EP2141104A1 - Bobbin and tube transport system - Google Patents

Abstract

In a process to drive an array of cross-wound textile spinning bobbins and sleeve transport system (1), the transport system has a first feed path (2) for the bobbins resting on transport dishes (3) and a return path (4) for empty bobbins. The two paths (2, 3) are linked by a transverse transport path (5) with a predetermined number of waiting positions (27) for bobbins on plates. During their travel along the first feed path, advance is temporarily blocked to create additional waiting positions (28) that are occupied is the waiting positions (27) are occupied on the transverse transport path (5).

Description

The invention relates to a method for operating a Spinnkops- and sleeve transport system and a Spinnkops- and sleeve transport system for a cheese producing textile machine with a plurality of winding units, wherein the transport system a feed line arranged on transport plates spinning cops, a return path for unwound sleeves and between these routes in Has area of the winding units arranged transverse transport routes with a predetermined number of waiting positions for arranged on transport plates spinning cops.

Such Spinnkops- and sleeve transport systems are known in the textile industry, in particular in connection with cheese winder, in various embodiments.

In the DE 43 38 552 A1 For example, a cross-winding machine with a Spinnkops- and sleeve transport system is described which has, inter alia, a Spinnkopszuführstrecke, a Hülsenabfuhrstrecke and numerous, leading to the winding units, so-called transverse transport routes. The transverse transport sections, in each of which an unwinding position for the spinning cops is arranged, are arranged between the spinning cops feed section and the tube removal section and extend orthogonally to these sections. In the range of various transport routes drivable conveyor belts are installed, on which the transport plates, which carry the spinning cops or the unwound sleeves, are frictionally conveyed. The arranged in the region of the transverse transport lines conveyor belts are either by the drive of Sleeve removal path with driven or each have their own drive. The length of the transverse transport sections is dimensioned such that, in addition to a spinning cop located in the unwinding position, further coppled transport plates positioned in the supply or waiting position can be accommodated in the transverse transport path. The Spinnkopszuführstrecke is designed as a reversible drivable storage section on which the cop-equipped transport plates patrol back and forth. The circulating conveyor belts of the transverse transport lines ensure that when passing through a transport plate patrolling the storage section, it is drawn off and transported to a waiting position on the transverse transport path. If all waiting positions on the transverse transport path are equipped with spinning cops, the copsbestückte transport plate simply moves past the transverse transport route. So it may happen that transport plates run to the end of Kopszuführstrecke when all storage positions of the transverse transport lines are busy. For this reason, the drive of Kopszuführstrecke is reversible and the spinning cops move back in the opposite direction. The illustrated embodiment of the transverse transport path therefore makes it possible to pick up cop-equipped transport plates from both feed directions. Such trained Spinnkops- and sleeve transport systems have been proven in practice, however, have the disadvantage that they are relatively expensive in their structural design.

The DE 33 08 172 A1 discloses a Spinnkops- and sleeve transport system, which also has a Spinnkopszuführstrecke, a sleeve discharge line and extending between them in the field of winding units transverse transport routes. The copsbestückten transport plates are arranged on a Leitkontur and one in the region of the transverse transport routes Turntable transferred to the waiting positions of the transverse transport routes. The guide contour is designed so that the Kopszuführung is possible only from one direction. Copsbestückte transport plates that are absorbed by none of the winding units are introduced from a reject guide, which is arranged at the last winding unit in a Kopsrückführeinrichtung. These excess cops are then returned by the Kopsrückführeinrichtung and input side fed back into the Kopszuführstrecke. This transport system has proven itself in practice. However, the Kopsrückführeinrichtung is an additional expense and requires space in the winder.

It is therefore the object of the present invention to improve the handling of the spinning head transport plates, which can not be transferred to the waiting positions of the transverse transport sections, and thereby simplify the spinning head feed.

The object is achieved by the characterizing features of the method claim 1 and the device claim 4. Advantageous developments of the invention are the subject of the dependent claims.

To solve the problem, the spinning cops along the feed path are blocked so that additional waiting positions arise on the feed line, which are occupied when the waiting positions are occupied on the transverse transport routes.

By means of the method according to the invention, it can be ensured that no spin copters are transported to the end of the feed path or beyond the last winding station. It is therefore no additional Spinnkopsrückführeinrichtung required and the feed line does not need to be reversible. Accordingly, the spin copters to the transverse transport routes must not be fed on both sides. For this reason, the transverse transport routes can be simpler. Overall, the spinning cop and tube transport system can be significantly simplified by the method according to the invention.

Preferably, the spinning cops are blocked at a plurality of positions along the feed path and the blocks along the feed path at the positions canceled again, which follow free waiting positions in the feed direction. This way, waiting waiting positions can be quickly filled again and it is ensured that there are always enough spinning cops available at each winding station.

To solve the problem, a Spinnkops- and sleeve transport system for a cross-wound textile machine is further proposed with a plurality of winding units and means for performing the method according to the invention. For this purpose, the transport system has means for blocking the spin cushions arranged on transport plates along the feed path, which are designed to hold the spinning cops in a waiting position on the feed path. Furthermore, means for detecting a spinning cop are present on selected waiting positions and the means for blocking are controllable in dependence on the means for detecting.

Preferably, a sensor for detecting a spinning cop is present at selected waiting positions. In a preferred embodiment, sensors for detecting a spinning cop are positioned at the waiting positions of the transverse transport paths that are closest to the feed path. This immediately recognizes when a waiting position on the transverse transport route must be filled again.

To block the Kopsteller various means are conceivable. For example, electromechanical or pneumatic locking bolts can be arranged along the feed path. Preferably, these locking bars are positioned in the feed direction immediately behind the branch to a transverse transport path. In this way, even without deblocking the bolt, spinning cops can be transported from a waiting position on the feed line to a waiting position on the transverse transport line.

In a particularly advantageous embodiment of the transport system according to the invention, the transverse transport routes each have a rotatable transport disc for conveying the transport plate, and the transport plates are displaced by means of the transport disc from the waiting position on the transverse transport path in the direction of the feed, which are blocked along the feed path moving transport plate , The rotating transport disc can simultaneously be designed to position a transport plate in an unwinding position and to push the transport plate after unwinding of the sleeve in the Ausmündungsbereich the transverse transport path. Thus, for blocking means can be used, which are also suitable for transport and positioning of the spinning cop in the transverse transport route. Furthermore, it can also be realized in such a way that when a new spinning cop is transported into the unwinding position, a spinning cop is automatically transferred from the waiting position on the feed line to the waiting position of the transverse transport path.

Advantageously, the transport disc on transport pockets, which correspond to a guide base of the transport plate, and the dimensions of the transport disc are chosen so that when moving the transport plate in the direction of the feed line, the unwinding position of the cop station located in the unwinding position is not changed. Thus, the unwinding-sensitive unwinding process is not adversely affected.

The invention will be explained in more detail with reference to an embodiment shown in the drawings.

Fig. 1

eine Draufsicht auf einen Teil eines Spinnkops- und Hülsentransportsystems zur Durchführung des erfindungsgemäßen Verfahrens

Fig. 2

eine Draufsicht auf einen Teil des Spinnkops- und Hülsentransportsystems mit auf der Zuführstrecke blockierten Spinnkopstransporttellern;

Fig. 3

eine der jeweils im mittleren Bereich der Quer- transportstrecken angeordneten Transportscheiben in Draufsicht.

Show it:

Fig. 1

a plan view of a portion of a Spinnkops- and sleeve transport system for carrying out the method according to the invention

Fig. 2

a plan view of a portion of the Spinnkops- and sleeve transport system with blocked on the feed path Spinnkopstransporttellern;

Fig. 3

one of each arranged in the central region of the transverse transport routes transport discs in plan view.

In Fig. 1 is schematically shown a part of a Spinnkops- and tube transport system 1 of an automatic cross-winding machine not shown. Such spinning cop and sleeve transport systems are, as is known, either connected directly to a corresponding Spinnkops- and sleeve transport system of a ring spinning machine or indirectly connected to the transport system of such a textile machine.

In the second case, the Spinnenkops- and sleeve transport system of the cheese winding machine has an interface for feeding spinning cops, which were made on the separated ring spinning machine, as well as an interface for the disposal of empty tubes, such as a sleeve peeling device on.

The Spinnkops- and sleeve transport systems 1 such automatic packages have different, different transport routes over which the numerous winding units of the automatic cheese winder supplied with fresh spin heads or disposed of unwound empty tubes. Of these known transport routes are in Fig. 1 only the Spinnkopszuführstrecke 2, the sleeve return path 4 and some of the arranged between the lines 2 and 4 transverse transport sections 5 shown. How out Fig. 1 can be seen, the Spinnkopszuführstrecke 2 is not rectilinear, but wavy. That is, the Spinnkopszuführstrecke 2 consists of a plurality of machine longitudinal axis 20 slightly inclined arranged transport sections, each of which expire on the junction region 12 of one of the transverse transport sections 5, and subsequent transport sections, which dodge outward behind the junction area. By this arrangement it is achieved that a spinning head transport plate 3, which moves in the transport direction T along the feed section 2, is automatically transported in the transverse transport path 5, if a free space on the transverse transport path 5 is present. If all waiting positions on the transverse transport path 5 are occupied with spinning cops, the transport plates 3 are automatically continued on the feed line 2.

During the Spulbetriebes run within the Spinnkops- and sleeve transport system 1, in the transport direction T, numerous Transport plate 3 um, which are equipped either with spinning cops or with empty empty tubes. The promotion of the transport plate 3 within the Spinnkops- and sleeve transport system 1 is carried out, with the exception of the central regions 11 of the transverse transport sections 5, via circulating Endlostransportbänder, preferably via flat belts. As in the in Fig.1 shown embodiment, in the junction region 12 of the transverse transport lines 5, for example, two in the machine longitudinal direction rotating conveyor belts 22 and 23 are provided, the upper run, as indicated by the arrows F ₂₂ and F _23, rotate clockwise. In the Ausmündungsbereich 13 of the transverse transport sections 5 another, also in the machine longitudinal direction revolving conveyor belt 24 is arranged, the upper strand, however, rotates counterclockwise (arrow F ₂₄ ). The conveyor belts 22 to 24 ensure a frictional transport of the transport plate 3 on the Spinnkopszuführstrecke 2, the sleeve return path 4 and in the junction areas 12 and the Ausmündungsbereichen 13 of the transverse transport sections. 5

In the central region 11 of the transverse transport sections 5, the transport plates 3 are each supported by a defined controllable transport disc 6. This in Fig. 3 shown in plan view transport disk 6 has, for example, three transport pockets 19, which are arranged offset by 120 degrees. The transport pockets 19 preferably correspond during transport with a guide base 16 on the transport plates 3. That means, the cyclically controllable via a stepper motor 21 transport discs 6 position the transport plate 3 each first in the unwinding position 10 and then ensure that transport plate 3, the sleeves are unwound, are pushed into the Ausmündungsbereich 13 of the transverse transport sections 5, where the transport plates 3 arrive on the conveyor belt 24, the transport plate 3 with the unwound empty tubes
transported back via the sleeve return path 4 to the ring spinning machine.

The Fig. 2 shows the Spinnkops- and sleeve transport system 1 with along the feed line blocked and in waiting position 28 Spinnkopstransporttellern. Such blocked transport plates are located in the areas A, B, D and E.
The transverse transport sections 5 located in the above areas are filled with transport plates 3 equipped with spinning cop. Thus, all waiting positions 27 of the transverse transport sections 5 are occupied by transport plates 3. In order to block the transport plates 3 on the feed line 2, the transport plates 3 located on the transverse transport sections 5 are pushed out in the direction of the feed section. This pushing out is realized by rotating the transport disk 6 clockwise. The transport pockets 19 of the transport disc 6 are designed so that during this turning operation, the spinning cop located in the unwinding position 10 is not changed in its position. For this purpose, the opening area of the transport pockets 19 is larger than the corresponding guide base 16 of the transport plate 3.

In the present embodiment, three waiting positions 27 are available on each transverse transport route. At the last waiting position, a sensor 26 is positioned at each transverse transport path. The last position is the supply line facing waiting position. The sensor 26 detects whether the respective waiting position is occupied by a spinning head transport plate or not. Hall sensors, for example, are suitable for this purpose. So that the Hall sensor detects the transport plate, a permanent magnet can be attached to the transport plate.

The sensor 26 of the transverse transport path in the area C of in Fig. 2 shown transport device detects that the last waiting position of the transverse transport path is not busy. This information is transmitted via a signal line to a control device, not shown. This causes the stepper motors of the transport disks 6 in the areas A and B to cancel the blocking of the feed line 2. Thus, the on the feed line 2 in waiting position 28 spinning cops are transported on. As soon as the sensor detects a spinning cop in area C, the feed section in areas A and B is blocked again. In order to enable several waiting positions on the feed path per transverse transport path, it is also possible to provide sensors for detecting the transport plates on the feed path.

Claims (9)

A method for operating a Spinnkops- and sleeve transport system (1) for a cross-wound producing textile machine with a plurality of winding units, wherein the transport system a feed line (2) arranged on transport plates (3) spinning cops, a return path (4) for unwound pods and between them Stretching arranged in the region of the winding units transverse transport lines (5) having a predetermined number of waiting positions (27) for transport plates (3) arranged spinning cops, characterized in that the spinning cops along the feed line (2) are blocked so that on the feed line (2) give additional waiting positions (28) which are occupied when the waiting positions (27) on the transverse transport routes (5) are occupied. A method according to claim 1, characterized in that the spinning cops are blocked at a plurality of positions along the feed path (2). A method according to claim 2, characterized in that blocks along the feed line (2) are canceled at the positions, which in the feed direction free waiting positions (27, 28) follow. Spinnkops- and sleeve transport system (1) for a cheese-producing textile machine with a plurality of winding units and means for performing the method according to one of claims 1 to 3, wherein the transport system a feed line (2) for on transport plates (3) arranged spinning cops, a return path (4) for unwound tubes and arranged between these distances in the field of winding units transverse transport lines (5) having a predetermined number of waiting positions (27), characterized in that means (6) for blocking the transport plates (3) arranged spin cops along the feed line (2) are present , which are adapted to hold the spinning cops in a waiting position (28) on the feed line (2), means (26) for detecting a spinning cop or transport plate (3) are present on selected waiting position (27, 28) and the means ( 6) are controllable for blocking in dependence on the means for detecting (26). Spinnkops- and sleeve transport system according to claim 4, characterized in that the means for detecting a spinning cop as a sensor (26) is formed. The spinning cop and tube transport system according to claim 5, characterized in that the sensors (26) for detecting a spinning cop are positioned at the waiting positions of the transverse transport sections (5) closest to the feed section (2). Spinnkops- and sleeve transport system according to claim 4, characterized in that the transverse transport routes (5) each have a rotatable transport disc (6) for conveying the transport plate (3) and the transport plate (3) by means of the transport disc (6) from the waiting position (27) on the transverse transport path (5) so in the direction of the feed path (2) are displaceable, along the feed line (2) moving transport plates (3) are blocked at the entrance of the transverse transport path (5). Spinner-top and sleeve transport system according to claim 7, characterized in that the rotating transport disc (6) is designed to position a transport plate (3) in an unwinding position (10) and the transport plate (3) after unwinding of the sleeve in the Ausmündungsbereich (13 ) of the transverse transport path (5). Spinnenkops- and sleeve transport system according to claim 8, characterized in that the transport disc (6) transport pockets (19) corresponding to a guide base (16) of the transport plate (3) and the dimensions of the transport pockets (19) are selected so that at Moving the transport plate (3) in the direction of the feed line (2) the unwinding position (10) is not changed.

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