The present invention relates to an unwinding device to unwind reels or rolls of web material and feed the web material to subsequent stations of a converting line or similar. More particularly, although not exclusively, the present invention relates to a device of the aforesaid type for unwinding reels of paper material, such as tissue paper to produce toilet paper, kitchen towels or similar, or napkins, handkerchiefs or other products.
The present invention also relates to a method for unwinding a web material from a reel and delivering it to a converting line downstream.
In many industrial fields, in particular in the paper converting field, it is necessary to deliver a web material, for example a sheet of paper, from a starting reel or roll to a converting line in which the web material is manipulated to produce semi-finished or finished products. For example, to produce paper in rolls, such as toilet or kitchen paper, large reels are placed in unwinding devices from which the web material from one or more reels is delivered to a converting line to produce rolls, which are subsequently cut into small rolls destined to be packaged and marketed. Analogously, reels of paper web material are used to feed lines to produce napkins, paper handkerchiefs or the like. Unwinding devices of parent reels with large diameters are also used in the plastic films and non-woven processing sector to feed the web product wound on the reels towards processing means downstream.
Above all in the paper converting sector, the unwinding devices have motor-driven unwinding mechanisms, typically composed of motor-driven belts, which transmit a torque to the reel being unwound as a result of friction between the drive mechanism and the external surface of the reel. These are referred to as unwinding devices with peripheral operation, indicating that the torque required to make the reel rotate and hence deliver the web material is transmitted by friction through the external surface, that is the periphery, of the reel. Examples of unwinding devices of this type are described in GB-A-0793937; U.S. Pat. No. 3,740,296; EP-A-0321887; U.S. Pat. No. 4,883,233; U.S. Pat. No. 3,202,376; U.S. Pat. No. 2,984,429; WO-A-9534497; WO-A-9633120.
In certain particular situations, such as when the reel of web material is exceptionally large in size and/or has a limited winding density, peripheral drawing is not suitable, as it may cause phenomena of reciprocal slippage between the turns of material wound on the reel (especially in the central zone of the reel), as a result of poor adhesion of the turns of web material and/or of the high inertia of the reel and its central shaft. Difficulties in unwinding occur in particular when the dimensions of the reel are considerable and the web material wound is particularly soft and delicate, such that when it is wound on the reel it cannot be tightened and the reel thus has a low winding density.
To prevent reciprocal slippage between the turns of web material in these circumstances it would be necessary to exert high pressure on the reel with the peripheral unwinding mechanisms. This is not advisable as it would cause permanent deformation of the web material with loss of those properties of softness and bulk obtained during production of the material using special procedures.
To solve these problems unwinding devices which apply an unwinding torque to the reel through the central shaft of the reel have been studied. Examples of unwinding devices of this type are described in U.S. Pat. No. 5,906,333; U.S. Pat. No. 6,030,496; EP-A-0872440 and WO-A-9846509.
EP-A-1136406 describes a dual unwinding device with a structure known per se and substantially equivalent to the one described in WO-A-95344497, in which unwinding is obtained by means of a center drive mechanism of the type equivalent to the one described for example in WO-A-9846509.
These systems with central operation are not satisfactory, especially when the reel has a large diameter and high inertia. Moreover, in some cases each side of the reel is provided with a mechanism in the form of a rotating plate, which presses on the flat surface to transmit rotational motion. This mechanism has a diameter which may be greater than the diameter of the reel being wound, especially when the diameter of the reel decreases as a result of delivery of the material. When this occurs the web material often breaks due to the fact that the edge of the outermost turn of the material is pinched and withheld between the flat frontal surface of the reel and the relative rotating plate mechanism. When this occurs the web material is prevented from unwinding and the material tears.
The object of the present invention is to produce an unwinding device for unwinding reels of web material which may efficiently also manipulate reels with large diameters and/or reels with very little winding density and/or of soft and delicate material and which is particularly suitable for manipulating reels of tissue paper.
Another object of the present invention is to produce an unwinding device which can unwind reels of web material without the risk of reciprocal slippage between the, turns of web material and of damage to the material.
These and other objects and advantages which shall become apparent to those skilled in the art by reading the text below are attained in substance with an unwinding device comprising:
In substance, in the device according to the invention the overall torque applied to the reel to cause rotation and consequently unwinding of the web material is in part exerted peripherally, through the peripheral drive mechanism, and in part centrally, through the shaft of the reel, through the center drive mechanism. Control of the torque applied to the two drive mechanisms, so that these are balanced, i.e. suitably distributed, guarantees correct unwinding, without reciprocal slippage between the turns of the reel.
As well as the advantage of obtaining regular unwinding without the risk of wrinkling the web material and/or of slippage between the turns of the material wound on the reel, with the device according to the invention it is also possible to attain rapid accelerations of the reel even when this has high inertia. In this way it is possible to reach the operating speed very quickly each time it is necessary to replace a reel that is used up or damaged with a new reel, which usually requires the production line to be stopped.
The fact that the new reel can be rapidly accelerated to the regular operating speed makes it possible to reduce downtimes and increase the average production level of the production line.
The presence of a dual drive mechanism also makes it possible to attain the further advantage of adopting a variable unwinding mode according to the nature of the web material and the characteristics of the reels being unwound. Indeed, the control system may be also programmed to control the central and peripheral drive mechanisms so as to deactivate one of the two. If the nature of the material and the characteristics of the reel advise purely peripheral unwinding, it is possible through the control system to deactivate the center drive mechanism. On the other hand, if the characteristics of the material and the reel advise central unwinding, the control system can deactivate the peripheral drive mechanism.
In practice, it is advantageous for the center drive mechanism to be subordinate to the peripheral drive mechanism, in the sense that the operating conditions of the center drive mechanism are varied by means of a feedback signal maintaining the unwinding conditions of the reel under control. On the other hand, the peripheral drive mechanism is controlled in the usual way, to maintain constant or substantially constant the tension of the web material delivered to the converting-line downstream of the unwinding device.
In a possible embodiment the center drive mechanism or in any case of the subordinate drive mechanism is controlled by controlling the torque applied. In substance, in this case the control modifies the operating conditions of the drive mechanism so that the torque that it applies to the reel is maintained substantially constant or in any case within a range or interval of predefined values. These predefined values may in actual fact be a function of the torque applied by the other drive mechanism. For example, the overall torque applied may be equally distributed between the two drive mechanisms. In this case, the value applied by the center drive mechanism is not maintained at a fixed absolute value or within an interval defined by fixed absolute value, but at a value or within an interval of values defined time by time as a function of the operating conditions, that is of the total torque required to maintain the reel in rotation.
According to another embodiment of the invention, control is implemented by detecting any slippage of the web material. For this purpose the web material may be provided with a reference which is read by a specific sensor. A second reference applied to the shaft of the reel, or in any case in a fixed angular position in relation to the shaft is detected by a second sensor. The angular distance between the two references must remain the same. When there are variations in this angular distance this means that the web material tends to slip on the reel. This condition must be avoided and the operating conditions of the subordinate drive mechanism (particularly of the center drive mechanism) are controlled and modified by means of a feedback signal proportional to this possible slippage or sliding of the web material, i.e. on the basis of a signal which detects (preferably with each turn of the reel and in any case repeatedly during unwinding) a variation in the angular distance between the two references.
According to an improvement of the present invention, the unwinding device may be equipped with a sensor to read the external diameter of the reel. The sensor may be a laser sensor, an ultrasound transducer or another suitable sensor. Determination of the diameter may be performed as an average, for example based on a plurality of readings taken during one turn of the reel. This makes it possible to obtain an average value when the reel is ovalized or in any case deformed and not perfectly cylindrical.
The diameter thus detected may allow more accurate control of the device. In fact, when it is necessary to make the reel rotate, for example after replacing a used up reel, the peripheral speed to which the reel must be taken, and with which acceleration law, are known from the operating data of the control unit. This makes it possible to control the peripheral drive mechanism, the speed of which will be equal to the speed requested for the web material unwound from the reel. Nonetheless, the speed at which the center drive mechanism must rotate is not known a priori. By knowing the diameter of the reel it is possible to determine (from the diameter and from the peripheral speed, i.e. from the feed speed of the web material) the angular speed which the reel must have. This angular speed value is used to control the center drive mechanism.
If the diameter is read continually during unwinding, the value of the diameter and the feed speed requested for the web material (equal to the peripheral speed of the reel and therefore of the peripheral drive mechanism) make it possible to calculate moment by moment the theoretical speed of the center drive mechanism. The aforesaid feedback signal overrides the control signal based on the theoretical speed. In this way extremely accurate regulation and control of unwinding is obtained. If the motion of the center drive mechanism determined by the calculated value of angular speed is not sufficient to prevent slippage of the web material, or causes unbalance of the two torques applied by the two drive mechanisms, the feedback signal corrects the operating conditions of the center drive mechanism, acting on one of its operating parameters, for example the torque or the speed.
Further advantageous features and embodiments of the invention are indicated in the attached dependent claims.
The invention also relates to a method for unwinding a reel of web material and delivering said web material to a converting line, in which a first unwinding torque is applied peripherally to said reel through contact means with the cylindrical surface of the reel and in which a second unwinding torque is applied to the shaft of said reel and in which said first and said second unwinding torque are coordinated with each other to correctly unwind the web material from the reel.
In a possible embodiment of the invention, the method includes: placing a peripheral drive mechanism in contact with the cylindrical surface of the reel and applying the first unwinding torque through said peripheral drive mechanism; placing a center drive mechanism in connection with the shaft of the reel and applying said second unwinding torque through said center drive mechanism.
In practice, in a possible embodiment of the invention, the method comprises the phases of:
In an improved embodiment, the method of the present invention may include the phases of:
A feedback signal may also be produced to control said center drive mechanism, said feedback signal modifying the operating conditions of the center drive mechanism as a function of the unwinding conditions of the reel.
Further advantageous features and embodiments of the method according to the invention are indicated in the attached dependent claims.
The invention shall now be better explained with reference to the description and the attached drawing, which shows a practical non-limiting example of the invention. In the drawing:
The invention is described below applied to an unwinding device comprising a dual carriage for simultaneously supporting two reels, one of which in stand-by and the other being unwound. This type of unwinding device is used to change the used up reel in automatic mode. It must however be understood that the underlying principles of the invention may also be applied to an unwinding device of another type.
The overall structure of the unwinding device incorporating the present invention is shown in
The reel B1 is in an unwinding position, corresponding to a processing line to which the web material N unwound from the reel is fed. The reel B2 is in a side standby position to replace the reel B1 when it is used up. Replacement is performed for example as described in WO-A-9534497, the description of which should be referred to for greater details.
In the unwinding position (reel B1), shown in particular in
A central zone of the carriage 1 between the side supports 5B and 3A of the reels B1 and B2 is provided, for each reel, with a center drive mechanism, designed to apply an unwinding torque on the shaft of the reel momentarily in the delivery position (reel B1 in the layout in
With reference to
The shaft 59 is supported idle inside a sleeve 65 which slides axially in a tubular element 67 rigidly connected to an upright 69 which also supports the motor 45 and the spindle 55. On the outside of the sleeve 65 there is a ring with respective seals on the internal cylindrical surface of the tubular element 67. The sleeve 65 thus forms a piston that slides inside a cylinder composed of the tubular element 67 and the two elements together form a piston-cylinder actuator which commands coupling and decoupling movement of the grooved coupling between shaft 59 and shaft A1 of the reel.
The center drive mechanism 41 or 43 may thus be released from the respective reel, allowing the used up reel to be replaced with a new reel. Moreover, it may be connected to the shaft of the reel and used to make the reel also rotate in the side standby position (reel B2 in
The device is also equipped with a control unit schematically indicated in
These sensors or detection means include a sensor 73 mounted on the structure 11 to detect the diameter of the reel B1 in the unwinding position. The sensor 73 may be a laser, infrared, ultrasound or other sensor suitable for the purpose. A sensor 75 is mounted on the arm 21 to read markings printed on the edge of the reel B1 or B2 in the unwinding position. These markings are applied for example by tracing a straight line on the flat face of the reel with a felt tip pen or in another manner. In
Another sensor 77 is associated with each of the supports of the reels B1 and B2 and is used to read a reference integral with the shaft A1 or A2 of the reel in the unwinding position. In
A load cell or other transducer may be associated with the transmission cylinder 9 of the web material, to detect the tension in the material. The load cell or other transducer may also be associated with a different transmission mechanism of the web material.
Finally, the central unit 71 may be interfaced with a control unit associated with other machines of the line, downstream of the unwinding device, which receive the web material N.
With these mechanisms and sensors, the device described may operate as follows.
A new reel B1 is inserted in the unwinding position (reel B1 in
After this calculation, the device may start up and the two driven mechanisms, the peripheral mechanism 13 and the center mechanism 41 respectively, are operated at the calculated speed.
Through the tension sensor, for example the load cell on the cylinder 9, the tension of the web material is detected and if necessary the central unit 71 consequently controls the speed of the belts 15 of the peripheral drive mechanism 13. If the detected tension is too high the speed of the peripheral drive mechanism is increased and vice versa. Consequently, on the basis of the measurement of the diameter obtained with the sensor 73 the angular speed of the drive mechanism 41 is also corrected.
To guarantee that both drive mechanisms take action on the reel B1 in a correct and combined manner, with adequate distribution of torques, and without the external turns of the reel tending to slip in relation to the internal turns and consequently in relation to the central shaft A1 of the reel (which may occur for example for very large and heavy reels or if the turns are wound slackly), a feedback system is provided.
In a first possible control mode, the central unit 71 detects a datum relative to the torque applied from the motors 23 and 45. If the peripheral drive mechanism 13 is (as preferable) the main mechanism or “master”, and the center drive mechanism 41 is the subordinate mechanism or “slave”, the unit 71 will produce a possible feedback signal when the torque applied by the center drive mechanism differs from a range of preset values, to re-balance the system. For example, if the torque applied by the center drive mechanism 41 tends to decrease below the set value, this means that the center drive mechanism tends to be drawn by the reel, rather than applying a driving torque to it. The feedback signal will cause positive acceleration of the center drive mechanism. On the other hand, if the torque applied by the center drive mechanism 41 tends to rise above a preset limit, this means that the drive mechanism 41 tends to prevail over the peripheral drive mechanism 13 and the feedback signal will consequently tend to reduce its angular speed. When this operating mode is adopted, the sensors 75 and 77 are not active or might even be missing.
In a different operating mode, using the sensors 75, 77, the center drive mechanism is controlled by a feedback signal produced on the basis of the readings of the two sensors 75, 77. In normal operating conditions, the angular distance between each of the markings M on the various turns of the material N and the reference R is fixed. If the outermost turn(s) of the web material tend(s) to slip on the turns below, there will be a variation in the angular distance between the marking read by the sensor 75 and the reference read by the sensor 77. The variation in the angular distance has a sign and may be positive or negative according to the tendency of the outermost turn to tighten or loosen in relation to the innermost web material. The relative feedback signal produced by this variation in the angular distance will tend to cancel slippage. Therefore, if the variation in angular distance corresponds to a tendency of the outermost turn to become tighter over the material below, this means that the shaft of the reel must be accelerated and consequently the angular speed of the center drive mechanism 41 will be increased. The opposite will occur if the outermost turn of web material tends to slacken. Indeed, in the first case the feedback signal will indicate that the outermost turn or portion of outermost turn of the material tends to “run faster” than the shaft of the reel and than the innermost zone of the reel and that the shaft must therefore be accelerated. In the second case the feedback signal will indicate the opposite situation: the outermost turn(s) of the web material tend(s) to slow down in relation to the core of the reel, which tends to run faster than the periphery.
The feedback signal may merely arrest the variation in the angular distance or may restore the angular distance to the original value, so as to avoid accumulation of reciprocal slippage between the turns of web material. In general, this is referred to in both cases as correction of the offset.
It is understood that the drawing only shows a possible embodiment of the invention, which may be varied in its forms and dispositions without however departing from the scope of the underlying concept of the invention. Any presence of reference numbers in the attached claims has the sole: purpose of facilitating the reading of the claims with reference to the description above and to the attached drawings, and does not limit the scope of protection represented by the claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IT02/00721 | 11/13/2002 | WO | 00 | 5/13/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/043837 | 5/27/2004 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2892597 | Schmidt | Jun 1959 | A |
2984429 | Huck | May 1961 | A |
3202376 | Dutro et al. | Aug 1965 | A |
3740296 | McDonald | Jun 1973 | A |
4278213 | Rubruck | Jul 1981 | A |
4729522 | Tafel et al. | Mar 1988 | A |
4883233 | Saukkonen et al. | Nov 1989 | A |
4893763 | Wales et al. | Jan 1990 | A |
5000394 | Wales et al. | Mar 1991 | A |
5156350 | Wales et al. | Oct 1992 | A |
5344089 | Crowley et al. | Sep 1994 | A |
5472153 | Crowley et al. | Dec 1995 | A |
5651511 | Crowley et al. | Jul 1997 | A |
5906333 | Fortuna et al. | May 1999 | A |
6030496 | Baggot et al. | Feb 2000 | A |
Number | Date | Country |
---|---|---|
0 321 887 | Jun 1989 | EP |
1 136 406 | Sep 2001 | EP |
0 321 887 | Apr 1958 | GB |
2161146 | Jan 1986 | GB |
WO 9534497 | Dec 1995 | WO |
WO 9633120 | Oct 1996 | WO |
0 872 440 | Oct 1998 | WO |
WO 9846509 | Oct 1998 | WO |
WO 0164562 | Sep 2001 | WO |
WO 0164562 | Sep 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20060038051 A1 | Feb 2006 | US |