EP1081259A1 - Apparatus controlling the air supply to the jet of an air intermingling device - Google Patents

Abstract

The system to control the air feed to the jets (2,2',2) of a pneumatic eddy appts. (V), where at least two yarns (E,F) are given a continuous eddy action with a twist imposed on them by the jets, has a valve (10) to control the air flow according to at least one bobbin winding parameter. At least one bobbin winding parameter includes the yarn movement speed, the bobbin dia., the bobbin weight or the length of the yarn (U) to be wound. The valve (10) is operated by a motor to control the vol. flow, and a sensor monitors the setting for the max. vol. flow. The valve has a valve slide, mounted to the motor axis. The valve drive is a step motor, and the setting for the max. vol. flow is defined by a given number of motor steps. The sensor is formed by a proximity switch. Using the yarn speed as a control parameter, the air flow is throttled on a slow yarn speed. Where the control parameter is the bobbin dia., the bobbin weight, or the length of yarn (U) to be wound, the air flow is throttled on low parameter values. The air flow has a continuous or stepped control.

Description

The invention is in the field of connecting a continuous filament to one or more Staple fiber yarns or two or more staple fiber yarns by air turbulence. Such connections of yarns, some of which also have other names, such as Bubbles, or air vortexing, are known to be more elastic for making Yarns are used, the possible uses of which have increased significantly recently (e.g. Underwear, sportswear, outerwear, shirts, sweaters). Elastic yarns are used in increasingly processed as composite yarns, in the form of wrapping yarns (wrapping twists), Double wire twisting and wound yarns (core yarns).

With the exception of the AC process (Air-covering), the elastomer yarn is used in all other processes wound, twisted or braided. Although this mechanical process is very are slow, it has become much faster and cheaper in terms of production costs So far, AC procedures have only been able to be enforced in some areas. So far it has been exclusive limited to filament yarns and could not be used for pure staple yarns.

In the classic AC process, the filament yarn is aerodynamically interlaced a kind of loop yarn with the elastane. The swirled yarn shows large volume differences, the elastane component being connected to the filament yarn only in a punctiform manner and the elastane is partially visible. On the other hand, the wrapping yarn is the elastane component largely enveloped and practically invisible depending on the selected expansion factor, and the twisted yarn shows a relatively uniform structure.

It has recently been proposed to enable the AC process to be applied to staple yarns (European patent application No. 99 106 310.8), for swirling a group of three nozzles arranged one behind the other, in the two outer nozzles a twist of the yarn in one nozzle and a twist in the inner nozzle the other direction. The continuous swirling enables the processing of Stacking yarns and the three nozzle arrangement provide a relatively stable connection between the yarns, with the middle nozzle used to fix the twists in the yarn.

In order to increase the economy of the AC process, the European patent application No. 99 109 917.7 proposed to provide only two nozzles and in the direction of the yarn to arrange a swirl stopper in front of the first and after the second nozzle and between them. With the swirl generated by compressed air, the ends of the staple fibers become binders used by wrapping the protruding ends of the flax fibers around the entire continuous elastane thread or around the whole staple fiber yarn, which makes the twisted yarn one shows uniform structure and the wrapping yarn formed has a high stability and very well processed, for example twisted, twisted (counter wire or on wire) or can be knitted.

In the preliminary stage of twisting or turning, this device serves as an accompanying function for the Compartments to form the elastic yarn with one or more staple yarns and allows the perfect "twisting" of elastic yarns made of pure cotton on double-wire machines, which was previously not possible.

The present invention relates to a device for controlling the air supply to the Nozzles of an air swirling device for the continuous swirling of at least two yarns, which are twisted in the nozzles.

The aim of the invention is to provide the known devices with regard to the quality of what is produced with them Yarns and in terms of minimizing air consumption can be further improved.

This object is achieved according to the invention by a valve which has means for controlling the Has air supply depending on at least one winding parameter. This at least a winding parameter is preferably the yarn speed, the bobbin diameter, the Bobbin weight or the length of the wound yarn.

The control of the air supply depending on the yarn speed is for the quality of the yarn produced is essential because of the maximum yarn speed Air energy supplied destroys or at least damages a slow-running yarn would. It is therefore important that the air supply does not suddenly stop when the yarn starts switched on at full strength, and that it is slowly reduced when running or stopping.

The control of the air supply depending on the coil diameter and the coil weight or the yarn length enables control of air consumption and yarn quality about the size of the coil. As with certain textile follow-up processes for the yarn withdrawal from With a large bobbin diameter, a maximum yarn quality is required, which can be quite smaller with a smaller coil diameter, one becomes with a large coil diameter Supply more air energy than smaller ones. This has the additional advantage that the maximum air consumption and thus also the maximum energy costs only with large Coil diameters occur, whereas with smaller coil diameters energy costs can be saved. A large coil diameter corresponds to a large coil weight and a large length of the spooled yarn.

Another preferred embodiment of the device according to the invention is characterized in that that the valve is a motor-driven element for controlling the volume flow and a sensor for monitoring the volume flow corresponding to the maximum Position of this organ.

According to a further preferred embodiment of the device according to the invention said organ can be driven by a stepper motor. It is preferably the maximum Volume flow corresponding position of the organ a certain number of steps of the Stepper motor assigned.

Fig. 1

eine schematische Darstellung einer Vorrichtung zur Luftverwirbelung eines Stapelgarns mit Elastan; und

Fig. 2

ein Detail von Fig. 1.

The invention is explained in more detail below on the basis of an exemplary embodiment illustrated in the drawings; it shows:

Fig. 1

a schematic representation of a device for air swirling a staple yarn with elastane; and

Fig. 2

a detail of Fig. 1st

und mit an der Kammer fixierten Lagerarmen (nicht dargestellt) mit Garnführungsrollen 3 und Umlenkrollen 4. Die Kammer 1 weist ausserdem zwei Druckluftanschlüsse 5 sowie eine Druckluftzuleitung 6 auf. Die Vorrichtung V ist zum Einbau in eine AC(Air-Covering)-Maschine vorgesehen, in welcher der Vorrichtung V mindestens ein Stapelgarn F und ein Elastangarn E zur Verwirbelung zugeliefert werden und das bei der Verwirbelung entstandene Kombinationsgarn U von der Vorrichtung V zu einer Aufwicklung AW geführt ist. Die Fadenlaufrichtung ist mit einem Pfeil A bezeichnet.The swirling device V shown in FIG. 1 essentially consists of a box-shaped chamber 1 serving as an air reservoir, with three nozzles 2, 2 'and 2 mounted on the chamber and supplied with compressed air from it

and with bearing arms fixed to the chamber (not shown) with yarn guide rollers 3 and deflection rollers 4. The chamber 1 also has two compressed air connections 5 and a compressed air supply line 6. The device V is intended for installation in an AC (air-covering) machine, in which the device V is supplied with at least one staple yarn F and an elastane yarn E for interlacing and the combination yarn U formed during interlacing from the device V for a winding AW is led. The direction of the thread is indicated by an arrow A.

As indicated in the drawing, both the staple yarn F and the elastane E from a delivery unit 7 or 8, the delivery unit 8 for the elastane to the side of the thread path arranged and a deflection roller 9 is provided for the elastane E in the thread path. It is possible to dispense with the delivery mechanisms 7 and 8, but in this case in the direction of the thread A a sufficiently long thread inlet must be provided in front of the device V, which is necessary to compensate for voltage fluctuations.

The nozzles 2, 2 'and 2 , by means of which the staple yarn F is rotated around the elastane E, lie on a common axis and are designed such that the two outer nozzles 2 and 2 a rotation of the staple yarn in one direction and through the central nozzle 2 'in the other direction. The yarn preferably receives a Z twist through the middle nozzle 2 'and through the outer nozzles 2 and 2 an S turn. The nozzles 2, 2 'and 2 are equally spaced from one another, the distance from the center of the nozzle to the center of the nozzle being approximately 40 to 50 mm.

The compressed air connections 5 of the chamber 1 are arranged symmetrically and lie in the middle between the nozzles 2, 2 'and 2', 2 , so that the pressure and flow conditions prevail in the area of the feed lines to the nozzles and that all the nozzles have a uniform air throughput. The outside of the outer nozzles 2 and 2 arranged yarn guide rollers 3 are against the axis of the nozzles 2, 2 'and 2nd offset so that the yarns F and E and the combination yarn U easily out of the axis of the nozzles 2, 2 'and 2 are deflected and not only lie tangentially on the yarn guide rollers 3, but also wrap them around at a certain angle. This ensures that the outer nozzles 2 and 2 caused yarn rotation, which runs from these nozzles to the yarn guide rollers 3, is blocked on the yarn guide rollers and can not continue.

The distance between the outer nozzles 2, 2 and the yarn guide rollers 3 is half the distance between the nozzles. The size of this distance has a significant influence on the quality of the interlacing and thus on the quality of the combination yarn. The lateral displacement of the yarn guide rollers 3 relative to the nozzle axis is relatively small and is a few, preferably about 2 to 10 mm. This offset enables a higher thread speed. Each yarn guide roller 3 is assigned a deflection roller 4, which is arranged offset to the axis of the nozzles in the opposite direction. The deflection rollers 4 are adjustably attached to their support for setting the thread tension. Both the yarn guide rollers 3 and the deflection rollers 4 are ball-bearing.

und 2 in Abhängigkeit von einem Spulparameter erfolgt, wobei dieser Spulparameter die Garngeschwindigkeit, der Spulendurchmesser, das Spulengewicht oder die Länge des aufgespulten Garns sein kann.The compressed air supply line 6 contains a valve 10, by means of which the air supply is controlled in the chamber 1 and thus to the nozzles 2, 2

and 2 takes place as a function of a winding parameter, which winding parameter can be the yarn speed, the bobbin diameter, the bobbin weight or the length of the wound yarn.

With the compressed air from nozzles 2, 2 and 2 a certain section of air energy which is required for the desired yarn quality is supplied to a section of yarn per unit of time, the air energy supplied per unit of time being matched to the maximum yarn speed of the device V. If the yarn speed is below the maximum value, which is the case every time the device is started and switched off, each yarn section receives significantly more air energy per unit of time, as a result of which the yarn can be destroyed or at least damaged or its structure negatively influenced. For this reason, with regard to the quality of the yarn and the trouble-free operation of the device V, it is important that the air supply is reduced accordingly at low yarn speeds. This is achieved in that the valve controls the air supply as a function of the yarn speed.

The yarn quality is, among other things, for the trouble-free withdrawal of the yarn from the rewinder AW manufactured spool of essential in the subsequent processing Influence, which influence increases with increasing coil diameter. Because with one given yarn speed the yarn quality increases with increasing air supply (up to a maximum value, above which it then decreases again), it is important, at least in the area of large bobbin diameters, the yarn with the correspondingly large air energy act upon. On the other hand, since compressed air is relatively expensive, it is for economic reasons advantageous, the air supply in the area of small bobbin diameter, where the influence of yarn quality on the trigger properties is not so strong, to keep it lower and therefore the Reduce energy costs. This is achieved in that the valve 10 controls the air supply depending on the coil diameter or the coil weight or the spooled yarn length takes place.

2, the valve 10, which is a type of throttle valve, consists essentially of a valve body 11 with a connection piece 12, an outlet opening 13 with a connection 14 for compressed air supply line 6 to chamber 1 (FIG. 1) and with a rotatable valve slide 15. The latter is on the axis of an engine 16 flanged to the valve body 11 attached. The valve slide 15 has on its end face facing the connecting piece in the level of the outlet opening 13 on a helical or spiral gradation 17, which extends over a part of the circumference of the valve slide of preferably about 270 °. The valve slide 15 thus has a stepped peripheral part in the region of the outlet opening with increasing depth and a cylindrical peripheral part. If the outlet opening 13 is covered by the cylindrical peripheral part, the valve is closed when the stepped peripheral part 17 is in the region of the outlet opening 13, the valve is open, wherein the air flow rate is dependent on the rotary position of the valve slide 15.

The motor 16 is preferably a stepper motor, so that between the number of steps of the Motor 16 and the rotational position of the valve spool 15 there is a clear connection. In particular, it is known how many steps of the motor 16 from the closed position until valve 10 is fully opened. The air-covering machine, in which the device 1 is installed contains a control with a computer, which All relevant winding and machine parameters are constantly fed from various sensors are. The computer, which thus the yarn speed, the bobbin diameter, the bobbin weight, knows the spooled yarn length, etc., provides 15 control signals for adjustment to the motor of the valve slide 15 and thus to control the air flow corresponding to the called winding parameters. This control can be based on one or more of the mentioned winding parameters take place.

The valve 10 is equipped with a sensor S for monitoring the position of the valve slide 15 equipped when the valve is fully opened. The sensor S is through a proximity switch formed, for example, from a fixed in the valve slide 15 encoder and consists of a fixedly arranged relative to the valve slide 15 transducer.

2, the encoder consists of a plate 18 made of magnetic material, which is embedded in the valve spool 15 near the axis of the motor 16, and from a metallic screw 19 with which the valve slide 15 is fixed on the motor axis; between Plate 18 and screw 19 is a magnetic flux. The sensor 20 is in the Level of the screw 19 arranged and equipped to measure this magnetic flux. The mutual position of screw 19 and sensor 20 is selected so that the When the valve is completely open, screw 19 lies directly in front of the sensor 20, which is in this Position registered the maximum magnetic field strength. Since it is known how many steps of the motor 16 are required from the closed position to reaching this position, simple control of the open position of the valve is possible.

The description of the valve 10 in connection with the device shown in FIG. 1 For interlacing air with at least one staple yarn with elastane using three in a row Arranged nozzles is not a limitation of the application of valve 10 to this type of machine to understand. The valve 10 is rather versatile and can be used in any way used by air-covering machine and also on air texturing and similar machines become.

Claims (10)

Device for controlling the air supply to the nozzles (2, 2

, 2nd

) an air intermingling device (V) for the continuous intermingling of at least two yarns (E, F), which in the nozzles (2, 2 , 2nd ) a swirl is applied, characterized by a valve (10) which has means for controlling the air supply as a function of at least one winding parameter. Device according to claim 1, characterized in that the at least one winding parameter the yarn speed, the bobbin diameter, the bobbin weight or the Length of the wound yarn (U) is. Device according to claim 2, characterized in that the valve (10) is a motor drivable organ for the control of the volume flow and a sensor (S) for the Monitoring the position of this organ corresponding to the maximum volume flow having. Device according to claim 3, characterized in that said organ by a rotatable valve spool (15) and that this on the axis of an engine (16) is attached. Device according to claim 4, characterized in that the motor (16) is a stepper motor and that the position of the valve slide corresponding to the maximum volume flow (15) corresponds to a defined number of steps of the stepper motor. Device according to claim 4 or 5, characterized in that said sensor (S) is formed by a proximity switch (18, 19, 20). Device according to one of claims 2 to 7, characterized in that when controlled the air supply as a function of the yarn speed at lower yarn speeds the air supply is restricted. Device according to one of claims 2 to 7, characterized in that when controlled the air supply depending on the coil diameter, the coil weight or the length of the wound yarn (U) with smaller values of these parameters a throttling the air supply takes place. Device according to one of claims 1 to 8, characterized in that a continuous Air supply is controlled. Device according to one of claims 1 to 8, characterized in that a stepwise Air supply is controlled.

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