EP1126058A2 - Device for driving rotating components in an open-end spinning machine - Google Patents

Abstract

The drive (2) for a rotating component (7), at an open-end spinning station, is a single motor drive system (2). The single motor drive is a step motor (2), to power a friction roller (3) which bears against the bobbin (7) to rotate it by friction contact directly or indirectly. Or the rotating component is a yarn take-off roller, between the spinner and the bobbin winder, with a single drive for a group of take-off rollers which covers only a small part of the workstations of the spinning machine. At the bobbin drive, with a friction roller (3), the acceleration phase on splicing increases the pressure between the friction roller (3) and the bobbin (7). The friction roller (3) has a surface character and/or structure to give the maximum force transfer to the bobbin. The diameter of the friction roller (3) is set so that, for the single motor drive system (2), an optimum combination is achieved of rotary speed and torque. When the wound bobbin (7) has reached the required diameter or the required yarn length has been wound, the bobbin (7) is braked by the motor drive (2). The single motor drive (2) has a selected direction of rotation. The rotary speed of the bobbin (7) is set according to the yarn tension. The yarn tension is registered according to the actual position of the yarn laying lever (5). The bobbin (7) rotary speed is controlled by the level of power fed to the drive motor or by an electronic control (6). A sensor (9) monitors the rotary speed of the bobbin (7) and/or its diameter.

Description

The invention is in the field of open-end spinning machines (hereinafter referred to as OE spinning machines designated). These have a variety of jobs, which in the lower Speed range thread speeds up to around 250 m / min (OE rotor spinning machines) and in the upper speed range, thread speeds of up to around 500 m / min (OE air spinning and OE friction spinning machines). The OE spinning machines are known as Slitting machines with a central drive and drive rods for the work stations educated. Each work station is equipped with a spinning unit and a winding device equipped. In the spinning units, the sliver placed in spinning cans becomes threads spun, which are wound on the winding devices to form cross-wound bobbins. Between take-off rollers are arranged in each spinning unit and winding device.

In the event of a thread break, the thread end is raised using a thread end preparation prepared for an attachment process. So that the piecing in the spun yarn is not an error is evident, this must be done under similar conditions, i.e. with a similar delivery speed, similar yarn count and twist as the normal yarn are produced. Usually the piecing speed is around 60% to 80% of the normal delivery speed. So that the spun thread remains constant during the run-up of the swirl element Receives thickness and twist, fiber feed and thread take-off must be equal run up like the speed-generating organ.

The acceleration of the thread spools, in particular large thread spools with a corresponding one Moment of inertia places high demands, especially at high delivery speeds to the assigned drive. In a piecing device described in DE-A-196 36 395 is used to repair a thread break by means of a spinning station Piecing carriage first unwinds a defined length of thread from the package in a between the thread take-off device and the winding drive of the piecing carriage arranged thread store temporarily. Then the winding drive the acceleration process of the starting coil started long before the piecing time, that the package is already a predetermined one at the time of thread take-off Has target winding speed. When this target winding speed is reached the thread store is then emptied again.

With this device, the individual processes must match exactly, otherwise when they are reached the target winding speed either the thread store is not completely emptied or the thread length stored in the thread memory would not be sufficient, which is both Thread breakage would result. In addition, there must be a precisely specified air flow in the thread store are generated so that the stored thread length can run in an orderly manner and none Loops are formed. In addition, for the so-called feedback, the controlled unwinding to find the thread end, an additional drive is necessary is.

In addition, in the known devices it is necessary in all cases to read the coil a thread break by a mechanism, for example a so-called lifting mechanism, to decouple from their drive so that they do not continue to drive after the thread break and rotates. This would cause the surface of the coil to become matted, resulting in a Quality reduction would result, and it would also be significant to search for the thread end difficult.

The take-off rollers arranged between the spinning unit and the winding unit are also driven by the central drive mentioned. The problem here is that the power transmission on the individual working positions by long bars not only very expensive and places considerable demands on the installation of such an OE spinning machine (leveling of the floor and the like), but that the machines in terms of the possible Coil structure are very inflexible.

The invention now aims to provide a device for driving rotatable members of an OE spinning machine are indicated, which are characterized by a simple mechanical structure and distinguishes a simple control, and which does not require an additional drive. Furthermore should easily set up an OE spinning machine equipped with such a drive and be as flexible as possible in the coil structure and there should be the possibility of individual coordination the speed of the rotatable organs of the individual workplaces or work positions consist.

The object is achieved according to the invention in that for each of the named Organs a single motor drive is provided.

A first preferred embodiment of the device according to the invention is characterized in that that the rotatable organs can be driven directly or indirectly via friction rollers Coils are formed.

A second preferred embodiment of the device according to the invention is characterized in that that the rotatable organs through in the thread path between the spinning unit and the winding unit arranged take-off rollers are formed. Preferred is preferred in both Embodiments of the single motor formed by a stepper motor.

The solution according to the invention is thus used to drive the coils and / or the take-off rollers a single motor drive proposed. Such a single drive has the coil drive the advantage that in the event of a thread break, the winding unit in question is switched off and at Spinning can easily be started again without a thread store or a lifting mechanism would be required. In addition, the coil for energy recovery without any additional drive can be driven backwards.

With the take-off rollers, the single drive has the advantage that simple individual adjustment the pulling speed is possible that the cumbersome long drive rods no longer exist, and that the OE spinning machines in question are set up without additional effort can.

A third preferred embodiment of the device according to the invention is characterized in that that a single drive is provided for each group of take-off rolls, such a group with a common drive each only a small part of the Includes jobs of the spinning machine.

A fourth preferred embodiment is characterized in that the coil drive an increase of the contact pressure in the acceleration phase during piecing by a friction roller between the spool and the roller.

Another preferred embodiment of the device according to the invention is characterized in that that the friction roller has a surface quality suitable for maximum power transmission and / or has surface structure.

Fig.1

eine schematische Darstellung einer Spulstelle einer OE-Spinnmaschine,

Fig. 2

eines schematische Darstellung eines Fadenspanners; und

Fig. 3a-3d

Diagramme zur Funktionserläuterung.

The invention is explained in more detail below with the aid of exemplary embodiments and the drawings; it shows:

Fig. 1

1 shows a schematic illustration of a winding unit of an OE spinning machine,

Fig. 2

a schematic representation of a thread tensioner; and

3a-3d

Diagrams to explain the functions.

The winding unit of an OE spinning machine shown in FIG. 1 is an autonomous winding head module trained with individual drives for the bobbin to be manufactured and thread laying. The As shown, the winding head module consists of an angled support 1, on which essentially a drive 2 for a friction roller 3, a drive 4 for a thread laying lever 5 and a winding head controller 6 are arranged. The winding head control 6 is connected to a not shown Power supply connected. This winding head module forms a compact unit, simply on the intended textile machine, for example an OE spinning machine can be assembled. The carrier 1 can be designed in such a way that in addition to its function as a carrier of the individual parts of the winding head module, additional functions such as Cooling, takes over.

The friction roller 3 is provided for the non-positive drive of a coil 7, which to this Purpose rests on the jacket of the friction roller 3. The friction roller drive 2 is preferably so trained that his motor integrated into the hollow body of the distribution roller 3 and the distribution roller is fixed on the motor shaft, resulting in a very compact length of the friction roller drive system + Friction roller leads. In addition, for the friction roller 3 because of its fixation on the motor shaft no own storage required, which leads to cost savings. On Another advantage of this design is that the friction roller 3 because of the free accessibility of the winding head module from one side, as shown on the right, simply to assemble. The motor of the friction roller drive 2 is preferably a stepper motor.

Basically, a motor-driven one can be used to drive the coil 7 instead of the friction roller 3 Spindle are used, on which the coil is attached. Such a direct drive is advantageous at high and very high winding speeds, whereas at lower ones Winding speeds, such as are the rule on rotor spinning machines, for example Advantages of the roller drive predominate. These advantages are mainly deeper Cost and in that the inertia ratio of the drive to the spool in the friction roller is significantly smaller than with direct drive, so that motors with lower power are used can be. Another advantage results from the use of a stepper motor for the friction roller drive because the stepper motor compared to a brushless asynchronous motor has a significantly higher torque at lower speeds.

When dimensioning the friction roller, it is important to ensure that its diameter is as possible is kept small. Because then there is a reduction between the friction roller 3 and the coil 7, which affects the moment of inertia acting on the motor of the friction roller drive 2 has a favorable effect. The friction roller drive 2 and the coil 7 each have a speed sensor 8 or 9 assigned. Both speed sensors 8 and 9 are connected to the winding head control 6 and deliver the current speed data, from which the thread length and the coil diameter can be calculated. The latter is especially for the realization of winding laws dependent on the coil diameter (wild winding, precision winding, step precision winding) required.

The thread laying lever 5 sits on an axis of rotation 10 and points at it from the axis of rotation 10 distal end of a thread guide slot 11. The thread to be wound (not shown) runs from a supply spool or from a manufacturing or machining process via an arc plate 12 forming a control curve, which is indicated in the drawing by its contour is through the thread guide slot 11 to the bobbin 7. The mutual position of the thread laying lever 5 and arch plate 12 and the length of the thread guide slot are chosen so that the thread during the movement of the thread laying lever 5 the bottom of the thread guide slot 11 not touched. This ensures that the thread path from the arch plate 12 up to the coil 7 always the same, regardless of the diameter of the coil, Has geometry. Instead of the curved plate 12, a straight guide rail can also be used become.

The thread laying lever 5 performs an oscillating, back and forth movement during operation and moves according to the laws of thread winding within a swivel angle of about 30 ° to 60 °. The axis of rotation carrying the thread laying lever 5 10 is led into the interior of a dust-tightly closed housing (not shown), in which sits on the axis of rotation a toothed angle segment 13, which over a tooth sweater 14 of the laying drive 4 is driven. The motor of the laying drive 4 is preferred formed by a stepper motor. Regarding the dust-tight sealed housing refer to European patent application No. 99 107 229.9.

The angle segment 13 and the tooth sweater 14 have different diameters, so that there is a reduction ratio between i = 2 and i = 20 between the tooth sweater 14 mounted on the motor axis and the angle segment 13. As a result, the moments of inertia, which are largely caused by the thread laying lever 5, only act on the motor shaft by a factor of 1 / i ² and an inexpensive drive motor with relatively low power can be used. At the same time, when using a stepping motor for the laying drive 4, the incremental movement (resolution accuracy) of the thread laying lever 5 improves by the reduction factor i.

Reference number 15 denotes a mechanical stop for the thread laying lever 5, which serves as a reference point for the position of the thread laying lever 5. This reference point defines the starting position of the thread laying lever 5, relative to that for the Each stroke required steps of the motor of the laying drive formed by a stepper motor 4 can be defined. Referencing must be carried out each time the Spool head module are made, as well whenever the laying unit is de-energized or the stepper motor has lost its position.

As an option, the winding head module can pass through the thread laying lever 5 the stroke-detecting sensor are supplemented (see EP-A-0 453 622) by the length of the Monitor hubs from the center of the stroke to the reversal points and correct any errors To allow errors in the lifting movement. This sensor can, for example, by a arranged on the angular segment 13 and a magnetic transducer assigned to it stationary scanner be formed. When using a stepper motor, however, it is one Monitoring not required, because at most steps can be lost, the programmed one Hub would not be fully reached. If such errors are not corrected the system can be operated in open loop mode. That means that System as an inexpensive controller and not as a much more expensive feedback control system is executed.

This is one reason for the possibility of being able to operate the system in open loop mode the described reduction of the moment of inertia acting on the motor shaft. Because this Reduction has the consequence that the thread laying is mechanically very robust, so that in Usually the programmed stroke lengths are also adhered to and no deviations occur. It is only recommended for units for higher and highest speeds that System to be implemented as a feedback control system. In this case, it is advantageous on the Motor shaft of the motor of the drive 4 to provide an angle sensor based on the angular position the motor shaft to determine the stroke position of the thread laying lever 5 and in the event of deviations readjust the motor accordingly between the actual and setpoint. For even higher ones Speeds can save energy to affect deceleration and acceleration of the thread laying lever 5 can be provided in its reversal of movement. In terms of Energy storage of this type is referred to EP-A-0 838 422.

The angle segment 13 can be designed as a gear segment and with the tooth puller 14 in direct intervention. For reasons of wear and damping, however, it is advantageous that Angle segment 13 not to interlock, but to equip with a toothed belt that with the tooth sweater 14 is engaged. The toothed belt is preferably not endless but as Belt piece formed, the ends of which are attached to the angle segment 13. With very few Double strokes of the thread laying lever 5 per minute, which is the case with parallel winders, for example if this is the case, a directly toothed angle segment 13 can also be used.

The speed of the stepping motor of the laying drive 4 is determined by the winding head controller 6 changed over the stroke in such a way that a constant thread speed parallel to the axis the bobbin 7 also results when the thread laying lever 5 with its with the thread guide slot 11 provided end describes a circular path. The geometry of the arch plate 12 can be chosen so that at a constant speed of the thread laying drive 4 a constant Speed component of the thread parallel to the bobbin axis results.

The laying drive 4 can also be arranged outside the dustproof housing. To For this purpose, the shaft of the toothpull 14 would pierce a housing wall, the Passage opening would be sealed with an O-ring. The arrangement of the laying drive 4 outside the housing has the advantage that the engine heat is better dissipated can. The control electronics can also be arranged outside the housing, the Sensor for the passage of the thread laying lever 5 through the center of the stroke through the housing wall works, which when selecting a suitable sensor, for example a Hall effect sensor, and a plastic case is not a problem. The winding head modules of the OE spinning machine are connected via a bus 16 to a bus controller 17, which is the interface forms between the winding head controls 6 and a host computer. The bus controller 17 has one or more control terminals 18 for input and output of data.

• Alle bekannten Wickelgesetze, wie wilde Wicklung mit Bildverhütung, Präzisionswicklung und Stufenpräzisionswicklung.
• Eine höhere Spulendichte infolge von Präzisionswicklung (geschlossenes Windungsverhältnis) oder Stufenpräzisionswicklung (geschlossenes Windungsverhältnis).
• Eine konstantere Spulendichte für Färbespulen durch Präzisionswicklung (offenes Windungsverhältnis) oder Stufenpräzisionswicklung (offenes Windungsverhältnis).
• Einen in Grenzen frei wählbaren Spulenhub, insbesondere frei wählbare Spulenhöhe, Hubvariation (Reduzierung der Spulenkantenhärte), Hubverkürzung (Reduzierung von Fallfäden), Hubverlegung (Reduzierung der Spulenkantenhärte).
• Eine frei wählbare Spulengeometrie (zylindrische, konische, bikonische Spulen).
• Bildung einer Fadenreservewicklung.
• Freie Positionierung einer Endwulstwicklung innerhalb der Spule.
• Exakte Fadenlängenmessung.
• Kompensation der Schlepplänge.

The use of the described winding head module with the electronically controlled thread laying together with the distribution roller, whereby the thread placement and distribution roller are individually driven, enables among other things:

• All known winding laws, such as wild winding with image prevention, precision winding and step precision winding.
• A higher coil density due to precision winding (closed turns ratio) or step precision winding (closed turns ratio).
• A more constant bobbin density for dyeing bobbins through precision winding (open turns ratio) or step precision winding (open turns ratio).
• A freely selectable spool stroke within limits, in particular freely selectable spool height, stroke variation (reduction of spool edge hardness), stroke shortening (reduction of falling threads), stroke relocation (reduction of spool edge hardness).
• A freely selectable coil geometry (cylindrical, conical, biconical coils).
• Formation of a thread reserve winding.
• Free positioning of a final bead winding within the coil.
• Exact thread length measurement.
• Compensation of the drag length.

Another advantage of the single drive of the coil 7 is that the coil after reaching the desired diameter or the set thread length through the single drive is braked gently and no special additional mechanism for lifting the bobbin is required.

The coil 7 is wound on a spool sleeve which is attached to a spindle, which in turn connected on a lever arm rotatably connected to the machine frame is. To maintain a constant contact pressure between coil 7 and friction roller 3 are pressing means acting between the winding head module and the lever arm mentioned (not shown) provided. The pressing means can be designed so that for minimization the duration of the acceleration phase during acceleration when piecing the contact pressure the coil 7 increased on the friction roller 3, thereby improving the power transmission becomes. Alternatively or additionally, an improvement in the power transmission can be achieved by appropriate The choice and design of the surface of the friction roller 3 take place, for example, by this a corrugated or with longitudinal grooves or possibly a thread-like one Has structure.

So that the thread can be wound with a constant tension after a piecing process 2, a thread tensioner may be provided. This is adjustable by means of a crosswise to the thread F. Roll 19 is formed, which between the provided in the thread run after the spinning unit Draw-off rollers 20 and a thread guide arranged directly in front of the thread laying lever 5 21 (see arch plate 12, Fig. 1) is arranged. The thread tensioner 19 is located during the spinning process in the swivel position shown in dashed lines outside the path of the thread F and is set to the position drawn with full lines pivoted.

The described in connection with the drive of the friction roller 3 of the winding head module (Fig. 1) Single drive can also be used with the take-off rollers 20, which were previously used for the entire spinning machine are driven by a central drive through long rods. This single drive, which is essentially the drive 2 of the friction roller 3 of the winding head module is preferably also formed by a stepper motor. The single drive of the Draw-off rollers not only increases the flexibility of the OE spinning machine and simplifies it Installation, but it also reduces the number of components of the piecing machine. The Desired roller speeds are from one or more operator terminals 18 (Fig. 1) individually or together can be specified. Accordingly, it is also possible to use the take-off rollers not to drive individually but in groups, whereby in groups means that the Number of take-off rollers driven by a common drive is significantly smaller than the number of take-off rolls per machine side.

The thread tensioner shown in Fig. 2 is of the type used in today's OE rotor spinning machines is used for thread length compensation in the production of conical bobbins. In such bobbins, which are widely used, for example, in knitting and warp knitting, a thread length compensation must be provided, because depending on the bobbin pitch, Taper and thread guide position different amounts of yarn per revolution is required. The yarn path is controlled by an oscillating thread guide, which is controlled by a Spring or is biased by weight or controlled by a motor drive is moved. Another option is to use stencils made by their shape lengthen or shorten the yarn path. With these templates, however, the coil shape is specified so that when changing the taper a mechanical changeover the machine must be done.

While the thread tensioner shown in Fig. 2, the thread only when starting and thus relatively rarely contacted, the thread is constantly on the mentioned in the manufacture of conical bobbins Thread guide deflected. Apart from that for the adjustment of the thread guide required mechanical and electrical effort, this permanent redirection of the Thread that the thread due to the different wrap angle on the thread guide is wound onto the spool with correspondingly different thread tension. This different thread tension causes an inhomogeneous density distribution of the bobbin, which can lead to problems during further processing.

With the winding head module shown in Fig. 1, the compensation of the thread length at Manufacturing conical coils can be easily solved by turning the speed of the coil in Depending on the current position of the thread laying lever is kept variable. Fig. 3a shows an empty tube with the first layers of yarn, Fig. 3b shows a conical bobbin, where as Laying a wild winding is indicated, and FIGS. 3c and 3d show possible speed profiles. In Fig. 3c the x-axis denotes the middle and the curve K the effective speed an empty spool at the start of a spool trip. In Fig. 3d the x-axis denotes the middle and curve K 'the effective speed of a full coil, with step and step precision winding.

The winding head module requires neither a mechanical thread length compensation nor one Template; the different thread length per bobbin revolution is rather a corresponding variation of the speed of the bobbin 7 compensated, so that the thread tension is always within certain limits. The variation in the speed of the coil 7 and thus the The speed of the drive 2 of the friction roller 3 is dependent on the current position of the thread laying lever 5. The speed of the bobbin 7 is controlled by the speed sensor 9 and any differences between the measured speed and its setpoint corrected via the controller 6. If there is no sensor 9 for the speed of the coil 7 then the coil diameter can be evaluated for the speed. The regulation of Drive 2 of the friction roller 3 can either electronically or via the power supply of the drive motor respectively.

The described thread length compensation by varying the bobbin speed is not on OE spinning machines limited, but can also be used in other textile machines, such as Winding machines, twisting machines, specialist machines or scorching machines become. Likewise, the winding head module shown in FIG. 1 can also be used on other textile machines, such as winding machines or twisting machines can be used.

Claims (13)

Device for driving rotatable members (7, 20) of an OE spinning machine, thereby characterized in that a motorized individual drive (2) for each of the organs mentioned is provided. Device according to claim 1, characterized in that the individual motor drive (2) is formed by a stepper motor. Device according to claim 1 or 2, characterized in that the rotatable organs are formed by coils (7) which can be driven directly or indirectly via friction rollers (3). Device according to claim 1 or 2, characterized in that the rotatable organs by take-off rollers arranged in the thread path between the spinning unit and the winding unit (20) are formed. Apparatus according to claim 4, characterized in that in each case for a group of Take-off rollers (20) an individual drive is provided, such a group with a shared drive only a small part of the workstations of the spinning machine includes. Apparatus according to claim 3, characterized in that in the coil drive a friction roller (3) in the acceleration phase during piecing increases the contact pressure between coil (7) and friction roller (3). Apparatus according to claim 3 or 6, characterized in that the friction roller (3) a surface texture and / or surface structure suitable for maximum power transmission having. Device according to one of claims 3, 6 or 7, characterized in that the The diameter of the friction roller (3) is selected so that for the individual motor drive (2) the best possible combination of speed and required torque is achieved. Device according to one of claims 3, 6 or 7, characterized in that when reached the desired bobbin diameter or the desired wound length of thread the coil (7) is braked by the individual motor drive (2). Device according to one of claims 1 to 9, characterized in that the direction of rotation the motorized single drive (2) can be selected. Apparatus according to claim 3, characterized in that the speed of the coil (7) in Dependence on the thread tension is regulated. Apparatus according to claim 11, characterized in that the thread tension on the basis the current position of the thread laying lever (5) and the speed of the bobbin (7) by supplying the drive motor or by an electronic control (6) is regulated. Apparatus according to claim 11 or 12, characterized in that a sensor (9) for monitoring the speed and / or calculating the diameter of the coil (7) is provided.

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