RU200425U9 - Locking device for the perception of the axial load of the shaft - Google Patents

Abstract

The device refers to devices for fixing parts of the shaft-sleeve type. It consists of a shaft with a restrictive sleeve placed on it, in which, on the side of the surface opposite to the surface that perceives the axial load acting on the shaft, a hole is made perpendicular to the shaft axis, in which the pin is located for fixing the restrictive sleeve, and the length of the pin is determined from the ratio, where H is the length of the pin; D is the outer diameter of the restricting sleeve; d is the diameter of the pin; K is the size factor, K = 0.6-1. In the pin, parallel holes are made on both sides of the shaft, in which rod elements are placed in the form of cotter pins or wire ... 7 p.p. f-ly, 5 dwg

Description

The proposed technical solution relates to fastening devices, namely to devices for fixing, mainly, shaft-sleeve parts.

A device for fixing the end of a spring is known, containing a shaft, with a compression spring placed on it, one end of which interacts with a sleeve fixed in a device for attaching containers to the platform frame, and the second end of the spring creates an axial force acting along the shaft on the stopping device in the form of a washer fixed with a castellated nut on the end threaded part of the shaft, while the locking device is closed with a threaded cap: patent RU 2647358, B60P 7/13, B61D 3/20, B61D 45/00, publ. 03/15/2018, bul. No. 8.

The disadvantage of the device is the complexity of the design and its maintenance.

As a prototype, a locking device for the perception of the axial load of the shaft is adopted, containing a restricting sleeve placed on the shaft and taking the load acting on the shaft in the direction of its axis, while a hole is made in the shaft from the side of the surface of the restrictive sleeve opposite to the surface that receives the axial load , perpendicular to the axis of the shaft, which houses the pin for fixing the restricting sleeve and interacting with it: patent RU 154357, B61H 13/34, publ. 08/20/2015, bul. No. 23.

The disadvantages of the device are the complex design of the cast limiting sleeve, the complexity of fastening and maintenance, since a special technological tool with a pneumatic or hydraulic drive is required to secure the device. The design of the device also does not provide the possibility of axial and longitudinal movement of the shaft.

The technical result of the proposed technical solution is to simplify the design of the device, the conditions for its assembly and maintenance, as well as to ensure the possibility of longitudinal movement of the shaft and its rotation, which will expand the scope of the device.

The technical result is achieved due to the fact that in the locking device for the perception of the axial load of the shaft, containing a restricting sleeve placed on the shaft and receiving the load acting on the shaft in the direction of its axis, while in the shaft from the surface of the restricting sleeve opposite to the surface receiving axial load, a hole is made perpendicular to the shaft axis, in which a pin is placed for fixing the restricting sleeve and interacting with it, according to the proposed technical solution, parallel holes are made in the pin perpendicular to its axis, equidistant from the ends of the pin and at a distance exceeding the shaft diameter, and in parallel holes, oriented parallel to the surface of the restricting sleeve, there are rod elements that fix the position of the pin relative to the shaft, and the length of the pin is determined from the ratio:

,

,

where H is the length of the pin;

D is the outer diameter of the restricting sleeve;

d is the diameter of the pin;

K - size factor, K = 0.6-1.1.

Besides:

the value of the size factor K = 0.6-1.

the pin is secured by a wire passing through at least one of the pin holes and completely enclosing the shaft.

the pin is secured with a wire going through both holes in the pin.

at least one washer is placed between the pin and the restricting sleeve.

along the entire length of the pin, a flat is made to a depth of 0.1-0.4 of its diameter, with the pin facing the flat towards the cylindrical recess of the restricting sleeve.

a protective glass is placed on the restricting sleeve.

additional holes for the pin are made in the shaft along its axis at different distances and at different angles with respect to each other.

FIG. 1 shows a diagram of a fastening device for a container lock on a railway platform using a locking device; in fig. 2 is a general view of the locking device; in fig. 3 is a view from the end of the shaft of the locking device with the pin fixing with cotter pins, FIG. 4 is a view from the end of the shaft of the locking device with fixing the pin with a knitting wire, FIG. 5 - options for the location of the pin.

The device and the principle of operation of the proposed locking device for the perception of the axial load of the shaft is explained by the example of a container lock on a railway platform. The latch is designed to prevent empty containers from falling from the platform when they are exposed to an increased wind load in the form of squally winds.

The fastening device is part of the latch, which consists of a shaft 1 mounted with the possibility of longitudinal movement and rotation in the holes of the vertical elements 2 and 3 of the side beam 4 of the platform frame (Fig. 1). The vertical members in the retainer in FIG. 1 are a vertical wall 2 and a plate 3 welded to the upper flange 5 of the side beam 4 with a hole for the shaft 1. A fitting stop 6 is fixed on the upper flange 5 of the side beam 4, on which the fitting 7 of the container 8 transported on the platform frame is installed.

On the working side of the shaft 1, a container retainer is mounted, consisting of a holder 9 rigidly fixed to the shaft 1 with a handle 10, the rod 11 of which engages with the fitting 7 through the window 12 (Fig. 1). The container lock is designed to keep the fitting 7 from vertical movements arising from increased wind load on the container 8 and tending to throw it off the platform.

On the inactive side of the shaft 1 there is a spring 13 in a compressed state (Fig. 5). The shaft itself (not shown) can serve as a guide for the spring 13 of a small diameter, or the spring 13 of a larger size can be fixed in the guide cylindrical bushings - inner 14 and outer 15 (Fig. 2). It is advisable to install the outer sleeve 15 with a minimum gap between its inner hole and the shaft 1 - from 0.1 mm to prevent the spring 13 from skewing.

Bushings 14 and 15 have inner support (thrust) surfaces 16 and centering guide surfaces 17 for the ends of the spring 13. The guide surfaces 17 can be both internal and external, especially if the spring has a small diameter and the shaft 1 serves as a guide element for it. The inner sleeve 14 rests with its outer surface on the wall 2 under the action of the spring 13 on it.

The outer sleeve 15, as a result of the action on it of the force of the compressed spring 13, interacts with its outer surface with the pin 18 (transfers the axial load to the pin 18).

The outer sleeve 15, together with the pin 18, forms a locking device that receives the longitudinal axial load acting on the shaft 1.

The pin 18 is cylindrical and is located in the hole 19 (Fig. 2), which is located on the side of the end of the non-working side of the shaft 1 perpendicular to its axis. The pin 18 interacts with the outer surface 20 of the outer sleeve 15, that is, with the surface located on the opposite side from the action on the sleeve 15 of the axial force applied to the shaft 1.

The length of the pin is determined from the ratio:

,

,

where H is the length of the pin;

D is the outer diameter of the sleeve;

d is the diameter of the pin;

K - size factor, K = 0.6-1.1.

The use of the pin size factor K in the range from 0.6 to 1.1 allows you to select the optimal pin 18 dimensions with different diameters of the outer sleeve 15 and different axial forces.

With the optimal, predominant value of K = 1, the length of the pin 18 is provided, equal to the outer diameter of the outer sleeve 15 in order to increase the surface of interaction of the pin 18 with the surface of the outer sleeve 15 to absorb maximum axial forces and reduce contact stresses. That is, the ends of the pin 18 of length H, determined from the specified condition, will be located on the boundary of the projection of the outer sleeve 15.

K values close to the minimum are used in structures in which the shaft 1 does not experience permanently large axial loads or does not experience axial loads at all, as well as, for design reasons, when the dimensions of the structures are constrained.

In the pin 18 perpendicular to its axis, holes 21 and 22 are made parallel to each other (Fig. 3, 4) for rod elements in the form of cotter pins 23, 24 - at a distance exceeding the diameter of the shaft 1. Holes 21 and 22 are located symmetrically relative to the middle of the pin 18 or at the same distance from its ends.

Instead of cotter pins 23-24, it is preferable to use a knitting wire 25 (Fig. 4) as rod elements for fixing the pin 18, which will keep the pin 18 from turning about its own axis. To secure the pin 18, wire 25 passes through both holes 21 and 22. The ends of the wire can be fixed in different ways: by twisting, as in FIG. 4, bending the short ends of the wire 25 after exiting the holes 21, 22, bending the long ends of the wire 180 ° after exiting the holes 21, 22 and fixing the ends by twisting on the left on the shaft 1 (and not on the right, as in Fig. 4, not shown ), etc.

When the pin 18 is fixed with the wire 25 with twisting of its ends (twisting, Fig. 4), due to equal efforts in the upper and lower branches of the wire 25, the centering of the pin 18 relative to the shaft 1 is ensured.

The use of wire 25 in conjunction with the symmetrical arrangement of the holes 21, 22 relative to the center of the pin 18 ensures its symmetrical position relative to the shaft 1. That is, in this case, the ends of the pin 18 are equally distant from the surface of the shaft 1. This allows the use of the pin 18 of the maximum length to reduce the contact stresses in the event of heavy loads acting on it.

Instead of one wire 25, two separate wires (not shown) can be used, each of which is passed through one of the holes 21 or 22 and completely encloses the shaft 1 with the fastening of the ends of the wire.

Several additional holes can be made in the shaft 1 along its axis at different distances from the end and at different angles with respect to each other, into which the pin 18 can be installed. FIG. 5 shows several options for the location of the pin 18 in such holes. FIG. 2 shows the position of one of these possible holes - pos. 26.

By moving the pin 18 to different positions (Fig. 5), it is possible to adjust the parameters of the spring, such as the force of the initial tightening of the spring 13, the pressing force of the retainer to the frame and, therefore, the required forces to hold the retainer and transfer it to the required (working / non-working) position. For example, when the pin 18 is repositioned from the position shown in FIG. 2, the opening 26 will increase both the tightening force of the spring 13 and the force that must be applied to the handle 10 in order to compress the spring to move the lock to a different position.

To reduce the frictional forces when the shaft 1 is rotated about its axis, one or more washers 27 with antifriction lubricant or made of antifriction material can be installed between the pin 18 and the outer sleeve 15.

The same washers 28 can be installed between the spring 13 and the bearing surfaces 16 of the bushings 14 and 15, as well as between the inner sleeve 14 and the structural element of the mechanism in which the locking device is mounted - pos. 29. Washers 27-29 have a thickness of 1 ... 5 mm or another required in specific designs of devices that use a locking device.

When using washers 27-29, antifriction lubricant with properties corresponding to the climatic conditions of their operation is applied to their surface, as well as to the places of their installation. In this case, the washers act as sliding bearings to reduce the forces of rotation of the shaft 1, which is necessary, for example, for the operation of the lock shown in FIG. 1. In the absence of constant longitudinal movement and rotation of the shaft 1 in the structure in which it is installed, as well as if it is possible to move the shaft 1 only along its axis, without turning relative to it, washers 27-29 are not used.

To protect against dust and atmospheric precipitation, the non-working part of the shaft 1 with the pin 18, washers 27, 28 and part of the spring 13 can be protected by a glass 30, which is put on the outer sleeve 15 with an interference fit.

The cup 30 has a length that ensures the full stroke of the spring 13, i.e., when the spring is fully compressed, the open edge of the cup 30 should not touch the vertical surface of the wall 2, which interacts with the inner sleeve 14 or washers 29 (if used).

The cup 30 is made of a thin-walled material such as metal or plastic such as polyethylene phthalate (PET). As a glass 30 can be used the bottom part of plastic bottles of a suitable diameter - from the number of commercially available or specially made in size.

The glass 30 can also be fixed on the outer sleeve additionally or independently with the help of several spring clips located along the perimeter (circumferential or spiral) of the glass, made in the form of latches such as a petal or strip 31 (Fig. 2). Similar retainers 32 can be formed in the form of several indentations around the perimeter of the glass. The retainers 32 can also be made in the form of annular recesses - solid or separate along the circumference, especially when using a plastic cup. Instead of retainers in the form of dents 32 in the glass 30, welding drops located on the lateral surface of the outer sleeve 15, sawn down to the required height (not shown), can be used. For example, the height of the cut drops can be 0.1-2 mm, so that a glass 30 made of plastic can be put on them with an interference fit.

When using a plastic cup 30, it can be held by spring clips 31, 32 and / or a pin 18 made with a length exceeding the diameter of the outer sleeve 15. For this, the value of the dimension factor K is taken to be greater than one.

Large values of K close to K = 1.1 are used for shafts 1 of small diameter, for example, 30-40 mm.

K values in the range from 1.02 to 1.05 are used for large shaft diameters 1, for example, having a diameter of 80-100 mm or more.

As a result, the use of the indicated values of the coefficient of size K will provide the protrusion of the edges of the pin 18 beyond the outer sleeve 15 by several millimeters, which will allow the plastic cup 30 to be securely fastened to the pin 18. In this case, the cup 30 is put on both ends of the pin 18 protruding beyond the outer sleeve with a force , which will hold the glass 30 on the locking device, protecting it from precipitation and other influences, such as dust.

The outer sleeve 15 may not be provided with inner guiding (centering) surfaces 17, as in FIG. 2, and with external ones - pos. 33, figs. 1. The outer guide surfaces 33 in this case will also protect the end of the spring 13 with anti-friction washers.

Directly at the vertical elements 2 and 3 of the side beam 4 on the side of the non-working part of the shaft 1, holes 34 (Fig. 2) and 35 (Fig. 1) are made perpendicular to its axis for the "emergency" knitting (linking) wire 36 (Fig. 1), which is used when the spring 13 breaks. When the retainer is in good condition, the knitting wire 36 with the bent ends in a free state is put on the open part of the shaft 1 (Fig. 1), or placed in the hole 37 (Figs. 1, 2, 5) with the ends bent on end of shaft 1 - pos. 38 (Figs. 1–5). Instead of wire 36 or 38, a cotter pin with the same cross-sectional dimension (not shown) can be used.

To increase the reliability of the locking device and prevent, during its operation, the rotation of the pin 18 relative to its own axis, from the outer surface of the outer sleeve 15, the pin 18 can have a flat surface - flat 39 (Fig. 8) - along the entire length of the pin 18 and to a depth ( the value by which the transverse size of the pin decreases) by the value of 0.1 ... 0.4 of its diameter (Fig. 5).

The flat 39 is performed in a plane tangent to its lateral cylindrical surface - forming 40 of the pin 18 (Fig. 2).

The surface of the flat 39 under the action on the pin 18 of the forces of the compressed spring 13 is constantly pressed against the outer surface 20 of the outer sleeve 15 or washers 27, if they are used.

The presence of a flat 39 (Fig. 5) allows you to constantly orient the pin 18 in the hole 19 so that the cotter pins 23 and 24 are located parallel to the outer surface 20 of the outer sleeve 15 - to avoid unwanted contact of the cotter pins 23, 24 with the surface 20 and possible abrasion or damage to the cotter pins 23 , 24 when turning the shaft 1 in the process of switching the position of the container lock.

When using a locking rod (pin) 18 with a flat 39, with the retainer in good condition, the cotter pins 23, 24 will not come into contact with the surface 20 at all and will not experience any load.

When using flat 39, the pin 18 can be fixed not with a solid wire 25 (Fig. 4), but with two separate rings threaded into holes 21-22, the ends of the wire can also be fixed by twisting (not shown).

FIG. 1, position 41 shows the position of the wire 36 when the spring 13 is broken.

The operation of the locking device is explained using the example of a container locking device on a railway platform.

To assemble the retainer, the non-working end of the retainer shaft 1 is inserted into the holes of the vertical elements 3 and 2 until the holder 9 stops in the side beam 4 of the platform frame (Fig. 1).

While holding the shaft 1 in this position, washers 29, an inner sleeve 14 with its washers 28, a spring 13, washers 28, an outer sleeve 15 and washers 27 (Fig. 2) are put on its non-working end. Then, keeping the shaft 1 from longitudinal displacement, the outer sleeve 15 is moved along it, compressing the spring 13, so that the hole 19 in the shaft 1 for the pin 18 is released, which is inserted into this hole with one of the cotter pins previously fixed in it 23 or 24 s divorced ends. After that, the outer sleeve 15 is released, and it is pressed by the compressed spring 13 against the flat 39 of the pin 18. The second cotter pin 23 or 24 is fixed in the pin 18 by separating its ends. As a result, the pin 18 reliably holds the outer sleeve 15, which is acted upon by the axial force of the compressed spring 13, which at its second end interacts with the elements of the side frame of the platform.

In the assembled retainer, under the action of the axial force of the spring 13, the outer sleeve 15 is constantly pressed against the pin 18 (or against its flat 39), which is fixed without the possibility of axial movement in the hole 19 of the shaft 1 (Fig. 2), due to fastening with a wire twist 25 or cotter pins 23 , 24 located in the holes 21, 22 directly at the shaft 1 (Fig. 4).

When using washers 27-29, antifriction lubricant with properties corresponding to the climatic conditions of their operation is applied to their surface, as well as to the places of their installation. In this case, the washers act as sliding bearings to reduce the forces of rotation of the shaft 1, which is necessary, for example, for the operation of the lock shown in FIG. 1. In the absence of constant longitudinal movement and rotation of the shaft 1 in the structure in which it is installed, as well as if it is possible to move the shaft 1 only along its axis, without turning relative to it, washers 27-29 are not used.

If it is necessary to change the force of the initial tightening of the spring 13, the pin 18 is set in one of the required positions shown in FIG. five.

A wire 38 or a cotter pin of an appropriate size (not shown) is inserted into the hole 37 and is fixed against falling out of the shaft 1 by bending the ends.

The wire 36, 38 or the cotter pin does not perceive any load when the retainer is in good working order, but is used when the spring 13 breaks - to limit the release of the retainer beyond the size that it has in the working position.

Instead of wire 38 or in addition to it, a wire 36 is put on the open part of the shaft 1 with a large gap, the ends of which are bent so that it is securely held on the shaft 1 and does not interfere with its free movement along its axis.

A glass 30 is put on the outer sleeve 15 (Fig. 2), which is held on it by means of an interference fit or clamps 31 or 32.

The use of the size factor K larger than one allows the glass 30 to be additionally fixed on the ends of the pin 18 protruding by several millimeters. For less damage to the glass 30, the pin 18 can be made with a chamfer of 1-3 mm.

After that, the latch is ready for use and works as follows.

The latch is used when predicting an intense wind load, at which the protrusions of the fitting stop 6 may not keep the container 8 from falling from the platform. In the working position, the retainer under the action of the spring 13 is pressed against the side beam 4 of the frame, and the rod 11 engages with the fitting 7 (Fig. 1). As a result, the rod 11 prevents vertical movements of the container 8 under the action of large wind loads on it - in the form of squally winds.

To unload the container 8 and release its fitting 7, the latch is moved to the inoperative position. To do this, act on the handle 10, compressing the spring 13, and move the shaft 1 along its axis until the rod 11 comes out of engagement with the fitting 7 (that is, from the window 12 of the fitting 7) and further to the end (end) the rod 11 turned out to be beyond the boundary of the side beam 4 (Fig. 1). Holding the spring in such a compressed position with the handle 10, turn the lock relative to the axis of the shaft 1 so that the rod 11 is below the upper flange 5 of the side beam 4. After that, the handle 10 is released, and under the action of the spring 13, the lock is again pressed against the side beam 4, but already without engagement with the rod 11 of the fitting 7. The container 8 can then be removed from the platform. To transfer the latch to the working position after loading the container, the operations described above are performed in the reverse order.

In the non-working position, the latch is also translated when the spring 13 breaks - on purpose or spontaneously. In this case, the axial force of the compressed spring 13 ceases to act on the shaft 1, as a result of which the retainer ceases to be pressed against the side beam 4 of the frame. This can lead to the movement of the lock, mounted on the shaft 1, away from the platform frame and violation of the dimensions of the lock set for its working position, as well as to the violation of the dimensions of the platform.

In the example under consideration, when the spring 13 breaks, the rod 11 under the action of vibration during the movement of the platform will disengage with the fitting 7 and cease to hold the container 8 under the action of vertical and lateral wind loads, which can lead to the container falling from the platform.

To prevent the latch from going out of its size, use wire 38 or 36 as follows. Wire 36 (Fig. 1) is removed from the shaft 1, the retainer is pressed against the side beam 4 and the wire 36 is inserted into the hole 35, bending the ends so that the wire 36 cannot independently leave the hole 35. To indicate the defective state of the retainer and the required repair, the ends of the wire 36 can be brought to the visible part of the platform frame - pos. 41, figs. 1. When using wire 38, remove the glass 30 (Fig. 2), remove the wire 38 from the hole 37 and move it into one of the holes 34 (Fig. 2) or 35 (Fig. 1) with bending the ends, in the same way as and wire 36.

The glass 30 is then returned to its original place, fixing on the sleeve 15 (Fig. 2). Instead of wire 36 or 38 (FIG. 1), a cotter pin with the same cross-sectional dimension (not shown) can be used.

Wire 38 can also serve as a displacement limiter on the shaft 1 of the bushings 14, 15 with washers 27-29 to prevent the loss of these parts in the event of the spring 13 breaking and the pin 18 falling out of the hole 19.

During the operation of the container lock, the locking device itself operates as follows.

After completing the assembly of the retainer, the compressed spring 13 through the inner sleeve 14 acts on the wall 2 of the platform frame, and through the outer sleeve 15 creates a longitudinal force on the shaft 1 (Fig. 1). This force is perceived by a stopping device, which consists of an outer sleeve 15 and a stopper rod - pin 18, fixed stationary in the hole 19 of the shaft 1 (Fig. 2) and acting on the outer surface 20 of the outer sleeve 15. This stopping device transmits the axial force to the shaft 1 and stops (fixes, prevents movement along the shaft 1) the end of the spring 13, which interacts with the sleeve 15.

In the process of transferring the latch from the working position to the non-working position and vice versa, there is a longitudinal movement of the shaft 1 and its rotation about its axis. In this case, the spring 13 is additionally compressed, but the location of its end resting on the outer sleeve 15 does not change, regardless of the forces acting on the shaft 1, since its position is locked (fixed) by the pin 18. As a result, the pin 18 with the outer bushing 15, which together form a locking device for the spring 13, reliably fix (lock) the position of the spring 13, that is, they perform the function of a stop (stopper) for the end of the spring when any working axial loads act on the shaft, pressing the shaft 1 required for its working position or the required position of parts fixed or interacting with it.

Cotter pins 22, 23 and wire 25 may not be subjected to any stress when using pin 18 with flat 39.

The axial force acting on the shaft and perceived by the stopping device can be created not only by the spring 13, but also by any other method or by the action on the shaft 1 - by the weight of the parts, pneumatics, hydraulics, etc.

The use of a solid knitting wire 25 for fixing the pin 18 in the shaft 1 (Fig. 4) allows the pin 18 to be centered relative to the shaft 1, as well as to securely fix it in the shaft 1 without turning the pin 18 relative to its own axis when turning the shaft 1 to transfer the retainer from the working positions in non-working or vice versa.

The implementation in the pin 18 of the flats 39 (Fig. 5) and fixing the pin 18 with the cotter pins 23, 24 also excludes the possibility of turning the pin 18 about its axis and provides a reliable and stable (permanently oriented) location of the pin 18 relative to the adjacent surface of the outer sleeve 15 or washer 27 ( if washers are used) when the latch is working properly.

The use of a protective cup 30 protects the pin 18 of the washers 27, 28 and the outer sleeve 15 from dust, snow and ice, which improves the operating conditions of the locking device and reduces the forces in it that are required to rotate the shaft 1. The cup also prevents the pin 18 from falling out of the shaft 1 when the spring 13 and cotter pins 23 or 24 are broken.

The locking device can be used for shafts that operate under constant or periodic axial load, as well as for shafts in which it is required to prevent axial displacements of shaft 1 and ensure a fixed axially operating position of shaft 1 - in the mechanism in which it is mounted, in the absence of actions on the shaft of axial forces. In this case, the locking device will limit or prevent unwanted axial displacements of the shaft, creating an abutment by the sleeve and the pin for the parts interacting with the shaft when attempting to move them.

No special tools are required to service the proposed locking device. Installation, dismantling and maintenance of the device can be carried out using pliers or pliers, or without tools, if a soft wire is used to fix the pin and as an emergency wire.

Claims (13)

1. A stopping device for the perception of the axial load of the shaft, containing a restricting sleeve placed on the shaft and receiving the load acting on the shaft in the direction of its axis, while in the shaft from the surface of the restricting sleeve opposite to the surface receiving the axial load, a hole is made perpendicular axis of the shaft, in which the pin for fixing the restricting sleeve and interacting with it is located, characterized in that parallel holes are made in the pin perpendicular to its axis, equidistant from the ends of the pin and at a distance exceeding the shaft diameter, and in parallel holes oriented parallel to the surface of the restricting bushings, rod elements are located that fix the position of the pin relative to the shaft, and the length of the pin is determined from the ratio

, where H is the length of the pin; D is the outer diameter of the restricting sleeve; d is the diameter of the pin; K - size factor, K = 0.6-1.1. 2. The stopping device according to claim 1, in which the value of the size factor K = 0.6-1. 3. A stopper device according to claim 1, wherein the pin is secured by a wire passing through at least one of the pin holes and completely enclosing the shaft. 4. A stopper according to claim 1, wherein the pin is secured by a wire passing through both holes in the pin. 5. The stopping device according to claim. 1, in which at least one washer is placed between the pin and the restricting sleeve. 6. The stopping device according to claim 1, in which a flat is made along the entire length of the pin to a depth of 0.1-0.4 of its diameter, and the pin faces the cylindrical recess of the restricting sleeve. 7. A stopping device according to claim 1, wherein a protective sleeve is placed on the restricting sleeve. 8. The stopping device according to claim 1, in which additional holes for the pin are made in the shaft along its axis at different distances and at different angles with respect to each other.

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