EP4126727A1 - Device for laying a thread - Google Patents

Abstract

The invention relates to a device for laying a thread, comprising a pivotal guide bar (1). The guide bar (1) has a guide end (2) with a thread guide (3) and a drive end (5), said guide bar (1) being rotatably mounted on a stationary pivot axis (4). The drive end (5) of the guide bar is coupled to a drive (9) in order to drive the guide bar (1). The aim of the invention is to lay a thread in a defined and modifiable manner. According to the invention, this is achieved in that the drive (9) is designed as an oscillating linear drive (6) which is connected to the drive end (5) of the guide bar (1) by means of a coupling element (7).

Description

Device for laying a thread

The invention relates to a device for laying a thread according to the preamble of claim 1.

When manufacturing synthetic threads in a melt spinning process or when treating threads in a texturing process, it is common for the threads to be wound into a spool for storage at the end of the process. For this purpose, the thread is guided back and forth within a bobbin width of the bobbin to be wound, so that a cross winding results to form the bobbin. For this purpose, a thread guide is driven to oscillate so that the thread can be wound into a cylindrical or biconical cheese. To drive such a thread guide devices for laying a thread are known in the prior art, in which the thread guide is arranged at a leading end of a guide rod and in wel chem the guide rod is driven pendulum. Such a device for laying a thread has long been known from DE 1 131 575 A1.

In the known device for laying a thread, the guide rod is rotatably mounted on egg ner pivot axis. Elm to drive the thread guide of the guide rod held at the guide end, a drive acts on the opposite drive end of the guide rod. Since the drive end of the guide rod moves relative to the pivot axis on a circular path, the drive end is driven via a Gleitverbin extension with a multi-link gear, which is activated by a grooved washer to a uniform reciprocating movement. Due to the shape of the circumferential groove in the groove disc and its position, the guide end of the guide rod is moved back and forth, with a constant laying width prevailing. Such mechanical coupling gears are therefore completely unsuitable to be able to lead a Fa with the most variable possible laying width.

It has therefore prevailed until today only such devices for laying a thread in which the guide rod is held with its drive end on a driven shaft enclosed. Such systems are for example from DE 19960 024 Al with an electric drive or from DE 15 60360 Al with a mechanical drive is known. In all of these systems, however, it is necessary that the motion energy of the guide rod is generated solely by torque from the drive shaft. In this respect, the inertial forces of the guide rod act on the drive shaft, which requires correspondingly high braking and drive energies, especially in the reversal points. In addition, exact angle detection and angle control are required in order to guide a thread with a variable laying width.

It is therefore the object of the invention to provide a device of the generic type for laying a thread, in which the guide rod can be driven to an oscillating movement precisely and with easily adjustable laying widths.

This object is achieved according to the invention in that the drive is designed as an oscillating linear drive and that the linear drive is connected to the drive end of the guide rod by a coupling member.

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

The invention has the particular advantage that the pivoting movement of the guide rod can be generated solely by a straight linear movement. For transmission to the drive end of the guide rod guided on a circular path, a simple coupling element is provided between the linear drive and the guide rod, so that the relative mobility between the guide rod and the linear drive is guaranteed. In this respect, the guide rod can be swiveled quickly and very precisely by the linear drive.

To transfer the relative mobility between the linear drive and the drive end of the guide rod guided on a circular guide path, the development of the invention is preferably carried out in which the coupling member is formed by a push rod that is connected to the drive end of the guide rod by a swivel joint and by a second swivel joint a ram of the linear drive is connected. In this way, the linear movement of the linear drive can be transmitted directly to the drive end of the guide rod via the push rod.

In order to be able to maintain a defined laying width for laying the thread, the linear drive is formed by a pneumatic or hydraulic or electrical actuator which linearly moves the plunger back and forth within one stroke. The laying width at the leading end of the guide rod is determined by the stroke of the linear drive.

To set certain laying widths, the stroke of the actuator is preferably designed to be adjustable. Different coil widths or biconical coils can thus be wound in a simple manner.

In order to obtain the most compact possible arrangement, the development of the inven tion is preferably carried out in which the leading end of the guide rod at the end of a guide leg and the drive end of the guide rod at the end of a drive leg are formed, the pivot axis in the area between the guide leg and the drive leg is arranged and wherein the guide leg and the drive leg span an angle in the range of 50 ° to 180 ° between them. In particular, L-shaped guide rods can be used to convert the stroke movement of the linear drive into a pivoting movement of the guide end.

In order to be able to produce relatively large laying widths with the smallest possible stroke, the development of the invention is provided in which the guide leg has a length which is many times greater than a length of the drive leg. In this way, the laws of levers can be used to create the largest possible laying widths with a relatively small stroke.

For the reproducibility and adjustability of the laying widths on the guide de, the development of the invention is particularly advantageous in which a laying width for laying the thread is derived from a calculation formula as a function of The stroke of the linear drive and a length geometry of the guide rod result as follows:

V = (LF / LA) X H

The laying width is designated with V, the length of the guide leg with LF, the length of the drive leg with LA and the stroke of the linear drive with H.

This means that for each adjustable stroke of the linear drive, the laying width achieved when laying the thread must be determined in advance. The laying widths can be determined in advance, especially for performing stroke breathing and asymmetrical coils.

The inventive device for laying a thread is tert erläu below on the basis of some exemplary embodiments with reference to the accompanying figures.

They represent:

1 schematically shows a view of a first embodiment of the device according to the invention for laying a thread. FIG. 2 shows schematically a view of a further embodiment of the device according to the invention for laying a thread

In Fig. 1, a first embodiment of the device according to the invention for laying a thread is shown schematically. The embodiment has a guide rod 1, which is formed from a guide leg 1.1 and a drive leg 1.2. The guide rod 1 is rotatably mounted on a stationary pivot axis 4. The pivot axis 4 is arranged on the guide rod 1 in the area between the guide leg 1.1 and the drive leg 1.2. For this purpose, the guide rod 1 is L-shaped so that an angle is set between the guide limb 1.1 and the drive limb 1.2. The angle α can be in a range between 50 ° and a maximum of 180 °. The guide leg 1.1 of the guide rod 1 has an effective length, which is identified in Fig. 1 with the reference numeral LF. In contrast, the drive leg 1.2 has an effective length that is entered with the reference symbol LA in FIG. 1. The length LF of the guide leg 1.1 is here many times greater than the length LA of the drive leg 1.2. The effective lengths LF and LA relate to a pivot axis 4 as a pivot point and a pivot point 8.1 on the drive leg 1.2 as well as a guide end 2.

The guide leg 1.1 has a thread guide 3 at its guide end 2.

The drive leg 1.2 is connected to a drive 9 at a drive end 5. In this exemplary embodiment, the drive 9 is formed by a linear drive 6 which has an actuator 6.1 and a plunger 6.2. A coupling element in the form of a push rod 7 is arranged between the plunger 6.2 and the drive end 5 of the drive arm 1.2. The push rod 7 is connected to this with a swivel joint 8.1 with the drive end 5 of the drive leg 1.2. The push rod 7 is coupled to the plunger 6.2 of the linear drive 6 with a second swivel joint 8.2.

A control device 10 is assigned to the actuator 6.1. A guide speed and a stroke of the actuator 6.1 can be controlled by the control device 10. For this purpose, the actuator 6.1 can have pneumatic, hydraulic or electrical means for moving the plunger 6.2.

During operation, an oscillating drive movement is initiated at the drive end 5 of the drive leg 1.2 of the guide rod 1 via the linear drive 6. Thus, the drive arm 1.2 leads back and forth with an angle of rotation about the pivot axis 4. This rotary movement is transmitted to the guide leg 1.1. The pivoting angle of the guide leg 1.1 and thus the laying width oscillating through the guide end 2 of the guide rod 1, which corresponds to a coil width by way of example, is shown in FIG. In this exemplary embodiment, the coil is identified by the reference numeral 11. The laying width V, in which a thread is guided through the thread guide 3 at the guide end 2 of the guide rod 1, depends on the stroke of the linear drive 6 that is set in each case. re mean value and amplitude of the slide movement H (t) can be set. In this way, both stroke breathing and a storage position along the laying width V can be set. The hub H thus forms the adjusting means to influence the laying width of the Füh approximately end 2 and change. Due to the geometric relationships between the drive leg 1.2 and the guide leg 1.1, the Ver laying width V can be predetermined with the help of the stroke H of the linear drive 6. The following applies:

V = (LF / LA) X H

In this respect, the laying width V can be determined for each stroke H with the help of the lever geometry of the guide rod 1. The stroke on the linear drive 6 is set by the control device 10. The laying width can also be changed while a coil is being wound in order, for example, to achieve stroke breathing or a specific shape of the coil.

In the exemplary embodiment shown in FIG. 1, the linear drive 6 generates a vertically oscillating stroke movement in order to drive the guide rod 1. Alternatively, however, there is also the possibility that the linear drive 6 executes a horizontal Hubbe movement. In Fig. 2, an embodiment is shown for this purpose. The exemplary embodiment in FIG. 2 is identical in structure to the exemplary embodiment according to FIG. 1, so that only the differences are explained at this point and otherwise reference is made to the aforementioned description.

In the embodiment shown in Fig. 2, the guide rod has a Füh approximately leg 1.1 and a drive leg 1.2, which form an angle a of 180 ° between them. In this respect, the guide rod 1 is formed straight ahead, with a pivot axis 4 between the guide leg 1.1 and the drive leg 1.2 is arranged on.

The drive 9 is coupled to the drive end 5 of the drive leg 1.2. The drive 9 in this embodiment also has a linear drive 6, which is formed from an actuator 6.1 and a plunger 6.2. The plunger 6.2 is a Push rod 7 is connected to the drive end 5 of the guide rod 1. Here, the push rod 7 is connected to the drive arm 1.2 via a swivel joint 8.1 and to the plunger 6.2 via a second swivel joint 8.2. The plunger 6.2 is guided to and fro in the horizontal direction within a stroke H by the actuator 6.1. For this purpose, the actuator 6.1 is controlled by the control device 10. The push rod 7 forms the coupling member in order to enable a relative movement between the plunger 6.2 on a linear path and the drive end 5 on a circular path. The swivel joints 8.1 and 8.2 ensure a firm connection between the linear drive 6 and the guide rod 1 in every position.

In the embodiment in FIGS. 1 and 2, the device for laying a thread is shown as it can be used, for example, in a winding point for winding a thread. In principle, however, there is also the possibility that several guide rods 1 are assigned to the linear drive in order to be able to simultaneously wind several threads into bobbins. In this respect, the plunger 6.2 of the actuator 6.1 could be connected to several guide rods via several coupling links.

Claims

Claims 1. Device for laying a thread with a pivotable guide rod (1) which has a guide end (2) with a thread guide (3) and a drive end (5) and which is rotatably mounted on a fixed pivot axis (4), the Drive end (5) of the guide rod (1) is coupled to a drive (9), characterized in that the drive (9) is designed as an oscillating linear drive (6) and that the linear drive (6) by a coupling member (7) with the drive end (5) of the guide rod (1) is connected. 2. Apparatus according to claim 1, characterized in that the coupling member is formed by a push rod (7) which by a swivel joint (8.1) with the drive end (5) of the guide rod (1) and by a second swivel joint (8.2) with a plunger (6.2) of the linear drive (6) is connected. 3. Apparatus according to claim 2, characterized in that the linear drive (6) by a pneumatic or hydraulic or electrical actuator (6.1) gebil det which linearly guides the plunger (6.2) back and forth within a stroke (H). 4. Apparatus according to claim 3, characterized in that the hub (H) of the Ak sector (6.1) for setting a laying width (V) of the leading end (2) is designed to be adjustable. 5. Device according to one of claims 1 to 4, characterized in that the guide end (2) of the guide rod (1) at the end of a guide leg (1.1) and the drive end (5) of the guide rod (1) at the end of a drive leg (1.2 ) are designed that the pivot axis (4) is arranged in the area between the guide leg (1.1) and the drive leg (1.2) and that the guide leg (1.1) and the drive leg (1.2) between them an angle (a) in the area span from 50 ° to 180 °. 6. The device according to claim 5, characterized in that the guide leg (1.1) has an effective length (L _F ) which is many times greater than an effective length (LA) of the drive leg (1.2). 7. The device according to claim 6, characterized in that a laying width (V) for laying the thread results from a calculation formula as a function of the stroke (H) of the linear drive (6) and a length geometry of the guide rod (1) as follows: V = (LF / LA) x H