RU2772699C2 - Gate closing mechanism made with possibility of being mounted on gate with loop with eye bolt - Google Patents

Abstract

FIELD: locking systems.

SUBSTANCE: gate closing mechanism (16) is made with the possibility of being mounted on already existing loop (2) with an eye bolt having protruding threaded part (14). It contains case (17); drive lever (18) mounted with the possibility of rotation around first axis (19) of rotation on case (17); a drive placed in case (17) for rotation of drive lever (18), and connecting mechanism (21) for connection of the drive lever to threaded part (14) of eye bolt (9). Connecting mechanism (21) contains inner sleeve (22) screwed on the protruding part of eye bolt (9), and outer sleeve (23) mounted on inner sleeve (22) with the possibility of sliding back and forward and mounted on drive lever (18) with the possibility of rotation around second axis (24) of rotation.

EFFECT: gate closing mechanism can be mounted on already existing gate without removal of door (1) from support (3); in addition, with the same angular moment that can be applied by gate closing mechanism (16) to door (1), smaller torsion forces act on drive lever (18).

23 cl, 12 dwg

Description

The present invention relates to a gate closing mechanism that can be installed on existing gates suspended from a hinge on the side of a pole by means of an eyebolt hinge. A hinge with an eyebolt, with which the gate is suspended on a support, contains a hinge element installed on the side of the support, a hinge pin located on this hinge element, and an eyebolt. The eye bolt has an eye that is pivotally mounted in accordance with the hinge axis around the pivot on the hinge element, and a bolt extending from the side of the gate through the fastening element on the gate protruding from the side of the gate. The threaded part of the eyebolt has a protruding part, which has a free end, and which protrudes on the side of the fastening element, facing away from the pivot, at some distance from the fastening element of the gate leaf. The fastener is clamped between two adjusting nuts on the threaded section of the eyebolt. Adjusting nuts are used to adjust the distance that the threaded part of the eyebolt protrudes and thus the distance between the gate leaf and the support.

The closing mechanism for gates, to which the invention relates, comprises a housing, a drive lever mounted on the housing with the possibility of rotation around the first axis, a drive for driving a rotating drive lever, and a connecting mechanism for connecting the drive lever with the threaded part of the eyebolt. The body of the closing mechanism for the gate is further adapted to be mounted above or below the eyebolt hinge on the support so that the first axis of rotation is substantially parallel to the axis of the hinge.

Such a gate closing mechanism is known from EP 3162997 A. The operating lever of this known gate closing mechanism has an upwardly directed end in which a vertical elongated hole is provided through which the threaded part of the eyebolt passes. A small block is located in the elongated hole of the actuating arm, having a hole that precisely covers the nut screwed onto the threaded part of the eyebolt. The vertical edges of this hole in the block are slightly rounded so that the block can rotate slightly relative to the eyebolt nut. Such a rotation is needed if the axis of rotation of the lever does not completely coincide with the axis of the eyebolt hinge. The block itself can be slid up and down a short distance in an elongated hole in the operating arm, which is necessary to allow tolerance for the vertical position of the gate closing mechanism on the pole. Sliding the block up and down is also needed if the axis of rotation of the drive arm is not completely parallel to the axis of the eyebolt hinge.

In the known closing mechanism for gates, the upwardly directed end of the drive lever is adapted to be mounted on an eyebolt between the eyebolt and the protruding fastening element. The nut that the block is to interact with must also be installed in this position. Therefore, the problem that arises when installing a gate closing mechanism on an existing gate is that the gate must be removed from its support in order to be able to install the operating lever of the closing mechanism for gates on the eyebolt. In addition, the operating lever must be installed on the eyebolt before the gate closing mechanism can be installed on the post, which makes it difficult to correctly install the gate closing mechanism on the post.

Another disadvantage of the known closing mechanism for gates is that the operating lever can only have a limited length, since it must be on the gate between the eye of the eyebolt and the protruding fastening element, even when the gate leaf is at a minimum distance from the support. This results in high forces as a result of the angular momentum that the gate closing mechanism must apply to the gate leaf, between the end of the operating arm and the eyebolt. Due to the vertical distance that always exists between the position in which the drive lever is mounted on the body of the closing mechanism for the gate and the threaded part of the eyebolt, large torsional forces act on the drive lever. These torsional forces must be absorbed not only by the drive arm, but also by the bearings that hold the drive arm to the body of the gate closing mechanism. Therefore, not only the operating arm, but also the bearings must be strong and heavy in order to prevent damage to the closing mechanism for the gate.

The present invention is directed to a new gate closing mechanism that can be installed on existing gates without removing the gate leaf from its support and in which, for the same angular momentum applied by the gate closing mechanism to the gate leaf, less torsional forces act on the drive lever.

To achieve this goal, the closing mechanism for gates according to the present invention is characterized in that the connecting mechanism comprises an inner sleeve designed to be screwed through the free end of the threaded part of the eyebolt onto the protruding part of this threaded part, and an outer sleeve located on the inner sleeve so that to be able to slide back and forth in the axial direction of the threaded part of the eyebolt, and which is mounted on the drive lever so as to be able to rotate about a second axis of rotation parallel to the first axis of rotation.

Unlike the prior art gate closing mechanism, the actuating arm of the gate closing mechanism of the present invention is connected to that part of the eyebolt which protrudes through the protruding fastener of the gate leaf. Therefore, the gate leaf does not need to be dismantled to install the closing mechanism for the gate. Therefore, another major advantage of this gate closing mechanism is that the distance between the first axis of rotation around which the operating lever rotates and the second axis of rotation around which the connecting mechanism between the operating lever and the eyebolt rotates is substantially greater than in well-known closing mechanism for gates. As a result, the connecting mechanism can apply significantly less force to the eyebolt in order to obtain the same angular momentum acting on the gate leaf. This force can be, for example, two times less or even less, especially if the distance between the first and second axes of rotation is greater than the distance between the hinge axis and the free end of the eyebolt. Therefore, the torsion forces acting on the drive lever and on its bearings are significantly less, in particular, reduced by the same amount as the force applied by the connecting mechanism to the eyebolt.

In one embodiment of the gate closing mechanism of the present invention, the outer sleeve has an open end, allowing the inner sleeve to be screwed through the outer sleeve onto the protruding portion of the eyebolt.

This option allows you to install the connecting mechanism on the eyebolt or remove it when the closing mechanism for the gate is mounted on the post. Therefore, you can first install the closing mechanism for the gate on the support in the correct position under the eyebolt hinge, and then connect its operating lever to the eyebolt of the hinge. In the absence of an inner sleeve, there will be a relatively large gap between the eyebolt and the outer sleeve, which allows, with the right choice of different sizes, to tilt the outer sleeve over the free end of the eyebolt by the combined rotational movement of the outer sleeve around the second axis of rotation and the drive arm around the first axis of rotation.

In one embodiment of the gate closing mechanism of the present invention, the outer sleeve has an inner diameter and a free end designed to fit onto the protruding part of the eyebolt, with the second axis of rotation located at a first distance from the first axis of rotation, and the second axis of rotation located at the second distance, measured along the longitudinal axis of the outer sleeve, from the free end of the outer sleeve, whereby this inner diameter, the first distance and the second distance are determined so that when the gate closing mechanism is installed under the eyebolt hinge and the first axis of rotation coincides with the axis of the hinge , the outer sleeve, when the drive lever was rotated around the first axis of rotation and when the external sleeve was rotated around the second axis of rotation, could be installed on the protruding part of the eyebolt or removed from it in the absence of an internal sleeve.

When the actuating lever is longer, or in other words, when the first distance is longer, the outer sleeve already tilts more during its installation on the free end of the eyebolt when it comes into contact with the eyebolt. Because the outer sleeve only needs to be rotated a small angle to align with the longitudinal axis of the eyebolt, the difference between the inner diameter of the outer sleeve and the outer diameter of the eyebolt may not be large enough to tilt the outer sleeve when sliding it over the eyebolt. -bolt. Moreover, the inner diameter of the outer sleeve is obviously important in order to be able to tilt the outer sleeve over the free end of the eyebolt. The larger this diameter, the faster this becomes possible.

Preferably, the first distance and the second distance are defined so that when the gate closing mechanism is installed under the eyebolt hinge and the first axis of rotation coincides with the axis of the hinge, the outer sleeve is on the eyebolt by a third distance, which is at least 45%, preferably at least 50% and more preferably at least 55% of the inner diameter of the outer sleeve.

The greater the overlap between the outer sleeve and the eyebolt, the stronger the connection between them. Thus, this preferred embodiment allows for increased overlap between them.

Preferably the first distance is less than the distance between the hinge axis and the free end of the eyebolt plus the inner diameter of the outer sleeve.

This short length of the drive arm allows the outer sleeve to be tilted over the eyebolt for a relatively long distance.

In one variant of the closing mechanism for the gate according to the present invention, the threaded part of the eyebolt has an outer diameter, and the outer sleeve has an inner diameter that is at least 15%, preferably at least 20% larger than the outer diameter of the threaded part of the eyebolt. - bolt.

The greater the difference between the outer diameter of the eyebolt and the inner diameter of the outer sleeve, the easier it is to slide the outer sleeve onto the eyebolt and therefore the greater the overlap between the outer sleeve and the eyebolt can be.

In one embodiment of the gate closing mechanism of the present invention, the drive comprises a motor, in particular an electric motor or a hydraulic motor.

The motor is preferably positioned to rotate the drive arm in both directions so that the closing mechanism for the gate is intended not only to close but also to open the gate.

Preferably, such a motor is locked within the gate closing mechanism housing by a locking mechanism so that the operating lever can be rotated by hand.

Therefore, if the motor fails, for example due to a power failure, the gate can still be opened using the locking mechanism. The locking mechanism preferably comprises a cylinder lock actuated by a key.

In another embodiment, the closing mechanism for a gate of the present invention comprises a spring positioned to push the drive arm in one direction to close the gate, and which is tensioned when the gate leaf is rotated in the other direction to open the gate.

This option allows you to automatically close the gate without using the motor.

In one embodiment of the gate closing mechanism of the present invention, the actuating arm is mounted on the gate closing mechanism housing via a double row ball bearing.

The double row ball bearing effectively absorbs the torsional forces acting on the drive arm. Each of both ball bearings can therefore be relatively light.

In one embodiment of the gate closing mechanism of the present invention, the gate closing mechanism body is configured to be mounted on a support such that the first axis of rotation substantially coincides with the extension of the hinge axis.

When the axis of rotation of the drive arm coincides with the continuation of the axis of the hinge, when opening and closing the gate, the outer sleeve does not slide on the inner sleeve or slides a minimum distance, as a result of which the connecting mechanism always maintains maximum strength.

In one version of the closing mechanism for the gate according to the present invention, a hole is made in the drive lever, and on the outer sleeve there is a protrusion that is inserted into this hole and has the ability to rotate in it around the second axis of rotation. Preferably, this protrusion has a free end into which a bolt is screwed to secure the protrusion in the hole.

With the fixed protrusion of the outer bush inserted into the hole in the drive arm, a strong connection between the drive arm and the outer bush can be obtained. In particular, such resistance can withstand relatively large torsional forces acting on it.

In one embodiment of the gate closing mechanism of the present invention, the inner sleeve has a cylindrical outer surface and the outer sleeve has a cylindrical inner surface.

These bushings are not only easy to manufacture, but they also take up minimal space, which improves the appearance of the closing mechanism for the gate.

The invention further relates to a gate mounted on a support by means of an eyebolt hinge, on which is located the closing mechanism for the gate according to the present invention.

Other advantages and features of the invention will become apparent from the following description of a preferred embodiment of the gate closing mechanism of the present invention. However, this description is purely illustrative and does not limit the scope of the claims. The positions indicated in the description refer to the drawings, in which:

Fig. 1 is a perspective view of a gate leaf hung on a post by means of an eyebolt hinge, where the gate closing mechanism of the present invention is located on the eyebolt hinge.

Fig. 2 is the same view in perspective, but from a different angle.

Fig. 3 and 4 are front and top views, respectively, of a gate leaf hung on a post by means of an eyebolt hinge provided with the gate closing mechanism of FIG. 1 and 2.

Fig. 5 is a plan view of FIG. 4 where the inner sleeve has been removed and the outer sleeve of the eyebolt is tilted by the rotation of the drive arm relative to the gate closing mechanism body and by the rotation of the outer sleeve relative to the drive arm.

Fig. 6 is a horizontal section through a closing mechanism for a gate with an inclined outer sleeve and a turned operating lever, as shown in FIG. 5.

Fig. 7 is the same view as in FIG. 3, but in which the eyebolt hinge and the closing mechanism for the gate are shown in longitudinal section.

Fig. 8 is a longitudinal section shown in FIG. 7 at the level of the eyebolt hinge and the operating lever on an enlarged scale.

Fig. 9 is the same view as in Fig. 7, but with the distance between the post and the gate leaf increased with the help of an eyebolt.

Fig. 10 is the same view as in FIG. 7, but where the protruding eyebolt fastener is welded to the gate leaf, instead of being height-adjustable.

Fig. 11 is the same perspective view as in FIG. 1 where the closing mechanism for the gate contains a spring rather than a motor to close the gate.

Fig. 12 is a front view of a gate leaf suspended from a post by means of an eyebolt hinge fitted with the gate closing mechanism shown in FIG. 11, where the eyebolt hinge and spring-loaded closing mechanism are shown in longitudinal section.

The gate leaf 1 shown in FIG. 1 is hinged with its upper part and lower part (not shown) on a support 3, more specifically on a pole, by means of an adjustable height eyebolt hinge 2. A hinge with an eyebolt is described in EP 1528202 B or EP 2778331 A. To fasten this hinge to the leaf 1 of the gate, a guide 4 is welded to the side of the leaf. A slider 5 is inserted into this guide 4, into which two bolts 6 are screwed. of these bolts 6 on the leaf 1 of the gate with adjustable height, a fastener 7 is fixed, protruding from the front side of the leaf 1. An elongated hole 8 is made in the protruding fastener 7 for fastening the eyebolt 9 of the hinge 2. height adjustment, it is also possible to attach the protruding fastening element 7 directly to the gate leaf 1, for example by welding. Such an option is shown in Fig. ten.

In addition to the eyebolt 9, the hinge 2 includes a U-shaped hinge element 10 attached to the face of the post 3, for example by welding. This hinge element 10 has a kingpin 11. The eyebolt 9 has a section 12 of the eye, which is put on the kingpin 11 around the axis 13. The eyebolt additionally has a threaded part 14 passing through an elongated hole 8 in the protruding fastener 7. The threaded part 14 The eyebolt thus has a part which protrudes from the gate leaf fixing element 7 for a distance and contains the free end of the eyebolt. To fasten the eyebolt 9 to the protruding fastener 7, two adjusting nuts 15 are screwed onto the threaded part 15 of the eyebolt 9 on each side of the fastener 7, between which the protruding fastener is clamped. The adjusting nuts 15 allow you to adjust the distance from the gate leaf 1 to the post 3, as a result of which the distance at which the threaded part 14 of the eyebolt protrudes from the fastener 7 also changes.

The gate closing mechanism 16 comprises a housing 17, an actuating lever 18 rotatably mounted about a first rotation axis 19 on the housing 17 of the gate closing mechanism 16; drive 20 shown in FIG. 7, located in the housing 17 to rotate the drive lever 18; and a connecting mechanism 21 for connecting the drive lever 18 with the threaded part 14 of the eyebolt 9. The body 17 of the closing mechanism 16 for the gate is designed to be installed under the hinge 2 with the eyebolt on the post 3 so that the axis 19 of rotation of the wired lever 18 is substantially parallel to, and preferably substantially coincident with, the axis 13 of the hinge 2. When the gate leaf 1 is hung at the bottom of the support 3 by means of the eyebolt hinge 2, the gate closing mechanism 16 can also be mounted on the support above the lower hinge 2. With If necessary, the closing mechanism 16 for the gate can also be installed on the support 3 above the top hinge 2, if the support rises above the top hinge 2 by a sufficient distance.

The coupling mechanism 21 comprises an inner sleeve 22 screwed onto the free end of the threaded portion 14 of the eyebolt 9, and a cylindrical outer sleeve 23 to be slid onto the inner sleeve 22 to slide back and forth in the longitudinal direction of the threaded portion 14 of the eyebolt 9. Preferably, the outer sleeve 23 has a cylindrical inner surface, and the inner sleeve 22 has a cylindrical outer surface, while the inner surface of the upper sleeve 23 covers with some clearance the outer surface of the inner sleeve 22.

The outer sleeve 23 is additionally mounted on the drive lever 18 so as to be able to rotate around the second axis of rotation 24, which is parallel to the first axis of rotation 19. To do this, the drive lever 18 has a vertical hole 25 at its free end, and on the outer sleeve there is a protrusion 26, which is inserted into the hole 25 and has the ability to rotate in it around the second axis 24 of rotation. Both opening 25 and projection 26 are preferably cylindrical. To fasten the protrusion 26 in the hole 26, a bolt 27 is screwed into the free end of the protrusion 26.

To install the inner sleeve 22 on the threaded part 14 of the eyebolt 9, when the outer sleeve 23 is already put on this threaded part 14, the outer sleeve 23 has an open end that can be closed by a screw cap 28. Both at the front end of the inner sleeve 22, and in The front end of the screw cap 28 has a hexagonal cavity for a hex wrench, with which they can be tightened. To prevent the cover 28 from unscrewing, the hexagonal cavity in the cover 28 is reamed after tightening, making this cavity cylindrical. Thus, the inner sleeve 22 can no longer be unscrewed, or can only be partially unscrewed, while the connecting mechanism always remains attached to the eyebolt. Therefore, a potential burglar cannot detach the sash 1 from the support.

The inner sleeve 22 is preferably of such a length that it can be screwed onto the free end of the eyebolt until it stops in one of the two adjusting nuts 15. This allows not only fixing the inner sleeve 22 on the threaded section 14 of the eyebolt 9 by screwing the inner sleeve 22 sufficiently tight, but also to reinforce the protruding part of the eyebolt 9 with the inner sleeve 22. In this way, the eyebolt 9 can better resist the significant forces applied to it by the closing mechanism 16 for the gate.

Alternatively, not shown in the drawings, it is also possible to remove the outer adjusting nut 15 and screw the inner sleeve 22 all the way into the protruding fastener 7 of the leaf 1, if necessary with an intermediate washer. This has the advantage that the sash 1 can be carried a greater distance from the post. However, the leaf 1 in this case must be held in position by unscrewing the outer nut 15 with a clamp mounted on the post 3 and the side post of the gate leaf 1.

As shown in FIG. 5 and 6, it is possible to install the outer sleeve 23 of the connecting mechanism 21 between the operating lever 18 and the eyebolt 9 above the threaded part 14 of the eyebolt 9 after the gate closing mechanism 16 is already installed on the post 3. To do this, it is only necessary to turn the drive lever 18 around the axis 19 of rotation and at the same time turn the outer sleeve 23 around its axis 24 of rotation. Since the inner sleeve 22 has not yet been installed or, in case of disassembly, has already been removed, there is sufficient clearance between the threaded part 14 of the eyebolt 9 and the inner surface of the outer sleeve 23. The outer sleeve here preferably has an inner diameter which is at least 15%, more preferably at least 20% larger than the outer diameter of the threaded portion 14 of the eyebolt 9. The greater this difference in diameter, the further the outer sleeve 23 can be tilted. relative to the eyebolt and the stronger the connection between them will be.

In order to be able to tilt the outer sleeve 23 relative to the eyebolt 9, the actuating lever 18 must first of all be of sufficient length. If the free end of the eyebolt 9 is located at a distance 28 (shown in Fig. 8) from the axis 13 of the hinge, and the second axis of rotation 24 is at a first distance 30 from the first axis 19 of rotation, this first distance 30 must be sufficiently large compared to distance 29, while, however, the first distance does not always have to be greater than distance 29 and may be somewhat less than it. The smaller the first distance 30, the farther it will be possible to tilt the outer sleeve 23 relative to the eyebolt 9. Therefore, the first distance 30 is preferably less than the distance between the hinge axis 13 and the free end of the eyebolt 9 plus the inner diameter of the outer sleeve.

For a predetermined first distance 30, a second distance 31 between the second axis of rotation 24 and the free end of the outer sleeve 23 mounted on the eyebolt 9, measured along the longitudinal direction of the outer sleeve 23, must be small enough that the outer sleeve 23 can be tilted relative to the eyebolt. - bolt 9 by turning the drive lever 18 around the first axis 24 of rotation and turning the outer sleeve 23 around the second axis 24 of rotation. However, the second distance 31 should preferably be chosen to be large enough so that the distance that the outer sleeve 23 extends over the eyebolt 9, hereinafter referred to as the third distance 32, is sufficiently large.

In order to ensure the strength of the connection between the drive lever 18 and the eyebolt 9, this third distance 32, i.e. the overlap distance between outer sleeve 23 and eyebolt 9 is important. When the outer sleeve 23 is to be able to tilt relative to the eyebolt 9 as described above, this distance 32 is greater when the axis of rotation 24 of the outer sleeve 23 is at a larger second distance 31 from the free end of the outer sleeve 23. The first distance 30 is preferably chosen sufficiently small , and the second distance 31 is large enough that when the gate closing mechanism 16 is installed under the eyebolt hinge 2 so that the first axis of rotation 19 coincides with the axis 13 of the hinge, the third distance 32 is at least 45%, preferably at least 50% or more preferably at least 55% of the inside diameter of the outer sleeve.

For example, in the embodiment shown in FIG. 8, the first distance 30 is approximately 80% of the inner diameter of the outer sleeve 23 greater than the distance 29 between the hinge pin 13 and the free end of the eyebolt 9, and the second distance is approx. 143% inner diameter of the outer sleeve. Due to these dimensions, the third distance 32 is essentially equal to 60% of the inner diameter of the outer sleeve 23.

Since the outer sleeve 23 can slide longitudinally over the inner sleeve 22, it is still possible to adjust the distance between the gate leaf 1 and the support 3 by means of the eyebolt 9. For example, in FIG. 7 the gate leaf is closer to the support 3 than in FIG. 9. It is important to note that the distance 32 by which the outer sleeve 23 overlaps the eyebolt 9 is always the same. Therefore, the strength of the connecting mechanism 21 also remains constant.

The sliding connection between the two bushes 22, 23 additionally has the advantage that the closing mechanism 16 for the gate does not have to be correctly positioned on the support 3 under the hinge 2 so that the axis of rotation 19 of the drive arm 18 coincides with the axis 13 of the hinge. Even if the axes do not match, the closing mechanism for the gate will function correctly.

The drive 20 located inside the gate closing mechanism 16 may be a motor, as shown in FIG. 7-10, or by a spring mechanism as shown in FIG. 12.

The motor may be a hydraulic motor, but an electric motor is preferred due to its compactness. In FIG. 7 schematically shows the motor 33 located inside the housing 17 of the closing mechanism 16 for the gate. This electric motor 33 comprises a motor housing 34 with the windings necessary to drive a rotating shaft 35 into rotation. This driving shaft 35 protrudes upwards and enters a gate closing mechanism operating arm 18 to rotate it about the first rotation shaft 19 . The drive lever 18 is mounted on top of the housing 17 of the closing mechanism 16 for the gate on a double-row ball bearing 36 so that it can rotate about the first axis 19 of rotation. The body 16 of the closing mechanism 16 for the gate is screwed to the support 3 with two bolts 37 on top and a third bolt 38.

In the gate closing mechanism 16 shown in FIG. 7, the motor housing 34 has a cylindrical outer casing inserted into a cylindrical space in the housing 17 of the gate closing mechanism 16 . Thus, the motor housing 34 can be rotated in the housing 17 of the gate closing mechanism 16 . However, to rotate the drive lever 18, the motor housing 34 needs to be locked into the housing 17 of the gate closing mechanism 16. To do this, in the embodiment shown in Fig. 7, there is a locking mechanism 39 with a locking cylinder 40. Using the locking mechanism 39, the engine housing 34 can be locked or unlocked with a key. This allows the gate leaf 1 to be opened manually, for example in the event of a power failure.

The gate leaf can be opened and closed by means of a motor. The motor additionally has a control means by means of which it is possible to set the rest position of the drive lever 18. This makes it possible to use the gate closing mechanism for a leaf opening both to the left and to the right.

The gate closing mechanism shown in Fig. 12 does not have a motor as its drive 20, but a spring 41, more specifically a torsion spring. When the gate leaf 1 is opened, the spring 41 is tensed and automatically closes the leaf 1. The closing mechanism for the gate additionally contains a hydraulic damper 42, which dampens the closing movement of the leaf. The hydraulic damper 42 comprises a cylinder 43 divided into two chambers by a piston 44. The damper 42 is provided with a check valve which allows hydraulic fluid to flow from one chamber to the other when the gate leaf is opened. When the leaf is closed, the valve closes and the hydraulic fluid can only flow back to the other chamber through the narrow channel.

As shown in FIG. 12, the drive lever 18 of the gate closing mechanism 16 is mounted on top of the shaft 46 passing through the gate closing mechanism 16 by means of a pin 45. Above and below, between the shaft 46 and the gate closing mechanism body 17, there are double row bearings 47, 48, therefore the drive lever in this case is also mounted on the housing 17 of the closing mechanism 16 for the gate through a double-row bearing.

Both above and below, the operating lever can be installed on the shaft 46 in the same way, using the pin 45. Therefore, the closing mechanism for the gate can be installed on the support 3 in two vertical positions, namely, in one position for the leaf turning to the left and in an inverted position for a sash turning to the right.

In addition to the double row ball bearings 47, 48, the body 17 of the gate closing mechanism 16 is attached to the support 3 by two bolts 49, 50. In FIG. 12, the upper end of the torsion spring 41 is attached to the body 17 of the gate closing mechanism 16, and the lower end of the torsion spring 41 is attached to the shaft 46, more specifically by a pin 51.

The lower part of the body of the closing mechanism for the gate forms a cylinder 43, which is filled with hydraulic fluid and sealed at the top and bottom with oil seals 52. In the upper chamber of the cylinder 43, a threaded bushing 53 is attached to the shaft 46 with a pin 54. The piston 44 itself has a bushing 55 with an internal thread at the top, sleeve 53 of shaft 46. Since piston 44 cannot rotate within cylinder 43, rotation of shaft 46 causes piston 44 to move up and down.

As described above, a check valve (not shown in Fig. 12) is installed in the piston 44, which provides almost no damping when the gate opens. At the bottom of the shaft 46 is a small channel 56 which connects the upper chamber of the cylinder 43 to its lower chamber. At the lower end of the shaft 46, an adjusting screw 57 is screwed into this channel 56. The adjusting screw, more specifically, contains a needle 58, which forms a needle valve, through which it is possible to adjust the flow of hydraulic fluid through the channel 56, or, in other words, the damping effect of the hydraulic damper 42.

Claims (27)

1. Closing mechanism for the gate, made with the possibility of installation on the leaf (1) of the gate, which is pivotally suspended on the side of the support (3) using a hinge (2) with an eyebolt, and the loop (2) with an eyebolt contains a hinge element (10) installed on the side of the support (3), king pin (11) installed in the loop element (10), and eye bolt (9), while the eye bolt (9) has a section (12) of the eye, hinged in the hinge element (10) around the pivot (11) in accordance with the axis (13) of the hinge, and the threaded part (14) passing through the fastening element (7) on the leaf (1) of the gate, protruding from the specified side of the leaf ( 1) gate, and the threaded part (14) of the eyebolt (9) has a protruding part having a free end and protruding sideways from the fastener (7), away from the pivot (11) at some distance from the fastener (7) of the sash (1) gate, while the fastener (7) is clamped between two adjusting nuts (15) on the threaded part (14) of the eyebolt a (9), wherein the adjusting nuts (15) are configured to adjust the distance to which the threaded part (14) of the eyebolt (9) protrudes, and thus the distance between the gate leaf (1) and the support (3), at the same time, the closing mechanism (16) for the gate comprises a body (17), a drive lever (18) mounted with the possibility of rotation around the first axis (19) of rotation on the body (17), a drive (20) in the body for activating the rotation of the drive lever ( 18) and a connecting mechanism (21) for connecting the drive lever (18) with the threaded part (14) of the eyebolt (9), moreover, the body (17) of the closing mechanism (16) for the gate is designed to be installed under the hinge (2) with eyebolt on the support (3) so that the first axis (19) of rotation is parallel to the axis (13) of the hinge, characterized in that the connecting mechanism (21) contains an inner bushing (22) made with the possibility of screwing through the free end of the threaded part (14) of the eyebolt (9) onto the protruding part of the threaded part (14), and the outer bushing (23) mounted on the inner bushing (22) slidable back and forth in the longitudinal direction of the threaded part (14) of the eyebolt (9) and mounted for rotation around the second axis (24) of rotation, parallel to the first axis (19) of rotation, on the drive lever (18) . 2. Closing mechanism for the gate according to claim 1, characterized in that the outer sleeve (23) has an open end, allowing the inner sleeve (22) to be screwed onto the protruding part of the eyebolt (9) through the outer sleeve (23). 3. Gate closing mechanism according to claim 2, characterized in that the open end of the outer sleeve (23) is closed with a screw cap (28). 4. The closing mechanism for the gate according to any one of paragraphs. 1-3, characterized in that the inner sleeve (22) has such a length that it can be screwed onto the free end of the eyebolt (9) until it stops in one of the two adjusting nuts (15). 5. The closing mechanism for the gate according to any one of paragraphs. 1-3, characterized in that the inner sleeve (22) has such a length that it can be screwed onto the free end of the eyebolt (9) until it stops against the protruding fastener (7), instead of one of the two adjusting nuts. 6. The closing mechanism for the gate according to any one of paragraphs. 1-5, characterized in that the outer sleeve (23) has an inner diameter and a free end, made with the possibility of installation on the protruding part of the eyebolt, and the second axis (24) of rotation is located at the first distance (30) from the first axis (19 ) rotation, while the second axis (24) of rotation is located at the second distance (31), measured in the longitudinal direction of the outer sleeve (23), from the free end of the outer sleeve (23), and the inner diameter, the first distance (30) and the second distance (31) are defined so that when the closing mechanism (16) for the gate is installed under the eyebolt hinge (2) and the first axis (19) of rotation coincides with the axis (13) of the hinge, the outer sleeve (23) can be mounted on the protruding part of the eyebolt (9) or remove from it in the absence of the inner sleeve (22) by turning the drive lever (18) around the first axis (19) of rotation and turning the outer sleeve (23) around the second axis (24) of rotation. 7. Gate closing mechanism according to claim 6, characterized in that the first distance (30) and the second distance (31) are defined so that when the gate closing mechanism (16) is installed under the eyebolt hinge (2), and the first axis (19) of rotation coincides with the axis (13) of the hinge, the outer sleeve (23) overlaps the eyebolt (9) by a third distance (32), which is equal to at least 45% of the inner diameter of the outer sleeve (23). 8. Gate closing mechanism according to claim 7, characterized in that the third distance is equal to at least 50% of the inner diameter of the outer sleeve (23). 9. Gate closing mechanism according to claim 7, characterized in that the third distance is equal to at least 55% of the inner diameter of the outer sleeve (23). 10. The closing mechanism for the gate according to any one of paragraphs. 6-9, characterized in that the first distance (30) is less than the distance between the hinge axis (13) and the free end of the eyebolt (9) plus the inner diameter of the outer sleeve (23). 11. The closing mechanism for the gate according to any one of paragraphs. 1-10, characterized in that the threaded part (14) of the eyebolt (9) has an inner diameter, and the inner sleeve (22) has an outer diameter that is at least 15% larger than the outer diameter of the threaded part (14) of the eyebolt bolt (9). 12. Closing mechanism for gates according to claim 11, characterized in that the outer diameter of the inner sleeve (22) is at least 20% larger than the outer diameter of the threaded part (14) of the eyebolt (9). 13. The closing mechanism for the gate according to any one of paragraphs. 1-12, characterized in that the drive (20) contains a motor (33), in particular an electric or hydraulic motor. 14. Closing mechanism for the gate according to claim 13, characterized in that the motor (33) is configured to rotate the drive lever (18) in both directions to open and close the gate leaf (1). 15. Closing mechanism for the gate according to claim 13 or 14, characterized in that the motor (33) is locked in the housing (17) of the closing mechanism (16) for the gate by the locking mechanism (39), and the motor (33) is configured to be unlocked by this locking mechanism (39), which allows you to turn the drive lever (18) manually. 16. The closing mechanism for the gate according to any one of paragraphs. 1-12, characterized in that the drive (20) contains a spring (41) configured to press the drive lever (18) in one direction to close the gate leaf (1) and compresses when the drive lever (18) is turned in the other direction when opening the leaf (1) of the gate. 17. The closing mechanism for the gate according to any one of paragraphs. 1-16, characterized in that the drive lever (18) is mounted on the body (17) of the closing mechanism (16) for the gate using a double-row ball bearing (36, 47). 18. The closing mechanism for the gate according to any one of paragraphs. 1-17, characterized in that the body (17) of the closing mechanism (16) for the gate is designed to be installed on the support (3) so that the first axis (19) of rotation is a continuation of the axis (13) of the hinge. 19. The closing mechanism for the gate according to any one of paragraphs. 1-18, characterized in that the drive lever (18) is provided with a hole (25), and the outer sleeve (23) is provided with a protrusion (26), which is inserted into the hole (25) with the possibility of rotation around the second axis (24) of rotation . 20. Closing mechanism for the gate according to claim 19, characterized in that the protrusion (26) has a free end into which a bolt (27) is screwed to fix the protrusion (26) in the hole (25). 21. The closing mechanism for the gate according to any one of paragraphs. 1-20, characterized in that the inner sleeve (22) has a cylindrical outer surface, and the outer sleeve (23) has a cylindrical inner surface. 22. A gate equipped with a closing mechanism for the gate, wherein the gate leaf (1) is pivotally mounted on the side of the support (3) by means of a hinge (2) with an eye bolt, while the loop (2) with an eye bolt contains a hinge element (10 ) mounted on the side of the support (3), the king pin (11) located in the hinge element (10), and the eyebolt (9) having the section (12) of the eye pivotally mounted in the hinge element (10) around the king pin ( 11) in accordance with the axis (13) of the hinge, and the threaded part (14) passing through the fastening element (7) on the leaf (1) of the gate, protruding from the side of the leaf (1) of the gate, and the threaded part (14) of the eye bolt (9) has a protruding part with a free end, which protrudes laterally from the fastening element (7) in the direction from the pivot (11) at a certain distance from the fastening element (7) of the leaf (1) of the gate, while the fastening element (7) is clamped between two adjusting nuts (15) on the threaded part (14) of the eyebolt (9), whereby the adjusting nuts (15) made with the possibility of adjusting the distance to which the threaded part (14) of the eyebolt protrudes, and, thus, the distance between the leaf (1) of the gate and the support (3), at the same time, the closing mechanism (16) for the gate comprises a body (17), a drive lever (18) mounted with the possibility of rotation around the first axis (13) of rotation on the body (17), a drive (20) located in the body (17) for turning the drive lever (18), and the connecting mechanism (21) for connecting the drive lever (18) with the threaded part (14) of the eyebolt (9), moreover, the body (17) of the closing mechanism (16) for the gate is made with the possibility of installation under or above the hinge (2) with the eyebolt on the support (3) so that the first axis (19) of rotation runs parallel to the axis (13) of the hinge, characterized in that the connecting mechanism (21) contains an inner sleeve (22) screwed onto the threaded part (14) through the free end of the threaded part (14) of the eyebolt (9), and an outer sleeve (23) mounted on the inner sleeve (22) with the possibility sliding back and forth in the longitudinal direction of the threaded part (14) of the eyebolt (9) and mounted on the drive lever (18) with the possibility of rotation around the second axis (24) of rotation, parallel to the first axis (19) of rotation. 23. The gate according to claim. 22, characterized in that the closing mechanism (16) for the gate has the distinctive features according to any one of paragraphs. 2-21.

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