DE2115314B2 - MULTIPLE WIRE SPRINGS COATED WITH ELASTOMERS - Google Patents

Description

Since this plastic deformation of the spring coils is the greater, the greater the mass of the spring and because when one turns into a helical compression spring unwound torsion bar the material utilization is very poor - in the middle Zero, highest at the edges - you have torsion bars and helical compression springs wound from them Constructed from several wires, in which the material is not subject to twisting if possible, but is subject to tension and compression (German patent specification 767478, claim 5, and the magazine KEM Verlag Konradin-Kohlhammer, Stuttgart, July 1968, 8.10). In Fig. 1 of the drawing, a simple multi-wire compression spring is twisted from three Wires shown; in Fig. 6 a wrapped multi wire spring according to German patent specification 767 478.

With these multi-wire springs, the stranding resp.

Wrapping chosen so that it is opposite to the direction of the winding of the helical spring runs; in the case of a compression spring wound on the right, this is the stranding or wrapping chosen on the left. In this way it is achieved that the individual wires move during the spring work Put them together more tightly, as the strand from which the helical compression spring is wound is, is subject to torsion In practice, high accelerations have proven better than single-wire springs, not only because they stress the spring material in terms of tension and pressure and thereby the spring mass reduce, but also because the resolution of the wire cross-section of a single-wire spring in several small wire cross-sections of a multi-wire spring higher stresses which enables smaller wire cross-sections; because small wire cross-sections leave quenched and tempered to a significantly higher strength than larger ones (DIN 17223). So brings even the replacement of a single-wire compression spring with the most primitive type of multi-wire compression spring, due to the compression spring twisted from three wires or stranded from several wires, a significant improvement in service life in the event of shock loads high acceleration.

Investigations on multi-wire springs have shown that both with wrapped as well as with stranded multi-wire springs the increased service life to a considerable extent also on the attenuation of the impacts that arise in the event of several impacts in rapid succession Shock and reflection waves is due. This desired vibration damping The multi-wire spring is created by the friction between the individual wires during the spring work. This friction and thus vibration damping is all the smaller, the better the individual wires of the multi-wire spring are lubricated. A lubrication of the but suddenly accelerated helical compression springs is necessary because such springs are usually very long in relation to the coil diameter, so they are not are kink-proof and require a mandrel or sleeve guide. A spring that comes with The mandrel or sleeve guide works, but has to be lubricated because of the guide problems will.

Attempts have therefore been made to dampen vibrations and thus extend the service life to be achieved by covering the multi-wire spring with a plastic, which is elastically deformable, abrasion-resistant, oil- and heat-resistant and a small one Has coefficient of friction. Several elastomers can be used as such plastics at.

Investigations on multi-wire springs coated with elastomers have shown, however, that a noticeable increase in service life by such Plastic coating cannot be achieved.

Where the individual wires of the multi-wire springs touch, i.e. where the elastomer coating and thus the damping is the most promising, can the elastomer does not penetrate. The individual wires of the multi-wire spring before assembling However, it is not necessary to pull the strand over to the strand or the strand before winding it to the spring possible, since the elastomers are not created by the stranding of the individual wires strong pressures required for the heat treatment of the finished coiled springs Temperatures have grown.

The invention is based on the object of coating the individual wires of multi-torsion springs.

The present invention achieves the desired goal through a particular one Method in a simple manner in that the coating is in a state of Multi-wire springs take place in which the individual wires stand out from one another as a result Applying a force that is directed opposite to the operating force.

As stated above, multi-wire springs must be wound so that the individual wires of the stranded wire through the spring work of the spring, which leads to a twist the strand leads, put them closer together; is for example a multi-wire compression spring but pulled apart, the strand is twisted in the opposite state, and the individual wires move away from each other and enable in this state the penetration of the elastomer between the individual wires. With multi-wire tension springs The same applies if the multi-wire tension spring is wound with the turns spacing and is compressed for elastomer coating.

Multi-wire compression springs coated with suitable elastomers according to the invention have a significantly longer service life when subjected to shock loads with high acceleration as uncoated or uncoated compression springs. Your setting curve runs flatter, d. that is, they keep what a machine needs to function Working capacity much longer than multi-wire springs, which are in the untensioned state were coated with elastomer because that is located between the individual wires Elastomer significantly dampens both shock waves and reflection waves.

It is also possible, according to the invention, to expand the multi-wire compression springs To be coated with tougher, thicker elastomers.

You can also coat several times with more fluid elastomers, which results in a further improvement of the multi-wire compression springs subject to shock loads results.

Multi-wire compression springs are mostly used, i. i.e., they will thermally tempered in a state that is longer than their untensioned finished length. They are then shortened in the remunerated state by knocking them together, creating a Part of the initially steeply sloping setting curve is cut off. Such superiors In practice, springs stand better than springs, which are equal to the unstressed length their finished size.

Tests have shown that certain multi-wire compression springs, which were coated with elastomers before being applied, also a better one Show behavior when exposed to impact as if they were coated after being placed in front will.

This is also explained by the fact that the individual wires of the stranded wire do not lie as close to each other before moving forward as they were after moving forward, like this that the elastomer in this way also a better penetration between the Single wires of the braid is made possible.

In F i g.2 and 3, the torsion spring body, i.e. H.

the strand of a stranded multi-wire compression spring, (Fig. 1) in the unstressed State of the compression spring shown. In Fig. 7 the stranded wire is the multi-wire compression spring (Fig. 6) in the untensioned stand shown. In this condition of the compression springs, the individual wires of the braid lie close to one another. In Fig. 4, 5 and 8 is the strand of the stranded or wrapped multi-wire compression spring in the pulled apart State of the compression spring shown; in this The condition of the compression springs has changed The wire is twisted so that the individual wires of the wire move away from each other to have; the strand has opened so that it allows the elastomer to penetrate between allows their individual wires.

Claims (2)

Claims: 1. Method for coating coiled multi-wire springs with elastomers, d a d u r c Ii characterized that the coating is in a state the multi-wire springs takes place, in which the individual wires stand out from each other as a result Applying a force that is directed opposite to the operating force. 2. Process for coating multi-wire springs with elastomers according to claim 1, characterized in that the coating before the pre-setting the multi-wire springs takes place. The invention relates to a method for coating winding Multi-wire springs with elastomers. Springs subjected to impact are mainly used as coiled compression springs built; They must have a certain amount of work capacity and this over as much as possible keep many load changes because they are used as mechanical accumulators, the function of the device depends on their storage capacity: that of the spring stroke Work must be started while relaxing for the device to function properly be returned. Such springs must neither tire nor break, so the functionality of the device is maintained. Cylindrical helical compression springs subject to impact, the great accelerations are subjected to different and significantly higher stresses than Helical compression springs that are static or with an approximately sinusoidal time path curve are claimed. ("The dynamic loading of cylindrical coil springs", VDI-Z 99 (1957), no.12, p.527ff.) It has been proven that an acceleration of 1 g generates an increase in the material stress of approximately T = 40kp / mm2.5. ("The shock-loaded coil spring", KEM Verlag Konradin-Kohlhammer magazine, Stuttgart, December 1967, p. 12.) For these reasons it is understandable that it useful cylindrical helical compression springs, the jerky high accelerations endure, in the known construction, in which the spring is made from a wire is not there; because there are no known spring materials that can withstand torsional stresses withstand greater than approx. T = 140 kp / mm2. Even if helical compression springs are designed in such a way that the Torsional stresses on the spring wire are kept so small that they are in the The fatigue strength diagram of the spring wire are, these springs will not be stable, but after just a few impacts they settle considerably more than sinusoidally Stressed compression springs do with higher wire loads. That's because the mass and thus the inertia of such springs, the greater the smaller the spring designer determines the torsional stress for the spring work by selection thicker wire. In the event of a sudden load on one end of the spring, this is because with a high Accelerate the slope of the first turns immediately until they hit each other of turns is reduced, while the next turns facing away from the direction of impact still in the idle state with the winding spacing corresponding to this idle state until the shock wave picks them up. In this way the shock wave passes through the entire helical compression spring and beats every turn due to the inertia against the next one. The force with which the coils of a helical compression spring at large Accelerations hit each other still increase when several quickly successive ones Shocks stress the spring. Then there are no simple shock waves, but from the fixed spring end additional reflections of shock waves that run in opposite directions are and also lead to superimpositions, whereby the spring coils with an even hit each other with greater force than corresponds to the impact acceleration, and next to it also carry out more load changes than corresponds to the number of impacts. The through the Reflection caused superimpositions of the shock waves can reduce the winding distance Let individual turns vibrate larger than the untensioned length of the shock-loaded spring corresponds, so that the Hulis tension of the spring wire despite Preload of the spring not only from the positive maximum value IBt (that of the block length corresponds to), up to rl or z ,, but up to a negative value of the material stress can be enlarged. The clash of the spring coils due to their inertia Of course, this also happens when the spring designer adjusts the spring stroke so limited that - from a static point of view - the windings cannot touch. The force with which the spring coils hit each other is so great that even with very hard wire, the spring coils where they hit each other touch, hit flat. This plastic deformation is suffered by the windings of a but shock-loaded helical compression springs when they hit each other are in the state of highest torsional stress during spring work. Through this the torsional stress on the spring material is reduced, whereby the helical compression spring generated after just a few with great acceleration Load changes sets and loses work capacity.