RU2303669C2 - Machine with fork-like arch, equipped with movable carrier band - Google Patents

Abstract

FIELD: technique for twisting or cabling of multiple-strand wires or cables.

SUBSTANCE: machine has rotating arch section on which wire or cable moves in longitudinal direction during twisting or cabling, carrier band extending along longitudinal surface of arch on which wire or cable is moving, and drive mechanism for moving carrier band in direction of movement of wire or cable. Carrier band is movable at a velocity deviating from that of wire or cable by no more than 5%. According to one of versions of embodiment, machine comprises fork-like arch having opposite ends, inner surface and outer surface, carrier band movable in one direction over inner surface of arch and in opposite direction over outer surface of arch, pulleys positioned in the vicinity of arch ends and adapted for moving carrier band from one arch surface to another, and drive means for driving of carrier band into motion. Machine has stretching means designed for maintaining said carrier band at constant tension.

EFFECT: increased efficiency by reducing friction force occurring as a result of centrifugal force and/or Coriolis interaction force acting upon wire during movement thereof on said arch and reduced tension exercised by wire during movement thereof in arch.

12 cl, 4 dwg

Description

The present invention relates to the field of machines for the production of stranded wire or cable, in particular such machines that use a flyback arc.

Machines for the production of wires or cables, performing double torsion, single torsion, run, etc., are usually used for the manufacture of various types of wires and cables (including wires with or without coating, cables, fiber optic cables, etc. P.). The resulting wires and cables are of the type that contains many twisted cores or wires, and they are made in one step or in two or more stages.

In the case where the cables are made in two stages, first twisted wires are prepared by twisting the wires together using so-called twisting machines or machines for twisting wires in pairs. Then, cables for communication means are made from twisted wires, for example, using stationary tensioners, rotating tensioners (also called drum spinning machines) or other types of rotating equipment.

One type of equipment that is commonly used for twisting two, three, or four wires is a double torsion machine. The resulting retinue elements are called pairs, triads or fours.

This equipment includes a cradle for a coil, around which there is a rotating frame or a flyer arc (which is also simply called an arc), which is rotated around the cradle. Wires for twisting can come from coils (or bobbins) installed in the cradle inside the cage, which are twisted when they are fed to a rotating flyer arc, and then wound on a take-up drum outside the cage. When moving the wire along the flyer arc, it usually moves inside the arc along the guiding path so that the "arc wire" is kept from falling out of the arc. Centrifugal forces due to the rotation of the arc press the wire to the inner edge of the arc.

The configuration described above is called an “inside out” machine. However, the twist wires can also be fed outside of the twist cage and wound around a coil located inside the cradle for the coil. The latter configuration is sometimes referred to as an “outside to inside” machine.

Machines from the outside to the inside are usually preferred for use as individual twisting machines, since the wire can be fed from the storage means of a simpler design having a large capacity. In this case, the cradle for the coil, located inside the cage for twisting, should hold only one coil. The machine from the outside to the inside can also be easily adapted for use with a large number of wires.

In a conventional double-torsion machine, a wire or cable is twisted once when it enters the flyer arc and is twisted again when it exits the flyer arc. The twisted elements thus obtained are sent to a tensioner of any type (for example, to a stationary or rotating tensioner, to a single or double torsion machine, to a tension drum or to extrusion lines), for laying out twisted wires with the formation of a cable for communication means. It is usually produced in one step.

Twisting machines for wires can be horizontal or vertical, depending on the preferred layout of the plant. Examples of such machines using a flyback arc are described in US Pat. No. 5,966,917 and US Pat. No. 5,400,579. By themselves, these types of machines are well known in the cable industry and are hereinafter referred to as "fly-arc machines". Thus, this term covers any machines for the production of wires or cables that use a flyer arc.

In order to maximize the performance of these machines with a fly-arc, the feed speed of the wire or cable can exceed 250 m / min. As a consequence of the increased linear speed, the rotation frequency of the flyer arc must also be increased in order to maintain an appropriate layout in the wire or cable being produced. Thus, the rotation frequency of the flyer arc must be increased to an appropriate degree and can reach 3000 rpm or more. However, various machines for producing wires or cables that use a flyback arc have a performance that is limited, inter alia, by the permissible maximum rotation speed of the flyer arc.

The maximum frequency of rotation of the arc is limited by factors such as: centrifugal force acting on the wire when it moves along the path in the arc, Coriolis forces and friction forces on the surface of the arc. All these forces increase the tension of the wire during its manufacture. However, all types of wires have the maximum allowable tensile, which they withstand for a given period of time, without causing damage of various kinds. In itself, the maximum speed of manufacturing of production equipment is limited by the need to eliminate or reduce to a minimum unacceptable levels of such damage.

Designers of twisting machines have already attempted to limit centrifugal force, Coriolis force and arc friction coefficient, but with limited success. The applicants of the present invention have set themselves the task of solving this problem and providing higher manufacturing speeds and / or higher quality wires or cables by reducing or minimizing the effect of stretching the wire or cable during its twisting or twisting.

To overcome the disadvantages of previously known machines, it is desirable to create a machine with a crooked arc for the production of wires in which the tension applied to the wire being produced is reduced compared to conventional machines, as a result of which it becomes possible to manufacture wires or cables of improved quality and / or manufacture of wires or cables with acceptable quality at higher manufacturing speeds.

Thus, the main objective of the present invention is to provide a machine with a fly-arc for the production of wires, in which frictional forces arising due to centrifugal forces and / or Coriolis forces that act on the wire when moving along the path of movement of the wire in the arc are reduced.

Another objective of the present invention is to provide a machine with a fly-arc for the production of wires, in which a limited tension is maintained or the tension of the wire being manufactured decreases while it moves along the path of the wire in the arc, and more generally when the wire passes through the entire machine with a fly-arc wire production.

The aforementioned and other objectives of the invention are solved in whole or in part by creating a machine with a crooked arc for twisting or twisting wires or cables, which according to the invention contains a rotating arc section along which the wire moves longitudinally or cable when twisting or twisting, carrying a strip passing along the longitudinal surface of the arc along which the wire or cable moves, and the drive mechanism of the carrier strip, which moves the carrier strip in the direction in which the wire or cable spruce.

Preferably, the carrier strip moves at a speed that deviates no more than 5% from the speed of movement of the wire or cable.

Preferably, the carrier strip moves at a speed that deviates by no more than 1% from the speed of movement of the wire or cable.

Preferably, the carrier strip moves at a speed that deviates by no more than 0.1% of the speed of movement of the wire or cable.

Preferably, the arc has inner and outer surfaces, with the carrier strip and the wire or cable moving in the same direction along the inner surface of the arc.

Preferably, the carrier strip moves along the outer surface of the arc in the opposite direction relative to the direction of its movement along the inner surface of the arc.

Preferably, the carrier strip passes through pulleys located in the immediate vicinity of each end of the arc so that the carrier strip moves from one side of the arc to the other side of the arc.

Preferably, at least one of the pulleys is a drive pulley connected to a motorized drive means that drives the carrier strip.

Preferably, the motorized drive means is an electric motor coupled to the drive pulley.

Preferably, the electric motor is connected to the drive pulley via a differential gear.

The above and other objectives of the invention are also solved in whole or in part by creating a machine with a hinged arc, which according to the invention comprises a hinged arc having opposite ends, an inner surface and an outer surface bearing a strip configured to move in one direction along the inner surface of the arc and in the opposite direction along the outer surface of the arc, pulleys that are installed in close proximity to the ends of the arc and serve to move the carrier strip m one surface of the arc to the other, and drive means for driving at least one of the pulleys, whereby the driven carrier strip.

Preferably, the machine further comprises tensioning means for maintaining constant tension of the carrier strip.

In the text of the description of the present invention, the term "fly arc machine" refers to any known wire or cable making machine that uses a fly arc. The present invention is primarily directed to the manufacture of a wire or cable, which may contain coated or non-coated conductors of the wire or cable, and this may be, for example, fiber optic cable. A wire or cable can be made of any suitable ferrous or non-ferrous metal, including, for example, copper, steel or aluminum, however, any other material suitable for use as a wire or cable, or their component, such as plastic, fiberglass, etc.

Specialists in this field of technology know that machines with a fly arc for the production of wires and cables have a wide variety of applications and are intended for the manufacture of a wide variety of products in the form of wires and cables. Thus, although the present invention is described below with specific reference to the manufacture of wires, those skilled in the art will readily understand that the present invention may also find application in various other fields.

A flyer arc can be made from already known materials. Typically, a flyback arc is made of fiberglass or carbon fiber. However, depending on the rotational speed and the linear speed of the wire, specialists can easily apply other well-known materials suitable for arc design. Usually there are two arcs on the same machine with a hinged arc, and although the wire usually moves along only one arc, there are known machines with a hinged arc in which the wire is fed along each arc. The arcs are advantageously balanced in such a way as to minimize rotational vibrations caused by the movement of the arcs.

The endless carrier strip is mainly a loop of the corresponding material, which makes complete movement in a circle. An arrangement may be used in which the carrier strip moves upward inside the same arc and returns inside the opposite arc. Alternatively, the carrier strip may move up and return along one side of the arc. However, the carrier strip mainly moves in the longitudinal direction upward inside the arc, passes through the pulley and returns, when moving in the opposite direction, outside the arc. After this, the second pulley returns the carrier strip from the outside to the inside of the arc. Typically, wires that run along an arc (“arc wires”) come into contact with a carrier strip on the inner surface of the arc.

At least one of the pulleys advantageously communicates with the carrier strip drive means in order to move the carrier strip at a predetermined speed.

The carrier strip may be flat or may have some other acceptable shape. For example, it can be a concave shape, with the wire located in the center of the carrier strip, which helps reduce the likelihood of any damage due to the Coriolis force. The carrier strip is advantageously “infinite” and can be made of any material that provides strength characteristics acceptable for a given application. The carrier strip may be made of fabric or plastic, however, ferrous or non-ferrous metal, but mainly a metal alloy with high tensile strength, such as steel having good strength characteristics and at the same time having low tensile at the expected speeds, is more preferable for its manufacture.

The carrier strip is preferably held in a predetermined position within the channel of the carrier strip on the inner surface of the arc together with the arc wire using the guide wire. The return path of the carrier strip along the outer surface of the arc can be provided using several overlays that support the carrier strip and hold it in a predetermined position on the outer surface of the arc.

According to a preferred embodiment, the carrier strip is driven by a precision variable speed motor and a governor, and advantageously has a differential. Thus, the speed of the carrier strip can be precisely controlled and match the speed of the arc wire. The differential is predominantly connected to the roller shaft using matching belts and pulleys, so that the rotation of the roller arc does not affect the speed of the carrier strip. The crooked shaft is predominantly concentric with the drive shaft of the carrier strip, supported by ball bearings and, in turn, rotates a set of spur gears and, ultimately, the drive pulley of the carrier strip.

Advantageously, a spring tensioner is also provided which maintains the desired level of tension of the carrier strip.

Variants of the invention, as well as its new characteristics, which can be considered distinctive in terms of design, organization of the process, use and method of performing operations, together with additional tasks and advantages of the present invention will be more clear from the following detailed description, given as an example, without limiting character and given with reference to the accompanying drawings, in which similar elements have the same reference position.

However, it must be specifically emphasized that the drawings are provided only to illustrate the present invention and do not limit the scope of patent claims in accordance with the present invention, and in the drawings:

figure 1 is a top view of a known machine with a flyer arc;

figure 2 is a top view of a machine with a fly-arc in accordance with the present invention;

figure 3 is a top view of the section of the flyer arc of the machine shown in figure 2;

figure 4 is a partial perspective view of a section of the flyer arc shown in figure 3.

The operation and design of known machines with a hinged arc is described in detail in various publications, including, for example, in US patent No. 5400549. A general view of the known machine 10 with a hinged arc is shown in FIG. In this example, the flyback machine is an inside-out machine and has a support frame 11, as well as two shrouds 12 and 14, each of which contains a coil with a single-core wire coated, the shrouds being located in section 20 of the main body. The coils located inside the housings 12 and 14 are rotated by an electric motor 16 at such a speed that the wires “W” exit the coils, mainly at the same speed as the linear production speed.

On each side of section 20 of the main body there are arcs 22 and 24, which are connected using brackets 26 with a central axis 28, which, in turn, is connected to an electric motor (not shown) using a pulley 29, which is designed to rotate the arcs 22 and 24 relative to section 20 of the main body. A strand of wire is fed from each coil inside the casings 12 and 14 and passes around the single pulleys 30 to the double pulley 32. Two wires located next to each other then pass through the center of the housing section 20 to the first arc pulley 34 and then to the arc 22. Arcs 22 and 24 rotate around section 20 of the main body so that the first twisting of the wires occurs. The “arc wires” then move along the inside of the arc 22 and pass through various wire guides 36. At the end of the arc 22, the wires flow to the second pulley 38 of the arc, and then exit the machine 10 with a flyer arc. When the arc wires exit arc 22, a second twist is performed so that double torsion is provided in this machine.

The wires then pass through a tension drum (not shown), which pulls the wires through the flyer arc machine. After a tension drum, twisted or twisted wires are wound onto a take-up reel (not shown).

During operation, the linear wire feed speed and the arc speed can be adjusted to provide the appropriate performance for the particular wire tension to provide a given layout distance. In some embodiments, the rotational speed may be 2250 rpm or higher, which gives a twist frequency of 2 times higher, and a linear speed of 250 m / min or higher.

Figure 2 shows a flyback machine 100 in accordance with the present invention. In this embodiment, the machine 100 is installed at an angle, but in general terms is similar to the machine 10 shown in FIG. The machine 100 also includes a block of flyer arches, which is shown in more detail in FIG.

According to this embodiment, the arc 120 has a first pulley 122, a drive pulley 124, a spring tensioner 126, a pulley motor 135 and a drive mechanism 130 for rotating the drive pulley 124, which contains a differential 136 and several gears.

During operation, the pulley motor 135, which is a precision variable-speed motor with a governor, is connected to the differential 136 using pulleys and a belt 145. The output of the differential 136 is connected to the flyer shaft 139 using another set of pulleys and belts 146. The roll shaft is concentric with the drive shaft 138 of the bearing strip mounted in ball bearings and, in turn, rotates a set of spur gears 140, and then a set of bevel gears 141 of the drive pulley 124. Nes the support strip 110 extends along the inside of the arc 120 and passes around the drive pulley 124. Then, the support strip 110 extends along the outside of the arc 120 and passes around the pulley 122 to return to the inside of the arc 120. The spring tension device 126 maintains a suitable tension level of the support strip 110. The carrier strip 110 moves around the arc 120 due to the rotation of the drive pulley 124, with a speed that basically coincides with the speed of the wire along the inner side of the arc 120.

The drive pulley 124 also acts as an output pulley for the flywheel wire, so that the wire W exits the arc of the pulley.

It should be borne in mind that the linear velocity of the carrier strip specified by the control system can be leading, which means that the linear velocity of the wire or cable is equal to the velocity of the carrier strip. The auxiliary tension drum can control the speed of the cable, and the speed control of the carrier strip can be electronic and can match the speed of the tension drum. In some designs, the speed of the carrier strip may be higher than the speed of the wire or cable, which leads to a decrease in tension, or slower than the speed of the wire or cable, which leads to an increase in tension. Thus, it should be borne in mind that various controls can be used to control the tension of the wire or cable, allowing the desired control of tension.

Figure 4 shows a partial perspective view of a section of the flyer arc of figure 3. The arc 120 is made of fiberglass and has an inner surface along which the carrier strip 110 moves. The carrier strip 110 is located within the carrier strip channel 113 formed using the carrier strip guide 112 on the inner surface of the arc 120. The carrier strip 110 extends in the opposite direction along the outer side of the arc 120 and is held in place by the guide wires 114. In this case, for example, two strands of wire W are pressed against the carrier strip 110 on the inner side of the arc 120.

In accordance with the foregoing, it is proposed a machine with a fly-arc in accordance with the present invention, which completely solves all the tasks and provides these advantages. Despite the fact that the preferred embodiments of the invention have been described, it is clear that experts and specialists in this field may make changes and additions that do not, however, go beyond the scope of the following claims.

In addition, it should be borne in mind that the terms “includes,” “includes,” and “has,” as well as variations thereof, are used interchangeably in the description of the invention and in the claims, unless otherwise specifically indicated.

Moreover, the words “substantially” or “substantially” extend the scope of a particular characteristic, for example, “mainly a planar element” means a planar element, an almost planar element and / or an element having characteristics inherent to a planar element.

In addition, despite the fact that a discussion was held of an analogue known to the applicant, it applies to other similar well-known technical solutions.

Claims (12)

1. Machine with a crooked arc for twisting or twisting wires or cables, comprising a rotating arc section along which a wire or cable moves longitudinally while twisting or twisting, a carrier strip extending along the longitudinal surface of the arc along which a wire or cable moves, and a drive mechanism a carrier strip that moves the carrier strip in the direction in which the wire or cable moves. 2. The flyback machine of claim 1, wherein the carrier strip moves at a speed that deviates by no more than 5% from the speed of movement of the wire or cable. 3. The fly arc machine according to claim 1, wherein the carrier strip moves at a speed that deviates by no more than 1% from the speed of movement of the wire or cable. 4. The fly-arc machine according to claim 1, wherein the carrier strip moves at a speed that deviates by no more than 0.1% of the speed of movement of the wire or cable. 5. The fly-arc machine of claim 1, wherein the arc has an inner and outer surface, wherein the carrier strip and the wire or cable move in the same direction along the inner surface of the arc. 6. Machine with a flyback arc according to claim 5, in which the carrier strip moves along the outer surface of the arc in the opposite direction relative to the direction of its movement along the inner surface of the arc. 7. The fly arc machine according to claim 1, wherein the carrier strip passes through pulleys located in the immediate vicinity of each end of the arc so that the carrier strip moves from one side of the arc to the other side of the arc. 8. The fly-arc machine of claim 7, wherein at least one of the pulleys is a drive pulley connected to a motorized drive means that drives the carrier strip. 9. The fly-arc machine of claim 8, wherein the motorized drive means is an electric motor coupled to the drive pulley. 10. The flyback machine of claim 9, wherein the electric motor is connected to the drive pulley via a differential gear. 11. A machine with a flyback arc, comprising a flyer arc having opposite ends, an inner surface and an outer surface, a bearing strip configured to move in one direction along the inner surface of the arc and in the opposite direction along the outer surface of the arc, pulleys that are mounted in the immediate proximity to the ends of the arc and serve to move the carrier strip from one surface of the arc to another, and the drive means for driving at least one of the pulleys, as a result those which are driven by the carrier strip. 12. The fly-arc machine of claim 11, further comprising a tensioning means for maintaining constant tension of the carrier strip.

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