RU70558U1 - Eccentric Freewheel Mechanism - Google Patents

Abstract

The eccentric freewheel mechanism is designed to automatically connect and disconnect the kinematic chains of machine drives. Eccentric wedges are installed on the internal bilateral eccentric, the narrow part of each of which has protrusions of an arcuate shape. Spring-loaded dogs are installed in radially oriented blind holes made in the wide part of each eccentric wedge and interact with the ratchet teeth of the outer ring. The reliability of the operation is increased by holding the spring-loaded dogs of the eccentric wedges from relative rotation on the eccentric when the mechanism is jammed. Simplification of the design is achieved by performing the protrusions of the narrow part of the eccentric wedges of an arcuate shape. 2 ill.

Description

The utility model relates to the field of mechanical engineering and can be used to automatically connect and disconnect kinematic circuits in heavily loaded machine drives.

Known freewheel containing an outer cage made on the working surface with fine-grained teeth, a double-sided eccentric, on which the eccentric rings made with fine-grained teeth on the working surface are freely mounted. (Gorin M.P. Eccentric freewheeling mechanisms. - St. Petersburg: Polytechnic, 1992. - P.65. - Fig. 1.30. - 272 p.).

A disadvantage of the known clutch is insufficient durability and increased noise when working in heavily loaded drives of machines.

As a prototype, a freewheel has been selected, containing an outer ring with ratchet teeth on the inner surface, a double-sided eccentric, on which eccentric wedges made with ratchet teeth on the outer surface are freely mounted. At the end of each eccentric wedge, shanks are made in its narrow part, and grooves are made in the wide part of each eccentric wedge, corresponding in shape to the profile of the shanks (A.S. 1425376, USSR, MKI F16D 41/06. - Published in BI No. 35, 09/23/1988).

The disadvantages of this coupling are the design complexity and the low reliability of operation, since during the jamming period the relative rotation of the eccentric wedges on the eccentric is possible, as a result of which the tops of the ratchet teeth of the eccentric wedges collide with the tops of the teeth of the outer race.

The utility model solves the problem of improving the reliability and simplifying the design of the coupling.

The task is achieved by the fact that in the known freewheel, containing an outer race with ratchet teeth on the inner surface, a double-sided eccentric with profile cams, eccentric wedges made with ratchet teeth on the outer surface, arches in the narrow part of each eccentric wedge are made, in the wide part of each wedge, radially oriented blind holes are made, and a spring-loaded dog is installed in each hole, the protruding end of which is interconnected acts with the teeth of the outer cage.

With this constructive solution, during the jamming period, when the eccentric is rotated, the dogs keep the eccentric wedges from relative rotation on the eccentric, which ensures the correct entry into engagement of their ratchet teeth with the teeth of the outer race. The presence of arched protrusions at the end of each wedge in its narrow part simplifies the design of the mechanism.

Figure 1 shows a view of the eccentric freewheel from the end without a cover; figure 2 is a section aa of figure 1.

The eccentric freewheel mechanism consists of an external cage 1 with ratchet teeth on the inner working surface, a double-sided eccentric 2, made with profile cams 3 and 4, eccentric wedges 5 and 6, made with small module teeth on the external working surface. At the end of each wedge, in its narrow part, protrusions 7 and 8 are made of an arcuate shape, and the ends of the wedges are made in the form of straight sections 9 and 10. In the wide part of each eccentric wedge, radially oriented blind holes 11 and 12 are made in which the dogs 13 and 14, interacting with the springs 15 and 16. The mechanism is closed by a cover 17 held by a spring ring.

The eccentric freewheel works as follows.

When turning the eccentric 2 with the cams 3 and 4 counterclockwise, the eccentric wedges 5 and 6 are shifted in the radial direction to

the outer race 1 before entering the engagement of their ratchet teeth with the teeth of the outer race. In this case, the dogs 13 and 14 hold the eccentric wedges 5 and 6 from relative rotation on the surface of the profile cams 3 and 4. The coupling is jammed and the load is transferred from the eccentric 2 by the eccentric wedges 5 and 6 to the outer cage 1, and all the parts rotate as a whole . When turning the eccentric 2 with the cams 3 and 4 clockwise, the eccentric wedges 5 and 6 are shifted in the radial direction to the center of the eccentric 2 and rotate relative to the surface of the cams 3 and 4 until they enter the stop of the arc ledges 7 and 8, while the dogs 13 and 14 are pressed straight sections 9 and 10 of eccentric wedges to each other. As a result, an insignificant radial clearance is formed between the ratchet teeth of the eccentric wedges 5 and 6 and the outer race 1. There is a wedging and free movement of the mechanism with the non-contact movement of the ratchet teeth of the eccentric wedges 5 and 6 and the outer race 1, and the dogs 13 and 14 slide freely along the ratchet teeth external clips 1 and continue to be pressed to it due to the action of the springs 15 and 16, which ensures constant readiness of the coupling to jam.

Claims (1)

An eccentric freewheel mechanism containing an outer ring with ratchet teeth on the inner surface, a double-sided eccentric with profile cams, eccentric wedges made with ratchet teeth on the outer surface, characterized in that in the narrow part of each eccentric wedge there are arched protrusions in the wide part of each wedge, radially oriented blind holes are made, and a spring-loaded dog is installed in each hole, the protruding end of which interacts with the teeth of the outer cage.