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EP0396068B1 - Method and apparatus for making a bundle of wires or a cable - Google Patents

Method and apparatus for making a bundle of wires or a cable Download PDF

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Publication number
EP0396068B1
EP0396068B1 EP90108171A EP90108171A EP0396068B1 EP 0396068 B1 EP0396068 B1 EP 0396068B1 EP 90108171 A EP90108171 A EP 90108171A EP 90108171 A EP90108171 A EP 90108171A EP 0396068 B1 EP0396068 B1 EP 0396068B1
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EP
European Patent Office
Prior art keywords
strand
torsion
cable
signal
strands
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Expired - Lifetime
Application number
EP90108171A
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German (de)
French (fr)
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EP0396068A2 (en
EP0396068A3 (en
Inventor
Bernd Schulligen
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Drahtcord Saar GmbH and Co KG
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Drahtcord Saar GmbH and Co KG
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    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B7/00Details of, or auxiliary devices incorporated in, rope- or cable-making machines; Auxiliary apparatus associated with such machines
    • D07B7/02Machine details; Auxiliary devices
    • D07B7/022Measuring or adjusting the lay or torque in the rope
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B3/00General-purpose machines or apparatus for producing twisted ropes or cables from component strands of the same or different material
    • D07B3/02General-purpose machines or apparatus for producing twisted ropes or cables from component strands of the same or different material in which the supply reels rotate about the axis of the rope or cable or in which a guide member rotates about the axis of the rope or cable to guide the component strands away from the supply reels in fixed position
    • D07B3/022General-purpose machines or apparatus for producing twisted ropes or cables from component strands of the same or different material in which the supply reels rotate about the axis of the rope or cable or in which a guide member rotates about the axis of the rope or cable to guide the component strands away from the supply reels in fixed position with provision for imparting two or more twists to the filaments for each revolution of the guide member

Definitions

  • the invention relates to a method for producing a bundle from a plurality of metallic individual wires (strand) or a rope from a plurality of strands, in which the wires or strands are pulled off in a conventional manner by means of a pull-out device via a rotor from braked coils of a coil carrier and with an adjustable lay length are laid around one another and / or twisted around one another, in which the stranded wires or stranded strands are then further twisted in their twisting direction in an overturning device, so that the residual torsion of the strand or the rope fluctuates by an adjustable constant value, and at the end the finished strand or rope is wound up on a spool or is processed immediately.
  • the invention further relates to a device for producing a bundle of several metallic individual wires (strand) or a rope made of several strands, with a coil carrier with braked coils for receiving individual wires or strands with a rotor for folding and / or twisting the wires or Stranded wire, with an overturning device, with at least one pull-out mechanism and with a winding or transfer device (see, for example, JP-A-56-9489).
  • a strand is understood to mean a bundle of at least two, but usually several, for example four or five individual wires, which are laid around and / or twisted around one another.
  • a rope is understood to mean a bundle of several strands or of more than eight individual wires or of a combination of strands and individual wires, which in turn are laid around and / or twisted around one another.
  • Under one Lay length is to be understood as the distance between two points of a wire or a strand with the same spatial position after a complete twist by 360 o .
  • the unit of measurement 1 torsion is to be defined in the context of this application in such a way that a 6 m long piece of strand unwound from a spool after the end has been released is rotated 360 o in the direction of rotation (+ 1 torsion) or in the opposite direction (- 1st Torsion).
  • the individual wires e.g. high-strength, surface-treated steel wires can be drawn off from coils by means of a pull-out mechanism and twisted around one another with an adjustable lay length by means of a rotor to form a strand. Because of the spring properties of the wires, a torque that opposes this torsion occurs.
  • a certain torsion value e.g. To obtain the value zero, the strand is twisted even further in its direction of rotation by means of an overturning device, as a rule beyond the elastic deformation range into the plastic one.
  • the residual torsions can only be measured when the machine is switched off and the strand is cut open. If the measured value is within the permissible limits, the machine is put into operation again; if the value is inadmissible, the speed of the overturning device is usually increased or decreased via a mechanical adjustment gear in order to obtain the desired value. These measurements are repeated after passing through predetermined strand lengths.
  • the invention is therefore based on the object of specifying a method for producing a strand or a rope of substantially improved quality, in which, in particular, the problems indicated no longer occur due to different residual torsions.
  • This object is achieved in that the strand or the rope behind the overturning device or the puller is given a low constant tension that in the range of low constant tension during the entire manufacturing process Torsion value of the strand or the rope is measured continuously and that if the torsion measurement deviates from the set torsion value, a control signal is generated by means of which the speed of the over-twisting device is changed in such a way that the strand or the rope again assumes the set torsion value.
  • a device for producing a strand or a rope is characterized in that a tension generator stage for maintaining a low constant tension is located between the pull-out unit and the winding or transfer device, and in the area of the low constant tension a torsion measuring device for the continuous detection of the torsion value is present, the measurement signal of which can be fed to a control device, the output signal of which changes the speed of the overturning device.
  • the main idea of the invention is to continuously measure the torsion value of the strand or the rope during the entire production process and to correct it immediately in the event of deviations from the set value.
  • the measurement is carried out in a measuring loop with a torsion measuring roller, which changes its angular position in the event of deviations from the target value and thereby generates a correction signal.
  • the control signal of the torsion measuring roller is used to change the speed of the overturning device via an electrical circuit in such a way that the strand or the rope again assumes the set torsion value (setpoint).
  • the invention offers the advantage that for the first time it has been possible to produce a strand of great length which, regardless of the length-changing properties of the individual wires, maintains a predetermined residual torsion value over its entire length. This avoids rejects both in the strand material and in the cord material subsequently produced therefrom.
  • the advantage of the stranding or stranding machine is that the elimination of a mechanical winding coupling and a mechanical adjusting mechanism of the overturning device eliminates approximately 95% of the wear parts of the machine, which results in a considerable reduction in indirect personnel.
  • a further advantage is a reduction in testing costs and rework.
  • the bunching machine essentially consists of the main assemblies bobbin 1, rotor 2, overturning device 3, pull-out mechanism 4, take-up device 5 and the assemblies according to the invention tension generator 6, torsion measuring device 7, control device 8 and conventional drive units.
  • the coil carrier 1 there are two coils 1.2 on each of two fixed axes 1.1, on which wires 1.3, for example brass-plated steel wires, are wound, from which a strand is to be produced.
  • wires 1.3 for example brass-plated steel wires
  • the individual wires 1.3 can have a diameter of approximately 0.25 mm.
  • brakes 1.4 To slow down the Coils 1.2 serve brakes 1.4.
  • the wires 1.3 are guided when pulling over collecting rollers 1.5 and rollers 1.6 forming a fixed point and an output roller 1.7.
  • the rotor 2 which is driven by the motor 9 via belts 10 and an intermediate shaft 11, consists essentially of two rotor disks 2.1, which are wrapped several times by the individual wires 1.3.
  • Two deflection rollers 2.2 are used to guide the individual wires 1.3 that have already been brought together to form a strand 12.
  • the heald 12 is fed to the overturning device 3, which essentially consists of two rollers 3.2, arranged side by side in a bracket 3.1, around which the heald 12 is guided, and a drive unit 3.3.
  • the drive unit 3.3 can be designed in such a way that the overturning device 3 is driven by the main motor 9 via drive belt 10, the intermediate shaft 11 and a gear 4.3 and that an additional motor in the unit 3.3 is only used to change the speed.
  • a separate drive motor can also be provided.
  • synchronization means should be provided for a synchronous start of the roto 2 and the overturning device 3.
  • a pull-out mechanism 4 Downstream of the overturning device 3 is a pull-out mechanism 4, which in the present example essentially consists of two pull-out rollers 4.1 and 4.2, of which the pull-out roller 4.2 is motor-driven, specifically via a reduction gear 4.3, which is connected to the intermediate shaft 11.
  • the strand 12 is generally wrapped around the rollers 4.1 and 4.2 at least ten times.
  • two pull-out units are also used, of which the second is then usually located between the rotor 2 and the overturning device 3.
  • the finished strand 12 is wound in the winding device 5 onto a driven spool 5.1.
  • a laying device 5.2 ensures the correct winding of the strand 12 in the usual way. If required, the finished strand 12 can be fed to an immediate further processing instead of to the winding device 5 via a deflection roller (not shown). If necessary, the bunching machine can also have a customary post-forming device.
  • the strand 12 is fed to the tension generator stage 6 via a deflection roller 13, which in the present example consists of a dancer device with two rollers 6.1 and 6.2.
  • the roller 6.2 is arranged in a fixed position, while the dancer roller 6.1 is located on a dancer arm 6.3 which can be pivoted about an axis A and which carries a weight 6.4 on its rear side via a linkage.
  • the weight 6.4 determines the position of the dancer arm 6.3.
  • the strand 12 is guided around the rollers 6.1 and 6.2 about four times.
  • the strand 12 is fed to a first deflecting roller 7.1 of the torsion measuring device 7 and runs from there, forming a measuring loop 7.2 around a torsion measuring roller 7.3, back to a second deflecting roller 7.4 and finally to the winding device 5.
  • the upper edges of the rollers 7.1 and 7.4 are approximately at the level of the axis of the torsion roller 7.3.
  • the torsion measuring roller 7.3 the diameter of which can be between 8 and 20 cm, is mounted in a roller arm 7.5, which is easily rotatable about its longitudinal axis.
  • An electronic signal transmitter 7.6 is connected to the torsion measuring roller 7.3 and generates an electrical signal depending on the angle of rotation of the roller arm 7.5 and thus the torsion measuring roller 7.3.
  • This signal is fed in the control device 8 - possibly with the interposition of an integrator stage 8.1 - to a comparison stage 8.2.
  • comparison stage 8.2 the signal is compared with a signal which can be set on controller R2 and which corresponds to the desired value of the residual torsion.
  • an output signal is generated in comparison stage 8.2 and sent to the drive unit 3.3 of the overturning device, which changes the speed of the overturning device 3 in such a way that the strand 12 again assumes the value set on the controller R2.
  • the operation of the stranding machine and the method for producing a strand are to be explained in more detail below.
  • the beating machine sets the rotor 2, the puller 4, the overturning device 3 and the winding device 5 in motion, whereby a synchronous start is ensured.
  • the strand 12 moves at a speed of approximately 100 to 200 m / min, and the striking discs 2.1 of the rotor 2 rotate at a speed of approximately 5 to 6000 rpm.
  • the four individual wires 1.3 are withdrawn from the braked coils 1.2 and rotated around one another with the aid of the striking discs 2.1, where they receive their first lay on the right deflection pulley 2.2 and their second lay on the left deflection pulley 2.2, so that here the final lay length of the strand 12 is reached.
  • the amount of the lay length is determined by the pull-off speed of the pull-out unit 4 and the speed of the striking discs 2.1.
  • High-strength steel wires which are used in the manufacture of strands for a tire cord as individual wires 1.3, react when twisted due to their spring properties to the twist with a reverse torque against the twisting direction. This return torque of the strand 12 is canceled or set to a desired final value (residual torsion) in that the strand 12 is further twisted together in the overturning device 3, specifically via the elastic deformation region into the plastic one.
  • the tension generator stage 6 After passing through the pulling unit 4, the strand 12 is guided via the tension generator stage 6 and the torsion measuring device 7 to the winding device 5 and is wound there on a spool 5.1. While high pulling forces act on the strand 12 up to the pull-out mechanism 4, the tension generator stage 6 ensures that the strand 12 is guided over the measuring loop of the torsion measuring device 7 with an extremely low constant tension. Only this constant low Tension allows a sensitive torsion measurement on the strand 12. The amount of tension can be adjusted with the regulator R1.
  • the dancer arm 6.3 changes its position by slightly pivoting about the axis A, as a result of which a correction signal is generated in the signal generator 6.5, which changes the winding speed of the winding spool 5.1 via the control device 8, so that the exact tension value is immediately restored.
  • the strand 12 is continuously guided as a measuring loop 7.2, in which the torsion measuring roller 7.3 hangs.
  • a value of approximately 1 m has proven to be favorable for the length of the measuring loop. It is important that the ends of the measuring loop 7.2 are guided as close as possible to one another.
  • the torsion measuring device 7 functions as follows. First, the desired residual torsion value of the strand 12 is set with the regulator R2, which can be zero, but can also be a specific value of a plus torsion or minus torsion.
  • the electrical circuit of the control device 8 supplies a signal to the drive unit 3.3, which has the effect that the overturning device 3 has exactly such a speed that it gives the strand 12 the desired residual torsion value. As long as the strand 12 maintains this value, the position of the torsion measuring roller 7.3 does not change.
  • the residual torsion of the strand 12 in the measuring loop 7.2 deviates from the predetermined value, this results in the measuring roller 7.3 and thus the roller arm 7.5 being rotated, as a result of which a measuring signal is generated in the electronic signal transmitter 7.6 Comparator stage 8.2 is fed into the control device 8 and there is a changed one Output signal generated. With this output signal, the speed of the overturning device 3 is changed in such a way that the desired residual torsion value, which is set on the regulator R2, is immediately obtained again on the strand 12. As soon as the disturbance stops due to the changed surface of the individual wires, a control mechanism starts in the opposite direction.
  • the detection of torsional fluctuations with the torsion measuring roller 7.3 is so sensitive that it may be expedient to first feed the signals generated in the electronic transmitter 7.6 to an integrator stage 8.1 and to initiate the readjustment mechanism after a certain threshold has been reached.
  • the invention can also be carried out with a single impact machine instead of the double impact machine described. Above all, instead of the strands described, the invention can also be used to produce ropes with a residual torsion that is constant over their length. In this case, there are not individual wires but strands in the coils 1.2 of the coil carrier.

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  • Ropes Or Cables (AREA)
  • Decoration Of Textiles (AREA)
  • Wire Processing (AREA)

Abstract

The invention relates to a method and an apparatus for making a bundle of a plurality of individual metal wires (strands) or a cable composed of a plurality of strands. To obtain strands of substantially improved quality, it is proposed to give the strand a low constant tensile stress during production, continuously to measure the torsion value of the strand or cable in the region of this low constant tensile stress during the entire production operation, and, in the event of deviations of the measured torsion value from the predetermined torsion value, to generate a control signal, by means of which the rotational speed of the overwinding device is varied in such a way that the strand or cable assumes the set torsion value again.

Description

Die Erfindung betrifft ein Verfahren zum Herstellen eines Bündels aus mehreren metallischen Einzeldrähten (Litze) oder eines Seils aus mehreren Litzen, bei dem die Drähte bzw. Litzen in üblicher Weise mittels eines Ausziehwerks über einen Rotor von gebremsten Spulen eines Spulenträgers abgezogen und mit einer einstellbaren Schlaglänge umeinandergelegt und/oder umeinander verdreht werden, bei dem die verlitzten Drähte bzw. verseilten Litzen anschließend in einer Überdreheinrichtung in ihrer Verdrehrichtung weiter zusammengedreht werden, so daß die Resttorsion der Litze bzw. des Seils um einen einstellbaren konstanten Wert schwankt, und bei dem am Ende die fertige Litze bzw. das fertige Seil auf eine Spule aufgewickelt wird oder unmittelbar weiterverarbeitet wird. Die Erfindung betrifft weiterhin eine Vorrichtung zur Herstellung eines Bündels aus mehreren metallischen Einzeldrähten (Litze) oder eines Seils aus mehreren Litzen, mit einem Spulenträger mit gebremsten Spulen zur Aufnahme von Einzeldrähten bzw. Litzen mit einem Rotor zum Umeinanderlegen und/oder Umeinanderverdrehen der Drähte bzw. Litzen, mit einer Überdreheinrichtung, mit zumindest einem Ausziehwerk und mit einer Aufwickel- oder Weitergabevorrichtung (siehe z.B. JP-A-56-9489).The invention relates to a method for producing a bundle from a plurality of metallic individual wires (strand) or a rope from a plurality of strands, in which the wires or strands are pulled off in a conventional manner by means of a pull-out device via a rotor from braked coils of a coil carrier and with an adjustable lay length are laid around one another and / or twisted around one another, in which the stranded wires or stranded strands are then further twisted in their twisting direction in an overturning device, so that the residual torsion of the strand or the rope fluctuates by an adjustable constant value, and at the end the finished strand or rope is wound up on a spool or is processed immediately. The invention further relates to a device for producing a bundle of several metallic individual wires (strand) or a rope made of several strands, with a coil carrier with braked coils for receiving individual wires or strands with a rotor for folding and / or twisting the wires or Stranded wire, with an overturning device, with at least one pull-out mechanism and with a winding or transfer device (see, for example, JP-A-56-9489).

Unter einer Litze wird ein Bündel aus mindestens zwei, im Regelfall jedoch mehreren, z.B. vier oder fünf Einzeldrähten verstanden, die umeinander gelegt und/oder umeinander verdreht sind. Unter einem Seil wird ein Bündel aus mehreren Litzen oder aus mehr als acht Einzeldrähten oder aus einer Kombination von Litzen und Einzeldrähten verstanden, die wiederum umeinander gelegt und/oder umeinander verdreht sind. Unter einer Schlaglänge soll der Abstand zwischen zwei Punkten eines Drahtes oder einer Litze mit der gleichen räumlichen Lage nach einer vollständigen Verdrehung um 360o verstanden werden. Die Maßeinheit 1 Torsion soll im Rahmen dieser Anmeldung in der Weise definiert sein, daß ein von einer Spule abgewickeltes 6 m langes Stück Litze nach dem Loslassen des Endes eine Umdrehung von 360o in Verdrehrichtung (+ 1 Torsion) oder in entgegengesetzter Richtung (- 1 Torsion) ausführt.A strand is understood to mean a bundle of at least two, but usually several, for example four or five individual wires, which are laid around and / or twisted around one another. A rope is understood to mean a bundle of several strands or of more than eight individual wires or of a combination of strands and individual wires, which in turn are laid around and / or twisted around one another. Under one Lay length is to be understood as the distance between two points of a wire or a strand with the same spatial position after a complete twist by 360 o . The unit of measurement 1 torsion is to be defined in the context of this application in such a way that a 6 m long piece of strand unwound from a spool after the end has been released is rotated 360 o in the direction of rotation (+ 1 torsion) or in the opposite direction (- 1st Torsion).

Bei der Herstellung einer Litze auf bekannten Verlitzmaschinen werden die Einzeldrähte, die z.B. hochfeste, oberflächenbehandelte Stahldrähte sein können, mittels eines Ausziehwerks von Spulen abgezogen und mit einer einstellbaren Schlaglänge mit Hilfe eines Rotors zu einer Litze umeinander verdreht. Dabei tritt wegen der Federeigenschaften der Drähte ein dieser Torsion entgegengerichtetes Drehmoment auf. Um als Endprodukt eine Litze mit einem bestimmten Torsionswert, z.B. dem Wert Null zu erhalten, wird die Litze mittels einer Überdreheinrichtung in ihrer Verdrehrichtung noch weiter zusammengedreht, und zwar im Regelfall über den elastischen Verformbereich hinaus in den plastischen.When producing a strand on known stranding machines, the individual wires, e.g. high-strength, surface-treated steel wires can be drawn off from coils by means of a pull-out mechanism and twisted around one another with an adjustable lay length by means of a rotor to form a strand. Because of the spring properties of the wires, a torque that opposes this torsion occurs. In order to produce a strand with a certain torsion value, e.g. To obtain the value zero, the strand is twisted even further in its direction of rotation by means of an overturning device, as a rule beyond the elastic deformation range into the plastic one.

Die Reaktion einer derart "überdrehten" Litze ist eine Rückdrehung, welche um Null schwankt, d.h. die Litze wird im Normalfall keine oder nur eine schwache Reaktion in oder entgegen der Verdrehrichtung zeigen. Man spricht dann von Plus- oder Minusresttorsionen. Diese Resttorsionen stellen bei einem aus den Litzen gefertigten Metallcord ein wichtiges Merkmal des Cordes dar, da von den Resttorsionen in der Hauptsache die Planlage einer gummierten Metallcordbahn abhängt. Weiterhin sind die Resttorsionen für die Gleichmäßigkeit der Schnittkanten der Cordabschnitte verantwortlich, welche z.B. im Reifenbau zur Herstellung der einzelnen Lagen benötigt werden. Im Falle unterschiedlicher oder starker Resttorsionen wirken sich diese als Welligkeit in der Schnittkante aus.The reaction of such an "overturned" strand is a reverse rotation which fluctuates around zero, ie the strand will normally show no or only a weak reaction in or against the direction of rotation. One then speaks of plus or minus residual torsions. In a metal cord made from the strands, these residual torsions represent an important feature of the cord, since the flatness of a rubberized metal cord sheet mainly depends on the residual torsions. Furthermore, the residual torsions are responsible for the uniformity of the cut edges of the cord sections, which are required, for example, in tire construction to produce the individual layers. In case of different or strong residual torsions have a ripple effect in the cutting edge.

Bei bekannten Verlitzmaschinen können die Resttorsionen nur bei abgeschalteter Maschine und aufgeschnittener Litze gemessen werden. Liegt der Meßwert innerhalb der zulässigen Grenzen, wird die Maschine wieder in Betrieb gesetzt; ist der Wert unzulässig, wird überlicherweise über ein mechanisches Verstellgetriebe die Drehzahl der Überdreheinrichtung erhöht oder erniedrigt, um den gewünschten Wert zu erhalten. Diese Messungen werden nach dem Durchlaufen vorgegebener Litzenlängen wiederholt.In known bunching machines, the residual torsions can only be measured when the machine is switched off and the strand is cut open. If the measured value is within the permissible limits, the machine is put into operation again; if the value is inadmissible, the speed of the overturning device is usually increased or decreased via a mechanical adjustment gear in order to obtain the desired value. These measurements are repeated after passing through predetermined strand lengths.

Bei den bekannten Herstellungsverfahren kommt es über die Litzen- bzw. Seillängen zu nicht unerheblichen Resttorsionsschwankungen, die in erster Linie von einer über die Drahtlänge unterschiedlichen Oberflächenbeschaffenheit der Einzeldrähte und dem Gefüge des Stahldrahtes selbst, in geringerem Umfang von Einflüssen der Verlitzmaschine herrühren. Die bekannten Herstellungsverfahren weisen somit den Nachteil auf, daß sich häufig Produkte minderer Qualität oder sogar in erheblichem Umfang Ausschuß ergeben und daß die Verlitzmaschinen wegen des häufigen Anhaltens und Wiederanfahrens nicht optimal betrieben werden können.In the known manufacturing processes, there are not inconsiderable residual torsional fluctuations over the strand or rope lengths, which primarily result from the surface properties of the individual wires differing over the wire length and the structure of the steel wire itself, to a lesser extent from influences of the bunching machine. The known manufacturing processes therefore have the disadvantage that products of poor quality or even to a considerable extent result in rejects and that the bunching machines cannot be operated optimally because of the frequent stopping and restarting.

Der Erfindung liegt deshalb die Aufgabe zugrunde, ein Verfahren zur Herstellung einer Litze oder eines Seils wesentlich verbesserter Qualität anzugeben, bei der bzw. dem insbesondere die aufgezeigten Probleme aufgrund unterschiedlicher Resttorsionen nicht mehr auftreten.The invention is therefore based on the object of specifying a method for producing a strand or a rope of substantially improved quality, in which, in particular, the problems indicated no longer occur due to different residual torsions.

Diese Aufgabe wird erfindungsgemäß dadurch gelöst, daß der Litze bzw. dem Seil hinter der Überdreheinrichtung bzw. dem Ausziehwerk eine niedrige konstante Zugspannung gegeben wird, daß im Bereich der niedrigen konstanten Zugspannung während des gesamten Herstellungsvorgangs der Torsionswert der Litze bzw. des Seils dauernd gemessen wird und daß bei Abweichungen des Torsionsmeßwertes vom eingestellten Torsionswert ein Steuersignal erzeugt wird, mittels dessen die Drehzahl der Überdreheinrichtung in der Weise verändert wird, daß die Litze bzw. das Seil wieder den eingestellten Torsionswert einnimmt.This object is achieved in that the strand or the rope behind the overturning device or the puller is given a low constant tension that in the range of low constant tension during the entire manufacturing process Torsion value of the strand or the rope is measured continuously and that if the torsion measurement deviates from the set torsion value, a control signal is generated by means of which the speed of the over-twisting device is changed in such a way that the strand or the rope again assumes the set torsion value.

Eine Vorrichtung zur Herstellung einer Litze bzw. eines Seils ist dadurch gekennzeichnet, daß sich zwischen dem Ausziehwerk und der Aufwickel- bzw. Weitergabevorrichtung eine Zugspannungserzeugerstufe zum Einhalten einer niedrigen konstanten Zugspannung befindet und daß im Bereich der niedrigen konstanten Zugspannung eine Torsionsmeßeinrichtung zum laufenden Erfassen des Torsionswertes vorhanden ist, deren Meßsignal einer Regeleinrichtung zuführbar ist, deren Ausgangssignal die Drehzahl der Überdreheinrichtung verändert.A device for producing a strand or a rope is characterized in that a tension generator stage for maintaining a low constant tension is located between the pull-out unit and the winding or transfer device, and in the area of the low constant tension a torsion measuring device for the continuous detection of the torsion value is present, the measurement signal of which can be fed to a control device, the output signal of which changes the speed of the overturning device.

Der Kerngedanke der Erfindung besteht darin, den Torsionswert der Litze bzw. des Seils während des gesamten Herstellungsvorgangs dauernd zu messen und bei Abweichungen vom eingestellten Sollwert sofort zu korrigieren. Die Messung erfolgt in einer Meßschleife mit einer Torsionsmeßrolle, die bei Abweichungen vom Sollwert ihre Winkelstellung ändert und dadurch ein Korrektursignal erzeugt. Um bereits geringfügige Abweichungen vom Resttorsionssollwert mit der Torsionsmeßeinrichtung erfassen zu können, wird erfindungsgemäß vorgeschlagen, der Litze in einem bestimmten Bereich eine niedrige konstante Zugspannung zu geben und die Meßeinrichtung in diesem Bereich der Litzenführung anzuordnen. Das Steuersignal der Torsionsmeßrolle wird dazu verwendet, über eine elektrische Schaltung die Drehzahl der Überdreheinrichtung in der Weise zu verändern, daß die Litze bzw. das Seil wieder den eingestellten Torsionswert (Sollwert) einnimmt.The main idea of the invention is to continuously measure the torsion value of the strand or the rope during the entire production process and to correct it immediately in the event of deviations from the set value. The measurement is carried out in a measuring loop with a torsion measuring roller, which changes its angular position in the event of deviations from the target value and thereby generates a correction signal. In order to be able to detect even slight deviations from the residual torsion setpoint with the torsion measuring device, it is proposed according to the invention to give the strand a low constant tensile stress in a certain area and to arrange the measuring device in this area of the strand guide. The control signal of the torsion measuring roller is used to change the speed of the overturning device via an electrical circuit in such a way that the strand or the rope again assumes the set torsion value (setpoint).

Die Erfindung bietet vor allem den Vorteil, daß es mit ihr erstmals gelungen ist, eine Litze großer Länge herzustellen, die unabhängig von den über die Länge wechselnden Eigenschaften der Einzeldrähte auf ihrer gesamten Länge einen vorgegebenen Resttorsionswert einhält. Somit wird sowohl beim Litzenmaterial als auch beim später daraus hergestellten Cordmaterial Ausschuß vermieden. An der Verlitz- bzw. Verseilmaschine ergibt sich der Vorteil, daß durch den Wegfall einer mechanischen Wickelkupplung und eines mechanischen Verstellgetriebes der Überdreheinrichtung ca. 95 % der Verschleißteile der Maschine entfallen, woraus eine erhebliche Reduzierung des indirekten Personals resultiert. Schließlich sind als weitere Vorteile eine Reduzierung an Prüfkosten und Nacharbeit zu nennen.Above all, the invention offers the advantage that for the first time it has been possible to produce a strand of great length which, regardless of the length-changing properties of the individual wires, maintains a predetermined residual torsion value over its entire length. This avoids rejects both in the strand material and in the cord material subsequently produced therefrom. The advantage of the stranding or stranding machine is that the elimination of a mechanical winding coupling and a mechanical adjusting mechanism of the overturning device eliminates approximately 95% of the wear parts of the machine, which results in a considerable reduction in indirect personnel. Finally, a further advantage is a reduction in testing costs and rework.

Nachfolgend wird die Erfindung am Beispiel einer Verlitzmaschine in Form einer Doppelschlagmaschine näher erläutert.The invention is explained in more detail below using the example of a bunching machine in the form of a double striking machine.

Es zeigt die einzige Figur
   eine Verlitzmaschine (teilweise schematisch) in einer Seitenansicht.
It shows the only figure
a beating machine (partially schematic) in a side view.

Die Verlitzmaschine besteht im wesentlichen aus den Hauptbaugruppen Spulenträger 1, Rotor 2, Überdreheinrichtung 3, Ausziehwerk 4, Aufwickelvorrichtung 5 sowie den erfindungsgemäßen Baugruppen Zugspannungserzeugerstufe 6, Torsionsmeßeinrichtung 7, Regeleinrichtung 8 und üblichen Antriebsaggregaten.The bunching machine essentially consists of the main assemblies bobbin 1, rotor 2, overturning device 3, pull-out mechanism 4, take-up device 5 and the assemblies according to the invention tension generator 6, torsion measuring device 7, control device 8 and conventional drive units.

Im Spulenträger 1 befinden sich auf zwei ortsfesten Achsen 1.1 jeweils zwei Spulen 1.2, auf denen Drähte 1.3, z.B. vermessingte Stahldrähte aufgewickelt sind, aus denen eine Litze hergestellt werden soll. Im Fall von Litzen für Reifencorde können die Einzeldrähte 1.3 einen Durchmesser von ca. 0,25 mm aufweisen. Zum Abbremsen der Spulen 1.2 dienen Bremsen 1.4. Die Drähte 1.3 werden beim Abziehen über Sammelrollen 1.5 und einen Festpunkt bildende Rollen 1.6 sowie eine Ausgangsrolle 1.7 geführt.In the coil carrier 1 there are two coils 1.2 on each of two fixed axes 1.1, on which wires 1.3, for example brass-plated steel wires, are wound, from which a strand is to be produced. In the case of strands for tire cords, the individual wires 1.3 can have a diameter of approximately 0.25 mm. To slow down the Coils 1.2 serve brakes 1.4. The wires 1.3 are guided when pulling over collecting rollers 1.5 and rollers 1.6 forming a fixed point and an output roller 1.7.

Der vom Motor 9 über Riemen 10 und eine Zwischenwelle 11 angetriebene Rotor 2 besteht im wesentlichen aus zwei Rotor- bzw. Schlagscheiben 2.1, die von den Einzeldrähten 1.3 mehrfach umschlungen werden. Zwei Umlenkrollen 2.2 dienen zur Führung der bereits zu einer Litze 12 zusammengeführten Einzeldrähte 1.3.The rotor 2, which is driven by the motor 9 via belts 10 and an intermediate shaft 11, consists essentially of two rotor disks 2.1, which are wrapped several times by the individual wires 1.3. Two deflection rollers 2.2 are used to guide the individual wires 1.3 that have already been brought together to form a strand 12.

Nach Verlassen des Rotors 2 wird die Litze 12 der Überdreheinrichtung 3 zugeführt, die im wesentlichen aus zwei in einem Bügel 3.1 nebeneinander angeordneten Rollen 3.2, um die die Litze 12 herumgeführt ist, und einem Antriebsaggregat 3.3 besteht. Das Antriebsaggregat 3.3 kann in der Weise ausgebildet sein, daß die Überdreheinrichtung 3 vom Hauptmotor 9 über Antriebsriemen 10, die Zwischenwelle 11 und ein Getriebe 4.3 angetrieben wird und daß ein Zusatzmotor im Aggregat 3.3 lediglich zum Verändern der Drehzahl dient. Es kann aber auch ein separater Antriebsmotor vorgesehen sein. In jedem Fall sollten Synchronisiermittel für einen synchronen Anlauf des Rotos 2 und der Überdreheinrichtung 3 vorgesehen sein. Durch Veränderung der Drehzahl der Uberdreheinrichtung 3 kann das Maß der Überdrehung der Litze 12 und damit ihr Resttorsionswert eingestellt werden.After leaving the rotor 2, the heald 12 is fed to the overturning device 3, which essentially consists of two rollers 3.2, arranged side by side in a bracket 3.1, around which the heald 12 is guided, and a drive unit 3.3. The drive unit 3.3 can be designed in such a way that the overturning device 3 is driven by the main motor 9 via drive belt 10, the intermediate shaft 11 and a gear 4.3 and that an additional motor in the unit 3.3 is only used to change the speed. However, a separate drive motor can also be provided. In any case, synchronization means should be provided for a synchronous start of the roto 2 and the overturning device 3. By changing the speed of the overturning device 3, the degree of overturning of the strand 12 and thus its residual torsion value can be set.

Der Überdreheinrichtung 3 nachgeschaltet befindet sich ein Ausziehwerk 4, das im vorliegenden Beispiel im wesentlichen aus zwei Ausziehrollen 4.1 und 4.2 besteht, von denen die Ausziehrolle 4.2 motorgetrieben ist, und zwar über ein Reduziergetriebe 4.3, das mit der Zwischenwelle 11 verbunden ist. Die Litze 12 wird im allgemeinen mindestens zehnmal um die Rollen 4.1 und 4.2 herumgeschlagen. In bestimmten Anwendungsfällen können auch zwei Ausziehwerke zum Einsatz kommen, von denen sich dann üblicherweise das zweite zwischen Rotor 2 und Überdreheinrichtung 3 befindet.Downstream of the overturning device 3 is a pull-out mechanism 4, which in the present example essentially consists of two pull-out rollers 4.1 and 4.2, of which the pull-out roller 4.2 is motor-driven, specifically via a reduction gear 4.3, which is connected to the intermediate shaft 11. The strand 12 is generally wrapped around the rollers 4.1 and 4.2 at least ten times. Can in certain applications two pull-out units are also used, of which the second is then usually located between the rotor 2 and the overturning device 3.

Am Ende der Verlitzmaschine wird die fertige Litze 12 in der Aufwickelvorrichtung 5 auf eine angetriebene Spule 5.1 gewickelt. Eine Verlegeeinrichtung 5.2 sorgt dabei in üblicher Weise für ein korrektes Aufwickeln der Litze 12. Bei Bedarf kann die fertige Litze 12 statt zur Aufwickelvorrichtung 5 über eine nicht gezeichnete Umlenkrolle einer unmittelbaren Weiterverarbeitung zugeführt werden. Bei Bedarf kann die Verlitzmaschine weiterhin ein übliches Nachformgerät aufweisen.At the end of the bunching machine, the finished strand 12 is wound in the winding device 5 onto a driven spool 5.1. A laying device 5.2 ensures the correct winding of the strand 12 in the usual way. If required, the finished strand 12 can be fed to an immediate further processing instead of to the winding device 5 via a deflection roller (not shown). If necessary, the bunching machine can also have a customary post-forming device.

Nachfolgend werden die für die Erfindung wesentlichen Baugruppen der Verlitzmaschine beschrieben, nämlich die Zugspannungserzeugerstufe 6, die Torsionsmeßeinrichtung 7 und die Regeleinrichtung 8.The subassemblies of the bunching machine that are essential to the invention are described below, namely the tension generator stage 6, the torsion measuring device 7 and the control device 8.

Nach Verlassen des Ausziehwerks 4 wird die Litze 12 über eine Umlenkrolle 13 der Zugspannungserzeugerstufe 6 zugeführt, die im vorliegenden Beispiel aus einer Tänzereinrichtung mit zwei Rollen 6.1 und 6.2 besteht. Die Rolle 6.2 ist ortsfest angeordnet, während sich die Tänzerrolle 6.1 an einem um eine Achse A schwenkbaren Tänzerarm 6.3 befindet, der auf seiner Rückseite über ein Gestänge ein Gewicht 6.4 trägt. Das Gewicht 6.4 bestimmt die Stellung des Tänzerarms 6.3. Die Litze 12 ist ca. viermal um die Rollen 6.1 und 6.2 herumgeführt. Auf der Rückseite des Tänzerarms 6.3 ist weiterhin ein Signalgeber (Potentiometer) 6.5 angebracht, dessen Signal in der Regeleinrichtung 8 einer Regelschaltung mit dem Regler R1 zugeführt wird, die die Aufwickelvorrichtung 5 derart steuert, daß sich für den beweglichen Tänzerarm 6.3 eine konstante Stellung ergibt, woraus eine konstante Zugspannung für die Litze 12 folgt. Im Falle einer Litze aus vier oder fünf Einzeldrähten für einen Reifencord sollte diese Zugspannung unter 15 Newton liegen.After leaving the pull-out unit 4, the strand 12 is fed to the tension generator stage 6 via a deflection roller 13, which in the present example consists of a dancer device with two rollers 6.1 and 6.2. The roller 6.2 is arranged in a fixed position, while the dancer roller 6.1 is located on a dancer arm 6.3 which can be pivoted about an axis A and which carries a weight 6.4 on its rear side via a linkage. The weight 6.4 determines the position of the dancer arm 6.3. The strand 12 is guided around the rollers 6.1 and 6.2 about four times. On the back of the dancer arm 6.3 there is also a signal transmitter (potentiometer) 6.5, the signal of which is fed in the control device 8 to a control circuit with the controller R1, which controls the winding device 5 in such a way that a constant position results for the movable dancer arm 6.3, which results in a constant tension for the strand 12. In the case of a strand of four or five individual wires for one Tire cord, this tension should be less than 15 Newtons.

Nach Verlassen der Zugspannungserzeugerstufe 6 wird die Litze 12 einer ersten Umlenkrolle 7.1 der Torsionsmeßeinrichtung 7 zugeführt und verläuft von dort aus unter Bildung einer Meßschleife 7.2 um eine Torsionsmeßrolle 7.3 herum zurück auf eine zweite Umlenkrolle 7.4 und schließlich zur Aufwickelvorrichtung 5. Die oberen Ränder der Rollen 7.1 und 7.4 liegen etwa auf Höhe der Achse der Torsionsmeßrolle 7.3. Die Torsionsmeßrolle 7.3, deren Durchmesser zwischen 8 und 20 cm liegen kann, ist in einem Rollenarm 7.5 gelagert, der um seine Längsachse leicht drehbar ist.After leaving the tension generator stage 6, the strand 12 is fed to a first deflecting roller 7.1 of the torsion measuring device 7 and runs from there, forming a measuring loop 7.2 around a torsion measuring roller 7.3, back to a second deflecting roller 7.4 and finally to the winding device 5. The upper edges of the rollers 7.1 and 7.4 are approximately at the level of the axis of the torsion roller 7.3. The torsion measuring roller 7.3, the diameter of which can be between 8 and 20 cm, is mounted in a roller arm 7.5, which is easily rotatable about its longitudinal axis.

Mit der Torsionsmeßrolle 7.3 ist ein elektronischer Signalgeber 7.6 verbunden, der in Abhängigkeit vom Verdrehwinkel des Rollenarms 7.5 und damit der Torsionsmeßrolle 7.3 ein elektrisches Signal erzeugt. Dieses Signal wird in der Regeleinrichtung 8 - gegebenenfalls unter Zwischenschaltung einer Integratorstufe 8.1 - einer Vergleichsstufe 8.2 zugeführt. In der Vergleichsstufe 8.2 wird das Signal mit einem am Regler R2 einstellbaren Signal verglichen, das dem gewünschten Wert der Resttorsion entspricht. Als Reaktion auf den Vergleich wird in der Vergleichsstufe 8.2 ein Ausgangssignal erzeugt und an das Antriebsaggregat 3.3 der Überdreheinrichtung abgegeben, das die Drehzahl der Überdreheinrichtung 3 in der Weise verändert, daß die Litze 12 wieder den am Regler R2 eingestellten Wert einnimmt.An electronic signal transmitter 7.6 is connected to the torsion measuring roller 7.3 and generates an electrical signal depending on the angle of rotation of the roller arm 7.5 and thus the torsion measuring roller 7.3. This signal is fed in the control device 8 - possibly with the interposition of an integrator stage 8.1 - to a comparison stage 8.2. In comparison stage 8.2, the signal is compared with a signal which can be set on controller R2 and which corresponds to the desired value of the residual torsion. In response to the comparison, an output signal is generated in comparison stage 8.2 and sent to the drive unit 3.3 of the overturning device, which changes the speed of the overturning device 3 in such a way that the strand 12 again assumes the value set on the controller R2.

Nachfolgend sollen die Funktionsweise der Verlitzmaschine und das Verfahren zur Herstellung einer Litze näher erläutert werden. Nach dem Ingangsetzen der Verlitzmaschine setzen sich der Rotor 2, das Ausziehwerk 4, die Überdreheinrichtung 3 und die Aufwickelvorrichtung 5 in Bewegung, wobei für einen synchronen Anlauf gesorgt ist. Nach dem Anlauf bewegt sich die Litze 12 mit einer Geschwindigkeit von ca. 100 bis 200 m/min, und die Schlagscheiben 2.1 des Rotors 2 drehen sich mit einer Geschwindigkeit von ca. 5 bis 6000 U/min. Die vier Einzeldrähte 1.3 werden von den gebremsten Spulen 1.2 abgezogen und mit Hilfe der Schlagscheiben 2.1 umeinander verdreht, wobei sie an der rechten Umlenkrolle 2.2 ihren ersten Schlag und an der linken Umlenkrolle 2.2 ihren zweiten Schlag erhalten, so daß hier die endgültige Schlaglänge der Litze 12 erreicht ist. Der Betrag der Schlaglänge wird von der Abziehgeschwindigkeit des Ausziehwerks 4 und der Drehzahl der Schlagscheiben 2.1 bestimmt.The operation of the stranding machine and the method for producing a strand are to be explained in more detail below. After starting the The beating machine sets the rotor 2, the puller 4, the overturning device 3 and the winding device 5 in motion, whereby a synchronous start is ensured. After start-up, the strand 12 moves at a speed of approximately 100 to 200 m / min, and the striking discs 2.1 of the rotor 2 rotate at a speed of approximately 5 to 6000 rpm. The four individual wires 1.3 are withdrawn from the braked coils 1.2 and rotated around one another with the aid of the striking discs 2.1, where they receive their first lay on the right deflection pulley 2.2 and their second lay on the left deflection pulley 2.2, so that here the final lay length of the strand 12 is reached. The amount of the lay length is determined by the pull-off speed of the pull-out unit 4 and the speed of the striking discs 2.1.

Hochfeste Stahldrähte, die bei der Litzenherstellung für einen Reifencord als Einzeldrähte 1.3 zum Einsatz kommen, reagieren beim Verlitzen wegen ihrer Federeigenschaften auf die Verdrehung mit einem Rückdrehmoment entgegen der Verdrehrichtung. Dieses Rückdrehmoment der Litze 12 wird dadurch aufgehoben bzw. auf einen gewünschten Endwert (Resttorsion) eingestellt, daß die Litze 12 in der Überdreheinrichtung 3 weiter zusammengedreht wird, und zwar über den elastischen Verformbereich hinein in den plastischen.High-strength steel wires, which are used in the manufacture of strands for a tire cord as individual wires 1.3, react when twisted due to their spring properties to the twist with a reverse torque against the twisting direction. This return torque of the strand 12 is canceled or set to a desired final value (residual torsion) in that the strand 12 is further twisted together in the overturning device 3, specifically via the elastic deformation region into the plastic one.

Nach Durchlaufen des Ausziehwerks 4 wird die Litze 12 über die Zugspannungserzeugerstufe 6 und die Torsionsmeßeinrichtung 7 zur Aufwickelvorrichtung 5 geführt und dort auf eine Spule 5.1 gewickelt. Während bis zum Ausziehwerk 4 hohe Ziehkräfte auf die Litze 12 einwirken, sorgt die Zugspannungserzeugerstufe 6 dafür, daß die Litze 12 mit einer extrem niedrigen konstanten Zugspannung über die Meßschleife der Torsionsmeßeinrichtung 7 geführt wird. Erst diese konstante niedrige Zugspannung erlaubt eine empfindliche Torsionsmessung an der Litze 12. Der Betrag der Zugspannung kann mit Hilfe des Reglers R1 eingestellt werden. Wenn aufgrund äußerer Einflüsse die Zugspannung beginnt, von diesem Wert abzuweichen, ändert der Tänzerarm 6.3 durch geringfügiges Schwenken um die Achse A seine Stellung, wodurch im Signalgeber 6.5 ein Korrektursignal erzeugt wird, das über die Regeleinrichtung 8 die Wickelgeschwindigkeit der Wickelspule 5.1 verändert, so daß sich sofort wieder der exakte Zugspannungswert einstellt.After passing through the pulling unit 4, the strand 12 is guided via the tension generator stage 6 and the torsion measuring device 7 to the winding device 5 and is wound there on a spool 5.1. While high pulling forces act on the strand 12 up to the pull-out mechanism 4, the tension generator stage 6 ensures that the strand 12 is guided over the measuring loop of the torsion measuring device 7 with an extremely low constant tension. Only this constant low Tension allows a sensitive torsion measurement on the strand 12. The amount of tension can be adjusted with the regulator R1. If the tensile stress begins to deviate from this value due to external influences, the dancer arm 6.3 changes its position by slightly pivoting about the axis A, as a result of which a correction signal is generated in the signal generator 6.5, which changes the winding speed of the winding spool 5.1 via the control device 8, so that the exact tension value is immediately restored.

In der Torsionsmeßeinrichtung 7 wird die Litze 12 dauernd als Meßschleife 7.2 geführt, in der die Torsionsmeßrolle 7.3 hängt. Im beschriebenen Beispiel hat sich für die Länge der Meßschleife ein Wert von ca. 1 m als günstig erwiesen. Wichtig ist, daß die Enden der Meßschleife 7.2 möglichst nahe beieinander geführt werden. Die Torsionsmeßeinrichtung 7 funktioniert wie folgt. Zunächst wird mit dem Regler R2 der gewünschte Resttorsionswert der Litze 12 eingestellt, der Null betragen kann, aber auch ein bestimmter Wert einer Plustorsion oder Minustorsion sein kann. Solange keine Torsionsschwankungen in der Meßschleife 7.2 auftreten, liefert die elektrische Schaltung der Regeleinrichtung 8 ein Signal an das Antriebsaggregat 3.3, das die Wirkung hat, daß die Überdreheinrichtung 3 exakt eine solche Drehzahl aufweist, daß sie der Litze 12 den gewünschten Resttorsionswert verleiht. Solange die Litze 12 diesen Wert beibehält, ändert sich die Stellung der Torsionsmeßrolle 7.3 nicht. Sobald z.B. aufgrund einer geänderten Oberflächenbeschaffenheit der Einzeldrähte 1.3 die Resttorsion der Litze 12 in der Meßschleife 7.2 vom vorgegebenen Wert abweicht, hat dies ein Verdrehen der Meßrolle 7.3 und damit des Rollenarms 7.5 zur Folge, wodurch im elektronischen Signalgeber 7.6 ein Meßsignal erzeugt wird, das der Vergleicherstufe 8.2 in der Regeleinrichtung 8 zugeführt wird und dort ein geändertes Ausgangssignal erzeugt. Mit diesem Ausgangssignal wird die Drehzahl der Überdreheinrichtung 3 in der Weise verändert, daß sich an der Litze 12 sofort wieder der gewünschte und am Regler R2 eingestellte Resttorsionswert ergibt. Sobald die Störung aufgrund der geänderten Oberfläche der Einzeldrähte aufhört, setzt ein Regelmechanismus in umgekehrter Richtung ein. Die Erfassung von Torsionsschwankungen mit der Torsionsmeßrolle 7.3 ist derart empfindlich, daß es zweckmäßig sein kann, die im elektronischen Geber 7.6 erzeugten Signale zunächst einer Integratorstufe 8.1 zuzuführen und nach Erreichen einer bestimmten Schwelle den Nachregelmechanismus einzuleiten.In the torsion measuring device 7, the strand 12 is continuously guided as a measuring loop 7.2, in which the torsion measuring roller 7.3 hangs. In the example described, a value of approximately 1 m has proven to be favorable for the length of the measuring loop. It is important that the ends of the measuring loop 7.2 are guided as close as possible to one another. The torsion measuring device 7 functions as follows. First, the desired residual torsion value of the strand 12 is set with the regulator R2, which can be zero, but can also be a specific value of a plus torsion or minus torsion. As long as there are no torsional fluctuations in the measuring loop 7.2, the electrical circuit of the control device 8 supplies a signal to the drive unit 3.3, which has the effect that the overturning device 3 has exactly such a speed that it gives the strand 12 the desired residual torsion value. As long as the strand 12 maintains this value, the position of the torsion measuring roller 7.3 does not change. As soon as, for example, due to a changed surface quality of the individual wires 1.3, the residual torsion of the strand 12 in the measuring loop 7.2 deviates from the predetermined value, this results in the measuring roller 7.3 and thus the roller arm 7.5 being rotated, as a result of which a measuring signal is generated in the electronic signal transmitter 7.6 Comparator stage 8.2 is fed into the control device 8 and there is a changed one Output signal generated. With this output signal, the speed of the overturning device 3 is changed in such a way that the desired residual torsion value, which is set on the regulator R2, is immediately obtained again on the strand 12. As soon as the disturbance stops due to the changed surface of the individual wires, a control mechanism starts in the opposite direction. The detection of torsional fluctuations with the torsion measuring roller 7.3 is so sensitive that it may be expedient to first feed the signals generated in the electronic transmitter 7.6 to an integrator stage 8.1 and to initiate the readjustment mechanism after a certain threshold has been reached.

Es sollte angemerkt werden, daß die Erfindung statt mit der beschriebenen Doppelschlagmaschine auch mit einer Einfachschlagmaschine durchgeführt werden kann. Vor allem können mit der Erfindung aber statt der beschriebenen Litzen auch Seile mit einer über ihre Länge konstanten Resttorsion hergestellt werden. In diesem Fall befinden sich in den Spulen 1.2 des Spulenträgers nicht Einzeldrähte sondern Litzen.It should be noted that the invention can also be carried out with a single impact machine instead of the double impact machine described. Above all, instead of the strands described, the invention can also be used to produce ropes with a residual torsion that is constant over their length. In this case, there are not individual wires but strands in the coils 1.2 of the coil carrier.

Liste der BezugszeichenList of reference numbers

11
SpulenträgerCoil carrier
1.11.1
ortsfeste Achsenstationary axes
1.21.2
SpulenDo the washing up
1.31.3
DrähteWires
1.41.4
BandbremseBand brake
1.51.5
SammelrollenCollecting roles
1.61.6
Rollenroll
1.71.7
AusgangsrolleInitial role
22nd
Rotorrotor
2.12.1
SchlagscheibenImpact discs
2.22.2
UmlenkrollenPulleys
33rd
ÜberdreheinrichtungOverturning device
3.13.1
Bügelhanger
3.23.2
Rollenroll
3.33.3
AntriebsaggregatDrive unit
44th
AusziehwerkPull-out mechanism
4.14.1
AusziehrollePull-out roll
4.24.2
motorgetriebene Ausziehrollemotorized pull-out roller
55
AufwickelvorrichtungTake-up device
5.15.1
SpuleKitchen sink
5.25.2
VerlegeeinrichtungLaying device
66
ZugspannungserzeugerstufeTension generator stage
6.16.1
TänzerrolleDancer role
6.26.2
ortsfeste Rollestationary role
6.36.3
TänzerarmDancer arm
6.46.4
GewichtWeight
6.56.5
SignalgeberSignal generator
77
TorsionsmeßeinrichtungTorsion measuring device
7.17.1
erste Umlenkrollefirst pulley
7.27.2
MeßschleifeMeasuring loop
7.37.3
TorsionsmeßrolleTorsion roller
7.47.4
zweite Umlenkrollesecond pulley
7.57.5
RollenarmRoller arm
7.67.6
elektronischer Signalgeberelectronic signal generator
88th
RegeleinrichtungControl device
8.18.1
IntegratorstufeIntegrator level
8.28.2
VergleichsstufeComparison level
99
Motorengine
1010th
Riemenbelt
1111
ZwischenwelleIntermediate shaft
1212th
LitzeStrand
1313
UmlenkrollePulley
AA
Achseaxis
R1R1
Regler 1Controller 1
R2R2
Regler 2Controller 2

Claims (13)

  1. Method of producing a bundle comprising a plurality of metallic individual wires (strand) or a cable comprising a plurality of strands, wherein the wires or strands are unwound from braked coils of a coil carrier in conventional manner by means of an extractor via a rotor and are laid around one another and/or twisted around one another with an adjustable length of lay and/or twist, wherein the stranded wires or cabled strands respectively are subsequently wound together further in an overwinding means in their twisting direction, so that the residual torsion of the strand or cable, respectively, varies by an adjustable constant value, and wherein the finished strand or the finished cable is wound onto a coil at the end or is subsequently directly treated, characterised in that the strand or the cable respectively is given a low constant tensile stress behind the overwinding means or the extractor, respectively, in that the torsional value of the strand or respectively of the cable is constantly measured in the region of the low constant tensile stress during the entire production process, and in that, in the event of the torsion measurement value deviating from the set torsional value, a control signal is produced, by means of which the speed of the overwinding means is changed in such a manner that the strand or cable respectively resumes the set torsional value.
  2. Method according to claim 1, characterised in that the signal for the torsion measurement value is compared in a comparison stage with a signal which corresponds to the set torsional value, and in that, in the event of deviations, an output signal is produced and transmitted to the drive of the overwinding means, such signal changing the speed of said overwinding means.
  3. Method according to claim 2, characterised in that the signal for the torsion measurement value is initially supplied to an integrator stage.
  4. Method according to claim 1, characterised in that the torsion of the strand or cable respectively is measured in a measuring loop which has a length of approximately 1 m.
  5. Method according to claim 1, characterised in that the low constant tensile stress is produced by a compensating means.
  6. Method according to claim 1, characterised in that the maximum tensile stress of the strand or cable respectively behind the overwinding means is 15 newtons.
  7. Apparatus for producing a bundle comprising a plurality of metallic individual wires (strand) or a cable comprising a plurality of strands, including a coil carrier having braked coils for receiving individual wires or strands, respectively, a rotor for laying and/or twisting the wires or strands around one another, an overwinding means, at least one extractor and one winding-on or advancing device, characterized in that a tensile stress producing stage (6), for keeping to a low constant tensile stress, is situated between the extractor (4) and the winding-on (5) or advancing device, and in that a torsion-measuring means (7), for constantly determining the torsional value, is provided in the region of the low constant tensile stress, the measuring signal of said torsion-measuring means being feedable to a regulating means (8), the output signal of which changes the speed of the overwinding means (3).
  8. Apparatus according to claim 7, characterized in that the torsion-measuring means (7) has a torsion-measuring roller (7.3), which is mounted in a roller arm (7.5) rotatable about its longitudinal axis, and has a signal transmitter (7.6).
  9. Apparatus according to claim 8, characterized in that the diameter of the torsion-measuring roller (7.3) is between 8 and 20 cm.
  10. Apparatus according to claim 7, characterized in that the tensile stress producing stage (6) comprises a compensating means which has a stationary roller (6.2) and a roller (6.1), which is mounted in a compensating arm (6.3) pivotable about an axis (A).
  11. Apparatus according to claim 7, characterized by a comparison stage (8.2) in the regulating means (8), the measuring signal of the signal transmitter (7.6) being feedable to one input of said regulating means, and a signal for a torsional value, which signal is adjustable with a regulator (R2), is feedable to the other input of said regulating means, and the output signal of said regulating means can be applied to one input of the drive assembly (3.3) of the overwinding means (3).
  12. Bundle comprising a plurality of individual wires (strand), or cable comprising a plurality of strands, produced according to the method of claim 1, characterized in that the strand (12) or the cable respectively has a constant residual torsional value over its entire length.
  13. Strand or cable according to claim 12, characterized in that it is processed in a cord web.
EP90108171A 1989-04-29 1990-04-28 Method and apparatus for making a bundle of wires or a cable Expired - Lifetime EP0396068B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE3914330 1989-04-29
DE3914330A DE3914330A1 (en) 1989-04-29 1989-04-29 METHOD AND DEVICE FOR PRODUCING A WIRE BUNDLE OR ROPE

Publications (3)

Publication Number Publication Date
EP0396068A2 EP0396068A2 (en) 1990-11-07
EP0396068A3 EP0396068A3 (en) 1990-12-19
EP0396068B1 true EP0396068B1 (en) 1994-07-06

Family

ID=6379833

Family Applications (1)

Application Number Title Priority Date Filing Date
EP90108171A Expired - Lifetime EP0396068B1 (en) 1989-04-29 1990-04-28 Method and apparatus for making a bundle of wires or a cable

Country Status (7)

Country Link
EP (1) EP0396068B1 (en)
JP (1) JP2921583B2 (en)
AT (1) ATE108232T1 (en)
BR (1) BR9001987A (en)
DD (1) DD300116A5 (en)
DE (2) DE3914330A1 (en)
TR (1) TR25698A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6718624B1 (en) 1999-04-08 2004-04-13 Schleuniger Holding Ag Method for controlling a cable treating device

Families Citing this family (2)

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Publication number Priority date Publication date Assignee Title
DE19535595C2 (en) * 1995-09-25 2000-12-07 Drahtcord Saar Gmbh & Co Kg Process for producing a spiral wire filament, in particular for reinforcing rubber or plastic articles, device for carrying out the process and wire filament produced by the process
CN101736623B (en) * 2009-11-28 2011-12-21 石国平 Device for detecting and eliminating residual torsional stress of steel cord

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US3771304A (en) * 1971-03-16 1973-11-13 Sumitomo Electric Industries Twisting motion and process for producing wire cords
JPS569489A (en) * 1979-06-29 1981-01-30 Tokyo Rope Mfg Co Detecting and correcting of residual rotation in steel cord

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GB724101A (en) * 1951-06-09 1955-02-16 Jean Alfred Louis Rozieres Improvements relating to the manufacture of cables, ropes and the like
NL101600C (en) * 1957-03-30 1900-01-01
FR1260756A (en) * 1960-03-31 1961-05-12 Courtaulds Ltd Method and apparatus for measuring the nervousness of metallic cords during their manufacture
US3593508A (en) * 1968-05-23 1971-07-20 Gen Cable Corp Apparatus for imparting a predetermined value of twist to a material
DD134881A1 (en) * 1978-02-14 1979-03-28 Werner Fuehrer CONTINUOUS WORKING RECESSING DEVICE COUPLED WITH THE EXPANSION DEVICE
DE3139415A1 (en) * 1981-10-03 1983-04-21 W.H. Küster GmbH & Co KG, 6332 Ehringshausen Process for keeping constant the wire or cord tension in stranding machines and device for carrying out the process
JPS591791A (en) * 1982-06-22 1984-01-07 住友電気工業株式会社 Control of rotary number of wire twisting and gathering machine
JPS61124692A (en) * 1984-11-20 1986-06-12 神鋼鋼線工業株式会社 Method and apparatus for twist control of wire rope
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Publication number Priority date Publication date Assignee Title
US3771304A (en) * 1971-03-16 1973-11-13 Sumitomo Electric Industries Twisting motion and process for producing wire cords
JPS569489A (en) * 1979-06-29 1981-01-30 Tokyo Rope Mfg Co Detecting and correcting of residual rotation in steel cord

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6718624B1 (en) 1999-04-08 2004-04-13 Schleuniger Holding Ag Method for controlling a cable treating device

Also Published As

Publication number Publication date
DE3914330C2 (en) 1991-07-18
DE3914330A1 (en) 1990-10-31
JP2921583B2 (en) 1999-07-19
TR25698A (en) 1993-09-01
DE59006338D1 (en) 1994-08-11
BR9001987A (en) 1991-08-13
DD300116A5 (en) 1992-05-21
EP0396068A2 (en) 1990-11-07
EP0396068A3 (en) 1990-12-19
ATE108232T1 (en) 1994-07-15
JPH0369685A (en) 1991-03-26

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