DE4116186A1 - Clamping unit with limited motion between two parts - has rod moving in sleeve with movement limited by balls that are forced against angled surface of insert - Google Patents

Abstract

The damping unit has an inner rod (5) that can move relative to an outer element (3) with clamping being provided by balls (15) that locate against a tapered surface (16). The balls are pressed against the surface by an insert (22) that is spring biassed (18). The clamping ring is set into a main piston assembly (7) that can be displaced by applying fluid pressure (8a). The range of movement is limited by the insert end (26) contacting a surface, with the piston moving against a main spring (24). ADVANTAGE - Provides clamping between parts for both directions of movement.

Description

The invention relates to a clamping device for lifting the relative axial mobility of an outer part and an inner part passed through this one another opposite, with a clamping cone that is coaxial to the inner part is arranged with circumferentially distributed in the clamping gap between the clamping surface of the clamping cone and the outside arranged surface of the inner part, as a clamping body serving balls, which are held by a guide element ten, and the axial mobility in one direction by moving the clamping cone relative to the clamping body can be canceled.

Such an arrangement is for example for the coils known in spinning machines. In case that however, mass forces are still effective, even if if a fixation between the clamping cone and the Internal part was done via the clamping body, a further movement of the inner part in the sense of loosening the clamps direction possible.

The invention has for its object a Klemmein to create direction, optionally in one position is convertible into a clamping between the clamp body and the inner part for both directions of movement of the inner part relative to the outer part is possible.  

This object is achieved in that the guide element has a stop which at be with regard to one direction of movement already in the clamping position tion located sprags by further axial Ver storage of the clamping cone in contact with a stationary one Stop can be brought.

The advantage of this training is that depending on whether a freewheeling function should be given or not, the clamping cone for eliminating the possibility of movement in one direction only until the two parts are jammed or additionally for both directions of movement together with the inner part and the guide element are moved on can until the sprags over the guide member if it is attached to a stationary blocking stop, also create a lock for the freewheel direction.

In a further embodiment of the invention, that the guide element via a spring in the direction of the taper of the clamping gap is applied.

As a result, the sprags are always on standby position to achieve the necessary clamping effect with Be movement of the clamping cone held the clamping body.

A pressure is preferred for actuating the clamping cone medium-loaded piston provided with which the Clamping cone is connected.

The clamping bodies are axial to secure the release position against another stationary relative to the clamping cone Release stop supported. The clamping cone is one Amount moved relative to the guide element, the  ensures that no clamping effect can occur because then there is enough radial play. The Losean blow is preferably from the end face of the outside parts formed. Furthermore, the clamping body can be in grooves of the clamping cone, the conical clamping surfaces are part of the grooves. This ver the guide element also simplifies itself. The circumferential shared bracket of the clamping bodies designed as balls is taken over by the grooves. The the guide element Acting spring improves the guidance of the clamp body in the grooves. The guide element only needs that axial support for the sprags. For the Case that the clamping surface of a conical bore is formed, the guide element is a cage too shape which the clamping body also on the circumferential distance holds to each other. Such a clamp is preferred direction used as part of a lifting device.

A preferred embodiment of the invention is in the drawing is shown schematically.

This shows a longitudinal section through a lifting device with the clamping device according to the invention.

The lifting device 1 shown in the drawing has a housing 2 , in the end wall of which the outer part 3 is fastened. The outer part 3 is designed as a sleeve.

The inner part 5 designed as a shaft is passed through the bore 4 of the outer part 3 with play. The housing 2 is closed by a cover 6 . Both are connected by a snap connection.

A piston 7 is arranged axially displaceably between the outer surface 11 of the outer part 3 and the bore wall of the housing 2 . This forms towards the end wall of the housing 2 towards a cylinder chamber 8 , which can be supplied with a pressure medium connection 8 a nit pressure medium. The housing 2 is sealed to the piston 7 by means of the seal 9 and that of the outer part 3 to the piston 7 by means of the seal 10 . In the end of the piston 7 facing away from the cylinder space 8 , the clamping cone 12 is inserted into a bore 13 . The conical clamping surface tapering towards the cylinder space 8 or outer part 3 is designated by 16. In the exemplary embodiment, the conical clamping surface 16 is part of circumferentially distributed grooves. These each take up a ball 15 . However, it is also possible to design this as a conical bore. Between the outer surface 14 of the inner part 5 and the conical clamping surfaces 16 designed as grooves, clamping bodies in the form of balls 15 are accommodated. The balls 15 are held by a guide element 17 . They protrude radially inwards and outwards from the guide element 17 . The between the outer surface 14 of the inner part 5 and the clamping surfaces 16 formed clamping gap is marked with 16 a be.

The guide element 17 is stepped away from the outer part 3 . The inner part 5 is guided through the guide element 17 with radial play. The guide element has a support surface 19 to the balls 15 , on which a spring 18 is supported with one end, while its other end is supported on the inner surface of a spring bearing 20 . Furthermore, the guide element 17 has an extension 22 which protrudes axially from the spring bearing 20 . The spring bearing 20 has an edge 21 which is centered on the piston 7 and is supported axially against this end face which is distant from the cylinder space 8 . The return spring 24 is supported against the edge 21 . Its other end is supported on the inner surface 23 of the cover 6 and acts on the piston in the direction of the open position of the clamping cone 12 . This is the position shown in the drawing figure. When the cylinder chamber 8 is pressurized, the piston 7 moves to the right away from the outer part 3 in the direction of the end wall of the cover 6 . Since the balls 15 are acted upon by the support spring 18 in the direction of the narrowing clamping gap 16 a, wedging takes place between the clamping cone 12 and the inner part 5 . With further pressurization of the cylinder chamber 8 by pressure medium, the piston 7 is moved together with the clamping cone 12 and the inner part 5 along the adjustment axis X in the direction of the inner surface of the housing cover 7 designed as a blocking stop 27 until the guide element 17 with the blocking stop 26 is moved Extension 22 comes to rest on the blocking stop 27 . As a result, wedging of the inner part 5 to the clamping cone 12 is also achieved in the event that a train force is exerted on the inner part 5 in the sense of movement to the right out of the cover 6 . In the drawing position shown in the drawing, a free axial adjustability of the outer part 2 and inner part 5 relative to one another is possible. In the first clamping position is still a movement, in the sense of moving the balls 15 out of the clamping gap 16 a towards its larger opening end, while any axial adjustment in the case of the presence of the guide element 17 with its stop surface 26 on the blocking block 27 is impossible is.

The penetration of dirt is prevented by wipers 28 which are seen between the outer surface 11 of the inner part 5 and the outer part 2 on the one hand and the cover 6 and the outer surface 11 of the inner part 5 on the other hand.

The housing 2 with the cover 6 is preferably arranged to be stationary, while the inner part 5 is to be freely axially movable, but for certain situations it should be blocked via the clamping cone 16 for both directions of movement.

Reference symbol list

1 lifting device
2 housings
3 outer part
4 Bore of the outer part
5 inner part
6 lids
7 pistons
8 cylinder space
8a pressure medium connection
9 Housing seal
10 Seal to the outer part
11 outer surface of the outer part
12 clamping cone
13 hole
14 outer surface of the inner part
15 sprags / balls
16 conical clamping surface
16 a clamping gap
17 guide element
18 support spring
19 support surface
20 spring bearings
21 rand
22 extension of the guide element
23 inner surface of the cover
24 return spring
25 release stop
26 blocking stop of the guide element
27 Blocking stop of the housing cover
28 wipers
X adjustment axis

Claims (7)

1. Clamping device for canceling the relative axial mobility of an outer part and an inner part passed through it with respect to one another, with a clamping cone which is arranged coaxially to the inner part, with circumferentially distributed in the clamping gap between the clamping surface of the clamping cone and the outer surface of the inner part, as a clamping body serving balls, which are held by a guide element, wherein the axial mobility in one direction can be canceled by moving the clamping cone relative to the clamping bodies, characterized in that the guide element ( 17 ) has a stop ( 26 ), which with respect to one Direction of movement of the clamping bodies ( 15 ) already in the clamping position can be brought into contact with a stationary stop ( 27 ) by further axial displacement of the clamping cone ( 12 ). 2. Clamping device according to claim 1, characterized in that the guide element ( 17 ) via a spring ( 18 ) in the direction of the taper of the clamping gap ( 16 a) is acted upon. 3. Clamping device according to claim 1, characterized in that the clamping cone ( 12 ) is fixedly connected to a pressure piston which can be opened ( 7 ). 4. Clamping device according to claim 1, characterized in that the clamping body ( 15 ) are axially supported in the release position against a fixed with respect to the clamping cone ( 12 ) Lösean impact ( 25 ). 5. Clamping device according to claim 4, characterized in that the release stop ( 25 ) is formed by the end face of the outer part ( 3 ). 6. Clamping device according to claim 1, characterized in that the conical clamping surface ( 16 ) is part of circumferentially distributed in the clamping cone ( 12 ) and the clamping body ( 15 ) leading grooves. 7. Clamping device according to one or more of claims 1 to 6, characterized by the training as part of a Hubein direction ( 1 ).