EP1758807A1

EP1758807A1 - Method and device for winding a thread bobbin

Info

Publication number: EP1758807A1
Application number: EP05752900A
Authority: EP
Inventors: Michael Pyra; Martina Smerz; Ulrich Wagner
Original assignee: Oerlikon Textile GmbH and Co KG; Saurer GmbH and Co KG
Current assignee: Oerlikon Textile GmbH and Co KG
Priority date: 2004-06-18
Filing date: 2005-06-17
Publication date: 2007-03-07
Also published as: JP2008502558A; WO2005123558A1; DE102004029550A1; CN1968879A

Abstract

The invention relates to a method and a device for winding a thread bobbin (1). According to said invention, a thread is guided back and forth during the traversing stroke (6), before being deposited on the rotatively driven thread bobbin (1) and the thread is wound until a final diameter of the thread bobbin has been attained. To obtain a specified partial quantity of wound thread on the thread bobbin, the thread is temporarily guided outside the traversing stroke at least once before the final diameter of the thread bobbin (1) has been attained, to form a loop of thread (15) on the end face of the thread bobbin (1). The thread bobbin (15) with said loop of thread on its end face is characterised in that it is possible to pull defined partial quantities of the wound thread in succession from the thread bobbin (1) once the loop of thread has been severed.

Description

Method and device for winding a bobbin

The invention relates to a method for winding a thread spool according to the preamble of claim 1, a device for performing the method according to the preamble of claim 7 and a thread spool.

In the manufacture, further processing and finishing of textile threads in several process steps, it is known that the threads are wound into thread spools between the process steps for the purpose of storage. The bobbins wound in a previous process are then presented to the subsequent process as supply bobbins. For this purpose, it is necessary that thread spools of this type have good thread pull-off properties. A method and a device for producing such thread spools is known for example from WO 00/68126.

In the known method and the known device, the thread is laid before being deposited on a thread spool within a traversing stroke in such a way that end faces which are as straight as possible are formed at the ends of the spools, so that the thread is pulled off properly. Here, at least for the thread quantity stored on the thread bobbin, a continuous further processing process is guaranteed until a next thread end. Processing stages of the subsequent processes can thus often be determined by a thread end of a thread spool.

For example, it is known from EP 0 386 519 B1 to wind a specific thread length that is matched to the subsequent process to form a thread spool in the upstream process. However, such methods are disadvantageous in cases in which the maximum amount of thread that can be stored in a thread spool is not the same as the thread length required for a further processing process.

- L It is an object of the invention to provide a method for winding a bobbin according to the type mentioned at the beginning and an apparatus for carrying out the method in which the amount of thread required for a further processing process can be selected independently of the total amount of thread in the bobbin.

This object is achieved according to the invention by a method with the features according to claim 1, by a device for carrying out the method with the features according to claim 7 and by a thread spool with the features according to claim 11.

Advantageous developments of the invention are defined by the features and combinations of features of the respective subclaims.

The invention has the particular advantage that the entire thread quantity of a thread spool can be divided into several subsets. Each subset can be defined by a thread end created on the thread spool after winding. For this purpose, the thread bobbin is wound in such a way that the thread is guided at least once briefly outside the traversing stroke, by which the bobbin width is determined, before the final diameter of the thread bobbin is reached, so that an end-side thread loop forms on the thread bobbin. The thread is advantageously guided by a controllable guiding means which at least once briefly guides the thread in the predetermined interval in such a way that a portion of the thread is deposited outside the bobbin width.

The thread spools according to the invention therefore have the particular advantage that, prior to the further processing process, a plurality of thread ends can be generated, each of which specifies a thread length defined for the subsequent process. For example, it is known that false twist textured and dyed threads are twisted in a film process. In the follow-up process, the twisted threads are wound into thread spools in predetermined thread lengths. In the case, that a ^"yarn package according to the invention is presented to the twisting process, the twisting process can be by the predetermined on the bobbin subset determined so that, for example, an automatic doffing process for changing the thread bobbins is possible. The bobbin according to the invention are thus particularly suitable for subsequent processes, wherein in a Process step defined thread lengths are to be processed.

In the thread spools according to the invention, the thread loop is therefore formed by a piece of thread lying outside the winding assembly of the thread spool, which is preferably dimensioned in length such that a new thread end and a new thread start is formed after the thread loop has been severed.

In the method according to the invention, the point in time for the formation of the thread loop can be determined by the winding parameters such that a fraction of the total thread quantity of the thread spool can be determined. In this way, a winding time or a diameter of the thread spool or a wound thread length can be specified, which defines a first partial quantity on the thread spool from the beginning of the winding of the thread spool. In those cases in which the winding speed for forming the thread spool is essentially constant, the specification of winding times is preferably used to determine the partial quantity.

In order to be able to produce the thread deposits on the thread spool without problems before and after forming a thread loop, the development of the method according to the invention is particularly advantageous, in which the thread is guided by a traversing thread guide to form the thread loop. This variant of the method is preferably used in cases in which the thread is held within a traverse stroke by an oscillating traverse thread guide.

In the cases in which the thread is guided by several thread guides within a traverse stroke, the formation of the thread loop can be preferred briefly lead through an additional loop guide, which catches the thread in the thread run between a traversing thread guide and the thread spool.

In order to be able to use the auxiliary device in the subsequent process for fixing and holding thread ends, the development of the method according to the invention is particularly suitable, in which the thread loop is produced on the side of the thread spool on which a thread reserve winding associated with the thread spool is wound. Thus, all thread ends can be produced on one end face of the thread spool on the thread spool.

When carrying out the method according to the invention, the guide means is coupled to a control device. The control device has a data input and a data memory for receiving target parameters of the thread spool and a comparator for comparing the target parameters with actual parameters of the thread spool. The parameters of the thread bobbin are the winding time or the specified bobbin diameter or the specified thread length that is used to determine the partial quantity.

The method according to the invention is described in more detail below with reference to some exemplary embodiments of the device according to the invention with reference to the accompanying drawing.

They represent:

Fig. 1 shows schematically a first embodiment of the device according to the invention for performing the method according to the invention. Fig. 2 and

Fig. 3 schematically several views of a thread spool according to the invention. Fig. 4 schematically shows another embodiment of the device according to the invention for performing the method according to the invention 1 schematically shows a first exemplary embodiment of a device according to the invention for carrying out the method according to the invention. Only the components of the device that are relevant for carrying out the method according to the invention are shown here.

A bobbin tube 2 is held on a bobbin holder 3 and a bobbin 1 is wound around its circumference. The coil holder 3 is shown as a driven spindle 4. Here, the spindle 4 has clamping devices (not shown here) on the circumference in order to fix the winding tube 2 fitted onto the spindle 4. The drive of the spindle 4 is not shown here.

The spindle 4 is preceded by a rotatably mounted pressure roller 5 in the thread course. The pressure roller 5 or the spindle 4 are held in a movable manner in order to allow the thread spool 1 to grow while a thread 18 is being wound up. The pressure roller 5 lies against the circumference of the thread bobbin 1 during the winding process.

A traversing means 6 is arranged upstream of the pressure roller 5 in the thread path. The traversing means 6 has at least one traversing thread guide 7, which is driven oscillatingly within a traversing stroke by means of a drive means 19.

A guide means 8 is arranged laterally next to the thread bobbin 1 in the space between the traversing means 6 and the bobbin holder 3. The guide means 8 is formed by a loop guide 9 and an actuator 10 driving the loop guide 9. The actuator 10 is coupled to a control device 11. A sensor 12, which is also connected to the control device 11, is provided for detecting the spindle speed of the spindle 4.

In the device shown in FIG. 1, an incoming thread 18 is continuously wound into a thread spool 1. The thread 18 is through the Traversing thread guide 7 is guided back and forth within a traversing stroke, so that a thread spool 1 with a cross winding is created. The thread spool 1 has a cylindrical shape with the straight end faces 14.1 and 14.2. The filing of the thread 18 takes place via the pressure roller 5 lying on the circumference of the thread spool 1. The spindle 4 is driven to wind up the thread 18 in such a way that the peripheral speed of the thread spool 1 remains constant during the winding process.

During the winding process, the speed of the spindle 4 is detected by the sensor 12 and given to the control device 1. Since the spindle speed changes as a function of the increase in the thread bobbin 1, the actual parameters of the thread bobbin, such as winding time, bobbin diameter or thread length, can be derived directly therefrom and further processed in the control device 11. For this purpose, the control device 11 has a comparator 22 which is linked to a data memory 20. The data memory 20 is connected to a data input 21, by means of which the control device 11 receives set parameters of the thread spool 1. The target parameters of the thread spool supplied to the control device 11 via the data input 21 define the point in time for the formation of a thread loop on the end face 14.1 of the thread spool 1. A winding time, a bobbin diameter or a thread length can be specified here as target parameters. A constant actual-target comparison is carried out by the comparator 22 within the control device 11. As soon as the size of the actual parameter matches the target parameter, a control pulse is triggered via the control device 11 and fed to the actuator 10. The loop guide 9 is guided by the actuator 10 in the direction of the thread guide between the traversing thread guide 7 and the thread spool 1. The loop guide 9 catches the thread 18 and briefly guides it out of the traversing area, so that a piece of thread is deposited outside the spool width of the thread spool 1. The thread 18 is released by the loop guide 9 and wound further. The thread spool 1 now has a thread loop formed on the end face 14.1, which the end and the beginning of at least two subsets of the Define thread spool 1. This process can be repeated so that the entire amount of thread taken up by the thread spool can be divided into two, three or four subsets.

2 and 3, several views of a thread spool according to the invention are shown. 2 shows a top view and FIG. 3 shows a side view of the thread bobbin. Insofar as no express reference is made to one of the figures, the following description applies to both figures.

The thread spool 1 is held on a winding tube 2. The thread spool 1 consists of a thread wound in a cross winding. The thread spool 1 is wound cylindrically and has straight end faces 14.1 and 14.2 on both sides. A thread loop 15 is formed on the end face 14.1. The thread loop 15 consists of a piece of thread that protrudes from the bobbin. The piece of thread extends over part of the circumference of the end face 1. Here, the length of the piece of thread is selected such that a thread end and a thread start can be formed after severing the thread loop 15. The thread loop 15 defines two partial quantities of the thread wound on the thread spool 1, which can be drawn off from the thread spool 1 one after the other in a subsequent process. Each of the partial quantities on the thread spool 1 preferably has the same thread lengths, so that the continuity of the subsequent process is limited by the respective thread ends, so that, for example, an automatic thread change or bobbin change can be carried out in the subsequent process.

The thread spool 1 has on the side facing the end face 14.1 on the winding tube 2 a thread reserve winding 13, which marks the start of the winding process of the thread spool 1. The thread reserve winding 13 contains the thread end of the second wound subset on the thread bobbin 1.

- Il The thread spool 1 has the thread loop 15 and the thread reserve winding 13 on a common side, so that any auxiliary devices for guiding the thread ends can be used equally for each of the partial quantities.

4 shows a further exemplary embodiment of a device according to the invention for carrying out the method according to the invention. The exemplary embodiment has a coil holder 3, which is formed by two opposing centering plates 16.1 and 16.2. A winding tube 2 is held between the centering plates 16.1 and 16.2, on the circumference of which a thread spool 1 is wound. The centering plates 16.1 and 16.2 are rotatably mounted. On the circumference of the bobbin 1 there is a drive roller 17 which is driven by a roller drive 23 at a constant peripheral speed, so that the bobbin 1 rotates due to the friction with the drive roller 17.

A traversing means 6 is arranged upstream of the drive roller 17 in the thread path. The traversing means has a traversing thread guide 7 which is driven to oscillate via the drive means 19. The traversing means 6 could, for example, be designed as a belt traverse, as is known from EP 0 999 992 B1. In this respect, reference is expressly made to the cited publication at this point.

In order to wind up a thread 18, this is oscillated back and forth by the traversing thread guide 7 within a traversing stroke, so that a thread spool 1 is wound. During the winding process, the traversing stroke is continuously shortened, so that a thread spool 1 with biconical end faces 14.1 and 14.2 is wound.

4 shows an operating situation in which the traversing thread guide 7 is guided outside the traversing stroke area. In this situation, a piece of thread is deposited directly outside the bobbin width of the thread bobbin 1, so that a thread loop is formed on the end face 14.1. After the Fa the loop of the end face 14.1 is generated, the winding process is continued within the traversing stroke range. For this purpose, the traversing means 6 is connected to a control device (not shown here), by means of which the point in time for the formation of the thread loop and thus the size of the partial quantity of the thread being wound and still to be wound is determined.

The exemplary embodiments of the device according to the invention for carrying out the method according to the invention shown in FIGS. 1 and 4 are exemplary in their construction and design of the components. For example, a thread loop could also be formed by further developing and using the facilities available for forming the thread reserve winding. It is essential here that the thread loop of the thread spool generated on one of the end faces defines a subset of the wound thread and creates the possibility of forming a thread end.

LIST OF REFERENCE NUMBERS

1 thread spool

2 bobbin

3 bobbin holders

4 spindle

5 pressure roller

6 traversing agents

7 traversing thread guide

8 guide means

9 loop guides

10 actuator

11 control device

12 sensor

13 Thread reserve winding

14.1, 14.2 end face

15 thread loop

16.1, 16.2 centering plate

17 drive roller

18 threads

19 drive means

20 data memories

21 Data entry

22 comparator

23 roller drive

Claims

claims

1. A method of winding a thread spool, in which the thread is brought back and forth within a traverse stroke before being deposited on the rotatingly driven thread spool, and in which the thread is brought up to

Reaching an end diameter of the thread spool is wound, characterized in that before reaching the end diameter of the thread spool, the thread is guided at least once briefly outside the traversing stroke to form an end-side thread loop on the thread spool.

2. The method according to claim 1, characterized in that the time for forming the thread loop is determined by a winding time or by a diameter of the thread spool or by a wound thread length since the beginning of the winding of the thread spool.

3. The method according to claim 2, characterized in that a predetermined fraction of a maximum thread quantity of the thread spool is defined by the winding time or by the diameter of the thread spool or by the wound thread length.

4. The method according to any one of claims 1 to 3, characterized in that the thread for forming the thread loop is guided by a traversing thread guide, which leads the thread for winding the thread spool.

5. The method according to any one of claims 1 to 3, characterized in that the thread for forming the thread loop is briefly guided by a loop guide, the thread in the thread running between see a traversing thread guide and the thread spool through

Loop leader is caught.

6. The method according to any one of claims 1 to 5, characterized in that the thread loop is generated on the side of the thread spool on which a thread reserve winding associated with the thread spool is wound.

7. Device for performing the method according to one of claims 1 to 6, with a bobbin (2) holding the bobbin holder (3) for receiving a thread bobbin (1), with a traversing means (6) for moving a thread (18 ) within a traversing stroke and with a control device (11) for controlling the winding process, characterized in that a controllable guide means (8) is provided, by means of which the thread (18) at least once briefly outside the. before reaching the final diameter of the thread spool (1) Traversing stroke to form a thread loop (15) on the end of the thread spool (1) can be performed.

8. The device according to claim 7, characterized in that the guide means (8) is formed by an oscillating driven traversing thread guide (7) of the traversing means (6).

Device according to claim 7, characterized in that the guide means (8) is formed by a loop guide (9) which is arranged in the space between the traversing means (6) and the spool holder (3).

10. The device according to one of claims 7 to 9; characterized in that the guide means (8) is coupled to a control device (11) which has a data input (21) and a data memory (20) for receiving set parameters of the thread spool (1) and a comparator (22) for comparing the Has nominal parameters with actual parameters of the thread spool (1).

11. Thread spool consisting of a thread wound in a cross winding with end faces (14.1, 14.2) on both sides, characterized by at least one thread loop (15) projecting on one of the end faces (14.1, 14.2).

12. Thread spool according to claim 11, characterized in that the thread loop (15) is formed by a short piece of thread lying outside the winding assembly of the thread spool.

13. Thread bobbin according to claim 12, characterized in that the length of the thread piece is dimensioned such that a new thread start and a new thread end is formed after severing the thread loop (15).

14. Thread spool according to one of claims 11 to 13, characterized in that the thread loop (15) is associated with a thread reserve (13) wound on the same side (14.1) of the thread spool (1).