EP0255880A1 - Sliver can - Google Patents

Abstract

The sliver can has a fixed lower base (2) and a vertically displaceable intermediate base (3) supported on a spring (4). A hook element (6) is mounted on the underside of the intermediate base (3). The said element interacts in the bottom-most position of the intermediate base (3) with a spring-loaded catch element (8) mounted movably from the outside on the fixed base (2), in order releasably to lock the intermediate base (3) in its bottom-most position. When the intermediate base (3) is locked, it cannot unintentionally lift the material supported thereon, even if it is relatively light, over the upper edge of the can. The can can therefore safely be filled to a greater degree. <IMAGE>

Description

The invention relates to a spinning can, which has a fixed lower base and a vertically displaceable, spring-loaded intermediate base.

Spinning cans with an intermediate bottom, which is carried on a coil spring, have been known for a very long time. When the jug is empty, the spring holds the intermediate floor in the upper part of the jug. In the course of the filling process of the jug, the intermediate bottom gradually sinks down, in that the spring is compressed by the weight of the filled material.

In the known spinning cans with an intermediate floor there is a risk that the weight of relatively light material is not sufficient to keep the spring fully compressed when the can is full, and that the material is therefore at the top during transport of the can or when it is inserted into a subsequent machine comes out of the jug. In order to avoid malfunctions caused by such leaking material, you are forced not to fill the jug completely, so you cannot fully utilize the jug volume. To counteract this disadvantage by using a shorter or weaker spring is not desirable because the intermediate floor should be as high as possible in the empty can and because the can should also be usable for relatively heavy material.

The invention avoids the stated disadvantage in that a device for releasably locking the intermediate floor is provided in a lower position.

With this device, the intermediate floor can be held in the lower position during transport of the filled jug and when it is inserted into a subsequent machine. The can volume can therefore be fully utilized even with light material. To generate the spring load, a relatively strong long and long spring can be used. So that such a spring takes up as little space as possible in the compressed state, it is preferably designed as a conical spring, which can expediently be made from a wire with a rectangular cross section. The intermediate base can be prevented from escaping from the upper end of the can with an inwardly projecting projection arranged at the upper edge of the can.

The device for locking the intermediate floor can expediently be designed such that it engages automatically in the lower position of the intermediate floor.

The release of the lock after the jug has been brought into a subsequent machine can be done manually or automatically by moving a latch element of the device.

However, it is also possible to design the device for locking the intermediate floor in the manner of a push button, so that it only holds the intermediate floor in the lower position with a predetermined holding force. If this holding force is less than the spring load of the intermediate floor, then the intermediate floor remains locked only as long as the weight of the amount of material carried on the intermediate floor is greater than the difference between spring load and holding force. As soon as the weight becomes smaller when removing material from the spinning can, the intermediate floor unlocks automatically.

Further problems arise with the known spinning cans when rollers are attached to their undersides.

Especially when there are only three rollers, the cans can easily tip over during transport. In order to avoid this, the spinning can according to the invention can have a downwardly projecting projection on the circumference of the solid base, which extends downwards so far that he gets up on the floor before the inclination of the jug has become so great that it could tip over.

Another problem is that the rollers are contaminated by waste of textile material that is always lying around in spinning mills, making them stiff or difficult to steer. In order to prevent this, the spinning can according to the invention can have a ring of downwardly projecting hair at the circumference of the solid floor, which reaches down to the floor.

• Fig. 1 und Fig. 2 je einen Vertikalschnitt durch eine Spinnkanne, bei unterschiedlichen Stellun­gen des Zwischenbodens,
• Fig. 3 eine Unteransicht zu Fig. 2,
• Fig. 4 und Fig. 5 je eine Skizze einer Spinn­kanne mit einer Kegelfeder,
• Fig. 6 eine Skizze einer Spinnkanne mit zwei Federn mit entegegengesetzten Steigungen und
• Fig. 7 einen Vertikalschnitt durch den unteren Teil einer Spinnkanne mit einer abgewandelten Ausfüh­rung der Verriegelungseinrichtung.

Exemplary embodiments of the inventive spinning can are shown schematically in the drawings, namely:

• 1 and FIG. 2 each a vertical section through a spinning can, with different positions of the intermediate floor,
• 3 is a bottom view of FIG. 2,
• 4 and FIG. 5 each a sketch of a spinning can with a conical spring,
• Fig. 6 is a sketch of a sliver can with two springs with opposite pitches and
• Fig. 7 is a vertical section through the lower part of a spinning can with a modified version of the locking device.

The spinning can shown in FIGS. 1 to 3 has a circular cylindrical peripheral wall 1 and a lower base 2 fastened therein. An intermediate base 3 is arranged in the can to be displaced vertically.

A compression spring 4 is arranged between the fixed base 2 and the intermediate base 3 and holds the unloaded intermediate base in its upper end position shown in FIG is present.

The spring 4 is shown in FIGS. 1 and 2 as a cylindrical coil spring. So that the spring in the compressed state (Fig. 2) needs as little space as possible, you can ge, as in Figs. 4 and 5 shows, as a conical spring 4ʹ or 4ʺ. In addition, the spring 4ʺ outlined in FIG. 5 is wound from a wire with a rectangular (instead of circular) cross section. Furthermore, it may be expedient to use two coaxial coil springs (or conical springs) with opposite pitches instead of a single spring 4 in order to exert a more uniform force on the intermediate floor 3. A spinning can which, in addition to the coil spring 4, contains a coaxial second coil spring 4a with an opposite pitch, is sketched in FIG. 6.

In the middle of the underside of the intermediate floor 3 there is a hook element 6 which, in the lower end position of the intermediate floor, as shown in FIG. 2, extends downward through an opening 7 in the fixed floor 2. The hook element 6 interacts with a movable pawl element 8 attached to the underside of the fixed base in order to lock the intermediate base 3 in its lower end position according to FIG. 2. In the illustrated embodiment, the pawl element 8 is a pivotable lever that is spring-loaded against its engagement position with the hook element 6. When the intermediate floor 3 is moved into its lower end position, the hook element 6 with its inclined underside surface pushes the lever 8 to the side, and then the spring element automatically engages behind the hook element 6 due to its spring load. The free end of the lever 8 protrudes outward beyond the peripheral wall 1, as shown in FIG. 3, so that the locking of the intermediate floor 3 can easily be released manually or, if desired, automatically after the filled spinning can has been inserted into a machine which further processes the fiber sliver has been.

In addition to the described preferred embodiment, there are of course numerous other options for the configuration of the device for the Ver lock the intermediate floor 3 in its lower end position. For example, the head of the element 6 fastened to the intermediate floor 3 itself could be designed as a spring-loaded pawl which engages under an element fixedly attached to the lower floor 2. Or it could be arranged horizontally displaceable bolts or spring-loaded pawls passing through the peripheral wall 1 at point A (FIG. 2) in order to releasably hold the intermediate floor 3 in its lower end position.

Furthermore, the device for locking can also be designed such that it not only automatically locks the intermediate floor 3 as described with reference to FIGS. 1 to 3 when it is brought into its lower end position, but also releases the intermediate floor automatically as soon as it is from above weight force acting on the intermediate floor of the material carried on the intermediate floor falls below a predetermined limit value. An embodiment of such a locking device acting similarly to a push button, in which the hook element 6element attached to the intermediate floor 3 is only held or locked in the locking position in the locking position, is shown in FIG. 7. 7, the hook element 6ʹ not only has an inclined (in the example conical) underside surface 6a, but also an inclined (conical) top surface 6b. The pawl element 8ʹ is shown as an elastically stretchable ring which lies in a groove 11 in an attachment attached to the fixed bottom 2. When the intermediate floor 3 with the material carried thereon is moved into its lower end position, the hook element 6ʹ with its inclined underside surface 6a expands the ring 8ʹ and passes through it. The ring 8ʹ then contracts around the inclined top surface 6b and thus locks the intermediate floor 3 with a predetermined holding force in its lower end position. The size the vertical holding force is given by the elastic force of the ring 8 Ring and by the angle of inclination of the top surface 6b. The holding force is less than the force of the compressed spring 4. The intermediate floor 3 therefore remains locked in its lower end position only as long as the sum of the holding force and the weight of the material carried on the intermediate floor 3 is greater than the force of the spring 4. In the course of the removal of material from the spinning can, the intermediate floor 3 is therefore automatically unlocked as soon as the said sum becomes smaller than the force of the spring 4. The hook element 6ʹ then expands the ring 8ʹ with its inclined top surface 6b and passes through it.

The locking device described with reference to FIG. 7 can of course be easily reversed in such a way that the hook element 6element is attached to the fixed floor 2 and the resilient pawl element 8ʹ is attached to the intermediate floor 3.

On the underside of the fixed bottom 2 three rollers 9 are attached in the usual way to facilitate the transport of the spinning can. The peripheral wall 1 of the spinning can projects so far down over the plane of the fixed bottom 2 that its free lower edge, when the can is inclined, touches the floor before the incline of the can is so great that it could tip over. The condition is of course met if the solder through the center of gravity S (Fig. 1) of the spinning can still goes through the standing area, when the free lower edge of the peripheral wall 1 touches the floor, or in other words, when the vertical projection Sʹ of Center of gravity S on a plane E, each of which touches two adjacent rollers 9 and the free lower edge of the peripheral wall 1, lies within this free edge. (Level E coincides with the floor when the edge of the peripheral wall 1 touches the floor.

The rollers 9 are surrounded by a closed rim 10 arranged at the periphery of the fixed base 2 or at the lower edge of the peripheral wall 1 of downwardly projecting hair, which extends down to the floor (ie into a plane tangent to the undersides of the rollers 9) ) extend. The hair ring 10 ensures that waste of textile material that is always lying around in spinning plants does not reach the rollers 9 when the spinning can is moved.

Claims (12)

1. Spinning can, with a fixed lower base (2) and a vertically displaceable, spring-loaded intermediate base (3), characterized by a device (6, 8; 6ʹ, 8ʹ) for releasably locking the intermediate base (3) in a lower position. 2. Spinning can according to claim 1, characterized in that said device (6, 8; 6ʹ, 8ʹ) in the lower position of the intermediate floor (3) is designed automatically latching or engaging. 3. Spinning can according to claim 2, characterized in that said device (6, 8) has a spring-loaded pawl element (8) which is attached to the fixed base (2) so as to be movable from the outside and which has a hook element (6) attached to the intermediate base (3) ) interacts. 4. Spinning can according to claim 2, characterized in that said means (6ʹ, 8ʹ) has a pawl element (8ʹ) and a hook element (6ʹ), of which elements (8ʹ, 6ʹ) one on the fixed bottom (2) and the other is attached to the intermediate floor (3) and which elements (8ʹ, 6ʹ) cooperate with one another in the manner of a push button in order to non-positively lock the intermediate floor (3) in its lower position with a predetermined holding force. 5. Spinning can according to claim 4, characterized in that the predetermined holding force is less than the spring loading of the intermediate floor (3). 6. Spinning can according to one of claims 3 to 5, characterized in that the hook element (6; 6ʹ) on the intermediate floor (3) is centrally projecting downwards and that the fixed bottom (2) in the middle an opening (7) for the passage of the hook element (6; 6ʹ). 7. Spinning can according to one of claims 1 to 6, characterized in that the can at its top Ren edge has an inwardly projecting projection (5) to limit the upward displacement of the intermediate floor (3). 8. Spinning can according to one of claims 1 to 7, characterized in that a conical spring (4ʹ; 4ʺ) is arranged to generate the spring load between the fixed base (2) and the intermediate base (3). 9. Spinning can according to one of claims 1 to 8, characterized in that two coaxial coil springs (4, 4a) are arranged with opposite pitches to generate the spring load between the fixed base (2) and the intermediate base (3). 10. Spinning can according to one of claims 1 to 9, characterized in that for generating the spring load between the fixed bottom (2) and the intermediate bottom (3) at least one wound from a wire with a rectangular cross section (4ʺ) is arranged. 11. Spinning can according to one of claims 1 to 10, in which on the underside of the fixed bottom (2) rollers (9) are arranged. characterized in that the can has a downwardly projecting projection at the periphery of the solid base (2), which extends so far down that the vertical projection (Sʹ) of the center of gravity (S) of the can on each level (E), which touches two adjacent rollers (9) and the free edge of the projection, lies within this free edge. 12. Spinning can according to one of claims 1 to 11, in which on the underside of the fixed base (2) rollers (9) are arranged, characterized in that the can at the periphery of the fixed base (2) has a rim (10) of has projecting hairs that extend at least approximately down into a plane tangent to the underside of the rollers (9).

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