DE2129872A1 - Resilient tension element - Google Patents

Description

Resilient tension element The invention relates to a resilient one Pulling element with a stopper which limits the specified spring travel and which the Partial force transmits, which is the difference between the transmitted force and the spring force results, with several springs connected together and each A stopper is assigned to the spring, according to DT-OS 2 005 557.

These tension elements, in the embodiment with several compression springs, have an unfavorable ratio of overall height to spring travel, what their possible applications in some cases restricts.

The invention is based on the object of a resilient tension element to create the type mentioned, in which there is a more favorable ratio of overall height zü spring deflection results.

This object is achieved according to the invention in that for An intermediate stopper transmits a force acting on the upper end of a compression spring is provided, which serves as a stopper for the associated spring and at the same time the lower end of which connects to the upper end of the closest compression spring, while the lower end of the last compression spring is on the front of the housing supports. Preferably all individual parts are in one housing so arranged in mirror image to each other that on each end face of the housing a pull rod with the corresponding telescopic parts can be pulled out. To a lesser extent To achieve overall height, the compression springs can also be designed as truncated cone springs be.

Below are some preferred embodiments of the invention described in more detail and shown schematically in FIGS. 1 to 8.

Fig. 1 shows a pulling element with one-sided telescopic extension and three normal compression springs 1, 2 and 3 with different characteristics, advantageously spring 1 is weakest and spring 3 is strongest. The telescopic parts 4.5 are intermediate stoppers, because they each have a stopper 7 for the associated spring1 or 2 and at the same time connect their lower end to the upper end of the nearest one Compression spring; the minimum stopper height may exceed a limit value that applies to the individual Springs can be different, do not fall below. On the housing 6 can actual stopper 7 can be fixedly arranged. Serves as a counter bearing for the spring 3 the front of the housing 6. To avoid rattling in the unloaded state, 6 rubber rings 8 are glued into the housing. The tension element is applied e.g. via drawbar eyes 9, one on the housing and the other on the inside Drawbar 10 is attached .-- The left half of the figure shows the unloaded, the right half the tensioned element.

In Fig. 2, the left half of the figure is also in the unloaded and the right one drawn in the loaded state. It is a double telescopic one here Embodiment shown, which in principle has a similar structure like the embodiment in FIG. 1. The intermediate stoppers are provided by the parts 11 and 12 to which the stoppers 15 are attached.

Normal compression springs 16, 17 and 18 are used as springs. For actuation drawbar eyes 19 are again present on the inner drawbar 20. As a counter bearing Here, too, the support of the springs 18 on the end faces of the housing 13 is used.

In Fig. 3 an element with two springs with a round cross-section is shown, the same being designed as frustoconical springs 21. By choosing one The frustoconical spring does not apply to normal cylindrical compression springs Construction height restriction due to the butting of the individual turns. One can here the spring practically does not compress to the wire size, but it does results from an appropriate choice of the large and small winding diameter and the number of turns at maximum load a lower spring height in tensioned Position than a comparable compression spring with the same wire diameter and the same Number of turns. In this embodiment, an intermediate plate is used as an intermediate stopper 22 with guide tube 23.

The application takes place via the two eyelets 24, on the one hand are attached to the housing 25 and on the other hand to the pull rod 26. The burdened State is shown in dashed lines.

In Fig. 4 a variant of Fig. 3 is shown in which instead of of the frustoconical springs with a round cross-section frustoconical springs 27 with a rectangular Cross-section are used.

The rectangular cross-section over the whole of the spring can be used here Spring length are maintained or, as shown, to the smaller coil diameter decrease, which results in a different spring characteristic. As an intermediate stop 28 an intermediate plate with guide tube 29 serves again. The actuation takes place as beforehand by means of two eyelets 30 on the housing 31 or

on the pull rod 32. The tensioned state is shown in dashed lines. smoke here serves one end of the housing 31 as a support for the lower Spring 27.

Fig. 5 shows an embodiment with frustoconical springs 33,34 with Rectangular cross-section. The outer spring 34 is entrained via an intermediate stopper 35 with an approximately Z-shaped cross-section, on the inside of which the actual stopper 36 for the inner, advantageously weaker spring 33, is integrally formed. For the Spring 34 forms the outermost turn of the spring itself, the stopper. The loading takes place via the eyelets 37 on the one hand on the housing 38 and on the other hand on the pull rod 39 are attached, the end face of the housing as an abutment for the spring 34 serves. The right half of the figure shows the tensioned state.

In Fig. 6 is a tension element with three frustoconical springs 40, 41 and 42 shown. In this form, however, you cannot nest as closely as with Reach Fig. 5. Two rings with an approximately L-shaped cross-section serve as intermediate stoppers 43, each in connection with the inner spring coil, which in this case is the actual Represents stopper. Rubber buffers 44 are also glued in here as a noise damper. For actuation there are again eyelets 45 on the housing 46 or on the pull rod 47 are attached. The load case is shown in the right half of the figure.

Fig. 7 shows a combination of Figs. 5 and 6 showing a reduction in size of the outside diameter results. You can namely the inner intermediate stopper 48 with Form a Z-shaped cross-section, but must then expediently the following Intermediate stopper 49 give an L-shaped cross section. The inner spring 50 its inner turn is used, the outer one of the two following springs 51 and 52 Winding as actual Stopper. There are again eyelets for actuation 53 on the housing 54 or on the pull rod 55.

In Fig. 8 a pulling element that can be pulled out on both sides is shown, equipped with four frustoconical springs 56 and 57 with a rectangular cross-section and in the Principle of two tension elements according to FIG. 5 is built up. The lengths of the intermediate stoppers 58 and the tie rods 59 and the springs is designed so that in the contracted State shown in the left half of the figure, the parts are against each other, so that there is no rattling. On the tie rods 59 there are eyelets 60 for actuation available. The end faces of the housing 61 again serve as a counter bearing for the outer springs 57. The extended state can be seen in the right half of the drawing.

Expectations

Claims (3)

Claims 1. Resilient tension element with one, the specified Stopper, which limits the spring travel and transfers the partial force resulting from the difference between the force to be transmitted and the spring force results, with several Springs are interconnected and a stopper is assigned to each spring, according to DT-OS 2 005 557, characterized in that to transfer a to the upper Force acting at the end of a compression spring (1,2; 16,17; 21; 27; 33; 40,41; 50,51; 56) Intermediate stopper (4, s; 11,12; 22; 28; 3s; 43; 48,49; 58) is provided, which as a stopper serves for the associated spring and at the same time its lower end with the upper end the closest compression spring (2,3; 17,18; 21; 27; 34; 41,42; 51, 52; 57) connects, while the lower end of the last compression spring (3,18,21, 27,34,42,52,57) is attached the end face of the housing (6,13,25,31, 38,46,54,61) is supported. 2. tension element according to claim 1, characterized in that in one Housing (13,61) all individual parts arranged in such a way that they are mirror images of one another are that on each end of the housing a pull rod (20,59) with the corresponding Telescopic parts is extendable. 3. tension element according to claim 1, characterized in that the compression springs (2127; 33.34; 40.41.42; 50.51.52; 56.57) are frustoconical springs.