System and method for simultaneously unwinding multiple rolls of material

Abstract
A system and process for unwinding rolls of material is disclosed. The system is particularly well suited for unwinding soft, high-bulk tissue webs. In one embodiment, the system includes the combination of a center unwind device and a surface unwind device to unwind the roll of material in a primary unwind location. Once the roll of material is partially unwound, the roll is then moved to a secondary unwind location while a new roll of material is moved into the primary unwind location. In this manner, multiple rolls of material can be continuously unwound without substantial downtime. The system of the present invention can be used to unwind a single roll of material or can be designed to unroll multiple rolls of material simultaneously.
Description




BACKGROUND OF THE INVENTION




In the production of many paper products, such as tissue and towel products, paper webs are typically formed in a paper making system and initially stored in large parent rolls. The parent rolls are unwound for finishing operations, such as embossing, printing, ply attachment, perforating, and the like and then rewound into retail-sized logs or rolls.




Unwinding and further processing parent rolls made from paper webs, particularly soft and high bulk tissue webs, can be challenging due to the fact that the product can easily break or become damaged. Unwinding such rolls in a fast and efficient manner can also be problematical. For instance, in many traditional operations, parent rolls are unwound one roll at a time. After a parent roll is unwound, the machine is stopped for the removal of the core and deployment of a new parent roll. The downtime associated with parent roll changeovers, creates a substantial reduction in total available run time that reduces the maximum output that can be obtained from a rewinder line.




A center driven unwind system that has provided great improvements in systems and processes for unwinding parent rolls is disclosed in U.S. Pat. No. 5,906,333 to Fortuna, et al. and U.S. Pat. No. 6,030,496 to Baggot, et al., which are incorporated herein by reference in their entireties. In the above patents, a system is disclosed which includes a pair of horizontally spaced apart side frames. Each side frame includes an elongated arm capable of engaging a parent roll. The elongated arms are operably associated with variable speed drive means for unwinding the parent roll. Once the parent roll is partially unwound, the arms move the parent roll to a core placement table which rotatably supports the partially unwound roll. The elongated arms then move away from the core placement table to engage a second parent roll. A leading end portion of the web on the second parent roll is bonded to a trailing end of the partially unwound first parent roll to form a joined web.




Although the above system has provided great advancements, further improvements are still needed in the handling and unwinding of parent rolls. In particular, a need exists for a system capable of unwinding multiple parent rolls without a significant amount of down time. Further improvements are also needed for systems that can unwind high bulk tissue webs without breaking or otherwise damaging the webs as they are unwound.




SUMMARY OF THE INVENTION




In general, the present invention is directed to a system and method for unwinding rolls of material. The system and process of the present invention can be used to unwind various different types of materials. The system, however, is particularly well suited to unwinding paper webs, especially soft, high bulk tissue webs. Without damaging the webs.




In one embodiment, the unwind system of the present invention includes a frame defining a primary unwind location and a secondary unwind location. A first drive device adapted to engage a center position of a roll of material to be unwound is positioned to engage the roll of material when the roll of material is in the primary unwind location. As used herein, the “center portion” of a roll of material generally refers to whatever object or device the material is wound around and can include, for instance, a core, a spool, or the material itself in a coreless roll. The system further includes a second drive device adapted to engage an outside surface of the roll of material when the roll of material is in the primary unwind location. The second drive device operates in conjunction with the first drive device to unwind the roll of material. For instance, the first drive device can be a center unwind device, while the second drive device can be a surface unwind device. The second drive device can include a driven belt that is movable between a roll engagement position and a non-engagement position. In one embodiment, the second drive device is used in conjunction with the first drive device to initially unwind the material. Once the roll of material has reached a preselected unwind speed, however, the second drive device can then be disengaged. In this manner, the second drive device can be used to accelerate the roll of material without causing any material breakage.




The system of the present invention can further include a transfer mechanism that transfers the roll of material from the primary unwind location to the secondary unwind location after a portion of the material has been unwound from the roll. A third drive device is positioned at the secondary unwind location and is configured to further unwind the roll of material after the roll of material has been transferred to the secondary unwind location.




In one embodiment, the first drive device is configured to move with the roll of material from the primary unwind location to the secondary unwind location while continuously unwinding the roll. Once transferred to the secondary unwind location, the first drive device can disengage the roll and return to the primary unwind location, while unwinding is continued at the secondary location by the third drive device.




In an alternative embodiment, the second drive device moves with the roll of material from the primary unwind location to the secondary unwind location for continuous unwinding during the transfer.




The third drive device can be a center unwind device that engages a core or spool of the roll of material that is to be unwound or, alternatively, can be a surface unwind device that engages a surface of the roll of material that is to be unwound. In one embodiment, the third drive device can be configured to move from the secondary unwind location to the primary unwind location to engage a roll of material and continuously unwind the material while the material is being transferred to the secondary unwind location, as opposed to using the first drive device or the second drive device.




As described above, when transferring a roll of material from the primary unwind location to the secondary unwind location, one of the drive devices can be used to continuously unwind the roll. It should be understood, however, that in one embodiment of the present invention, the roll of material can be transferred from the primary unwind location to the secondary unwind location without continuous unwinding. In fact, since the primary unwind location and the secondary unwind location are relatively closely spaced together, such a small interruption in the unwinding process will not significantly effect the efficiency of the system.




Once a roll of material is partially unwound and transferred from the primary unwind location to the secondary unwind location, a second roll of material can be placed in the primary unwind location for subsequent unwinding. In this regard, the system of the present invention can include an air jet nozzle for emitting air onto a leading end of the second roll of material positioned at the primary unwind location. The air jet nozzle can blow the leading end of the second web onto the first web being unwound at the secondary unwind location. Once the leading end of the second roll of material is placed on top of the first roll of material being unwound, the plies can be attached together through pressure or the use of an adhesive. Once attached together, unwinding of the first roll of material can be ceased causing the material to break. Continuous unwinding of the second roll of material can then commence while the remains of the first roll of material can be removed from the system.




In one embodiment of the present invention, the frame can include a staging area and a collecting area in addition to the primary unwind location and the secondary unwind location. Rolls of material to be unwound can be kept in the staging area for transfer to the primary unwind location. For example, in one embodiment, the first drive device can be configured to move to the staging area and engage a roll of material and move with the roll of material to the primary unwind location.




The collecting area can collect the unwound cores or spools of the rolls of material. Once ejected from the secondary unwind location, the remainder of the unwound rolls of material can be fed by gravity to the collecting area.




Although the relative location of the different areas on the frame can be changed as desired, in one embodiment, the staging area can be located generally at the same elevation as the primary unwind location. The secondary unwind location, on the other hand, can be positioned below the primary unwind location. The collecting area can be positioned at an elevation lower than the secondary unwind location and generally below the staging area.




If desired, the system of the present invention can be completely automated. For instance, the system can include a controller, such as a microprocessor or a programmable logic unit. The controller can be used to control all of the drive devices for unwinding a roll according to the process of the present invention. In order to automate the system, the system can include various sensors for indicating when it is time to transfer rolls from one location to the next. For example, in one embodiment, the system can include a roll diameter sensor that sends information to the controller. The roll diameter sensor can sense information about the diameter of a roll being unwound in the primary unwind location. Once the roll reaches a predetermined diameter, the controller can be used to automatically transfer the roll to the secondary unwind location.




A speed sensor can also be incorporated into the system for determining the unwind speed of a roll of material in the primary unwind location. The speed sensor can be used to indicate when it is time to engage or disengage the second drive device.




In one embodiment, the above-described system can be used to unwind two or more rolls of material simultaneously. The two or more plies of material being unwound in this embodiment can be fed, for instance, to a converting system for forming a multi-ply product. For instance, the converting system can be used to form a multi-ply bath tissue, facial tissue or paper towel.




When unwinding two rolls of material simultaneously, the system of the present invention can include a first unwinding subsystem for unwinding a first roll of material and a second unwinding subsystem for unwinding a second roll of material. In one embodiment, the first subsystem can be configured to unwind the first roll of material in a first direction, while the second unwinding subsystem can be configured to unwind the second roll of material in a second and opposite direction. By unwinding or rotating the rolls of material in opposite directions, the same side of a similarly constructed sheet can be used to form the outer surfaces of a multi-ply product.




The first unwinding subsystem and the second unwinding subsystem can be arranged on the frame assembly in various configurations. For example, in one embodiment, the first unwinding subsystem and the second unwinding subsystem can be placed in a side-by-side arrangement on the frame. In an alternative embodiment, the first unwinding subsystem can be placed over the second unwinding subsystem on the frame. Within each unwinding subsystem, the secondary unwind location can be positioned directly below the primary unwind location or, alternatively, can be placed below and at an angle of greater than about 20° to the primary unwind location.




Other features, and aspects of the present invention are discussed in greater detail below.











BRIEF DESCRIPTION OF THE DRAWINGS




A full and enabling disclosure of the present invention, including the best mode thereof to one of ordinary skill in the art, is set forth more particularly in the remainder of the specification, including reference to the accompanying Figure in which:





FIG. 1

is a side view of one embodiment of a system made in accordance with the present invention showing a roll of material being loaded into a staging area;





FIG. 2

is a side view of the system illustrated in

FIG. 1

showing a roll of material being moved to a primary unwind location;





FIG. 3

is a side view of the system illustrated in

FIG. 1

showing the unwinding of a roll at a primary unwind location while a new roll of material is transferred to a staging area;





FIG. 4

is a side view of the system illustrated in

FIG. 1

showing a roll of material that is unwinding being transferred from a primary unwind location to a secondary unwind location while a new roll of material is being transferred to the primary unwind location;





FIG. 5

is a side view of the system illustrated in

FIG. 1

showing continued unwinding of a first roll of material at a secondary unwind location, while a second roll of material is being transferred to a primary unwind location;





FIG. 6

is a side view of the system illustrated in

FIG. 1

showing a first roll of material almost completely unwound at a secondary unwind location being spliced with a second roll of material positioned at a primary unwind location;





FIG. 7

is a side view of the system illustrated in

FIG. 1

showing the unwinding of a roll of material at a primary unwind location, while an exhausted roll of material is being transferred to a collecting area;





FIG. 8

is a top view of the system illustrated in

FIG. 1

;





FIG. 9

is a side view with cut away portions of a drive device positioned at a secondary unwind location; and





FIG. 10A

is a side view of one embodiment of a system made in accordance with the present invention for unwinding two rolls of material simultaneously;





FIG. 10B

is a side view of the system illustrated in

FIG. 10A

showing continued unwinding of two rolls of material at secondary unwind locations;





FIG. 11A

is a side view of an alternative embodiment of a system made in accordance with the present invention for unwinding two rolls of material simultaneously;





FIG. 11B

is a side view of the system illustrated in

FIG. 11A

showing continued unwinding of the rolls of material at secondary unwind locations;





FIG. 12A

is a side view of another alternative embodiment of a system made in accordance with the present invention for unwinding two rolls of material simultaneously;





FIG. 12B

is a side view of the system illustrated in

FIG. 12A

showing continued unwinding of the rolls of material at secondary unwind locations; and





FIG. 13

is one embodiment of an unwind system made in accordance with the present invention for unwinding three rolls of material simultaneously.











Repeat use of reference characters in the present specification and drawings is intended to represent same or analogous features or elements of the present invention.




DETAILED DESCRIPTION




Reference now will be made in detail to the embodiments of the invention, one or more examples of which are set forth below. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment, can be used on another embodiment to yield a still further embodiment. Thus, it is intended that the present invention cover such modifications and variations as come within the scope of the appended claims and their equivalents.




The present invention is generally directed to a system and process for unwinding rolls of material. The system can be used to unwind a single roll of material or can be used to unwind two or more rolls of material simultaneously. The system of the present invention can be used in various applications, such as for unwinding a previously formed paper web, such as a tissue web. While being unwound, the paper web can be fed through various finishing operations, such as calendering, embossing, printing, ply attachment, perforating, and the like. Of particular advantage, the system of the present invention is well adapted to unwinding high bulk and generally low strength products without damaging the products. Further, the system of the present invention is capable of unwinding the materials efficiently without a substantial amount of down time.




Referring to

FIGS. 1 through 9

, a system generally


10


made in accordance with the present invention is illustrated. For purposes of explanation,

FIGS. 1 through 7

generally show the sequential steps of how one embodiment of a system of the present invention can be used to unwind rolls of material.




Referring to

FIG. 1

, the system


10


includes a frame


12


. As shown, the frame


12


includes a staging area


14


for receiving rolls of material, a primary unwind location


16


, a secondary unwind location


18


, and a collecting area


20


. In general, a roll of material


22


is first placed in the staging area


14


and transferred to the primary unwind location


16


. The roll of material


22


is partially unwound at the primary unwind location


16


before being transferred to the secondary unwind location


18


where further unwinding takes place. Once unwound, the remainder of the roll is then ejected from the secondary unwind location


18


and is collected at the collecting area


20


. Once ejected from the secondary unwind location


18


, the remainder of the roll of material can roll by various means including gravity to the collecting area


20


.




In

FIG. 1

, the roll of material


22


being loaded onto the system includes a core


24


. It should be understood, however, that the system of the present invention can also be used to unwind rolls wound on spools and coreless rolls.




Any suitable roll of material can be unwound according to the process of the present invention. As stated above, however, the system is particularly well suited for unwinding paper products. Such paper products can include paper towels, industrial wipers, bath tissue, facial tissue, and the like. Of particular advantage, the system of the present invention can be used to unwind large rolls of a very soft and high bulk tissue without damaging the tissue.




The tissue can be, for instance, a facial tissue or a bath tissue. The tissue can be made predominantly of pulp fibers and can be creped or uncreped. For example, the tissue can be a web creped from a Yankee dryer or, alternatively, can be an uncreped through air dried fabric.




One embodiment of a suitable high bulk tissue that can be unwound according to the present invention is disclosed in U.S. Pat. No. 5,607,551 to Farrington, Jr., et al. which is incorporated herein by reference. The '551 patent particularly describes soft, high-bulk uncreped through dried tissue sheets. Such tissues can be characterized by bulk values of about 9 cubic centimeters per gram or greater (before calendering), more specifically from about 10 to about 35 cubic centimeters per gram, and still more specifically from about 15 to about 25 cubic centimeters per gram.




The basis weight of paper products processed according to the present invention can vary depending upon the particular application. For instance, when unwinding paper products, the basis weight of the rolled products can range from about 5 lbs per ream to about 120 lbs per ream. Tissue webs typically have a basis weight of below about 30 lbs per ream, and particularly below about 30 lbs per ream.




The initial diameter of the rolls of materials unwound in the system of the present invention can also vary depending upon the particular application. When unwinding paper products, for instance, the roll of materials can have a diameter of at least about 60 inches and particularly about 80 inches. More particularly, many paper rolls for use in present invention can have diameters greater than about 120 inches, such as from about 130 inches to about 250 inches. The width of such products can also vary such as from about 55 inches to about 225 inches or greater.




As shown in

FIG. 1

, the first roll of material


22


is loaded onto the frame


12


at the staging area


14


. For most applications, the roll of material


22


will be loaded onto the frame


12


using a crane or similar lifting device. To help assist in guiding the roll of material onto the frame, the system of the present invention can include one or more guide rails


26


. For example, in one embodiment, the system can include two guide rails located on opposite sides of the frame.




As shown in

FIG. 2

, from the staging area


14


, the roll of material


22


is transferred to the primary unwind location


16


for unwinding. As shown, at the primary unwind location


16


, the roll of material


22


is engaged by a first drive device


28


for unwinding the material.




In general, any suitable transfer mechanism can be used in order to transfer the roll of material


22


from the staging area


14


to the primary unwind location


16


. As shown in

FIG. 2

, in this embodiment, the roll of material


22


is guided along opposing rails located on the frame


12


until the roll reaches the primary unwind location. Alternatively, however, a pair of bearings or chucks can engage each side of the roll of material


22


and move the roll to the primary unwind location


16


using movable arms, hydraulic cylinders, pneumatic cylinders, ball screws, or pushers. In still another alternative embodiment of the present invention, the first drive device


28


can move to the staging area


14


, engage the roll of material


22


and move it to the primary unwind location


16


.




As stated above, once the roll of material is transferred to the primary unwind location, the first drive device


28


engages and unwinds the material. The first drive device


28


is generally referred to as a center unwind device as it engages the center portion


24


of the roll of material


22


. For instance, the first drive device


28


can include a retractable chuck that engages the core or spool


24


of the roll


22


. The chuck can be placed in operative association with a belt that is driven by a motor.




In accordance with the present invention, besides the first drive device


28


, the system can also includes a second drive device


30


positioned at the primary unwind location


16


. The second drive device


30


can be a surface unwind device that assists in rotating the roll of material


22


by applying a tangential force to the outside surface of the roll.




In general, any suitable surface unwind device can serve as second drive device


30


. For instance, the surface unwind device disclosed in U.S. Pat. No. 5,730,389 to Biagiotti, which is incorporated herein by reference, can be used in the present invention.




In one embodiment, the second drive device


30


can include a driven belt that is placed in contact with the roll of material


22


. Alternatively, however, one or more driven rollers can also be placed in contact with the roll.




As shown, the second drive device


30


is moveable between a non-engagement position located off of the roll of material


22


and an engagement position located against the roll of material. In this manner, the second drive device


30


can be used to selectively assist in unwinding rolls if desired according to the present invention.




The present inventors have discovered various benefits and advantages can be obtained when using a center unwind device in conjunction with a surface unwind device. In particular, the second drive device


30


can provide supplemental torque assist from the outside of the roll of material


22


while the first drive device


28


couples to one end or both ends of the core or spool to transmit torque through the layers of material. By providing supplemental torque from the outside of the parent roll, a more equal distribution of torque transmission through each layer of the material is obtained. This method of torque transmission is especially desirable during initial acceleration of low density, high bulk tissue rolls when slippage between layers and breakage is most likely to occur.




Although the second drive device


30


can be used to unwind rolls continuously, for most applications, the second device


30


is only used to initiate unwind acceleration and/or deceleration of very large diameter rolls. For instance, in one embodiment of the present invention, initial rotation of the roll of the material


22


is begun by a combination of the first drive device


28


and the second drive device


30


. Once the roll reaches a particular rotational speed, however, the second drive device


30


can be disengaged, allowing all torque transmission to take place via the first drive device


28


. When unwinding high bulk tissue webs contained in a roll having a diameter of about 85 inches are larger, it is generally desirable to drive the roll solely through the shaft once the roll has attained a desired unwind speed in order to avoid potential roll/sheet damage that can be caused by certain surface drive devices.




As shown in

FIG. 2

, a web


36


is unwound from the roll of material


22


and further processed as desired. As described above, the web can be fed through various finishing operations or can simply be unwound in order for repackaging. In the embodiment illustrated in

FIG. 2

, the web


36


is shown being fed through a pair of nipped rolls


32


and


34


.




Referring to

FIG. 3

, the unwinding of the roll of material


22


is shown after the second drive device


30


has been disengaged. Further rewinding is done solely by the first drive device


28


.




As shown, a second roll of material


38


is loaded into the staging area


14


of the frame


12


as unwinding of the first roll of material


22


continues. Referring to

FIG. 4

, once the roll of material


22


has reached a predetermined diameter, the roll can be transferred from the primary unwind location


16


to the secondary unwind location


18


. Simultaneously or consecutively, the second roll of material


38


can be transferred from the staging area


14


to the primary unwind location


16


.




Any suitable transfer mechanism can be used to transfer the first roll of material


22


to the secondary unwind location


18


. During transfer, unwinding of the roll of material can cease or if desired, can continue. For instance, as shown in

FIG. 4

, in one embodiment the first drive device


28


can remain engaged with the first roll of material


22


during transfer to the second unwind location


18


. In this manner, the first drive device can continue to unwind the first roll of material


22


during the roll change sequence until the roll reaches the secondary unwind location.




Referring to

FIG. 5

, the roll of material


22


is shown in the secondary unwind location


18


. As illustrated, first drive device


28


is still in engagement with the roll of material. Unwinding of the web


36


continues in the secondary unwind location


18


. The second roll of material


38


is shown approaching the primary unwind location


16


.




Referring to

FIGS. 8 and 9

, at the secondary unwind location


18


is a third drive device


40


. In this embodiment, as particularly shown in

FIG. 9

, the third drive device


40


includes a belt


42


upon which the roll of material


22


rests. The belt


42


is driven by a motor


44


. The belt


42


can contact the outside surface of the roll of material as a surface drive device. Alternatively, however, as shown in

FIG. 8

, the belt


42


can contact the core or spool upon which the material is wound. In this manner, the third drive device


40


acts more like a center unwind device. Third drive device


40


is used to continue unwinding the roll


22


as the first drive device


28


disengages from the roll and returns to the primary unwind location


16


.




For example, referring to

FIG. 6

, the first drive device


28


is shown returning to the primary unwind location


16


and engaging the second roll of material


38


. Unwinding of the first roll of material


22


, however, is continued at the secondary unwind location


18


by the third drive device


40


. The third drive device


40


unwinds the roll of material


22


at a predetermined unwind speed in preparation for splicing with the second roll of material


38


.




As shown in

FIG. 6

, as first drive device


28


engages the second roll of material


38


, the second drive device


30


also engages the roll at its outside surface. Through the combination of the first drive device


28


and the second drive device


30


, rotation of the second roll of material


38


is initiated. The second roll of material


38


is accelerated by both the first drive device


28


and the second drive device


30


to generally match the web speed of the web


36


being unwound from the secondary unwind location


18


. As the second roll of material


38


is unwound, the leading edge of the material falls on top of the web


36


due to the force of gravity.




As shown in

FIG. 6

, the system can include additional means, such as an air nozzle


46


which emits a curtain of air or other gas to facilitate peeling the leading edge of the web from the second roll of material


38


and to ensure that the new web lands onto the existing web


36


that is already threaded through the process. It should be understood, however, that the use of the air nozzle


46


or any other similar device is optional.




Once both webs have been placed together, the webs proceed at the same speed to a ply bonding process downstream. The plies can be bonded together using, for instance, ply crimpers, a set of nip rolls, an embossing roll or through the use of an adhesive. Once the plies have been bonded together, the third drive device


40


ceases torque transmission to the first roll of material


22


, which causes the web


36


to sever.




Referring to

FIG. 7

, after the webs have been spliced together and web


36


has been severed, the remaining roll


22


is disengaged from the third drive device


40


. The expired roll in the secondary unwind location


18


can be manually or automatically slabbed down for waste removal. The expired roll can be relocated and secured in a convenient, fixed position for the wound material to be cut or peeled off. The waste paper material can fall to the floor or onto a conveyor for subsequent removal from the area beneath the system. If included in the roll, the bare shaft or core can be released from the secondary unwind position and transferred to a collecting position


20


as shown in FIG.


7


. In one embodiment, the frame


12


can include a set of rails which have a strategic grade so as to permit the shaft or core to roll downhill towards the collecting area


20


.




During removal of the first roll of material


22


from the secondary unwind position


18


, the second roll of material


38


can be unwound from the primary unwind location


16


as described above. As shown in

FIGS. 6 and 7

, a third roll of material


48


can be loaded into the staging area


14


of the frame


12


for processing in accordance with the present invention.




As described in the embodiment above, the system and process of the present invention use at least two drive devices to unwind rolls of material and allow for the splicing of the rolls without ever having to stop the operating process. Moreover, since rolls of materials processed by the system of the present invention only move in a direction perpendicular to their rotational axis as opposed to any movement parallel to their rotational axis, the system can unwind very wide parent rolls, such as rolls having the width of the paper making machine itself without delays associated with cross-directional movement. Furthermore, the system of the present invention can be completely automated if desired.




For example, as shown in

FIG. 8

, the system can include a controller


50


for controlling all of the drive devices and any transfer mechanisms. The controller


50


can be, for instance, a microprocessor or a programmable logic unit.




In one embodiment, various sensors can be included in the system in order to provide information to the controller


50


for control of the various operations that occur during unwinding. For instance, as shown in

FIG. 8

, the system can include a roll diameter sensor


52


that senses the diameter of the roll of material


22


. Based on information received from the sensor


52


, the controller can determine when it is time to transfer the roll of material


22


from the primary unwind location to the secondary unwind location.




Besides a roll diameter sensor, the system can also include a rotational speed sensor. The rotational speed sensor can provide information for determining when it is time to engage and disengage the second drive device


30


. Speed sensors can also be used to match the speed between the first roll of material


22


and the second roll of material


38


during splicing.




The system and sequence of events illustrated in

FIGS. 1 through 7

represent one embodiment of the present invention. It should be understood, however, that various modifications can be made to the system without departing from the scope of the invention. For instance, in an alternative embodiment, when a roll of material is transferred from the primary unwind location to the secondary unwind location, the roll can be engaged by the second drive device


30


instead of the first drive device


28


. The second drive device can continuously unwind the roll of material as the material is placed in the secondary unwind location. After the roll of material is positioned in the secondary unwind location, the second drive device


30


can then return to the primary unwind location.




As described above, for many applications, the second drive device


30


is only used to initiate rotation of the roll of material in the primary unwind location. In this embodiment of the present invention, however, the second drive device can be used to initiate the unwinding of the roll of material and then disengage from the material. After the roll of material has partially unwound, the second drive device can once again be brought into engagement with the roll for further unwinding and transfer to the secondary unwind location.




When processing high bulk tissue webs, surface unwind devices can create sheet damage when contacting rolls of materials having relatively large diameters, such as greater than about 85 inches. When the diameter of the roll of material is less than about 85 inches, use of a surface drive device to transmit torque through a high bulk tissue web will normally not damage the web. Thus, when using the second drive device to transfer the roll of material from the primary unwind location to the secondary unwind location and the roll of material is a high-bulk product, in some applications it may be desirable for the second drive device to initially engage the roll of material, disengage the roll of material, and then re-engage the roll of material after the diameter has been sufficiently reduced.




In the embodiment illustrated in

FIGS. 6 and 7

, the third drive device


40


is shown as a surface unwind device. In another alternative embodiment of the present invention, however, the third drive device


40


can be a center unwind device that unwinds a roll of material by engaging the center of the roll. When the third drive device


40


is a center unwind device, the device can engage the roll of material on the side opposite the first drive device


28


.




When the third drive device


40


is a center unwind device, in one embodiment, the third drive device can be configured to move between the primary unwind location


16


and the secondary unwind location


18


. In this manner, the third drive device can be used to assist in transferring the roll of material from the primary unwind location to the secondary unwind location while continuously unwinding the material without interruption. In this embodiment, the third drive device can be configured to move between the different unwinding locations much like the first drive device


28


as shown in

FIGS. 4 and 5

.




In addition to unwinding a single roll of material, the system of the present invention can also be used to unwind two or more rolls of material simultaneously. For instance, referring to

FIG. 10A

, one embodiment of a system generally


110


for unwinding two rolls of material simultaneously is shown. As illustrated, the system includes a first unwinding subsystem


113


and a second unwinding subsystem


213


. Each of the subsystems are similar in form to the system illustrated and described in

FIGS. 1 through 7

.




As shown in

FIG. 10A

, the first unwinding subsystem


113


is in a side-by-side relationship with the second unwinding system


213


. Each unwinding subsystem includes a primary unwind location


116


and


216


and, a staging area


114


and


214


. As shown, the system includes a single collecting area


120


for collecting the unwound reels or spools.




In the first unwinding subsystem


113


, a first roll of material


122


is unwound at the primary unwind location


116


by a first drive device


128


and a second drive device


130


. Similar to the embodiment described in

FIGS. 1-7

, the first drive device


128


is a center unwind device, while the second drive device


130


is a surface unwind device that is, for most applications, used to initiate unwinding.




Similar to the first unwinding subsystem


116


, the second unwinding subsystem


216


unwinds a second roll of material


222


using a first drive device


228


and a second drive device


230


. A sheet


236


is unwound from the second roll of material


222


while a sheet


136


is unwound from the first roll of material


122


. The sheets


136


and


236


are fed into a converting system. For instance, the sheets can be fed in between a pair of nipped rolls


132


and


134


. For many applications, especially when the sheets are paper webs, the sheets are attached together and formed into a multi-ply product, such as a bath tissue, a facial tissue, a paper towel, an industrial wiper, and the like.




In the embodiment illustrated in

FIG. 10A

, the first unwinding subsystem


113


is configured to unroll the first roll of material


122


in a counter-clockwise direction as indicated by the arrow. The second unwinding subsystem


213


, on the other hand, is configured to unwind the second roll of material


222


in a clockwise direction. Unwinding the two rolls of material in different directions provides various advantages in some applications. For example, unwinding the two rolls of material in opposite directions enables easy threading of the sheets through the system and can provide for automatic splicing. Also, if the sheets are laminated together, unwinding the rolls in opposite directions allows the same side of the sheet from both rolls to form the outer surface of the laminate. This can be particularly advantageous when two similar sheets having different surface characteristics are combined together to form a product.




After a portion of the rolls


122


and


222


have been unwound, the rolls are transferred from the primary unwind locations


116


and


216


to secondary unwind locations


118


and


218


as shown in FIG.


10


B. Winding is continued at the secondary unwind locations until the rolls are exhausted and new rolls of material have been loaded into the primary unwind locations


116


and


216


. At the secondary unwind locations


118


and


218


, the rolls of material


122


and


222


are unwound by third drive devices (not shown). The third drive devices can be surface unwind devices or center unwind devices.




Depending upon the application, unwinding of the rolls of material can continue while the rolls are being transferred from the primary unwind locations


116


and


216


to the secondary unwind locations


118


and


218


.




In the embodiment illustrated in

FIG. 10B

, within the second unwinding subsystem


213


, the secondary unwind location


218


is located directly below the primary unwind location


216


. In the first unwinding subsystem


113


, however, the secondary unwind location


118


is located below and at an angle to the primary unwind location


116


. In particular, the secondary unwind location


118


is at an angle of at least 20°, particularly at least 30°, and in the embodiment illustrated at an angle of about 45° to the primary unwind location


116


. Having the path of travel from the primary unwind location


116


to the secondary unwind location


118


at an angle can facilitate unwinding of the roll of material


122


and make the transition between the different unwinding locations smoother when unwinding multiple rolls. For example, by having the primary unwind location


116


positioned upstream with respect to the secondary unwind location


118


, a free edge of the material being unwound at the primary unwind location will fall on top of a web being unwound at the secondary unwind location. This allows the webs to be easily spliced together when unwinding is being discontinued at the secondary unwind location in lieu of a new roll of material that has been loaded at the primary unwind location.




Once the rolls of material


122


and


222


have been transferred to the secondary unwind locations


118


and


218


, further rolls of material from the staging areas


114


and


214


can be transferred to the primary unwind locations


116


and


216


. For example, in the embodiment illustrated in

FIG. 10B

, rolls of material


148


and


248


can be moved along a rail until being engaged by the drive devices located at the primary unwind locations


116


and


216


.




Referring to

FIGS. 11A and 11B

, another alternative embodiment of an unwind system for simultaneously unwinding multiple rolls of material is illustrated. Like reference numerals have been used in order to represent the same or similar components. In the embodiment illustrated in

FIGS. 10A and 10B

, the first and second unwinding subsystems


113


and


213


are placed in a side-by-side arrangement. In the embodiment illustrated in

FIGS. 11A and 11B

, on the other hand, the first unwinding subsystem


113


is placed over the second unwinding subsystem


213


within the frame assembly


112


.




As shown in

FIGS. 11A and 11B

, the first unwinding subsystem


113


unwinds a first roll of material


122


at a primary unwind location


116


and a secondary unwind location


118


. In this embodiment, the secondary unwind location


118


is located substantially directly below the primary unwind station


116


. In the second unwinding subsystem


213


, a roll of material


222


is unwound at a primary unwind location


216


and a secondary unwind location


218


. As opposed to the first unwinding subsystem


113


, in the second unwinding subsystem


213


, the secondary unwind location


218


is located below and at an angle to the primary unwind location


216


. The angle with respect to the horizontal is at least 20°, particularly at least 30°, and as shown in the Figures, can be about 45°.




One of the advantages to stacking the unwinding subsystems as shown in

FIGS. 11A and 11B

is that the web span from the unwinding locations to the calendar rolls


132


and


134


is approximately equal for both of the unwinding subsystems. Since the web spans are approximately equal, each of the unwinding subsystems will unwind the webs at approximately the same tension.




Another advantage to the stacked arrangement shown in

FIGS. 11A and 11B

is that less floor space is required for the system.




Referring to

FIGS. 12A and 12B

, another alternative embodiment of an unwind system for unwinding multiple rolls of material simultaneously is illustrated. Similar to the embodiment shown in

FIGS. 10A and 10B

, the first unwinding subsystem


113


and the second unwinding subsystem


213


are in a side-by-side arrangement. In this embodiment, however, the staging areas


114


and


214


are located on opposite sides of the rolls of material being unwound.




In the embodiment illustrated in

FIGS. 12A and 12B

, the web span between the unwinding locations and the nipped rolls


132


and


134


remains approximately equal during the entire unwinding process. As shown particularly in

FIG. 12B

, in this embodiment, both of the secondary unwind locations


118


and


218


are located below and at an angle to the primary unwind locations


116


and


216


respectively. More particularly, the secondary unwind location


118


is located below and at an angle to the primary unwind location


116


within the first unwinding subsystem


113


. Within the second unwinding subsystem


213


, the secondary unwind location


218


is also positioned below and at an angle to the primary unwind location


216


. As shown, although the secondary unwind locations


118


and


218


are located at about the same angle to the primary unwind locations


116


and


216


, the angles are in opposite directions. In this manner, the web span remains approximately equal between the two unwinding subsystems as the rolls are transferred to the secondary unwind locations and automatic roll change capability is preserved.




Referring to

FIG. 13

, still another alternative embodiment of an unwind system for unwinding multiple rolls of material is illustrated. The unwind system shown in

FIG. 13

is substantially the same as the unwind system illustrated in

FIGS. 10A and 10B

. In the system illustrated in

FIG. 13

, however, instead of being configured to unwind two rolls of material simultaneously, this system is configured to unwind three rolls of material simultaneously. It should be understood, however, that besides two or three rolls of material, the system of the present invention can be used accommodate more rolls by adding further unwinding subsystems.




As shown in

FIG. 13

, the system includes a first unwinding subsystem


113


, a second unwinding subsystem


213


and a third unwinding subsystem


313


. In the Figure, the secondary unwind locations


118


,


218


and


318


are shown in phantom below the primary unwind locations


116


,


216


and


316


. As illustrated, the secondary unwind locations


118


and


218


are located below and at an angle to the primary unwind locations


116


and


216


. The secondary unwind location


318


, however, is located substantially directly below the primary unwind location


316


.




These and other modifications and variations to the present invention may be practiced by those of ordinary skill in the art, without departing from the spirit and scope of the present invention, which is more particularly set forth in the appended claims. In addition, it should be understood that aspects of the various embodiments may be interchanged both in whole or in part. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the invention so further described in such appended claims.



Claims
  • 1. An unwind system for simultaneously unwinding two rolls of material comprising:a frame including a first unwinding subsystem and a second unwinding subsystem, each of the subsystems including: a primary unwind location and a secondary unwind location; a first drive device adapted to engage a center portion of a roll of material to be unwound, said first drive device being positioned to engage said roll of material when said roll of material is in the primary unwind location; a second drive device adapted to engage an outside surface of said roll of material when said roll of material is in the primary unwind location, said second drive device operating in conjunction with said first drive device to unwind said roll of material, the second drive device providing supplemental torque to the outside surface of the roll of material; a transfer mechanism that transfers said roll of material from the primary unwind location to the secondary unwind location after a portion of said material has been unwound from said roll; and a third drive device positioned at the secondary unwind location, the third drive device for further unwinding said roll of material; wherein each of the subsystems are in communication with a converting system for receiving a first sheet from a first roll of material being unwound by the first unwinding subsystem and a second sheet from a second roll of material being unwound by the second unwinding subsystem, said converting system forming a multi-ply product.
  • 2. An unwind system as defined in claim 1, wherein each unwinding subsystem further includes a staging position for holding a roll of material prior to transfer to the primary unwind location.
  • 3. An unwind system as defined in claim 2, wherein, within each unwinding subsystem, said first drive device is configured to move to said staging position, engage a roll of material and move with said roll of material to said primary unwind location for unwinding.
  • 4. An unwind system as defined in claim 1, wherein, within each unwinding subsystem, the first drive device includes a chuck for engaging and unwinding a roll of material.
  • 5. An unwind system as defined in claim 1, wherein, within each unwinding subsystem, said first drive device is configured to move with said roll of material from the primary unwind location to the secondary unwind location while continuously unwinding said roll, said first drive device being further configured to disengage said roll of material at the secondary unwind location.
  • 6. An unwind system as defined in claim 1, wherein, within each unwinding subsystem, said second drive device comprises a driven belt, said second drive device being movable between a roll engagement position and a non-engagement position.
  • 7. An unwind system as defined in claim 6, wherein, within each unwinding subsystem, the second drive device is configured to work in conjunction with the first drive device to unwind a roll of material and then to move to said non-engagement position after the material has reached a preselected unwind speed.
  • 8. An unwind system as defined in claim 1, wherein, within each unwinding subsystem, said third drive device comprises a center unwind device that engages a center portion of a roll of material and unwinds said roll.
  • 9. An unwind system as defined in claim 1, wherein, within each unwinding subsystem, said third drive device comprises a surface unwind device that engages a surface of a roll of material and unwinds the roll.
  • 10. An unwind system as defined in claim 1, wherein each unwinding subsystem further includes a controller and a roll diameter sensor, said controller being configured to receive information from the roll diameter sensor about the diameter of a roll being unwound in the primary unwind location and, based on said information, to automatically transfer the roll to the secondary unwind location upon reaching a predetermined diameter.
  • 11. An unwind system as defined in claim 1, wherein the first unwinding subsystem is configured to unwind the first roll of material in a first direction and wherein the second unwinding subsystem is configured to unwind the second roll of material in a second and opposite direction.
  • 12. An unwind system as defined in claim 1, wherein, within the first unwinding subsystem, the secondary unwind location is located substantially directly below the primary unwind location and wherein within the second unwinding subsystem, the secondary unwind location is located below and at an angle of at least 20° to the primary unwind location.
  • 13. An unwind system as defined in claim 1, wherein the first unwinding subsystem is located over the second unwinding subsystem.
  • 14. An unwind system as defined in claim 1, wherein, within each of the unwinding subsystems, the secondary unwind location is located below and at an angle of at least 20° to the primary unwind location.
  • 15. An unwind system as defined in claim 1, further comprising a third unwinding subsystem for unwinding a third roll of material simultaneously with the first roll of material and the second roll of material.
  • 16. An unwind system as defined in claim 1, wherein the sheet span from the primary unwind location to the converting system is substantially the same for each of the unwinding subsystems.
  • 17. An unwind system as defined in claim 1, wherein the first unwinding subsystem and the second unwinding subsystem are configured to unwind rolls of material in the same direction.
  • 18. An unwind system as defined in claim 1, wherein, within each of the unwinding subsystems, the secondary unwind location is located substantially directly below the primary unwind location.
  • 19. An unwind system for simultaneously unwinding two rolls of a web of material comprising:a frame including a first unwinding subsystem and a second unwinding subsystem, each of the subsystems including: a primary unwind location; a first drive device adapted to engage a center portion of a web of material to be unwound, said first drive device being positioned to engage said roll of material when said roll of material is in the primary unwind location; and a secondary drive device adapted to engage an outside surface of said roll of material when said roll of material is in the primary unwind location, said second drive device operating in conjunction with said first drive device to unwind said roll of material, the secondary drive device providing supplemental torque to the outside surface of the roll of material, said second drive device unwinding said roll of material at least during initial rotation of said roll.
  • 20. An unwind system as defined in claim 19, wherein each unwinding subsystem further includes a secondary unwind location and a third drive device positioned at the secondary unwind location, the third drive device for further unwinding said roll of material.
  • 21. An unwind system as defined in claim 20, wherein, within each unwinding subsystem, said third drive device comprises a center unwind device, said first drive device engaging one side of the center portion of the roll of material and said third drive device engaging an opposite side of the center portion, said third drive device being configured to move with said roll of material from the primary unwind location to the secondary unwind location while continuously unwinding said roll.
  • 22. An unwind system as defined in claim 20, wherein, within each unwinding subsystem, said third drive device comprises a surface drive device.
  • 23. An unwind system as defined in claim 20, wherein, within each unwinding subsystem, said first drive device is configured to move with said roll of material from the primary unwind location to the secondary unwind location while continually unwinding said roll, said first drive device being further configured to disengage with said roll of material at the secondary unwind location.
  • 24. An unwind system as defined in claim 20, wherein, within the first unwinding subsystem, the secondary unwind location is located substantially directly below the primary unwind location and within the second unwinding subsystem, the secondary unwind location is located below and at an angle of at least 20° to the primary unwind location.
  • 25. An unwind system as defined in claim 20, wherein within each of the unwinding subsystems, the secondary unwind location is located below and at an angle of at least 20° to the primary unwind location.
  • 26. An unwind system as defined in claim 19, wherein each unwinding subsystem further includes a secondary unwind position and wherein said second drive device is configured to move with said roll of material from the primary unwind location to the secondary unwind location while continually unwinding said roll.
  • 27. An unwind system as defined in claim 19, wherein, within each unwinding subsystem, said frame further defines a staging position for holding a roll of material prior to transfer to the primary unwind location, said staging position being generally at the same elevation as said primary unwind location.
  • 28. An unwind system as defined in claim 19, wherein, within each unwinding subsystem, said second drive device is configured to work in conjunction with said first drive device to initiate the unwinding of a roll of material and then to disengage from the roll of material after the material has reached a preselected unwind speed.
  • 29. An unwind system as defined in claim 19, wherein the first unwinding subsystem is configured to unwind a first roll of material in a first direction and the second unwinding subsystem is configured to unwind a second roll of material in a second and opposite direction.
  • 30. An unwind system as defined in claim 19, wherein the first unwinding subsystem is located over the second unwinding subsystem.
  • 31. An unwind system as defined in claim 19, further comprising a third unwinding subsystem for unwinding a third roll of material.
  • 32. An unwind system as defined in claim 19, wherein the first unwinding subsystem and the second unwinding subsystem are configured to unwind rolls of material in the same direction.
  • 33. An unwind system as defined in claim 19, wherein, within each of the unwinding subsystems, the secondary unwind location is located substantially directly below the primary unwind location.
  • 34. An unwind system for simultaneously unwinding two rolls of material comprising:a frame assembly including a first unwinding subsystem and a secondary unwinding subsystem, each of the subsystems including: a primary unwind location and a secondary unwind location, said secondary unwind location located below said primary unwind location, wherein, within at least one unwinding subsystem, the secondary unwind location is located substantially directly below the primary unwind location, and a first drive device adapted to engage a center portion of a roll of material to be unwound, said first drive device being positioned to engage said roll of material when the roll of material is in the primary unwind location.
  • 35. An unwind system as defined in claim 34, wherein each unwinding subsystem further includes a transfer mechanism that transfers the roll of material from the primary unwind location to the secondary unwind location after a portion of the material has been unwound from the roll; anda second drive device positioned at the secondary unwind location, the second drive device for further unwinding the roll of material.
  • 36. An unwind system as defined in claim 34, wherein, within each unwinding subsystem, the frame assembly further comprises a staging position for holding a roll of material prior to transfer to the primary unwind location.
  • 37. An unwind system as defined in claim 34, wherein, within each unwinding subsystem, the first drive device is configured to move with the roll of material from the primary unwind location to the secondary unwind location while continuously unwinding the roll.
  • 38. An unwind system as defined in claim 34, wherein the first unwinding subsystem is configured to unwind a first roll of material in a first direction and the second unwinding subsystem is configured to unwind a second roll of material in a second and opposite direction.
  • 39. An unwind system as defined in claim 34, wherein within the first unwinding subsystem, the secondary unwind location is located below and at an angle of at least 20° to the primary unwind location and within the second unwinding subsystem, the secondary unwind location is located directly below the primary unwind location.
  • 40. An unwind system as defined in claim 34, wherein the first unwinding subsystem is located over the second unwinding subsystem.
  • 41. An unwind system as defined in claim 34, further comprising a third unwinding subsystem for unwinding a third roll of material in conjunction with rolls of material being unwound by the first unwinding subsystem and the second unwinding subsystem.
  • 42. An unwind system for simultaneously unwinding three rolls of material comprising:a frame including a first unwinding subsystem, a second unwinding subsystem and a third unwinding subsystem, each of the subsystems including: a primary unwind location and a secondary unwind location; a first drive device adapted to engage a center portion of a roll of material to be unwound, said first drive device being positioned to engage said roll of material when said roll of material is in the primary unwind location; a second drive device adapted to engage an outside surface of said roll of material when said roll of material is in the primary unwind location, said second drive device operating in conjunction with said first drive device to unwind said roll of material; a transfer mechanism that transfers said roll of material from the primary unwind location to the secondary unwind location after a portion of said material has been unwound from said roll; and a third drive device positioned at the secondary unwind location, the third drive device for further unwinding said roll of material; wherein each of the subsystems are in communication with a converting system for receiving a first sheet from a first roll of material being unwound by the first unwinding subsystem, a second sheet from a second roll of material being unwound by the second unwinding subsystem, and a third sheet from a third roll of material being unwound by the third unwinding subsystem, said converting system forming a multi-ply product.
  • 43. An unwind system for simultaneously unwinding two rolls of material comprising:a frame assembly including a first unwinding subsystem and a secondary unwinding subsystem, each of the subsystems including: a primary unwind location and a secondary unwind location, said secondary unwind location located below said primary unwind location, and at an angle of at least 20° to the primary unwind location; and a first drive device adapted to engage a center portion of a roll of material to be unwound, said first drive device being positioned to engage said roll of material when the roll of material is in the primary unwind location.
RELATED APPLICATIONS

The present application is a Continuation-In-Part Application of U.S. patent application Ser. No. 10/010,952, filed on Nov. 13, 2001, entitled “System And Method For Unwinding Tissue Webs”.

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Continuation in Parts (1)
Number Date Country
Parent 10/010952 Nov 2001 US
Child 10/023477 US