DE29504421U1 - Ring resilient in the radial direction, especially for axially securing axles - Google Patents

Description

Ring _r resilient in radial direction, particularly for axial securing of axles

The invention relates to a radially resilient ring, in particular for axially securing axles, which has areas on the shell wall side and areas on the center side for entering the associated ring grooves of the components to be secured.

Such known locking elements, designed in the form of split rings, are accommodated in ring grooves of shafts and axles and are supported with their shell wall side area on the component through which the axle or shaft passes. In the case of rings designed as circlips, the ends of the circlip adjacent to the gap opening are thickened and have entry openings there for circlip pliers.

The invention is based on the object of designing a ring of the type in question in a manner that is simple to manufacture so that increased axial forces can be absorbed compared to known designs.

This task is solved by a circumferential wave-shaped course such that the outward-facing wave crests form one area and the inward-facing wave crests form the other area.

As a result of such a design, a springy ring of this type with increased utility value is created. In comparison to retaining rings of the same dimension, the ring according to the invention is able to absorb significantly higher axial forces. Due to the wave-shaped course, the support surface on the axle and on the component surrounding it increases. The closer the outward and

21 592 VGN: 251712 Dr.R./S/G 13.03.1995

The closer the inward-facing wave crests move to one another, the larger the available support surface becomes. Spring steel is suitable as a material for the spring ring, which is hardened and tempered after shaping. The surface can be phosphated and oiled. For example, a dimension can be selected _such that the inner diameter of the ring is 9 mm and the outer diameter is 11 mm. The wave crests pointing in opposite directions then take up a dimension of 2 mm. Furthermore, adjacent wave crests can be arranged at an angle of 30° to one another.

An advantageous further development is characterized by handling sections in a wave structure that protrude radially from the ends of the circumferential strip. During production, one can start from an endlessly corrugated material and create the handling sections after cutting to length by simply bending it, so that each handling section then consists of a wave crest, which wave crests are directed in opposite directions to one another. This creates an opening into which, for example, a circlip pliers can advantageously engage in order to spread the ring open. This means that no additional holes need to be created by drilling or punching. Existing wave crests at the end of the cut strip are used to form the handling sections.

Another advantageous feature is to provide a bend from a leaf spring material strip. With an inner diameter of 9 mm of the ring, a width of approx. 2.5 mm is recommended. This special design also has the advantage of a certain tolerance compensation, since a slight evasive movement

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This is made possible by the circumferential wave-shaped shape of the ring.

An embodiment of the invention is explained below with reference to Figs. 1 to 4. It shows

Fig. 1 shows an enlarged perspective view of a ring according to the invention,

Fig. 2 the ring in the operating position for restraining an axle relative to a component through which it passes,

Fig. 3 the section along the line III-III in Fig. 2 and

Fig. 4 a side view of the ring.

The number 1 designates a ring that is springy in the radial direction and has an open gap. This consists of a leaf spring material strip that has a wave-like course in the circumferential direction. The outward-facing wave crests 2 represent the area of the ring that is on the shell wall side, while the inward-facing wave crests 3 dip into an annular groove 4 of an axis 5 that is to be secured in the axial direction. The ends E, i.e. the wave crests 3 there, continue in radially protruding handling sections H in a wave structure. With regard to these handling sections H, these are wave crests with oppositely directed peaks, forming an insertion opening 6 for a circlip pliers.

To form ring 1, an endless corrugated leaf spring material strip is used. After cutting

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After cutting a leaf spring section of the appropriate length, it is bent into the final shape described above. Since no separate holes need to be made for the tool insertion opening 6, the ring can be produced in a cost-effective manner.

In the example design, the ring has an inner diameter d of 9 mm and an outer diameter D of 11 mm with a width b of the leaf spring material strip of 2 _r 5 mm. The thickness x of the leaf spring strip is approximately 0.3 mm for this dimension. The distance between adjacent wave crests corresponds to the angle alpha of 30°. This applies to both the outer and inner wave crests 2, 3.

The adjacent outer and inner wave crests 2, 3 are connected by short straight sections 7.

As can be seen from Fig. 1 and 3, the end-side, inward-lying wave crests 3 are more curved than the other wave crests. The wave crests there receive this stronger curvature when the radially protruding handling sections H are created.

The ring 1, which is resilient in the radial direction, is fitted into a hole 8 of a component 9 after the axle 5 has been inserted. The ring 1 is brought into the ring groove 4 projecting over the component 9 with the aid of a circlip pliers engaging in the insertion opening 6. The inwardly located wave crests 3 are supported on the bottom of the ring groove 4, while the outwardly directed wave crests 2 are supported on the end wall 10 of the component 9 flanking the ring groove 4. In this way, a large support surface is obtained between the component 9 and the axle 5, combined with the fact that high axial forces can be absorbed.

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are acceptable, which can be higher than with the known designs.

It would be possible for the component 9 to receive the ring 1 in a pocket that is open on one side _, so that the ring groove 4 is flanked on both sides by walls of the component 9. If the ring is in the pocket before assembly, the insertion-side end of the axle 5, for example, can cause the ring to widen, which engages in the ring groove 4 after the axle 5 has been fully inserted. However, it is also possible, if the pocket on the component side is designed accordingly, to use a tool that spreads the ring open to receive the ring, so that the axle can enter the inner opening of the ring without obstruction.

Instead of handling sections H projecting radially outwards, handling sections directed radially inwards could also be provided. A ring designed in this way could then also be assigned to inner ring grooves of components.

All disclosed features are essential to the invention. The disclosure content of the associated/attached priority documents (copy of the prior application) is hereby fully included in the disclosure of the application, also for the purpose of incorporating features of these documents into the claims of the present application.

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Claims (3)

• · AMSFROCHE 1. Ring resilient in the radial direction, in particular for axially securing axles, which has areas on the shell wall side and areas on the center side for entry into associated annular grooves of the components to be supported, characterized by a wave-shaped course in the circumferential direction such that the outward-facing wave crests (2) form one area and the inward-facing wave crests (3) form the other area. 2. Ring according to claim 1 or in particular according thereto, characterized by handling sections (H) in a wave structure projecting radially from the ends (E) of the circumferential profile. 3. Ring according to one or more of the preceding claims or in particular according thereto, characterized by the bend from a strip of leaf spring material. 21 592 VGN: 251712 Dr-R./S/G 13.03-1995