The invention relates to improvements to unwinders for unwinding reels of web material, for example in particular reels of tissue paper to feed web material to a line for converting web material and producing cellulose articles, such as rolls of tissue paper, packs of napkins or the like.
The invention also relates to a method for unwinding web material from an unwinding reel by means of an unwinder.
In some production lines that produce folded or wound sheet articles, for example cellulose articles, such as tissue paper or the like, it is required to unwind large diameter reels to feed a converting line, which carries out a series of operations on the unwound web material to obtain finished or semi-finished products, which in turn are further converted into finished products.
Typically, in the field of production of tissue paper articles, such as toilet paper, kitchen towels, napkins or the like, converting lines are used comprising one or more unwinders that feed one or more web materials, dispensed from respective reels being unwound, toward stations downstream that perform the converting operations. For example, one or more of the following units can be provided downstream of the unwinder: printing units, embossing units, rewinders, storage units, interfolding machines for the production of napkins, folding machines for the production of napkins or the like, packaging machines.
The large diameter reels that are unwound to feed the web material to the converting line must periodically be replaced when the web material wound thereon comes to an end, or when switching from the production of one type of article to another, for which a different type of web material is required. For this purpose, the unwinders are normally provided with reels replacement means. Due to the high productivity of the converting lines, it is necessary to replace the reels with a certain frequency, even every two hours. Therefore, it is useful to have a rapid, efficient and automated reel replacement system. Typically, systems and means are provided for removing the empty reel, or the rod on which it was formed, and replacing it with a new reel. Also known are unwinders with two or more unwinding stations, in which splicers automatically splice, with the machine at a standstill or on the fly, the web material from a reel that is coming to an end to the web material of a reel standing by.
Examples of unwinders for unwinding reels of web material, typically tissue paper, are described for example in U.S. Pat. Nos. 6,679,451, 7,618,004, 9,670,020, EP 1136406, EP 0975542, EP 1270470, EP 0872440.
In particular, EP0975542 and EP0872440 describe unwinders that comprise both central unwinding devices and peripheral unwinding devices. The latter comprise belts that act on the reel downwards from above. This increases the stress on the winding rod of the reel and on the tailstocks or punches that support them, resulting in mechanical problems.
WO 2004/080867 describes an automatic unwinder in which a reel is unwound through the combined use of a peripheral unwinding device and a central unwinding device. The reel that is coming to an end is lifted by motorized tailstocks forming part of the central unwinding device, to be subsequently transferred to removal means, placed in the upper part of the unwinding station. In this way, by means of a shuttle it is possible to insert a new reel into the unwinding station in front of the peripheral unwinding device. The central unwinding device is double, and has two pairs of tailstocks, so that while a first pair of tailstocks is in the upper position to complete unwinding of a reel that is coming to an end, a second pair of tailstocks can engage the new reel inserted by the shuttle and start to unwind it in combination with the peripheral unwinding device.
In the present context, a peripheral unwinding device is a device capable of imparting an unwinding torque, which rotates the reel of web material, through transmission of a friction force between a motor member and the substantially cylindrical outer surface of the reel.
Vice versa, a central unwinding device, in the sense meant herein, is a device that transmits an unwinding torque to the reel via its winding rod. Central unwinding devices normally comprise pairs of tailstocks, expansible or that can in any case engage with the central rod on which the reel is wound. At least one of the tailstocks is motorized to transmit a rotation motion to the winding rod of the reel.
The reels used in the paper converting industry are often very heavy. For example, it is possible to use reels with an axial length from two to five meters and a diameter of up to around three meters, with weights that can reach up to 5000 kg.
These reels are often handled inside the converting plant using bridge cranes or, in some cases, with fork-lift trucks provided with reel pick-up members. These members can be gripper members, which clamp the lateral surface of the reels. In other cases, the means for transporting and handling the reels comprise fork-lift trucks with pins that are inserted into the tubular winding rod placed at the center of the reels.
The unwinder used in a given converting line must be compatible with the loading means used to handle the reels and insert them into the unwinder or load them on a shuttle that, in turn, transports the reel to the unwinder. In view of the variety of the devices used to transport and handle the reels, it may be necessary to adapt an unwinder to the specific needs of the final user, resulting in costs for the design and/or adaptation of the unwinder. Moreover, to increase the level of automation of a production plant, the loading means often consist of autonomous vehicles, i.e., automatically guided vehicles, with which it is preferable to associate an unwinder that allows the reel to be loaded automatically without the need for personnel and hence without using a bridge crane and devices to engage the tubular winding rod of the reel with the arms of the bridge crane.
According to one aspect, there is provided an unwinder of reels of web material having at least one unwinding station comprising a pair of tailstocks adapted to engage and support a reel to be unwound, combined with a peripheral unwinding device adapted to co-act with a reel in said unwinding station. The unwinder further comprises a shuttle adapted to insert reels into the unwinding station. The shuttle is movable between a loading position of the reel on the shuttle and a position aligned with the pair of tailstocks. In the latter position the shuttle can transfer a reel from the shuttle to the tailstocks, or transfer an empty reel, or its winding rod, from the tailstocks to the shuttle. Advantageously, the peripheral unwinding device is arranged so that, in use, i.e., when it acts on the reel engaged by the tailstocks to rotate it and unwind the web material, said peripheral unwinding device is positioned under the reel of web material. In this way, the force exerted by the peripheral unwinding device on the reel being unwound (force that allows torque to be transmitted from the unwinding device to the reel as a result of friction) has a component that is subtracted from the weight force of the reel.
With this arrangement, in a shuttle unwinder, which allows high performances and a high level of automation during reel change to be reached, the advantage is achieved of reducing the mechanical stress on the tailstocks and on the winding rod of the reels engaged by the tailstocks. In this way, the risks of the rods breaking and the tailstocks being damaged due to overloading are reduced. This is particularly important in the case of motorized tailstocks, i.e., in the case in which the unwinder has a central unwinding system that works in combination (or can work in combination) with the peripheral unwinding system.
In advantageous embodiments, the peripheral unwinding device is movable between an active position, wherein it co-acts with a reel engaged by the tailstocks, and a position withdrawn with respect to the tailstocks. When the peripheral unwinding device is in the withdrawn position, a space is created to insert the shuttle easily in front of or between the tailstocks and thereby carry out the operations to unload and remove the empty reel (or its winding rod), and the operations to insert and load a new reel.
The detailed description of embodiments will describe a particularly advantageous configuration of the peripheral unwinding device which moves from the active position to the withdrawn position with a translation movement parallel to the orientation of the axes of the tailstocks, and hence parallel to the direction of the axis of the reel when it is engaged with the tailstocks. In other embodiments it would also be possible to move the peripheral unwinding device in different ways and directions. For example, the peripheral unwinding device can be translated in a horizontal direction orthogonal to the axis of the tailstocks, or in a vertical direction orthogonal to the axis of the tailstocks. For example, in the case of a double unwinder with symmetrical arrangement of two pairs of tailstocks and related peripheral unwinding devices and shuttles, a splicing zone of web materials coming from the two reels in the two unwinding stations can be arranged between the two pairs of tailstocks. The space for a withdrawn position of one or the other of the two opposite and symmetrical peripheral unwinding devices can be obtained in the zone in which the splicer is arranged.
In advantageous embodiments, in particular when the peripheral unwinding device is movable parallel to the axis of the tailstocks, in the active position the peripheral unwinding device is in an intermediate position between the tailstocks, and in the withdrawn position the peripheral unwinding device is staggered laterally, in the direction of the rotation axes of the tailstocks, with respect to said tailstocks.
In advantageous embodiments the shuttle and the peripheral unwinding device are movable in the same direction, preferably in the direction of the axis of the tailstocks. Preferably, the loading position of the shuttle and the withdrawn position of the peripheral unwinding device are on opposite sides of the unwinding station. In this case, it is advisable and particularly advantageous for the shuttle and the peripheral unwinding device to be movable along a common guide system, to reduce the overall dimensions, the number of components and consequently the cost of the unwinder.
In particularly advantageous embodiments, one or both the tailstocks can be motorized. In this case, the tailstocks define a central unwinding device. The reels can in this way be unwound applying an unwinding torque through the combined effect of the peripheral unwinding device and of the central unwinding device. In this case, activation of one or the other or of both the unwinding devices (peripheral and central) can depend on various factors, among which the quality of the web material wound on the reel, the winding density, the dimension of the reel, etc. For example, it is also possible to activate and/or deactivate one or the other of the two unwinding devices (peripheral and central) in different stages of unwinding of the same reel, for example as a function of the diameter of the reel, or also as a function of the production speed, i.e. of the speed at which the web material must be unwound from the reel and fed to the converting line.
Advantageously, although it would be possible to arrange handling means for handling the reels and the winding rods on the shuttle, so that the tailstocks can remain in a fixed position with respect to the structure of the unwinder, it is preferable for the tailstocks to be movable between at least a position for picking up the reel from the shuttle and an unwinding position. The movement can be supplied, for example, by a pair of carriages or slides provided with a motion according to translation axes incident with each other. Preferably, for simpler construction and greater efficiency, the tailstocks can be supported by rotating arms, i.e., arms pivoted to a fixed structure, to rotate about an axis substantially parallel to the axis of the tailstocks. The shuttle can be provided with a cradle optionally movable in a direction of translation, for example a horizontal direction, to move toward and away from the rotation axis of the arms that support the tailstocks. This can provide particularly advantageous functions, as will be described with reference to an embodiment.
Although in principle the unwinder can have a single unwinding station, with a pair of tailstocks and a peripheral unwinding device, for greater efficiency and greater speeds during replacement of the reels, it is advantageous for the unwinder to comprise two unwinding stations, preferably the same as, or symmetrical to, each other. In this case a splicing zone can be arranged between the two substantially symmetrical stations, in which a splicer is positioned to splice the web material of a reel in one of the two unwinding stations to the web material of a reel in the other of the two unwinding stations. With two unwinding stations and a splicer it is possible to carry out operations to change or replace an empty reel with a new reel on the fly.
Further advantageous features and embodiments of the unwinder are defined hereunder and in the appended claims.
According to a further aspect, there is described a method for unwinding web material from a reel being unwound in an unwinding station, in particular with an unwinder as defined above, comprising the steps of:
Further advantageous features and embodiments of the method described herein are illustrated hereunder and in the appended claims.
Embodiments of an unwinder described herein will be illustrated hereunder with reference to the accompanying drawings, wherein:
In brief, the unwinder described herein comprises one and preferably two unwinding stations, in which respective reels of web material to be dispensed to a converting line are arranged. The use of two unwinding stations allows a first reel to be unwound in one of the two unwinding stations, while a second new reel is prepared in the other unwinding station. When the first reel is empty, or must in any case be replaced, the leading edge of the web material of the second reel is spliced to the web material of the first reel, which is usually cut to create a trailing edge. In this way the web material, coming from reels that are replaced as they come to an end, is fed continuously.
Each unwinding station comprises a peripheral unwinding device and advantageously can comprise a central unwinding device. When the reel must be replaced, because it is empty or for any other reason, it is lifted from the peripheral unwinding device, to allow the latter to translate to a withdrawn, i.e., inactive, position and leave free space in front of the reel to be replaced. Lifting can be carried out through tailstocks, for example belonging to a central unwinding device, which engage the ends of a central rod on which the web material forming the reel is wound. In this way, a shuttle can be positioned under the reel to be replaced. The shuttle is used to receive the empty reel, or the rod on which it is wound, and transfer the remainder of the reel, or the winding rod thereof, into a position in which it is picked up by an operator. In the same position the shuttle can receive a new reel, which is then transferred thereby in front of the unwinding position to be engaged by the tailstocks. Once the new reel is engaged by the tailstocks and has been lifted from the shuttle, the shuttle is translated to a lateral position to leave room once again for the peripheral unwinding device, which is re-positioned at the new reel.
As will be apparent from the detailed description of embodiments with reference to the accompanying drawings, with the unwinder as configured above, a series of advantages are possible with respect to prior art unwinders, in particular in terms of rapidity of the operations to replace empty reels, of flexibility in handling of the reels and of reliability.
With regard to the drawings, with particular reference to
The unwinder illustrated in the accompanying drawings is indicated as a whole with 1 and comprises two unwinding stations 1A and 1B. The unwinding stations 1A and 1B are substantially symmetrical with respect to a vertical line A-A (
Again with reference to the layout in
As the two unwinding stations 1A and 1B are symmetrical, hereinafter reference will be made only to the unwinding station 1A, of which the various components will be described. These are positioned symmetrically in the unwinding station 1B.
The unwinding station 1A comprises a peripheral unwinding device 5. The peripheral unwinding device 5 comprises in general members adapted to transmit an unwinding torque to the reel through friction by means of contact of unwinding members with the peripheral cylindrical surface of the reel. In the embodiment illustrated, the peripheral unwinding device 5 comprises a pair of endless unwinding belts 7, entrained around a plurality of guide rollers 9. One of these rollers, indicated with 9.1, for each belt 7 is motorized, for example by means of a motor 11.
The guide rollers 9, 9.1, the motor 11 and the belts 7 are mounted on a movable unit, hereinafter indicated as slide 13. The slide 13 is movable according to the direction F along a guide system comprising for example two guides 15 parallel to each other. The guides 15 are for example fixed to a load bearing structure 17. The guides 15 extend transversely through the unwinding station 1A and can extend from a first end 15A to a second end 15B. The ends 15A and 15B are on opposite sides of the unwinding station 1A. The guides 15 and hence the direction F of movement of the slide 13 are parallel to the axis of rotation of a reel when this is located in the unwinding station 1A.
The load bearing structure 17 can have uprights 17A, to which supporting members of a central unwinding device can be mounted. The uprights 17A are arranged in an approximately intermediate zone of the transverse extension of the unwinding station 1A, and therefore between the ends 15A and 15B of the guides 15.
In the embodiment shown, rotating arms 19 are hinged to the uprights 17A. The arms 19 can rotate according to the double arrow f19 about a horizontal axis 19A, see in particular
Each one of the two arms 19 supports, at the distal ends thereof, i.e., the end farthest from the axis of rotation 19A, a respective tailstock indicated with 21A and 21B, respectively for the two arms 19. The two tailstocks 21A, 21B can be symmetrical or different with respect to one another. In the example illustrated the two tailstocks 21A, 21B are slightly different with respect to one another, as only one is motorized, as described below. The assembly of tailstocks 21A, 21B forms a central unwinding device, i.e., which imparts an unwinding torque on the winding axis of the reel B1 or B2.
The rotating arms 19 are movable synchronously about the rotation axis 19A, so that the tailstocks 21A, 21B can remain axially aligned to one another.
The tailstocks 21A, 21B rotate about a respective rotation axis parallel to the rotation axis 19A of the rotating arms 19.
In the embodiment shown, the tailstock 21B is motorized by means of a motor 23, while the tailstock 21A is idle. In other embodiments, not shown, both the tailstocks 21A, 21B can be motorized, with respective motors 23 maintained synchronized through an appropriate electronic control.
The tailstocks 21A, 21B are movable along their axis of rotation, to move toward and away from each other. For example, in some embodiments the tailstocks 21A, 21B can each be supported on a respective carriage or slide 25A, 25B. The slides 25A, 25B can be movable along guides 27 integral with the arms 19. Actuators, not shown, can control the translation movement of the slides 25A, 25B along the guides 27. Said guides 27 extend parallel to the guides 15 and allow the two tailstocks to move in an axial direction according to the double arrow f21. In this way, the tailstocks 21A, 21B can move toward and away from each other in the direction of the axis of the reel arranged in the unwinding station 1A.
In advantageous embodiments, as shown in the drawings, the unwinding belts 7 are positioned below the axis of the reel, so that the force exerted thereby on the lateral surface of the reel is not added to the weight, but rather subtracted from the weight of the reel. In substance, the belts can support the reel being unwound from below to above, so as to reduce the mechanical load on the arms 19 and on the tailstocks 21A, 21B. In this way, the bending load that acts on the winding rod of the reel is also reduced, thereby reducing the risk of breakage and/or malfunctioning. The eccentricity of the reel is also reduced as a result of the lower bending deformation. In general, the configuration of the belts 7 is such that the resultant force applied thereby to the reel has at least one component facing upward, i.e., so that the weight force that is discharged onto the tailstocks 21A, 21B is reduced.
Each unwinding station 1A, 1B comprises a shuttle indicated as a whole with 31. As will be more apparent from the description below, the shuttle 31 has the function of removing the winding rods of the empty reels and of inserting the new reels in the correct position between the tailstocks 21A, 21B. In the embodiment shown, the shuttle 31 of each unwinding station 1A, 1B is movable along the same direction F along which the peripheral unwinding device 5 moves. For this purpose, the shuttle 31 can be mounted sliding on the same guides 15, although it would also be possible to provide different guides for the peripheral unwinding device 5, or more specifically for its slide 13, and for a shuttle 31. The use of common guides makes the overall architecture simpler, more compact and less expensive.
In the embodiment shown, the shuttle 31 comprises a slide or carriage 33, equipped with shoes that engage with the guides 15. In the embodiment shown, the carriage 33 in turn supports a pair of guides 35 oriented at 90° with respect to the guides 15. A slide 37 is mounted sliding on the guides 35 and is movable along the guides 35 according to the double arrow f37. A cradle 39, configured with a V-shaped surface that receives the reels and the winding rods of the empty reels, to transfer them toward and away from unwinding members of the unwinding station, is mounted on the slide 37. In some embodiments, the cradle 39 is mounted so as to be able to rotate with respect to the slide 37 on which it is mounted, for example by 90°, about a vertical axis C-C.
In some embodiments, the cradle 39 has a continuous surface 39A defining one side of the cradle and two arms 39B defining the other side of the cradle. An empty space is left between the arms 39B to facilitate movement of the cradle 39 toward the reels loading and handling means, for example means that have external jaws to engage the reels on their outer cylindrical surfaces. The arms 39B and the surface 39A form a V-shaped cradle.
Having described the main components of the unwinder 1 and of its unwinding stations 1A, 1B, an operating cycle for the replacement of an empty reel with a new reel will now be described with reference to the sequence of
In
Again with reference to
In the layout of
Subsequently (
To release the winding rod A1 on the cradle 39 of the shuttle 31, the embodiment illustrated provides for a first retraction movement of the torsional coupling members 22A, 22B and a subsequent refraction movement of the tailstocks 21A, 21B according to the arrow f21, so as to extract the torsional coupling members 22A, 22B from inside the winding rod A1.
Other embodiments can provide for winding rods that project from the respective reel and that can be engaged with the torsional coupling members 22A, 22B in another way, for example through external clamping of portions of the winding rod A1 projecting from the reel formed around it.
In
In the embodiment illustrated, the arms 19 are stopped in their vertical position. However, it must be understood that the upward rotation movement of the arms 19 can also be postponed with respect to what is illustrated in the sequence described and that the stand-by position of the arms 19 may not be perfectly vertical, but for example rotated further downward, as a function of the diameter of the new reel to be loaded. What matters is that the arms 19 are lifted before insertion of the new reel, according to what is illustrated in the subsequent sequences.
In
In the next
In
When the arms 19 have been rotated until the axes of the tailstocks 21A, 21B are taken into alignment with the axis X-X of the reel B3, the tailstocks 21A, 21B can be moved toward each other by inserting the torsional coupling members 22A, 22B into the hole of the winding rod A3.
In the next
In
In
After reaching the condition of
The sequences described above and shown in
Vice-versa, if the devices for loading and unloading rods and reels with respect to the shuttle 31 are provided with pins that are inserted into the hole of the winding rods, so as to be able to move the reels according to a direction parallel to said guides, the rotation of the cradle 39 about the vertical axis C-C is no longer necessary. Alternatively, if loading of the reels and unloading of the winding rods always takes place with the winding axis parallel to the guides 15 and to the axis of rotation of the tailstocks, it would be possible to use a shuttle in which the cradle 39 does not rotate about the vertical axis C-C.
The movement according to the double arrow f37 of the slide 37 on the guides 35 allows reels of different diameters to be handled, as by moving the arms 19 according to the arrow f19 and the cradle 31 in the direction of the double arrow f37 it is possible to center the tailstocks 21A, 21B with the winding axis of reels of different diameters. Alternatively, the cradle 39 can be devoid of the movement according to f37 and the tailstocks can be provided with a movement orthogonal to their axis of rotation and parallel to the development of the arms 19.
Unwinding of the reels of web material can take place in several ways: for soft reels with large diameters, for example reels of structured paper, both the peripheral unwinding device 5 and the central unwinding device could be used, at least initially, so that the use of the central unwinding device alone does not tend to “screw” the turns of paper about the axis of the reel and the use of the peripheral unwinding device alone does not make too many marks on the surface of the paper due to the greater torque to be transferred from the belts 7 to the outer surface of the reel. When the reel is about to come to an end, it is possible to continue to unwind the web material with the central unwinding device alone, shifting and subsequently moving away the peripheral unwinding device 5 toward the end 15B before the reel is emptied. For soft reels with small diameters the central unwinding device can instead be used alone. In other cases, preferably for compact reels, the peripheral unwinding device 5 can be used alone.
Number | Date | Country | Kind |
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102018000007796 | Aug 2018 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/070237 | 7/26/2019 | WO | 00 |