BG112576A - Wedge-shaped clutch - Google Patents

Abstract

A wedge-shaped clutch is a device intended for transmission of rotary motion from one shaft to another in automated systems with cyclic drive. It can also serve as a limiter of transmitted torque. It consists of a tubular body (1) in which are placed three cylindrical wedge-shaped bodies (2, 3 and 4) , through which a stud (9) passes, connected by a threaded connection (12) to the wedge-shaped body (2). On the other end of the stud (9) is placed a spring (11), on which pressure is exerted by a nut (7), whereby the cylindrical wedge-shaped bodies (2, 3 and 4) are wedged with each other to the inner opening of the tubular body ( 1). Under this condition, the clutch transmits motion from the tubular body (1), which is the first shaft, to the second shaft, which is composed of the wedge-shaped bodies (2, 3 and 4). The force of the transmitted torque is determined by the tension of the spring (11). When the rotary motion has to stop, an axial force (P) is applied along the axial line of the stud (9) on the side of the spring (11), the wedge-shaped bodies (2, 3 and 4) disengage by the inner diameter of the tubular body (1) and both shafts are released relative to each other. 7 claims, 3 figures

Description

_h ··: · ; _: WEDGE CONNECTOR

Field of technique

A wedge clutch is designed to transmit rotary motion from one shaft to another in automated systems with a cyclic drive. It can also serve as a torque limiter.

Prior art

The most popular in technology is the Ferrod clutch, widely used in the automotive industry. Another type of clutch is the plate clutch used in metal cutting machines, as well as the spur gear clutch, etc.

All these connectors are of large dimensions and diameters.

Technical essence of the invention

The purpose of the invention is to create a compact device with small external dimensions, convenient for installation in any conditions, simple in construction and transmitting a large torque.

•'2 ··

This task is solved with the created wedge connector. This coupling can transmit both radial and axial forces or serve as a limiter for the power of the transmitted torque.

The main principle in the creation of the wedge coupling is the conversion of axial force into radial force. The coupling consists of a housing representing a tubular body, inside which there are two cylindrical wedge-shaped bodies, standing with their sharp tips opposite each other and movable in the tubular body. In another version of a wedge coupling, there are three cylindrical wedge-shaped bodies in the tubular body, one of which is a double wedge-shaped one. In practice, one shaft is the clutch housing, the tubular body, and the other shaft is composed and consists of at least two cylindrical wedge-shaped bodies.

When an axial force is applied, cylindrically pressing the wedge-shaped bodies against each other, they wedge between themselves and in the inner bore of the tubular body and convert the axial force into a radial one, thus the coupling works.

Explanation of the attached figures

In fig. 1 is a coupler working with two cylindrical wedge-shaped bodies.

In fig. 2, a clutch operating with three cylindrical wedge-shaped bodies is given.

In fig. 3 shows a variant of a wedge clutch with three cylindrical wedge-shaped bodies with a preset maximum torque.

Implementation examples

In fig. 1 is an example of the implementation of a wedge coupling consisting of the following elements: 1 housing of the coupling, in the form of a tubular body, inside it there are two cylindrical wedge-shaped bodies 2 and 3 facing each other with wedge-forming surfaces 8.2 of body 2 and 8.3 of body 3, forming the wedge-shaped shape of bodies 2 and 3. Cylindrically wedge-shaped bodies 2 and 3 are movable relative to the inner opening of tubular body 1.

In fig. 2 shows a wedge coupling consisting of the following elements: 1 tubular body, 2 and 3 cylindrical wedge-shaped bodies located at both ends of tubular body 1, 4 cylindrical double wedge-shaped body located between bodies 2 and 3, the wedge-forming surfaces of body 4, 8.4 a and 8.4b are opposite lying and parallel as follows 8.4a to 8.3 on body 3 and 8.4b to 8.2 on body 2.

...4 ..

Cylindrically wedge-shaped bodies 2, 3 and 4 are movable relative to the inner opening of the tubular body 1.

In fig. 3 shows another variant for the realization of a wedge coupling and the elements are as follows: 1 tubular body - coupling body, 2 and 3 cylindrical wedge bodies, 4 cylindrical double wedge body, cylindrical wedge bodies 2, 3 and 4 are mounted in a tubular body 1, as the wedge-forming surfaces, 8.2, 8.3, 8.4a and 8.4b are opposite each other and parallel, 8.2 vs. 8.4b and 8.3 vs. 8.4a, 9 a stud connected by a threaded connection 12 to a wedge-shaped body 3 located in axially located holes of wedge-shaped bodies 2 and 4, a spring 11 mounted on the side of a cylindrical wedge-shaped body 2 on a stud 9 between washers 5 and 6 and a nut 7 on a threaded part 10 of a stud 9. Cylindrical wedge-shaped bodies 2, 3 and 4 are movable relative to the inner opening of tubular body 1.

Use of the invention

Wedge connector in fig. 1 works as follows. When forces P2 and P3, equal in magnitude and opposite in direction, are applied simultaneously and axially to cylindrically wedge-shaped bodies 2 and 3 located in a tubular body 1 and running relative to its inner opening, an axial force occurs pressing the two bodies against each other in the wedge-forming surfaces 8.2 and 8.3, under this effort, jamming occurs by sliding cylindrical wedge-shaped bodies 2 and 3 along the wedge-forming surfaces 8.2 and 8.3 with the inner opening of the tubular body 1. Under this condition, the two clutch shafts are engaged and can transmit rotary motion to each other. In this type of coupling, one shaft is a tubular body 1, and the second consists of two parts, a cylindrical wedge-shaped body 2 and a cylindrical wedge-shaped body 3. When removing forces P2 and P3, the three elements of the coupling, tubular body 1 and cylindrical wedge-shaped bodies 2 and 3 are splined and the two clutch shafts are released relative to each other.

In fig. 2 clutch wedge works as follows. When forces P2 and P3, equal in magnitude and opposite in direction, are applied simultaneously and axially to cylindrical wedge-shaped bodies 2 and 3, an axial force occurs pressing the two bodies against a cylindrical double wedge-shaped body 4. Wedge-shaped bodies 2, 3 and 4 located in tubular body 1 are running relative to its inner opening with opposite and parallel wedge-forming surfaces, bodies 2 and 4 with surfaces 8.2 and 8.4b, bodies 3 and · ^; ·6··' *··* ··' .:. :

with surfaces 8.3 and 8.4a. With the axial force generated by forces P2 and P3 acting opposite to each other, cylindrical wedge-shaped bodies 2, 3 and 4 press and slide along the wedge-forming surfaces, bodies 2 and 4 with surfaces 8.2 and 8.4b, bodies 3 and 4 with surfaces 8.3 and 8.4a and are thus wedged in the inner opening of the tubular body 1. In this way, the coupling is engaged while the forces P2 and P3 are acting and can transmit a rotary motion from a shaft which is a tubular body 1 to the other shaft which is composed of cylindrical wedge-shaped bodies 2, 3 and 4. Upon termination of the action of forces P2 and P3, the elements of the coupling bodies 1, 2, 3 and 4 are wedged and the coupling disengages.

In fig. 3 shows another option for the realization of a wedge clutch, its purpose is to limit the power of the transmitted torque to a preset value and to protect the equipment from overloading in emergency situations.

The operation of the coupling is as follows: a stud 9 with a threaded joint 12 is connected to a cylindrical wedge-shaped body 3 and passes through axially located openings of a cylindrical double wedge-shaped body 4 and a cylindrical wedge-shaped body 2. The bodies 2, 3 and 4 are located in a tubular body 1 running relative to its inner opening. Cylindrical wedge-shaped bodies 2, 3 and 4 are placed such that the wedge-forming surfaces 8.2 and 8.4b, 8.3 and 8.4a are opposite each other and parallel to each other. On the stud 9 on the side of the wedge-shaped body 2, between washers 5 and 6, a spring 11 is placed, which is subjected to pressure from a nut 7, wound on a threaded part 10 of the stud 9. Thus, a spring 11 subjected to pressure from a nut 7, through a stud 9 mounted through a threaded joint 12 in a wedge-shaped body 3, creates conditions for the occurrence of two axial forces with opposite directions and equal in magnitude. Cylindrically wedge-shaped bodies 2, 3 and 4 are pressed against each other by the wedge-forming surfaces 8.2 and 8.4b, 8.3 and 8.4a, whereby they are wedged in the inner opening of the tubular body 1. The wedge force is directly proportional to the spring force created 11 and directly proportional to the transmitted torque from tubular body 1, which is one shaft of the coupling to the other shaft, which is composed of cylindrical wedge-shaped bodies 2, 3 and 4. When the resistance moment (that which must be overcome by the torque transmitted of the clutch) increases and becomes greater than the wedging force between the two clutch shafts (tubular body 1 and cylindrical wedge bodies 2, 3 and 4), then they slip against each other.

In the case of a wedge clutch from fig. 3 is characteristic that it has permanently engaged shafts (tubular body 1 and

8'* cylindrical wedge-shaped bodies 2, 3 and 4) with a force determined by the created effort of spring 11. When the transmission of rotational movement from the shafts of the clutch must be stopped, along the axis line of stud 9, on the side of spring 11, applies the force P. This force must be greater than the force of tension of spring 11 and with a direction coinciding with the direction of tension of spring 11, in which stud 9 pushes cylindrical wedge-shaped body 3 in the direction of action of force P, cylindrical wedge-shaped bodies 2, 3 and 4 are wedged out of the inner opening of the tubular body 1 and the clutch stops the transmission of rotary motion.

Claims (7)

x/ 1. Wedge connector, consisting of a tubular body (1) characterized by the fact that two cylindrical wedge-shaped bodies (2 and 3) with equal external diameters are movable in the inner opening of the tubular body (1), on which the opposite faces of bodies (2 and 3) in a tubular body (1) are at equal angles other than 90° to their longitudinal axis, the tips of the acute angles of cylindrically wedge-shaped bodies (2 and 3) are opposite and rotated relative to each other about the longitudinal axis of tube body (1) at 180°. ₍ 2. Wedge connector consisting of a tubular body (1) characterized by the fact that three cylindrical wedge-shaped bodies (2, 3 and 4) with equal external diameters are movable in the inner opening of the tubular body (1), on which the opposite ends of the bodies ( 2, 3 and 4) in a tubular body (1) are at equal angles other than 90° to their longitudinal axis, the apexes of the acute angles of cylindrical wedge-shaped bodies (2, 3 and 4) are opposite and rotated relative to each other about the longitudinal axis of tubular body (1) at 180°, cylindrical wedge-shaped body (4) is double wedge-shaped. -·2·· 3. According to claim 1, cylindrical wedge-shaped bodies (2 and 3) have the shape of a cylindrical body which on one side is crossed by a plane at an angle other than 90° to the longitudinal axis of the cylinder. 4. According to claim 2, a cylindrical double wedge-shaped body (4) has the shape of a cylindrical body whose two ends are intersected by the two planes of a dihedral angle, the cylindrical body being perpendicular to its bisector plane. 5. According to claims 1 and 2, all cylindrical wedge-shaped bodies in a tubular body (1), regardless of their number, have equal angles at the apex of the wedge of the opposite faces other than 90° with respect to their longitudinal axis. 6. According to claims 1 and 2, all cylindrical wedge-shaped bodies (2, 3 and 4) can be tubular wedge-shaped bodies. 7. According to claim 2, the double wedge-shaped body (4) may be more than one in one coupling.