Rewinding machine and winding method

The rewinding machine includes a path for feeding a web material; a first winding roller and a second winding roller defining a nip, across which the web material passes; downstream of the nip a third winding roller with movable axis, cooperating with the first winding roller and the second winding roller to form a winding cradle for the rolls. An auxiliary winding roller with movable axis is also provided, which can be inserted between the first winding roller and the second winding roller downstream of the nip.

TECHNICAL FIELD

The present invention relates to the field of the web material converting machines, and in particular the field of paper converting machines. More in particular, the invention relates to the so-called rewinding machines, that wind a web material, for example a single- or multi-ply tissue paper sheet, to form rolls destined for consumption.

BACKGROUND ART

In the paper converting field and in other industrial sectors machines are known to produce rolls of web material starting from reels of large diameter, which are unwound in specific unwinding machines that feed winding or rewinding machines. These latter wind the web material to form rolls of diametrical dimensions equal to the dimensions of the product destined for consumption. These rolls present, in some cases, an axial extension which is a multiple of the length of the rolls destined for consumption, and are therefore subsequently cut to transform the rolls or logs produced by the rewinding machines into individual rolls or small rolls of lower diameter for packaging and marketing.

These rolls are usually formed through winding around a tubular winding core, typically made of cardboard or plastic. The winding core remains inside the finished product. US-A-2005/0279875 and other documents of the same patent family describe a rewinding machine particularly designed for producing tissue paper rolls around winding cores.

In other cases the rolls are wound around removable spindles, that are extracted from the roll or log once this latter has been finished and unloaded from the rewinding machine. U.S. Pat. No. 6,565,033 and U.S. Pat. No. 6,752,345 describe a winding system with removable spindle.

Also machines have been provided for producing logs or rolls of web material, typically tissue paper, without winding spindle or core. U.S. Pat. Nos. 5,538,199; 5,603,467; 5,639,046; 5,690,296; US-A-2009/0101748 describe examples of this machine type.

The machine described in U.S. Pat. No. 5,639,046 comprises for instance: a path for feeding the web material; a first winding roller and a second winding roller defining a nip across which the web material passes; downstream of the nip, a third winding roller with a movable axis cooperating with the first winding roller and with the second winding roller to form a winding cradle for said rolls and, upstream of the nip, a surface delimiting a channel for forming the first winding turns of each roll.

This winding technique has several advantages if compared with the traditional systems for winding around winding cores or spindles, and also if compared with the systems for winding around removable spindles. In particular, with the same outer diameter, the rolls formed without winding core or spindle have a greater quantity of wound web material, i.e. they have, with the same quantity of wound material, a lower bulk. The storage and transport costs are thus reduced. As there is no need for a winding core, there is consequently no need in the production line for a machine for producing the winding cores, a so-called core winder. This leads to a greater ease in the line arrangement, to space-saving and to a reduction in the labor costs for managing the production line. Also the production costs decrease, as there is no more consumption of cardboard and glue necessary for producing the tubular winding cores.

If compared with the winding systems with removable spindle, the winding systems without spindle and without tubular core do not require complex mechanisms for removing and recycling the winding spindles.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a rewinding machine. in particular a peripheral, preferably automatic and continuous rewinder, allowing to produce full rolls, i.e. rolls without winding spindle or core, of higher quality than the rolls that can be obtained with known machines. In the present description, peripheral rewinding machine means a machine, wherein winding is obtained by imparting to the roll a rotary and winding motion through contact with movable surface members, i.e. members acting on the cylindrical surface of the roll being formed. The machine is automatic as subsequent winding cycles are automatically performed without the need for the operator to intervene. The machine is furthermore called continuous as winding substantially occurs at a continuous feed speed, without interruption, preferably at a substantially constant speed of the web material being wound.

Substantially, according to the invention a rewinding machine is provided for producing rolls of web material comprising: a path for feeding the web material; a first winding roller and a second winding roller defining a nip across which the web material passes; downstream of said nip, a third winding roller with movable axis cooperating with the first winding roller and with the second winding roller to form a winding cradle for winding said rolls, wherein, downstream of the nip between the first and the second winding roller an auxiliary winding roller with movable axis is furthermore provided, which can be inserted between the first winding roller and the second winding roller. The auxiliary winding roller approaches the roll in the initial forming phase before the roll formed during the previous cycle has been completely unloaded from the machine, and therefore before the third winding roller with movable axis has come into contact with the new roll being formed.

This arrangement allows a better control over the roll in the first forming phase. This allows, in some embodiments, a greater uniformity in the winding density. In particular, if the roll is kept into contact with at least three winding rollers substantially over all the winding cycle, the density change is avoided that, in the known winding machines without core, is due to the fact that the first winding phase is performed between only two winding rollers. In fact, during this phase the pressure applied by the winding rollers is high, to maintain control and grip over the roll, and the winding density is consequently higher than during the remaining phase of the roll forming cycle. The present invention can reduce or eliminate this problem.

In other preferred embodiments of the invention the auxiliary winding roller has a smaller diameter than the first winding roller, the second winding roller and the third winding roller. The diameter of the auxiliary winding roller can be for instance less than one third and preferably equal to or lower than a quarter of the diameter of the smallest among the first, the second, and the third winding roller. The third winding roller has usually a smaller diameter than the first and the second winding roller. Such a reduced diameter of the auxiliary winding roller allows to insert this roller deeply inside the space delimited between the first and the second winding roller, moving it near the median plane of the nip between the rollers. It is also possible for the cylindrical surface of the auxiliary winding roller to enter until the laying plane of the axes of the first and of the second winding roller, i.e. until (or beyond) the centerline of the nip between the first and the second winding roller. The auxiliary winding roller is preferably movable along a substantially circular trajectory, which is preferably nearly coaxial with the first winding roller. This allows to obtain a particularly compact and simple structure. However, it is also possible to support and move the auxiliary winding roller in a different manner.

In advantageous embodiments, among the three winding rollers the first winding roller, around which the auxiliary winding roller moves, is the one which guides the web material, i.e. the one around which the feed path of the web material extends.

In some embodiments the auxiliary winding roller is supported by a plurality of support elements forming a comb-shaped bearing structure. The auxiliary winding roller is preferably subdivided into a plurality of substantially coaxial cylindrical elements. In some embodiments the cylindrical elements are keyed on a common shaft. The comb-shaped bearing structure forms a series of supports distributed along the axial extension of the auxiliary winding roller, allowing this latter to have a very small diameter. The shaft, onto which the cylindrical elements forming the auxiliary winding roller are keyed, is advantageously motorized. A motor is preferably provided for the rotation of the auxiliary winding roller distinct from the motor or motors controlling the rotation of the other rollers of the machine. These can be driven into rotation by a single common motor, or by two or also by three distinct motors, one for each said first, second, and third winding roller. A central control unit can electronically control the motors, maintaining them phased. To this end encoders for the various motors could be adequately provided.

In improved embodiments of the invention the first winding roller is supported with a movable axis. This allows to change in a controlled manner the centre-to-centre distance between the first and the second winding roller, to optimize the initial phase of winding of each roll and the passage thereof through the nip between the first winding roller and the second winding roller toward the winding cradle defined between the first, the second, and the third winding roller.

In some embodiments the first winding roller is supported by a pair of arms hinged around a pivoting axis substantially parallel to the axis of rotation of said first winding roller. This pivoting axis of the arms supporting the first winding roller can be advantageously arranged downstream of the nip between the first and the second winding roller, near the oscillation or rotation axis of a pair of arms supporting the third winding roller and imparting thereto the necessary pivoting movement to allow a controlled diameter increase of each roll being formed in the winding cradle.

In advantageous embodiments the motor driving the auxiliary winding roller into rotation can be carried by one of the arms supporting the first winding roller.

In some embodiments, starting the winding of a roll can directly occur between the first and the second winding roller. These winding rollers can be moved for instance towards one another to grip the web material in the nip between the rollers, cause the breakage thereof and start to wind the initial free end formed by severing the web material. In other embodiments the machine preferably comprises a plate upstream of the nip between the first winding roller and the second winding roller. The plate can be provided with a movement toward the first winding roller to pinch the web material between the plate and the roller. In advantageous embodiments the plate forms with said first winding roller a channel inside which the winding of the rolls starts. The plate is preferably arched and extends around the first winding roller with a concavity facing the rotation axis of the first winding roller. The plate is preferably provided with a gradual movement away from the winding roller to allow forming the first turns of web material of each roll.

The third winding roller and the auxiliary winding roller are preferably controlled so that, while a first roll in the winding final phase is moved away from the first winding roller into contact with the second winding roller and the third winding roller, said auxiliary winding roller is inserted between the first winding roller and the third winding roller towards the nip formed between the first and the second winding roller, towards a second roll in initial winding phase passing across said nip and coming into contact with said auxiliary winding roller.

The third winding roller and the auxiliary winding roller are preferably controlled so that, when the first roll has been discharged from the winding cradle, the third winding roller is put into contact with the second roll for at least one part of the winding cycle.

According to another aspect of the invention, a method is provided for winding rolls of web material without a winding core, comprising the steps of:providing a first winding roller and a second winding roller defining, there between, a nip across which the web material is fed;providing a third winding roller with movable axis downstream of said nip, defining with said first winding roller and said second winding roller a winding cradle;winding at least one part of a first roll of web material into contact with said first winding roller, said second winding roller and said third winding roller;moving the first roll away from the first winding roller maintaining it into contact with said second winding roller and said third winding roller;inserting an auxiliary winding roller between said first roll and said first winding roller;engaging a second roll in an initial winding phase between said first winding roller, said second winding roller and said auxiliary winding roller, after having interrupted the web material when the first roll has been formed.

In some embodiments, the method according to the present invention comprises the steps of:unloading the first roll from the winding cradle;moving the third winding roller towards the second roll, maintaining the second roll into contact with said first winding roller, said second winding roller and said auxiliary winding roller for a part of the winding cycle.

In preferred embodiments the method according to the invention comprises the step of moving the auxiliary winding roller away from the second roll, continuing winding the second roll into contact with the first winding roller, the second winding roller and the third winding roller.

Further features of the method and the machine according to the invention are described hereunder with reference to an embodiment and in the appended claims, which form an integral part of the present description.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

With initial reference toFIGS. 1, 1A, and 2, the main elements of a rewinding machine according to the invention will be described, only as regards the parts and the components necessary for comprehending the invention. The machine in its entirety can comprise other components, groups, devices and accessories, known to those skilled in the art and that will not be described.

The machine, indicated in its entirety with number1, comprises a feed path for a web material N. The path is defined by a series of rollers and, in particular, by a pair of rollers2and3arranged downstream of a perforating unit5and upstream (with respect to the feed direction of the web material N) of a winding head indicated in its entirety with number7. The perforating unit5comprises, in a known manner, a rotating roller5A comprising blades5B cooperating with a counter blade5C carried by a fixed roller or by a beam5D. The structure of the perforating unit5is known per se and will not be described in greater detail. The perforating unit5transversally perforates the web material N, which advances at a substantially constant speed according to the arrow fN, forming perforation lines substantially orthogonal to the machine direction, i.e. to the longitudinal extension of the web material N. The perforation lines subdivide the web material N into small sheets that can be detached singularly.

In an advantageous embodiment the winding head7comprises a first winding roller11and a second winding roller13, between which a nip15is defined through which the web material N is advanced. The first winding roller11rotates according to the arrow fl1about its own axis11A, whilst the second winding roller13rotates about an axis13A according to the arrow f13.

In some advantageous embodiments the first winding roller11is supported at its ends by a pair of arms17, only one of which is shown inFIG. 1, pivoted around an oscillation axis17A. The oscillation of the arms17according to the double arrow fl7is imparted by an actuator19connected to the pair of arms17through rods21(see alsoFIG. 2).

The first winding roller11and the second winding roller13, together with a third winding roller23, define a winding cradle22inside which occurs at least one part of the winding cycle of each log or roll formed by the rewinding machine1, as it will be better explained hereunder with reference to the sequence ofFIGS. 3 to 8.

The third winding roller23is supported by a pair of oscillating arms25, hinged around an axis25A so that the axis23A of the third winding roller23can move around the axis25A. The oscillation of the arms25is controlled by an actuator29through rods27. The axes11A,13A, and23A of the winding rollers11,13, and23are substantially parallel to one another.

InFIG. 2, 11B indicates the rotation shaft of the first winding roller11. Rotation is imparted to the shaft11B, and therefore to the first roller11, by a motor31that, in the illustrated example, is coaxial with the first winding roller11and is carried by one of the arms17.

Flanks33are supported on the shaft11B through the interposition of bearings35. The flanks33can thus oscillate or rotate about the axis11A of the first winding roller11. The oscillation or rotation movement of the flank33is imparted by an actuator37through rods39hinged at41to the two flanks33(see in particularFIG. 2). A comb-shaped bearing structure43is supported on the flanks33, which supports a shaft45with an axis substantially parallel to the axis11A of the first winding roller11. Cylindrical coaxial elements47are keyed on the shaft45so as substantially to form an auxiliary winding roller48, whose axis is parallel to the axes of the winding rollers11,13, and23. As shown in particular inFIGS. 1 and 2, the diameter of the auxiliary winding roller48is much smaller than the diameter of the winding rollers11,13, and23. The diameter of the auxiliary winding roller48is typically of such dimensions that it can be inserted inside the space defined between the first winding roller11and the second winding roller13downstream of the nip15for feeding the web material, until arriving near the plane on which the axes11A and13A of the rollers11and13are located. Substantially, the auxiliary winding roller48can be practically brought to the nip15, i.e. at the central point of this nip matching with the plane on which the above mentioned axes11A and13A of rotation are located.

The bearing structure43supporting the auxiliary winding roller48is hinged about an axis43A carried by the flanks33, preferably matching with the axis around which the rods39, which connect the flanks33to the actuator37, are hinged. An elastic element51, visible in particular inFIG. 2, is mounted on at least one of the flanks33. The elastic element51can be constituted by a pneumatic cylinder-piston actuator, acting as an air spring. According to other embodiments, the elastic element51may comprise a tension spring.

The elastic element51holds the bearing structure43, and therefore the auxiliary winding roller48, in a position of maximum approach to the rotation axis11A of the first winding roller11, however allowing a movement of the winding roller48away from the rotation axis11A of the first winding roller11in case of emergency, as it will be explained below. If the elastic element51is in the form of a cylinder-piston actuator, it can be also used in some embodiments to lift the auxiliary winding roller48and the corresponding bearing structure43for machine maintenance, repair or cleaning purposes.

In some embodiments the auxiliary winding roller48is driven into rotation by its own motor53. The motor53is preferably carried by one of the arms17supporting the first winding roller11. More in particular, to optimize the bulk and the arrangement of the various machine members, the motor53is carried by the arm17opposite to the arm17carrying the motor31that actuates the first winding roller11. The motor53actuates a pulley54that transmits the motion, through a belt55, to a double pulley56advantageously supported on the shaft11B of the first winding roller11. Around the double pulley56a further belt56is driven, which transmits the motion, through a further double pulley58, to a third belt59, driven in turn around a further pulley60keyed on the shaft45of the auxiliary winding roller48. The pair of flanks33supporting the bearing structure43can oscillate around the axis11A of the first winding roller11under the control of the actuator37, thus making the axis of the auxiliary winding roller48to follow a circular trajectory coaxial to the winding roller11, whilst the arrangement of belts and pulleys described above endures the rotary motion transmission from the motor53to the auxiliary winding roller48in any angular position of the bearing structure43and of the flanks33.

Upstream of the nip15(relative to the feed direction of the web material) a plate61is arranged, carried by a beam63which is, in turn, carried by flanks65hinged around the axis13A of the second winding roller13. At least one of the flanks33carries a feeler for a cam69rotating about an axis69A according to the arrow f69. The plate61can advantageously have a projection61A, extending transversally to the feed direction of the web material N and therefore parallel to the axis11A of the first winding roller11, for gripping the web material N on the cylindrical surface of the first winding roller11so as to cause the severing thereof in a synchronized manner with the winding cycle of each roller, as described below with reference to the operation cycle illustrated in the sequence ofFIGS. 3 to 8.

The machine described hereinbefore operates in the following way. InFIG. 3a first log or roll L1of web material N has been completed and is in a position comprised between the second winding roller13and the third winding roller23, during the ejection phase toward a slide24. The forward movement of the completed roll L1toward the chute24can be obtained by varying the rotation speeds of the winding rollers, for instance by reducing the rotation speed of the winding roller13and/or increasing the speed of the winding roller23, so as to generate a difference between the peripheral speeds of the rollers13and23. The change in the peripheral speed of the rollers also allow further operations, for instance tensioning the web material N to facilitate the severing thereof and making a roll in the initial forming phase to pass across the nip15.

To start winding a subsequent roll, the plate61is pressed against the cylindrical surface of the first winding roller11, so that the projection61A of the plate61pinches the web material N against the surface of the winding roller11. The movement of the plate61toward the first winding roller11is controlled by the cam69acting on the feeler67causing the flanks65, carrying the beam63supporting the plate61, to oscillate about the axis13A. As the surface of the plate61is substantially stationary, the web material N pinched between the projection61A of the plate61and the cylindrical surface of the first winding roller11is suddenly stopped, thus causing severing of the web material N between the pinch point defined by the projection61A and the completed roll L1. To this end it is possible to provide that the surface of the plate61or a part thereof (for example the projection61A) is treated or coated so as to have a friction coefficient preferably greater than the friction coefficient of the cylindrical surface of the winding roller11.

In some embodiments the projection61A can be discontinuous, i.e. it can have a series of interruptions along the direction transverse to the feed direction of the web material N. Vice versa, the winding roller11can have alternating annular bands characterized by a different friction coefficient. A series of annular bands with lower friction coefficient and a series of annular bands with greater friction coefficient can be arranged longitudinally along the winding roller11in such positions that the annular bands with greater friction coefficient are arranged at the interruptions of the projection61A. The annular bands with high friction coefficient grip therefore the web material N to pull and wind it, whilst the annular bands with low friction coefficient allow the web material to slip when it is pinched by the discontinuous projection61A at said annular bands with lower friction coefficient.

Severing preferably occurs at a perforating line formed by the perforator5. To this end, the winding cycle is synchronized with the angular position of the perforating roller5A so that, when severing occurs to interrupt the web material after a roll L1has been completely wound, a perforating line is in the most adequate position between the projection61A of the plate61and the completed roll L1.

In this phase of the winding cycle the auxiliary winding roller48is spaced from the path of the web material N, i.e. at a certain distance from the nip15through which the web material N is fed.

The shape and the position of the plate61relative to the cylindrical surface of the winding roller11are such that the rotary motion of the winding roller11makes the free initial end of the web material, generated by the breakage along the perforating line in the phase illustrated inFIG. 3, twist around itself. As a result, the web material starts to form a winding nucleus that moves forward rolling on the surface of the plate61along the channel defined between the surface of said plate and the cylindrical surface of the first winding roller11.

FIG. 4shows a subsequent phase, wherein the log or roll L1under completion is still held between the second winding roller13and the third winding roller23, whilst an initial winding nucleus of a second roll or log L2has been formed in the channel62defined between the pate61and the cylindrical surface of the first winding roller11. This initial portion or central nucleus of the second roll L2has crossed the centerline of the nip15between the first winding roller11and the second winding roller13, i.e. it has passed the plane on which the axes11A and13A of rotation of the first and of the second winding roller11and13are located, and has come into contact with the second winding roller13.

As the web material N has been severed and the tail end LC is completing its winding around the roll L1, the auxiliary winding roller48can be lowered and moved toward the roll L2in the initial forming phase, moving toward the area of minimum distance between the winding roller11and the winding roller13. Thanks to its highly reduced diameter, the auxiliary winding roller48can be inserted deeply in the space defined between the first winding roller11and the second winding roller13downstream of the centerline of the nip15, so as to come into contact with the second roll L2in the initial forming phase when this second roll L2still has an extremely small diameter. It is therefore possible to start winding the new roll L2between three winding rollers11,13,48in an initial phase of the winding cycle.

FIG. 4shows the plate61that, once the roll L2has come into contact with the second winding roller13, can be moved away from the cylindrical surface of the first winding roller11due to the rotation of the cam69.

FIG. 5shows an arrangement of the rewinding machine in a later phase than that illustrated inFIG. 4. The first roll L1has been ejected from the winding cradle formed by the winding rollers11,13, and23, so that the third winding roller23can start its lowering movement (arrow f23) toward the first winding roller11and the second winding roller13. In this phase the roll L2being formed is still into contact with the first winding roller11, the second winding roller13and the auxiliary winding roller48. Said second roll L2is increased in diameter due to the rotation of the winding rollers11,13, and48and to the substantially constant feed speed of the web material N.

In this winding phase, to allow easy increase in the diameter of the second roll L2without it being excessively pressed, the arms17supporting the first winding roller11pivot about the rotation axis17A according to the arrow f17under the control of the actuator19and the rods21. Thus, the centre distance between the first winding roller11and the second winding roller13increases, as well as the available space for the diameter increase of the second roll L2.

Again to allow the increase in the diameter of the roll L2and a movement thereof toward the exit of the space between the rollers11and13, the flanks33supporting the bearing structure43, that supports the auxiliary winding roller48, also rotate according to the arrow f33under the control of the actuator37and the rods39.

This entails a gradual movement of the auxiliary roller48away fro the nip15defined between the first winding roller11and the second winding roller13. Displacements of the axes of the rollers11and48can be advantageously controlled according to the thickness of the web material N and the feed speed, as the increase over time in the diameter of the roll L2depends upon these two parameters. By controlling the movement of the axes of the rollers11and48it is furthermore possible to control the winding density of the roll L2. By acting on the movement of the rotation axes of the rollers11and48it is possible to make this density be nearly constant or variable according to the roll diameter. Winding the roll into contact with three winding rollers11,13,48since the first winding phase allows to keep the density of the first turns at a limited value, thus avoiding formation of a roll presenting an inner part with substantially greater density than the outer part.

In this phase of the winding cycle the peripheral speed of the winding roller11and the peripheral speed of the winding roller13are so controlled as to cause a controlled forward movement of the roll L2. In fact, the centre of the roll L2being formed moves forward at a speed equal to half the difference between the peripheral speeds of the above mentioned rollers11and13. More in particular, to allow a gradual and controlled forward movement of the roll L2being formed, in an advantageous embodiment the peripheral speed of the second winding roller13has been temporarily made lower than the peripheral speed of the first winding roller11and of the auxiliary winding roller48, which rotate preferably at a constant peripheral speed equal to the linear feed speed of the web material N. As already mentioned, thanks to this difference in the peripheral speeds of the rollers11and13the centre of the roll L2being formed moves forward at a speed equal to half the difference between the peripheral speeds of the winding roller11and of the winding roller13. As shown inFIG. 5, the roll L2is held and controlled between three winding rollers11,13, and48.

FIG. 6shows the successive instant, when the third winding roller23has been lowered until its cylindrical surface achieves the surface of the roll L2being formed. The roll L2has increased in diameter relative to the phase shown inFIG. 5, and it moved forward, away from the laying plane of the axes of the winding rollers11and13and therefore away from the nip15between said rollers.

In the phase ofFIG. 6, the roll L2is preferably into contact with the first winding roller11, the second winding roller13, and the third winding roller23, as well as with the auxiliary winding roller48. Even if at this point it is possible to move the auxiliary winding roller48away from the roll L2being formed, in an advantageous embodiment of the method according to the invention winding of the second roll L2continues for a certain part of the winding cycle into contact with the four winding rollers11,13,23, and48, as it is visible by comparingFIGS. 6 and 7

The third winding roller23is gradually lifted (arrow f23inFIG. 7) remaining into contact with the roll L2being formed. This gradual lifting allows a diameter increase of the roll L2being formed. This movement is controlled by the actuator29through the rods27. The auxiliary winding roller48is analogously moved away from the nip15by making the flanks33pivot through the actuator37and the rods39, so as to allow, in this case, the increase in the diameter of the log or roll L2being formed. In this phase of the winding cycle the peripheral speeds of the four winding rollers11,13,23, and48can be equal to one another.

A change in the rotation speed of one or more of the winding rollers is also possible, for instance to control and vary the winding density, or to recover any slackening occurred in the previous phases of the winding cycle, particularly during the exchange phase, i.e. the phase of severing the web material and starting the second roll L2.

FIG. 8shows a subsequent phase of the winding cycle, when the log or roll L2is in contact only with the first winding roller11, the second winding roller13and the third winding roller23. This latter continues to be gradually raised due to the rotation of the arms25around the axis25A controlled by the actuator29through the rods27. The auxiliary winding roller48has been moved away from the roll L2due to a further rotation of the flanks33around the axis of rotation of the first winding roller11through the actuator37connected to the flanks33by means of the rods39.

In a modified embodiment it is possible for the auxiliary winding roller48to remain into contact with the roll L2for a longer time or even for all the roll winding cycle. Winding of the roll L2maintains this contact condition with the three winding rollers11,13,23nearly until the final quantity of web material N has been achieved. When winding is being completed, the roll L2must begin to move away from the first winding roller11to achieve the position of the roll L1ofFIG. 3. To this end it is possible to modify the peripheral speed of one or both the winding rollers13and23, as mentioned above.

A possible embodiment provides for the winding roller13to be decelerated, which roller in the previous winding phase, when the roll L2has been arranged between, and into contact with, the rollers11,13, and23, has been brought again to the peripheral speed equal to that of the roller11and of the roller23. By causing a new deceleration of the winding roller13, the roll L2starts to move forward in the nip formed between the second winding roller13and the third winding roller23, losing contact with the first winding roller11and moving away there from. In this way a free portion of web material N is formed (seeFIG. 3), preparing the web material N for the subsequent severing or tearing phase due to the gripping against the surface of the winding roller11caused by the projection61A of the plate61.

In some embodiments it is also possible for the third winding roller23temporarily to accelerate, so as to cause an over-tension of the web material N and to make therefore the subsequent tearing of the web material faster and safer as soon as it is pinched between the cylindrical surface of the first winding roller11and the projection61A of the plate61. It is also possible to move the roll L2away from the roller11due to the effect of the acceleration of the third winding roller23only, without decelerating the winding roller13. Deceleration of the winding roller13is however advantageous to prepare the machine for the subsequent phase, wherein the new roll rolls through the nip15, to move from the channel62to the nip15and from this latter toward the winding cradle delimited by the winding rollers11,13,48and then by the rollers11,13,48, and23.

From the description above it is clearly apparent that nearly all the winding cycle of each log or roll L1, L2can be performed into contact with at least three winding rollers, thanks to the use of the winding roller48with a diameter substantially smaller than the diameter of the third winding roller23. In fact, only the first turns, wound in the nucleus of the roll when this is in the nip15, are formed into contact with only two winding rollers, i.e. the first winding roller11and the second winding roller13, or between the first winding roller11and the substantially stationary surface of the plate61. The contact with the auxiliary winding roller48(FIG. 4) starts extremely in advance of the moment when the third winding roller23can come into contact with the log or roll being formed. This occurs thanks to the fact that the auxiliary winding roller48has a very reduced diameter and also to the fact that it can come into operation, touching the roll L2, when the third winding roller23is still into contact with the roll L1, formed during the previous winding cycle, and is finishing the winding cycle of this roll L1, causing it gradually to roll around the second winding roller13until to achieve the chute24.

In advantageous embodiments the rotary motion of the winding rollers11,13,23,48is given by four distinct, electronically controlled, electric motors. Also the translation movement of the axes of the winding rollers48,11, and23is controlled by three distinct actuators (for instance electronically controlled electric motors). A fourth actuator causes the cam or eccentric69to rotate. All the actuators or motors, with which the rewinding machine is fitted, are adequately controlled by a single programmable electronic central control unit. Adequate encoders can be advantageously provided to verify the position of the various members and to give a feedback signal for the control rings.

It is understood that the drawing only shows an example provided by way of a practical arrangement of the invention, which can vary in forms and arrangements without however departing from the scope of the concept underlying the invention. Any reference numbers in the appended claims are provided for the sole purpose of facilitating reading of the claims in the light of the description and the drawing, and do not in any manner limit the scope of protection represented by the claims.