DE10246188A1 - Device for winding a thread - Google Patents

Abstract

A device for winding a thread on a bobbin is described, a thread guide unit for guiding the thread being provided which is guided in an axially movable manner. The thread guide unit is connected to a hollow shaft motor as the drive means. The hollow shaft motor has a drive rod which, depending on the control of the hollow shaft motor, sets the thread guide unit in a to-and-fro movement with reversal points at a desired speed. The hollow shaft motor is suitable as a particularly simple embodiment as a drive means for the thread guide unit. Further advantageous embodiments relate to the sealing of the drive rod with respect to the housing of the hollow shaft motor. An air flow is preferably generated in the direction of the drive rod and away from the hollow shaft motor in order to prevent dust from penetrating into the hollow shaft motor.

Description

The invention relates to a device for winding a thread on a bobbin according to the preamble of the claim 1.

Devices for winding up a Fadens are used in the field of textile machines to To produce packages. On bobbins is set according to a Process a thread wound around a tight package of the thread to reach on the package and also a safe unwinding to allow the thread.

A generic device for winding a thread on a spool is out DE 4 432 498 A1 known. The device has several cross-wound bobbins which are rotatably mounted on an axis of rotation. Each cross-wound bobbin is assigned a thread guide unit, which in turn is arranged to be axially displaceable in a guide. A winding of the thread on the package is achieved in that, on the one hand, the package is rotated about its central axis and, on the other hand, the thread guide device is moved back and forth in an axial movement.

It is off for the axial displacement of the thread guide device DE 4 310 905 A1 known to use two carriers movable in the opposite direction via endless belts. The thread is moved in a first direction by a first driver and taken over in an end region of the winding surface by a second driver that moves in the opposite direction and moved to the second end region of the winding surface. In the second end area, the thread is again taken over by the first driver and moved to the first end area again. The movement of the drivers takes place in the known embodiment by a belt drive.

Out DE 3 734 481 A1 a device for thread laying on a package is also known, in which thread guides are moved via an endless belt and a motor. The motor can be rotated in two directions of rotation, so that the endless belt can be moved alternately in two directions of movement. A corresponding change in the direction of rotation of the motor generates the back and forth movement of the thread guides required for winding.

The object of the invention is therein, an improved device for winding a thread to provide a coil.

The object of the invention is achieved by solved the features of claim 1. An advantage of the device according to the invention consists in the fact that a linear drive with a Drive rod in the form of a hollow shaft motor is used. The Using a linear actuator and a drive rod offers the advantage of a precise and rapid movement of the thread guide unit. Baffles for one Straps are not required. In addition, the elasticity and inertia caused by the straps are reduced the control of the thread guide unit avoided.

Further advantageous embodiments of the invention are in the dependent claims specified.

The hollow shaft motor preferably has a frequency converter that can be controlled via a control unit is. The control unit controls the frequency converter in the manner and instruct that the drive rod the thread guide unit in the desired Way moves.

In a preferred embodiment is the thread guide unit coupled with two spring elements in such a way that the spring elements the kinetic energy of the thread guide unit before reversing movement and after reversing movement the stored kinetic energy back to the thread guide unit submit. In this way, on the one hand there is a damping of the speed of movement the thread guide unit reached in the reverse range and also a feed of the recorded Enables kinetic energy. This is a gentle and low-energy movement of the thread guide unit possible. At the same time, the spring elements enable a quick reversal of movement possible.

The control unit preferably reduces the speed of the thread guide unit before the reversal of movement and thus ensures a gentle change in movement the thread guide unit. This is a low-vibration and gentle movement of the Thread guide unit allows.

In a preferred embodiment the drive rod is over a sealing element in a housing of the hollow shaft motor, wherein the sealing element is designed as dust protection. In this way it is avoided that the interior of the hollow shaft motor too much dusty. This ensures a long service life of the hollow shaft motor guaranteed.

In a preferred embodiment the sealing element is designed in the form of a sealing labyrinth. Training as a sealing labyrinth offers relatively good dust protection and is inexpensive.

In a further preferred embodiment the dust protection is designed in the form of an overpressure device, the air in the area of the sealing gap between the housing and the drive rod out of the housing blows. In this way, dustiness of the interior of the Hollow shaft motor avoided.

The sealing element is preferably in shape a hollow ring with blowing openings, which are arranged in a ring around the drive train on an outside of the housing. In this way, a concentration of the air flow is concentrated on the required area. This avoids the unnecessary generation of excess pressure. This enables the device to be operated with little energy.

In a preferred embodiment are the blow holes arranged in a blowing direction towards the drive rod are arranged and are directed at least slightly away from the housing. This firstly cleans the actuator stem itself from dust and also creates an airflow that blows the dust away from the case. consequently will be a reliable Protection of the interior of the hollow shaft motor from dust guaranteed.

The invention is explained below of the figures closer explained. Show it

1 1 shows a schematic arrangement of the device for winding a thread,

2 a hollow shaft motor with drive rod,

3 a sealing element in the form of a labyrinth seal,

4 a sealing element in the form of a hollow ring with blowing openings,

5 a cross section through a preferred embodiment of the hollow ring and

6 a speed diagram of the hollow shaft motor plotted against a disturbance variable.

1 shows a schematic representation of a traversing unit of a textile machine, which is essentially a bobbin 1 and a thread guide unit 2 having. The sink 1 is on a rotatable shaft 3 arranged by a rotary motor 4 is driven. The thread guide unit 2 has an eyelet 5 on, through which a thread 6 is led.

The string 6 is provided by a thread spool, not shown. The thread guide unit 2 is in the axial direction in a guide rail 7 axially displaceable. The thread guide unit 2 has a guide rod in two given opposite end regions 8th on that through the guide rail 7 are led. The thread guide unit 2 is on a lifting rod 9 attached. The lifting rod 9 is at a first end via a clutch 10 with a drive rod 11 connected. The drive rod 11 is part of a hollow shaft motor 12 , The hollow shaft motor 12 has a gearbox 13 on that with a rotor 14 connected is. The hollow shaft motor also has 12 via a stator 15 that over power lines 16 with a frequency converter 17 connected is. The frequency converter 17 stands with a voltage network 18 in connection, which for example provides three sinusoidal voltages of 400 V. The frequency converter 17 can also be connected to a control unit 19 be connected.

The stator 15 has a plurality of stator windings that are circular around the rotor 14 are arranged. The stator windings are powered by the frequency converter 17 depending on the control by the control unit 19 powered in the way that the rotor 14 is moved in the desired direction of rotation at the desired speed. The rotor 14 drives the transmission 13 on, which in turn is the drive rod 11 set in an axial movement. This is the gearbox 13 For example, designed as a nut with an internal thread 21 in operative connection with an external thread 20 the drive rod 11 stands. The drive rod 11 is fixed against rotation. The nut is pivoted. In addition, the nut is in the axial direction by stops 25 in the position opposite the housing 22 established. When the gear rotates 13 remains the axial position of the gearbox 13 unchanged and the drive rod 11 is shifted in the axial direction.

In this way there is a displacement of the thread guide unit 2 causes. Hollow shaft motors are well known and are manufactured, for example, by Rexroth.

The guide rods 8th is a spiral spring 23 assigned. The spiral springs 23 are on a holding frame 24 attached and each in an end region of the movement of the lifting rod 9 arranged. The distance between a coil spring 23 and the guide rod 8th is chosen in the way that the guide rod 8th before reversing the movement of the lifting rod 9 and thus the thread guide unit 2 for contact with the spiral spring 23 arrives and the spiral spring 23 against the holding frame 24 biases. After reversing the movement of the lifting rod 9 gives the coil spring 23 by the bias of the coil spring 23 stored kinetic energy of the lifting rod 9 back to the lifting rod 9 from.

Instead of the spiral springs shown 23 Other types of spring elements can also be arranged which dampen the movement of the lifting rod 9 in the region of a reversal of the direction of movement of the lifting rod 9 cause at the same time part of the kinetic energy of the lifting rod 9 save and after reversing the movement of the lifting rod 9 the stored kinetic energy back to the lifting rod 9 submit. In this way, a faster reversal of movement of the thread guide unit 2 causes. For example, spiral springs can also be arranged, which pull when the lifting rod reverses movement 9 be biased.

Instead of the in 1 thread guide unit shown 2 and coil 1 can use a variety of coils 1 and thread guide units 2 be arranged on the shaft 3 rotatably mounted or with the lifting rod 9 are firmly connected. In this way, a variety of threads can be used simultaneously 6 on spools 1 be wound up.

To control the frequency converter 17 has the control unit 19 via a corresponding control program, which is stored in a memory of the control unit 19 is filed.

2 shows several perspective views of the hollow shaft motor 12 with the drive rod 11 , In 2A is a side view of the hollow shaft motor 12 shown. It can be seen that the drive rod 11 preferably in a second guide rail 26 via a leadership block 27 is guided in the axial direction. One end of the drive rod 11 is fixed to the guide block 27 connected, the guide block 27 in lateral guide grooves 28 the second guide rail 26 engages with appropriately shaped cams. The guide grooves 28 the second guide rail 26 are each on the side of the second guide rail 26 educated. The leadership block 27 preferably provides the clutch 10 over which the lifting rod 9 with the drive rod 11 is firmly connected.

2 B shows a view from above of the hollow shaft motor 12 and the drive rod 11 , It can be seen that the end of the drive rod 11 via a clamp connection with the guide block 27 connected is. The clamp connection 29 can preferably also be used to attach the lifting rod 9 be used.

In 2C is an enlarged side view of the guide block 27 and the drive rod 11 shown. The drive rod 11 has a retaining groove 30 on that on a corresponding holding surface 31 of the guide block 27 rests. In this way, rotation of the drive rod 11 safely avoided.

2D shows an enlarged view of the guide block 27 from above.

2E shows a view from the axis of the drive rod 11 , The hollow shaft motor 12 has a bearing sleeve 34 through which the drive rod 11 in the hollow shaft motor 12 is led. Between the bearing sleeve 34 and the drive rod 11 is a sealing element 32 arranged. The sealing element 32 serves to seal the interior of the hollow shaft motor 12 against dust.

3 shows a preferred embodiment of the sealing element 32 , which is adjacent to the surface of the drive rod 11 a labyrinth seal 35 having. The labyrinth seal 35 consists essentially of several surfaces that are perpendicular to the longitudinal direction of the drive rod 11 are arranged. In this way, air must flow into the interior of the hollow shaft motor from the outside 12 wants to flow over the stepped sealing surfaces. Due to the arrangement of the vertically arranged surfaces, a swirling of the flow is achieved, so that an inflow into the interior of the hollow shaft motor 12 is difficult. As a result, dust is preferably stored in cavities 36 the labyrinth seal 35 from.

4 shows a further preferred embodiment of the sealing element 32 in the form of a hollow ring 37 , The hollow ring 37 has blow holes 38 on that ring-shaped around the drive rod 11 are arranged. The hollow ring 37 stands over a connecting line 39 with an air compressor 40 in connection. The air compressor 40 supplies the hollow ring 37 with overpressure so that the hollow ring 37 Air through the blow openings 38 emits. The blow holes 38 are arranged in such a way that the blowing openings 38 Air jet emitted dust from the actuator stem 11 blows away and from the housing 33 of the hollow shaft motor 12 blows away.

5 shows a cross section through the drive rod 11 and the hollow ring 37 with the blow holes 38 , The orientation of the blow openings is clear 38 to recognize that leads to an air flow coming from both the hollow shaft motor 12 leads away as well in the direction of the drive rod 11 is directed. The one from the hollow ring 37 generated air jet has both a directional component in the direction of the drive rod 11 as well as a second component away from the hollow shaft motor 12 on. This prevents dust from entering the actuator stem 11 by the axial movement of the drive rod 11 into the interior of the hollow shaft motor 12 arrives.

In 6 is schematically over time the speed of the hollow shaft motor 12 when winding a thread 6 shown. At time T ₀ , the speed changes from a negative to a positive speed. With a negative speed, for example, is a movement of the thread guide unit 2 to the right and a movement to the left associated with a positive speed. Between the time T ₀ and the time T ₁ , the speed is increased with a first slope up to a first speed. After time T ₁ , the speed is increased with a second, smaller slope to a second speed up to time T ₂ . At time T ₂ , which is before an end position is reached, the speed is determined by the control unit 19 by reducing the power supply to the hollow shaft motor 12 reduced and at time T _{3 converted} into a reversal of motion, ie a negative speed. In a corresponding manner, the speed change takes place cyclically over time. This will cause the thread guide unit to move back and forth 2 causes a winding of the thread 6 to the entire width of the spool 1 is required. Between the time T ₀ and the time T ₃ , the stroke breathing is shown, that of the width of the coil to be wound 1 equivalent.

The stroke breathing changes periodically by, for example, ± 3 mm, so that the reversal point of the thread guide unit 2 is not always exactly in the same place. This is a more advantageous winding of the coil 1 reached.

The reduction of the current strength for driving the hollow shaft motor 12 becomes dependent from the deflection of the thread guide unit 2 controlled. Since the deflection itself is not measured, the revolutions / the current angular position are determined by a motor encoder of the hollow shaft motor 12 used as a measure of the deflection. In the illustrated embodiment of the 6 The time T ₂ corresponds to a fixed deflection of the thread guide unit 2 , from which the speed of the thread guide unit is reduced by reducing the current 2 is reduced shortly before the reversal point.

In addition to changing the size of the lifting breathing, ie the reversal points of the thread guide unit 2 the average stroke speed is varied by setting a disturbance variable in order to improve the winding of the thread 6 to obtain. The disturbance variable, ie the deviation with respect to the mean stroke curve speed, is plotted in the lower diagram line parallel to the speed over time. This is up to a maximum of 10% of the stroke speed, ie the mean speed. The change in the disturbance variable causes a slow speed overlay, for example a triangular shape, as in 6 shown, compared to the stationary speed of the thread guide unit 2 ,

In the 6 The functionality shown is in the form of a control program in the control unit 19 or stored in the frequency converter (application software). To influence the winding process, the parameters disturbance in%, T _up in s and T _down , in s, the path s in mm, the stroke breathing in mm and the cycles, e.g. 4, after which a change in the stroke breathing is carried out, be programmed.

After starting the function, the is specified, for example, by an external machine command, is running The winding process starts automatically up to a stop command.

1

Kitchen sink

2

Thread guide unit

3

wave

4

rotary engine

5

eyelet

6

thread

7

guide rail

8th

guide rod

9

lifting rod

10

clutch

11

drive rod

12

Hollow shaft motor

13

transmission

14

rotor

15

stator

16

power lines

17

frequency converter

18

voltage network

19

control unit

20

external thread

21

inner thread

22

casing

23

spiral spring

24

holding frame

25

attack

26

Second guide rail

27

guide block

28

guide

29

clamp connection

30

retaining groove

31

holding surface

32

sealing element

33

34

bearing sleeve

35

labyrinth seal

36

cavity

37

hollow ring

38

blowing opening

39

connecting line

40

air compressor

Claims (9)

Device for winding a thread ( 6 ) on a spool ( 1 ), with a thread guide unit ( 2 ) to guide the thread ( 6 ), with the thread guide unit ( 2 ) on a guide rail ( 7 ) is axially movable, the thread guide unit ( 2 ) with a drive means ( 12 ) with which the thread guide unit ( 2 ) is axially movable, characterized in that the drive means as a hollow shaft motor ( 12 ) is designed so that the hollow shaft motor ( 12 ) a drive rod ( 11 ) has that the drive rod ( 11 ) can be driven in an alternating linear direction and that the thread guide Ness ( 2 ) with the drive rod ( 11 ) is in operative connection. Device according to claim 1, characterized in that the hollow shaft motor ( 12 ) a frequency converter ( 17 ) with a control unit ( 19 ) has that the hollow shaft motor ( 12 ) Stator windings ( 15 ) and a rotor ( 14 ) that the rotor is operatively connected to the drive rod ( 11 ) indicates that the frequency converter ( 17 ) depending on the control by the control unit ( 19 ) the stator windings ( 15 ) supplied with power in defined time ranges and thereby the speed and direction of movement of the drive rod ( 11 ). Device according to one of claims 1 or 2, characterized in that the thread guide unit ( 2 ) with two spring elements ( 23 ) is coupled that the two spring elements ( 23 ) are arranged in such a way that when the thread guide unit ( 2 ) the spring element in a reversal range of the direction of movement ( 23 ) Kinetic energy of the thread guide unit ( 2 ) and after changing the direction of movement of the thread guide unit ( 2 ) the stored kinetic energy back to the thread guide unit ( 2 ) issues. Device according to one of claims 1 to 3, characterized in that the control unit ( 19 ) is designed in such a way as to reduce the speed of the thread guide unit in the reversal areas before a reversal point of the direction of movement of the thread guide unit. Device according to one of claims 1 to 4, characterized in that the drive rod ( 11 ) via a sealing element ( 32 ) in a housing ( 22 ) of the hollow shaft motor ( 12 ) that the sealing element ( 32 ) causes dust protection. Apparatus according to claim 5, characterized in that the sealing element ( 32 ) in the form of a labyrinth seal ( 35 ) is trained. Apparatus according to claim 5, characterized in that the dust protection as an overpressure device ( 37 . 39 . 40 ) that the overpressure device ( 37 . 39 . 40 ) to the housing ( 22 ) that there is air from the housing ( 22 ) in the area of a sealing gap between the housing ( 22 ) and drive rod ( 11 ) is inflatable. Apparatus according to claim 7, characterized in that the sealing element in the form of a hollow ring ( 37 ) with blow openings ( 38 ) is designed so that the blowing openings ( 38 ) ring-shaped around the drive rod ( 11 ) are arranged, and that the hollow ring ( 37 ) with an air source ( 40 ) connected is. Device according to claim 8, characterized in that the blowing openings ( 38 ) are arranged in a blowing direction in the direction of the drive rod ( 11 ) and at least partially away from the housing ( 22 ) are directed.