EA015194B1 - Shock-absorbing device - Google Patents

Abstract

An invention relates mainly to devices of impact energy absorption for use in carriages and locomotives aimed at reducing longitudinal forces, working in a train at hitting of carriages. The task of invention is an increase of efficiency and life time of a shock absorbing device due to introduction of additional selective change the degree of absorption of the shock loading at its large and small values. The shock absorber (fig.3) consists of a body 1 with side walls 2, the body 1 includes friction wedges 4 together with a pressure wedge 3. Wedges 4 are in touch with a bedplate 5 located on a polymeric array. This array consists of the seriously located resilient blocks 6. The claimed features of the invention: friction wedges 4 made with the extended under parts 9, located between the side walls of the body 1 and by overhead part of polymeric array. An embodiment of the shock absorbing device aimed to increase life time of the polymeric blocks comprises applying an anti-friction protective coating on the extended under parts of the friction wedges 9 from the side of polymeric array or providing anti-friction protective straps 10. Application of resilient blocks 6 of polymeric array and location its overhead part encircling thereof with friction wedges 4 promotes power capacity of shock-absorbing device and reliability of its operation.

Description

The invention relates primarily to shock energy absorption devices mounted on cars and locomotives in order to reduce the longitudinal forces acting on a train during a car collision.

A known device that absorbs impact energy [1]. Such an absorbing apparatus consists of a housing in which a pressure wedge, friction wedges are placed. Friction wedges are located in contact with the pressure wedge and the base plate resting on an elastic polymer array consisting of several self-aligning elastic blocks arranged in series. In pairs, the elastic blocks are separated by centering bowl-shaped metal plates sliding along the longitudinal centering ribs made in the housing.

The disadvantage of the analogue [1] is its complexity due to the design features and the presence of a centering connection of some of its elements, as well as the limited (only 110 mm) stroke of the absorbing apparatus.

Known simpler, efficient and with an increased stroke the device that absorbs impact energy [2], adopted as a prototype.

Such an absorbing apparatus consists of a multifaceted housing in which a pressure wedge and friction wedges are placed. Friction wedges are installed in contact with a base plate located on an elastic polymer array consisting of several successive elastic blocks. The elastic blocks are separated by plates and are passed through the rod with them.

Such a prototype apparatus, in contrast to the analogue [1], has a larger working stroke. It also lacks intermediate cup-shaped metal plates. This simplifies the design of the prototype [2] with the possibility of reducing the dimensions of the apparatus and with more than the analogue [1], the number of elastic blocks.

However, the degree of shock absorption by these blocks is not sufficient for large values of this load. This is due to the fact that the frictional forces arising on the contacting surfaces of the hull and wedges are not always sufficient to achieve reliable energy absorption by the moving wedges under the influence of, for example, a significant collision force of the railcars. As a result, the efficiency of the absorbing apparatus decreases.

Therefore, the objective of the invention is to increase the efficiency and durability of the absorbing apparatus by introducing additional selective changes in the degree of absorption of the shock load at its large and small values.

The problem is solved in that the absorbing apparatus, consisting of a housing with side walls, in which friction wedges are placed together with the pressure wedge, which are in contact with the base plate located on the polymer array, consisting of sequentially located elastic blocks, has distinctive signs: friction the wedges are made with elongated lower parts located between the side walls of the housing and the upper part of the polymer array.

The implementation of friction wedges with elongated lower parts is aimed at increasing the contact area of these wedges with the side surfaces of the casing and the side surfaces of the upper polymer elastic elements, which will improve the energy intensity of the absorbing apparatus at high shock load.

The location of the elongated lower parts of the friction wedges between the side walls of the housing and the upper part of the polymer array will increase the radial pressure on the friction wedges from the side of the side of the upper elastic blocks at high impact loads, since in this case they will expand significantly in diameter (flatten), which will increase the pressure of the friction wedges to the walls of the apparatus body and increase the degree of shock absorption. In this case, with small shock loads, the effect of the lateral parts of the polymer blocks on the elongated lower parts of the friction wedges will not be as significant as with large shock loads, the polymer block in this case will work mainly as an elastic element. In this case, the course of the absorbing apparatus will remain large enough, which will positively affect its shock-absorbing characteristics.

That is, due to the fact that during the impact a significant part of the load falls on the upper elastic blocks (closest to the pressure wedge), which experience much more significant deformations as compared to the lower elastic blocks, the deformation of the elastic blocks is greater, the closer they are to the pressure wedge. The stronger the impact, the more the upper elastic blocks expand in diameter and more strongly affect the elongated lower parts of the friction wedges with their lateral surfaces and the greater the energy absorbed by the friction forces. With weak impacts, the polymer block works mainly as an elastic element, practically without affecting the friction wedges with its side walls, as a result, the rigidity of the apparatus does not increase. Thus, during impacts of both small and large forces, the stroke of the apparatus remains sufficiently large.

An embodiment of the absorbing apparatus in order to increase the durability of the polymer blocks can be applied to the elongated lower parts of the friction wedges from the polymer side

- 1 015194 array of anti-friction coating or installation of anti-friction linings.

The invention is illustrated by illustrations.

In FIG. 1 shows a perspective view of an absorbing apparatus;

in FIG. 2 is a section AA in FIG. one;

in FIG. 3 is a section BB of FIG. one;

in FIG. 4 is an enlarged image of the upper elastic block of FIG. 2 with significant deformation;

in FIG. 5 is the same as in FIG. 4, but with a slight deformation of the elastic block;

in FIG. 6 - assembly rod for mounting and dismounting the absorbing apparatus.

The absorbing apparatus consists of a housing 1 with side walls 2. In the housing 1 are placed together with a pressure wedge 3 friction wedges 4 in contact with the base plate 5 (Fig. 2).

The base plate 5 is located on the polymer array, consisting of several sequentially located elastic blocks 6, passed through the rod 7. The pressure wedge is equipped with three hooks 8 (Fig. 2), pressed against the three upper hooks of the housing 1 by a polymer array of elastic blocks 6.

Friction wedges 4 are made with elongated lower parts 9, which are equipped with anti-friction pads 10.

Each of the elastic blocks 6 is made in the form of a sleeve, perceiving shock loads. The sleeve can be made of both elastomers (e.g. rubbers) and polymers (e.g. thermoplastic elastomers), characterized by the necessary combination of ductility (relative deformation can reach 0.5) and dissipative properties with high technology and the possibility of utilization of elastic elements that have exhausted your resource. The outer surface of the sleeve of the elastic blocks 6 can be made spherical.

The variety of materials used in the elastic blocks 6 determines the versatility of its application, including in products that dampen vibrations, absorb energy and in various dampers.

In each of the elastic blocks 6 (Fig. 3), an axial hole 11 is made, through which the rod 7 is passed. The thread on the rod 7 is designed to install an absorbing device in a traction clamp (not shown) and for removal from it. In the outer surface of the friction wedges 4 can be pressed bronze liners 12 (Fig. 1 and 3), reducing the wear rate of the surfaces of the housing 1 and these wedges.

Between the elastic blocks 4 are supporting plates 13.

For mounting and dismounting the absorbing apparatus, an assembly rod 14 (FIG. 6) with an elongated threaded portion 15 and a narrow elongated head 16 is used.

When assembling an absorbing device (not shown), first, a polymer array of elastic blocks 6 is assembled together with a support plate 5 through which an assembly rod 14 is passed, the head of which rests on the support plate 5. Then, the assembled assembly is installed inside the absorption device so that the end of the threaded part 15 stood out. Then they screw a nut on it (not shown), tightening the elastic blocks 4 of the polymer array to the desired strain size.

Next, friction wedges 4 and a pressure wedge 3 are installed on the base plate. Then, the aforementioned screw nut is unscrewed, thereby lifting the elastic blocks 6 upward, until the hooks 8 of the pressure wedge 3 stop in the upper end of the housing 1. Then, the assembly rod is removed from the absorbing device and replace it with the rod 7.

As a result, the absorbing apparatus is ready for operation and operates as follows.

Under the action of the shock load, the pressure wedge 3 is shifted, compressing the elastic blocks 6 and pressing the friction wedges 4 to the housing 1 of the absorbing apparatus. The friction force between the friction wedges 4 and the side walls 2 of the housing 1 increases to the greatest value with full compression of the elastic blocks 6 of the polymer array (at the same given loads and collision speeds). In this case, the work spent on the activation of the absorbing apparatus is spent mainly on overcoming the friction forces and is completely absorbed, turning into thermal energy.

In this case, with a significant shock load, the upper elastic blocks 6 of the polymer array are first deformed, which are flattened and acting by the side surfaces on the wear-resistant linings 10 (Fig. 4) contribute to the additional pressing of the friction wedges 4 to the housing 1, increasing the friction force between them.

With a small shock load, the pressing of the upper elastic blocks 6 to the wear-resistant pads 10 of the friction wedges 4 (Fig. 3) is small. Therefore, the polymer array will work mainly as an elastic element, without causing a significant force on the elongated lower parts of the friction wedges 4 to appear on the lateral sides of the elastic elements, which will positively affect the characteristics of the device (i.e., high shock absorbing abilities and a significant course of the absorbing device will be preserved at weak and strong impacts).

After removing the load, the forces expended previously on the compression of the elastic blocks 6, ensure the return of all the moving elements of the absorbing apparatus to its original position.

- 2 015194

The use of elastic blocks 6 of the polymer array and the location of its upper part with coverage by friction wedges 4 increases the energy consumption of the absorbing apparatus and the reliability of its operation.

Information sources.

1. KI patent No. 2128301 Friction shock absorber, IPC E16E 7/08, В6Ю 9/02, priority 1998.06.02, publication 1999.03.27.

2. Patent I8 2002108920 A1 Absorbing apparatus of a railroad car having a large working stroke, IPC B61O 9/18, priority 2001.05.15, publication 2003.06.10 (prototype).

Claims (2)

1. The absorbing apparatus, consisting of a housing with side walls, in which friction wedges are placed together with the pressure wedge, which are in contact with the base plate located on the polymer array, consisting of sequentially located elastic blocks, characterized in that the friction wedges are made with elongated parts that are located between the side walls of the housing and the upper, closest to the pressure wedge, part of the polymer array. 2. The apparatus according to claim 1, characterized in that from the side of the polymer array the elongated parts of the friction wedges are provided with a wear-resistant coating and / or overlays.