DE2626169A1 - DEFORMABLE COMPONENT FOR BUFFER, IN PARTICULAR FOR AUTOMATIC COUPLING DEVICES OF RAILWAY CARRIAGES - Google Patents

Description

description
to the patent application

from SKF Industrial Trading and Development Company B.V., Jutphaas, Plettenburgerweg, Holland

concerning

Deformable component for buffers, in particular for automatic coupling devices of railway wagons

The invention relates to high energy absorption buffers, such as buffers for use in devices for the automatic coupling of railway wagons. In particular The invention relates to a deformable component for installation in buffers of this type, the component being of high strength has, with tensile stress-elongation characteristic, substantially linear shape, during each deformation cycle a large part of the stored energy should be converted.

It is known that buffers are used in many cases, particularly in automatic coupling devices for railroad cars made that can absorb high impact energy, some of which is to be released to the environment during the operating cycle. Such buffers can consist of a plurality of deformable components made of deformable metal elements, for example Springs or elements made of a material with plasto-elastic properties, for example an elastomer element exist. In the former case, the deformable elements have only a weak ability to convert energy. If you are out Because of this, incorporating friction elements, there are other disadvantages, such as wear and tear and instability of the various Elements. In the latter case, however, it is difficult to achieve the required strengths within acceptable sizes

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to achieve, due to the high deformability of such a material.

It is also known to build buffers or shock absorbers with a deformable element of one of the above Types (springs or elements made of a material with plasto-elastic properties) associated with hydraulic working buffers, whereby the damping effect is achieved, by allowing a fluid, for example oil, to flow through appropriate restriction openings. Buffers of this type are very complicated and therefore expensive to manufacture.

The object of the invention is to create a deformable component for buffers and shock absorbers in which both high impact energies can be absorbed, as well as considerable amounts of energy can be converted into heat.

At the same time, the component should not take up much space and be simple and compact in structure. After all, should too the tensile strain-elongation characteristic is essentially linear be.

The solution to this problem results from patent claim 1, while the subclaims define preferred developments.

The mode of operation of such a component can be described as follows: As the deformable material, for example an elastomer as practically incompressible. be considered it follows that a shortening of the length must be accompanied by an increase in the cross section. The function of the Metal element is to make a certain internal pressure 'required before expansion takes place, and thus the longitudinal deformation of the component becomes possible. This pressure expands the metal element and increases the compression load compared to the value that would be required to order an element made of deformable material without a metallic insert to deform the same amount. Overall, the

Strength of the component increased. gQ9952 / 0322

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Embodiments of the subject matter of the invention are explained in more detail below with reference to the accompanying drawings.

Fig. 1 shows schematically the application

of a deformable component according to the invention

2 shows the deformable component in perspective, partially in section according to the invention

Fig. 3

- 8 are longitudinal sections of deformable components according to the invention in various ways Embodiments

Fig. 9 shows some force-displacement diagrams

Characteristics recorded with components according to the invention for explanation the achieved hysterics.

According to Figures 1 and 2, a buffer can be selected from a plurality of deformable components 1 exist in series one behind the other are arranged between a movable plate 2 and a fixed plate 3, the former with a force F can be burdened, for example by the impact a mass that is stopped by parts that are connected to the plate.

The component according to the invention consists of a first element made of deformable material 4 (FIG. 2) and at least one further metal element 5 of a corresponding shape, for example made of a wire wound in the shape of a cylindrical helix and completely embedded in the material that makes up the first element. The first element can be made of any deformable material, preferably a material with plastic-elastic properties, i.e. such a material that converts energy into heat while the deformation. Suitable materials are elastomers, plastic materials and natural and synthetic rubbers.

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The metal element 5 consists of at least one elastic system, which is dimensioned so that it can withstand an internal pressure, in the case of deformations according to the required strength; it can be in the form of a coil spring, with either Wire cross-section in a plane perpendicular to the screw axis. The metal element 5 sits coaxially in the first element 4, and its dimensions are chosen so that it is close to the periphery the latter lies; deformable components, the metal elements 5 in an intermediate position within the deformable Elements 4 is, however, are intended to be encompassed by the invention. Under these conditions, the metal element becomes 5 a kind of cover for the element 4, suitable for absorbing its radial deformations.

Preferably, the metal element 5 can be two with each other the same springs 6 include (Figure 4) with the same pitch diameter, which in a center line plane perpendicular to The axis of the deformable first element 4 rest; the direction of winding of the wire spiral of these springs is opposite. in the In another case, the metal element can comprise two coaxial helical springs 7,8 (Fig. 5) with different pitch diameters, so that one spring is completely separated from the other is enclosed.

In another embodiment (Fig. 6) each spring 7,8 is in two parts in the center line plane perpendicular to the axis of the Element 4 split; the direction of winding of the spring coil in one half of the element is opposite to that of the Feathers in the other half. The cross section of the wire of each spring, which in the embodiments described so far as was assumed to be round, may have any shape, for example in the case of the embodiment of FIG. 7, which is structurally the 5, the cross section of the spring 7, 8 is a planar figure with straight sides; in particular, a pair of planes will fit 9 of the spring 7 to the pair of surface Io of the spring 8.

In addition, the deformable first element 4 can be provided with a hole 11 in its axis (FIG. 8) for receiving a straight column, if necessary, on which a multiple

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number of deformable components can be arranged.

The mode of action of a deformable component, such as it emerges from the constructions described is the following:

It is assumed that such a component is part of a buffer, in accordance with the sketch according to FIG. 1 and that the buffer must take up an axial load F, which is caused, for example, by a dynamic effect (impact) is caused. Axial forces are therefore between the surfaces of the movable plate 2 and of the fixed plate 3, as well as between the abutting surfaces of two successive ones Components 1. The deformable first element 4 of each component works under the action of such forces essentially under compression and is compressed in the axial direction. Simultaneously with this axial compression of the first element 4, there is also a radial bulging, since the deformable element is negligible Has volume compressibility.

During this axial bulging, the springs 6, 7, 8 counteract this deformation and thus create a Pressure on the deformable first element, which leads to increased strength of the component. Would be the feathers absent, the deformable element would turn out to be the same under much lower external loads Bulge way; however, since these springs are provided, they increase the effect of radial interception Resilience and strength of the deformable elements.

As a result of the axial compression of the spring of a component, the latter has a known tendency to move radially bulge out, which increases the pitch diameter of each turn, and since the spring is integral with the deformable first element 4 is embedded, it is clear

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that during the axial compression of the component, the element itself essentially performs a screwing movement about its axis, which screwing movement is caused by the radial deformation of the spring. Such torsional deformation, which together with the axial compression on the deformable first element 4 is transferred * contributes to increasing the tensile strength of the element and thus to Strength of the component. The hydrostatic pressure caused by the metal element also has the tendency to To increase the modulus of elasticity of the deformable element (which is a well-known phenomenon) so that increased strength is also achieved for this reason.

The elastic torsional deformation of the component is different depending on whether the spring (or springs) has the same length as the deformable element 4 (embodiments according to FIGS. 2, 3, 5, 7) or a length equal to half the element length (embodiments according to FIGS. 4 and 6). In the former case, every cross-section becomes the deformable Element subjected to the same elementary torsion so that the end faces of the component have the tendency relative to twist each other by an angle equal to the sum of these elementary torsions. In the latter case, however lead the different winding senses of the spring spirals embedded in each component half to opposite torsions of each half, so that the result is a net torsion angle1 zero remains between the end faces of the component and a maximum torsion angle between each end face and the central cross-section of the component where the springs meet.

The deformable component according to the invention has a very high resilience and strength. In addition, the ability is also the elastic one stored by the component To give off energy (hysteresis) to the environment, also very much high. Finally, the elastic characteristic (tensile stress-strain diagram) of the component is essentially linear. Finally, you can enjoy all of the beneficial properties mentioned above with a simple, very compact and space-saving

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Achieve construction.

These properties of the component can be proven experimentally; are the results of some such tests reproduced in the diagrams of FIG. 9, which show the static hysteresis loops measured on deformable ones Elements and components of different types. Each loop is defined by a closed curve whose area is known to be proportional to the energy that is given off while running through the loop, and both sides of which correspond to the tensile stress-strain curve during the application of the load or the withdrawal of the effect on the element or the component.

The hysteresis curve a relates to tests carried out on a deformable cylindrical element such as the element 4 in Figs. 2 and 3, but without a built-in spring and with the same dimensions and a diameter-to-height ratio equal to 1.

The strength and load-bearing capacity increases considerably according to the teaching of the invention (diagram b,) if the same deformable element as in the previous test is used, but with a built-in spring. Man recognizes that the elastic properties become substantially linear. The converted energy (area within the curve) is also high and thus the damping capacity is also high. The considerable increase in the values at the curve in question that can be obtained with the object of the invention depends on numerous factors.

The strength and load-bearing capacity are not only increased because the values of these parameters with respect to the Deformable element and the spring are added to each other, but also because the deformable element works very effectively in handling the load because of the incorporation of the spring into the element. If

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namely a spring is built into the deformable element according to the teaching of the invention, the radial Deformation of the element is definitely prevented, and at the same time it is forced to work under torsion. On the other hand, the deformation of the spring is greatly influenced by the presence of the material of the deformable Element by which the spring is surrounded, as it can only be deformed if this material itself deforms. This mutual influence between the spring and the deformable element is the cause of the Enlargement of the characteristic values mentioned above.

The energy converted when going through each hysteresis loop is high because the deformable element is not only axially deformed, but also subjected to torsional deformation.

The essentially linear elastic characteristic makes these components particularly suitable for dampers in automatic Coupling devices for railway wagons.

It is obvious that the component according to the invention can be used in many cases where forces are to be absorbed. The respective application forms of the component can be from deviate from the specified shapes and dimensions without departing from the basic concept of the invention.

Patent claims:

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Claims (7)

PATENT CLAIMS 1J Deformable component for a buffer, in particular ür an automatic coupling device for railroad cars, characterized in that the component consists of a first element made of deformable material and of at least one metal element, for example a helical one coiled wire, which is completely embedded in the material of the deformable first element in such a way that the metal element essentially prevents the radial deformation of the first element when the component is subjected to a compression load in the direction of the axis of the first element, and that under the action of this load the metal element deforms under pressure exerted on the deformable first element, causing it to become torsionally deformed is subjected substantially with respect to the axis of the first element. 2. Component according to claim 1, characterized in that the material of the first element is an elastomer. 3. Component according to claim 1, characterized in that the material of the first element is a plastic. 4. Component according to one of the preceding claims, characterized in that there are two metal elements each in In the form of a helical spring, the pitch diameter of the helical lines of the two elements is substantially are equal, and the axial length of each metal element is substantially equal to half the axial length of the first Element is made of deformable material. 5. Component according to one of claims 1-4, characterized in that that it comprises two metal elements, each in the form of a helical spring, the pitch diameter being the Helical lines of the elements is different, and one is arranged within the other. 6. Component according to one of the preceding claims, there- 609852/0322 -lO- characterized by / that the cross section of the helical spring-shaped Metal element has a circular shape perpendicular to its axis. 7. Component according to one of claims 1-5, characterized in that that the cross section of the metal element perpendicular to the axis of the same delimited one of straight sides Has shape. 609852/0322