DE1774722B1 - CARRYING SHAFT FOR CORES - Google Patents

Description

The invention relates to a support shaft for winding cores. Such support shafts are used for releasable Recording of winding of a web-shaped material when winding or unwinding and are in the relevant machines can be used or detached from these as required.

Devices in the form of wedge bodies are known on such support shafts, the wedge surfaces of which with correspondingly inclined wedge surfaces of radially displaceable and radially inwardly spring-loaded Clamping jaws are so engaged that an axial movement of the wedge body into a radial movement the clamping jaw is implemented under the action of the spring or by overcoming the same (German utility model 1 901 271). It is also known, the wedge surfaces of such wedge bodies and the associated clamping jaws with opposite inclination to form the wedge body for clamping to move or relax the clamping jaws (USA.-Patent 2 591 730), what if necessary happens using turnbuckle-like spindles with counter-rotating thread sections (German patent 734 397).

The journals of known support shafts are body with the jacket, which is segmented by the and can be formed by ring springs loaded clamping jaws itself or for the passage of the Clamping jaws can have corresponding recesses, rigidly connected. This has the disadvantage that two pairs of operations are required for each winding change, namely the clamping or loosening of the winding core and the fastening or loosening of the support shaft with respect to their bearings, be it because, the support shaft would be overhung, which for reasons of stress in the rarest of cases is possible. This is a cumbersome, time consuming operation, and it is an object of the invention based on creating a support shaft that makes it possible to combine these two operations.

To solve this problem, the invention is based on a support shaft for winding cores that are in a hollow winding core for a web-shaped material is insertable, with recesses in the jacket of the hollow cylindrical support shaft body for receiving radially displaceable clamping jaws, which through two symmetrically arranged inside the support shaft body with respect to the axis normal center plane, wedge bodies axially displaceable in opposite directions can be pushed out and are spring-loaded against them.

According to the invention, the object is achieved in that the wedge bodies each with one to a bearing pin designed for the storage of the support shaft, hollow cylindrical extension are provided and that the axial stroke length of the wedge bodies and the inclination and orientation of their wedge surfaces in such a way are chosen that the fully extended radially beyond the jacket of the support shaft body or behind this retracted position of the clamping jaws a fully over the end face of the support shaft body also axially pushed out or behind this retracted position of the bearing pin assigned.

This measure ensures that the wedge body is displaced in a single operation in the axial direction one mounted in a machine and carrying a winding or winding core Support shaft released from its storage as well as the clamping of the winding core on this support shaft can be loosened. The support shaft with the full or empty winding core attached to it can then be removed from the machine, whereupon the support shaft for reuse can be pulled out. Accordingly, a support shaft with a loose wound core carried thereon are brought into a ready position and by repeated Axial displacement of the wedge body with both the

ίο Winding core firmly connected as well as in the machine be stored.

Advantageously, one known per se, each with one of two, can be used to actuate the wedge body Threaded sections of opposite pitch with the straight wedge bodies in thread engagement standing, secured against axial movements serve, the axial extent of which is at most equal to the Is the length of the support shaft when the bearing journals are retracted.

In the drawing, a preferred embodiment of the invention is shown as an example.

F i g. I is a longitudinal section through one half of a support shaft designed according to the invention extended jaws and journals;

Figure 2 is a similar longitudinal section for illustrative purposes the clamping jaws and bearing journals in the retracted state;

F i g. 3 is a section through the shaft along the line HI-III in FIG. 1.

The support shaft according to the invention consists of a hollow support shaft body 1, which is made with threads 5 or 6 equipped parts, namely a central sleeve 2 and an intermediate cylinder 3 and an end sleeve 4 is constructed at each end.

Through recesses 7 in the intermediate cylinder evenly distributed over the circumference of the support shaft 3 jump radially displaceable clamping jaws 8 of generally rectangular cross-section with sharp-edged Ribs 9 on their outer surfaces, which in the extended state in one over the support shaft inserted hollow winding core 11 (dash-dotted lines in F i g. 1).

The clamping jaws 8 rest with wedge surfaces 8 a, Sb formed on their inside on corresponding wedge surfaces 12 a, 12 b of wedge bodies 12 and are loaded against them by annular springs 13 which are received in corresponding grooves 14 formed on the outer surface.
The wedge bodies 12 of the two ends of the support shaft can be moved in opposite directions in the axial direction in order to expand the clamping jaws 8. Each wedge body 12 has an attached sleeve 15 at its inner end, which engages with longitudinal ribs 16 in axial guide grooves 18 of a sleeve 17 screwed into the middle sleeve 2 and is provided with an internal thread which is threadedly engaged with a threaded section 19 of a spindle 21 . The opposite end of the support shaft, not shown, corresponds to the one shown mirror-symmetrically, and the threaded section of the spindle 21 corresponding to the threaded section 19 in the opposite part is of opposite winding direction.

The spindle is mounted in roller bearings and secured against axial movement by a projection 22.

The outer ends of the spindle are formed into square heads 23, which allow the attachment of a tool allow.

The outer end of each wedge body is one

Bearing pin 24 is formed, the outer jacket of which is provided with grooves 25.

F i g. 1 shows the support shaft in the state in which it carries a winding core 11 and in which the bearing journals 24 are stored in the machine.

To detach the support shaft from the machine, a tool is placed on the square head 23 and the spindle is rotated in the direction of the countermovement of the wedge bodies 12. Not only are the wedge bodies moved in the axial direction towards the center of the support shaft, but also the wedge surfaces 12 a, 12 b relative to the wedge surfaces 8 α and 8 b in the sense of a loosening of the wedge engagement, so that the jaws under the action of Springs 13 are pulled inward. The rotary movement is ended when the bearing journals 24 are completely withdrawn from the associated bearings of the machine, so that at this point in time the support shaft with the winding core then loosely carried thereon can be removed from the machine. The removal of the support shaft in this state is not hindered by the spindle 21, the total length of which does not exceed the total length of the support shaft body.

To insert the support shaft with a winding core into the machine, the support shaft with the loosely worn winding core with retracted bearing pin in relation to the ready-to-install position brought onto the machine, and then the spindle 21 in the sense of spreading the clamping jaws 8 and the outward movement of the journals 24 rotated until the journals sufficiently far into the associated Engage parts of the machine and the ribs 9 of the clamping jaws 8 securely into the inner surface of the winding core engage.

Claims (2)

Patent claims: 1. Support shaft for winding cores, which can be inserted into a hollow winding core for a web-shaped material, with recesses in the jacket of the hollow cylindrical support shaft body for receiving radially displaceable clamping jaws, which are axially opposed by two inside the support shaft body symmetrically arranged with respect to the axis normal center plane displaceable wedge bodies can be pushed out and are spring-loaded against them, characterized in that the wedge bodies (12) are each provided with a hollow cylindrical extension designed to form a bearing pin (24) for mounting the support shaft, and that the axial stroke of the wedge body (12) as well as The inclination and orientation of their wedge surfaces (12 b) are chosen so that the fully extended or retracted position of the clamping jaws (8) fully over the surface of the support shaft body (1) axially pushed out or withdrawn behind this ne position of the bearing pin (24) is assigned. 2. Support shaft according to claim 1, characterized in that for actuating the wedge body (12) a known per se, each with one of two threaded sections (19) in opposite directions with the currently guided wedge bodies (12) in thread engagement against axial movements secured spindle (21) is used, the axial extent of which is at most equal to the length of the Support shaft with retracted bearing journals is (Fig. 2). 1 sheet of GQPY drawings