Reference is made to commonly assigned, co-pending U.S. patent application Ser. No. 10/460,552, entitled: WINDING APPARATUS HAVING BERNOULLI GUIDE CHUTE LEADING INTO ROLLER-CORE NIP AND METHOD, filed Jun. 12, 2003, in the name of Joseph A. Watkins et al.
The invention relates to equipment and methods for winding webs and more particularly relates to a film winder having a traveling, gimbaled cinch roller and winding method.
Automated equipment has long been available to wind webs of photographic film, paper, and other materials tightly about cores. The web is commonly wound onto a core through a nip between the core or growing web roll and another roller. This helps wind the film tightly. The winding mechanisms include provisions allowing for growth of the web roll. U.S. Pat. No. 4,697,755 discloses a mechanism in which a core is pivoted as the size of the web roll changes. U.S. Pat. No. 3,712,554 discloses a winding mechanism in which a builder roller is pivoted. U.S. Pat. No. 5,256,232 translates a builder roller on a slidable carriage. The builder roller also pivots. This approach also has the advantage of allowing separate adjustment of tension on the web and pressure at the nip. This approach uses an idler roller to turn the web and direct the web onto the builder roller.
Prior to winding, the web is cinched onto the core. This can be done by inserting the free end of the web into a slot in the core, but this can lead to deformation or damage to the end of the web. This is undesirable in some uses, such as film cinematography, in which the free end of the film can have otherwise usable images. The cinching can be provided without the use of a slot or the like, by gripping the leading portion of the web prior to and during the winding of an initial turn. This adds complexity in that the elements used to initially grip the leading portion of the film cannot be left in positions that would interfere with the growing web roll.
U.S. Pat. No. 5,248,107 discloses a film winding apparatus, in which a core is supported on a pair of drums and is held in place by a rider roller. For cinching, a nip roller is brought into contact with the web to hold the web in position. The leading portion is then wrapped around the core by a wrapping table, a slide roller, and a wrapping roller. The wrapping table and slide roller are first moved vertically. The slide roller is then moved horizontally to push the web against the core. The wrapping roller is then brought toward the web to push the web against the core. The wrapping roller is then rolled circumferentially around 45 degrees of the core to wrap that part of the leading portion against the core. The nip roller, wrapping table, slide roller, and wrapping roller are all moved to their original positions after cinching. This approach uses many parts and moves those parts in a complex manner.
U.S. Pat. Nos. 2,989,265 and 5,690,264 disclose apparatus having center pivoted web rollers.
It would thus be desirable to provide improved winding apparatus and methods that cinch with little or no damage to the free end of the web, in a way that is comparable with a carriage mounted builder roller.
The invention is defined by the claims. The invention, in broader aspects, provides winding methods and apparatus. In the methods, a primary nip is formed against a web. The primary nip defines continuing and leading portions of the web. A secondary nip is formed against and moved along the leading portion, from an outfeed side of the primary nip to an infeed side. The continuing portion and a free end of the leading portion are then simultaneously advanced into the primary nip. Winding apparatus has a winding spindle and builder roller that rotate about parallel winding and builder roller axes, respectively. An axle defines a guide axis and carries a cinch roller that rotates about the guide axis. The axle pivots between first and second orientations, in which the guide axis parallels and is transverse to the winding axis, respectively. The axle moves in the first orientation, in an incomplete orbit about the winding spindle from a start to a rotated position, both adjacent the builder roller, and returns in the second orientation.
It is an advantageous effect of the invention that improved winding apparatus and methods are provided that cinch with little or no damage to the free end of the web, in a way that is comparable with a carriage mounted builder roller.
The above-mentioned and other features and objects of this invention and the manner of attaining them will become more apparent and the invention itself will be better understood by reference to the following description of an embodiment of the invention taken in conjunction with the accompanying figures wherein:
The term “web” is used herein to refer to a thin membrane of photographic film, coated or uncoated paper or plastic, or other material. The web has a uniform transverse dimension, within limits required for a particular use. The length of the web is determinate or indeterminate, as appropriate for a particular use. For example, the web can be a short sheet of known length or a long roll that is cut to a particular length, as needed.
The term “rotary element” is used herein to refer to a rotating structure that is capable of receiving the web in a single turn or portion of a turn, or in a wrap or coil having multiple turns. For example, the “rotary element” can be a roller, a mandrel, or a core or spool that can be removably mounted on a spindle. The invention is generally discussed herein in terms of embodiments in which the rotating element is a core that is mounted on a spindle.
The term “fixed” and like terms are used herein in the sense of an immobile rather than movable mounting.
Referring initially to
A winding spindle 16 is mounted to the base 12. The winding spindle 16 defines a core space (indicated by arrow 18 in
A web supply 22 is mounted to the base 12 in spaced relation to the winding spindle 16. The configuration of the web supply 22 is not critical. In the winding apparatus 10 shown in
Additional components can also be provided as a part of the web supply 22. For example, components such as idler rollers, tensioners, and cutters, can be provided. Referring to
A cutter 30 is located between two of the secondary rollers 28. The cutter 30 can be any of the mechanisms known to those of skill in the art for cutting webs. The web 14 extends through the cutter 30, as shown in
The apparatus 10 can be limited to the function of rewinding film; however, other functions can also be provided. Such functions are illustrated diagrammatically in
In the following, the cores 20 positioned on the winding spindle 16 and the unwinding spindle 24 are both the same; however, for convenience in the following discussion, the core 20 on the winding spindle 16 is sometimes referred to as the “winding core 20a” and the core 20 on the unwinding spindle 24 is sometimes referred to as the “unwind core 20b”.
The winding spindle 16 rotates about a winding axis 38. This rotation is powered by a web drive 40. Additional components such as the unwinding spindle 24 can also be driven by the web drive 40. The web drive includes one or more motors and can optionally include a gear train or trains, belt or belts, or other transmission (not shown). In the illustrated embodiment, the winding spindle 16 and unwinding spindle 24 are each directly driven by a separate electric motor 42 and the secondary rollers 28 are all idlers.
Referring now to
Between the unwinding spindle 24 and winding spindle 16 is a builder roller assembly 48. The builder roller assembly 48 includes a builder roller 50, which is supported on an arm 52 that is joined to a carriage 54. The builder roller 50 can be an idler, that is, unpowered; or can be driven. It is currently preferred, for simplicity, that the builder roller 50 not be driven. In the embodiments disclosed herein, the builder roller 50 has a pair of opposed builder roller flanges 56. (See
Referring to
In the embodiment shown, the arm 52 is pivotably joined to the carriage 54 and the carriage 54 has a support member 68 that is fixed to the main member 66. (The term “fixed” and like terms are used herein in the sense of joined in immobile relation to another part.) The support member 68 has a shaft 70 that is freely pivotable relative to the support member 68. The arm 52 is fixed to and pivots with the shaft 70.
The arm 52 is biased toward the winding spindle 16 by a biaser 72. Various types of biasers, such as air springs and torsion rods, can be used. In the illustrated embodiments, the biaser 72 is a coil spring that is coiled around the support member 68. A first end 74 of the spring 72 is held by an adjustment nut 76 (shown in
Referring now to
In the illustrated embodiment, a sprocket support 86 is joined to the mount 80 at an outer end. A sprocket 88 is held between the sprocket support 86 and mount 80. The sprocket 88 is rotatable by a sprocket drive 90 about a sprocket axis 92 that is parallel to the winding axis 38 defined by the winding spindle 16. (See
A ring bearing 94 has first and second rings 96,98 that are freely movable relative to each other. The first ring 96 is fixed to the inner end of the mount 80. The first ring 96 is aligned with the sprocket 88. The second ring 98 is fixed to a ring gear 100 and a collar 101. The ring gear 100 and ring bearing 94 are coaxial with the winding axis 38. An endless belt 102 extends between the sprocket 88 and the ring gear 100. Shock absorbers 104 optionally provided on the mount 80 or sprocket support 86 damp vibration of the sprocket 88 and belt 102, during stopping.
The carrier 82 is movable with the collar 101. The carrier 82 has a holder plate 106 that is a fixed to extensions 108 of the collar 101. The extensions 108 axially space the holder plate 106 outward from the mount 80. The holder plate 106 is roughly Y-shaped and has a pair of ears 110 that are joined to the extensions 108 of the collar 101. A guide assembly 112 is mounted to the holder plate 106. The guide assembly 112 is rotatable about the winding axis 38 along with the carrier 82, collar 101, ring gear 100, and second ring 98.
The guide assembly 112 has a yoke 114 having a pair of opposed fingers 116. (See
An axle 120 is mounted to and extends outward from the yoke 114. The axle 120 defines a guide axis 122. The cinch roller 84 is mounted to the outer end 124 of the axle 120. The cinch roller 84 has a pair of opposed cinch roller flanges 126.
It is preferred that the cinch roller is gimbaled to the axle 120. It is further preferred that the cinch roller 84 is gimbaled to the axle 120 at the longitudinal center of the cinch roller 84. In the illustrated embodiments, the cinch roller 84 is gimbaled to the axle 120 midway between the cinch roller flanges 126, by a gimbal bearing 128. (See
An actuator 130 is operatively connected to the yoke 114 of the guide assembly 112, directly or by a linkage or other mechanical coupling. The actuator 130 can be a servomotor or pneumatic drive element or the like. The actuator 130 moves the guide assembly 112 between a first orientation and a second orientation. In the first orientation, the axle 120 of the guide assembly 112 is disposed parallel to the winding axis 38. (See, for example,
In the illustrated embodiment, the yoke 114 has a post 132 that extends outward through one of the ears 110 of the holder plate 106. A linkage 134 couples the post 132 to the actuator 130, in this case to the piston of an air cylinder that is connected to a compressed air source 133 (shown in
Operation of the apparatus 10 can be controlled manually, or by mechanic logic, that is, mechanical connections that coordinate operation of the various features. The apparatus 10 can also be controlled by a microprocessor or other electronic controller 44, as illustrated in
In some uses, it may be desirable to add additional components to the apparatus 10. An example of such a component is a web tensioner (not shown). Features and use of web tensioners, guides, and other such components are well known to those of skilled in the art.
Apparatus 10 can be changed in other ways to meet the requirements of a particular use. In the embodiment of the apparatus 10 above described, the web 14 is taken off the bottom of the unwind web roll 26 and the spindles 16,24 rotate in the directions indicated by arrows 146 and 148. The outer surface of the web 14 of the unwind web roll 26 becomes the outer surface of the web 14 of the wind web roll 26. (See
Referring now to
A starter segment 150 of the web 14 is next unwound. The starter segment 150 of the web 14 includes a leading portion 152 that has a free end 154 and a threading portion 156 that connects the leading portion 152 to the remainder 158 of the unwind web roll 26. (See
In the illustrated embodiment, the web 14 is threaded from the unwind web roll 26, over two of the secondary rollers 28, and through the cutter 30. This initial threading of the web 14 can be performed manually or using automated equipment, in a manner known to those of skill in the art. The knife 32 of the cutter 30 cuts the web 14 to provide an initial datum. (See
In the illustrated embodiments, the length of the threading and leading portions 156,152 remains constant. This is not the case if the required web portions have variable lengths due to the action of a web tensioner or other component that can alter the path of the web 14 from the web roll 26. In this case, the required length for the starter segment 150 needs to be monitored manually or by use of sensors, and adjustments provided as needed.
After the starter segment 150 has been advanced, the starter segment 150 is threaded under the right lower secondary roller 28, and back up to the builder roller 50. The starter segment 150 is then draped over the top of the builder roller 50. (See
After the draping of the starter segment 150 over the builder roller 50, the carriage 54 is translated toward the winding core 20a from a standby position to a forward position. In the standby position, the builder roller 50 is spaced away from the winding spindle 16. (See
The primary nip 160 has an infeed side 162 and an outfeed side 164. (See
When the carriage 54 is translating from the standby position to the forward position, the guide assembly 112 is in the second orientation. After the builder roller assembly 48 reaches the forward position and the builder roller 50 and winding core 20a have formed the primary nip 160, the guide assembly 112 is pivoted relative to the holder plate 106 into the first orientation. During this pivoting, the cinch roller 84 comes into contact with the leading portion 152 of the web 14 and then pushes the leading portion 152 against the winding core 20a. The position of the leading portion 152 at this time may be as shown in
When the guide assembly 112 is in the first orientation, the cinch roller 84 and the winding core 20a together define a secondary nip 168. (See
If the apparatus 10 is to be used for winding photographic film, then it is preferred that the film be contacted in the primary and secondary nips 160,168 only at opposed lateral margins of the film. This prevents pressure marking in image areas of the film, since the film is not contacted between the lateral margins. In this case, each nip 160,168 can be considered to have two spaced apart segments separated by an enlarged gap in which the web 14 is not squeezed. In other embodiments, the nips are continuous from side to side and can continuously contact the web between lateral margins of the web.
When the secondary nip 168 is first formed, the cinch roller 84 is in a start position at the outfeed side 164 of the primary nip 160, in an approximately 8 o'clock position relative to the winding axis 38. (See
During rotation of the cinch roller 84 about the winding core 20a, the secondary nip 168 travels along the leading portion 152 of the web 14 and most of the way around the winding core 20a. This travel of the secondary nip 168 bends the leading portion 152 of the web 14 into a loop and presses the leading portion 152 against the winding core 20a.
In the illustrated embodiments, the leading portion 152 of the web 14 is smoothed onto the winding core 20a, with little or no deleterious contact, such as scuffing, stretching, or bunching. Several features of the illustrated embodiments provide this result.
In the illustrated embodiments, the primary nip 160 is formed before the formation of the secondary nip 168. This approach, in combination with the close positioning of the two nips 160,168 when the secondary nip 168 is initially formed, tends to minimize slack in the web 14 between the two nips 160,168. Slack is undesirable, because, during travel of the secondary nip 168, the cinch roller 84 would tend to pull the slack portion against the winding core 20a leading to possible damage.
In the illustrated embodiments, during the travel of the secondary nip 168, the linear velocity of the leading portion 152 of the web 14 relative to the winding core 20a is at or near zero at the secondary nip 168. This prevents differential movement of the leading portion 152 relative to the winding core 20a, which could lead to damage to the leading portion 152. The zero relative linear velocity of the winding core 20a and leading portion 152 is achieved by holding both web advance and winding core 20a rotation stopped, while the cinch roller 84 travels from the start position at the outfeed side 164 of the primary nip 160 to the rotated position at the infeed side 162 of the primary nip 160. Web advance can be stopped at the web supply 22, but it is preferred that web advance is stopped at or near the primary nip 160.
The web advance can be stopped by pinching the web 14 between the builder roller 50 and the winding core 20a. During the translational movement of the builder roller assembly 48, the builder roller 50 is pushed firmly toward the winding core 20a until the web 14 is pinched. The web 14 remains pinched while the guide assembly 112 is rotated about the winding core 20a. The force applied by the builder roller 50 against the pinched web 14 provides for a static friction that overcomes the pulling force applied by the action of the cinch roller 84 on the web 14 and winding core 20a. The force applied by the builder roller 50 is, preferably, minimized to reduce the risk of damage to the web 14. A separate brake (not shown) can alternatively or additionally be used for stopping web 14 movement, but use of the builder roller 50 alone is simpler.
In the illustrated embodiments, the linear velocity of the cinch roller 84 at the secondary nip 168 is the same or about the same as the linear velocity of the travel of the secondary nip 168 along the leading portion 152. This prevents differential movement of the leading portion 152 relative to the cinch roller 84, which could lead to damage to the leading portion 152. Like linear velocities of the revolving cinch roller 84 and the leading portion 152, are achieved by allowing the cinch roller 84 to freely revolve about the guide axis 122, relative to the axle 120, while holding the leading portion 152 and winding core 20a stopped. The free revolving of the cinch roller 84 also reduces friction against the leading portion 152 at the secondary nip 168. Alternatively, the cinch roller 84 can be powered, but this is adds complexity, since synchronization of the revolving about the guide axis 122 and rotation about the rotation axis is needed to prevent distortions of the web 14, such as scuffing, stretching, or bunching.
The leading portion 152 of the web 14 has a length that is less than the circumference of the winding core 20a. The leading portion 152 is long enough to extend from the primary nip 160 to the secondary nip 168 and, preferably, is long enough to extend beyond the secondary nip 168. The length and rotated position of the guide assembly 112 can be adjusted to accommodate curl or stiffness of the leading portion 152 that would tend to direct the free end 154 of the leading portion 152 away from the primary nip 160.
After the cinch roller 84 reaches the rotated position, the winding spindle 16 is rotated, which causes the winding core 20a and builder roller 50 to rotate in opposite directions of rotation, as indicated by arrows 170 and 172 in
The rotation of the winding spindle 16 is continued until a plurality of turns of web 14 are wrapped over the leading portion 152. The leading portion 152 cinches to the winding core 20a after a turn or two.
The gimbaling of the cinch roller 84 to the axle allows the cinch roller 84 to pivot back and forth relative to the guide axis 122 while the leading portion 152 of the web 14 is bent against the winding core 20a. This accommodates nonuniformity in the cross-section of the winding core 20a and, more importantly, allows the cinch roller 84 to pivot during the winding of the first few turns of web 14. This pivoting of the cinch roller 84 at the gimbal allows the cinch roller 84 to remain parallel to the web 14 at the secondary nip 168, while the first few turns of web 14 are wrapped around the winding core 20a. If a non-gimbaled cinch roller 84 is used, then pressure on one side of the growing web roll 26 increases as the web 14 is wound, due to the change in diameter causes by the turns of web 14. With some web 14 materials, this is unimportant, but with film, there is a risk of pressure marking if a non-gimbaled cinch roller 84 is used.
At some time after cinching, the guide assembly 112 is pivoted back from the first orientation into the second orientation. (See
If the web roll 26 is large, then the builder roller assembly 48 is backed away from the winding axis 38 during winding. The builder roller assembly 48 begins winding in the forward position, and is then moved through a sequence of intermediate winding positions until the web roll 26 is completed.
Referring now particularly to
As long as the builder roller 50 remains in contact with the web 14 at the primary nip 160 and the arm 52 is pivoted within a range of constant force for the spring, then the force applied by the builder roller 50 is also decoupled from the position of the builder roller assembly 48 relative to the winding axis 38. This allows the translational movement of the builder roller assembly 48 during winding to be standardized based upon the rate of web growth at a particular winding rate. This also allows builder roller 50 tension to be quickly and easily optimized for a particular web material and other winding conditions, since builder roller position during winding does not need to be considered.
Referring now particularly to
Features of the invention can be varied to meet particular requirements. For example, it may be convenient to eliminate flanges on the builder roller 50 and cinch roller 84, if the winding core 20a is flanged. Likewise, the apparatus 10 can be modified to utilize the builder roller to dispense a liquid or powdered material onto the web 14 or otherwise treat the web 14. For example, the builder roller can emboss or can apply an overcoat or adhesive layer or inked pattern (using a patterned builder roller).
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
2989265 | Selsted | Jun 1961 | A |
3712554 | Lorenzini et al. | Jan 1973 | A |
4697755 | Kataoka | Oct 1987 | A |
5248107 | Sumida et al. | Sep 1993 | A |
5256232 | Fuss et al. | Oct 1993 | A |
5386950 | Abt | Feb 1995 | A |
5639039 | Ohno et al. | Jun 1997 | A |
5690264 | Distefano et al. | Nov 1997 | A |
6082659 | Sankaran et al. | Jul 2000 | A |
Number | Date | Country |
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231209 | Dec 1985 | DD |
Number | Date | Country | |
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20050029389 A1 | Feb 2005 | US |