RU150303U1 - ABSORBING APPARATUS - Google Patents

Abstract

1. An absorbing apparatus comprising a body with an open neck, wherein a pressure cone, friction wedges with a pressure plate, and a reciprocating device in the form of a package of polymer elastic elements with a curved side surface, between which separation plates with holes are located, are placed in the body; moreover, the package of polymer elastic elements together with the pressure cone and friction wedges is located between the pressure plate and the bottom of the housing and installed in it on a guide rod, characterized in that m, that at least one polymer elastic element of the reciprocating device has at least one outer groove formed by curved and / or rectilinear surfaces of this polymer elastic element converging at an acute angle. 2. The apparatus according to claim 1, characterized in that the angle between the pressure cone and the friction wedges is less than 37 °. 3. The apparatus according to claim 1, characterized in that the holes in the separation plates are made in the form of bilateral convexes and / or a texture is located on the outer surfaces of these plates. The apparatus according to claim 1, characterized in that concentric grooves and / or holes are made on the surface of the pressure plate facing the stack of polymer elastic elements. The apparatus according to claim 1, characterized in that the pressure cone, friction wedges, pressure plate through the package of polymer elastic elements and the housing are fixed to each other by hooks made on the pressure cone and inside the neck of the housing. 6. The apparatus according to claim 5, characterized in that the guide rod is longer than the body. The apparatus according to claim 6, characterized in that at one of the ends

Description

The utility model relates to railway transport and relates to devices designed to absorb the interaction energy of rolling stock units.

A known design of the friction-elastomeric absorbing apparatus [1, Patent RU No. 2225306, B61G 9/16, 03/10/2004]. The apparatus consists of a housing with a closed end part and an opposite open end part made with friction shoes converging inward, which in turn interact with a pressure wedge with a central channel and transfer the load through the spring stop packages of elastomeric pillows installed between the closed end part of the body and the spring focusing. Through the package of elastomeric pillows, as well as the spring stop and the central channel of the pressure cone, a guide rod passes, pressed against the package body. To hold the wedge and friction shoes in the open end part of the housing, the latter has projections under which the counter flanges of the wedge are rotated during assembly.

During repairs, the assembly of this absorbing apparatus requires the presence of special expensive equipment in the car repair depot, which provides preliminary preloading of the elastic elements and rotation of the wedge for engagement with the projections of the hull. Existing equipment does not allow this. Therefore, it is difficult to mass repair such devices in car repair depots.

To reduce the seizure of friction shoes with the housing, annular grooves are made in it, in which bronze inserts are placed. However, the presence of grooves in the housing significantly reduces its strength in this place and, as a result, the kinks of the housing and the failure of the apparatuses observed during operation.

Another disadvantage of the analogue [1] is the low energy consumption of new devices in the state of delivery from the manufacturer, due to the inoperability of the friction surfaces of the pressure cone, friction shoes and the housing made by casting or stamping.

Known absorbing apparatus [2, Patent RU No. 2350501, B61G 9/10, B61G 9/18, 08/22/2007], adopted as a prototype utility model, having softer modes of operation in comparison with the analogue [1] and having high reliability and stability work. It is supplied to ensure ease of assembly in factory and repair conditions.

Such an absorbing prototype apparatus comprises a housing with an open hexagonal neck with friction surfaces converging on a cone inside it. At the same time, a pressure cone, friction wedges with a pressure plate, and a reciprocating device in the form of a package of polymer elastic elements with a continuous curved side surface, between which there are separation plates with punching holes with serrated flanges, are placed in the housing. A package of polymer elastic elements is installed in the housing on the guide rod in the form of a coupling bolt with a nut, the head of which is located in the recess of the bottom of the housing. Such a package, together with a pressure cone and wedges, is located between the pressure plate and the bottom of the housing. In addition, there is also a separation plate between the pressure plate and the stack of polymer elastic elements.

However, the disadvantage of such an absorbing apparatus [2] is the insufficient service life due to the implementation of polymer elastic elements with a continuous curved side surface. This form of these elements is aimed at improving their manufacturability, achieving good energy intensity and power characteristics. However, when these elements are compressed in a bag to absorb kinetic energy from the impact of the absorbing apparatus, they significantly increase in diameter, which causes them to rub against the walls of the housing. This reduces the life of the product.

Another disadvantage of the prototype apparatus is the presence of a separation plate between the pressure plate and the package of polymer elastic elements. Such a plate is designed to improve the retention of this package, however, as a result, the internal space for its placement is reduced. Therefore, it has a relatively small height. As a result, each of the polymer elastic elements experiences excessive deformations during compression during the working stroke of the absorbing apparatus, which reduces their service life. In addition, because of this, the energy intensity of such a package is insufficient, which negatively affects its power characteristics. There is also the possibility of subsidence of the package, loosening of the wedges, and, as a result, the friction unit may lose its capacity for absorbing apparatus due to the loss of contact of the friction surfaces.

The objective of the utility model is to obtain a technical result for increasing the energy intensity and safety of servicing the absorbing apparatus, improving its performance.

The problem is solved in that the absorbing apparatus comprising a housing with an open neck, while the housing contains a pressure cone, friction wedges with a pressure plate, as well as a back-retaining device in the form of a package of polymer elastic elements with a curved side surface, between which there are separation plates with holes, and the package of polymer elastic elements together with the pressure cone and friction wedges is located between the pressure plate and the bottom of the housing and mounted on it on directs rod has the features: at least one polymer elastic member reciprocating retaining device is formed at least one outer groove formed at an acute angle converging curved and / or straight surfaces of the polymer elastic member.

Such an introduction of the outer groove will make it possible to have the shape of polymer elastic elements, which, in contrast to the prototype [2], will not significantly increase in diameter when they are compressed from the impact of the absorbing device, since a significant part of the deformable material around the perimeter of such elements will tend will move in the direction of their groove. Therefore, there will be no abrasion of polymer elastic elements on the walls of the body of the absorbing apparatus, which will increase its service life. At the same time, good energy intensity and power characteristics of these elements in the package will be preserved.

It is also desirable that the angle between the pressure cone and the friction wedges be less than 37 °. This allows you to reduce the spacer force acting on the walls of the body of the absorbing apparatus from the side of the friction wedges due to the transfer of part of the power component to the package of polymer elastic elements. Due to this, it becomes possible to increase the height of this package, which is useful for the following indicators:

- each of their polymer elastic elements in the package does not experience excessive deformations when the apparatus is compressed to a working stroke, which extends their life;

- increases the energy consumption of the package due to the completeness of the power characteristics;

- increases the tightening force of the absorbing apparatus;

- eliminates the possibility of subsidence of the package, loosening of the wedges and, as a consequence, the loss of friction unit its performance due to loss of contact of friction surfaces.

It is advisable that the holes in the separation plates were made in the form of double-sided convexes and / or a texture would be located on the outer surfaces of these plates. This will allow fixing polymer elastic elements on both sides of the plate. It also prevents the development of plastic deformation of polymer elastic elements, which positively affects the completeness of the power characteristics of the absorbing apparatus and, accordingly, its energy intensity.

In order to increase the internal space for placement in the housing of the absorbing package of polymer elastic elements, in contrast to the prototype [2], an intermediate plate is not installed between the pressure plate and the specified package of elements, and instead concentric grooves and / or holes made on the surface perform the holding function pressure plate facing the package of polymer elastic elements.

It is also recommended, in order to increase the safety of servicing the absorbing apparatus, that its pressure cone, friction wedges, pressure plate through the package of polymer elastic elements and the body be fixed to each other by hooks made on the pressure cone and inside the hexagonal neck of the body. Therefore, the entire load from the side of the package of polymer elastic elements will fall not on the guide rod, which due to the breakdown of its thread can shoot, as in the prototype [2], but on the body, which will prevent possible injury to people during, for example, transportation or installation of an absorbing device.

It is advisable that the length of its guide rod would be greater than the length of its body. This is useful for further increasing the height of the package of polymer elastic elements inside the absorbing apparatus in order to increase its energy intensity. In this case, during the operation of the absorbing device as part of the automatic coupling of freight cars of a certain design, the end part of the guide rod will be able to freely extend beyond the bottom of the absorbing device into the cavity formed inside the automatic coupling due to the removal of the rear of its traction clamp.

To prevent the consequences of the return blow of a part of the traction clamp on the end face of the guide rod of the absorbing device, it is recommended that a nut be wound on one end of the rod.

An embodiment of the absorbing apparatus without the use of the hooks mentioned above, made on the pressure cone and inside the hexagonal neck of the housing, is also possible. For this, it is recommended that the guide rod be made in the form of a coupling bolt, on the thread of which a flare nut will be wound. Then this will reliably tighten the pressure cone, friction wedges, pressure plate through the reciprocating device in the form of a package of polymer elastic elements separated by separation plates onto each other on the housing.

It is also recommended that, with the aim of arranging a package of polymer elastic elements of increased height inside the absorbing apparatus to increase the energy intensity of this package, use a coupling bolt along the length of the larger body. For the same purposes, it is recommended to carry out a bonk on the bottom of the body with a height of at least 50 mm, through which the shaft of the coupling bolt will be passed.

In this case, the head of the bolt will be located above the level of the end face of the bottom of the body, and may not even go beyond it during the working stroke of the absorbing device, or go into the cavity formed after impact below the bottom only at the end of the working stroke of the absorbing device. This will improve its performance.

An extreme polymer elastic element of a larger diameter and height than all other polymer elastic elements can be located around the bonnet of the bottom of the body.

In order to obtain a complete and stable power characteristic of the absorbing apparatus, it is recommended to use metal-ceramic inserts on the surfaces of its friction wedges, conjugated with the friction surfaces of the neck of the body.

To enhance the above effect in the case of the introduction of an external groove in the polymer elastic elements of the reciprocating device, it is also recommended that at least one such internal polymer elastic element has at least one internal groove formed by curved angularly converging and / or the rectilinear surfaces of this polymer elastic element.

The essence of the utility model is illustrated by illustrations, where in FIG. 1 shows a frontal section of an absorbing apparatus; in FIG. 2 is a top view A of the absorption apparatus of FIG. one; in FIG. 3 is an enlarged view of the upper part of the absorbing apparatus of FIG. one; in FIG. 4-6 - enlarged views of the upper part of the absorbing apparatus according to other options for its implementation; enlarged views of the upper part of the absorbent apparatus of FIG. 7 is an enlarged view of the bottom of the absorbent apparatus of FIG. 6; in FIG. 8 and 9 - embodiments of the separation plates; in FIG. 10 is a General view of the pressure plate; in FIG. 11-13 - possible embodiments of the polymer elastic elements of the absorbing apparatus.

The absorbing apparatus (Fig. 1, 2) contains a housing 1 with an open hexagonal neck 2 with friction surfaces converging on a cone inside it 3. A pressure cone 4 is placed in the housing 1, friction wedges 5 with a pressure plate 6. A back-retaining device is also located there. in the form of a package of polymer elastic elements 7 with a curved side surface 8. Between the polymer elastic elements 7 are dividing plates 9. The package of polymer elastic elements 7 together with the pressure cone 4 and friction wedges 5 is located ezhdu pressure plate 6 and the bottom of housing 10 and is mounted therein on a guide rod 11, the head 12 of which is housed in the recess 13 of the bottom 10 of the body 1.

The polymer elastic elements 7 are made with at least one additional curved side surface 14, which is divided by a groove 15 with their curved side surface 8.

The angle α (Fig. 3) between the pressure cone 4 and the friction wedges 5 is less than 37 °, and the angle β that converges on the cone into the hexagonal neck 2 of the friction surfaces 3 is less than 3 °, and the angle γ between the friction wedge 5 and the pressure plate 6 is from 0 to 20 °.

In the dividing plates 9 (FIGS. 8 and 9), holes 16 are made with flanges 17 in the form of bilateral convexes, as well as the texture either in the form of intersecting recesses 18 (Fig. 8) or in the form of concentric recesses 19 (Fig. 9).

On the surface of the pressure plate 5 (FIG. 1) facing the stack of polymer elastic elements 7, concentric grooves 20 (FIG. 10) or / and holes 21 are made.

The pressure cone 4 (Figs. 1-3, 5.6), the friction wedges 5, the pressure plate 6 through the package of polymer elastic elements 7 and the housing 1 can be fixed to each other by hooks 22 made on the pressure cone 4 and inside the hexagonal neck 2 of the housing one.

At the end of the guide rod 11 (Fig. 5), to prevent it from falling out of the apparatus during transportation and to return it to its original position when the apparatus is backtracked, it is recommended that the nut 23 be screwed onto the guide rod along its threaded part 24.

An embodiment of the absorbing apparatus without the use of the hooks 22 mentioned above is also possible (Figs. 1-3, 5.6). To do this, it is recommended that the guide rod 11 be made in the form of a coupling bolt (Fig. 6), on the thread 25 of which a flare nut 26 is screwed. In addition, it is recommended to use an increased height of polymer elastic elements 7 inside the absorbing device to increase the energy consumption of this package, apply a coupling bolt in length is longer than the length of the housing 1. For the same purposes, it is recommended that the bottom 27 (Fig. 7) of the housing 1 be bonku 27 with a height of at least 50 mm. Then around it can be located extreme polymer elastic element 28 of larger diameter and height than all other polymer elastic elements 7.

In order to obtain a complete and stable power characteristic of the absorbing apparatus, it is recommended to use ceramic-metal inserts 30 on the surfaces of its friction wedges 5, conjugated with the friction surfaces 3 of the neck 2 (Fig. 4).

In any of the polymer elastic elements 7 can be made, not only at least one groove 15 located along the perimeter of their outer surface, but can also be made together or separately, at least one groove 29 (Fig. 11-13) located on their inner surface.

Such grooves 15 and 29 may be formed by curved and / or rectilinear surfaces of the polymer elastic element 7 converging at an acute angle.

The absorbing apparatus operates as follows.

Under the influence of shock load, from the side of the coupler of freight cars of a train (not shown), the pressure cone 4 of the absorbing device is shifted inside it, compressing polymer elastic elements 7 through the pressure plate 6 and pressing the friction wedges 5 to the friction surfaces 3 of the hexagonal neck 2 of the housing 1, creating friction between them. When it grows to its maximum value with full compression of the polymer elastic elements 7 (at the same given loads and collision speeds), there is an intensive braking of the movement of the pressure cone 4 and absorption of impact energy. In this case, the work spent on the activation of the absorbing apparatus is spent mainly on overcoming the friction forces and compressing the package of polymer elastic elements 7, and is completely absorbed, turning into thermal energy.

When a load is applied, the radial size of the polymer elastic elements 7 increases, but not very significantly due to the tendency of the sections of its curved surfaces 8 and additional curved surfaces 14 to move towards the groove 15.

By acting on their surfaces on the texture in the form of intersecting recesses 18 (Fig. 8) or in the form of concentric recesses 19 (Fig. 9), as well as on the flanging 17 of the holes 16, due to the limitation of the degree of deformation (flattening), the polymer elastic elements 7 do not acquire residual deformation, which is achieved by a positive effect.

In addition, a significant part of the deformable material around the perimeter of the polymer elastic elements 7 will tend to move in the direction of their grooves 15 and / or 29. Therefore, there will be no abrasion of such elements on the walls of the housing 1 of the absorbing apparatus, which will increase its service life. At the same time, good indicators of its energy intensity and power characteristics will remain.

After removing the load, the forces expended previously on the compression of the polymer elastic elements 7, ensure the return of all the moving parts of the absorbing apparatus to its original position.

The use of the proposed absorbing apparatus of increased and stable energy intensity will reduce the impact on freight cars through couplers and increase their uptime before decommissioning.

Information sources:

1. Patent RU No. 2225306, B61G 9/16, 03/10/2004.

2. Patent RU No. 2350501, B61G 9/10, B61G 9/18, 08.22.2007.

Claims (13)

1. An absorbing apparatus comprising a body with an open neck, wherein a pressure cone, friction wedges with a pressure plate, and a reciprocating device in the form of a package of polymer elastic elements with a curved side surface, between which separation plates with holes are located, are placed in the body; moreover, the package of polymer elastic elements together with the pressure cone and friction wedges is located between the pressure plate and the bottom of the housing and installed in it on a guide rod, characterized in that m, that at least one polymer elastic element of the reciprocating device has at least one outer groove formed by curved and / or rectilinear surfaces of this polymer elastic element converging at an acute angle. 2. The apparatus according to claim 1, characterized in that the angle between the pressure cone and the friction wedges is less than 37 °. 3. The apparatus according to claim 1, characterized in that the holes in the separation plates are made in the form of bilateral convexes and / or a texture is located on the outer surfaces of these plates. 4. The apparatus according to claim 1, characterized in that concentric grooves and / or holes are made on the surface of the pressure plate facing the stack of polymer elastic elements. 5. The apparatus according to claim 1, characterized in that the pressure cone, friction wedges, pressure plate through the package of polymer elastic elements and the housing are fixed to each other by hooks made on the pressure cone and inside the neck of the housing. 6. The apparatus according to claim 5, characterized in that the guide rod is longer than the body. 7. The apparatus according to claim 6, characterized in that a nut is screwed on one of the ends of the rod. 8. The apparatus according to claim 1, characterized in that the guide rod is made in the form of a coupling bolt, on the thread of which a flare nut is screwed. 9. The apparatus according to claim 8, characterized in that the coupling bolt is longer than the housing. 10. The apparatus according to p. 8, characterized in that on the bottom of the body is made bonkoy with a height of not more than 50 mm, through which the shaft of the coupling bolt is passed. 11. The apparatus according to p. 10, characterized in that around the bonkoy is an extreme polymer elastic element of a larger diameter than all other polymer elastic elements. 12. The apparatus according to p. 1, characterized in that on the surfaces of its friction wedges, paired with the friction surfaces of the neck of the body, are ceramic-metal inserts. 13. The apparatus according to claim 1, characterized in that at least one polymer elastic element of the reciprocating device has at least one internal groove formed by curved and / or rectilinear surfaces of this polymer elastic element converging at an acute angle. .

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