DE10033211A1 - Elastomer spring and locking device - Google Patents

Abstract

Elastomer spring (100, 400, 500, 600), which has an elongated spring body, with a plurality of spring segments (150, 450, 550, 650), which is bent out and deflectable transversely to the longitudinal direction of the elastomer spring (100, 400, 500 600) are. The spring segments are lined up in a ring-like and linear manner in one piece. In the case of a ring-like design, the elastomer spring has spring action in the axial and / or in the radial direction.

Description

The invention relates to an elastomer spring with a elongated spring body.

Elastomer springs are commonly used to record, store and Delivering mechanical energy used. They serve for Mitigation of shocks and vibrating loads, for generation of forces and moments as well as for converting mechanical ones Energy in thermal energy and to dampen shocks and Vibrations. Elastomer springs are commonly found in the essential application as vibration damper.

Elastomer material is deformable and not compressible. For example, O-rings made of elastomer material are used concentric connectors used as retaining springs. Here, for example, on a cylindrical body such as a shaft, a hollow body, like for example, a sleeve arranged. An O-ring is in a groove of the shaft arranged. The o-ring and the groove are dimensioned such that the inner radius of the O-ring is slightly larger than the inner radius of the groove. Moreover the outer radius of the O-ring is slightly larger than that Inner radius of the sleeve to be positioned.

Due to the slight oversize of the inner radius of the O-ring can move within the groove and therefore when push the sleeve onto the shaft by resilience dodge. However, such an O-ring is not used here deformed concentrically so that the sleeve is not concentric can be arranged on the shaft.

If the sleeve is also against a stop on the Shaft are pressed, the conventional O- Ring a problem in that when sliding the sleeve on  the shaft of the o-ring is twisted or twisted, causing a preload of the O-ring against the rotation and thus a force arises which is contrary to the deferment direction the sleeve acts on the shaft. This force presses the sleeve away from the stop on the shaft, so that an exact Do not position the sleeve on the stop on the shaft is possible.

It is an object of the invention to provide an elastomer spring create the precision and functionality conventional elastomer springs improved.

According to the invention, an elastomer spring with a elongated spring body created, which one A plurality of in one piece in the longitudinal direction of the elastomer spring has lined up spring segments, each of which are bent out transversely to the longitudinal direction, the Spring segments can be deflected transversely to the longitudinal direction.

The spring segments can be wavy or trapezoidal be bent out. Here the spring segments can also be bent out in a rectangular shape.

According to a preferred embodiment according to the invention the spring segments of the elastomer spring are ring-like strung together. Here, the spring segments in Axial direction and / or radial direction of the elastomer spring be bent out and deflectable.

The ring-like embodiments according to the invention can be open or closed. The open ring-like trained embodiment offers the advantage that in addition to the spring action in the direction transverse to the Longitudinal direction of the spring body also a spring action in Longitudinal direction can exist. The closed ring-like trained embodiment offers compared to the open ring-shaped embodiment an even higher  Precision, for example with regard to the inner radius of a groove or the inner radius of a sleeve with which the ring-like trained embodiment can be used.

According to another preferred embodiment according to the Invention, the spring segments are lined up linearly.

The elastomer spring according to the invention can be circular or rectangular cross section or other suitable Have cross-sectional shape. Furthermore, the cross section can the length of the elastomer spring is different his.

According to the invention, a latching device with a Elastomer spring according to the preferred embodiments, one cylindrical inner body and a cylindrical hollow body created. The inner body is on its outer surface provided a groove and the hollow body has on it Inside a notch. The elastomer spring is in the Groove arranged and snaps onto the cylindrical Insert the hollow body into the locking groove. The Locking groove is particularly flat. In particular their depth is less than half the height of the spring Elastomer spring.

The invention is described with reference to the drawing preferred embodiments explained in more detail. In the Show drawing:

Fig. 1 is a sectional view of an arranged between a shaft and a sleeve elastomeric spring according to a preferred embodiment of the invention,

Fig. 2 is a longitudinal section through the arrangement according to Fig. 1,

Fig. 3 disposed between a shaft and a sleeve elastomeric spring according to another preferred embodiment of the invention,

Fig. 4 is a plan view of another preferred embodiment of the invention;

Fig. 5 is a sectional view taken along line IV-IV from Fig. 4,

Fig. 6 is an elastomeric spring according to another preferred embodiment of the invention in ausgefedertem state,

Fig. 7 is a sectional view taken along line VI-VI of Fig. 6,

Fig. 8 shows the elastomer spring according to the preferred embodiment of Fig. 6 in the compressed state, and

FIG. 9 is a sectional view along the line VIII-VIII from FIG. 8.

As seen from Fig. 1, an elastomeric spring is arranged according to a first preferred embodiment of the invention between a shaft 200 in a groove 210 of the shaft 200 and a hollow body, such as a sleeve 300.. The elastomer spring 100 has an elongated spring body with a plurality of spring segments 150 . The spring segments are each bent out transversely to the longitudinal direction of the elastomer spring 100 , ie in this embodiment in the radial direction of the ring-like elastomer spring 100 . The bent-out spring segments 150 create a wave-shaped course of the ring-like elastomer spring 100 . Each spring segment 150 has sections or bulges 110 which are bent radially outwards and sections or bulges 130 which are bent radially inwards. This results in each case at the bottom or at the top of elastomer spring 100 indentations 120 and 140th The bulges 110 and 130 of the elastomer spring 100 serve as contact points on the inside and outside of the elastomer spring. Due to the plurality of bulges 130 provided on the inside, the elastomer spring 100 can be arranged without play, for example in a groove 210 formed in the shaft 200 . The wave-shaped course of the ring-like elastomer spring 100 achieves a spring effect in the radial direction. As a result, it is possible, for example, to mount the elastomer spring 100 in the groove 210 without overstretching the elastomer material, since, due to the undulating course, the waves can be stretched and thus the circumference of the elastomer spring 100 increased .

The indentations 120 and 140 of the elastomer spring 100 can also be used as fat deposits, which improves the durability of the elastomer spring 100 and the parts connected by it in a resilient manner.

When the sleeve 300 is pushed onto the shaft 200 via the elastomer spring 100, the spring segments 150 of the elastomer spring 100 essentially spring in each other and transversely to the longitudinal direction, which is the circumferential direction in the case of the open or closed ring-shaped elastomer spring according to the invention, of the elastomer spring 100 ,

The plurality of spring segments 150 , which each provide a contact point 110 on the outside of the elastomer spring 100 and a contact point 130 on the inside of the elastomer spring 100 , can provide a plurality of uniformly distributed contact points, by means of which the sleeve 300 is centered on the shaft 200 is possible.

Depending on the selection of the elastomer material and the Dimensioning the cross section and the The cross-sectional profile of the elastomer spring can be Spring hardness of the elastomer spring according to the invention predetermine.

As long as the size of the spring stroke corresponds at most to the size of the indentation 120 of the elastomer spring 100 , compression of the elastomer spring 100 is possible essentially without squeezing the elastomer spring. In this area, the spring force of the elastomer spring can easily be determined by taking into account the material properties of the elastomer material and the dimensions of the elastomer spring.

From Fig. 2 is a sectional view of a locking device can be seen, which uses the elastomer spring according to the first be preferred embodiment of the invention. A cylindrical inner body, for example a shaft 200 , is provided with a groove 210 and with a stop 220 . A hollow body, such as a sleeve 300 , has a locking groove 310 . Furthermore, the sleeve 300 is provided at its end facing the stop 220 of the shaft 200 with an inward slope 320 . The elastomer spring 100 according to the first preferred embodiment is arranged in the groove 210 of the shaft 200 . When attaching the sleeve 300 to the shaft 200, the elastomer spring is springs 100 by the voltage applied to the bulges 110 of the elastomeric spring 100 bevel 320 in each spring segment 150 generally in itself.

If the sleeve 300 is pushed further onto the shaft 200, so cushions the elastomer spring 100 is fully in the groove, until the sleeve 300 pushed forward, that the spring can engage in the latching groove 310 of the sleeve 300 100th If the sleeve 300 is to be pressed against the stop 220 of the shaft 200 with a predetermined force, the locking groove 310 can be arranged at a somewhat greater distance from the end region of the sleeve 300 facing the stop 220 than the distance of the groove 210 from the stop 220 is. Here, the elastomer spring 100 can only partially spring into the locking groove 310 , as a result of which a force acting in the axial direction of the shaft 200 presses the sleeve 300 against the stop 220 .

The height of the indentation 120 is preferably at least equal to the spring height of the elastomer spring 100 .

From Fig. 3 is a sectional view of a latching device can be seen, in which the elastomeric spring 100 can be used according to the first preferred embodiment. A shaft 201 is provided with a groove or a groove 211 . A sleeve 301 is provided with a groove 311 on its inner surface. An elastomer spring 100 according to the first preferred embodiment is arranged in the groove 311 . The shaft 201 is provided with a bevel 221 . When the shaft 201 is inserted into the sleeve 301 , the elastomer spring 100 is pressed into the groove 311 by means of the bevel 221 using the spring properties of the elastomer material in the groove 311 and pre-tensioned in the radial direction towards the shaft 201 . If the groove 211 reaches a sufficient overlap with the groove 311 , the elastomer spring 100 springs into the groove 211 , whereby the shaft 201 engages in the sleeve 301 .

With this arrangement, the inner indentations 120 of the elastomer spring 100 can be used as fat deposits. If they are provided with grease, these are able to provide appropriate lubrication of the shaft 201 as well as the elastomer spring 100 and the sleeve 301 during a plurality of insertion processes.

From Fig. 4 is an elastomer spring 400 is seen according to a second preferred embodiment of the invention. The bulges of the elastomer spring 400 according to the second preferred embodiment are formed transversely to the longitudinal direction of the elastomer spring 400 and are more pronounced than according to the first preferred embodiment.

The bulges 410 to the outside and the bulges 430 to the inside determine a zigzag shape in the longitudinal direction of the elastomer spring 400 . Corresponding indentations 420 remain corresponding to the indentations 430 on the inside of the elastomer spring 400 . Corresponding indentations 440 remain corresponding to the indentations 410 on the outside of the elastomer spring 100 . The outer regions of the bulges 410 and 430 are rounded off in the elastomer spring 400 according to the second preferred embodiment. They can serve as contact points, for example, for centering components that are to be arranged concentrically.

FIG. 5 shows a sectional view along the line IV-IV from FIG. 4. The elastomer spring 400 according to the second preferred embodiment has a rectangular cross section in its longitudinal direction. In comparison to the first preferred embodiment, this leads to an increased locking action of the elastomer spring 400 in a correspondingly designed groove, so that the elastomer spring 400 can also be used for one-way connections. These are used, for example, for sealing, wherein the connection can only be released by destroying the elastomer spring 400 , which is used here as a seal.

From FIGS. 6 to 9, a third preferred embodiment according to the invention can be seen. Fig. 6 shows a section through an elastomeric spring 600 according to the third preferred embodiment of the invention. FIGS. 6 and 8 show the elastomeric spring according to the third preferred embodiment as development of a ring-like elastomer spring or as an elongated elastomeric spring.

An elastomer spring 600 is arranged between an upper elongate body as upper part 700 and a lower elongate body as lower part 710 . The upper part 700 has a groove 701 and the lower part 710 has a groove 711 , which is preferably designed to correspond to the groove in the upper part 700 . As can be seen from FIGS. 6 to 9, the elastomer spring 600 is arranged in the grooves 701 and 711 between the upper part 700 and the lower part 710 .

The elastomer spring 600 according to the third preferred embodiment is designed in particular in a straight line and has a plurality of spring segments 650 . Each spring segment has a bulge 610 and a bulge 630 . The spring segments 650 of the elastomer spring 600 are each bent out transversely to the longitudinal direction of the elastomer spring 600 . Each spring segment 650 is essentially deflectable in itself. A contact point is provided at each bulge 610 or 630 , by means of which the elastomer spring 600 can rest in the groove 701 or 711 in the upper part 700 or in the lower part 710 .

FIG. 7 shows a section along the line VI-VI in FIG. 6. FIG. 7 shows how the elastomer spring 600 is arranged between the upper part 700 and the lower part 710 . The plurality of spring segments 650 provide a plurality of contact points on the bulges 610 and 630 of the elastomer spring 600 , as a result of which the upper part 700 and the lower part 710 are supported several times. In particular, in thin and flexible formed upper and lower parts 700 and 710 is such a multi-support advantageous in that the reactions of the elastomeric spring 600 on the upper part 700 and lower part 710 are small, and so deformation of the upper part 700 and lower part 710 avoided become.

The elastomeric spring 600 according to the third preferred embodiment in eingefedertem state of FIGS. 8 and 9 can be seen. Due to the wave-shaped or zigzag-shaped course in the longitudinal direction of the elastomer spring 600 , each spring segment 650 can essentially deform itself, so that upsets or displacements of the contact points of the elastomer spring 600 on the upper part 700 and the lower part 710 can be avoided. This enables a defined, uniform deflection with uniform force distribution on the upper part 700 and on the lower part 710 .

A fourth preferred embodiment according to the invention can be seen from FIGS. 10 and 11. FIG. 10 shows a radial top view and FIG. 11 shows an axial top view of the fourth preferred embodiment of the invention. In this embodiment, the elastomer spring 500 is ring-shaped. In the axial direction, it has a corrugated or serrated course with a plurality of bulges 510 and 530 . Compared to the first preferred embodiment, which creates a spring action in the radial direction of the ring-like elastomer spring 100 , the ring-like elastomer spring 500 according to the fourth preferred embodiment has a spring action in the axial direction.

Contact points of the elastomer spring 500 are provided in the region of the vertices of the bulges 510 and 530 , with which the elastomer spring can rest, for example, between two circular disks arranged on a shaft and support them axially resiliently against one another. However, the elastomer spring according to the fourth preferred embodiment can also be used for resiliently supporting a sleeve with respect to a stop formed on a shaft or for other axial spring processes. In particular, very low spring forces can be set very precisely by the methods described in the other embodiments. Furthermore, the elastomer spring 500 offers a lower overall height with the same spring height compared to steel springs.

The elastomer spring 500 has a plurality of spring segments 550 , each with a bulge 510 and a bulge 530 in the axial direction. Each spring segment is essentially deformed when the elastomer spring 500 is compressed, so that interactions with the other spring segments are minimized.

The elastomer material of the elastomer spring 500 can have a rectangular or circular cross section or another suitably designed cross section. The course of the elastomer spring 500 in the longitudinal direction, ie circumferential direction, can be rectangular, undulating or sinusoidal.

Claims (9)

1. elastomer spring with an elongated spring body which has a plurality of spring segments ( 150 , 450 , 550 , 650 ) which are arranged in one piece in the longitudinal direction of the elastomer spring and which are each bent out transversely to the longitudinal direction, the spring segments ( 150 , 450 , 550 , 650 ) can be deflected transversely to the longitudinal direction. 2. Elastomer spring according to claim 1, wherein the spring segments ( 150 , 450 , 550 , 650 ) are bent out in a wave shape. 3. Elastomer spring according to claim 1, wherein the spring segments ( 150 , 450 , 550 , 650 ) are bent out in a trapezoidal shape. 4. Elastomer spring according to one of claims 1 to 3, wherein the spring segments ( 150 , 450 , 550 , 650 ) are strung together like a ring. 5. Elastomer spring according to claim 4, wherein the spring segments ( 150 , 450 , 550 , 650 ) in the axial direction and / or radial direction of the elastomer spring ( 100 , 400 , 500 , 600 ) are bent out and deflectable. 6. Elastomer spring according to one of claims 1 to 3, wherein the spring segments ( 650 ) are lined up linearly. 7. elastomer spring according to one of the preceding claims, the elastomeric material being circular in cross section having. 8. elastomer spring according to one of claims 1 to 3, wherein the Elastomeric material has a rectangular cross section. 9. locking device with an elastomer spring ( 100 , 400 , 500 , 600 ) according to any one of claims 4, 5, 7 or 8, a cylindrical inner body ( 200 ) and a cylindrical hollow body ( 300 ), wherein the inner body ( 200 ) on its outer surface is provided with a groove ( 210 ) and the hollow body ( 300 ) has a latching groove ( 310 ) on its inside, the elastomer spring ( 100 , 400 , 500 , 600 ) being arranged in the groove and on the cylindrical inner body ( 200 ) pushed-on hollow body ( 300 ) can be snapped into the locking groove ( 310 ).