This application is related to and claims the benefit of Italian Patent Application No. 102020000030290, filed on Dec. 10, 2020, the contents of which are herein incorporated by reference in their entirety.
The present disclosure relates to a twisting flyer for single-twist cable stranding machine.
The sector to which the disclosure relates is industrial equipment and plant for the production of cables and of insulated multipolar wires, multi-filament strands of copper, steel ropes, and the like, where the requirement is to join two or more elements in order to build a stranded assembly with a determined pitch. In particular, the disclosure has applications in rotating machines, known in the sector as “cable stranding machines”, which are used for the formation of a stranded product and for collecting it on a spool, starting from the individual elements that go to make it up (filaments, single cores, strands, cables, complex conductors etc.), and more specifically in single-twist stranding machines.
As is known, a single-twist cable stranding machine is substantially a rotating winder, the collection spool of which rotates inside a structure which also rotates about a same rotation axis and is known in the sector as a “rotor” or “flyer”. The rotation of the flyer/spool system produces a twist of the cable for each single turn of the flyer (in fact, the term “single-twist” indicates the situation wherein one twist of the cable is obtained with one turn of the flyer).
The relative rotation speed between the flyer and the collection spool determines the stranding pitch, while the line speed is given by the product of the rotation speed of the flyer and the stranding pitch.
For the same stranding pitch, the greater the rotation speed, the higher the productivity of the machine.
The cable thus stranded is distributed using a guide pulley over the width of the collection spool using an adapted deposition system. Two types of single-twist cable stranding machines are known: “with a cantilevered shaft”, and “with tailstocks”.
In the first type, the deposition of the stranded cable occurs by means of the translation of the collection spool, which is supported by a shaft of large dimensions.
In the second type, the deposition of the stranded cable occurs through the translation of a guide pulley, while the spool, which does not translate, is supported between two mutually opposite tailstocks.
In this second type of machine, “with tailstocks”, the system that supports one of the two tailstocks is constituted by a shaft provided with an entrainment faceplate, conveniently motorized, which is used to make the collection spool rotate. The shaft can translate axially in order to allow the opening and closing of the tailstock clamping the spool during the step of loading and unloading thereof On the other side, the system that supports the other tailstock does not translate and is idle, therefore it rotates by entrainment.
The flyer in this type of machine typically is made up of a structure with crossmembers which are supported by two shoulders, in the internal space of which the collection spool is accommodated coaxially.
The stratification of the cable on the collection spool is achieved by way of the translation of a guide pulley which deviates the route of the cable toward the spool. Such pulley is coupled to a ring of large dimensions which rotates concentrically around the spool and is supported by guide bushings which slide on the supporting crossmembers.
As an alternative to the translating-ring structure, some machines, which also fall into the “with tailstocks” category, but that are dedicated to different uses (with spools of large dimensions, greater weights and higher pull rates of the stranded cable) have a flyer which is produced with a steel crossmember that rotates around the collection spool. In this case the cable deposition system has a carriage holding the guide pulley which can slide on rails along the crossmember. A machine of this type, with a rotating steel crossmember, has a structure and components of large dimensions and considerable inertia, which impose a major limitation on the rotation speed and consequently on production.
In a machine with a translating and rotating ring, the differing deformation (in direction and intensity) of the ring and of the supporting crossmembers, caused by centrifugal forces, entails major friction forces on the sliding bushings. To combat these friction forces, which moreover increase proportionally with rotation speed, motors and transmission elements must necessarily be over-dimensioned with respect to a condition with low friction forces.
In addition, the deformation of the structure in any case entails an unbalancing of the entire system of rotation, which induces significant and risky vibrations on the machine in general.
Also, another drawback is encountered in the fact that during the rotation the cable to be stranded bends outward owing to the centrifugal force due to its weight, a phenomenon that increases proportionally with the rotation speed.
In general, in both versions described of a single-twist cable stranding machine “with tailstocks”, owing to the drawbacks highlighted which are caused by the considerable rotating masses and by the effects of centrifugal forces, the rotation speeds are typically limited to between 350 and 500 rpm, with collection spools of 800-1000 mm in diameter.
For larger dimensions of spools, considering that the rotating structure must necessarily be larger, the speeds are further reduced.
The present disclosure provides a flyer for a single-twist cable stranding machine, of the type “with tailstocks”, which is capable of improving the known art in one or more of the above mentioned aspects.
Within this aim, the disclosure provides a flyer for a cable stranding machine that can operate at a higher rotation speed than conventional flyers, thus making the machine more productive.
The disclosure also provides a flyer of lower weight than conventional flyers which can be applied to the same machines.
The disclosure advantageously limits, even at high speeds, deformations of the structure and wear of the mechanical elements involved in the translation of the flyer, such as guide bushings, traction cords, guide pulleys, belts, shafts and bearings.
The disclosure is able to scale up the drive unit of the flyer.
The disclosure contains the deformation of the cable outward owing to the action of centrifugal forces.
The present disclosure overcomes the drawbacks of the background art in a manner that is alternative to any existing solutions.
The disclosure provides a twisting flyer for a cable stranding machine that is highly reliable, easy to implement and of low cost.
This aim and these and other advantages which will become better apparent hereinafter are achieved by providing a twisting flyer for a single-twist cable stranding machine, which is adapted to rotate about a rotation axis and is characterized in that it comprises two shoulders connected by crossmembers, and an articulated structure which is adapted to translate on said crossmembers and which comprises in turn:
Further characteristics and advantages of the disclosure will become better apparent from the detailed description that follows of a preferred, but not exclusive, embodiment of the flyer for a cable stranding machine according to the disclosure, which is illustrated by way of non-limiting example in the accompanying drawings wherein:
With reference to the figures, the twisting flyer according to the disclosure, generally designated by the reference numeral 10, being designed for a single-twist cable stranding machine, with tailstocks, is adapted to rotate about a rotation axis, here indicated with A, which matches the winding axis of a cable 11. The cable 11 is joined by the machine and deposited on a collection spool.
Inside the twisting flyer 10, on the same rotation axis A, a takeup spool 30 of the cable 11, shown in dotted lines in
The twisting flyer 10 comprises two shoulders 12 which are connected by crossmembers 13, four in the example shown.
The twisting flyer 10 advantageously comprises an articulated structure 14, substantially quadrilateral, which is adapted to translate on the four crossmembers 13 and which comprises in turn:
The articulated structure 14 also comprises:
In an embodiment not shown, the rods 20 and 21 can have a curved shape, defining overall a substantially circumferential structure.
The articulated structure 14, with the carriages and the guide pulley 17, constitute a wire-guide system that is adapted to translate rigidly along the crossmembers 13, pulled by a motor, in a conventional manner, using a steel cable coupled to the respective carriages, the first carriage 15 and the second carriage 18, with the clamps 24a and 24b, which are installed on the carriages. This cable is not shown, in order to simplify the illustration. It passes through a system of idle pulleys 25a and 25b, which are coupled to the shoulders 12 of the flyer 10.
There is also a system of pulleys, including the pulley 26 installed on one shoulder 12 in a cantilever fashion directed outward. The cable 11 to be stranded undergoes one twist for each turn of the flyer 10 and is conducted on the flyer through the pulley 26 and is deviated by the guide pulley 17 toward the collection spool 30.
In the example shown, the means for translation 16 for the first carriage 15 and for the second carriage 18 are constituted by sliding bushings with which they are adapted to translate on the crossmembers 13, the latter having a circular cross-section. In particular, the crossmembers 13 are tubular elements coupled with their ends to the shoulders 12 of the structure.
The sliding bushings are conventional per seand are made preferably of plastic material and in two symmetrical parts, in order to follow the deformation of the crossmembers 13 during the rotation of the flyer 10.
The balancing weights 22a and 22b comprise at least one block which is fixed to each one of the rods, of the first pair 20 and of the second pair 21.
The twisting flyer 10, according to the disclosure, also comprises stroke limit sensors 27 and 28 for the first 15 and second 18 carriages, which are installed on the crossmembers 13, proximate to the ends thereof, in particular on two of the crossmembers. Sensors 27 are mounted on one of the crossmembers 13 and are adapted to detect the presence of the first carriage 15, while sensors 28 are mounted on the other crossmember 18 which have a spring on which contact can occur with the carriage 18 or with a bushing. The contact or the presence detected by the sensors 27, 28 activates a control system which stops the cable stranding machine, thus preventing damage owing to a possible overtravel of the carriages.
Advantageously, the twisting flyer 10 according to the disclosure comprises a pair of arc-like elements 23, each one fixed via brackets 33 with the ends to the two shoulders 12 at at least one pair between the first crossmembers and the second crossmembers 13 and at a distance from the rotation axis A that is greater than the distance of the crossmembers 13 from that axis A. The function of such arc-like elements 23 is to contain the cable 11. Being adapted to rotate with the rest of the structure of the flyer about the rotation axis A, their purpose is to contain the camber of the cable caused by the centrifugal force acting on it owing to the high rotation speed and deriving from the weight of the cable itself The heavier the cable and the less it is subjected to traction during its unreeling (an increase in the traction can sacrifice its quality), the greater the deformation of the cable.
Conveniently the transverse cross-section of each arc-like element 23 has a concave surface directed toward the rotation axis. Such arc-like element is preferably made of composite material and is covered with plastic material by virtue of which the concave surface has an anti-friction finish which, as a consequence, protects the object from the wear owing to slipping of the cable.
Operation of the twisting flyer, according to the disclosure, is the following.
When the stranding machine in which the twisting flyer 10 is installed is put into operation, the flyer is made to rotate. During the rotation the articulated structure 14 performs a translational motion with the first 15 and second 18 carriages, along the crossmembers 13. The speed of displacement of the system determines the pitch of deposition of the cable 11 on the spool 30, which is installed concentrically in the space defined by the articulated structure 14.
The twisting flyer 10 is made rotate with a different angular speed from that of the spool 30 and is adjustable as a function of the desired stranding pitch.
During the rotation of the twisting flyer 10 the centrifugal forces owing to the weight of the carriages 15 and 18, with the pulley 17 and the counterweight 19, are balanced by the centrifugal forces generated by the balancing weights 22a and 22b mounted on the hinged rods. Therefore, during the rotation of the articulated structure 14, when the carriages translate on the crossmembers, no friction forces are generated.
Owing to the balancing of the forces, the center of gravity of the system is on the rotation axis A, thus preventing vibrations of the structure. The articulated structure 14, which is rendered elastic by the hinges, follows the deformation of the supporting crossmembers caused by the centrifugal forces, thus avoiding interference (and therefore great friction forces) on the sliding bushings, contrary to what happens in conventional rigid systems with an annular structure.
The structure of the twisting flyer according to the disclosure has lower volume, mass and inertia than conventional structures, with consequent possible resizing of the drive unit used for the rotation (less air friction, less rolling resistance in the bearings).
The balancing at all speeds of the forces acting on the guide bushings for the translation results in a reduction of the friction forces thereon, and therefore also in a reduction of wear of the sliding systems and of the elements in motion in the machine, such as cords, belts, pulleys, shafts, and bearings. A greater slideability of the wire guide system results in less friction forces to combat and in a scaling up of the drive unit designed to the translation.
With the balancing of the centrifugal forces, which occurs at any rotation speed, the drive unit can be increased, with consequent increase of the line speed and therefore of the productivity of the machine.
It should also be noted that, by virtue of the arc-like element, it is possible to contain the deformation of the cable without limiting the number of revolutions per minute of rotation, as by contrast happens in conventional flyers.
The twisting flyer according to the disclosure can reach speeds of 1000 rpm with spools of 630 mm diameter, while containing the deformation of the cable and thus preventing it from becoming entangled in other parts of the machine.
In practice it has been found that the disclosure fully achieves the intended aim and objects by providing a twisting flyer for a single-twist cable stranding machine, which makes the machine more productive and more efficient than conventional solutions, while at the same time limiting wear on the sliding means and on the moving elements.
The disclosure thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the appended claims. Moreover, all the details may be substituted by other, technically equivalent elements.
In practice the materials employed, provided they are compatible with the specific use, and the contingent dimensions and shapes, may be any according to requirements and to the state of the art.
Number | Date | Country | Kind |
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102020000030290 | Dec 2020 | IT | national |