3 is performed by the side links 10.

One way or another, these links of the mechanism are mounted on the casing 8, a fixed link, which is called a rack in the theory of mechanisms. Since the leading and driven links are closed to the housing 8, the kinematic chain of the mechanism is closed. As shown in figure 5, where the mechanism is depicted in isometry, the housing 8 is made in the form of a bracket having a base and two sides protruding from the base. The screw 12 is supported on the sides of the housing by two ends.

In the considered structural embodiment, the link of the mechanism forming a screw pair with the screw 12 is a slider made in the form of a nut 14. The nut 14 is a continuous cylinder in which a threaded hole is made, passing diametrically through the middle of the side surface of the cylinder.

Interacting with the screw 12, the nut 14 acts as a connecting link, with which, in accordance with the concept of the invention, forms a rotary pair an additional link made in the form of a rocker 15 mounted on the nut 14 with the possibility of rotation and located between the side links 10. At the same time, participating in transmitting movement to the side links 10, the beam 15 also performs the function of a connecting link.

Structurally, the rocker arm 15 is a unit assembled from two plates, in each of which a hole is made in the center covering the cylindrical surface of the nut 14. The rocker arms 15 are interconnected by hollow axles 16. The hollow axles 16 are also used to transmit movement from the rocker 15 to the lateral links 10. In this embodiment, each side link 10 is installed on the base of the housing 8 by means of a sleeve 17 and is made in the form of a swinging link with a groove (slot) on the side that interacts with the hollow axis 16 connecting the plates to the corresponding the leading end of the beam 15. In addition, each side link 10 has the ability to rotate between the extreme positions determined by the stop of the side link in the corresponding side of the housing 8, which is clearly shown in Figs. 8 and 9. The sleeve 17 performs the function of the axis of rotation of the side link 10, and can be used to pass through the fastening elements of the mechanism to the sash, which allows you to unload the body parts 8 from the loads and to close these loads on the sash design.

Each of the side links 10 is connected to the crossbar 3 or the deadlift of the crossbar through the hole 18. Instead of the hole, any other suitable side link element, such as an axle or groove, can serve as a means of connecting the side link with the locking element.

The mechanism in the embodiment shown in figures 5-9, operates as follows.

When the shutter is locked, the rotation of the screw 12 is converted into a translational movement of the nut 14 along the screw 12 relative to the housing 8. In this case, the beam 15 moves together with the nut 14, interacting with the side links 10. The reaction force from one side of the side link 10 can be (and, as a rule , happens) more than from the other side, due to the fact that one crossbar 3 enters into conjunction with the edge of the hole 6 earlier or tighter than the other. The difference in reaction forces causes an ever-increasing rotation of the rocker arm 15 relative to the normal to the axis of the screw towards the "braking" side link 10.

As soon as the rocker 15 brings the first, more pliable, side link 10 to the extreme position (which can correspond to the stop of this side link in the side of the housing or a sufficiently tight fit of the corresponding bolt 3 with the edge of the hole 6 in the door frame), the continued rotation of the screw 12 will be converted into the rotation of the second, stiffer side link 10 until the reaction on its side is equal to the reaction of the first side link. In this phase, the rocker 15 essentially acts as a lever rotating relative to the practically stationary hinge axis 16 conjugated to the first side link.

The above description of the construction was given only as an example of a specific embodiment of the mechanism, stated in general terms in the claims. However, other constructive embodiments of the mechanism and its means of differential multidirectional movement of the locking elements are possible, which will be confirmed below by other examples of the possible implementation of the mechanism according to the invention.

Figure 10 presents a plan view of the proposed mechanism in another embodiment, where the additional link, as in the above embodiment, forms a rotational pair with a connecting link in the form of a slider 19, mounted with the possibility of linear movement relative to the housing along the guides 20, rigidly connected with the housing 8, and forming a screw pair with the drive link of the mechanism, made in the form of a screw 21. In contrast to the screw 12 shown in Fig.5-9, the screw 21 is supported on the housing 8 at one end with fixation from axial displacement Itelno body.

An additional link in this embodiment is made in the form of three levers, one of which is made in the form of a rocking chair 22, one end pivotally mounted on a slider 19, and the other end - articulated with two levers in the form of rods 23, connecting it with the corresponding side links 10. Lateral links 10, in turn, are connected to crossbars 3, the direction of movement of which is indicated by arrows.

In this embodiment, the alignment of forces on the lateral links is achieved by incorporating the mechanism of the rotary pair of "slider-rocking" into the kinematic chain. The angle of rotation of the rocker 22 relative to the slider 19 is limited by the bonds imposed by rigid rods 23.

It should be noted that figure 5-10 as an example embodiment of the invention presents the design options of the proposed mechanism in a symmetrical design. With a symmetrical design, the mechanism provides an equalization of the forces transmitted by the side links 10 to the crossbars 3. However, the invention can find application and, if necessary, provide a given degree of unevenness of the pressure of various parts of the leaf to the design of the opening. This can be achieved by asymmetric execution of the mechanism, for example, the implementation of the rocker 15 is unequal.

5-10, pivoting side links 10 are shown as an example embodiment of the invention. However, the use of pivoting links is only one way of changing the direction of transmitted movement. Therefore, the invention is also practicable using other options for the movable installation of the side links relative to the housing.

11-13, a mechanism is presented in another embodiment, where the additional link is a cable transmission made in the form of two cables 24 and 25, mounted on the side links 10 on different sides of the bushings 17, through which each side link 10 is mounted on the base of the housing 8. In the housing 8, a screw 12 is installed, similarly to the embodiment shown in FIGS. 5-9, along which a slider 26 moves, equipped with a nut with an internal thread. However, in this case, the slider 26 is also equipped with two independently rotating rollers or sliding surfaces spaced in height, in the grooves of which ropes 24 and 25 move, covering the slider 26 on both sides. Each of the side links 10 is connected to the bolt 3 (or traction) by holes 18 at the ends of the side links or in another suitable way.

In this embodiment, when moving the slider 26, one cable is tensioned and the other is weakened, which leads to the rotation of the side links 10 relative to the bushings 17. Depending on where the slider 26 moves, the ends of the side links 10 converge or diverge with the holes 18. In this case also provides differential multidirectional movement of the crossbars 3 in response to the movement of the slider 26.

In some cases, such an implementation will be most preferable, since it can provide additional features and benefits due to the flexibility of the cables. In particular, the levers may not be mounted on the housing of the drive mechanism, but spaced to the edges of the doors. The system may have an arbitrary length. Cables can be placed in various places, while avoiding obstacles, etc.

On Fig-16 presents another embodiment of the inventive mechanism, in which there are no lateral links, and the mechanism is equipped with an element for connecting the slider with locking elements, made in the form of a plate 27, pivotally connected on one side with the slider 28, as in the previous embodiment equipped with a part with an internal thread and moving along the screw 12 installed in the housing 8.

The plate 27 has parts spaced apart on different sides from the axis of movement of the slider, in which elongated grooves 29 are made, located at an angle to each other and to the specified axis of movement of the slider. The crossbars 3 (or the corresponding rods) are connected to the grooves by means of axes (protrusions or the like) or the bent ends of the rod-shaped elements installed in the grooves 29 with the possibility of moving along them with approaching or moving away from the axis of movement of the slider.

In this embodiment, when moving the slider 28, the indicated axes move at the ends of the crossbars 3 along the grooves 29, which leads to a divergence or convergence of the crossbars 3 depending on where the slider 28 moves. With uneven movement of the crossbars 3, the plate pivots about the slide 28 and at the same time also provides differential multidirectional movement of the crossbars 3.

Claims (16)

1. The drive mechanism of a pair of locking elements, comprising a housing, an element with an external thread mounted in the housing for rotation, and a slider provided with an internal thread and mounted on an element with an external thread with the possibility of reciprocating movement in response to its rotation, means of differential multidirectional movement of the locking elements in response to the movement of the slider having parts spaced on different sides from the axis of movement of the slider, characterized in that it contains a pair of lateral x links mounted on different sides of the slider with the possibility of rotation in response to the movement of the slider and having means of connection with the locking elements, while the means of differential multidirectional movement is made in the form of an additional link located between the slider and the side links. 2. The mechanism according to claim 1, characterized in that the additional link is pivotally connected to the slider and side links and is made in the form of a rocker arm, at the ends of which there are axes, while the side links are pivotally mounted on the housing and have grooves in which these axes enter with the ability to rotate the side links in response to the movement of the rocker. 3. The mechanism according to claim 1, characterized in that the side links are pivotally mounted on the housing, while the additional link is made in the form of a rocking chair and two rods pivotally connected together at one of its ends, the second end of the rocker being pivotally connected to the slider, and the second ends of the rods are pivotally connected to the side links with the possibility of rotation of the side links in response to the movement of the rods. 4. The mechanism according to claim 1, characterized in that the additional link is a cable transmission made in the form of two cables mounted on the side links and placed on both sides of the slider with the ability to move relative to it, while the side links are pivotally mounted on the housing between cable attachment points. 5. The mechanism according to any one of claims 1 to 4, characterized in that it further comprises at least one slide guide, and the element with an external thread is made in the form of a screw mounted at one end resting on the housing with fixing relative to the housing in the axial direction screw lines. 6. The drive mechanism of a pair of locking elements, comprising a housing, an element with an external thread mounted in the housing for rotation, and a slider provided with an internal thread and mounted on an element with an external thread with the possibility of reciprocating movement in response to its rotation, differential means multidirectional movement of the locking elements, having parts spaced on different sides from the axis of movement of the slider, characterized in that as the specified differential means directional movement of the locking elements, it contains a plate having elongated grooves of connection with locking elements located at an indicated spaced apart angle at an angle to each other, and the plate is pivotally connected to the slider. 7. The mechanism according to claim 6, characterized in that it further comprises at least one slide guide, and the element with an external thread is made in the form of a screw mounted with its one end resting on the housing with fixing relative to the housing in the direction of the screw axial line. 8. A locking device for fixing the leaf relative to the structure of the opening closed by it, comprising a pair of locking elements mounted on the leaf with the ability to move and interface with parts of the opening structure, and a drive mechanism for a pair of locking elements, comprising a housing mounted on the leaf, an element with external thread, mounted in the housing with the possibility of rotation, a slider provided with an internal thread and mounted on an element with an external thread with the possibility of reciprocating movement from test for its rotation, a means of differential multidirectional movement of the locking elements in response to the movement of the slider, having parts spaced on different sides from the axis of movement of the slider, and the locking elements are profiled and installed with the ability to force the leaf to be pressed against the opening structure when the locking elements interact with the mating with them parts of the construction of the opening, characterized in that the drive mechanism comprises a pair of side links mounted on opposite sides of the slide with the possibility NOSTA rotation in response to movement of the slider and having a connection means with locking elements and an additional link, performs the function of the differential displacement of said multi-directional means of the locking elements and arranged between the slider and the side links. 9. The device according to claim 8, characterized in that the additional link is pivotally connected to the slider and side links and is made in the form of a rocker arm, at the ends of which there are axes, while the side links are pivotally mounted on the housing and have grooves in which these axes enter with the ability to rotate the side links in response to the movement of the rocker. 10. The device according to claim 8, characterized in that the side links are pivotally mounted on the housing, while the additional link is made in the form of a rocking chair and two rods pivotally connected together at one of its ends, the second end of the rocking joint pivotally connected to the slider, and the second ends of the rods are pivotally connected to the side links with the possibility of rotation of the side links in response to the movement of the rods. 11. The device according to claim 8, characterized in that the additional link is a cable transmission made in the form of two cables mounted on the side links and placed on two sides covering the slider with the ability to move relative to it, while the side links are pivotally mounted on the housing between cable attachment points. 12. The device according to claim 8, characterized in that the side links are pivotally connected to the locking elements. 13. The device according to claim 8, characterized in that the locking elements are provided with rods pivotally connected to the side links. 14. A locking device for fixing the sash relative to the structure of the opening closed by it, comprising a pair of locking elements mounted on the sash with the ability to move and interface with parts of the opening structure, and a drive mechanism for a pair of locking elements, comprising a housing mounted on the sash, an element with external thread, mounted in the housing with the possibility of rotation, a slider equipped with an internal thread and mounted on an element with an external thread with the possibility of reciprocating movement in test for its rotation, a means of differential multidirectional movement of the locking elements in response to the movement of the slider, having parts spaced on different sides from the axis of movement of the slider, and the locking elements are profiled and installed with the ability to force the leaf to be pressed against the opening structure when the locking elements interact with the mating with them parts of the construction of the opening, characterized in that the said means of differential multidirectional movement of the locking elements includes There is a plate having elongated grooves of a connection with locking elements located on said spaced apart parts, located at an angle to each other, the plate being pivotally connected to the slider. 15. The device according to 14, characterized in that the drive mechanism further comprises at least one slide guide, and the element with an external thread is made in the form of a screw mounted with its one end resting on the housing, with fixing relative to the housing in the direction of the screw axial line . 16. The device according to 14, characterized in that the locking elements are connected to the grooves through pins or bent ends of the rod-shaped elements installed in the grooves with the possibility of movement along them.

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