DE2450767A1 - Securing ring fixing components to shafts - has conical shape with cut away section which almost closes in fixed position - Google Patents

Abstract

The ring can also be used for fixing on axles or locating in apertures, and high axial force can be transmitted safely. The securing ring has a conical shape and a cut away section which almost closes when the ring is pressed in position. The ends of the ring have ribs or O ring sections so that the effective diameter of the ring can be altered. The ring fits in shaped recess with inclined edge in the shaft and a recess in the component being fixed to the shaft. The ring can be fitted on the shaft on one side, away from the applied force, or on both sides of the component being attached.

Description

Circlip for axially securing parts on shafts or axles and in bores.

There are open, flat locking rings are known that are in the groove of a Shaft, axis or bore can be used transversely to this and their protruding from the groove Part is used to absorb axial forces of the part to be secured. This, for a shaft or axle to the inside, for a hole to the outside resilient circlips can be due to a hard suspension for introduction into the grooves only a little bend up or in. The groove depths are limited, and thus they are perpendicular to the Shaft, axis and borehole standing contact surfaces are also limited and can only serve to absorb relatively low axial forces. Mainly occurring impact forces would destroy the contact surfaces of the grooves that serve to absorb the force.

Another type of known safety device is that radially resiliently open disc with inwardly directed lugs which radially in a groove made transversely to the shaft axis is inserted. The contact surfaces the approaches of these disks in the axial direction in the groove of the shaft are only part of the contact surface of the groove, which itself is proportionate due to the small groove depth is low. This securing washer is therefore also relatively smaller for the purpose of receiving it Suitable for axial forces.

There are also a variety of security devices that can be used in arched in the radial direction, usually with inwardly extending radially attached Locking washers with slots, which when pushed axially onto the shaft spring open as a result of the slots and either by the spring force, as a result the existing friction, or by engaging the inner edge of the locking washer serve in a corresponding groove transversely to the shaft axis to absorb axial forces. In all of these designs, only relatively small axial forces can also be absorbed will. Only the spring action of the locking washer itself in the axial direction does not allow a fixed position of the built-in part when an axial force is applied and favor the contact surfaces changed in their position due to the spring deflection a shift in the axial direction.

The object of the invention is therefore to create a locking ring, with which large axial forces can be transmitted.

According to the invention this object is achieved in that the locking ring Is conical and has a separation on one side from the ring plane and forms an almost closed ring segment.

In the drawing is an embodiment of an inventive Circlip explained in more detail.

Fig. 1 shows a cross section of the part to be secured in the shaft circlip to be inserted.

Fig. 2 shows the same arrangement in the inserted state of the locking ring.

Fig. 3 shows the arrangement in which the part to be secured on both sides is secured in the axial direction.

Fig. 4 shows a cross section of the part to be secured in the bore to be inserted locking ring and Fig. 5 shows the same arrangement in the inserted Condition of the locking ring.

In Fig. 1, the inwardly resilient locking ring is in the conical Slot 2, formed by the conical recess 3 in the shaft or axis 4, and the conical turning 5 of the part to be secured 6, upstream in the installed position.

Fig. 2 shows the inserted locking ring in its end position. The circlip 1 cannot due to its inwardly gerschteten bias step out of the conical @ it @ @ he @@ ttrad independently.

At the z. B. evenly distributed, annular force P in the axial direction on the part 6 to be secured, the normal force N acts over the conical turning 5, over the locking ring 1 on the conical turning 3 of wave 4.

The conical locking ring 1 can thus by the upcoming Force P, which is directed axially, is not pushed out of the conical slot 2 because all force components N are perpendicular to the outer surface of the cone of the locking ring act.

According to the invention, a significant advantage is the conical Circlip 1 in that large axial forces P can be absorbed because once the conical recess 3 of the shaft 4 only a slight reduction in size Cross-section to the full shaft cross-section and the contact surfaces of the conical locking ring 1 on the shaft 4 and the part to be axially secured 6 are relatively large.

Because the conical locking ring 1 is in the end position of the to be secured the part 6 can be introduced into the conical slot 2, as in Fig. 3 shows the part 6 with a further conical locking ring 1 according to axially secured against shifting in both directions.

The conical locking ring 1 can also be used to axially secure Bearing caps, washers, axles, etc. are used in bores. According to Fig. 4 becomes one-sided perpendicular to the plane of the ring separated and outward resilient locking ring 7 in the conical slot 8, formed by the conical Turning 9 in the bore 10 of the part 11 and the conical turning 12 of the z. B. disc 13, inserted. According to FIG. 5, the axially applied forces P exert force components N directed perpendicular to the lateral surfaces, which cause a displacement of the locking ring 7 can not cause. Here too, large forces can be applied in the axial direction Direction to be recorded.

Fig. 6 shows the locking ring 1 in the normal state.

Fig. 7 shows the locking ring 1 in position when pushed into the conical slot 2.

Fig. 8 shows the locking ring 1 in the locking position.

To release the fuse from the shaft with the part to be secured can 9 at the open ring ends of the conical locking ring 1 and 7 one protruding nose 14 each, or, according to FIG. 10, one protruding eyelet 15 each, or 11 each have a slot 16 arranged.

Claims (3)

Claims S Circlip for axially securing parts on shafts, axles or bores, characterized in that the locking ring is conical and has a separation on one side and an almost closed one to the ring plane Ring segment forms. 2. Securing ring according to claim 1, characterized in that on the separation point on both sides lugs (14) or eyes (15) to change the ring diameter are arranged. 3. Securing ring according to claims 1 and 2, characterized in that that at the separation point on both sides slots (16) in the ring jacket for change of the ring diameter are arranged. Blank page