ITUA20170770A1 - Dock for a spinning machine - Google Patents

Description

Quay for a spinning wheel

The invention relates to a quay for a spinning machine equipped with at least one device for twisting and winding a thread on a spindle, which device for twisting and winding is used, in particular, in the operations of spinning a thread in ring spinning machines for allowing the twisting and winding, or winding, of the yarn around a spindle so as to make a spool of a given type of yarn.

There are known devices for twisting and winding a thread on a spindle for a ring spinning machine, each of which comprises an inner ring and an outer ring between which a cage is interposed supporting in predetermined positions a plurality of rolling bodies, arranged at 120 ° relative to each other.

The external ring, fixed, in use is mounted in a circular seat obtained in a platform of the ring spinning machine, while the internal ring is fixed to an external wall of a tube coaxial to a spindle.

In the body of the sleeve there is a hole arranged to house and engage a substantially C-shaped wire guide element inside which in use the wire to be twisted and wound is engaged, which has previously been stretched by means of a plurality of pairs of rollers rotating at different speeds.

The spindle is rotated together with all the other spindles of the same front of the spinning machine by a head motor. The rotation of the spindle stretches the wire, one end of which is fixed to the spindle itself, which rotates the cage, the inner ring, the sleeve, thanks to the interaction between a portion of the wire and an area of the wire guide element . At the same time, during the spinning operations, the quay is suitably operated in a vertical direction, ie along a direction substantially parallel to the axis of each spindle.

The rotary motion of the spindle produces the twisting of the yarn while the latter wraps around the spindle to create a spool.

The productivity of spinning machines of the known type is limited by the speeds of rotation that can be tolerated by the parts in rotary motion.

To increase the number of spools produced, it is therefore essential to reduce the friction between the rolling elements and the rolling tracks in which they roll, while maintaining control over the wire tension.

To this end, in known types of spinning machines, the devices for twisting and winding a thread on a spindle are each provided with a lubrication system comprising at least two through openings formed in the outer ring and arranged to allow passage to its own inside of a taut wick, which is impregnated with oil absorbed by capillarity when it is passed through an oil tank external to the device and arranged upstream of the outer ring. The wick impregnated with oil cooperates by rubbing with a portion of the cage or with a portion of the raceway in such a way that part of the oil is removed and thus ensures that the contact areas between the rolling elements and the raceways are lubricated. .

The lubrication system results in a short life of the devices due to dirt due to oil-soaked hairs that separate from the wick as it rubs to release oil. It follows that the spinning machines equipped with such devices must be frequently overhauled and the dirty devices replaced, with consequent high costs of maintenance and replacement of the devices.

A defect of known spinning machines is that they do not provide a cooling system, for example to limit the heating of the moving parts and, therefore, wear, but the cooling system is external to the spinning machine itself and, therefore, is not efficient. because it does not act directly on the twisting and winding device of a thread on a spindle, but only in the environment in which the spinning machine is placed.

Furthermore, the docks of known types of spinning machines are made by bending a steel sheet and are therefore very heavy.

During a spinning cycle, the speed of each inner ring, cage and tube may need to be varied depending on the stage of the cycle or, for example, when it is necessary to stop and then restart a spindle due to yarn breakage.

In order to reduce the speed imposed by the spindle, on the inner ring, on the cage and on the sleeve, the devices for twisting and winding a thread on a spindle of known type comprise a plurality of magnets, mounted side by side with polarity opposing that interact magnetically with the inner ring generating a braking action. By varying the position of the magnets with respect to the inner ring, you can vary the braking action on each inner ring or on each cage.

In order to vary the position of the magnets, spinning machines of known type comprise a rod which controls all the devices for twisting and winding a thread on a spindle and can be axially operated to act on a lever with which each torsion device is provided and winding of a wire on a spindle that allows an axial or radial displacement of the magnets.

Braking adjustment by means of a rod-lever system is not very precise. In addition, if you want to vary the braking in a single torsion device, you need to release the respective lever from the rod, which requires the manual intervention of an operator with a considerable waste of time.

Furthermore, in known type ring spinning machines, to check if a yarn has broken during the spinning cycle, an operator must travel the entire length of each front of the spinning machine, trying to contact the yarn. When the operator does not feel the contact, he deduces that the thread of a particular spindle has broken.

Consequently, maintenance operations are long and it is not possible to intervene promptly directly on the broken yarn, as it is not visible, given the large number of spindles on the same front of the spinning machine, but it is necessary for the operator to check for each spindle. the presence of the wires until any broken ones are identified. An object of the present invention is to improve the banks of spinning machines of the known type. Another object is to produce a platform for a spinning machine which is more efficient, for example in terms of heat dissipation, than a platform for a known type of spinning machine, and which therefore allows to guarantee a long useful life for the torsion devices. and winding a thread on a spindle mounted on it.

A further object is to produce a bench for a spinning machine which is economical and simple to use and to assemble.

According to the invention, a quay is provided for a spinning machine equipped with at least one device for twisting and winding a thread on a spindle as indicated in claim 1.

The invention can be better understood and implemented with reference to the attached drawings which illustrate an exemplary and non-limiting form of implementation in which:

Figure 1 is a perspective view from above illustrating a plurality of devices for twisting and winding a thread on a spindle mounted on a quay according to the invention of a ring spinning machine;

Figure 2 is a perspective view like that of Figure 1 but from below;

Figure 3 is a section taken along a plane III-III of Figure 1;

Figure 4 is a perspective view of an electronic control unit of a device for twisting and winding a thread on a spindle of Figure 1;

Figure 5 is a bottom perspective view of the electronic control assembly of Figure 4 with a cover removed to show an electronic board;

Figure 6 is an exploded view of the electronic control unit of Figure 4;

Figure 7 is a perspective view from above of a group for twisting and winding a thread on a spindle provided in each of the twisting and winding devices of Figure 1;

Figure 8 is a perspective view like that of Figure 7 but from below;

Figure 9 is a section taken along a plane IX-IX of Figure 7;

Figure 10 is an exploded view of the twisting and winding assembly of a thread on a spindle of Figure 7.

With reference to Figures 1 and 2, a plurality of twisting and winding devices 1 of a thread on a spindle mounted side by side on a quay 2 according to the invention of a ring spinning machine is shown.

Each torsion and winding device 1 is mounted concentrically to a respective circular opening 3 obtained in the platform 2.

In use, a spindle is positioned inside each circular opening 3 which is rotated by a head motor of the spinning machine together with all the other spindles of the same front of the spinning machine. As will be better explained later in the description, the rotation of the spindle stretches the yarn, one end of which is fixed to the spindle itself, which rotates some components of the twisting and winding device 1. At the same time, during the spinning operations, the platform 2 is operated to move suitably in a vertical direction, that is, along a direction substantially parallel to an X axis (Figure 3) of each circular opening 3. Thanks to the torsion and winding device 1, the yarn, previously stretched through a plurality of pairs of rollers rotating at different speeds, is twisted and wound around the spindle in order to create a spool of a specific type of yarn.

The quay 2 according to the invention is made of extruded aluminum which allows its weight to be limited with respect to the quays of traditional spinning machines made by bending a steel sheet, to compensate for the greater weight of the torsion and winding devices 1 compared to the torsion and winding devices of known type, due to the presence of an electromagnet with relative control electronics, for each device, as will be explained below.

Each circular opening 3 can have a diameter of about 75 mm and the distance between the axes X of two adjacent circular openings 3 can be about 82.5 mm. These dimensions make it possible to facilitate the assembly and maintenance operations to be carried out on the torsion and winding devices 1.

Each torsion and winding device 1 comprises an electronic control unit 4, visible in Figure 2 and shown in particular in Figure 4, and a torsion and winding unit 5 visible in Figure 1.

As will be explained better in the following, the twisting and winding assembly 5 comprises rotating components which engage the yarn and are rotated by the tension of the yarn which is stretched between them and the spindle driven in rotation. In this way, these rotating components allow for twisting and winding around the spindle of the wire. The electronic control unit 4 is arranged, in particular, to exert a controlled braking action on the rotating components of the torsion and winding unit 5 based on the progress of a yarn spinning cycle.

During a spinning cycle, in fact, the speed of the rotating components may have to be varied according to the stage of the cycle or, for example, when it is necessary to stop and then restart a spindle due to yarn breakage.

With reference to Figure 3, the dock 2 has a substantially C-shaped section and comprises a plurality of cooling fins 6, protruding from an external side wall 7 of the dock 2 towards the external environment so as to thus increase the surface radiant to favor a dispersion of heat by convection.

In particular, the cooling fins 6 are arranged parallel to each other and substantially cover the entire length of the quay 2.

The cooling fins 6 act as heat sinks, in particular of the heat generated by the torsion and winding unit 5, thus allowing to lower an ambient temperature and prevent the torsion and winding unit 5 and / or the electronic control unit 4 from being overheats causing wear and / or malfunction. With reference to Figures 4 to 6, each electronic assembly 4 comprises a braking device, in particular an electromagnet 9, and an electronic card 10 arranged to control a braking action that the electromagnet 9 exerts on a rotating component of the assembly twisting and winding 5.

Each electronic unit 4 comprises a body 8 preferably made of plastic material, in which a housing 19 for the electromagnet 9 and a further housing 20 for the electronic board 10 are obtained, schematically shown in Figures 5 and 6. The body 8 is shaped approximately parallelepiped-shaped and can have profiles with grooved areas 11 arranged to reduce the volume of the electronic control unit 4 and, consequently, the relative mass, to weigh less on the supporting elements of the spinning machine which must support the platform 2 .

In the body 8 there is also a through hole 12 which, in use, like the circular opening 3, surrounds the spindle.

In order to allow the fixing of the electronic control unit 4 to the platform 2, in the body 8 there are through openings 13 arranged to house connection means 14, of a known type, comprising for example screws and shown from above in Figure 1, which interact with respective connection holes made in the platform 2 and allow to fix the electronic control unit 4 in a predetermined position on the platform 2.

Thanks to an appropriate positioning of the through openings 13 and the connection holes, the through hole 12 and the circular opening 3 are concentric when the electronic unit 4 is mounted on the platform 2.

The Figures show three through openings 13 with respective three connecting means 14 and three connecting holes, but the number of such elements can also be different.

The electronic control unit 4 also comprises a light source 15 arranged to send an optical signal to an operator, or to an optical supervision system, to indicate an operating condition of the torsion and winding unit 5.

The light source 15 can comprise a first light source 16 and a second light source 17 each of which is arranged to emit a light of a different color than the other, for example green and red, respectively. A different meaning known to the operator can be associated with this color, depending on the condition to be indicated.

For example, a condition of good operation of the torsion and winding unit 5 can be associated with the light emission of the first light source 16, i.e. a condition in which the thread is kept under tension and, therefore, is not interrupted, and in which the rotating components of the torsion and winding assembly 5 rotate correctly. Conversely, a malfunction condition of the torsion and winding unit 5 may be associated with the light emission of the second light source 17, due to or due to the fact that the rotating components of the torsion and winding unit 5 do not rotate correctly, which is significant of a problem with the torsion and winding unit 5, or due to the fact that the torsion and winding unit 5 is stationary, which is significant of an interruption of the wire which, being no longer under tension, does not drag the rotating components of the unit of torsion and winding 5 in rotation around the spindle.

The conditions of good operation or malfunctioning of the torsion and winding unit 5 are established on the basis of the effective rotation speed of the rotating components of the torsion and winding unit 5 detected by a speed sensor 18 provided in the electronic control unit 4.

The speed sensor 18 is arranged in a housing 21 obtained in the body 8 shaped in such a way that the speed sensor 18 faces the through hole 12, once mounted in the housing 21. In this way, the speed sensor 18, in use, it is capable of detecting a rotation speed of the rotating components of the torsion and winding unit 5.

The speed sensor 18 can be, for example, of the optical or Hall effect type.

In the event that the speed sensor 18 is optical, it comprises a reflective strip arranged on approximately 50% of the circumference of the through hole 12, so as to accurately detect even the highest speeds (30-40,000 rpm) of the rotating components of the torsion and winding unit 5.

The value of the rotation speed of the torsion and winding assembly 5 is then transmitted by the speed sensor 18 to the electronic board 10 which provides for the comparison between the detected speed value and the set reference value. The set reference value is variable during the spinning cycle, for example as a function of the bobbin manufacturing stage.

The first and second light sources 16, 17 can be powered alternatively by the electronic card 10, in particular by a switch operated by a relay powered by the electronic card 10.

For example, if the rotation speed of the rotating components of the torsion and winding unit 5 falls below a reference value set for the speed of the torsion and winding unit 5, the electronic board 10 commands the relay power the second light source 17, while when the rotation speed of the rotating components of the torsion and winding assembly 5 remains within a range of values around the set reference value, the electronic board 10 commands the relay to keep the first source powered bright 16.

A rotation speed lower than the set reference value of the rotation speed indicates a malfunction of the torsion and winding unit 5, since the rotating components of the latter rotate but at a reduced speed, while a rotation speed in particular equal to 0 is an index of wire breakage as the torsion and winding unit 5 no longer rotates.

The first light source 16 and the second light source 17 can each comprise an LED for generating the respective light emission.

Alternatively, the light source 15 can also comprise a single LED, to which, for example, a condition of good operation of the torsion and winding group 5 is associated when it does not generate a light emission, or to which a malfunction condition is associated. when it is powered, that is when it generates a light emission.

Thanks to the light source 15, the operator is able to establish whether a wire that was twisting and winding a certain twisting and winding device 1 has broken or not just by visually checking the light signal. This prevents the operator from having to travel the entire length of each front of the spinning machine, trying to contact the yarn to check if the latter broke during the spinning cycle.

Consequently, the maintenance operations of the twisting and winding devices 1 of a thread on a spindle are faster than conventional twisting and winding devices and it is possible for the operator to intervene promptly and directly on the broken yarn or on the assembly. of torsion and winding 5 malfunctioning.

Naturally, in order to be visible from the outside and from a distance, the light source 15 must protrude from an upper face 22 of the electronic unit 4 and a suitable passage 23 must be made in the platform 2 to allow that, when the electronic control unit 4 is mounted on the platform 2, the light source 15 protrudes towards the external environment.

The electronic board 10 is powered through a live power supply line 24, on which the electronic board 10 is connected by means of electrical connection plugs 25 when the electronic control unit 4 is mounted on the dock 2. In fact, the electric connection plugs 25 they have a length such as to allow contact with the supply line 24 during assembly. In this way, the electronic board 10 is easily connected to the power supply without the need for additional wiring. This allows for very quick maintenance and assembly.

The power supply line 24 is arranged in a longitudinal seat 26 obtained along the entire length of the quay 2.

The electronic board 10, in addition to controlling the power supply of the light source 15, communicates via a data communication channel, not shown, for example a data transmission bus, with a central control unit of the spinning machine.

The central control unit includes software arranged to manage the spinning cycle and rotate the spindle motors.

The central control unit also sends data to the electronic board 10, on the basis of which the latter controls the torsion and winding unit 5. In particular, the central control unit informs the electronic board 10 of the specific operating parameters for each stage of a spinning cycle.

In turn, the electronic board 10 sends status signals and alarms to the central control unit, for example indicative of a malfunction of the torsion and winding unit 5.

Therefore, a bidirectional communication is established between the electronic board 10 and the central control unit.

The Figures show a power line 24 in the form of an electrified track. In other words, the power supply line 24 comprises a pair of power cables, in particular which supply a direct current. In this case, the data bus uses the same cables as the power line 24.

However, the power supply line 24 can provide several cables, and, correspondingly, the electronic board 10 will comprise a number of electrical connection plugs 25 equal to the number of cables of the power supply line 24, the signal transmission cable being, in this case, independent of the power supply line 24.

The electronic board 10 comprises electronic components 27 of known type, schematically illustrated in Figures 5 and 6, designed to establish communication with the central control unit of the spinning machine and with the light source 15.

The further housing 20 obtained in the body 8 to house the electronic board 10, has a substantially box-like shape open upwards. The electronic board 10 is placed in the assembly phase inside the further housing 20.

The further housing 20 can be made in a single body with the body 8 and can be provided at a first end of the body 8.

A cover 28 is provided to engage with a perimeter 29 of the box-like housing 20 in order to close the latter and protect the electronic components 27 from external bodies, for example from dust.

Like the electronic board 10, the electromagnet 9 is also electrically connected to the power supply line 24 with a fixed connector, not shown, which is automatically engaged during assembly. In this way, maintenance and assembly are quick and easy. For connection to the power supply line 24, suitable electrical tracks are provided, not illustrated, arranged to bring the power supply to the electromagnet 9.

The electromagnet 9 is also arranged on the opposite side of the through hole 12 with respect to the electronic board 10 and is separate from the latter.

The electromagnet 9 can comprise a plurality of packed insulated laminations and a winding with a high number of turns to have the minimum absorption.

The housing 19 of the electromagnet 9 is arranged in the body 8 in such a way that the electromagnet 9, once assembled, at least partially embraces the through hole 12 and, therefore, in use, the torsion and winding assembly 5, at least partially purpose of interacting with a rotating component of the torsion and winding assembly 5 to vary its rotation speed, in particular to exert a braking action on the aforementioned rotating component.

In fact, the electromagnet 9 generates a magnetic field due to the passage of current through its winding. When the winding is powered with a variable current, the magnetic field is itself variable and therefore, so too is the intensity of the braking force produced. By thus driving the current flowing through the winding, it is possible to modulate the intensity of the magnetic field and, therefore, the intensity of the braking action which is naturally proportional to that of the magnetic field.

In particular, during the entire spinning cycle, the electronic board 10 constantly receives the value of the effective rotation speed of the rotating components of the torsion and winding unit 5 detected by the speed sensor 18, the reference value for the speed rotation of the rotating components of the torsion and winding unit 5 so as to obtain correct twisting and tension of the thread around the spool, this reference value being sent by the central control unit to the electronic board 10, and, finally, an operating parameter indicator of the cyclic vertical movement of the quay 2 so that the electronic board 10 can make the necessary corrections according to the real diameter of the wire winding on the spindle, also this parameter being sent by the central control unit to the electronic board 10.

The electronic card 10 compares the detected speed with the set speed. When the detected speed is higher than the set one, it commands an increase in the intensity of the electric current of the electromagnet 9 so as to increase the intensity of the magnetic field generated and, consequently, its braking action, vice versa if the detected speed is lower than that set, it commands a reduction in the intensity of the current of the electromagnet 9 so as to decrease the intensity of the magnetic field generated and, consequently, its braking action.

Furthermore, the electronic board 10, thanks to the modulation of the current which passes through the winding of the electromagnet 9, is able to carry out a starting procedure until the working speed of a torsion and winding unit 5 is reached, for example, after thread breakage and subsequent repair performed by an operator on the basis of operating parameters sent by the central control unit.

The electronic board 10 is therefore able to optimize braking during the entire spinning cycle, depending on the variations in the speed of the yarn as a function of the phases of the spinning cycle.

With reference to Figures 7 to 10, the torsion and winding assembly 5 comprises an inner ring 30 and an outer ring 31 between which an annular positioning element 32 is interposed supporting a plurality of rolling bodies 33 in predetermined positions.

The rolling bodies 33 can be three in number, as in the Figures, substantially arranged at 120 ° with respect to each other, but their number can be varied.

The rolling elements 33 are made of a ceramic material so as to be able to reach and sustain high rotation speeds. In particular, the rolling elements 33 are made of silicon nitride.

The annular positioning element 32 is provided with a plurality of projections 34, substantially C-shaped facing downwards, each of which forms a positioning seat 35 for a respective rolling body 33, said positioning seat 35 being arranged to partially embracing a respective rolling body 33 and maintaining it in the relative aforementioned predetermined position. The plurality of projections 34 is shaped so that, in use, each rolling body 33 is inserted inside a respective positioning seat 35 with play so that it can be free to rotate inside. For this purpose, therefore, the positioning seat 35 must be suitably sized according to the size of the rolling bodies 33.

Each rolling body 33 can have a substantially spherical shape.

In use, the outer ring 31 is fitted on one edge of the circular opening 3 of the platform 2 and is the only component of the torsion and winding unit 5 that does not rotate around the spindle. The outer ring 31 is also arranged to rest on a support seat 51 provided in the body 8 of the electronic control unit 4, shown for example in Figure 6. The support seat 51 is positioned and dimensioned in such a way that when the outer ring 31 rests there, the connection means 14 can interact with a portion of an upper surface 53 of the outer ring 31 to lock it to the platform 2 together with the electronic control unit 4.

The outer ring 31 and the inner ring 30 can be made of a ceramic material, or steel.

The outer ring 31 and the inner ring 30 have a substantially C-shaped section, these sections being turned towards each other during assembly. In fact, an inner surface 36 of the outer ring 31 has a first groove 37, while an outer surface 38 of the inner ring 30 has a second groove 39 which, in use, facing out, make up a rolling track for the rolling elements 33 .

The raceway of the rolling elements 33 can have an oblique contact which allows it to withstand, in addition to radial loads, also axial loads. In this way, the torsion and winding unit 5 is able to counteract an upward traction due to the fact that the traction of the wire is greater than the mass of the rotating rolling elements 33.

The torsion and winding unit 5 also includes a sleeve 40 made of a highly conductive metal material, adapted to interact with the electromagnet 9, and obtained, for example, by turning from an extruded bar. The internal hole of the quill 40 can have a diameter of 55 mm. Aluminum is preferably used as a highly conductive metal material, due to its low specific weight.

It is on the sleeve 40 that the magnetic field of the electromagnet 9 interacts to exert its braking action based on the commands of the electronic board 10.

The inner ring 30 is mounted, in use, against a portion of an outer wall 41 of the sleeve 40. In particular, the inner ring 30 can be fixed to the outer wall 41 by means of a structural adhesive so as to avoid mechanical stress on the inner ring 30. The annular positioning element 32 can be made of a technopolymer suitable for high temperatures, resistant to wear and with a very low coefficient of friction. This technopolymer gives the annular positioning element 32 a high degree of elasticity that allows correct assembly of the rolling elements 33 without requiring deformation of the inner and outer rings 30, 31 ceramic, or steel.

In use, an upper edge 52 of the inner ring 30 is received in coupling with interference in a connection seat of the annular positioning element 32, not shown in the Figures. In this way, the inner ring 30 and, consequently also the sleeve 40, are connected to the annular positioning element 32 which is then coupled during the assembly step to the outer ring 31 so as to be interposed between the inner ring 30 and the outer ring 31.

Once assembled, the inner ring 30, with the sleeve 40 fixed to it, and the outer ring 31 are mounted concentric to the circular opening 3 and, therefore, substantially coaxial to the spindle provided inside the circular opening 3.

Therefore, the diameters of the inner ring 30 and of the sleeve 40 must be smaller than that of the outer ring 31.

Finally, once both the electronic control unit 4 and the torsion and winding unit 5 have been mounted on the platform 2, the connecting means 14 are inserted so that they mutually engage them through the interaction with the through openings 13 of the electronic unit control 4, with the upper surface portion 53 of the torsion and winding assembly 5 and with the connecting holes of the platform 2.

A hole 42 is formed in the body of the sleeve 40 and is arranged to house and engage a guide element 43 for the wire. The guide element 43 is substantially C-shaped, so that one end of the C can be inserted inside the hole 42.

The guide element 43 of the thread is arranged so that the stretched thread to be subjected to twisting and winding is inserted inside it and engages with a portion of an internal area 44 thereof.

When the head motor of the spinning machine rotates a spindle, together with all the other spindles of the same front of a spinning machine, the rotation of the spindle stretches the drawn yarn, one end of which is fixed to the spindle itself, which rotates the sleeve 40 and, consequently, the annular positioning element 32 and the inner ring 30 connected to the sleeve 40 as described above, thanks to the interaction between the wire and the portion of the internal area 44 of the guide element 43.

At the same time, during the spinning operations, the quay 2 is suitably operated in a vertical direction, ie along a direction substantially parallel to the axis of each spindle.

In this way, the rotary motion of the spindle produces the twisting of the yarn while the latter wraps around the spindle to create a spool.

From the above, the rotating components of the torsion and winding assembly 5 are the inner ring 30, the annular positioning element 32, the rolling bodies 33 and the sleeve 40. The outer ring 31 is, on the other hand, fixed .

The guiding element 43 of the wire may comprise a protruding element, not shown in the Figures, made of a ceramic material and arranged to reduce wear and increase the radius of curvature of the wire in transit. This protruding element is fixed in an upper portion of the C of the guide element 43 of the wire.

Thanks to the protruding element, it is possible to prevent impurities, for example any hairs released by the wire, from penetrating inside the torsion and winding unit 5 and, in particular, inside the rolling track, thus affecting the correct rolling of the rolling elements 33.

Furthermore, to avoid the entry of impurities between the rotating components of the torsion and winding unit 5, the torsion and winding device 1 comprises a pressurized air supply system 45 obtained in the body 8, shown in particular in Figure 3.

The pressurized air supply system 45 communicates on one side with a duct 46 obtained in the thickness of the platform 2 through an air supply hole 47 (Figure 6), and on the other side it flows into an upper area of the body 8 located in proximity of the circular opening 3 through an air outlet hole 48.

The air outlet hole 48 is in flow communication with the raceway when the torsion and winding unit 5 and the electronic control unit 4 are mounted on the platform 2.

The compressed air, generated for example by an external pump, is fed to the pressurized air supply system 45 through the duct 46.

The pressurized air supply system 45 can comprise one or more air supply channels formed in the body 8.

A gasket 49, for example an O-ring, is arranged around the air supply hole 47 to keep the pressurized air supply system 45 pressurized.

The gasket 49 is housed in a respective seat 50 obtained in the body 8 of the electronic control unit 4.

The compressed air flow fed to the raceway also serves to cool the rotating components and occasionally provide them with lubrication, for example through a fluidifying agent in the form of powder.

Thanks to the pressurized air supply system 45, it is therefore possible to avoid or minimize lubrication, which significantly extends the life of the rotating components of the torsion and winding unit 5. In particular, the use of an impregnated wick is avoided. of oil used as a lubricating element in the twisting and winding devices of the state of the art which brings dirt, i.e. oil impregnated hairs released from the wick, which affects the life span of the twisting and winding devices of the state of the art. It follows that the maintenance costs of the twisting and winding devices 1 are considerably reduced with respect to the twisting and winding devices of the state of the art.

Furthermore, the torsion and winding devices 1 have a much longer useful life than those of the state of the art also thanks to the use of compressed air introduced into the rolling element raceway 33 through the pressurized air supply system 45 This implies that the maintenance costs are rather low compared to the twisting and winding devices of the state of the art. Furthermore, by eliminating the lubrication by means of oil lubricant there is no need to provide an oil tank, and the overall mass of the quay 2 with the torsion and winding devices 1 mounted thereto is lower than the torsion and winding devices of the state of the technique, weighing to a lesser extent on the supporting elements of the spinning machine.

Thanks to the quay according to the invention, the useful life of the torsion and winding devices 1 mounted on it is even further increased compared to the torsion and winding devices of the state of the art. In fact, the cooling fins 6 acting as dissipators of the heat generated by the torsion and winding unit 5, allow to lower an ambient temperature and prevent the torsion and winding unit 5 and / or the electronic control unit 4 from overheating causing wear. and / or a malfunction.

The torsion and winding devices are very versatile, since both the electronic control unit 4 and the torsion and winding unit 5 can also be mounted on a bench of a traditional spinning machine, ie made of bent sheet metal. The only change to be made to a traditional quay is to provide an electrified power line for the electrical / electronic components of the electronic control unit 4.

In the event of failure or malfunction of a torsion and winding unit 5 it is sufficient for the operator or the optical supervision system to check the light sources 15, thanks to which he can promptly intervene on the torsion and winding unit 5 affected by the failure or malfunction, which makes the maintenance operations of the twisting and winding devices 1 of a thread on a spindle quicker than with known twisting and winding devices.

Furthermore, both the electronic control unit 4 and the torsion and winding unit 5 can be mountable in plug-and-play mode on the platform 2 and no specific electrical installation procedures are required thanks to the absence of wiring, this greatly simplifying operations. assembly and maintenance.

Again, thanks to the electronic board 10, the braking action exerted by the electromagnet 9 on the tube 40 is controlled very efficiently. In fact, an electronic board 10 is provided for each torsion and winding device 1 associated with a respective spindle, so as to control a single braking device on the basis of the detected rotation speed of the rotating components and the characteristic parameters of the various stages of a spinning cycle, allowing to increase both the productivity and the quality of the yarn obtained.

Claims (7)

CLAIMS 1. Bench (2) for a spinning machine equipped with at least one twisting and winding device (1) of a thread on a spindle, said bench (2) being made of extruded aluminum and comprising at least one circular opening (3) to house a spindle of said spinning machine, an external side wall (7) and a plurality of cooling fins (6) projecting from said external side wall (7) towards an external environment so as to increase a radiating surface of said platform (2). Dock (2) according to claim 1, wherein said cooling fins (6) of said plurality of cooling fins (6) are arranged parallel to each other and run substantially the entire length of said dock ( 2). Platform (2) according to claim 1 or 2, wherein said twisting and winding device (1) comprises an outer ring (31) fitted on said circular opening (3). Dock (2) according to one of the preceding claims, and further comprising a longitudinal seat (26) running along the entire length of said dock (2) and housing a power supply line (24) arranged to power an electronic board ( 10) of said twisting and winding device (1). Dock (2) according to one of the preceding claims, and further comprising a duct (46) obtained in a thickness of said dock (2) to allow the passage of compressed air to be introduced into a pressurized air supply system ( 45) of said twisting and winding device (1). Platform (2) according to one of the preceding claims, and further comprising a passage (23) obtained in a thickness of said platform (2) to allow a light source (15) of said twisting and winding device (1) protrudes towards the external environment. Bus platform (2) according to one of the preceding claims, having a substantially C-shaped section.