EP2199440B1 - Compensation thread tension regulator and creel - Google Patents

Description

The invention relates to a compensation thread tensioner with a thread inlet, a thread outlet, a compensation device between the thread inlet and the thread outlet, which is movable against a compensating force by a thread running from the thread inlet to the thread outlet thread while changing their engagement geometry with the thread, and a reassurance between the thread inlet and the compensation means comprising two contiguous pacers between which the thread passes.

Furthermore, the invention relates to a gate with such a compensation thread tensioner.

The invention will be described below in connection with the warp preparation. However, it is not limited to this, but applicable everywhere where Thread is withdrawn from a spool and should be kept under a predetermined and uniform as possible voltage.

In warp preparation, many threads are simultaneously deducted from a corresponding number of coils, which are arranged in a gate. These many threads are then wound simultaneously on a warping drum, for example, the warping drum of a cone warping machine. In order to keep the structure of the resulting thread winding as evenly as possible, which is essential for subsequent processing, one uses a thread tensioner for each thread. There are different designs for this. The present invention is concerned with a so-called compensation thread tensioner.

In a compensation thread tensioner acts on a compensation device in one direction a compensation force and in the other direction of the force acting on the thread train, so the thread tension. The compensation device changes during its movement their engagement geometry with the thread and thus also the frictional engagement between the thread and the compensation device. If the tension in the thread becomes too great, the friction is reduced so that the thread tension decreases again. If, on the other hand, the thread tension becomes too small, then the friction is increased, so that the thread tension increases again. With this procedure, it is true that an absolutely constant thread tension can not be obtained. However, the thread tension fluctuations are within a tolerable range. In particular, when the thread is removed overhead from a spool, it is very restless when entering the compensation thread tensioner. This also applies if you use a so-called balloon breaker. Also in this case, the thread still tends to vibrate very strongly. A swinging thread has a different frictional engagement with the compensation device than a less strong or even non-oscillating thread. The vibration of the thread thus affects the effect of the compensation device.

It has therefore arranged a calming device behind the thread inlet. This calming device consists in the simplest case of two calming elements which abut each other. If the thread passes between the two calming elements, for example plate-like or plate-like elements, then it raises these two calming elements slightly apart. The pressure exerted by the two calming elements on the thread, but sufficient in many cases, to lead to a sufficient calming of the vibrations.

This procedure has proven itself in principle. Nevertheless, it can be observed that from time to time unpredictable and often even sudden changes in the thread tension occur.

Out DE 196 33 256 C1 a device for adjusting the tension of a thread is known, which is formed by a designed as a balloon limiter reassurance is supplied. A thread brake has a stationary part in the form of a rotatable about the axis plate and a perpendicular to the plane of the part movable part in the form of another plate. Between the parts of the thread is passed through it and it generates a frictional force by means of an actuator. For this purpose, an arrangement is provided which consists of the actuator and a sensor and bends in the direction of the yarn brake. To remove soiling of the thread brake, one plate is lifted off the other plate. The thread then cleans the thread brake.

Out JP O-560 72 872 is a compensation thread tensioner known. A thread passes through a thread inlet and a thread outlet. The thread engages pins in an area. Before the thread passes through the area, it passes an area in which a calming device with two plate-shaped calming elements is provided.

Out DE 617 215 is a disc-thread tensioner known. The thread is fed to a pair of clamping discs of the thread tensioner through an eyelet. The clamping disc pair sits loosely on a sleeve. The bush is seated on a common shaft for a plurality of thread tensioners. A coil spring is provided, by which the contact pressure of the clamping disc pair can be regulated depending on the setting. A lever arm of a thread monitor is provided with a nose. When thread breakage, the nose enters one of the slots of the nose of the sleeve, whereby the respective thread tensioner from the common drive of the plurality of thread tensioners is turned off. In a completely different embodiment, it is also known to put brake discs, regardless of the entrainment by the thread during working inevitably in slow revolutions.

German Utility Model 93 20 081.1 U1 a thread brake for creel is known, wherein a thread is fed through an eyelet. A looping brake is arranged in the yarn flow direction in front of a disk brake. The disk brake has two brake plates, between which a thread is guided. The upper brake plate is pressurized with a lever to brake the thread. The lower plate is supported by a bearing shaft. In a toothing of the bearing shaft engages a toothing of a traversing rod, whereby the lower plate can be rotated.

The invention has for its object to keep the yarn tension as evenly as possible.

This object is achieved in a Kompensationsfadenspanner of the type mentioned in that at least one of the calming elements has a movement drive, which generates a relative movement between the reassurance element and the thread whose direction does not coincide with the direction of movement of the thread, of the calming elements in the direction of gravity is arranged down and this reassurance element is connected to the movement drive, wherein the lower reassurance element entrains the upper calming element by friction.

With the movement drive can be achieved that the reassurance element is moved relative to the yarn and in a direction that does not coincide with the direction of movement of the yarn at least in the contact region between the reassurance element and the thread. It is believed that the changes in yarn tension are due to the fact that the frictional conditions that affect frictional engagement between the yarn and the compensator are influenced by deposits that transfer from the yarn to the settlers. Such a deposit, such as a wear Avivagen, is then taken from time to time by the thread and transported to the compensation device. There it changes the frictional engagement, so that the desired uniformity in the thread tension can no longer be maintained. If one now generates a relative movement between the calming element and the thread whose direction does not coincide with the direction of movement of the thread, then one avoids that such abrasion from the thread can settle in one place on the calming element. Rather, an abrasion, if it should occur because evenly distributed over the calming element or a portion thereof. Surprisingly, one can observe that then overall, a stronger accumulation of the output on the calming element can be observed. Rather, the abrasion then appears with the current thread again be removed, with the removal takes place as evenly as the deposition of the abrasion on the calming element. In any case, one can observe that the thread tension can be kept more uniform over a much longer period of time than before. The movement drive is designed as a rotary drive. This is a relatively simple embodiment of the motion drive. The motion drive puts the calming element in rotation. This rotation can be alternating in two directions of rotation. In a preferred embodiment, however, a single direction of movement is maintained, so that the reassurance element rotates continuously. Of the calming elements one is arranged in the direction of gravity at the bottom and this calming element is connected to the movement drive. With this configuration, it is possible in a simple manner, to put the other calming element in a movement. The other calming element is then arranged at the top in the direction of gravity and is pressed by gravity onto the lower calming element. The lower calming element then takes the upper calming element by friction. Both tranquilizers do not have to rotate at the same speed. However, both calming elements prevent abrasion from attaching to them at a certain position.

Preferably, the settling member located at the bottom is adjacent to a base of the compensating thread tensioner. you can then use the base of the compensator thread tensioner to accommodate the rotary drive. The transmission of drive energy from the motion drive to the reassurance element is not disturbed by the thread.

The movement drive preferably has an engine arranged on the compensation thread tensioner. Such a motor does not have to provide greater drive power. He only has to be able to move the reassuring element associated with him, in particular to turn. Accordingly, such a motor can build relatively small. It is only necessary to transmit a drive power, for example electrical voltage, to the compensation thread tensioner.

In an alternative embodiment it can be provided that the movement drive has a transmission element which is accessible from the outside. In this case, it is possible to provide an external drive, for example, a transmission device, a shaft, a chain drive, a V-belt or the like, and to drive the reassurance element from the outside. This has the particular advantage that you can supply multiple compensation thread tensioner with a single motor, so that the reassurance of all connected compensation thread tensioner can be moved.

Preferably, the compensation device has at least one pin, wherein a contact angle between the thread and the pin can be changed by a movement of the compensation device. The frictional connection Among other things, the angle between the thread and the pin depends on the contact angle, that is, on the wrap angle with which the thread bears against the pin. This wrap angle will usually be significantly less than 180 °. For this reason, the term "contact angle" is preferably used instead of the term "wrap angle". The frictional engagement between the thread and the pin is determined by a non-rotatable pin according to the laws of rope friction. A non-rotatable pin is preferred here.

It is particularly preferred that the pin is part of a group of three pins, over which the thread is U-shaped guidable. So you arrange the three pins so that a pin between the other two pins is arranged. Now, if the two pins on the one hand and a pen on the other hand can be moved relative to each other, then the thread is pulled more or less far into the U. Accordingly, the contact angle between the pins and the thread increases or decreases.

The object is achieved in a gate of the type mentioned above by using a compensation thread tensioner of the type described.

In this case, it is particularly preferred that a plurality of compensation thread tensioners have a common movement drive. Accordingly, one saves, for example, a separate motor for each compensation thread tensioner.

Fig. 1

eine Draufsicht auf einen Kompensationsfaden- spanner und

Fig. 2

eine Schnittansicht einer Beruhigungseinrich- tung.

The invention will be described below with reference to a preferred embodiment in conjunction with a drawing. Herein show:

Fig. 1

a plan view of a compensation thread tensioner and

Fig. 2

a sectional view of a calming device.

A compensation thread tensioner 1 has a base 2 on which the parts described below are arranged. The base 2 can be fixed with a clamping device 3 in a gate, not shown. Appropriately, each coil position in the gate associated with such a compensation thread tensioner.

The compensation thread tensioner 1 has a thread inlet 4 formed by an eyelet, for example, and a thread outlet 5 also formed by an eyelet, for example. Other configurations for thread inlet and thread outlet are possible.

Between the thread inlet 4 and the thread outlet 5 a compensation device 6 is arranged. The compensation device 6 has a lever 7 which can be pivoted about a pivot point 8. The lever 7 is under the action of a spring 9, the force of which can be changed by an adjusting device 10. The spring 9 tries to rotate the lever 7 clockwise about the pivot point 8.

A thread 11, which is guided from the thread inlet 4 to the thread outlet 5, is guided by an eyelet 12 (or another guide device) which is fastened to the lever 7. The train of the thread 11 tries to pivot the lever 7 in a counterclockwise direction against the force of the spring 9 about the pivot point 8.

On the lever 7, a pin 13 is arranged, which can be performed at a pivoting movement of the lever 7 about the pivot point 8 between two pins 14, 15, which are fixed to the base 7.

Further, two pins 16, 17 are fixed to the lever 7, which can be guided past a pin 18 which is fixed to the base 2, when the lever is pivoted clockwise.

In the illustrated position of the lever 7, the thread 11 is pulled by the compensation thread tensioner 1 with only slight contact with the pins 14, 15, 16. Accordingly, said pins 14, 15, 16, 17 cause only a slight frictional engagement with the thread 11 and accordingly slow it down only slightly.

If, however, in a portion of the thread 11, which is upstream of the compensation device 6, only a small tension is exerted on the thread, then pulls the spring 9, the lever 7 so that a first U-shaped course of the thread 11 forms around the pin 14, the pin 13 and the pin 15, and a second U-shaped course around the pins 16, 18 and the pin 17. The pins 13-18 are non-rotatably on the lever. 7 or held on the base 2, so that the thread 11 with these pins 13-18 then has a certain frictional engagement, which leads to an increase in the yarn tension at the yarn outlet 5.

Between the thread inlet 4 and the compensation device 6, a calming device 19 is arranged. The calming device 19 has, as in Fig. 2 can be seen, a lower calming element 20 and an upper calming element 21. The two calming elements 20, 21 are under the action of gravity to each other. The thread 11 is guided between the two calming elements 20, 21 and lifts them apart, at least where the thread 11 runs along. The two calming elements 20, 21 are formed as plates, which are each provided with a bevel 22 on their mutually facing edge regions in order to facilitate the threading of the thread 11. The two calming elements 20, 21 are rotatably mounted on a common axis 23. An upward movement is limited by a stop 24. The stopper 24 is as shown in Fig. 1 can be seen, laterally adjacent to the calming elements 20, 21 connected by a screw 25 to the base 2. The stopper 24 simultaneously carries the axis 23rd

The lower gravity element 20, which is also arranged adjacent to the base 2 in the direction of gravity, is mounted on a carrier 26 which is rotatable on an axis 27 which is likewise fixed in the base 2.

The carrier 26 is non-rotatably connected to a gear 28 which is in engagement with a further gear 29 which is driven by a motor 30 shown only schematically.

In an alternative embodiment, it may be provided that the gear 28 is arranged at a different position and with a drive shaft 31 is engaged, which is accessible from the outside.

If, in operation, the thread 11 runs from the thread inlet 4 to the thread outlet 5 and is provided with the desired tension by the compensation device 6, then the two settling elements 20, 21 rotate about the axis 23. This rotation takes place directly for the lower settling element 20 by the drive 30, 31. The upper calming element 21 is entrained by friction from the lower calming element 20.

Since the thread 11 in this movement of the calming elements 20, 21 continuously applied to a different position on the calming elements 20, 21, it is excluded that forms a deposit at a position of the calming elements 20, 21, which then later uncontrolled by the thread 11 could be carried away. If something of the thread 11 dissolves, for example, a Avivageabrieb, then this abrasion spreads evenly on the contact surfaces on the reassurance elements 20, 21 and is taken from there as equally by the thread 11 again. Larger changes in the frictional engagement of the thread 11 with the pins 13-18 can be prevented.

If one uses a shaft 31 for driving the lower contact device 20, then one can provide a common motion drive for a plurality of compensation thread tensioners 1 on a gate. Also, such a common motion drive can be dimensioned with a relatively low power, since the moment necessary to drive a single reassurance means 20 is comparatively small.

Claims (9)

1. Compensating thread tensioner (1) with a thread run-in (4), with a thread run-out (5), with a compensating device (6) between the thread run-in (4) and the thread run-out (5), which compensating device is movable counter to a compensating force by a thread (11) running from the thread run-in (4) to the thread run-out (5) and at the same time changes its geometry of engagement with the thread (11), and with a steadying device (19) between the thread run-in (4) and the compensating device (6), which steadying device has two steadying elements (20, 21) which bear one against the other and between which the thread (11) runs, characterized in that at least one of the steadying elements (20, 21) has a movement drive (30, 31) which generates a relative movement between the steadying element (20,21) and the thread (11), the direction of which relative movement does not coincide with the direction of movement of the thread (11), one of the steadying elements (20, 21) being arranged at the bottom in the direction of gravity, and this steadying element (20) being connected to the movement drive (30, 31), the lower steadying element (20) driving the upper steadying element (21) by means of friction.
2. Compensating thread tensioner according to Claim 1, characterized in that the movement drive (30, 31) is designed as a rotary drive.
3. Compensating thread tensioner according to Claim 1 or 2, characterized in that the lower steadying element (20) is adjacent to a base (2) of the compensating thread tensioner (1).
4. Compensating thread tensioner according to one of Claims 1 to 3, characterized in that the movement drive has a motor (30) arranged on the compensating thread tensioner.
5. Compensating thread tensioner according to one of Claims 1 to 4, characterized in that the movement drive has a gear element (31) which is accessible from outside.
6. Compensating thread tensioner according to one of Claims 1 to 5, characterized in that the compensating device (6) has at least one pin (13-18), a contact angle between the thread (11) and the pin (13-18) being variable by means of a movement of the compensating device (6).
7. Compensating thread tensioner according to Claim 6, characterized in that the pin (13, 18) is a component of a group of three pins (13-15; 16-18), via which the thread (11) can be guided in a U-shaped manner.
8. Creel having a compensating thread tensioner (1) according to one of Claims 1 to 7.
9. Creel according to Claim 8, characterized in that a plurality of compensating thread tensioners (1) at least according to Claim 5 have one common movement drive.

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